EVALUATION OF THE AGRONOMIC, UTILIZATION, NUTRITIVE 
AND FEEDING VALUE OF DESHO GRASS (Pennisetum pedicellatum)  
 
 
 
 
PhD Dissertation 
 
 
 
 
 
Bimrew Asmare Limenih 
 
                                   
 
 
 
 
 
 
 
 
 
 
 
 
June 2016 
 
 
Jimma University
EVALUATION OF THE AGRONOMIC, UTILIZATION, NUTRITIVE 
AND FEEDING VALUE OF DESHO GRASS (Pennisetum pedicellatum)  
 
 
 
A PhD Dissertation Submitted to the School of Graduate Studies 
College of Agriculture and Veterinary Medicine 
 Department of Animal Sciences  
Jimma University 
 
 
 
In Partial Fulfillment of the Requirements for the Degree of Doctor of 
Philosophy (PhD) in Animal Nutrition 
 
 
 
By 
 
Bimrew Asmare Limenih 
 
 
 
 
June 2016  
 
Jimma University 
APPROVAL SHEET 
 
SCHOOL OF GRADUATE STUDIES 
JIMMA UNIVERSITY 
 As Dissertation Research advisors, we hereby certify that we have read and evaluated this PhD 
Dissertation prepared, under our guidance, by Bimrew Asmare entitled “Evaluation Of The 
Agronomic, Utilization, Nutritive And Feeding Value Of Desho Grass (Pennisetum 
pedicellatum)” We recommend that it can be submitted as fulfilling the Dissertation 
requirement.  
1. Solomon Demeke (Professor)                            ____________         __________ 
  Major Advisor                                                       Signature                   Date     
2. Taye Tolemariam (Professor)                     ____________         __________                                                                                                                                                     
    Co-Advisor                                                               Signature                 Date                         
3. Firew Tegegne (PhD, Assoc. Prof.)                       ____________         __________                                                                                                                                                     
        Co-Advisor                                                          Signature                   Date                 
3. Jane Wamatu (PhD, Associate Scientist)                       ____________         __________                                                                                                                                                     
        Co-Advisor                                                          Signature                   Date                 
As member of the Board of Examiners of the PhD Dissertation Open Defense Examination, we 
certify that we have read, evaluated the Dissertation prepared by Bimrew Asmare, and examined 
the candidate. We recommend that the Dissertation be accepted as fulfilling the Dissertation 
requirement for the Degree of Doctor of Philosophy in Animal Nutrition.  
 
1.  _______________________               ______________              ____________ 
    Chairperson                                            Signature                               Date 
2. ________________________             _______________             _____________ 
      Internal Examiner                                   Signature                             Date  
3. ________________________                 ______________            ______________ 
     External Examiner                                    Signature                           Date                          
               
Final approval and acceptance of the Dissertation is contingent upon the submission of the final 
copy to the Council of Graduate Studies (CGS) through the School of Graduate Committee 
(SGC) of the candidate’s major department.
ii 
 
 
 
 
 
DEDICATION 
 
I dedicate this Dissertation to my uncles Melese Limenih and Merigeta Lisanwork Bayeh for 
their enthusiastic partnerships in the success of my life. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
iii 
 
STATEMENT OF THE AUTHOR 
 
I declare that this Dissertation is my work and that all sources of materials used for this 
Dissertation have been duly acknowledged. This Dissertation has been submitted in partial 
fulfillment of the requirements for the PhD degree at Jimma University and is deposited at the 
University library to be made available to readers under the rules of the Library. I truly declare 
that this Dissertation is not submitted to any other institution anywhere for the award of any 
academic degree, diploma or certificate. 
 
Brief quotations from this Dissertation are acceptable without special permission on conditions 
that accurate acknowledgement of the source is made. Requests for permission for extended 
quotation from or reproduction of this Dissertation in whole or in part may be approved by the 
head of the Department of Animal Sciences or the Dean of the School of Graduate Studies when 
in his or her judgment the proposed use of the material is in the interest of scholarship. In all 
other circumstances, however, permission must be obtained from the author. 
 
  
Name: Bimrew Asmare                  Signature: ________________ 
Place: Jimma University, Jimma. 
Date of submission: __________________ 
 
 
 
 
 
 
 
 
 
 
iv 
 
BIOGRAPHICAL SKETCH 
 
The author, Bimrew Asmare was born on June 2, 1978 in Fagita Lekoma District, Awi 
Administrative Zone, Amhara National Regional State. He attended his elementary education in 
Besena and Dejazmach Mengesha Jemberie Primary Schools. He continued his high school 
studies at Dangila Senior Secondary School and completed at Chagni Senior Secondary School. 
After passing Ethiopian High School Certificate Examination successfully, he joined the then 
Awassa College of Agriculture (the current Hawassa University) in 1996/97 academic year and 
graduated with B.Sc. degree (in Distinction) in Animal Production and Rangeland Management 
in July 2000.  
 
Soon after his graduation, the author was employed by the Amhara National Regional State, 
Bureau of Agriculture and assigned at Andassa Livestock Production Center. Bimrew joined 
Mersa Agricultural Technical and Vocational Education and Training (ATVET) College and 
assigned as an instructor at the Department of Animal Sciences in 2003. In 2004, he transferred 
to Woreta ATVET College and worked as an instructor and Head of the Department of Animal 
Sciences. In 2006, he joined the School of Graduate Studies of Haramaya University and 
graduated with M.Sc. degree in Animal Production in December 2008. Soon after his graduation, 
Bimrew re-joined Woreta ATVET College and served as Senior Instructor at the Department of 
Animal Sciences. In November 2009, he joined Bahir Dar University, College of Agriculture and 
Environmental Sciences, Department of Animal Production and Technology and served as a 
Lecturer and Coordinator of Continuing and Distance Education at the College of Agriculture 
and Environmental Sciences. Finally he joined Jimma University College of Agriculture and 
Veterinary Medicine, Department of Animal Sciences in October 2012 to pursue his PhD in 
Animal Nutrition. At present the author is married and has a son.  
v 
 
ACKNOWLEDGEMENTS 
 
The author would like to express his sincere thanks to his advisors Professor Solomon Demeke, 
Professor Taye Tolemariam, Dr. Firew Tegegne and Dr. Jane Wamatu for their guidance and 
encouragement from the inception of the proposal up to the final dissertation and paper 
preparation. The author would like to acknowledge the Ethiopian Ministry of Education, for 
provision of financial support and Bahir Dar University for allowing study leave and the use of 
research facilities. Jimma University is appreciated for timely budget release and provision of 
certain critical missing links during the study period. The author would like to acknowledge the 
International Center for Agricultural Research in the Dry Areas (ICARDA), for its financial 
assistance and provision of laboratory facilities. The author’s gratitude would extend to Dr. 
Barbara Rischowsky and Dr. Aynalem Haile for their support. Mr. Yonas Asmare of ILRI 
animal nutrition laboratory deserves great appreciation for his analytical assistance. The author’s 
special appreciation goes to his class mates Ashenafi Assefa and Kassaun Gurmessa for their 
good friendship.  
 
The author’s thanks goes to Wondemenh Mekonenn, Yihenew Agaje, Shigdaf Mekuriaw and 
Shewangizaw Wolde of Andassa and Areka research centers for their contribution in site 
selection, field layout and data collection during the planing and conduct of the agronomic trial. 
The author’s gratitude also extended to Mr. Yeshambel Asmamaw and Muluat Hundre of Burie 
Zuria and Doyogena District Agricultural Offices, respectively, for their assistance in the 
selection of the Kebeles and participating households and in the planing and organization of the 
field survey study. The contribution of Esubalew Admasu and Melkamu Kefale of Bahir Dar 
University, College of Agriculture and Environmental Sciences, deserve great acknowledgment. 
Special thanks go to Dr. Yeshambel Mekuriaw, Dr. Asaminew Tassew, and Dr. Hailu Mazengia 
for their encouragement throughout the study period. The author extends his thanks to 
CASCAPE project (aligned to Bahir Dar University, College of Agriculture and Environmental 
Sciences) for introducing desho grass to northwestern Ethiopia which was used as source of 
planting material for the conduct of the agronomic experiment.  
 
vi 
 
 Above all, the author would like to give his special and deepest appreciation to his wife 
Yeshiwork Bishaw and to his son Estifanos Bimrew, who suffered a lot from his absence; and 
yet offered him love, understanding and encouragement, during his academic undertaking and 
field data collection. Finally the author would like to thank the Almighty God for giving him 
health, strength, and support in the successful completion of his study. 
vii 
 
ABBREVIATIONS  
 
ADF   Acid Detergent Fiber 
ADG     Average Daily Gain 
ADL     Acid Detergent Lignin 
AGDP Agricultural Gross Domestic Product 
ALRC Andassa Livestock Research Center 
ANOVA Analysis of Variance 
AOAC Association of Official Analytical Chemists 
BW     Body Weight 
BZDoA Burie Zuria District Office of Agriculture 
CAES College of Agriculture and Environmental Sciences 
CASCAPE Capacity Building for Scaling Up of Evidence Based Best Practices in 
Agricultural Production in Ethiopia 
CP      Crude Protein 
CPY Crude Protein Yield 
CSA Central Statistical Agency 
DAP Di-Ammonium Phosphate 
DCP Digestible Crude Protein 
DDoA Doyogena District Office of Agriculture  
DG Desho Grass 
DGH Desho Grass Hay 
DM     Dry Matter 
DMI Dry Matter Intake 
DMD    Dry Matter Digestiblity 
DMY Dry Matter Yield 
DOM Digestible Organic Matter 
DOMI    Digestible Organic Matter Intake   
EPPO European and Mediterranean Plant Protection Organization 
FAO Food and Agriculture Organization of the United Nations  
 
viii 
 
ABBREVIATIONS (Continued) 
FCE Feed Conversion Efficiency 
FDoA Farta District Office of Agriculture  
GDP     Gross Domestic Product 
GLM     General Linear Model 
ICARDA International Center for Agricultural Research in the Dry Areas 
ILCA International Livestock Center for Africa 
ILRI International Livestock Research Institute 
IPMS Improving Productivity and Market Success 
IVDMD In vitro Dry Matter Digestibility 
IVOMD In vitro Organic Matter Digestibility 
m.a.s.l. Meter Above Sea Level 
ME      Metabolizable Energy 
MJ Mega Joule 
LLPP Leaf Length Per Plant 
LSR Leaf to Stem Ratio 
NDF     Neutral Detergent Fiber 
NLPP Number of Leaves Per Plant 
NPH Natural Pasture Hay 
NRC National Research Council 
NSC Noug Seed Cake  
OM Organic Matter 
OMDC    Organic Matter Digestibility Coefficient 
OMI Organic Matter Intake 
RCBD Randomized Complete Block Design 
SAS Statistical Analysis System 
SD Standard Deviation 
SNNPRS Southern Nations, Nationalities, and Peoples Regional State 
TLU Tropical Livestock Unit 
 
ix 
 
ABBREVIATIONS (Continued) 
WB Wheat Bran 
WHO World Health Organization  
WOCAT World Overview of Conservation Approaches and Technologies 
x 
 
     TABLE OF CONTENTS 
TITLE  PAGE 
 
APPROVAL SHEET ii 
DEDICATION iii 
STATEMENT OF THE AUTHOR iv 
BIOGRAPHICAL SKETCH v 
ACKNOWLEDGEMENTS vi 
ABBREVIATIONS viii 
TABLE OF CONTENTS xi 
LIST OF TABLES xiv 
LIST OF FIGURES xv 
LIST OF TABLES IN THE APPENDIX xvi 
ABSTRACT xvii 
1. INTRODUCTION 1 
1.2. Research Gap 3 
1.2. Research Questions and Objectives 3 
2. LITERATURE REVIEW 5 
2.1. Feed Resources in Ethiopia 5 
2.1.1. Natural Pasture 5 
2.1.2. Crop Residues 6 
2.1.3. Agro-industrial By-products 8 
2.1.4. Indigenous Fodders 12 
2.1.5. Improved Forages 13 
2.1.6. Non-Conventional Feed Resources 14 
2.2. Effect of Season on Availability and Quality of Feeds 14 
2.3. Effect of Environmental Factors on Plant Growth and Chemical Composition 15 
2.4. Desho Grass (Pennisetum pedicellatum) 16 
xi 
 
     TABLE OF CONTENTS (Continued) 
TITLE  PAGE 
 
2.4.1. Geographical Distribution of Desho Grass (Pennisetum pedicellatum) 16 
2.4.2. Nutritive Value of Desho Grass 17 
2.4.3. Desho Grass in Ethiopia 17 
2.4.4. Growing Conditions of Desho Grass 18 
2.5. Effect of Harvesting Dates on Yield and Quality of Forages 18 
2.6. Washera Sheep Breed and its Characteristics 19 
2.7. Nutrient Requirement and Growth Performance of Sheep 20 
2.7.1. Dry matter intake 21 
2.7.2. Energy requirements 23 
2.7.3. Protein requirements 24 
3. MATERIALS AND METHODS 26 
3.1. Description of Study Areas 26 
3.2. Survey on Desho Grass Production and Utilization 29 
3.3. Study on Agronomic and Laboratory Characteristics 30 
3.4. Animal Evaluation Experiment 31 
3.4.1. Experimental Feed Preparation 31 
3.4.2. Management of the Experimental Animals 31 
3.4.3. Growth Trial 32 
3.4.4. Digestibility Trial 33 
3.5. Laboratory Analysis 33 
3.6. Sampling Technique and Statistical Analysis 34 
4. RESULTS AND DISCUSSION 36 
4.1. Desho Grass Production and Utilization 36 
4.1.1. Household Characteristics of Desho Grass Producers 36 
4.1.2. Feed Resources and Feeding System 37 
4.1.3. Production and Management of Desho Grass 41 
4.1.4. Utilization of Desho Grass 43 
xii 
 
   TABLE OF CONTENTS (Continued) 
TITLE  PAGE 
 
4.1.5. Factors Affecting Preference of Desho Grass for Livestock 48 
4.2. Agronomic and Laboratory Characteristics of Desho Grass 50 
4.2.1. Effects of altitude, harvesting days and their interactions on plant morphological 
characteristics and number of re-growth days of desho grass 50 
4.2.2. Effect of altitude, harvesting date and their interacton on chemical composition 
and yield of desho grass 53 
4.2.3. Correlation Analysis of Morphological and Nutritional Parameters of Desho Grass
 57 
4.3. Animal Evaluation of Desho Grass (Pennisetum Pedicellatum) 60 
4.3.1. Chemical Composition of Experimental Feeds 60 
4.3.2. Feed Intake 62 
4.3.4. Dry matter and nutrient digestibility 64 
4.3.3. Body weight change and feed conversion efficiency 66 
4.3.5. Correlation between nutrients intake, digestibility and daily body weight gain of 
Washera sheep 68 
5. CONCLUSION AND RECOMMENDATION 70 
5.1. Conclusion 70 
5.2. Recommendations 71 
6. REFERENCES 72 
7. APPENDICES 91 
xiii 
 
LIST OF TABLES 
 
TABLE                                                                                                                                    PAGE     
Table 1. Proportion of animal feed resources in ethiopia 6 
Table 2. Daily energy requirements of sheep 23 
Table 3 . Experimental rations used in the feeding trial 31 
Table 4. Socioeconomic and biophysical characteristics of the respondents 37 
Table 5. Feed resource and feeding system practice of respondents in study districts (N=240) 39 
Table 6.  Factors affecting the utilization of desho grass as feed by smallholder farmers in the 
study districts 44 
Table 7.  Factors affecting the number of uses of desho grass for the household 47 
Table 8.  Factors affecting preference of desho grass by livestock in the study districts 49 
Table 9. Effects of altitude and harvesting days on plant morphological characteristics and 
number of re-growth days of desho grass 51 
Table 10. Effect of altitude, harvesting date and their interacton on chemical composition and 
yield of desho grass 54 
Table 11. Correlation coefficients among morphological parameters, chemical composition, yield 
and in vitro organic matter digestibility of desho grass 58 
Table 12. Correlation coefficients among morphological parameters, chemical composition, yield 
and in vitro organic matter digestibility of desho grass (continued) 59 
Table 13. Daily dry matter and nutrient intake of washera sheep fed natural pasture and desho 
grass hay basal diet, supplemented with mixture of noug seed cake and wheat bran in 
50:50 ratio. 63 
Table 14. Apparent digestibility coefficients of nutrients by washera sheep fed natural pasture 
and desho grass hays basal diet supplemented with mixture of noug seed cake and wheat 
bran. 65 
Table 15. Body weight parameters and feed conversion efficiency of washera sheep fed on 
natural pasture hay and desho grass hay mixture and supplemented with noug seed cake 
and wheat bran in 50:50 ratio. 66 
Table 16. Correlation between nutrient intake, digestibility and body weight gain in washera 
sheep fed natural pasture and desho grass hay supplemented with noug seed cake and 
wheat bran mixture. 69 
xiv 
 
LIST OF FIGURES 
FIGURE                                                                                                           PAGE     
Figure 1. Map Showing Study Districts:  Burie Zuria (A), Bahir Dar Zuria (Andassa Livestock 
Research Center And Bahir Dar University) (B), Farta (C) And Doyogena (D). 28 
Figure 2. Feed Shortage Mitigation Strategies Of Respondents In The Two Districts 38 
Figure 3. Desho Grass Production Strategies Of Respondents 42 
Figure 4. Farmer Cutting Desho Grass (A) And Cow Eating Fresh Grass (B) 46 
Figure 5. Trends In Body Weight Changes Of Washera Sheep Fed Natural Pasture And Desho 
Grass Hay And Supplemented With Mixture Of Noug Seed Cake And Wheat Bran. 67 
 
 
xv 
 
LIST OF TABLES IN THE APPENDIX 
 
TABLE                                                                                                                              PAGE                
 
Table 1. Summary of anova for plant morphological characteristics and number of re-growth 
days of desho grass as affected by altitude 93 
Table 2. Summary of anova for plant morphological characteristics and number of re-growth 
days of desho grass as affected by days in the midland and highlands 93 
Table 3. Summary of anova for plant morphological characteristics and number of re-growth 
days of desho grass as affected by the interaction of harvesting days and altitudes 94 
Table 4.  The effect of altitude on chemical composition and yield of desho grass 94 
Table 5. The effect of harvesting dates on chemical composition and yield of desho grass in mid 
altitude area. 95 
Table 6.  The effect of harvesting dates on chemical composition and yield of desho grass in high 
altitude area. 95 
Table 7. The effect of harvesting dates on chemical composition and yield of desho grass in high 
altitude area. 96 
Table 8. Summary of anova for the dry matter and nutrient intake of washera sheep fed natural 
pasture and desho grass hay supplemented with noug seed cake and wheat bran mixture 
in 50:50 ratio. 96 
Table 9. Summary of anova for nutrient digestibility of washera sheep fed natural pasture and 
desho grass hay supplemented with noug seed cake and wheat bran mixture in 50:50 
ratio. 97 
Table 10. Summary of anova for body weight parameters and feed efficiency ratio of washera 
sheep fed natural pasture and desho grass hay supplemented with noug seed cake and 
wheat bran mixture in 50:50 ratio. 97 
xvi 
 
EVALUATION OF THE AGRONOMIC, UTILIZATION, NUTRITIVE 
AND FEEDING VALUE OF DESHO GRASS (Pennisetum pedicellatum)  
 
ABSTRACT 
This study comprised of field survey, agronomic trial, laboratory and animal evaluation of desho 
grass. A total of 240 households (hh) were involved in the field survey conducted to assess the 
status of desho grass production and utilization in Burie Zuria and Doyogena districts, with the 
use of pre-tested and semi- structured questionnaire. The grass was planted at mid and highland 
altitudes using vegetative root splits in randomized complete block design to determine the 
effects of altitude and harvesting dates (90, 120 and 150 days after planting) on  morphology, 
dry matter (DM) yield and chemical composition of desho grass. Feeding & digestibility trials 
were conducted using 25 Washera yearling rams with mean body weight of 19.4+1.89 kg in 
randomized complete block design to evaluate the feed potential of desho grass as a basal diet. 
The dietary treatments studied were; 100% Natural Pasture Hay (NPH) (T1), 75% NPH+25% 
Desho Grass Hay (DGH) (T2), 50% NPH + 50% DGH (T3), 25% NPH+75% DGH (T4), and 
100% DGH (T5). All the treatment groups were supplemented with 300 g/h DM of concentrate & 
data on feed intake, daily body weight gain, feed conversion efficiency & fecal samples were 
collected during the 90 and 7 days of feeding and digestibility trial respectively. The field survey 
data were analyzed with the help of descriptive statistics and probit model using SAS 9.2. The 
agronomic characteristics and laboratory analytical data were subjected to two-way ANOVA 
and correlation analysis of SAS 9.2. Animal evaluation data were analyzed using one-way 
ANOVA of SAS. Tukey’s Honest Significant Test was used to separate means that showed 
significant difference. The results of the field survey revealed that the mean landholding, 
livestock holding and family size of the respondents was 0.95 hectare, 3.56 tropical livestock 
units and 6.5 persons/hh, respectively. The proportion of farmers who use desho grass as a feed 
were 60% and 35%  use it for more than one purpose including feed. About 42, 3 and 53% of the 
respondents reported that they feed desho grass to lactating cattle, small ruminants and to all 
livestock species respectively. There was significant positive correlation (P<0.01) between 
experience of desho grass production practice and utilization for different purposes in the study 
areas. About 43% of desho grass producers have received training on desho grass production 
and utilization. The utilization of the grass for many purposes is not well practiced by many 
farmers, due to in adequate extension services and lack of training. The results of the agronomic 
trials indicated that leaf length per plant (LLPP) of the grass planted in mid altitude (28.98 cm) 
was greater than that (21.81 cm) planted in the high altitude. Highest harvesting date 
significantly increased (P<0.05) plant height (PH), number of tillers per plant (NTPP), number 
of leaves per plant (NLPP), leaf length per plant (LLPP) and re-growth dates (RGD). The DM 
yield of desho grass significantly increased, while crude protein (CP) content signifinantely 
decreased (P<0.05) as the harvesting date increased from 90 to 150 days. Agronomic results 
xvii 
 
revealed that desho grass performs well both in mid and high altitude areas and represent 
potential livestock feed resource at early stage (90 to 120 days after planting) of feeding.The 
daily DM intake and mean daily body gain of the experimental sheep showed significant 
improvement (P<0.05) with increased level of inclusion of desho grass into the basal ration. The 
digestibility coefficient of DM, OM, CP, NDF and ADF were significantly different (P<0.05) 
among the treatments (in the order of T1<T2<T3<T4<T5). The result of the feeding trial 
indicated that desho grass hay could safely be included at 50-100% into small ruminant basal 
ration at the expense of natural pasture hay in Ethiopia. The grass performed well in both mid 
and highlands, multifunctional in use and appropriate for smallholder farming systems of the 
country. 
 
Keywords: Altitude, Basal diet, Body weight, Desho grass, In vitro organic matter digestibility, 
Natural pasture Hay, Harvesting dates, Metabolizable energy, Probit Model, Washera sheep. 
xviii 
 
1. INTRODUCTION 
 
Ethiopia owns the largest livestock population among African countries (CSA, 2015). Livestock 
contribute 15-17% of GDP and 35- 49% of agricultural GDP, and 37-87% of the household 
incomes (Ayele et al., 2003). A study by IGAD (2010) indicated that the livestock sector 
contributes about 47% to the Agricultural Gross Domestic Product (AGDP), including monetary 
values and the non-marketed services (traction and manure) in Ethiopia. At the household level, 
livestock plays a significant role as sources of food and family income for smallholder farmers 
and pastoralists. About 80% of the Ethiopian farmers use animal traction to plough cropping 
fields (Melaku, 2011). Livestock also plays an important role in urban and peri-urban areas for 
the poor evoking a living out of it and for those involved in commercial activities (Ayele et al., 
2003). Hence, livestock remains as a pillar for food security, human nutrition and economic 
growth of the county (Shapiro et al., 2015). In developing countries (including Ethiopia) demand 
for human foods of animal origin is increasing from time to time due to human population 
growth, rise in income and urbanization (Thornton, 2010) which could be seen as an opportunity 
to benefit from the livestock sector. However, the contribution of the Ethiopian livestock 
resource to human nutrition and export earning of the country is disproportionately low due to 
poor productivity of the animals as compared to the regional and continental average (FAO, 
2001; Behnke and Metaferia, 2011). This is mainly due to low quality and insufficient feed 
supply (Berhanu et al., 2007; FAO, 2010; Getahun et al., 2010). 
 
The major available feed resources in Ethiopia are natural pasture, crop residues, aftermath 
grazing, and agro-industrial by-products (Alemayehu, 2006; Adugna, 2007; Firew and Getnet, 
2010; Yaynshet, 2010). The current report of CSA (2015) revealed that 56, 30 and 1.2% of the 
total livestock feed supply of the country is derived from grazing on natural pasture, crop 
residues and agro industrial byproducts respectively. However, the  contribution of the natural 
pasture,  is retreating from time to time due to poor management and continued expansion of 
crop farming (Solomon et al., 2003), indicating that livestock feed shortage in the country is 
further aggravated by the continuous conversion of grazing land to crop land. The available 
grazing lands are also vulnerable to degradation and consequently become barren and gullies due 
to poor management. This illustrates the increasing role of poor quality crop residues in livestock 
1 
 
feeding (Zewdie and Yosef, 2014), which in turn is explanatory for exploring alternative feed 
resources.  
 
One of the options in combating the existing livestock nutritional constraints is the use of 
indigenous cultivated multipurpose forages as livestock feed (Abebe et al., 2008; Anele et al., 
2009) in addition to crop residues. According to Anele et al. (2009), indigenous forages are 
familiar with the smallholder farmers, grow with low inputs, and are adaptable to different agro-
ecological conditions. The use of indigenous forages as a feed resource is appealing under the 
present Ethiopian conditions to increase production and productivity of livestock (Shapiro et al., 
2015). Thus, one of the interference areas to boost livestock production in the country includes 
the use of indigenous forages as the major source of feed (Shapiro et al., 2015).  
 
Desho grass is one of the indigenous forage species which need a comprehensive research in 
Ethiopia. Desho grass (Pennisetum pedicellatum) is native to tropical countries including 
Ethiopia (Ecocrop, 2010; Leta et al., 2013; EPPO, 2014). In Ethiopia desho grass is known as a 
perennial plant originated in Southern region of the country. Currently the grass is utilized as a 
means of soil conservation practices and animal feed in the highlands of Ethiopia (Welle et al., 
2006; Ecocrop, 2010). The grass is drought resistant plant, used as feed for ruminants (FAO. 
2010; EPPO, 2014). It has the potential of meeting the challenges of feed scarcity since it 
provides more forage per unit area and ensures regular forage supply due to its multi-cut nature 
(Ecocrop, 2010). Desho grass is suitable for intensive management and performs well at an 
altitude ranging from 1500 to 2800 m.a.s.l (Leta et al., 2013). The ability of desho grass as 
drought tolerant makes it easily adaptable to tropical environments. The merits of the grass  to 
provide multi-cut forages suggests that it is a potential feed source in the dry season when feed 
availability in the tropics is critical (Brias and Tesfaye, 2009). The combined benefits of desho 
grass suggest the use of the grass as potential feed source and means of soil conservation in the 
mixed crop livestock production systems of Ethiopia.   
 
It is known that the quality of given forage as animal feeds is a function of its nutrient 
concentration, palatability and digestibility by animals (Julier et al., 2001). Such attributes of 
forage are affected by the interaction of a number of factors including plant species/variety, plant 
2 
 
morphological fraction, environmental factors, and stage of maturity and feeding practices 
(Papachristou and Papanastasis, 1994). The extent to which these factors affect the productivity 
and nutritive value of desho grass is not well known in Ethiopia. Therefore, investigating the 
status of production, agronomic practices, morphological characteristics, chemical composition, 
nutritive value and utilization of desho grass under different agro-ecological conditions are 
important tools in understanding the potential value of the grass.  
 
1.2. Research Gap 
 
There are certain information generated on desho grass in the form of newsletter and working 
papers in Ethiopia (Smith, 2010; Leta et al., 2013). The use of desho grass in soil and water 
conservation has been reported (Welle et al., 2006; Smith, 2010). According to Papachristou and 
Papanastasis (1994), the nutritive value of fodder and forage crops is affected by different factors 
such as plant species, plant morphological fractions, the stage of maturity of the plant, and 
environmental factors including rainfall, temperature and soil type. What has been studied about 
desho grass in Ethiopia were restricted in locations and focused on the potential value of the 
grass for soil and water conservation without considering its feed value. There has been no 
comprehensive and adequately informative attempt made in the area of identification of the feed 
value and other economic importance of desho grass in Ethiopia. In line with this, Lukuyu et al. 
(2011) reported the importance of understanding chemical composition and utilization 
information of locally available feed resources to include it in to livestock feeding system. Thus, 
it is important to study in to the economic importance and the effects of altitude and stage of 
maturity at harvest on morphological parameters, yield, chemical composition and livestock feed 
value of desho grass in Ethiopia. 
 
1.2. Research Questions and Objectives  
 
Shortage of feed both in quantity and quality is reported to remain one of the limitations of 
livestock production in Ethiopia, indicating the need to investigate in to locally available forage 
plants with potential feed value. Desho grass is one of the locally available forages with high 
potential for environmental rehabilitation and animal feed. Therefore, it is important to study its 
characteristics, uses and roles in the farming systems of Ethiopia.    
3 
 
The research questions addressed in this study were; 
 (1) What is the status of desho grass production and management in Burie Zuria and Doyogena 
districts of Ethiopia? 
(2) How is desho grass utilized by small holder farmers?  
(3) What factors affect the production and utilization of desho grass under small holder farmers’ 
condition?  
(4) Do altitude and stage of maturity at the time of harvest affect morphological fractions, 
chemical composition and yield of desho grass?  
(5) What is the response of animals fed desho grass as a basal diet compared to natural pasture 
hay? 
 
General objective 
The general objective of this dissertation was to generate information on farmers’ utilization and 
management practices of desho grass, determine effect of altitude and stage of harvest on 
morphological parameters, herbage yield, chemical composition and feeding value of the grass 
under controlled conditions. 
 
Specific objectives 
The specific objectives of this dissertation were: 
1. To assess the production and utilization practices of desho grass in Burie Zuria and 
Doyogena districts. 
2. To evaluate the effects of altitude and dates of harvesting after planting on the morphological 
characteristics, yield and chemical composition of desho grass, in Burie Zuria and Doyogena 
districts.  
3. To determine the production performance (feed intake, digestibility and body weight change) 
of Washera sheep fed different levels of desho grass hay with supplementary concentrate 
mixture feed. 
4 
 
2. LITERATURE REVIEW 
 
2.1. Feed Resources in Ethiopia 
 
There are different types of livestock feed resources in Ethiopia, most of which are subjected to 
seasonal availability. According to Seyoum et al. (2001), feed resources vary with the type of 
agricultural activities (mode and intensity of crop production), population pressure, agro-ecology, 
season of the year and environmental conditions such as rainfall distribution. Alemayehu (2005) 
grouped the Ethiopian livestock feed resources into grazing land (natural pasture), crop residues, 
aftermath grazing, improved pasture, fodder trees and browse, forage crops and agro-industrial 
by-products. Moreover, there are also feed resources such as byproducts of vegetables, kitchen 
wastes, etc generally known as non-conventional feeds.  
 
2.1.1. Natural Pasture 
 
Natural pasture is an important sources of ruminant livestock feed in developing countries (FAO, 
2001; Solomon et al., 2008). Similarly the major contributor of livestock feeds in Ethiopia is 
natural pasture or grazing lands (CSA, 2015) and it is reported that about 56.23 % of the total 
feed resources is derived from grazing on natural pasture (Table 1). Natural pastures include 
annual and perennial species of grasses and herbaceous legumes (FAO, 2001). The availability 
of natural pasture in the highlands of Ethiopia depends on the intensity of crop production, 
population pressure, the amount of rainfall, and distribution pattern of rainfall and seasons of the 
year (Mohammed and Abate, 1995). The contribution of these factors to the total feed resource 
base varies from area to area based on cropping intensity (Seyoum et al., 2001). The reliability of 
natural pasture as a source of feed in Ethiopia is restricted to the wet season (Zinash et al., 1995). 
And yet grazing lands play a significant role in livestock feeding and support a diverse range of 
grasses, legumes, shrubs and trees. Feed values of natural pasture fluctuate considerably in 
quality based on components such as protein and fiber, which are generally inversely 
proportional to each other. Natural pastures are categorized as poor quality roughage with low 
intake (Berhanu et al., 2009), tough texture, poor digestibility and nutrient deficiency, 
5 
 
particularly that of crude protein and metabolizable energy in relation to the requirements of the 
animals (Mupangwa et al., 2002). 
 
Table 1. Proportion of Animal Feed Resources in Ethiopia 
 
S.No. Feed Type Percentage 
1 Grazing 56.23 
2 Crop residue 30.6 
3 Hay 7.44 
4 Agro-industrial byproducts 1.21 
4 Others feed/concentrate feeds 4.76 
5 Improved fodder or pasture 0.3 
                            
Source: CSA (2015) 
 
In Ethiopia, the available grazing land diminished faster during the last few years and is likely to 
continue in the future. The increased population pressure, expansion of crop farming, and 
emerging urbanization leads to further shrinkage of the existing natural pasture land. It has been 
reported that, the share of natural grazing pasture at the national level has been reduced from 
90% (Alemayehu, 1985), to about 56.23% (CSA, 2015). The productivity of the available 
grazing lands is estimated to range between 0.5 and 6 tons of DM/ha, the value of which is 
characterized as low productivity as compared to the yield from improved pasture (Adane and 
Berhan, 2005; Alemayehu, 2006).   
 
2.1.2. Crop Residues 
 
In the mixed cereal dominated crop and livestock farming system of the Ethiopian highlands, 
crop residues provide about 50% of the total ruminant livestock feed resource. The contributions 
of crop residues could be as high as 80% during the dry seasons of the year (Adugna, 2007). The 
high dependency on crop residues as livestock feed is expected to be higher and higher, as more 
and more of the grazing lands are cultivated to satisfy the grain needs of the rapidly growing  
6 
 
human population. The contribution of crop residues to the national feed resource base is 
significant (Solomon et al., 2008), since the available evidences tend to indicate that (Daniel, 
1988; Lemma, 2002), under the current Ethiopian condition, crop residues provide 40-50% of the 
annual livestock feed requirement. According to Gashaw (1992), in most parts of the central 
highlands of Ethiopia, crop residues account for about 27% of the total annual feed supply during 
the dry periods. On the average, crop residues provide 10-15% of the total feed intake in the 
mixed crop-livestock producing areas (Alemayehu, 2004) in the central highlands of Ethiopia. It 
has been reported that, in most intensively cultivated areas, crop residues and aftermath grazing 
account for more than 60-70% of ruminant animal’s basal diet (Seyoum et al., 2001).The general 
tendency is that the role of crop residue as livestock feed is increasing from time to time at the 
expense of shrinkage of grazing lands (CSA, 2015). 
 
Teff, barley, wheat and pulse straws are stacked after threshing and fed to animals during the dry 
season when the quality and quantity of the available natural pasture declines drastically in 
different parts of the Ethiopian highlands (Adugna and Said, 1994; Solomon et al., 2008). The 
supply of these crop residues is directly proportional to the land area used for cropping the grains 
(Daniel, 1988). Cereals account for more than 75% of the total crop residue yield in the central 
highlands of Ethiopia (Yoseph, 1999). Crop residues are increasingly becoming the major basal 
feed for livestock in the crop-livestock mixed farming systems of Ethiopia. The optimum 
utilization of crop residues is constrained by their low feed quality as measured in terms of 
protein content and digestibility (Daniel, 1988). Moreover, most of the crop residues used as 
livestock feed are subjected to seasonal fluctuation in availability and used without any treatment 
and/or strategic supplementation (Adugna and Said, 1992; Solomon et al., 2008).  
 
Crop residues are of very poor in feeding value attributed to low metabolizable energy, available 
protein and serious deficiency in mineral and vitamins (Staniforth, 1979). Crop residues vary 
greatly in chemical composition and digestibility depending on varietal differences (Reed et al., 
1986) and agronomic practices (Staniforth, 1979). The feeding value of crop residues is also 
limited by their poor voluntary intakes and low digestibility (Alemu, 1991). The crude protein 
content of crop residues ranges between 2.4 and 7% and their IVDMD ranges between 34 and 
52% (Gashaw, 1992). Cereal straws have a mean CP, NDF, and IVDMD values of 4.5, 79.4 and 
7 
 
51.1%, respectively compared to pulse straws, which have a mean CP, NDF and IVDMD values 
of 7, 62.9 and 63.5%, respectively. Straws of oil crops have CP and NDF values of 5.4 and 
66.4%, respectively (Alemu et al., 1991).  
 
Crop residues are generally characterized by high fiber content and low digestibility and intake 
(Zewdie et al., 2011). Most cereal straws and stovers are known for their lower nutritive value 
compared to haulms of grain legumes and vines from root crops such as sweet potato. The 
haulms of leguminous crops were reported to represent good quality roughages with CP contents 
ranging between 5 and 12% (Adugna, 2007). In the highland mixed crop livestock farming 
systems of the Ethiopian highlands, the cereal crop residues provide about 50% of the total feed 
source for ruminant livestock. The contributions of crop residues reach up to 80% during the dry 
seasons of the year (Adugna, 2007). Further increased dependence on crop residues for livestock 
feed is expected, as more and more of the native grasslands are cultivated to satisfy the grain 
food needs of the rapidly increasing human population in the country. 
 
The total annual production of crop residues in Ethiopia is estimated to be 30 million tons of DM 
(Adugna et al., 2012), of which 70% is utilized as livestock feed. Based on the existing trend of 
conversion of grazing land into cropping land, crop residues based livestock production system is 
expected to increase proportionally (Peter et al., 2010). However, crop residues tradeoffs (using 
crop residues for different uses) such as household energy source, house construction and other 
related industrial use may lead to serious competition with livestock production. Crop residues 
are also advocated in the context of soil conservation and it is recommended that about 30% of 
the total crop residues produced on a given plot of land should be left on the land for soil 
amelioration and protection from erosive losses. The combinations of these crop residues 
tradeoffs will in general reduce the contributions of crop residues to livestock feed resources 
(Angaw et al., 2011). Hence, there is a need to look for other alternative feed resources as 
complementary feeds to crop residues.  
 
2.1.3. Agro-industrial By-products 
 
Feed resources of agro-industrial origin include by-products of cereal milling and by-products 
cooking oil extractions, both which are good source of easily fermentable energy and protein. 
8 
 
Agro-industrial by-products that are once categorized as wastes are now considered as valuable 
livestock feeds (Ensminger et al., 1990). Almost all plant material produced or processed for 
food or feed yields one or more by-products that can be utilized as animal feed. Under the 
current Ethiopian conditions the major agro-industrials by-products include residues remaining 
behind oil seed and grain processing (Firew and Getnet, 2010). Residues from the processing of 
the various agricultural by-products should become a more important element in ameliorating 
inadequate feed supplies (Devendra and Mcleroy, 1982). Oilseed cakes (oilseed meals) are by-
products generated from processing of oil crops such as groundnut, sunflower and soybean. 
Ibrahim (1998) reported that oilseed cakes are rich in protein quality and quantity and fatty acids. 
Oil seed cakes commonly used as protein concentrates in animal feeding are soybean meal, 
coconut meal, cottonseed meal, linseed (flax) meal, noug seed cake, sesame meal and sunflower 
meal. The use of oil seed cakes in animal feeding are affected by availability and digestibility of 
amino acids, the concentrations of minerals and vitamins and the level of moisture, fiber and 
urease. The feeding value of oil seed meal also varies according to the method of extraction 
(Ensminger et al., 1990).  
 
In Ethiopia, oil extraction is done almost entirely by mechanical pressing method with the use of 
old machines in the oil milling industries (CSA, 2015). It has been indicated that sunflower seed 
cake was utilized effectively by Menz sheep in the Ethiopian highlands in terms of rumen 
microbial nitrogen synthesis, nitrogen retention and growth (Osuji and Nashal, 1993). The 
addition of small amounts of energy such as crushed maize grain on the top of the oilseed cake, 
further increased microbial nitrogen synthesis, nitrogen retention and live weight gain. Solomon 
(1992) reported significant increase in growth rates of sheep fed on ration supplemented with 
groundnut seed cake. Based on feed conversion efficiency, oil seed cakes could  be ranked on 
descending order as cotton seed cake, noug cake and ground nut cake (Solomon,1992).The other 
major agro-industrial by-products commonly used as animal feed are by-products obtained from 
flour milling, brewery and sugar  industries. Agro-industrial by-products could either be protein 
concentrate, energy concentrate or both. Local brewer’s byproducts (brewer’s grains) are good 
source of protein for livestock feeding in Ethiopia (Solomon, 2007). They are low in fiber 
content, high in digestibility and energy value for ruminant animal feeding compared with poor 
quality tropical feed resource (Seyoum and Zinash, 1989). Alemu et al. (1991) reported more 
9 
 
than 35% crude protein and 50-70% in-vitro organic matter digestibility for oil seed cakes and 
18-20% crude protein and more than 80% in-vitro organic matter digestibility for flour milling 
by-products. Supplementing low quality ruminant feeds with agro-industrial by-products 
improves animal performance attributed to the higher nutrient density of the supplement to 
correct the nutrient deficiencies in the basal diet. 
 
2.1.3.1. Noug Seed Cake  
 
Oilseed cakes (oilseed meals) are by-products from processing a variety of oil crops such as 
groundnut, sunflower and soybean. The cakes remaining behind the extraction of cooking oils 
are rich in protein and fatty acids (Ibrahim, 1998). Among the oil seeds of the tropics, Noug seed 
(Guizoita abyssinica) is widely cultivated in Ethiopia and represent widely available and cheap 
source of good quality protein for animal feeding. Noug seed (Guizoita abyssinica) is an annual 
herbaceous plant with soft hairy stems reaching a height of 15 m. The plant is cultivated in India 
and tropical Africa, particularly in Ethiopia, for the edible oil obtainable from the small black 
seeds. Noug seed cake is exported as feed for caged birds. The nutritive value of Noug seed cake 
is affected by the oil processing method and the degree of extraction of edible oil (Alemu, 1981).  
 
Noug seed cake is high in feeding value and could be included as good quality protein 
concentrate for all classes of livestock.  Up to 30% noug seed cake has been successfully used in 
dairy cattle and poultry rations in Ethiopia. Noug seed cake is reported to contain 88.6% OM, 
30.8% CP, 32.4% NDF, 29.7% ADF, 11.7% ADL and 11.4% ash on DM basis (Abebe, 2008). 
The result of a study was conducted by Ulfina et al. (2003) to observe the response of aged 
Horro ewes to pre-market supplementary feeding showed an improvement in final weight and 
daily gain with increased level of noug seed cake based suplementary concentrate. Tadesse and 
Zelalem (2003) showed that cows supplemented with 208 g noug seed cake had higher DMI than 
those supplemented with 168 g noug seed cake indicating a positive response to increased 
supplementation. Similarly, 120 days sheep fattening trial resulted in higher final body weight 
and average daily weight gain as the level of concentrate feeding (50% noug seed cake and 50% 
  
maize mixture) increased from 0 g per head per day to 500 g per head per day (Solomon et al., 
1992). On the other hand, supplementation at 400 or 500 g per head /day showed no significant 
10 
 
difference in both parameters. In studies conducted using maize stover as a basal diet for sheep, 
supplementing noug seed cake increased the total DM intake, but with a significant decrease in 
maize stover intake, and the digestibility of DM, OM, N as well as most of the cell wall 
components in the total diet increased as percentage of noug seed cake increased in the diet 
(Butterworth and Mosi, 1986).  
 
2.1.3.2. Wheat bran  
 
Wheat bran is readily available and cheap agro-industrial by-product that could be used in animal 
feeding (Alemu et al., 1989). Wheat bran is one of the most popular and important 
supplementary concentrate livestock feeds. It is highly palatable and has a mild laxative effect. 
The bran is the outermost layer of the seed, which is high in fiber, but also contains some flour 
and is relatively higher in CP content than the seed (Cheeke, 1991).  Wheat bran good source of 
carbohydrates, protein, minerals and vitamins and considered as one of the feeds that can be used 
for fattening. The CP content of wheat bran varies from 60-220 g/kg DM, but normally ranges 
between 80 and 140 g/kg DM (McDonald et al., 2010). Gillespie (2002) indicated that wheat 
bran has 89% DM, 11.3%, CF and 15% ADF. According to Ensminger et al. (1990) wheat bran 
contains 11% CF, 70% total digestible nutrient (TDN), 3.1 kg Mcal DE and 17.5% CP.  
 
Wheat bran has a high capacity to absorb water and swell, has a bulk effect in colon and gives 
laxative property. Because of their bulky nature and high fiber content, bran and other mill by-
products are not usually fed to swine and poultry (Cheeke, 1991).  Getenet et al. (1999) reported 
that supplementation of 400 g/day peanut cake and wheat bran mixtures at a ratio of 75:25 had 
better response in live weight gain of lactating does and higher DMI and live weight gain in kids. 
Simeret (2005) reported  daily body weight gain of 39.9- 44.72 g/day for Somali goats fed on 
hay basal diet supplemented with graded levels of peanut cake and wheat bran mixture. 
Generally, the fiber content of wheat bran makes it a preferred supplement for ruminants rather 
than for mono-gastric animals (Cheeke, 1991).  
11 
 
2.1.4. Indigenous Fodders  
 
Shrubs and fodder trees play a significant role in livestock production in all agro-ecological 
zones of tropical Africa. Fodder tree foliages are commonly browsed directly on trees, or after 
lopping by livestock herders. They are also offered as cut-and-carry feed install-fed situations 
(Atta-Krah, 1990). The importance and availability of fodder trees in tropical Africa are 
influenced by a number of factors such as: the natural distribution of trees within the agro-
ecological zones, the distribution, types and importance of livestock, the integration and role of 
livestock within the farming system, and the availability of alternative sources of fodder in 
livestock feeding in the agro-ecological zone (Atta-Krah, 1990). Productivity of the fodder trees 
in terms of foliage production per unit area has been found to be linked with habitat and soil 
texture. Some fodder trees in humid and sub humid climate were reported to produce 2.3 to 4.69 
tons of forage DM/ hectare/year (Baumer, 1992). Fodder trees contain medium to high level of 
CP ranging from 120-250 g per kg, indicating that they are valuable source of protein in 
livestock feeding in the tropics (Solomon, 2001). Le Hoearou (1980) reported that fodder trees 
contain 26-95% DM and 10-30% CP. Perennial fodder trees retain high CP content for longer 
period than annual shrubs. However, the CP digestibility of certain fodder species was found to 
be low and several cases of livestock death have been associated with their high tannin content in 
foliage (Kumar, 1992). The role of fodder trees in ruminant nutrition has not been truly defined 
and is likely to be different depending on whether they are used as strategic supplement or basal 
feed source. 
 
Indigenous fodder trees and shrubs are important feeds of ruminant animals due to their 
appreciable nutrient content that are deficient in ordinary feed resources such as crop residues 
and natural pasture (Orwa et al., 2009; Aberra, 2011; Firisa et al., 2013; Awoke, 2015). Most 
browse plants are high in crude protein content, ranging between 10 and 25% on dry matter 
basis. Indigenous fodder trees could be considered as reliable feed resource to develop 
sustainable livestock feeding system due to their ability of remaining green for a longer period 
(Okoli et al., 2003 cited in Aynalem and Taye, 2008). The ability of most browse species to 
remain green for a longer period is attributed to deep root systems, which enable them to extract 
water and nutrients from deep soil profile which in turn contributes to the increased crude protein 
12 
 
content of the foliage (Le Houérou, 1980). There is a very critical need to evaluate the feed 
values of the indigenous browse plants and develop sustainable feeding standards in the tropics. 
A wide range of indigenous trees and shrubs are grown in Ethiopia. To mitigate the problem of 
ruminant animal feed availability and quality in the tropics, use of browse plants as an option has 
been sought (Enideg, 2008; Aberra, 2011). 
 
2.1.5. Improved Forages  
 
Introduction, popularization and utilization of improved multipurpose forage crops and trees 
such as Sesbania spp., Leucaena leucocephala, Calliandra spp. and Chamaecytisus palmensis 
through integration with food crops cultivation in the mixed crop-livestock system in Ethiopia 
started in the 1970s aimed at supplementing the widely available roughage feed resources 
(Alemayehu, 2006). Unsatisfactory and limited success rates have been reported from the 
attempts made in the establishment of improved forages (Abebe et al., 2008) with less than one-
percent contribution (CSA, 2015) which calls for further effort in extension and research 
activities in the area. Cultivated fodder crops such as oats, vetch, alfalfa, and fodder beet are not 
well developed under the present Ethiopian conditions (Getnet and Ledin, 2001; Alemayehu, 
2005). Shortage of land in the mixed crop-livestock production system, technical problems such 
as planting and managing the seedlings, insect damage and low interest of farmers were some of 
the reported reasons for poor adoption of improved forage production (Abebe et al., 2008). In the 
highland of Ethiopia, immediate response to population pressure is targeted towards an 
expansion of cultivated area to maintain per capita crop output (Ruthenberg, 1980). Thus, 
livestock and crop activities may become competitive for land resources (McIntire et al., 1992). 
Although the demand for feed may increase under these conditions, competition with food crops 
is unfavorable to forage adoption, particularly because farmers tend to be unwilling to sacrifice 
food production to produce fodder for animals (McIntire et al., 1992). 
 
Some potential contribution of indigenous multipurpose plants such as Vernonia amygdalina, 
Buddleja polystachya, Maesa lanceolata, Ensete  ventricosum, and Bambusa spp. as a livestock 
feed resource in the smallholder traditional farming systems has been reported in different parts 
of the country (Aynalem and Taye, 2008; Beyene et al., 2010). Abebe et al. (2008) noted that 
13 
 
farmers showed more interest for multipurpose indigenous fodder trees than exotic ones. This 
indicates that the potential of improved forage adoption is limited under subsistence oriented 
livestock production as the economic incentives are low. In contrast, the potential for adoption of 
improved forages could be higher under market oriented livestock production system, such as 
dairying with crossbreds or improved breeds, and fattening of large and small ruminants 
(Gebremedihin et al., 2003). 
 
2.1.6. Non-Conventional Feed Resources  
 
Non-conventional feed resources refer to feeds that have not been traditionally used for feeding 
livestock and are not commercially used in the production of livestock feeds. Feedstuffs such as 
fish offal, duckweed and kitchen leftovers (i.e., potato peel, carrot peel, onion peel, and cabbage 
leftover), poultry litter, algae, local brewery and distillery by-products, sisal waste, cactus, coffee 
parchment and coffee pulp are commonly used in Ethiopia, and could be invaluable feed 
resources for small and medium size holders of livestock (Negesse et al., 2009). A common 
feature about feeds is that the traditional feeds of tropical origin tend to be mainly from annual 
crops and feeds of animal and industrial origin. Due to their low cost and availability of non-
conventional feed resources such as by-products from local brewery and distillery are widely 
used by smallholder farmers (Nurfeta, 2010; Mekasha et al., 2003). According to Negesse et al. 
(2009), non-conventional feeds could partly fill the gap in the feed supply, decrease competition 
for food between humans and animals, reduce feed cost, and contribute to self-sufficiency in 
nutrients from locally available feed sources. It is therefore imperative to examine for cheaper 
non-conventional feed resources that can improve intake and digestibility of low quality forages.  
 
2.2. Effect of Season on Availability and Quality of Feeds 
 
Seasonal fluctuation in the availability and quality of feed has been a common phenomenon 
influencing livestock production in Ethiopia. Years of good rain enable production of surplus 
forage while contrasting years of poor rain result in forage production much below what is 
required to sustain normal development and production in livestock (Alemayehu, 1998). The 
seasonal pattern of feed supply interacts with seasonal pattern of feed requirement, such as those 
14 
 
caused by pregnancy, or lactation and to lesser extent, by difference in metabolic requirements 
due to changing climatic condition. This is true because of the fact that controlled breeding with 
seasonal variation of feed supply and demand is not synchronized.  
 
 In spite of the rising dependence on fibrous crop residues as animal feeds, there are still certain 
constraints to the efficient utilization of this feed resource. Substantial efforts have been made so 
far to resolve the feed shortage problem in the Ethiopian highlands, aimed at improving feed 
availability and thereby improve livestock productivity. However, the impact was so little to 
cope with the problem that animals are still subjected to the long periods of nutritional stress 
(LDMPS, 2006). Grazing on either private or communal grasslands was a common practice 
following the onset of rain starting from late April to early November (Solomon et al., 2008). In 
general, giving due consideration for the quality and quantity of seasonal availability of feed 
resources is of paramount importance for the development of appropriate livestock feeding 
strategies and interventions. 
 
2.3. Effect of Environmental Factors on Plant Growth and Chemical Composition   
 
Some of the factors that affects the yield and chemical composition of plants include stage of 
maturity, soil type, weed infestation, and diseases and pests (Ranjhan, 1980). Thus, employing 
simple and inexpensive management practices like appropriate planting space, regular weeding, 
appropriate cutting height and harvesting days will have a significant contribution towards 
increasing the level of productivity and chemical composition (MRDP, 1990). The soil and its 
chemical, physical and biological composition exert notable influence on the distribution of plant 
species. Fodder grown on soil deficient in macro or micro elements will also be deficient in the 
same nutrients (Ranjhan, 1980). Rainfall promotes rapid vegetative growth during the warm 
months in tropical and sub tropical areas. With the increase in supply of water to the plants, the 
absorption of mineral matter, particularly that of calcium increases (Ranjhan, 1980). The plant 
growth and development is affected markedly by temperature and soil moisture conditions 
(Daniel, 1996). An increase in ambient temperature favors the conversion of photosynthetic 
products in to structural components, which has been related to increased proportion of the 
stems. Leaf quality of forage plants decline as result of lignifications (Ranjhan, 1980). 
15 
 
Temperature leads to a five percentage unit difference in dry matter digestibility of tropical grass 
across various altitudes where it is grown (Minson, 1980). The optimum temperature for the 
assimilation of CO2 in many plants is around 20-30 °C (Innelli, 1984). Weeds found in any types 
of pasture compete for space, moisture and nutrients, and result in reduction of forage quality 
and yield. 
 
2.4. Desho Grass (Pennisetum pedicellatum)  
 
Desho grass is a many-branched leafy grass growing up to 1 m high or more (FAO, 2010; Leta et 
al., 2013). The culms are erect and branching, and the leaves are 15-25 cm long and 4-10 mm 
wide, flat and glabrous. The spikelets are 4 mm long, usually solitary (Ecocrop, 2010; FAO, 
2010). Desho grass is used as fodder and considered to be a very palatable species to cattle 
(FAO, 2010). The grass provides high green herbage yield ranging between 30 and 109 t/ha 
(Ecocrop, 2010) and compares favorably with Sorghum bicolor. Desho grass responds well to 
fertilizer application and could be combined with fodder legumes either in mixtures or in 
rotational cropping. In short rotation with maize or groundnuts, the grass yields better than 
traditional forage grasses, especially when fertilized, while the roots and stubbles also increase 
soil fertility (Leta et al., 2013). From animal feed resource point of view, desho grass is used in 
temporary pastures or in cut-and carry systems since it provides ample quantities of good quality 
green forage and stands several cuts a year. The grass is also useful for hay and silage 
preparation (Ecocrop, 2010). 
 
2.4.1. Geographical Distribution of Desho Grass (Pennisetum pedicellatum)  
 
Desho grass is native to tropical Africa and grows widespread within 20°N and 20°S. The grass  
is mainly found on disturbed land, road edges and on recent fallow lands, where annual rainfall 
range between 600 mm and 1500 mm with a rainy season of 4-6 months and average daily -
temperatures of about 30- 35°C. Desho grass thrives on a wide range of soils (including 
degraded sandy or ferruginous soils) provided they are well drained. However, the grass is 
susceptible to water logging and frost but has some drought tolerance (Ecocrop, 2010; FAO, 
2010). Desho grass is used as a soil stabilizer in India (Ecocrop, 2010).  
 
16 
 
2.4.2. Nutritive Value of Desho Grass 
 
Desho grass has a crude protein content of 9.6% on DM basis at early stage and 1.6% at straw 
stage, respectively. The digestibility and voluntary intake decrease with increase in stage of 
maturity which indicates that the grass should be fed at early stage of maturity. Mature desho 
grass must be well supplemented with protein sources in order to sustain growth and/or milk 
production. Urea treatment may be a valuable option to improve its nutritive value (nitrogen 
content and digestibility) with the addition of adequate energy supplementation. The grass is 
widely used as green fodder for cattle in different parts of the world (Sinsin, 1993; Cisse et al., 
2002; Holou, 2002). The nutritive value of late stage desho grass hay is low to support 
maintenance nutrient requirement of adult rams of 17-25 kg, even if supplementation with 
nitrogen and energy improves performances. Desho (Pennisetum pedicellatum) grass is widely 
used as green fodder for cattle (Sinsin, 1993; Cisse et al., 2002; Holou, 2002); however, the grass 
was found to be inferior to sorghum fodder primarily because of lower voluntary intake 
(Awadhesh et al., 2000). The supplementation of late-harvested forage with cottonseed meal 
increased intake and digestibility, attributed to greater stimulation of rumen flora as a result of 
increased availability of energy and nitrogen-providing nutrients (Nianogo et al., 1997). 
 
2.4.3. Desho Grass in Ethiopia 
 
Desho grass is one of the indigenous potential forage species which needed comprehensive 
research in Ethiopia. Desho grass (Pennisetum pedicellatum) is native to tropical countries 
including Ethiopia (Ecocrop, 2010; Leta et al., 2013; EPPO, 2014). In Ethiopia desho grass is 
known as a perennial plant originated in Southern Nations, Nationalities Peoples Regional State 
in a place called Chencha in 1991 (Welle et al., 2006). Currently it is utilized as a means of soil 
conservation practices and animal feed in the highlands of Ethiopia (Ecocrop, 2010; Yakob et 
al., 2015). The grass is popular, drought resistant plant, used as feed for ruminants (FAO. 2010; 
EPPO, 2014). It has the potential of meeting the challenges of feed scarcity since it provides 
more forage per unit area and ensures regular forage supply due to its multi-cut nature (Ecocrop, 
2010). Desho grass is suitable for intensive management and performs well at an altitude ranging 
17 
 
from 1500 to 2800 m.a.s.l (Leta et al., 2013). Desho grass performs best at an altitude greater 
than 1700 m above sea level (Welle et al., 2006).  
 
2.4.4. Growing Conditions of Desho Grass 
 
The provision of all the technical specifications for cultivation of desho grass is essential to 
improve grazing land management practices. Cuts of the grass are ideally planted in rows, spaced 
at 10 cm by 10 cm, using a hand hoe (Smith, 2010) in Ethiopia by WOCAT project in SNPPRS. 
This spacing gives each plant sufficient soil nutrients and access to sunlight to achieve optimal 
growth, while ensuring that the soil is completely covered by the grass once established. It is 
recommended to plant other leguminous species alongside desho grass to promote biodiversity. 
Multipurpose shrubs/trees (Leucaena sp and Sesbania sp.) can be planted approximately 5 m 
apart with no particular layout. Other legumes (alfalfa and clover) can be mixed with desho grass 
by broadcast throughout the plot (Danano, 2007). 
 
Once planted, desho grass maintenance activities such as applying fertilizer, weeding and gap 
filling, are required to ensure proper establishment and persistency of desho grass (Solomon et 
al., 2010). Fertilizer should be applied throughout the plot one month after planting. It is 
recommended to use organic compost in the form of animal manure, leaf litter, wood ash, food 
scraps, and/or any other materials rich in biodegradable matters (Danano, 2007). Weeding and 
gap filling are continuous activities in desho grass production (Leta et al., 2013). After 2 to 3 
years, maintenance inputs decrease substantially or cease altogether as the grass cover closes up 
and the plot becomes a sustainable fodder source. Past interventions have shown that desho 
based grazing land management practices are best implemented when communal grazing land is 
re-distributed into small plots (less than 0.5 ha) that are convenient for individual use, 
development and management (Danano, 2007). 
 
2.5. Effect of Harvesting Dates on Yield and Quality of Forages 
 
As there is no work on the relation of harvesting days on quality and yield on morphological 
fraction and nutritive value of desho grass, citation has focused on other grasses. Terry et al. 
18 
 
(2010) reported the chemical composition of three different harvesting dates (60, 90,120 days 
after planting). The DM, OM, NDF, ADF, ADL and hemicelluloses content of plants increased 
with increase in harvesting dates from 60 to 120 days after planting, whilst the crude protein 
showed a decreasing trend. The results of the  research conducted to study  the effect of different 
harvesting dates on the chemical composition and herbage yield of Napier grass (Pennisetum 
purpureum), Taye et al. (2007) reported  similar trend  to that of Terry et al. (2010), when Napier 
grass was harvested at 60, 90 and 120 days after planting.  The CP decreased with an increase in 
harvest days. Similar result has been reported by different researchers (Taye et al., 2007; Peiretti, 
2009). It was observed that the CP levels decreased by 27% when harvesting date increased from 
60 to 120 days. Even though the 60 day harvest yielded the highest cellulose and CP, it recorded 
the lowest herbage yield, plant height and tiller numbers. The increase in herbage yield with an 
increase in harvesting days after planting could be attributed to the increase in tiller number, leaf 
formation, leaf elongation as well as stem development (Ansah et al., 2010). 
 
2.6. Washera Sheep Breed and its Characteristics 
 
The Washera sheep breed has a population of about 1.22 million (CSA, 2006) and are one of the 
most productive Ethiopian sheep breeds (Chipman, 2003) in terms of growth and overall 
performance. The breed inhabits the northwestern highlands of Ethiopia (Sisay, 2002) mainly the 
wet, warmer and mid-highlands (1600-2000 m.a.s.l.) of the Amhara and Benishangul-Gumz 
Regional States (Dangur and Mandura districts) (Solomon et.al. 2007). The Washera sheep is 
characterized by large body size, wide fat tails curved upward tip, horizontally carried or semi-
pendulous long ears and both sexes are hornless with slightly concave facial profile (Sisay, 
2002). They have long and thin legs, long neck, and prominently protruding brisket and bigger 
body size as compared to the other indigenous sheep types found in the Amhara National 
Regional State. Washera sheep are comparable in size with the Horro, Bonga, and Adilo sheep 
types found in other parts of Ethiopia (Sisay, 2002). They have a coat cover of short and smooth 
hair. Three patterns of coat color are observed, namely plain; patchy; and spotted with reddish 
brown; white patches or spots on the forehead and lower parts of the legs. Plain reddish brown 
and plain white are dominant color types (Sisay, 2002). Feedlot and on-farm performance of 
Washera sheep were quite high, with average daily weight gains of up to 126 g, with 500 g per 
19 
 
day concentrate supplementation. Washera sheep average hot carcass weights recorded from 
different experiments ranged between 6 and 16 kg (Tesfaye et al., 2011; Abebe et al., 2011; 
Wude et al., 2012; Gebru et al., 2015). 
 
2.7. Nutrient Requirement and Growth Performance of Sheep 
 
Ruminant animals in developing countries are reared on poor quality roughages, particularly 
cereal straws (Van Soest, 1994). Among ruminant animals, sheep and goats utilize pasture and 
rangelands effectively and are capable of turning agro-industrial by-products into milk, meat and 
fiber (Pond et al., 1995). Nutrients of importance to sheep are the same as that of other ruminant 
animal species and comprises of energy, protein, minerals, vitamins and water. Most of sheep 
nutrition programs are based on some type of forage as the primary feedstuff. This can be pasture 
or range forages, or harvested forages such as hay or silage (Mike, 2007). Pastures and ranges 
are the natural habitats of sheep, since they thrive under an extremely wide variety of climatic 
conditions with the utilization of the most adverse types of vegetations. A high proportion of the 
diet of sheep is normally made up of forage (Cheeke, 1991). Even though there may be wide 
variation in plants, sheep are able to find the necessary nutrients from grasses, legumes, weeds, 
shrubs and herbs (Rangjhan, 1997).  
 
The nutrient requirement of sheep varies with differences in age, body weight and stage of 
production. In South Africa, daily dry mater intake (DMI) of Blackhead Persian and Dorper 
breeds has been reported to range between 0.93 and 1.27 kg per 100 kg live weight. Sheep 
adapted to arid areas have comparatively lower nutrient requirements which could largely 
account for their survival under harsh environmental condition of arid lands (Payne and Wilson, 
1999). Sheep consume relatively higher proportion of forages than any other classes of livestock. 
They are naturally adapted to grazing on pasture and ranges and thrive best on forage that is 
short and fine (Ensminger, 2002). During the grazing season, sheep are able to meet their 
nutrient requirements from pastures. The major sources of feed for sheep are crop residue 
including cereal straws and stovers during the dry period. A significant difference in growth rates 
of sheep supplemented with different types of oil seed cakes has been reported from different 
parts of Ethiopia. Growth rate of 26, 78 and 54 g/h/d was reported from sheep supplemented with 
20 
 
groundnut cake, sunflower cake and sesame cake, respectively (Solomon, 1992). It is also 
reported that sheep supplemented with cotton seed cake gained more weight than sheep fed rice 
straw without supplementation (Ngwa and Tawah, 2002). For high rates of growth, the demand 
for essential amino acids is higher than can be provided by optimized rumen fermentation and 
therefore supplements of by-pass protein sources should be given to maximize intake and 
production.  
 
2.7.1. Dry matter intake 
 
The voluntary feed intake of sheep depends on the type of diet offered and the physiological age 
of the sheep. The main dietary factor, determining feed intake appears to be the energy density 
(Wilson and Pond, 1999). Diets high in fat are consumed in lower amounts so, in such cases, 
other nutrients such as protein must be increased to ensure adequate nutrition. The results of a 
number of feeding trials conducted in India and other Asian countries have shown a DM intake 
0.75 0.75
ranging between 44 g DM/kg W  for barely straw and 75 g DM/kg W  for alfalfa 
(Ranjhan,1997). Under intensive rearing conditions, nutrient requirement of (finishing rations) 
20-30 kg body weight sheep, comprises of 0.65-0.85 kg DM, 52-65 g DCP and 1.4-2.00 ME 
MCal (Ranjhan,1993). The daily DMI of growing lambs with mean live weight of 15-35 kg was 
0.75
estimated at 73.1 g/ W  (Ranjhan, 1997). The recommended total DM intake of roughage as 
percent of body weight for 30 kg sheep is 2.6 % at 780 g DM intake/day (NRC, 1981).  
 
The higher the quality of the feed offered, the higher would be the feed intake. Palatability is of 
great importance in feeding animals for better performance. Unless the feed is palatable, animals 
will not eat enough feed to permit them to produce meat economically (McDonald et al., 2010). 
Most of the Ethiopian dry forages and roughages have low CP content, indicating that the rumen 
microbial nutrient requirement can hardly be met unless supplemented with protein rich feeds 
(Seyoum and Zinash, 1989). For satisfactory digestion of poor quality roughage, adequate 
supplementation is needed. The addition of a small amount of high quality concentrate will 
generally increase rumen fermentation and thereby increase the intake greatly. Intake depends 
upon the structural volume and cell wall content, whereas digestibility depends up on both cell 
21 
 
wall and its ability to resist digestion as determined by lignifications and other factors (Van 
Soest, 1982).  
 
The effect of increased digestibility on improving feed intake depends on the quality of roughage 
feed used. If the roughage feed has low digestibility, total intake will be increased more than if 
its digestibility is high. This means concentrate added to roughage of low digestibility tends to be 
consumed in addition to the roughage, but when added to roughage of high digestibility, it tends 
to replace the roughage (McDonald et al., 2010). Generally, when the herbage has less CP 
content, nitrogen supplementation increases both intake and digestibility, particularly when the 
CP content of the herbage feed is less than 6% (Lambourne et al., 1986). Digestibility is low 
when a ration has too little CP in proportion to the amounts of soluble carbohydrates.   
 
The feed intake of animals is commonly considered to be proportional to their metabolic body 
0.75
weight (W ). Bonsi et al. (1996) reported that the DM intake of the Ethiopian sheep fed basal 
0.75
diet of teff straw was about 58.6-82.2 g DM/kg W . Data collected from different feeding trials 
in different parts of Ethiopia have shown that the DM intake of some Ethiopian sheep types 
ranged between 368 and 784 g/day (Bimrew et al., 2010; Abebe et al., 2011; Awoke, 2015). 
Similarly, Solomon (2001) reported DM intake of sheep placed on teff straw ranged between 
387.3 and 452.5 g/day. Mean DM intake ranging between 568.6 and 637.2 g/day was reported 
from Menz sheep supplemented with dried forages of selected multipurpose trees. Ewnetu 
(1999) also indicated that the daily DM intake of Menz and Horro lambs ranged between 75.5 
and 78.3 g per unit of metabolic body weight, respectively.   
 
Supplementary concentrates markedly affect concentrate intake per live metabolic body weight; 
and total DM intake per metabolic body weight (Tadesse et al., 2003). Tesfay and Solomon 
(2009) reported that increasing levels of concentrate supplement (150, 250, and 350 g) resulted 
in higher daily total DM intake. Similarly, Awot and Solomon (2009) showed that the DM intake 
of Afar sheep fed a basal diet of urea treated teff straw was higher for wheat bran supplemented 
groups as compared to the non-supplemented ones. A result obtained at ILCA (1986) showed 
that supplementing of 100 g noug seed cake/day/head of a diet of teff straw treated with 2.5% 
urea and fed ad libitum resulted in reduced straw consumption and increased total feed intake 
22 
 
and body weight gain, indicating that there is significance increase in CP and energy intake with 
increased concentrate level. 
 
2.7.2. Energy requirements 
 
Energy is the most limiting nutrients in sheep and goat feeding (Wilson and Pond, 1999). Both 
sheep and goats obtain energy from pasture, hay, silage, cereal grains, and cereal grain by-
products. Mike (2007) remarked that energy needs of sheep are influenced by their body size 
(weight), the stage of production, the degree of activity, fleece length and environmental factors 
(temperature, wind chill, etc.). Bigger sheep need a larger intake of energy than small or average 
sized sheep. Sheep in dry lot or in small pastures need less energy than sheep grazing over large 
range or pasture areas. In winter, sheep with short fleece need more energy than those with a full 
fleece. Moreover, the energy status of sheep is dependent on their feed intake, energy content 
and digestibility of the feeds (Mike, 2007). The daily energy requirements for a 20 kg live weight 
lambs gaining 0, 50,100, and 150 g/day are summarized in Table 2. 
 
Table 2. Daily energy requirements of sheep 
Animal Category Live weight gain (g/day) DMI (kg/day) 
0 50 100 150  
Female (MJ/day) 3.4 4.5 5.8 6.5 0.46 
Castrated (MJ/day) 3.4 4.5 5.7 6.2 0.46 
Male (MJ/day) 3.9 4.8 5.8 6.4 0.46 
MJ=Mega joule; DMI=Dry matter intake 
Source: McDonald et al. (2010) 
 
Sheep with small body size, may not effectively utilize the energy contained in bulky feeds, 
showing that, energy concentration and digestibility is the most important in sheep nutrition. 
Thus, lambs are often fed high grain diets during finishing aimed at early marketing. Meeting the 
high-energy demands of rapid growth, rapid fetal development or lactation may also require 
supplementation with grain (Pond et al., 1995).  
 
23 
 
2.7.3. Protein requirements  
 
Sheep need protein, as do other classes of animals for maintenance, growth, reproduction, 
finishing and production of wool. Green pastures and legume hay (alfalfa, clover, soybeans, and 
others) are widely available and excellent sources of protein for sheep feeding in most areas. 
Protein is a critical nutrient, particularly for young and rapidly growing and for mature lactating 
animals. Consequently, optimal use of protein is important in practical animal feeding systems, 
since, protein supplements are much more expensive than energy supplements. The provision of 
by-pass proteins to ruminant animals fed low quality roughages increases feed intake. Part of the 
response in growing animals might be attributed to the fact that by-pass protein provides amino 
acid in which microbial protein is deficient. Thus, by-pass protein increase growth rate, which in 
turn increase feed intake in addition to improving absorbed nutrient balance (Cheeke, 1999). In 
ruminant animals including sheep, the amount of protein consumed is more important than the 
quality of the protein (Mike, 2007). In sheep, the rumen microbes use any form of nitrogen to 
synthesize good quality useable protein. The most common time of protein supplementation 
would be during periods of high production and rapid growth, when pasture plants are border-
line in protein content.   
  
Oil seed cakes contain 40-50% CP and are excellent sources of supplemental protein. McDonald 
et al. (2010) stated that protein requirements of ruminant animals are stated in terms of effective 
rumen degradable protein and metabolizable protein. Ranjhan (1993) indicated that a 25 kg 
sheep requires 806-891 g DM and 94-137 g CP for average daily body weight gain of 64-
101g/h/d. Similarly a 20 kg growing sheep require 85 g of CP and 46.8 g of DCP. McDonald et 
al. (2002) showed that the daily metabolizable protein requirements of growing lambs with a live 
weight gain of 0, 50, 100 and 150 g /day is 21, 47, 61, and 76 g per day respectively with a daily 
DM uptake of 0.837 kg/day.  
 
According to Pond et al. (1995), the consumption of low quality roughages such as straw and 
poor quality grass hay can be increased markedly with the addition of protein supplements. The 
CP requirements for growing and fattening sheep with 20 kg body weight are 85 and 127 
g/head/day, respectively (Ranjhan, 1997), whereas according to Cheeke (1999), early-weaned 
lambs with 10 and 20 kg live weight have CP requirements of 127 g/head/day and 167 
24 
 
g/head/day with 26.2 and 16.9 % of DM diet, respectively (Ensiminger, 2002). The growth 
performance of sheep under grazing conditions could be improved with supplementary feeding 
of high protein diet. Sheep fed high protein diet (208 g per kg DM/day) had improved DM intake 
(509 vs. 425.9 g/head/day) and live weight gain (36.6 vs. 10.7 g/head/day) as compared to those 
on low protein diet (168 g per kg DM/day) (Kabir et al., 2004). 
 
Common weeds, browse and aftermath rank as the second most important feed resources for 
tropical sheep and provide the major feed resource for smallholder flocks during much of the dry 
season (Devendra and Mcleroy, 1982). Feed resources of agro-industrial origin include those 
providing easily fermentable energy, protein supplements and by-products of cereal milling 
which are source of both energy and protein. Agro-industrial by-products that are once thought 
of as wastes are now considered valuable livestock feeds (Ensminger et al., 1990). Almost every 
type of plant that is produced or processed for human food yields one or more by-products that 
can be utilized as animal feed. These feeds mainly include oil seed cakes and cereal grain by-
products (Ensminger et al., 1990). 
 
Crop residues are potentially rich sources of energy as about 80% of their DM consists of 
polysaccharides, but underutilized because of their low digestibility, which limits feed intake 
(FAO, 2002). These constraints are related to their specific cell wall structure, chemical 
composition and deficiencies of nutrients such as N, S, P and Co, which are essential to rumen 
microorganisms. Residues from the processing of the various agricultural by-products represent 
an important element ameliorating inadequate feed supplies as stated by Devendra and Mcleroy 
(1982). Concentrate feed sources especially cereal grains are expensive for animal feeding 
(Getnet et al., 1999). Thus, other alternatives and relatively cheaper sources, such as agro 
industrial byproducts should be looked into. According to Getnet et al. (1999), nowadays, the 
number of oil extracting and flour milling industries are expanding in different parts of Ethiopia. 
These by-products provide a potential source of supplements for livestock. 
25 
 
3. MATERIALS AND METHODS 
 
3.1. Description of Study Areas 
 
The survey work on the production and utilization of desho grass was conducted in Burie Zuria 
district of West Gojam zone, Amhara National Regional State and Doyogena district of Kembata 
Tembaro zone of Southern Nations, Nationalities and Peoples Regional State. The agronomic 
characteristics of the grass were studied at Andassa Livestock Research Center, located in West 
Gojam and in Farta district of South Gondar Zone of the Amhara Regional State. The laboratory 
chemical analysis was conducted at International Livestock Research Institute, Animal Nutrition 
Laboratory (Addis Ababa). The animal evaluation of desho grass was done at sheep research 
farm of Zenzelma Campus, Bahir Dar University. 
 
3.1.1. Burie Zuria District 
 
Burie Zuria district is located in West Gojam Zone, Amhara National Regional State, located 
between 10˚15′N and 10˚42′29″N latitude and between 36˚52′1″E and 37˚7′9″E longitude. 
According to Burie Zuria district office of Agriculture (BZDoA, 2014), the total area  of the 
district is 58, 795 ha out of which 52.18%, 6%, 26.88%,10.48% and 10.7% is crop land , grazing 
area, forest and bush land, wasteland and construction sites and water body, respectively. The 
topography of the district is characterized by 76% plain, 10% mountainous, 7% up and down, 
and 7% valleys. Burie Zuria district has three soil types red (63%), blue (20%) and black (17%). 
The major portion of the district is Woinadega/mid altitude (77.23%) followed by Kola (21.77%) 
o
and Dega/high altitude (1%) with daily temperature range of 17-25 degree C. The annual mean 
rainfall of the district is 1000 to 1500 mm. The major crops grown in the district are maize, 
finger millet, teff, wheat, barley, potato, pepper, onion, field pea and faba bean. The total area 
under desho grass in the district was reported to be 47.5ha (BZDoA, 2014). 
 
Burie Zuria district is characterized by both mid and high altitude areas and has an altitude range 
of 700 to 2300 m.a.s.l. The district is appropriate for different crops and livestock production. 
The types of livestock reared in Burie Zuria district includes cattle, sheep, goat, equine, chicken 
and bee colonies (IPMS, 2014). Livestock is considered as an important component in the 
26 
 
farming system of the district. Hence, farmers in the study area hold livestock species such as 
cattle, equines (horses, asses and mules), small ruminants, poultry and bee colonies, which serve 
the household as source of draft power, meat, milk, honey and beeswax, family income, manure 
and means of transportation. 
 
3.1.2. Andassa Livestock Research Center 
 
Andassa Livestock Research Center (ALRC) is located an altitude of 1730 m.a.s.l, lies between 
° ° 
11 29' N latitude and 37 29' E longitude. The area receives about 1434 mm of rainfall annually. 
o o
The mean annual temperature vary from a maximum of 29.5 C in March to a minimum of 8.8 C 
in January. The soil of the center is dominantly dark clay soil (ALRC, 2014). 
 
3.1.3. Bahir Dar University Zenzelma campus  
 
The animal evaluation feeding trial was conducted at Bahir Dar University, Zenzelma Campus 
situated in Bihar Dar city administration. It is located at 570 km from Addis Ababa and 7 km 
0 0
from Bahir Dar and lies 11 37’N and 37 28’E, at and an altitude of 1912 m.a.s.l. The annual 
0
average temperature is 29 C and annual rain fall ranges from 1428-1521mm (CAES, 2015).  
 
3.1.4. Farta District 
 
The highland of Farta district called "Melo”, is located near Debre Tabor Town, South Gondar 
Adminsrative Zone, Amhara Regional State. The area is located at an altitude of 2650 meters 
above sea level. Farta district lies between 11°32′ and 12°03′N latitude and 37°31′ and 38°43′E 
longitude.  The major soils of the district comprises of 20% black, 30% red, and 50% brown. The 
mean annual rainfall is 1570 mm and the mean minimum and maximum annual temperature is 
o
9.6 and 21.5 , respectively (FDoA, 2014). 
  
27 
 
C 
B 
A 
 
D 
 
 
Figure 1. Map showing Study districts:  Burie Zuria (A), Bahir Dar Zuria (Andassa Livestock Research 
Center and Bahir Dar University) (B), Farta (C) and Doyogena (D). 
 
3.1.5. Doyogena District 
 
Doyogena district is found in Kembata-Tembaro Zone, Southern Nations Nationalities and 
Peoples’ Regional State and located between 7 018'25"N-7 021'49"N latitude and 37045'33"E- 
37048'51" E longitude.located at 258 km South-West of Addis Ababa. The district comprised of 
a total land area of 17,263.59 hectares. About 86% of the total land area is used for crop 
cultivation, 11.8% forest and bushes, 2% grazing land, and 0.2% degraded land. It has an altitude 
ranging between 1900 and 2748 meter above sea level (m.a.s.l). The district has two major agro-
ecologies, Dega/highland (70%) and Woinadega /mid land (30%). Some 10% of the area is plain 
land while the remaining 90% is mountainous /hilly. It has a minimum and maximum 
o o
temperature of 10 c and 16 c, respectively and receives average annual rainfall of 1400 mm 
(DDoA, 2014).  
 
The major crops cultivated in the highlands of the Doyogena district are ensete (Ensete 
ventricosum), cabbage, potato, barley, wheat, faba bean and field pea. In the low altitude of the 
28 
 
district, farmers cultivate sugar cane and maize. The soil type is mostly black clay loam, rich in 
organic matter (InterAide, 2014).The total land area under desho grass was estimated to be 
2,789.5 ha. The district has a livestock population of 46,703 cattle, 13,822 sheep, 1,444 goats, 
6,343 equines and 27,253 poultry (DDoA, 2014). 
 
3.2.Survey on Desho Grass Production and Utilization 
 
The study districts were purposely selected for the field surveys based on their total land 
allocated to desho grass production and utilization. Four Kebeles were purposely selected from 
each of the two districts based on their respective land area planted to desho grass. A total of 240 
desho grass producers (30 from each Kebele) were used to conduct the assessment on the 
production and utilization of desho grass using the formula: 
 
𝑁
n=   (Yamane, 1967) 
1+𝑁(𝑒2)
 
Where n is sample size computed, N is the total households in the study area and e is the level of 
precision. 
 
 
The assessment was conducted using semi-structured questionnaire administered by experienced 
and trained enumerators. The questionnaire was prepared and pretested before the actual data 
collection started. The data collected with the use of the questionnaire were complemented with 
information obtained from key informants that included (among the others) elderly people and 
community leaders of the Kebeles as well as animal science and natural resource experts. 
Secondary data were obtained from the district agricultural offices. Livestock holding per 
household was converted to tropical livestock unit using   the conversion factors (ILCA, 1990). 
The data collected include the socio-economic factors, desho grass production and utilization and 
purpose and role of desho grass. The dependent variables tested were the extent of use of desho 
grass as a feed, multipurpose aspect of desho grass and livestock preference in feeding the grass. 
 
 
 
  
29 
 
3.3.Study on Agronomic and Laboratory Characteristics 
 
The agronomic characteristics of the grass were studied at Andassa Livestock Research Center, 
2
and in Farta district of South Gondar Zone. A total area of 88 m  was selected from each of the 
mid land and high land locations. These were ploughed in May and harrowed in June 2014. The 
experiment was laid out in randomized complete block design having three replications and a net 
plot of size 3 m x 3.25 m in both mid and highland locations. Desho grass obtained from 
Southern Nations and Nationalities Regional State by CASCAPE - project was planted using 
vegetative root splits in rows. Soil samples were taken from each plot before planting and 
analyzed for major elements such as N, P, C, OM, pH, and texture. The spacing between rows 
and plants were 50 and 10 cm, respectively. Land preparation, planting, weeding and harvesting 
was made according to the recommendations (Leta et al., 2013). DAP and urea were applied at 
planting and after establishment at the rate of 100 and 25 kg per ha.  
 
The morphological parameters such as plant height and leaf length were measured with 
measuring tape and the number of tillers and leaves were computed as mean of counts taken 
from ten plants that was randomly selected from the middle rows of each plot at 90, 120 and 150 
days after planting in both locations. The leaf to stem ratio was determined by cutting plants 
from randomly selected two consecutive rows, separating in to leaves and stems, drying and 
weighing each component. Harvesting was done by hand using a sickle, leaving a stubble height 
of 8 cm above the ground. Following the first harvesting date, follow-up study was done to 
determine the re-growth potential and subsequent harvesting. A fresh herbage yield of the grass 
was measured immediately after each harvest and weighed on the field soon after mowing using 
a field balance. Sub-samples were taken from each plot at each site to determine fresh yield. The 
crude protein yield (CPY, t/ha) was determined by multiplying DMY by CP content. Finally 
O
adequate quantities of the sub-samples were dried in oven at 65 C for 72 hours and stored in 
airtight bags to be used for chemical analysis.  
30 
 
3.4. Animal Evaluation Experiment  
 
3.4.1. Experimental Feed Preparation 
 
The treatment set up of the animal evaluation experiment is shown in Table 3. The basal diets 
(desho grass and natural pasture hay) were prepared in advance, before the commencement of 
the feeding trial. Desho grass grown at Bahir Dar University College of Agriculture and 
Environmental Sciences animal farm was harvested at four months of age (Leta et al., 2013), 
prepared into hay, transported to the experimental site and stored in dry places well protected 
against rain and rodents. Natural pasture hay was purchased from the surrounding farmers, 
transported to the experimental site and properly stored. Both desho grass and natural pasture 
hay were chopped (at the size of 1-10cm) to improve intake by the experimental animals. Wheat 
bran and noug seed cake were purchased from Bahir Dar flour and oil factories and stored in 
cool and dry place until included in the experimental ration.  
 
Table 3. Experimental rations used in the feeding trial 
 
 
Treatments Basal diet Supplement (g DM/Day  CM) 
 
1 100% NPH                    ad libitum 300g 
 
2 75%NPH+25% DGH     ad libitum 300g 
 
3 50%NPH+50%DGH     ad libitum 300g 
 
 4 25% NPH+75%DGH    ad libitum 300g 
 5 100%DGH                   ad libitum 300g 
 
Key: NPH=natural pasture hay; DGH=Desho grass hay; DM=dry matter; CM=concentrate mixture 
(NSC 50%:50% WB). 
 
3.4.2. Management of the Experimental Animals 
 
Twenty five yearling rams of Washera breed of sheep were purchased from local markets based 
on dentition and information provided by the owners. Soon after arrival at the experimental 
31 
 
station, the animals were vaccinated against ovine pasteurellosis, sheep pox, blackleg and 
anthrax with 1ml ovine pasteurellosis vaccine, 1ml sheep pox vaccine and 1/2 ml anthrax 
vaccine per sheep, respectively. The sheep were also de-wormed against internal parasites (flat 
worms and round worms) and sprayed against external parasites (tick and mange). The 
experimental sheep were quarantined for 21 days in a separate house and placed on the 
experimental site for 15 days of preliminary period to get accustom to the new environment. The 
animals were closely observed for incidence of any ill health and disorders during the 
preliminary period.  
 
At the end of the preliminary period, the sheep were individually weighted and divided into 5 
groups each with initial group weight of 19.4+1.89 kg (mean+ SD)/sheep. The five treatment 
rations were randomly assigned to the experimental animals in randomized complete block 
design with five replications for a feeding period of 90 days. The experimental animals were 
housed in disinfected and well ventilated individual pens. Each pen was provided with adequate 
floor space and equipped with feeding and watering troughs. The experimental sheep were 
identified with neck collars. Noug seed cake and wheat bran were mixed in 50:50 ratio and 
offered at 300 g of DM/head at 0800 and 1600 hours in two equal portions daily. Basal diet and 
supplemental feeds were offered separately. All sheep had free access to clean water and salt 
throughout the experimental period.  
 
3.4.3. Growth Trial  
 
Daily feed offered and refusals were collected from each treatment throughout the experimental 
period. Daily mean feed intake was measured as differences between offered and refused feeds. 
The sheep were offered ad libitum hay, at 25% refusal adjustment at every week, throughout the 
experimental period. The body weight of each animal was taken every ten days after overnight 
fasting. The daily body weight gain was calculated as the difference between final body weight 
and initial body weight divided by number of feeding days. The feed conversion efficiency of the 
experimental animals was determined by dividing the average daily body weight gain by the 
amount of feed consumed per day. 
32 
 
3.4.4. Digestibility Trial 
 
The digestibility trial was conducted at the end of the feeding trial. In the digestion trial, each 
sheep were fitted with fecal collection bags for four days of acclimatization period to fecal 
collection bags prior to collection period of seven consecutive days. Each experimental sheep 
were offered known amount of the diet under investigation followed by collection and weighing 
of feces excreted. The feces collected were thoroughly mixed. About 20% of the mixed feces 
samples were taken and frozen at -10 ºC, and pooled over the collection period for each animal 
(put standard reference for it). At the end of the collection period, each sample were mixed and 
dried at 60 ºC for 72. Samples of the feed consumed and feces collected were taken to ILRI 
Animal Nutrition Laboratory and subjected to laboratory chemical analysis. Finally digestibility 
of each nutrient was calculated using the following equations:  
 
Apparent nutrient digestibility coefficient     = Nutrient intake – Fecal nutrient output 
                                                                                   Nutrient Intake 
   
3.5. Laboratory Analysis  
  
The chemical analysis of all samples of feeds collected during agronomic and feeding trials, 
refusals and feces were conducted at International Livestock Research Institute (ILRI) Animal 
o
Nutrition Laboratory. The grass samples were dried at 65 c for 72 hours and ground to pass 
through a 1mm sieve. Ash/Organic matter (OM), Dry mater (DM), Crude protein and total ash 
were determined according to AOAC (1990). The neutral detergent fibers (NDF), acid detergent 
fiber (ADF), acid detergent lignin (ADL) were determined according to Van Soest and 
Robertson (1985). True in vitro organic matter digestibility (TIVOMD) was determined 
according to Tilley and Terry (1963).  
 
The metabolizable energy (ME) was estimated from digestible energy (DE) and IVOMD using 
regression and summation equations developed by NRC (2001):  
 
 
33 
 
First DE (Digestible energy) was obtained using the formula:  
 
DE= (0.01*(OM/100)*(IVOMD+12.9)*4.4)-0.3 then  
ME (MCal/kg) =0.82*DE was calculated and converted to Kilogram  
ME (MJ/Kg) =4.184*ME (MCal/kg). 
 
Where: DE=digestible energy; IVOMD= invitro organic matter digestibility; ME= metabolizable 
energy; MJ= mega joule; MCal= Mega calorie and kg=killo gram. 
 
3.6. Sampling Technique and Statistical Analysis 
 
Purposive sampling technique was employed to select districts and Kebeles but simple random 
sampling method was used to determine the households for the interview. A factorial experiment 
with two factors was applied to determine the effect of altitude and harvesting dates on 
morphological parameters, nutrient composition and yield of desho grass. A randomized 
complete block design (RCBD) was used to evaluate local sheep performance when desho grass 
hay replaced natural pasture hay at different levels as a basal diet and supplemented with noug 
seed cake and wheat bran mixture. 
 
The data collected from the desho grass production and utilization assessment were 
systematically coded and analyzed using Statistical Analysis System (SAS, 9.2). The dependent 
variables (desho grass utilization as feed, number of roles of desho grass and preferences of 
desho grass) were binary in nature and independent. To accommodate this non-independence, a 
bivariate probit model was used to simultaneously estimate the effect on the probability of 
multiple use of desho grass to set of explanatory variables. All data obtained from chemical 
analysis and animal experiment were subjected to analysis of variance (ANOVA) using the 
General Linear Model (GLM) procedure of Statistical Analysis System (SAS) software, version 
9.2 (SAS, 2007).  
 
The model for laboratory analysis in agronomic and laboratory study consisting of altitude and 
harvesting days and their interactions, while the model for feeding and digestibility trial included 
the treatment and error effects. 
34 
 
Models used in the three studies: 
1. The statistical model used in survey of desho grass production and utilization can be 
expressed as: 
Yi = xi.  + I 
 where Y1 is the decision vector, xi is a vector of explanatory variables derived from 
household surveys, with  as the corresponding regression coefficient and  is the error 
term. 
 
2. The statistical model for  agronomic and laboratory study consisting of altitude and 
harvesting days and the following mathematical model was applied to analyze the effect 
of all possible factors in the two sets of analysis:  
Yijk = µ+ Ai + Hj + Ai*Hj+ εijk 
Where Yijk is the response (plant morphological parameters, chemical composition, yield 
and in vitro organic matter digestibility of desho grass) at each altitude and harvesting 
days 
µ =overall mean,  
 Ai= altitude (i =mid and high),  
Hj= effect of harvesting days (j =90, 120 and 150),   
th th
Ai*Hj= the interaction of i  altitude and j  harvesting date   
εijk = the residual error.  
 
3. The statistical model for the feeding and digestibility trial included diet and error effects 
analysis of data was: 
Yij = μ + ti + bj + eijk,  
Where, Yij is the response variable,  
μ= is the overall mean,  
ti= is the treatment effect,  
bj =is the block effect and eijk is random error. 
 
The data were analyzed using the General Linear Model (GLM) of SAS 9.2 (2002). Turkey’s 
honest significant test was employed for separation of treatment means.  
35 
 
4. RESULTS AND DISCUSSION 
 
4.1. Desho Grass Production and Utilization  
 
 4.1.1. Household Characteristics of Desho Grass Producers   
 
The socioeconomic characteristics of the respondents are presented in Table 4. In Burie zuira 
district the majority of respondents were at mid age 41-50 years (35.0%) followed by younger 
age group 31-40 (26.67%) and 51-60 (19.17%) called elderly group. The same kind of age 
structure was observed for Doyongena respondents with the large majority (60.83%) laid on mid 
age followed by youth (14.17%) and younger age (12.5%).The higher population of the literate 
class in both districts may have advantage of "good acceptance" of improved agricultural 
technologies. This literacy level is better than the findings of other authors (Zewdie and Yosef, 
2014; Yeshambel and Bimrew, 2014; Bedasa et al., 2015) from different parts of the country. 
Education plays vital role to adopt and promoted new technologies. Moreover, it was explicitly 
indicated that farmers with high educational levels adopt new technologies more rapidly than 
farmers with lower level of educated (Ofukou et al., 2009).  
 
The mean land holding of the respondents in both districts were lower than the national average 
land holding of about 1.6 ha/hh, reported by FAO (2008) which might in turn affect improved 
forage production in both districts. The relatively lower land holding obtained from both study 
districts could be due to the higher mean population density in both districts. The types of 
livestock species kept by respondents in both districts comprise of multipurpose cattle, sheep, 
goats, equines and chicken. In Burie Zuria district the mean TLU for cattle, sheep, goat, equine 
and poultry population were 4.92, 0.32, 0.27, 1.06 and 0.07 TLU, respectively. The total means 
TLU of Burie Zuria (6.64) was lower than 9.87 TLU (Solomon, 2006) reported for Dejen 
district, Amhara National Regional State. 
 
The mean TLU of 2.68, 0.28, 0.15, 0.72 and 0.04 were observed for cattle, sheep, goat, equine 
and poultry, respectively, for Doyogena respondents. The total mean TLU holding of Doyogena 
district (3.87) was smaller than that (5.45 TLU/hh) reported by Yeshitila (2008) from Alaba 
36 
 
district, Southern Nations Nationalities and People’s Regional State. In both districts, 
multipurpose cattle (cattle used for draft power, milk and meat) are dominant livestock with 
relatively higher energy and protein diets requirnment.  
 
Table 4. Socioeconomic and biophysical characteristics of the respondents 
 
Socioeconomic characteristics     Burie zuria district       Doyogena district 
Age of households N % N % 
18-30 years 11 9.17 15 12.50 
31-40 years 32 26.67 17 14.17 
41-50 years 42 35.00 73 60.83 
51-60 years 23 19.17 10 8.33 
>60 years 12 10.00 5 4.17 
Education level of respondents     
Illiterate 25 20.83 32 26.67 
Read and write 48 40.00 33 27.50 
Elementary school 31 25.83 11 9.17 
Junior level 9 7.50 29 24.17 
High school 7 5.83 15 12.50 
Household characteristics  Mean SD Mean SD 
Family size 5.97 1.4 6.61 1.2 
Active labor 3.71 1.3 4.10 1.7 
Total livestock unit 5.46 1.6 3.57 1.4 
Land holding 1.3 0.4 0.6 0.6 
Key: SD=standard deviation. 
 
4.1.2. Feed Resources and Feeding System  
 
Shortage of feed is the major problem raised by all the respondents in both districts. In Burie 
Zuria district, 98.3% of the respondents face seasonal feed shortage of which the majority 
(54.2%) reported to have faced the problem during dry season. The remaining 45.8% 
respondents reported to have faced feed shortage both during and wet seasons. In Doyogena 
district, 99.2% of the respondents face feed shortage of which about 86.3% reported to have 
37 
 
faced the problem in dry season and the remaining reported to have faced the problem both 
during dry and wet seasons. Feed shortage mitigation strategies of the respondents in study 
districts are shown in Fig.2.   
 
60
50
40
30
Burie Zuria
20 Doyognea
10
0
Purchase feed Crop residue only Purchase feed+ 
only crop residue
 
Figure 2. Feed shortage mitigation strategies of respondents in the two districts 
 
The feed shortage mitigation options of both districts were similar. In Burie Zuria district, feed 
shortage mitigation strategies comprise of feed purchasing and the use of crop resides (54.2%), 
feed purchasing only (35%), and the use of crop residue only (10.8%). In Doyogena district, feed 
shortage mitigation strategies comprises of feed purchasing only (43.4%), the use of crop residue 
only (34.4%) and both feed purchasing and use of crop residue (21%). As indicated in other parts 
of the country (Rehrahie, 2001; Adugna, 2007; Fetsum et al., 2009; Firew and Getnet, 2010) 
increment in crop production and increment of livestock population are considerably adding the 
feed shortage in the study areas. 
 
The feeds and feeding system practiced by the respondents is shown in Table 5. The major feed 
resources available in both districts comprised of natural pasture, crop residues, natural pasture 
hay, and some indigenous fodder trees and improved forages including desho grass. The major 
feed resource of Burie Zuria district included natural pasture (47.5%) followed by crop residue 
(42.5%), while the major feed resource of Doyogena district included natural pasture (41.5%) 
38 
 
followed by crop residue (46.4%), indicating that crop residues are gradually becoming the 
dominant feed resources in both districts.  
 
Table 5. Feed resource and feeding system practice of respondents in study districts (N=240) 
 
Parameters Districts 
Feed resource for livestock Burie zuria Doyogena 
N % N % 
Grazing only (yes) 57 47.5 42.5 
51 
Crop residue only(yes) 51 42.5 56 46.4 
Grazing and crop residues 12 10 13 11.1 
Feeding system     
Full day grazing(yes) 96 80 109 91.9 
Grazing and night time supplementation (yes) 24 20 11 0.9 
Supplementation practice     
Supplement  your livestock (yes) 109 90.8 117 97.1 
Supplement  your livestock (No) 11 9.2 3 2.9 
 
Livestock feeding could be categorized as partial grazing plus home or homestead feeding in 
both study districts. In Burie Zuria district 80% of respondents use half a day grazing plus home 
feeding using cut fodder and cereal crop residues, while 20% of respondents follow whole day 
grazing plus night time supplementation. In Doyogena district, 99.1% of respondents reported to 
follow half day grazing plus half day home feeding with green fodder and crop restudies 
depending on availability. Relatively few (0.9%) respondents reported to have used the whole 
day grazing in Doyogena district. Home or homestead feeding observed in the study districts is 
an interesting feature of livestock feeding with enormous advantages in promoting fodder 
development aimed at using cut and carry system.   
 
In Burie Zuria district, about 90.8% of respondents provide supplementary feed on the top of 
grazing, while in Doyogena districts 97.1% of the respondents provide supplementary feed on 
the top of grazing. The supplementary feeds used were reported to be green fodder (49.7%), local 
brewers by product (33.1%) and grain hulls and other byproducts (18.2%) in Burie Zuria district 
while green fodder (67.3%), Enset leaves (28.4%) grain hulls and byproducts (4.3%) were 
reported to have been used as supplementary feed resources in Doyogena district. The types of 
39 
 
animals given supplementary feeds in Burie Zuria district included lactating cows (44%), draft 
oxen (32.80%), both lactating and draft oxen (19.1%), and all grazing animals (4.1%). Similarly, 
lactating and draft oxen (53.3%), lactating cows (28.7%), draft oxen (10.7%), and all grazing 
animals (4.9%) are reported to be given priority in supplementation in Doyogena district. 
Depending on the production system being employed, there are reports that indicate the 
contribution of crop residues as feed resource outweigh far more than grazing and browsing 
(Seyoum et al., 2001; Solomon, 2004; Awoke, 2015). The same study reported that crop-
residues and stubble grazing accounted for about 74.15% of the total annual feed supply year 
round during the time at which feed intake from grazing is inadequate or almost unavailable. In 
most intensively cultivated areas, crop residues and aftermath grazing accounts for about 60 -
70% of the basal diet (Seyoum et al., 2001). 
 
All the respondents of both districts reported to have practiced improved fodder (including desho 
grass) production and utilization. In Doyogena district, the majority of the respondents (77.9%) 
produce desho grass only, with few others (6.6%) producing fodders like vetch and vetch and 
elephant grass (4.1%).  In Burie Zuria district only few (6.6%) produce desho grass only with 
larger proportion practicing many types of fodders including  desho grass, Sesbania sesban and 
Rhodes grass (49.9%) followed by desho grass, oat, vetch and S. sesban (31.2%) and desho 
grass, elephant grass and S. sesban (13.4%).  
 
Due to its positive biological impact on degraded lands, the government of Ethiopia has given 
due attention to the use of forage development in stock exclusion on watershed areas, even if 
much progress has not been achieved till recently (CSA, 2013). The available reports in Ethiopia 
(Alemayehu, 2005; Abebe et al., 2008) indicated that unsatisfactory and limited success rates of 
improved forage development had been encountered because of shortage of land in the mixed 
crop-livestock agriculture and technical problems such as poor skils in planting and managing of 
the seedlings, insect damage and low interest of farmers. Hence, the introduction of desho grass 
into the farming system has the advantage to mitigate the feed shortage problems. According to 
CSA (2015), the improved forage contribution to the livestock feed source is insignificant (0.3%) 
and calls for further effort in extension and research activities in both districts. Due to 
unprecedented population increase, land scarcity and crop-dominated farming, there has been 
40 
 
limited introduction of improved pasture and forages to smallholder farming communities and 
the adoption of this technology by smallholder farmers has been generally slow (Solomon et al., 
2010). 
 
4.1.3. Production and Management of Desho Grass 
 
The system of desho grass production in the study areas was mainly based on rain fall in a 
similar way to the other forage species. In Burie Zuria district, 80% of the respondents depend on 
water availability for desho grass production and about 4.2% reported to have used irrigation. 
The other 15.8% reported to have used both rain and irrigation as the case may be. Establishment 
of desho grass in the study districts was based on using root splits as reported by all the 
respondents of both district. The results of this study are in agreement with the earlier ones (Leta 
et al., 2013). In Doyogena district, all the respondents reported to have depended on rain for 
desho grass cultivation. Fertilizer application in the form of manure or artificial fertilizer is 
important for desho grass production (Leta et al., 2013). In the study districts, fertilizer 
application was not uniform both in the type of fertilizer used and in mode of application. In 
Burie Zuria district, 58.3% of the respondents apply either natural or artificial fertilizer on desho 
grass and the remaining respondents (41.7%) do not use either of the two fertilizer types. Among 
the respondents that use fertilizer, 75.83% and 24.17% are found to apply manure and 
commercial fertilizer, respectively. In Doyogena district 64.5% of the respondents use either of 
the two fertilizer type of which about 94.6% use manure and the remaining (5.4%) use 
commercial fertilizer. In both districts weeding of desho grass was not practiced, may be due to 
lack of awareness and shortage of labor.  
 
41 
 
 
 
Figure 3. Desho grass production strategies of respondents 
 
The frequency of cutting the desho grass after the first harvest in Burie Zuria district was 
reported to be every two weeks  (44.7%) during the rainy season. About 20.3% of respondents 
reported to practice more than two weeks frequency of cutting and about 35% of the 
respondents’ indicated to have used variable frequency of cutting based on the availability of 
moisture. In Doyogena, 23.8% of the respondents harvest at a frequency of every two weeks, 
whereas about 74.6% reported that frequency of cutting depends on moisture availability. This is 
in line with the recommended practice of harvesting desho grass at about 4 months of age after 
planting and the frequency of cutting after the first harvest depends on moisture availability (Leta 
et al., 2013). In Burie Zuria district 70.8% of respondents had training on desho grass planting 
and utilization while in Doyogena district only 13.3% of the producers got training on desho 
grass production and utilization. The discrepancy may be due to the fact that desho grass was 
relatively new fodder and much emphasis has been given on training of producers in Burie Zuria 
while in Doyogena the grass has been there for relatively long time and less emphasis has been 
given on the training aspect. 
42 
 
4.1.4. Utilization of Desho Grass  
 
4.1.4.1. Desho grass as feed 
 
The results obtained showed that the utilization of desho grass as animal feed (Table 6) was 
given more emphasis because of the majority of the respondents (60%) use the grass as animal 
feed. There was a hypothesis that utilization of desho grass as feed is affected by district 
characteristics. The result indicated that there was significant negative correlation (P<0.01) 
between utilization of desho grass as animal feed and non-feed roles og the grass as reported by 
respondents of Bure Zuria district while significant positive correlation (P<0.01) between 
utilization of desho grass as animal feed and non-feed role of the grass was observed in the case 
of respondents of Doyogena district. The results obtained tend to indicate that desho grass is 
better utilized as feed in Doyogena district as compared to Burie Zuria district. 
 
The relatively low status of utilization of the grass as feed in Burie Zuria district indicates that 
the district is suitable for cereal grain production, which in turn results in better availability of 
crop residues to be used as feed. Farmers in Doyogena district tend to use more of cut and carry 
system. In Doyogena district, the major crops grown are potatoes and ensete (Ensete 
ventricosum) which generate comparatively smaller quantities of crop residues for livestock 
feeding. Age of household head was assumed to have correlation with utilization of desho grass 
as feed. The results showed that age of the household head was not significantly correlated 
(P>0.05) with the degree of utilization of desho grass as animal feed, indicating that all age 
groups use desho grass for the intended purpose. Previous reports by other workers (Adesina and 
Zinnah, 1993; Fufa and Hassan, 2006) found that increase in age of a farmer was associated with 
low probability of using agricultural technologies as shown by the existence of a non-linear 
relationship between age and the use of agricultural technologies (Rogers, 1983).   
 
 
43 
 
Table  6.  Factors affecting the utilization of desho grass as feed by smallholder farmers in the 
study districts 
  
Explanatory variables Est. Coeff. SE  SL 
District       -1.34 0.40 *** 
Household head age     
18-30 years -0.55 0.53 ns  
31-40 years -0.16 0.48 ns  
41-50 years  -0.55 0.44 ns  
51-60 years -0.61 0.47 ns  
Education  level:      
Illiterate 0.58 0.36 * 
Read and write 0.86 0.39 * 
Elementary school -0.11 0.34 ns  
High school  -0.29 0.42 ns  
Experience in desho grass (years) -0.20 0.08 ** 
Active labors (N) -0.04 0.06 ns  
Farmland size (h) 0.28 0.26 ns  
Backyard desho production  0.29 0.32 ns  
Access to training (yes) -0.93 0.26 *** 
Total livestock units (N) 0.04 0.06 ns  
Feeding system (grazing) 0.98 0.36 *** 
R2 0.37     
No observations 240     
*=p<0.05;**=p<0.01;***=p<0.001, SE= standard error 2
; SL=significance level; R = Coefficient of 
determination. 
 
The hypothesis was as experience of desho grass production increases, utilization of the grass as 
feed also increases. However, there was significant negative  correlation (P<0.01) between the 
experience in production of desho grass and utilization of desho grass as animal feed showing 
that experienced members of the farming community in desho grass production, prefers to use 
the grass for other purposes like soil stabilization. This result is in agreement with the previous 
reports on desho grass (Welle et al., 2006; Smith, 2010) which indicated that desho grass has 
valuable role in soil conservation. The assumption was that presence of active labor in the family 
would significantly affect utilization of desho grass as feed. But the result indicated that there 
was no statistically significant correlation (P>0.05) between the number of active laborers in the 
44 
 
homestead and the utilization of desho grass as animal feed, indicating that the production and 
use of desho grass as feed is not necessarily labor intensive and require larger plot sizes.  
 
Size of farmland was assumed to affect utilization of desho production as feed because those 
farmers who have relatively bigger farmland size use it for desho production and in turn use it as 
feed. However, the results of the current study showed that there was no significant correlation 
(P>0.05) between farmland size and the distance of the desho grass plots from the households. 
Farmers usually plant desho grass on backyard and small plots of land on soil bunds. They do not 
have the tendency to increase desho grass production even with the availability of adequate land. 
Training access on desho grass production and utilization was hypothesized to be significantly 
correlated with utilization of the grass as feed. The result showed that there was significant 
negative correlation (P<0.01) between training of the farmers and the use of desho grass as 
animal feed, tending to indicate that training increases awareness on the alternative uses such as 
feed, soil conservation and income roles of desho grass.  
 
Total livestock holding of household was assumed to have significant effect on utilization of the 
grass as feed but there was no significant correlation (P>0.05) between livestock numbers in the 
household and the utilization of desho grass as animal feed, might be due to the low levels of 
livestock holding per household in the two districts studied (averages of 3.56 TLU). The type of 
livestock feeding system practiced was positively and significantly correlated (P<0.01) with the 
use of desho grass as animal feed as hypothesized. This might be due to the fact that there was a 
high tendency to use desho grass as a supplement when grazing is the main source of feed. 
During the period of serious feed scarcity, farmers prefer to feed desho grass to lactating animals 
and desho grass was fed to all types of animals if it is available in plenty.  
 
The educational level and use of desho grass for animal feed were not significantly correlated 
(P>0.05). This might be due to the fact that respondents have the same indigenous knowledge 
and experience of respondents in using desho grass. This is contrary to the expectation and 
previous findings (Mugisha et al., 2004; Salasya et al., 2007) which reported that education 
enhances the use of agricultural technologies because educated farmers have a better opportunity 
45 
 
to acquire and process information as well as understand the technical aspects of new 
technologies. 
 
A B 
 
Figure 4. Farmer cutting desho grass (A) and cow eating fresh grass (B) 
 
In Burie Zuria district, about 57.5% of the respondents use desho grasses as source of income 
through the sale of seedlings. In Doyogena district, only 12.3% of respondents get income from 
the sale of desho grass seedling and fresh grass. The variation of income in the use of desho 
grass as income source might be due to the availability of alternative feeds in Burie zuria and sell 
of seedling as income source than the farmers in Doyogena district. The use of desho grass as 
income sources is in line with Shiferaw et al. (2011) who stated that desho grass has a role as 
income source for farmers. Apart from income generation, desho grass was used for soil 
conservation in both districts; the result is in agreement with that of the other reports (Leta et al., 
2013; Welle et al., 2006) explained that desho grass was income source for stallholder farmers in 
other areas of the country. 
 
4.1.4. 2. Factors Affecting the Number of Roles of Desho Grass 
  
The factors affecting the number of roles (single, dual, and multiple roles) of desho grass is 
presented in Table 7. There was no significant correlation (P>0.05) between the numbers of roles 
of desho grass and age groups of the respondents which was in contrary to the hypothesis that 
age would have significant effect on number of roles. This may be due to the fact that desho 
46 
 
grass was produced in the study districts on very small plot of land which may be used for one or 
more roles in both districts. The result indicates that the knowledge and experience of desho 
grass production and general utilization in both districts was almost similar and all age groups 
have similar knowledge about the roles of desho grass.  
 
Table 7.  Factors affecting the number of uses of desho grass for the households 
 
Explanatory variables Single role Dual role Multirole 
Est. SE Est. SE Est. SE 
Coeff. Coeff. Coeff. 
District     -0.94 0.34 0.64 0.42 0.68 0.76 
Age of household head              
18-30 years -0.44 0.49 0.59 0.58 0.04 0.78 
31-40 years -0.18 0.44 0.25 0.52 0.45 0.65 
41-50 years  -0.36 0.40 0.73 0.49 0.03 0.57 
51-60 years  0.24 0.44 0.68 0.52 -0.59 0.73 
Education  level:             
Illiterate 0.34 0.35 -0.66 0.39* 0.34 0.58 
Read and write only  0.24 0.37 0.35 0.40 -0.21 0.63 
elementary school completed -0.07 0.33 0.21 0.35 -0.40 0.59 
High school graduated -0.23 0.41 0.38 0.43 -5.10 0 
Experience in desho grass (years) -0.13 0.08* 0.09 0.09 0.19 0.15 
Active labors (N) -0.01 0.06 -0.03 0.06* 0.08 0.11 
Farmland size (h) -0.01 0.24 0.11 0.27 0.14 0.46 
Backyard 0.17 0.30 -0.24 0.34 0.11 0.52 
Total livestock units (N) 0.04 0.06 -0.11 0.06 0.02 0.11 
R2 0.12   0.29   0.70   
No observations 240   240   240   
*=p<0.05;**=p<0.01;***=p<0.001; SE= standard error; 2
 R = Coefficient of determination; 
N=number. 
 
Desho grass production and utilization is relatively a new experience in both districts and most 
of the respondents have similar understanding about the roles of desho grass. Level of education 
was assumed to have significant effect on utilization of desho grass as feed. However, the result 
showed that, education level of the household head has no significant correlation (P>0.05) with 
the number of roles of desho grass showing that high educational level is not important in the use 
47 
 
of desho grass for different purposes. Desho grass production experience of farmers had 
significant correlation (P<0.01) with the number of roles of desho grass as initially hypothesized. 
That means the more years of production of desho grass gives them the ability to utilize it for 
different functions. There was no significant correlation (P>0.05) between the number of active 
labor force and the number of roles of desho grass in contrary to the initial hypothesis. This 
might be due to desho grass was not highly expanded and replaced other crops which otherwise 
could require large labor.  
 
The hypothesis was that size of farm landholding would significantly affect the number of roles 
of desho grass. But the result showed that there was no significant correlation (P>0.05) between 
farm size (land holding) and the contribution of desho grass within the household, since the grass 
is produced as a backyard crop on small plot of land on soil bund production strategies which are 
less competing with the other crops for the available farm land. There was no significant 
correlation (P>0.05) between the size of total livestock holding and the number of roles of desho 
grass as total livestock owned for both districts which in contrary to the hypothesis. This can be 
explained as desho grass was used in small quantities as supplementary feed rather than using in 
large amounts as basal diet (grazing and crop residues) which tend to require large volume of 
feed per day depending on the number of TLU per household. 
 
4.1.5. Factors Affecting Preference of Desho Grass for Livestock  
 
The preference of desho grass for livestock species is presented in Table 8. There was significant 
correlation (P<0.01) difference between Burie Zuria and Doyogena districts in desho grass for 
lactating cattle, small ruminant and all livestock as hypothesized. This may be due to the fact that 
Burie Zuria district has got large number of livestock (4.37 TLU) holding per household than 
Doyogena district (2.75). The possible explanation for this may be Burie Zuria district which has 
large livestock per household uses other alternative feeds sources which satisfy the larger 
population.  
48 
 
Table 8.  Factors affecting preference of desho grass by livestock in the study districts 
 
Variables  Lactating Cattle Small ruminants All livestock 
 Est. Coeff. SE Est. Coeff. SE Est. Coeff. SE 
District      0.64 0.39* 15.17 1.66*** -0.82 0.40** 
Household head age         
18-30 years  -0.39 0.48 31.28 1.98 0.16 0.49 
31-40 years  -0.28 0.44 32.37 3.51 0.32 0.44 
41-50 years  -0.28 0.40 28.17 1.40 0.26 0.40 
51-60 years -0.76 0.44 25.79 2.53 0.59 0.44 
Education  level of household head:       
Illiterate  0.43 0.37 7.38 1.81 -0.65 0.37 
Read and write  0.57 0.38 6.91 1.66 -0.75 0.38 
Elementary school  0.45 0.36 3.95 2.90 -0.55 0.36 
High school -0.20 0.44 11.47 4.15 0.03 0.43 
Active labor family -0.03 0.06 -0.30 0.84 0.16 0.09 
(N) 
Feed Shortage  5.85 0.33*** -0.93 0.26 -1.48 0.52*** 
Landholding (ha) -0.12 0.25 -1.52 3.95 0.14 0.25 
Total livestock (TLU) -0.14 0.06** -2.37 2.00 0.25 0.07* 
Backyard desho -0.05 0.30 -1.80 2.42 0.00 0.30 
production  
R2 0.24  0.993  0.31   
No observations 240  240  240  
2
*=p<0.05;**=p<0.01;***=p<0.001, SE= standard error.TLU= Tropical Livestock Unit; N=number; R = 
Coefficient of determination 
 
The hypothesis that household age would significantly affect utilization of desho grass for 
different species was disproved and the result showed age has no significant (P>0.05) correlation 
on utilization of desho grass for different species of livestock. This might be due to the fact that 
desho grass is used for different types of animals depending on the availability of desho grass.  
Household education level has no significant (correlation (P>0.05) between utilization of desho 
grass for different species of livestock in contrary to the initial hypothesis. This indicates that 
desho grass utilization does not need high literacy level or special knowledge. There was 
hypothesis that active labor in the family would significantly affect desho grass utilization as 
feed. However, the result showed there was no significant correlation (P>0.05) between active 
labor on the use of desho for lactating, small ruminant, and all types of livestock may be because 
49 
 
desho grass was mostly produced at the backyard of the farmer which in turn does not need 
much labor force for cut and carry.  
 
There was negative significant (P<0.01) correlation between feeds shortage and use of desho 
grass for lactating cattle, small ruminant and all livestock as initially hypothesized which might 
be due to the use other feeds such as crop residues to satisfy basal diet requirement because 
desho grass is a supplementary diet in all respondents. Farmland size has no significant (P>0.05) 
correlation with the types of livestock species fed desho grass in contrary to the initial 
hypothesis. This might be due to the fact that desho grass was not planted on large area of land as 
a trade off for other forages or crops. Initially it was hypothesized that the larger livestock 
holding in the family the more utilization of desho grass as feed. But the result showed there was 
negative and significant correlation (P<0.01) correlation between the total livestock holding and 
desho grass utilization for lactating cattle and all livestock may be due to the fact that desho 
grass was not used as basal diet and farmers tend to use other feeds sources as basal diet and use 
desho grass as supplementary diet. On the other hand, there was no significant (P>0.05) 
correlation between backyard production and species of livestock fed desho grass may be due to 
the fact that desho grass was produced in small amount and used in small amount as supplement 
for all types of species available. In addition to lactating cattle, desho grass was used for 
fattening cattle (14%) and equine (3.8%) in both districts. This is in line with other studies 
reported that the grass is considered to be a very palatable species to cattle (in India) and the 
palatability has been reported as average in the Sahel (FAO, 2010). 
 
4.2. Agronomic and Laboratory Characteristics of Desho Grass  
 
4.2.1. Effects of altitude, harvesting days and their interactions on plant morphological 
characteristics and number of re-growth days of desho grass 
 
The results of the effect of altitude, harvesting dates and their interactions on plant 
morphological characteristics and re-growth potential of desho grass are presented in Table 9. 
The results obtained indicate that with the exception of leaf length per plant (LLPP), other 
morphological characteristics of desho grass studied were not significantly affected (P>0.05) by 
50 
 
altitude. Desho grass grown in high altitude area have taken relatively longer period (P<0.05), to 
reach full re-growth after harvest which might be due to the environmental variations between 
mid and highland areas. 
 
Table 9. Effects of altitude, harvesting dates and their interactions on plant morphological 
characteristics and number of re-growth days of desho grass 
 
Factors Parameters 
Attitudes Harvesting dates PH  NTPP NLPP LLPP LSR RGD 
(cm) (counts) (counts) (cm) (days) 
b b b a b
Mid  90  72.97  33.67  262 21.38  1.25  15.33  
a a a a ab
 120  101.30  50.03  326.67 32.12  1.18  18.00  
a a a b a
 150  107.5  59.02  342.33 33.44  0.82  20.00  
 Mean 93.92 47.66 310.33 28.98 1.08 17.78 
 SE 8.02 3.00 25.54 2.96 0.09 0.96 
 Sig. *** *** ns *** *** *** 
b b
High 90  69.33  47.82 286.67  18.05 1.23 18.67 
ab ab
 120  86.83  49.48 317.67  20.72 1.15 19.67 
a a
 150  105.26  47.82 330.33  26.66 0.81 21.67 
 Mean 87.14 49.47 311.56 21.81 1.06 20.00 
 SE 4.71 3.61 8.17 3.17 0.06 1.00 
 Sig. *** Ns *** ns ns ns 
 Overall mean 90.53 48.57 310.95 25.395 1.07 18.89 
 Overall SE 11.34 5.60 31.98 5.59 0.14 1.59 
 CV (%) 12.53 11.54 10.28 21.93 12.99 8.42 
P-value  Altitude ns ns ns *** ns *** 
Harvesting date  *** *** *** *** *** *** 
Interaction ns *** ns ns ns ns 
Treatments means with different letters in a columnare significantly different (P < 0.05) for altitudes. 
SE=Standard error; CV= coefficient of varation; PH=plant height; NTPP= number of tillers per plant; 
LLPP=leaf length per plant; LSR= leaf to stem ratio; RGD= Regrowth date; ns= non segnifcant. 
 
51 
 
The relatively shorter duration (17.78 days) required to attain full re-growth status of the grass 
planted in the mid altitude as compared to the duration of 20.00 days required to attain similar 
status of re-growth in the high altitude might be due to variations in altitude, temperature and soil 
characteristics of the two locations. In mid altitude, Plant height (PH), number of leaves per plant 
(NLPP) and number of tillers per plant (NTPP) were significantly (P<0.05) increased as 
harvesting stage increases from 90 to 150 days. In high altitude, the only parameter increased 
significantly (P<0.05) with harvesting stage was plant highet (PH) by increament in harvesting 
days. In the mid altitude area, like the highlands, plant height was low at early stages of growth, 
but enhanced growth was observed after 120 days of harvesting. The increment in PH at latter 
stage of harvest might be due to full development of steam and leaf. Number of leaves per plant 
was significantly increased (P<0.05) as the age of plant increased may be due to the full stage of 
growth which contribute to the number of leaves and total biomass of the plant.   
 
In the highland agro ecology, the results obtained indicate that with the plant height (PH), 
number of tillers per plant (NTPP), and leaf length per plant( LLPP) were significantly (P>0.05) 
lower at early harvesting date (90) but 120 and 150 dates did not show significant difference. 
Plant height is an important parameter contributing to yield in forage crops. Plant height was low 
at early stages of growth, but enhanced growth was observed after 120 days of harvesting. The 
duration required to fully re-vegetate in the high altitude was significantly different (P<0.05) 
among harvesting dates indicating that late stage of harvest takes more time to re-vegetate. The 
increment in PH at latter stage with advancement in harvesting dates in both altitudes might be 
due to full development of steam and leaf. This result is in agreement with Taye et al. (2007) 
who reported the same characteristics for Napier grass. The number of tillers per plant was 
significantly (P<0.05) at the mid altitude in relation to the advance in harvesting date of plants as 
the result of the development of new shoots bearing on each plant result in greater number of 
tillers as the plant matures.  
 
The results obtained from highland areas indicate that with the plant height (PH), number of 
leaves per plant (NLPP), were significantly (P<0.05) higher at late harvesting date (150) but 90 
and 120 dates did not show significant difference. The increment in number of tillers per plant 
was in line with other reports for different grasses (Kamel et al., 1983; Seyoum et al., 1998; 
52 
 
Taye et al., 2007). The number of leaves per plant (NLPP) was not significantly (P<0.05) 
different due to harvesting dates in the mid altitude. Leaf to stem ratio (LSR) was not significant 
between 90 and 120 dates of harvest but a significantly different (P<0.05) result was observed 
for the latest harvesting date (150 day) LSR decreased significantly (P>0.05). The works of 
different authors also confirm this result for different species of tropical grasses (Boonman, 
1993; Tessema, 2000; Taye et al., 2007). The duration required to re-vegetate after harvest (re-
growth dates) were significantly (P<0.05) varied due to harvesting dates. The number of days 
required to attain good status of re-growth was significantly affected (P<0.05) by altitude. 
Relatively longer growth time after later stage of harvest was observed which might be due to 
slow development of new shoots as the result of maturity of the plant. The only parameters that 
showed significant (P<0.05) difference was the interaction between number of tillers per plant, 
altitude and harvesting dates. 
 
4.2.2. Effect of altitude, harvesting date and their interacton on chemical composition and 
yield of desho grass  
 
The effect of altitude, harvesting dates and their interaction on chemical composition, dry matter 
and crude protein yield and in vitro organic matter digestibility of desho grass is shown Table 10. 
There were significant differences (P<0.05) in percent dry matter, percent organic matter, crude 
protein, crude protein yield and phosphorous contents between mid and high altitudes, which 
might be associated with environmental differences such as temperature, moisture and soil 
characteristics. The mean CP content of the current result is lower than that reported by Kabore 
et al (2012). This discrepancy can be explained by the fact that chemical composition and overall 
quality of a given forage is affected by soil nutrient (Tessema et al., 2011), climate (Arzani et al., 
2008) and associated factors. Moreover, the inherent type of species and soil characteristics are 
important factors in altering the nature of forage quality. 
53 
 
Table 10. Effect of altitudes, harvesting dates and their interacton on chemical composition and yield of desho grass 
Factors Parameters 
Attitudes Harvesting DM (%) DMY OM (%) CP CPY NDF (%) ADF ADL IVOM ME (MJ/Kg Ca P 
dates (t/ha) (%) (t/ha) (%) (%) D (%) DM) (g/kg) (g/kg) 
b a b ab b
Mid  90  30.85 13.71  92.71  9.55 1.41 75.19 41.82  4.38 47.13 6.82 3.60  2.00  
ab a ab a ab
 120  31.07 15.20  92.14  8.25 1.44 75.75 43.43  5.54 44.62 6.5 4.11  2.35  
a b a b a
 150  32.33 21.60  88.95  8.0 1.41 77.14 45.84  5.81 47.13 6.82 2.60  2.63  
 Mean 31.42 16.84 91.27 8.6 1.53 76.03 43.7 5.24 43.06 6.13 3.44 2.33 
 SE 1.12 2.56 0.63 0.55 0.21 1.33 0.91 0.54 2.93 0.49 0.23 0.13 
 Sig. ns *** *** ns ns ns *** ns ns ns *** *** 
b b a b b a
High 90  27.35 11.71  85.52  8.17  0.97 70.38  38.72  4.84 44.1 6.69 3.56 3.37  
b ab ab b ab b
 120  27.75 12.25  88.99  7.55  1.01 72.17  40.86  5.52 42.12  6.13 3.42 3.10  
a a b a a c
 150  31.61 19.91  90.36  5.61  1.13 78.22  44.28  6.11 48.21 5.87 3.54 2.5  
 Mean 28.9 14.62 88.29 7.11 1.04 73.59 41.29 5.49 44.81 6.23 3.96 2.86 
 SE 1.12 2.48 0.63 0.55 0.20 1.33 0.9 0.54 2.92 0.49 0.23 0.13 
 Sig. ns *** *** *** ns *** *** ns ns ns ns *** 
 Overall 
mean 30.16 15.73 89.78 7.86 1.29 74.81 42.51 5.37 43.94 6.18 3.7 2.60 
 SE 1.94 3.35 1.30 0.95 0.32 2.04 1.83 1.32 4.95 0.83  0.54 0.25 
 CV (%)  6.43 21.31 1.45 12.05 25.06 2.72 4.31 24.68 11.27   13.40 14.49 9.54 
P-value Altitude *** ns *** *** *** *** *** ns ns ns ns *** 
Harvesting ns *** ns *** ns *** *** ns ns ns *** ns 
date  
Interaction ns ns ns *** ns ns ns ns ns ns ns ns 
 
Treatments means with different letters in a column are significantly different (P < 0.05) for altitudes. SE=Standard error. Alt=altitude; 
DM= dry matter; DMY=dry matter yield; CP=crude protein; CPY=crude protein yield; CV= coffcient of variation; ns=non significant 
NDF=neutral detergent fiber; ADF=Acid detergent fiber; ADL=Acid detergent lignin; IVOMD=In vitro organic matter digestibility; 
ME=metabolaizbale energy; Ash=ash content; Ca=calcium; P=phosphorous.  
54 
 
Studies show that, feeds containing more than 12.0 MJ/kg of DM of metabolizable energy and 
feeds containing less than 9.0 MJ/kg of DM of metabolizable energy are categorized as high and 
low enegy feed, respectively (Lonsdale, 1989). Hence, according to this classification, desho 
grass grown in both mid and high altitude is classified as low energy feed that are below the 
minimum maintenance energy requirement of sheep (McDonald et al., 2010). The result of  the 
high altitude location indicated that there were significant differences (P<0.05) in dry matter 
yield (DMY), organic matter (OM), crude protein (CP), neutral detergent fiber (NDF), acid 
detergent fiber (ADF), and Phosphorous content between the grasses harvested at different dates. 
The DMY and OM content of desho grass significantly increased (P<0.05) as the days of harvest 
increased. The CP content, however, decreased as the harvesting days increased. The acid 
detergent fiber (ADF) component of the grass showed a tendency of increment with change in 
altitude and harvesting dates. The reduction in CP content and increament in ADF contents 
indicates that more cellulo-lignose formation and decrement in soluble fraction including CP 
with advancement in age of the plants. Similar to the mid-altitude location, Phosphorus content 
of the plant also showed significant reduction (P<0.05) with increase in harvesting days. 
 
The result of this study is in agreement with that of the others (Berihun, 2005; Berhanu et al., 
2007) who reported that DM content of grasses increased with an increase in growth and 
development status of the plants, and with advancement in harvesting dates. The highest total dry 
matter yield was reported at the harvesting date of 150 days after planting, the results of which 
was in agreement with that of Leta et al. (2013) indicating that time of harvesting had high 
influence on dry matter yield. The parameters significant (P<0.05) by the interaction of altitude 
and harvesting dates were organic matter (OM) and Phosphorus (p) content. The yield increment 
might be due to the additional tillers developed which brought an increase in leaf formation, leaf 
elongation and stem development (Crowder and Chheda, 1982). The highest yield of forage 
harvested at late stage of maturity could also be attributed to the availability of favorable rainfall, 
temperature and soil nutrient over the extended growing period. The significant increase in dry 
matter yield with increase in the age of plants was in agreement with the results reported by  
other  (Koster et al., 1992; Yasin et al., 2003) from trials conducted on both cultivated grasses 
and natural pasture in different parts of Ethiopia (Fekede et al., 2014). 
 
55 
 
The mean CP content of desho grass (8.6%) obtained from the mid altitude and (7.5%) from the 
highland study areas were higher than that reported (6.5%) from the same species in other 
countries (Waziri et al., 2013; Heuze and Hassoun, 2015). The mean CP content of desho grass 
obtained from the current experiment was within the range of 5.9-13.8% reported for Pennisetum 
species (Napier grass) (Kanyama et al., 1995; Kahindi et al., 2007). The CP content reported 
from both altitudes is comparable with that  of most of tropical grasses  (Humphreys, 1991) and 
that of  most of the Ethiopian roughages which have a CP content of less than 9% (Seyoum and 
Zinash, 1989), the amount of which is lower than the minimum CP requirement (9%) for  rumen 
microbial protein synthesis (ARC, 1980). According to the results of this study, CP content 
(8.6%) of desho grass planted in the mid altitude was higher than that planted in high altitude 
(7.5%) which might be associated with the difference in temperature, precipitation and soil 
characteristics as indicated by Daniel (1996), who reported that plant growth and nutritional 
quality are markedly affected by temperature and soil moisture conditions.  
 
Lignifications of forages appeared to occur almost constantly with increase in harvesting dates. 
However, the result of this study was in agreement with that of other workers (Whitman, 1980; 
Yihalem et al., 2005; Taye et al., 2007) who reported that lignin content increase with increase in 
the days of harvesting. This might be due to the fact that as plants grow older there is a greater 
need for the development of structural carbohydreates such as cellulose, hemicelluloses and 
lignin. Commonly, the upper leaves produced by older plants appear to be more of lignified than 
younger leaves (Whiteman, 1980). 
 
Among macro minerals, Phosphorous and Calcium are the most important nutrients required for 
normal animal performance. The Phosphorous content of the desho grass planted in the mid 
altitude (2.86g/kg) was significantly higher than that planted in the high altitude (2.32g/kg). The 
difference in Phosphorous content of the desho grass planted in mid and high altitude might be 
due to variation in soil characteristics and climatic condition which determine the uptake of soil 
nutrients by the plants. The result of this study indicated that the P content of desho grass 
decreased with increase in harvesting days, which might be due to the translocation of P to the 
root parts of the herbage as described by Crowerder and Chheda (1982). The information 
obtained from this study is in agreement with other researchers (Kariuki et al. 1999; Tessema et 
56 
 
al., 2002) who reported that the P content in grass declined with advancing stages of cutting. The 
Ca and P values obtained from the current study were comparable to that reported from desho 
grass species by Heuze and Hassoun (2015). The values of Ca recorded from desh grass at all the 
three dates of harvesting were higher than the minimum critical level of Ca requirnment of beef 
cattle (0.18%-1.04%) as reported by (NRC, 1984). Generally, the chemical composition of desho 
grass varied with the phenology in a similar way to that of other tropical grass species 
(Upadhyay et al., 1978; Jakhmola and Pathak; 1983). 
 
4.2.3. Correlation Analysis of Morphological and Nutritional Parameters of Desho Grass  
  
The simple linear bivariate correlation analyses among morphological, quality and yield 
parameters of desho grass are presented in Table 11. The NTPP was positively correlated with 
other morphological parameters such as NLPP and LSR as well as RGD. The LSR was 
positively correlated with IVOMD and ME which might be due to the fact that leaves have more 
organic matter that contributes to the organic matter digestibility and available energy for 
metabolism. Dry matter content and yield of desho grass were positively correlated with NDF, 
ADF, PH and LLPP and with each other. The positive association of DM and DMY with some 
of the morphological parameters (plant height and leaf length per plant) may result from better 
competition for radiant energy at the extended days of harvesting. Such type of correlation was 
observed in other study (Hunter, 1980). This indicated that as the DM increased, the cell wall 
constituents also contributed for increment of plant parts which eventually lead to increament in 
total DMY. However, the DM and DMY were negatively correlated with LSR which might be 
due to the fact that, as plant matures it increases the stem portion which has more DM than the 
leaf part. 
 
57 
 
Table 11. Correlation coefficients among morphological parameters, chemical composition, yield and in vitro organic matter 
digestibility of desho grass 
 
 D DM CP         CP NDF      A  D F      A  D L     N   TP PH NLP LLPP RGD LSR TA P Ca  IVO ME 
M     Y              Y         P P MD    
DM      1   0.67 -0.05 0.47 0.67* 0.68* 0.25 -0.14 0.51* 0.32 0.68** -0.04 -0.55* -0.32 -0.59** -0.41 -0.20 -0.13 
* * * 
DM  1 -0.24 0.63 0.64* 0.78* 0.31 -0.02 0.58* 0.46 0.48* 0.19 -0.47* -0.17 -0.37 -0.35 -0.11 -0.02 
Y          * 
CP           1 0.54 -0.03 -0.12 -0.08 -0.12 -0.07 -0.14 0.28 -0.61* 0.39 -0.32 -0.16 0.04 0.02 0.02 
* 
CP    1 0.38 0.57* 0.14 -0.13 0.44 0.22 0.56* -0.31 -0.03* -0.42 -0.44 -0.24 0.05 0.14 
Y         
ND     1 0.72* 0.17 0.08 0.40 0.33 0.44 0.23 -0.52* -0.19 -0.52* -0.38 -0.14 -0.10 
F         * 
AD      1 0.28 0.03 0.60* 0.47* 0.56* 0.16 0.49* -0.38 -0.53* -0.38 -0.01 0.08 
F         * 
AD       1 0.09 0.55* 0.47* 0.45 0.23 -0.42 0.24 -0.04 -0.31 -0.24 -0.21 
L        * 
NT        1 0.46 0.65* 0.28 0.70* -0.26 0.21 -0.31 -0.04 -0.32 -0.28 
PP * 
58 
 
Table 12. Correlation coefficients among morphological parameters, chemical composition, yield and in vitro organic matter 
digestibility of desho grass (continued) 
 
DM         D CP     C   P ND AD AD NT PH NLPP LLPP RGD LSR TA P Ca  IVO ME 
M Y         F         F         L        PP MD    
Y          
PH        1 0.72** 0.84** 0.28 0.50* -0.07 -0.62** -0.43 -0.29 -0.17 
NLPP         1 0.64* 0.64* -0.61* -0.16 -0.46 -0.41 -0.17 -0.11- 
LLPP          1 0.05 -0.41 -0.21 -0.63* -0.35 -0.42 -0.32 
RGD           1 -0.47* 0.28 0.04 0.03 -0.23 -0.23 
LSR                    1 0.08 0.41 0.52* 0.08 0.01 
TA             1 0.56* 0.51* -0.33 -0.37 
P              1 0.66* 0.06 -0.05 
Ca                1 -0.12 -0.21 
IVOM                1 0.98** 
D    
ME                 1 
Level of significance: ** = P < 0.01; *= P < 0.05; DMY = dry matter yield; DM = dry matter; DDMY = digestible dry matter yield; CP = crude 
protein; CPY = crude protein yield; NDF = neutral detergent fiber; ADF = acid detergent fiber; ADL=acid detergent lignin; TA = total ash; Ca = 
calcium; P=phosphorous; IVOMD= in vitro organic digestibility; NLPP=number of leaves per plant; LLPP=leaf length per plant; RGD=re-growth 
date; NTPP = number of tillers per plant; Ph = plant height.
59 
 
The crude protein content and yield of desho grass were positively correlated with ADF and with 
each other. The ADF content of desho grass was positively correlated with NDF. The fiber 
components (NDF, ADF, cellulose) and lignin were positively correlated with each others.This 
indicated that there was a high relationship among the different cell wall constitutes that resulted 
from increased age of the plants. These components of cell wall increased as the age of plant 
increased and showed a higher association (P<0.001) with each other. ADF fraction is positively 
correlated with PH, NLPP, LLPP and LSR. The ADF fraction was negatively correlated with 
LSR. LSR was positively correlated with IVOMD which was in agreement with earlier reports s 
(Yihalem et al., 2005: Taye et al., 2007). The results also showed that PH was negatively 
correlated with Ca content of desho grass. The direct relationship between leaf to stem ratio and 
CP content and the inverse association of leaf to stem ratio and fiber content were both 
previously observed by Tessema et al. (2002) in Napier grass. This difference might be due to 
the species variation and management of the grasses.  
 
4.3. Animal Evaluation of Desho Grass (Pennisetum Pedicellatum)  
 
4.3.1. Chemical Composition of Experimental Feeds 
 
The result of the chemical composition of the experimental feeds and refusals are presented in 
Table 12. It has been stated that CP content ranging between 7 and 7.5% is required to satisfy the 
maintenance requirement of ruminant animals (Van Soest, 1982). Hence, the observed CP 
content of natural grass and desho grass hay used in this feeding trial was found to be below the 
maintenance requirements of sheep. The nutrient content of pure natural pasture hay was lower 
than that of pure desho grass hay. The CP content of natural pasture hay was lower than the 
previously reported (Bimrew et al., 2010; Yeshambel et al., 2012; Awoke, 2015) from natural 
pasture hay of Northwestern Ethiopia. Such variations could partly be attributed to location, soil 
type, variety, post harvest handling and stage of maturity at harvest. The physical characteristics 
of the hay used for this experiment indicated that it was harvested at late stage of maturity which 
could explain low CP and high fiber contents. The CP content of the treatment diets increased 
and that of NDF, ADF and ADL decreased with increasing proportion of desho grass inclusion in 
the diet. 
60 
 
Table 12. Chemical composition of experimental feeds and refusals used in animal evaluation 
experiment 
 
Feed Offers (g/Kg DM) 
Treatment DM Ash OM CP NDF ADF ADL 
T1 912.50 115.11 884.89 35.20 712.3 464.3 56.9 
T2 921.26 116.60 883.40 45.46 695.4 426.4 54.0 
T3 925.41 123.14 876.86 52.90 676.5 414.8 45.1 
T4 928.28 119.21 880.79 57.30 685.9 414.9 48.6 
T5 935.15 121.29 878.71 54.49 673.1 381.1 36.0 
ConMix 908.67 86.60 913.40 225.00 380.3 238.8 92.9 
Basal Feed refusals (g/Kg DM) 
T1 931.50 97.45 902.55 22.03 745.4 464.4 61.9 
T2 930.13 90.43 909.57 22.84 740.8 456.3 63.8 
T3 929.05 111.11 888.89 33.65 679.1 435.7 51.5 
T4 933.15 111.37 888.63 39.31 698.4 423.5 47.8 
T5 926.93 106.26 893.74 38.24 700.2 421.8 51.4 
Keys: DM=dry matter; OM=organic matter; CP=crude protein; NDF=neutral detergent fiber; 
ADF=Acid detergent fiber; ADL=Acid detergent lignin; T=treatment; T1= 100% NPH 
adlib+(300g DM CM);T2=25% NPH+75% DGH adlib+(300g DM CM);T3= 50% NPH+ 50% 
DGH+(300g DM CM ); T4= 25% NPH+ 75% DGH adlib+(300g DM CM ); T5=100% DGH 
adlib+(300g DM CM ). 
 
The mean CP content of desho grass hay used in the current study was comparable with the 
reports of Aliyu et al. (2012) but lower than that reported by other workers (Waziri et al., 2013; 
Heuze and Hassoun, 2015) from other countries. However,                                                                                                                                                                                                             
mean CP content of desho grass hay used in the current experiment was within the range of5.9-
13.8 %, recorded from Napier grass (Kanyama et al., 1995; Kahindi et al., 2007). The ash 
content of desho grass is higher than that reported from other countries (Aliyu et al., 2012). It has 
been stated that CP value ranging between 7 and 7.5% is required to satisfy maintenance 
requirement of ruminant animals (Van Soest, 1982). Hence, the observed CP content of the basal 
diet used in the current study was below the maintenance requirements of sheep. According to 
Pond et al. (1995), NDF portion of feed could be used by ruminant animals which depend on 
61 
 
microbial fermentation of most fibrous plant components. Feeds low in ADF constitutes more 
digestible nutreitn as ADF is negatively correlated with feed digestibility of nutrients (McDonald 
et al., 2010). Lonsdale (1989) classified feed materials according to their energy and protein 
contents. Feedstuffs having more than 200g/kg of DM of CP are categorized as protein high 
feeds and feedstuffs containing less than 120g/kg of DM of CP are categorized as protein low 
feeds. Similarly feedstuffs containing more than 12.0 MJ/kg of DM of metabolizable energy are 
classified as high energy feed and feedstuffs containing less than 9.0 MJ/kg of DM of 
metabolizable energy are classified as low energy feeds. Hence, according to this classification, 
the concentrate mixture used in the present study could be classified as high protein quality 
supplement capable of supporting animal growth performance. 
 
4.3.2. Feed Intake 
 
The daily dry matter and nutrient intake of sheep fed natural pasture and desho grass hay, with 
concentrate supplementation are presented in Table 13. The experimental sheep placed on  the 
treatment diets containing 100% (T5), 75% (T4), 50% (T3) and 25% (T2) desho grass hay 
consumed 22.13, 18.9, 9.06, and 7.06%, respectively, higher than the amonts consumed by the 
groups placed on 100% natural pasture hay (T1). This result indicates that desho grass hay is 
superior in nutritive value to natural pasture hay. The results obtained also indicated that an 
increase in level of inclusion of desho grass hay in the basal diet resulted in significant (P<0.05) 
and proportional increase in the total basal DM intake of sheep. There was significant (P<0.05) 
and proportional increase in total daily DM intake of the experimenta sheep. The highest daily 
DM intake was obtained from the group fed on T5 (0% desh grass hay plus 100% desho grass). 
The total DM intake as percent of body weight of the experimental sheep was 3% while intake 
per metabolic body weight of experimental sheep varied from 61 to 64 % although the results 
were not statistically significant (P>0.05). The daily nutrient intakes of experimental sheep 
followed the same trend as that of total DM intake.   
 
The total DM intake of sheep in the current study was comparable to results of Awoke (2015) for 
the same breed of sheep fed hay as a basal diet and supplemented with F.sycomorous leaf, fruit 
and their mixtures. However, the total DM intake was lower than the reports of Yilkal et al. 
62 
 
(2014) for the same breed of sheep fed natural pasture hay supplemented with processed lupin 
grain (Lupinus albus).The high intake of desho grass hay is in agreement with the reports of 
FAO (2010) which described that the grass was highly palatable for cattle and sheep feeding. 
The total DM intake noted in this study was comparable to the range of values of 666-788 g/day 
reported for Farta sheep fed hay supplemented with wheat bran, noug seed cake and their 
mixtures (Fentie and Solomon, 2008). The mean total DM intake of sheep in the current study 
-1 0.75 
was 58.08 kg  W which was comparable to the results of other workers (Bonsi et al., 1996; 
Mulat et al., 2011) who reported total DM intake of sheep within the range of 58.6-82.2 g DM 
-1 0.75
kg  W . The total DM intake expressed as percent of body weight obtained from the current 
study is in agreement with that of Getu et al. (2012) the value of which is in the range of the 
recommended dry matter intake of ruminants (2-6%) by ARC (1980). 
 
Table 13. Daily dry matter and nutrient intake of Washera sheep fed natural pasture and desho 
grass hay basal diet, supplemented with mixture of noug seed cake and wheat bran in 50:50 ratio. 
 
 Parameters  Treatments 
T1 T2 T3 T4 T5 SEM SL 
c bc b a a
Basal DM intake (g/day) 350.23 374.99  381.95  416.44  427.75  6.31 *** 
CM DM intake (g/day) 300.00 300.0 300.0 300.0 300.0 0.00 Ns 
c bc b a a
Total DM intake (g/day) 650.23  674.99  681.95  716.44  727.75  6.31 *** 
DM intake (% BW) 3 3 3 3 3 0 Ns 
0.75
DM intake per  kg W  61 61 62 63 64 1.5 Ns 
c bc b a a
OM  intake (g/day) 583.94  605.28  608.95  640.82  649.88  5.57 *** 
d c b a a
CP intake (g/day)  72.56  76.73  79.38 82.14  82.67  0.24 *** 
b b b a a
NDF  intake (g/day)   324.96  334.57  334.57  355.81  357.21  3.91 *** 
b b b b a
ADF  intake (g/day) 204.37  206.69  208.68  209.33  217.62  2.49 *** 
c b b a a
ME (MJ/Kg DM) 6.04  6.76  7.10  7.88  8.22  0.16 *** 
a, b, c
=means within rows having different superscript are significantly different at***= (P<0.05); 
ADF=acid detergent fiber; BW= body weight; CM=concentrate mixture; CP=crude protein; NDF=neutral 
detergent fiber; OM=organic matter; SEM=standard error mean; SL=significant level. 
 
The OM, CP, NDF, ADF and ADL intakes followed the same trend as that of the daily DM 
intake and showed significant (P<0.05) difference between the treatments. The general tendency 
63 
 
is that there is increase in the consumption of each nutrient with increased level of inclusion of 
desho grass in the basal ration. Abebe (2008) reported similar feed intake to that of the current 
study with supplementation of Sesbania sesban at 30% of the ration (0.98% of body weight) 
which improved total feed intake and digestibility, growth rate and the overall reproductive 
performance of sheep. The estimated ME (MJ/Kg DM) intake was significant (P<0.05) among as 
the level of desho grass increased from 0 to 75% but 75 % and 100 % desho grass fed animals 
showed non-significant (P>0.05).  
 
The lowest energy density at which the sheep do not lose weight is between 8 and 10 MJ ME/kg 
DM and the minimum protein level required for maintenance is about 8% CP in the DM, and the 
most productive animals such as rapidly growing lambs and lactating ewes need about 11% CP 
(McDonald et al., 2010). These energy and protein levels are considerably higher than the 
average values in natural pastures and crop residues. Hence, the ME of desho grass hay in this 
experiment satisfies the maintenance requirements of lambs as stated in McDonald et al (2010). 
 The increase in ME intake might be associated with organic matter in desho grass similarly to 
the other nutrients. Studies in other countries indicated that supplementation of desho hay with 
cottonseed meal increased intake and digestibility, attributed to greater stimulation of rumen 
flora as a result of increased availability of energy and nitrogen-providing nutrients (Nianogo et 
al., 1997). 
 
4.3.4. Dry matter and nutrient digestibility 
 
The apparent digestibility coefficients of nutrients by Washera sheep fed on different 
combinations of natural pasture and desho grass hays basal diet with supplementary concentrate 
are shown in Table 14. The result indicated that the digestion coefficients of all parameters (DM, 
OM, CP, NDF and ADF) were significantly different (P<0.05) in treatment groups and in the 
order of T5>T4>T3>T2>T1. The dry and organic matter digestibility coefficient of desho grass 
reported in the current study were higher than the digestibility of most tropical grasses (54%) 
(Minson, 1990) and OM digestibility reported for the same species from other countries (66%0 
(Bougouma-Yaméogo, 1995). The apparent digestibility of all the nutrients including DM 
attained by the treatment groups fed on the treatment containing pure (100%) natural pasture hay 
64 
 
were significantly (P<0.05) lower than all the others, followed by the group fed on the treatment 
containing 25-50% desho grass indicating the better nutritive value of desho grass than the 
natural pasture used in this study. 
 
Table 14. Apparent digestibility coefficients of nutrients by Washera sheep fed natural pasture 
and desho grass hays basal diet supplemented with mixture of noug seed cake and wheat bran. 
 
 
Parameters T1 T2 T3 T4 T5 SEM    SL 
d c bc ab a  
DM 0.61  0.68  0.71  0.76 0.79  0.01 * 
 
d c bc ab a
OM 0.66  0.71  0.74  0.78  0.81  0.01 * 
 
c b ab a a
CP 0.72  0.76  0.79  0.81  0.82  0.01 *  
d cd bc ab a
NDF 0.66  0.71  0.74  0.79  0.81  0.01 *  
 
c c b a a
ADF 0.65  0.67  0.71  0.76  0.78  0.01 * 
 
a b c
: Means in the same row having different superscript are significantly different; DM=Dry matter; 
OM=Organic matter; CP=crude protein; NDF=neutral detergent fiber; ADF=acid detergent fiber; 
ADG=average daily body weight gain;***( P<0.05); SEM= standard error of means; SL= 
significance level. 
 
The apparent digestibility obtained from the group fed on 75-100% desho grass were 
significantly (P<0.05) higher than the others (with few exception) the results of which further 
confirm the better nutritive value of desho grass than the natural pasture used in the current 
study. The better apparent digestibility of desho grass might be due to relatively higher CP 
content of desho grass hay as compared to natural pasture hay. The higher protein content might 
have increased the digestibility of the crude fiber of the feeds. If the protein rich feeds are added 
to balance low protein roughages, there will be increase in the population of the microorganism 
and the resulting rate fermentation of the crude fiber component (Ranjihan, 1997).  
 
Earlier workers (Moore and Mott, 1972; Mugerta et al., 1973) showed that a digestibility 
coefficient of above 65% indicates good nutritive value and that below this level intake is limited 
by low digestibility. Evidence indicated that the digestibility of OM might be as high as 85% in 
young pasture grass and as low as 45% in winter herbage (McDoland et al., 2010). The 
digestibility of OM and CP in the current study is well above 65% indicating that the three diets 
used in this study were of good feeding value (Moore and Mott, 1972; Mugerta et al., 1973). 
65 
 
McDonald et al. (2010) remarked that concentrate feed which is rich in protein content promotes 
high microbial population which in turn facilitates rumen fermentation.   
 
4.3.3. Body weight change and feed conversion efficiency 
 
The mean body weight gain and feed conversion efficiency data recorded from the feeding trial 
are presented in Table 15. The mean daily weight gain of treatment groups significantly and 
proportionally increased (P<0.05) with the increased level of inclusion of desho grass hay in the 
basal diet. However, final body weight and feed conversion efficiency (FCE) were not 
statistically significant (P>0.05).  
 
Table 15. Body weight parameters and feed conversion efficiency of Washera sheep fed on 
natural pasture hay and desho grass hay mixture and supplemented with noug seed cake and 
wheat bran in 50:50 ratio. 
 
Parameters  T1 T2 T3 T4 T5 SEM SL 
Initial BW (kg) 19.5 19.1 19.0 18.9 18.3 0.9 Ns 
Final BW (kg) 23.6 24.5 24.6 25.7 25.8 0.8 Ns 
b ab ab a a
ADG (g/d/h) 52.2  59.9  70.0  74.4  76.4  4.9 *** 
FCE 0.08 0.09 0.10 0.10 0.11 0.0 Ns 
a, b, c
=means within rows having different superscript are significantly different at P<0.05; BW=body 
weight; ADG=Average Daily gain; FCE=Feed Converstion effciecy; SEM=standard error of means; 
SL=significance level;ns=nonsignificant. 
 
 
The mean daily body weight gain (74.4-76.4 g/d/h) brought by the groups fed on the basal diet 
containing 75-100% desho grass was significantly higher (P<0.05) than all others. On the 
contrary, there was no significant difference betweent the treatment groups fed on the diets 
containing 0-50% desho grass in the mean daily body weight gain (P>0.05). The improved feed 
conversion efficiency although non-significant (P>0.05), in the current result may presumably be 
due to higher nutrient concentration of the basal diet due to the increment of level of desho grass. 
Owing to the total increment of CP intake from T1 to T5, insignificant but body weight 
66 
 
increment was observed in the current study which is in line with previous results (Getnet, 2007, 
Getu et al., 2012).  
 
Mean daily body weight gain of sheep obtained from this study was higher than the results of 
Simachew (2009) who reported that the mean daily gain of Washera sheep fed natural pasture 
hay supplemented with maize bran, noug seed meal and their mixtures ranged between 38.9 and 
55.6 g/day. The ADG and FCE of sheep in the current result is comparable to the reports of 
Anteneh et al (2015) for Washera sheep fed natural pasture hay and supplemented with 
concentrate mixture and sugar cake tops. On the other side, the results of the current study was 
comparable to the results of Tiyoel et al. (1987) who reported 72.75 g/day from Horro sheep fed 
on natural grass hay basal diet supplemented with concentrate (300g/d DM). The general trends 
in body weight changes of Washera sheep fed on the combination of natural pasture with 
supplementation of concentrate mixture is shown in Fig. 5. As the figure illustrates, body weight 
of experimental sheep in the current study continued in an increasing trend throughout the 
experimental period. 
 
30
25
20
15
10
5
0
1 2 3 4 5 6 7 8 9 10
Weeks
T1 T2 T3 T4 T5
 
Figure 5. Trends in body weight changes of Washera sheep fed natural pasture and desho grass 
hay and supplemented with mixture of noug seed cake and wheat bran. 
 
The study illustrates that supplementation of desho grass improves performance of animals. This 
statement supported by the result of Nianogo et al. (1997) who reported that the nutritive value 
67 
 
Body Weight (Kg) 
of desho grass is low especially hay is low and cannot support the maintenance requirements of 
adult rams of 17-25 kg, but supplementation with nitrogen and energy improves performance 
(Zoundi et al., 2002). The current result is supported  by the work of  Fluharty and McClure 
(1996) who indicated that lambs fed high protein ration (ad libitum) had greater DM intakes, 
mean daily weight gain, feed conversion efficiency within shorter period of feeding  compared to 
those fed  diets with normal protein concentrates (85% ad libitum). Generally, the current result 
is in agreement with Wude et al. (2012) who recommended supplementary level of 300 g/day 
DM concentrate for sheep fed crop residue as a basal diet.  
 
4.3.5. Correlation between nutrients intake, digestibility and daily body weight gain of 
Washera sheep  
 
The correlation between nutrient intake and digestibility of the current study is shown in Table 
16. Dry matter intake and digestibility were positively correlated (P<0.05) with CP, OM, NDF 
and ADF intake and digestibility and with each other. This result is in agreement with previous 
results by Fentie and Solomon (2008). The DMI and DMD were positively correlated with mean 
body weight gain and the organic matter intake was positively correlated with CP, NDF, ADF 
digestibility except ADF intake which was not significantly (P>0.05) correlated with ADG. 
 
The result of the correlation analysis indicated that daily body weight gain was positively 
(P<0.05) correlated with DM, OM, CP, NDF, and ADF intake and digestibility which is in 
agreement with previous results obtained from the feeding trial conducted with Washera sheep 
(Abebe et al., 2011; Assefu, 2012; Yeshambel et al., 2012; Awoke, 2015) and Farta breed of 
sheep (Fentie and Solomon, 2008; Bimrew et al., 2010) in northwestern Ethiopia. The improved 
averagely daily gain for increased desho grass proportion in the total diet of sheep may 
presumably be due to higher nutrient concentration and nutrient digestibility which increased the 
body weight of sheep.  As many research results made the fact evident thus far, the effect of increased 
digestibility on improving feed intake depends on the quality of roughage feed used. The correlation 
analysis result indicated that inclusion of desho grass hay as basal diet in small ruminant feeding 
is a promising feed in terms of nutrient utilization and animal performance.   
 
68 
 
Table 16. Correlation between nutrient intake, digestibility and body weight gain in Washera 
sheep fed natural pasture and desho grass hay supplemented with noug seed cake and wheat bran 
mixture.  
 
DMI DMD OMI OMD CPI CPD NDFI NDFD ADFI ADFD ADG 
** *** *** *** *** *** *** *** *** *
DMI 1.00 0.95 0.99  0.94  0.91  0.90  0.93  0.94  0.61  0.91  0.62*
* *
 
*** *** *** *** *** *** *** *** ***
DMD     0.91  0.99  0.91  0.98  0.93  0.94  0.61  0.89  0.64  
1.00 
*** *** *** *** *** *** **
OMI   1.00 0.91  0.87  0.85  0.96  0.91*** 0.68  0.87  0.57  
*** *** *** *** * *** **
OMD    1.00 0.90  0.98  0.81  0.99  0.39  0.93  0.61  
*** *** *** ** *** ***
CPI     1.00 0.91  0.84  0.91  0.55  0.86  0.68  
*** *** ns *** **
CPD      1.00 0.77  0.98  0.38  0.92  0.61  
*** *** *** *
NDFI       1.00 0.83  0.81  0.84  0.53  
* *** **
NDF         1.00 0.43  0.94  0.61  
D 
** ns
ADFI           1.00 0.52  0.25  
**
ADF          1.00 0.56  
D 
ADG             1.00 
*** Significant at P<0.001;** significant at P<0.01; * significant at P<0.05; ns=non-significant.DMI= dry matter 
intake; DMD=dry matter digestibility; OMI=organic matter intake; OMD=organic matter digestibility; CPI= crude 
protein intake; CPD= crude protein intake; NDFI= neutral detergent fiber; NDFD= neutral detergent fiber 
digestibility; ADFI=acid detergent fiber intake; ADFD= acid detergent fiber digestibility; ADG=Average daily gain. 
69 
 
5. CONCLUSION AND RECOMMENDATION 
 
5.1.Conclusion 
 
The most important factors affecting desho grass utilization were availability of feed, training 
and experience in production of desho grass. Results of the study indicated that the major 
production strategy of desho grass was backyard, although there are stock exclusion and soil 
bunds systems. Farmers, who have received training in desho grass production, tend to use it to a 
lesser extent as a feed instead they use it for other roles like land management practice. The grass 
was used mainly for animal feed (60%) in both districts (highland areas tend to use desho grass 
more than those in the midland area). Due to poor accessibility to feeds in the highlands, 
vulnerability of soil towards erosion, high density of livestock per household, desho grass might 
have a higher potential to be utilized as fodder and for soil conservation in the highland areas. 
Training on the use of desho grass is important to promote desho grass production as an avenue 
to generate income and for soil conservation in addition to animal fodder.  
 
Desho grass is multipurpose fodder used for soil water conservation, animal fodder and means of 
income for smallholder farmers in Ethiopia. Among the most important merits of desho grass is 
its ability to adapt both mid and high altitude, thrives well on different soil types (clay to red 
soils) areas of Ethiopia. The grass has potential to produce large amount of biomass per unit area, 
suitable to different forage production strategies (backyard, stock exclusion areas and soil 
bunds), acceptable to different livestock species and increases productivity of livestock. Hence, 
the grass has much untapped potential for smallholder crop livestock production systems and 
future commercial oriented animal production in Ethiopia 
 
The morphological and nutritional qualities of desho grass were highly affected by harvesting 
day than altitude. The grass well performed both in mid and altitude areas of Ethiopia provided 
appropriate management is applied. Generally, harvesting of desho grass from 90 to 120 days is 
recommendable since it has shown good result for yield and quality of the grass. As desho grass 
has high biomass yield and good chemical composition, it can be concluded that it has a potential 
to be an alternative ruminant feed in mid and highlands of Ethiopia. The results of animal 
70 
 
evaluation study indicated that desho grass hay had better chemical composition particularly in 
crude protein (CP) content, higher intake and palatability by sheep than a mixed sward natural 
pasture hay. Moreover, increasing the proportion of desho grass hay from 0 to 100% as a basal 
diet of Washera lambs increased the DM intake, digestibility of nutrients, body weight and feed 
conversion efficiency, with overall better performance at the high level of feeding of the grass. 
Overall, the series of experiments conducted in this study revealed that desho grass has 
multifaceted role for the smallholder farmers in terms of animal fodder, soil and water 
conservation, and income source.  
 
The grass can perform well both in the mid and high land areas of the country provided 
appropriate management practices are followed. Harvesting date had effect on plant 
characteristics and chemical composition as well as yield like other types of grasses. The animal 
evaluation study also showed that desho grass can be an alternative feed for growing local sheep 
in Ethiopia. 
 
5.2. Recommendations 
 
Based on the current work, the following recommendations and future desho grass research and 
development priorities are highlighted. 
 More extension work should be done on the production and utilization of desho grass to 
integrate it in the farming systems of mid and highland areas of Ethiopia. 
 The agronomic trial should be conducted in successive years and different agro-
ecological conditions. 
 The response of desho grass to different manure levels and fertilizer rates should be 
investigated to recommend an optimum production package of the grass.  
 As desho grass has relatively low CP, the grass should be combined with local protein 
sources such as indigenous and improved leguminous fodders, agro-industrial and 
breweries byproducts as supplements and tested on different types of animals.  
 Further study on economical feasibility of inclusion of desho grass in sheep diet must be 
investigated. 
 Agronomic and animal evaluation of desho grass under on-farm condition is worthwhile. 
71 
 
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90 
 
 
 
 
 
 
 
 
 
 
 
 
 
7. APPENDICES
91 
 
7.1. List of Publications 
       The following papers were prepared from the dissertation research: 
1. Bimrew Asmare, Solomon Demeke, Taye Tolemariam, Firew Tegegne, Jane Wamatu 
and Barbara Rischkowsky, 2016. Evaluation of desho grass (Pennisetum pedicellatum) 
hay as a basal diet for growing local sheep in Ethiopia. Tropical Animal Health. 48 (4): 
801-806. 
2. Bimrew Asmare, Solomon Demeke, Taye Tolemariam, Firew Tegegne, Jane Wamatu 
and Barbara Rischkowsky, 2016. Determinants of the utilization of desho grass 
(Pennisetum pedicellatum) by farmers in Ethiopia. Tropical Grasslands: 4(2): 112–121.  
3. Bimrew Asmare, Solomon Demeke, Taye Tolemariam, Firew Tegegne and Jane 
Wumatu, 2016. Effects of altitude and harvesting days on morphological characteristics, 
yield and nutritive value  of desho grass (Pennisetum pedicellatum)(Under review in the  
Agriculture and Natural Resources Journal)  
92 
 
7.2. List of Appendix Tables  
Table 1. Summary of ANOVA for plant morphological characteristics and number of re-growth 
days of desho grass as affected by altitude 
 
Parameters DF MS F Value Pr > F SL 
PH    16 206.86 0.60 0.45 ns 
NTPP     16 14.72 0.17 0.69 ns 
NLPP     16 6.72 0.00 0.95 ns 
LLPP     16 231.41 5.15 0.04 *** 
LSR     16 0.00 0.04 0.84 ns 
RGD    16 22.22 4.36 0.05 *** 
 
Table 2. Summary of ANOVA for plant morphological characteristics and number of re-growth 
days of desho grass as affected by days in the midland and highlands 
 
 Mid altitude  High altitude 
Parameters DF MS F Pr > F SL MS F Pr > F SL 
Value Value 
PH  6 1016.88 5.28 0.0476 *** 1016.88 5.28 0.0476 *** 
NTPP   6 497.66 18.40 0.0028 *** 497.66 18.40 0.0028 *** 
NLPP   6 5440.33 2.78 0.1399 *** 5440.33 2.78 0.1399 *** 
LLPP   6 131.25 4.99 0.0530 *** 131.25 4.99 0.0530 *** 
LSR   6 0.16 7.22 0.0253 *** 0.16   7.22 0.0253 *** 
RGD  6 16.44 5.92 0.0380 *** 16.44 5.92 0.0380 *** 
93 
 
Table 3. Summary of ANOVA for plant morphological characteristics and number of re-growth 
days of desho grass as affected by the interaction of harvesting days and altitudes 
 
Parameters DF MS F Value Pr > F SL 
PH 16 1388.47 5.11 0.04 *** 
NTPP  16 217.99 2.89 0.12 ns 
NLPP  16 5504.00 4.12 0.06 *** 
LLPP  16 7.80 0.13 0.72 ns 
LSR  16 0.33 11.06 0.00 *** 
RGD 16 56.33 19.00 0.00 *** 
 
Table 4.  The effect of altitude on chemical composition and yield of desho grass  
 
Parameters DF MS F Value Pr > F SL 
DM 16 28.55 5.55 0.03 *** 
DMY  16 22.13 0.97 0.34 ns 
OM 16 39.90 7.77 0.01 *** 
CP 16 10.07 6.26 0.02 *** 
CPY 16 1.11 11.87 0.00 *** 
NDF 16 26.79 2.73 0.12 ns 
ADF 16 26.11 3.72 0.07 *** 
ADL 16 0.28 0.17 0.69 ns 
IVOMD 16 13.71 0.44 0.52 ns 
ME  16 0.05 0.05 0.82 ns 
Ca  16 1.21 2.20 0.16 *** 
P 16 1.29 7.97 0.01 *** 
94 
 
Table 5. The effect of harvesting dates on chemical composition and yield of desho grass in mid 
altitude area. 
  
Parameters DF MS F Value Pr > F SL 
DM 6 1.90 0.50 0.63 ns 
DMY  6 52.72 2.87 0.13 ns 
OM 6 12.29 10.44 0.01 *** 
CP 6 2.07 2.28 0.18 ns 
CPY 6 0.11 0.88 0.46 ns 
NDF 6 3.01 0.57 0.59 ns 
ADF 6 12.32 5.11 0.05 ns 
ADL 6 1.72 1.96 0.22 ns 
IVOMD 6 75.80 2.97 0.13 ns 
ME  6 2.61 3.66 0.09 ns 
Ca  6 1.76 10.66 0.01 *** 
P 6 0.30 6.20 0.03 *** 
 
Table 6. The effect of harvesting dates on chemical composition and yield of desho grass in high 
altitude area. 
Parameters DF MS F Value Pr > F SL 
DM 6 1.90 0.50 0.63 ns 
DMY  6 52.72 2.87 0.13 ns 
OM 6 12.29 10.44 0.01 *** 
CP 6 2.07 2.28 0.18 *** 
CPY 6 0.11 0.88 0.88 ns 
NDF 6 3.01 0.57 0.59 *** 
ADF 6 12.32 5.11 0.05 ns 
ADL 6 1.72 1.96 0.22 ns 
IVOMD 6 75.80 2.97 0.13 ns 
ME  6 2.61 3.66 0.09 ns 
Ca  6 1.76 10.66 0.01 *** 
P 6 0.30 6.20 0.03 *** 
95 
 
Table 7. The effect of harvesting dates on chemical composition and yield of desho grass in high 
altitude area. 
Parameters DF MS F Value Pr > F SL 
DM 16 3.66 0.97 0.41 ns 
DMY  16 0.63 0.06 0.94 ns 
OM 16 27.70 16.37 0.00 *** 
CP 16 3.29 3.68 0.06 ns 
CPY 16 0.02 0.18 0.84 ns 
NDF 16 14.50 3.49 0.06 *** 
ADF 16 0.91 0.27 0.77 ns 
ADL 16 0.09 0.05 0.95 ns 
IVOMD 16 91.58 3.73 0.05 ns 
ME  16 2.61 3.80 0.05 ns 
Ca  16 0.24 0.84 0.15 ns 
P 16 0.88 14.39 0.00 *** 
 
Table 8. Summary of ANOVA for the dry matter and nutrient intake of Washera sheep fed 
natural pasture and desho grass hay supplemented with noug seed cake and wheat bran mixture 
in 50:50 ratio. 
 
Parameters DF MS F Value Pr > F SL 
Basal DMI (g DM/day) 20 4795.71 24.08 <.0001 *** 
Con DMI (g DM/day) 20 0.00 . . ns 
TDMI (g DM/day) 20 4795.90 24.08 <.0001 *** 
OMI (g /DM/day) 20 3563.79 22.94 <.0001 *** 
CPI (g /DM/day) 20 64.52 255.45 <.0001 *** 
NDFI (g /DM/day) 20 1160.94 16.36 <.0001 *** 
ADFI (g /DM/day) 20 648.65 68.63 <.0001 *** 
ADL (g /DM/day) 20 130.95 5.89 0.0027 *** 
ME (MJ/Kg DM) 20 3.82 31.27 <.0001 *** 
 
96 
 
Table 9. Summary of ANOVA for nutrient digestibility of Washera sheep fed natural pasture 
and desho grass hay supplemented with noug seed cake and wheat bran mixture in 50:50 ratio. 
 
Parameters DF M S F Value Pr > F SL 
         DM 20 0.02 20.73     <.0001 *** 
         OM 20 0.02 21.65     <.0001 *** 
         CP 20 0.01 18.10    <.0001 *** 
         NDF 20 0.02 20.28     <.0001 *** 
         ADF 20 0.01 40.19     <.0001 *** 
 
Table 10. Summary of ANOVA for body weight parameters of Washera sheep fed natural 
pasture and desho grass hay supplemented with noug seed cake and wheat bran in 50:50 ratio. 
 
Parameters DF MS F value Pr > F SL 
IBW 20 0.55 0.13 0.9676 ns 
FBW 20 2.23 0.58 0.6781 ns 
ADG 20 211.78 2.28 0.0966 *** 
FCE 20 0.00 0.48 0.7470 ns 
  
97 
 
7.3. Questionnaire  
 
Questionnaire for “Assessment of desho grass (Pennisetum pedicellatum) production and 
utilization in Burie Zuria and Doyogena districts of Ethiopia”   
The information obtained from this interview questionnaire will be used  only  for  academic  
purpose  and  the  personal  information  will  be  kept  confidential.   
I, therefore, kindly request you to feel free in answering the questionnaire.    
Thank You 
Name of the Enumerator ------------------------------------------------------Signature --------------- 
Date------------------------------------------------------ 
1. Personal information 
1.1 Date of interview ----------------------------------------------         
1.2. Region ---------------------------------------- 
1.3. Zone -----------------------------------------------      
1.4. Districts ----------------------------------------  
1.5. Kebele---------------------------------------------------------------------  
1.6. Name of farmer -----------------------------------    
1.7. Sex of HH ---------------------------------------------------------------------------  
1.8. Age (yrs) of HH -------------------------------------------------------------------------  
1.9. How many family members do you have?  
a. Male ----------------------------------------------------------  
b. Female ---------------------------------------------------------  
c. Children (≤14 years) --------------------------------------------------  
d. Adult (≥18-60 years) -------------------------------------------------------  
e. Dependants (>60years) ----------------------------------------------------------  
1.10. Religion: a. Orthodox Christian b. Muslim   c. Protestant d. Catholic      
1.11. Marital status of the household:  a. Married     b. Single c. Divorced    d. Widowed  
98 
 
2.  Socioeconomic Characteristics  
2.1.   Family member’s age, sex and educational status  
Age Sex Educational Status 
Male   Female  0 1-4 5-8 9-10 Certificate  Diploma  University     
0-5 years          
6-14 years          
15-25 years          
25-35 years          
36-45 years          
46-65 years          
>65 years          
 
2.2. Educational status the of household head                
 a. Cannot read & write   b. Read & write (1 - 4)   c. Elementary School (5 - 8)      
d. Secondary School (9 - 10) e. High School (11 - 12)   f. Certificate and above   
2.3. Number of active workers in the family including household head    
 a. one   b. two     c. three     d. four     e. more than four  
2.4. What is your major occupation?    a. Farming       b. Trading      
  c. Governments employ     d. Laborer       e. other (specify) --------------   
2.5. In which income group do you locate yourself in the community?  
a. High income group    b. Middle income group      c. Low income group 
2.6. Do you have farm land? a. Yes   b. No  
2.7. If no, specify your job--------------------------------------------------------------------------- 
2.8. If yes, specify the number and size of the plot ----------------------&-----------------------hectare 
2.9. Land holding and land use system  
a. Total area of land owned by the household (ha) ---------------------------------- 
b. Food crop production (ha) ----------------------------------  
c. Improved forages grown in natural resource conservation areas (ha) --------------------- 
d. Grazing land (ha) ---------------------------------- 
e. Fallow land (ha) ------------------------------------ 
99 
 
f. Forage production (ha) ----------------------------------  
g. Fodders grown in the soil conservation areas (ha) -------------------------------------------  
h. Rented/contracted land (ha) ----------------------------------------------  
i. Other (specify) ------------------------------------------------ 
 
3. Livestock Production  
3.1. Do you have farm animals /livestock?   a. Yes     b. No 
3.2. If yes, state the type and quantity.      
Cattle herd structures 
Types of animal Number of animals 
Local  Cross  Total  
Milking cows     
Dry cows     
Oxen     
Calves male     
Calves female     
Heifers     
Bulls    
 
Sheep and goats 
Type of Number of animals 
animals   Local  Cross  Total  
Ewe     
Ram     
Lamb     
Does     
Bucks     
Kids    
100 
 
Equine 
Type of animal  Total 
Horse   
Mule   
Donkey   
Poultry 
Types of Number of animal 
animal Local  Cross  Total  
Hen     
Cock     
Cheek    
 
3. 3. Why do you keep the livestock? In order of rank. 
        a. traction   b. milk Production   c. traction and milk                                
        d. savings   e. other (specify) --------------- 
 
4. Improved forage production and their utilization   
4.1. What are the improved forage development strategies you practice?  
a. backyard forage development   b. under sowing of cereal crops with forage legumes 
c. grazing on sown-mixed pasture   d. forage strips on bunds  
e. forage seed production and collection 
4.2. How do you improved forage production feed your animals?  
  a. Indoor feeding (confined in a house) using individual feeding system  
  b. In a collection yard using group feeding  
  c. Let to graze in a grazing land (grazing in an improved forage pasture land, natural  
  d. Other (specify) -------------------------------------------------------------------------------------- 
4.3. Do you have access to improved forage production land?  a. Yes          b. No  
4.4. If yes, is it communal or private? --------------------------------------------------------------------- 
4.5. What is the size of your improved forage production land? ----------------------------------ha  
4.6. What are the major strategies you follow to solve this improved forage grow shortage?  
---------------------------------------------------------------------------------------------------------------- 
101 
 
4.7. What types of improved forage grow? 
 
Improved forag Months 
e types                st nd rd th 
1 2  3 4
Sep Oct Nov Dec Jan Feb Mar Apr May Jun Jul Aug 
 
             
             
             
             
             
 
4.8. Is the grazing resource adequate to your animals?  
          a. Yes                b. No  
4.9. What are/is the major feed for your livestock during dry season? 
a. grazing and browsing  b. crop residues   c. improved forages   d. local breweries 
byproducts 
4.10. What are/is the major feed for your livestock during wet season? 
a. grazing and browsing  b. crop residues   c. improved forages   d. local breweries 
byproducts 
4.11. Do you face feed shortage for your livestock? a. yes    b. no 
4.12. If yes, what measures do you take to alleviate problems of feed shortage?  
          a. Purchase concentrates                       b. Purchase forage (rent grazing land)                                      
          c. Purchase crop residues                      d. Reduction of stock                                                                
          e. Other (specify) --------------------  
4.13. At which season do you face feed shortages?  
        a. Short rainy season (sept-Nov)       b. Long rainy season (June-Aug)                                                                
        c. Short dry season (Dec-Jan)            d. Long dry season (Feb-Apri) 
 
 
102 
 
5. Desho grass production and utilization 
5.1. Desho grass production and management 
5.1.1. When did you start planting desho grass?(year)________________________ 
a. 1 year   b. 2 years    c. 3 years     d. 4 years   e. 5 years  f. 10 years   g. 15 year and above  
5.1.2. What is the source of desho grass planting material? ______________________________ 
5.1.3. How do you plant desho grass? ______________________________ 
5.1.4.  From the total land you have, how much area is covered by desho grass?_______(local 
unit) 
5.1.5. When do you plant desho grass? ________________________________(Month) 
5.1.6. Do you use irrigation for desho grass production?   a. yes               b. no 
5.1.7. If your answer is yes for the above question, is irrigation economically to use for desho 
production? a. yes      b. no     c. I don’t have information 
5.1.8. Do you apply fertilizer on your desho grass?   a. yes      b. no     c. I don’t have 
information. 
5.1.9. If your answer is yes for the above question, what kind of fertilizer you apply on desho 
grass?  a. DAP   b. Urea    c. Manure    d. depends on availability 
5.1.10. Do you practice weeding desho grass?  a. yes     b. no     c. I don’t have information. 
5.1.11. When do you harvest desho grass? ________________________________(Month) 
5.1.12. How much is the production of desho grass biomass per unit area?(local units per unit 
area)____________________________________________________________________
______________________________________________________________________ 
5.1.13.  Where do you plant desho grass? 
 a. Backyard   b. Soil bund   c. Road side     d. stock exclusion    e. Other 
(specify)__________________________________________ 
 
5.2. Desho grass utilization  
5.2.1. For what purpose you use desho grass primarily? 
a. Animal feed    b. To earn money     c. Soil conservation    d. Other  (specify)___________ 
5.2.2. For what other purposes you use desho grass? 
a. Animal feed   b. To earn money     c. Soil conservation    d. Other 
(specify)_____________ 
103 
 
5.2.3. If you are using desho grass for animal feed for which species do you feed? 
a. Cattle     b. Sheep and goat    c. Equine    d. Other 
(specify)___________________________________________ 
5.2.4. If you are feeding desho grass for lactating cows, what is the unique advantage of desho 
grass these groups? 
 
5.2.5. In what form are you feeding desho for your animals? 
a. Cut and carry     b. Hay     c. Silage      d. Other 
(specify)___________________________________________ 
5.2.6. What is the role of desho grass for animal? a. Basal diet b. Supplement c. both 
5.2.7.If you are not feeding desho grass for your animals but you have planted it, what is the 
reason not  
feeding?_________________________________________________________________
________________________________________________________________________
________________________________________________________________________ 
5.2.8. If you are earning money by selling desho grass, in what form are you selling? 
a. Planting material/seedling   b. Fresh cut grass     c. Hay     d. Other 
(specify)___________________________________________ 
5.2.9. What are the special features of desho grass over others grass species you planted? 
________________________________________________________________________ 
5.2.10. From animal feed aspect, please describe the special characteristics of desho grass. 
__________________________________________________________________ 
5.2.11. What are the merits of desho grass in terms of biomass productivity? 
_______________________________________________________________________ 
5.2.12. Have you got training on production and utilization of desho grass?  a. yes   b. No  
5.2.13.  If your answer is yes, please describe the topic of training and the organization offered 
the training. 
_________________________________________________________________________  
5.2.14.  List any demerits of desho grass in terms of production, utilization and feeding. 
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a. What are (is) the problems associated with desho grass 
production?______________________________________________________________ 
_____________________________________________________________ 
b. What are (is) the utilization constraints of desho 
grass?___________________________________________________________________ 
__________________________________________________________ 
5.2.15. What are (is) the feeding problems of desho 
grass?___________________________________________________________________ 
5.2.16. Do you require training or support in terms of desho grass? a. Yes   b. No 
5.2.17.  If your answer is yes, in what areas you need training?  a. Production of desho grass    
   b. Desho grass utilization   c.  Feeding management of desho grass   d. other (specify) 
_______________________________________________________________________ 
5.2.18. Please describe the general comments to increase the production and utilization of desho 
grass in your area?______________________________________________ 
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7.4. Some Photos  
Desho grass utilization 
 
 
Land preparation and planting 
 
 
 
 
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Data collection 
 
 
  
107 
 
  
   
   
108