Bioprotectants to keep foods safe from aflatoxin Bioprotectants to keep foods safe from aflatoxin 
contamination contamination
Development and scale-up of 
bioprotectants to keep staple foods safe 
from aflatoxin contamination in Africa
Ranajit Bandyopadhyay, Alejandro Ortega-Beltran, Matieyedou Konlambigue, 
Lawrence Kaptoge and Titilayo D. O. Falade, International Institute of Tropical Agriculture, 
Nigeria; and Peter J. Cotty, Ocean University of China, China
 1 Introduction
 2 Aspergillus biology and aflatoxin epidemiology
 3 Aflatoxin management options
 4 Biocontrol product development and the registration process in Africa
 5 Manufacturing development
 6 Barriers preventing adoption and how to overcome them
 7 Scaling up aflatoxin biocontrol technology
 8 Current challenges and needs
 9 Some final thoughts
 10 Conclusion
 11 Where to look for further information
 12 Acknowledgment
 13 References
1  Introduction
Recent decades have seen a transformation in agriculture in response to 
multiple challenges and opportunities. These include increasing demand 
for food/feed for an ever-growing population and raw materials for diverse 
industries, the dynamics of climate change and technological advances, 
among many other factors. Agricultural production has increased dramatically 
in most parts of the world. However, improvements in the safety of plant and 
animal products have not kept pace with production. Foodborne pathogens 
and contaminants cause a large burden of disease globally. It is estimated that 
foodborne diseases account for 600 million cases and 420 000 deaths each 
year. Children under 5 years of age account for 30% of all foodborne deaths.
http://dx.doi.org/10.19103/AS.2021.0093.16
© The Authors 2022. This is an open access chapter distributed under a Creative Commons Attribution 4.0 License (CC BY)
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2  Bioprotectants to keep foods safe from aflatoxin contamination
Aflatoxin is an important food safety challenge across the globe but is 
a particular problem in sub-Saharan Africa (SSA), where its occurrence and 
severity are most acute. Aflatoxins affect a range of food and feed products of 
plant, animal and insect origins as indicated in Table 1. These food and feed 
products frequently contain aflatoxin concentrations above official regulatory 
limits. Contamination is often high in groundnuts and maize, resulting in lethal 
concentrations surpassing 8000 parts per billion (ppb) (CDC, 2004). Animals 
including fish, poultry and cattle fed with contaminated feed become sources 
of dietary contamination themselves.
Aflatoxin contamination is critical because of its influence on health. 
Aflatoxicosis may be acute or chronic. Acute aflatoxicosis is episodic and 
results from dietary consumption of food containing extremely high levels of 
aflatoxins. A notorious case is the 2004 aflatoxicosis outbreak in Kenya that 
led to 125 deaths out of 317 cases – a high case fatality rate of 39% (CDC, 
2004). Chronic aflatoxicosis is caused by long-term sub-lethal exposure to 
aflatoxins and results in negative health outcomes such as hepatocellular 
carcinoma. About 30% of all liver cancer cases in Africa can be attributed 
to aflatoxin exposure (Liu and Wu, 2010). In children, aflatoxin exposure has 
been associated with stunting. Exposure can predate birth and continue 
through the first 1000 days of life through breast milk and weaning foods 
(Hsieh and Hsieh, 1993; Partanen et al., 2010; Anthony et al., 2016). Other 
health outcomes associated with aflatoxin exposure include immune system 
suppression, toxic hepatitis, Reye’s syndrome or fatty degeneration of the 
viscera, bile duct degeneration, low infant birth weight and acute hepatic 
encephalopathy (Groopman et al., 2008). Farm animals experience similar 
types of health effects as humans, but some are more pronounced and 
Table 1 Aflatoxin-susceptible food categories, examples and extent of contamination
Food category Examples Extent
Cereals Maize, sorghum, millet, sesame, rice, fonio millet and teff Common
Oil seeds Groundnuts, bitter melon seeds, sunflower and palm kernel Common
Spices, condiments Ginger, chili, Bambara groundnuts and locust beans Common
Tree nuts Pistachio, figs, almond and cashew nuts Common
Roots and tubers Yam and cassava chips Infrequent
Vegetables Bitter leaf and okra Infrequent
Aquatic animals Dried fish and farmed fish (e.g., catfish, tilapia, trout) Infrequent
Poultry Poultry meat and eggs Common
Ruminants Dairy products, muscle and offal Common
Insects Caterpillars and termites Common
Source: Adedeji et al., 2017; Kachapulula et al., 2018; Okoth, 2016.
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Bioprotectants to keep foods safe from aflatoxin contamination 3
perceptible. Aflatoxin exposure in animals leads to reduced productivity and, 
sometimes, death.
Aflatoxins negatively impact economic development. Indirect impacts 
result from chronic and acute exposure to aflatoxins on human and animal 
health that increases health costs. The African Union’s Partnership for Aflatoxin 
Control in Africa (PACA) estimates that annual health costs due to aflatoxin-
related cancers in Nigeria are US$1600 million (m); Tanzania US$1100 m; 
Uganda US$577 m; Malawi US$393 m; Senegal US$161 m; and The Gambia 
US$22 m (https://www .afl atox inpa rtnership .org /resources -catagory /country 
-and -regional). In the case of aflatoxin exposure in livestock, additional feed is 
needed to counteract poor growth as well as the cost of veterinary treatments 
from reduced immunity and reduced market value from animal products due to 
lower weight and quality and higher mortality (Aikore et al., 2019).
Direct impacts of aflatoxins on economic development are related to costs 
associated with lost trade opportunities and recall of food products or their 
destruction by an importing country when standards are not met (Wu and 
Khlangwiset, 2010). Allowable levels of aflatoxins in food differ among African 
countries, depending on prevalence, testing regimes and the ability to manage 
toxin exposure (van Egmond and Jonker, 2004). In-country monitoring across 
Africa is minimal, leading to the risk of traders segregating higher quality 
produce for international trade that is more strictly monitored and retaining 
lower quality crops for in-country trade and consumption (Wu and Guclu, 
2012). For all these reasons, aflatoxin mitigation can therefore contribute to 
achieving the United Nations Sustainable Development Goals (Ortega-Beltran 
and Bandyopadhyay, 2021).
This chapter summarizes the biology of aflatoxin-producing fungi and 
various factors affecting their occurrence, including climate change. Various 
management practices for aflatoxin mitigation are then discussed. These 
include biocontrol, which is increasingly being adopted by farmers in several 
countries. We discuss biocontrol product development and commercialization 
in various African countries. Subsequently, we highlight some barriers to 
adoption and other challenges. Much of the chapter is drawn from the 
experiences of the International Institute of Tropical Agriculture (IITA) and 
its partners that spearheaded the aflatoxin biocontrol initiative in Africa: the 
Aflasafe Initiative.
2  Aspergillus biology and aflatoxin epidemiology
2.1  Causal agents of aflatoxin contamination
Several Aspergillus species can produce either B or both B and G aflatoxins 
(Frisvad et al., 2019). The most common producer of aflatoxin is A. flavus, 
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4  Bioprotectants to keep foods safe from aflatoxin contamination
which produces B aflatoxins (Amaike and Keller, 2011; Klich, 2007). There are 
two major morphotypes within A. flavus: the L and the S morphotypes (Cotty, 
1989). The former produces variable aflatoxin levels, significant numbers of 
spores and a few large (>400 µm) sclerotia. The latter produces consistently 
high aflatoxin levels, fewer spores and numerous small (<400 µm) sclerotia. 
Another important species is A. parasiticus, a B and G aflatoxin-producing 
species associated with groundnut in most areas where the crop is produced 
(Horn et al., 1995; Kachapulula et al., 2017; Schroeder, 1969). A. parasiticus 
sometimes infects maize, pistachio, almond, fig and other crops (Donner et al., 
2015; Probst et al., 2014).
Many aflatoxin-producing Aspergillus isolates have become delineated 
into new species (Carvajal-Campos et al., 2017; Singh et al., 2020; Soares 
et al., 2012). In most cases, they are not epidemiologically significant. In some 
areas, species or groups of fungi occurring at relatively low frequencies are 
significant because of their high aflatoxin-production potential (Probst et al., 
2014). For example, in Kenya, a group of fungi with S morphology are potent 
aflatoxin producers and have been linked to severe episodes of aflatoxicosis 
and death (Probst et al., 2012). Similarly, in West Africa, another group of highly 
toxigenic fungi with S morphology occurs at relatively low proportions but may 
significantly contaminate staple crops grown in that region (Agbetiameh et al., 
2018; Atehnkeng et al., 2008; Cardwell and Cotty, 2002; Diedhiou et al., 2011). 
Examination of fungal communities in areas yet to be studied, or in those not 
intensively examined, will certainly result in identification of new species.
Aflatoxin-producing genotypes within a species have different toxin 
production potentials (Horn and Dorner, 1999; Kachapulula et al., 2017; 
Mehl et al., 2012; Novas and Cabral, 2002; Ortega-Beltran et al., 2015). These 
potentials also vary among and within diverse substrates (Mehl and Cotty, 2013; 
Ortega-Beltran et al., 2014; Suwarno et al., 2019). There are aflatoxin-producing 
species with members that have lost the ability to produce aflatoxins. Such 
isolates are known as atoxigenic. Natural genetic defects across the aflatoxin 
biosynthesis gene cluster or lack of the whole cluster itself cause atoxigenicity 
(Adhikari et al., 2016; Chang et al., 2005; Donner et al., 2010).
Aflatoxin-producing fungal community structures are highly dynamic. 
There is great variation within and among fields, in both small and large areas, 
within cropping systems and across years (Bayman and Cotty, 1991; Mehl 
et al., 2012; Ortega-Beltran and Cotty, 2018). Community structures dominated 
by certain genotypes or species for 1 year may change dramatically within a 
relatively short term (Drott et al., 2019; Ortega-Beltran et al., 2020).
There is large genetic variability within and among species. One way 
to determine genetic variability within a species is to assign isolates into 
vegetative compatibility groups (VCGs) (Leslie, 1993). Isolates belonging to a 
VCG are thought to descend from the same clonal lineage. There is also genetic 
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Bioprotectants to keep foods safe from aflatoxin contamination 5
variability within a VCG (Grubisha and Cotty, 2010; Ortega-Beltran et al., 2016). 
Regardless of intra-VCG variability, members of a VCG are more closely related 
to each other than to members of other VCGs. There may be thousands of 
VCGs of any single species within a given area. Members of a VCG may occur 
in different countries (Agbetiameh et al., 2019; Moral et al., 2020) and even in 
different continents (Ogunbayo et al., 2013).
The name Aspergillus has been used to describe the anamorph stage 
of several species composing this genus. The teleomorph stage for various 
Aspergillus species has been described (Horn et al., 2009a; Luis et al., 2020). 
Although a teleomorph stage has been described for A. flavus (Petromyces 
flavus B.W. Horn, I. Carbone et G.G. Moore, sp. nov.) – through laboratory 
manipulation – the species is considered to reproduce predominantly in an 
asexual manner (i.e., through spores) (Islam et al., 2018; Ortega-Beltran et al., 
2020; Papa, 1986). Sexual recombination is not significant in field conditions. 
There have been some reports of sexual recombination in field conditions but 
only after subjecting isolates to specific laboratory conditions that rarely occur 
in nature (Horn et al., 2009a,b, 2014; Olarte et al., 2012).
2.2  Factors influencing aflatoxin contamination
Aflatoxin-producing fungi survive in the soil primarily as sclerotia and mycelium. 
These propagules multiply in organic matter and plant debris and produce 
copious amounts of spores (conidia) that are carried by wind, water, rain 
splashes and insects onto sites of infection. Flowers and developing grains are 
the primary sites of infection. Subsequently, the pathogens colonize grain tissues 
and produces aflatoxin in the plant substrate (Diener et al., 1987). The aflatoxin 
problem starts at the pre-harvest stages in the field and is accentuated when 
storage conditions are favorable for further fungal colonization and growth.
Multiple factors are responsible for aflatoxin contamination in crops. These 
include the presence of aflatoxigenic fungi, susceptibility of crops, a favorable 
environment for aflatoxin accumulation, agronomic practices that support 
contamination and insect damage to crops. Significant aflatoxin contamination 
results in crops when these factors occur together. It is critical to manage these 
risk factors for aflatoxin reduction.
The prevalence of aflatoxin-producing fungi in a fungal population is 
important for aflatoxin contamination. High aflatoxin accumulation occurs when 
aflatoxigenic fungi are present in sufficiently high quantities in the crop. The 
prevalence of fungal groups is influenced by founder events. Founding events 
may occur spontaneously or be triggered by biocontrol efforts using atoxigenic 
fungi (Mehl et al., 2012; Lewis et al., 2019; Ortega-Beltran et al., 2020). The 
latter promotes high populations of atoxigenic genotypes leading to lower 
aflatoxin accumulation (Bandyopadhyay et al., 2016, 2019a). Spontaneous 
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6  Bioprotectants to keep foods safe from aflatoxin contamination
founding populations of toxigenic strains result in high aflatoxin levels in crops 
(Probst et al., 2010, 2012).
Until the natural defense system of a crop is compromised to make the 
crop susceptible to aflatoxigenic fungi, it is difficult for the fungi to infect, 
colonize and synthesize aflatoxins in crops. Plant stress is an important factor 
that compromises the natural defense system of the crop. Stresses include heat, 
water and drought. These result in loss of kernel integrity such as silk cut or 
physiological changes such as reduction in phytoalexin levels (Odvody et al., 
1997; Kebede et al., 2012). Stress to the crop can also come from pest damage 
(Dowd, 2003) and nutrient deficiencies (Htoon et al., 2019).
Extremes of temperatures, which may occur in either warm humid climates 
or hot arid and semi-arid areas, can predispose crops to aflatoxin contamination 
(Cotty and Jaime-Garcia, 2007; Medina et al., 2014). Dryer, hotter climates 
promote higher densities of Aspergillus spp. and can favor the prevalence of 
fungi with high aflatoxin production capability (Cotty and Jaime-Garcia, 2007). 
Dryer, hotter conditions also predispose stressed crops to both insect attack 
and infection by aflatoxin-producing fungi (Abbas et al., 2009; Cotty et al., 1994; 
Paterson and Lima, 2010). Erratic rainfall during later stages of crop maturity 
can provide conditions for aflatoxin formation (Cotty and Jaime-Garcia, 2007; 
Gilbert et al., 2016) and may make it difficult to dry crops to appropriate levels 
for safe storage (Bradford et al., 2018; Ndemera et al., 2020).
Improper agronomic practices such as late planting, incorrect spacing, 
poor irrigation and insect control practices predispose crops to aflatoxin 
contamination (Payne et al., 1986; Rodriguez-del-Bosque, 1996; Canavar 
and Kaynak, 2013; Weaver et al., 2017; Williams et al., 2017). Crop rotation 
practices that follow aflatoxin-susceptible crops with other susceptible crops 
will encourage the continued propagation of aflatoxigenic fungi (Jaime-Garcia 
and Cotty, 2010). Untimely harvest is another predisposing factor to aflatoxin 
contamination. Insect damage provides entry sites on grains while insects also 
carry inoculum to the entry site (Dowd, 2003; Bakoye et al., 2017). Insect control 
strategies are thus important in aflatoxin management.
Climate change is having and will continue to have a great negative 
effect on crop susceptibility to plant pathogens (Pautasso et al., 2012). In the 
case of aflatoxin, climate change is already causing increased contamination 
events in areas where the problem is perennial but also in areas that were not 
considered at risk (Battilani et al., 2016; Paterson and Lima, 2011). Apart from 
increased temperatures and disruptions of rainfall cycles, climate change is 
also accompanied by greater levels of CO2 (Medina et al., 2017a). Increased 
CO2 has been shown to promote greater crop stress and subsequent aflatoxin 
accumulation in laboratory conditions. Significant changes in CO2 levels in 
real conditions may contribute to greater aflatoxin accumulation. Aflatoxin 
mitigation strategies must consider the ways that combinations of increased 
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Bioprotectants to keep foods safe from aflatoxin contamination 7
temperature, increased or decreased water availability and elevated CO2 may 
reduce the effectiveness of current management strategies.
3  Aflatoxin management options
There are several aflatoxin management options for reducing the risk factors 
that predispose crops to aflatoxins. Aflatoxin management should begin in the 
field during planting and continue throughout the harvest and post-harvest 
stages. Several reviews have described various management tools available 
for mitigating aflatoxin accumulation in food and feed (Ayalew et al., 2017; 
Udomkun et al., 2017; Falade, 2018). These tools address risks associated 
with high prevalence of aflatoxigenic fungi, susceptible hosts, inadequate 
agronomic and post-harvest practices.
Several microbial species (e.g., fluorescent Pseudomonas, Bacillus subtilis, 
and Trichoderma spp.) have been tested as biocontrol agents for reducing 
aflatoxin contamination at the pre- and post-harvest stages (Desai et al., 2000; 
Mohammed et al., 2018; Peles et al., 2021). None of those microbes have been 
evaluated beyond the experimental phase. Modulating Aspergillus populations 
in favor of atoxigenic genotypes to reduce the prevalence of aflatoxigenic fungi 
is a way to manage populations of aflatoxigenic strains. These can be achieved 
via application of naturally occurring atoxigenic genotypes of A. flavus endemic 
to the region of application (Dorner and Lamb, 2006; Bandyopadhyay et al., 
2016, 2019b; Ortega-Beltran et al., 2016). This biocontrol approach is discussed 
in detail later in this chapter.
Breeding for host plant resistance to aflatoxin is used to develop plant 
cultivars that are less susceptible to aflatoxin contamination (Kim et al., 2006; 
Brown et al., 2013). Some approaches are targeted at integrating antifungal 
proteins or promoting physical changes such as increased tightness of husk 
cover, kernel hardness and pericarp wax (Kebede et al., 2012). Biotechnological 
approaches using RNAi technology are highly effective in reducing aflatoxin 
biosynthesis (Thakare et al., 2017) and colonization by Aspergillus (Sharma 
et al., 2018). Transgenic technologies have also targeted insect pest resistance 
which indirectly helps aflatoxin management (Wu, 2006; ICRISAT, 2016; Weaver 
et al., 2017).
Multiple agronomic practices are needed to manage aflatoxin 
contamination. Some of these include crop rotation of susceptible plants 
by non-susceptible plants, use of appropriate adapted varieties, irrigation 
where available, proper spacing, timely harvest and insect and weed control 
(Rodriguez-del-Bosque, 1996; Dowd, 2003; Waliyar et al., 2003; Jaime-Garcia 
and Cotty, 2010).
Timely harvest to avoid rain is important to keep grain moisture under 
control and prevent aflatoxin accumulation. Rapid drying of grains on clean 
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8  Bioprotectants to keep foods safe from aflatoxin contamination
surfaces (e.g., tarp) or using dryers can reduce aflatoxin contamination (Pretari 
et al., 2019). Dry grains, kept under optimal storage conditions such as proper 
aeration, insect and pest control, are critical (Turner et al., 2005). Hermetic 
storage (e.g., Purdue Improved Crop Storage bags) mitigates fungal growth 
and insect activity, contributing to aflatoxin control (Williams et al., 2014; Maina 
et al., 2016).
4  Biocontrol product development and the registration 
process in Africa
4.1  The science of atoxigenic-based biocontrol
Atoxigenic isolates of A. flavus lacking the ability to produce aflatoxins were 
identified over 50 years ago (Joffe, 1969). The common occurrence of that 
trait in A. flavus, coupled with increased competitiveness of some genotypes, 
suggested that such genotypes could be used as biocontrol agents to 
outcompete aflatoxin producers in the field (Cotty, 1989). Studies in the United 
States by the U.S. Department of Agriculture–Agricultural Research Service 
(USDA-ARS) revealed that pre-harvest application of the atoxigenic isolate A. 
flavus AF36 reduced aflatoxin accumulation in maize when tested in field trials, 
both at the pre- and post-harvest stages (Brown et al., 1991). Those studies 
paved the way for the development of aflatoxin biocontrol using atoxigenic A. 
flavus genotypes as an active ingredient in biocontrol formulations.
The main mechanism of biocontrol is the competitive exclusion that results 
in a modified A. flavus community with a lower average aflatoxin-producing 
ability (Horn et al., 2011). The formulated product is composed of dead 
sorghum grains coated with spores of the active ingredients (0.0005% w/w of 
the formulated product) and other adjuvants. Farmers broadcast the product in 
the field at the rate of 10 kg/ha 2–3 weeks before crop flowering for maize and 
groundnut. The carrier sorghum grain acts as a food source on which the active 
ingredients, which are already present on its surface, multiply and produce a 
large number of spores for at least 20 days. The carrier grains thus act as ‘in 
situ field factories of biocontrol spores.’ These spores continually disperse, 
colonize various niches in soil and other substrates and create a founding 
population of active ingredients, which further multiplies and displaces other 
Aspergillus strains. The active ingredients dominate in the treated field (and 
to some extent in neighboring areas) in place of other Aspergillus strains and 
ultimately become associated with the crop. Spores of the active ingredients 
produced on soil and other substrates are dispersed by wind, rain and insects 
to reach the crop’s infection sites. The substrate to deliver the biocontrol is 
key in providing a competitive advantage to the applied fungi over aflatoxin 
producers present in the treated fields (Cotty and Mellon, 2006). Competitive 
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Bioprotectants to keep foods safe from aflatoxin contamination 9
exclusion significantly prevents aflatoxin producers from reproducing in the 
field and thus from becoming associated with the crop. High levels of applied 
atoxigenic genotypes in the treated crops are associated with low levels of 
aflatoxins (Agbetiameh et al., 2020; Doster et al., 2014; Mehl et al., 2012; 
Shenge et al., 2019). In general, treated and untreated fields and crops contain 
the same fungal densities (Agbetiameh et al., 2020; Atehnkeng et al., 2014; 
Bock et al., 2004; Dorner, 2009; Doster et al., 2014; Senghor et al., 2020).
Other indirect mechanisms that may contribute to reduced aflatoxin 
accumulation by atoxigenic genotypes include:
• toxin degradation by atoxigenic genotypes (Maxwell et al., 2021)
• a so-called ‘touch inhibit’ mechanism (Damann, 2015)
• production of both extrolites and volatile compounds by atoxigenic 
genotypes which may discourage aflatoxin production (Moore et al., 2019; 
Sweany and Damann, 2020).
However, competitive displacement mechanisms are the predominant 
contributors to reduced aflatoxin content in treated crops.
Much has been achieved in the United States since the late 1980s and early 
1990s. The atoxigenic biocontrol product Aspergillus flavus AF36 was initially 
registered with the United States Environmental Protection Agency (US EPA) 
for use in cottonseed and subsequently for use in maize, pistachio, almond 
and fig (Cotty et al., 2007; Doster et al., 2014; Ortega-Beltran et al., 2019). The 
product AF36 is produced and distributed by the Arizona Cotton Research and 
Protection Council (ACRPC), a farmer-run organization (Cotty et al., 2007). It is 
used over hundreds of thousands of hectares, and most treated crops meet 
stringent local and international standards. Without biocontrol, it would be 
difficult for farmers growing susceptible crops in contamination hot spots to 
produce safe crops.
AF36 belongs to VCG YV36. YV36 occurs naturally across the United 
States (Grubisha and Cotty, 2015), and in several states across Mexico 
(Ortega-Beltran et al., 2016). The natural presence of YV36 across Mexico has 
allowed experimental use of AF36 in maize fields in certain states (N. Palacios, 
CIMMYT, personal communication). Another aflatoxin biocontrol product used 
in the United States is Afla-guard®, which is registered with the US EPA and 
manufactured by Syngenta® for use in maize and groundnut (Dorner, 2009).
In the mid-1990s, USDA-ARS and IITA started a collaboration to introduce 
the atoxigenic biocontrol technology in SSA (Bandyopadhyay et al., 2019b, 
2019). Causal agents of contamination in target African environments were 
characterized (Agbetiameh et al., 2018; Atehnkeng et al., 2008; Cardwell and 
Cotty, 2002; Cotty and Cardwell, 1999; Diedhiou et al., 2011; Donner et al., 
2009). Native atoxigenic isolates belonging to widely distributed VCGs were 
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10  Bioprotectants to keep foods safe from aflatoxin contamination
then identified in various countries (Agbetiameh et al., 2019; Atehnkeng et al., 
2016; Probst et al., 2011; Senghor et al., 2020, 2021). Native atoxigenic isolates 
are inherently adapted to local cropping systems and environmental conditions 
and have interacted with the causal agents of contamination in target areas for a 
long time (Mehl et al., 2012; Probst et al., 2011). Native isolates should result in 
better aflatoxin reduction compared to exotic genotypes. Using native isolates 
over introduction of exotic Aspergillus organisms is preferred by regulatory 
authorities.
4.2  Product development process
Development of efficient aflatoxin biocontrol products requires mining 
the fungal biodiversity across a target country. The biodiversity can be 
comprehensively assessed by examining large numbers (e.g., 5000 isolates) 
of A. flavus isolates associated with target crops (Agbetiameh et al., 2018, 
2019; Atehnkeng et al., 2008; Probst et al., 2011). These isolates are obtained 
from georeferenced crop or soil samples collected from different parts of 
the country. Such an exercise allows detection of atoxigenic genotypes 
belonging to the most common atoxigenic VCGs across a country of interest 
with known adaptation to target agroecosystems, their cropping systems, 
climatic and soil conditions. Examination of small numbers of isolates (say, 
100 and sometimes less) from a few areas increases the probability of 
selecting poor atoxigenic genotypes that may not provide adequate levels 
of protection or atoxigenic genotypes that may belong to VCGs containing 
members with aflatoxin-production abilities, since VCGs containing both 
atoxigenic and aflatoxin-producing members are relatively common (Ortega-
Beltran and Cotty, 2018).
Applications of atoxigenic genotypes are intended to cause long-
term changes to communities of Aspergillus section Flavi, with applied 
genotypes becoming prevalent thereby lowering aflatoxins in the target 
region. Care is therefore taken to only use VCGs that do not contain aflatoxin-
producing members. As with all organisms, mutations continually occur in 
this predominantly haploid fungus that evolves primarily in a clonal fashion 
(Adhikari et al., 2016; Islam et al., 2018). Defects that result in atoxigenicity 
of active ingredients are sufficiently ancient that multiple mechanisms of 
atoxigenicity occur and atoxigenicity is fixed in the VCGs to which those active 
ingredients belong (Adhikari et al., 2016). However, genotypes that more 
recently acquired an atoxigenic trait and occur in VCGs that are predominantly 
high aflatoxin producers may be problematic (Ortega-Beltran and Cotty, 2018). 
Gene flow occurs within VCGs, and this results in the potential for aflatoxin-
producing ability to be acquired by atoxigenic fungi in aflatoxin-producing 
VCGs through the parasexual cycle (Grubisha and Cotty, 2010, 2015). VCGs 
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Bioprotectants to keep foods safe from aflatoxin contamination 11
with aflatoxin-producing members are thus avoided when selecting active 
ingredients for biocontrol products.
Traditionally, atoxigenic VCGs were found through a laborious, time-
consuming process using microbiological procedures that include vegetative 
compatibility assays (VCA) (Atehnkeng et al., 2016; Doster et al., 2014; Probst 
et al., 2011). With the advent of molecular tools, the process has been simplified. 
Atoxigenic isolates within a population are first identified by assessing deletions 
in markers spaced across the aflatoxin biosynthesis gene cluster (Callicott and 
Cotty, 2015). Those atoxigenic isolates can then be genotyped using simple 
sequence repeat (SSR) markers (Agbetiameh et al., 2019; Grubisha and Cotty, 
2009; Senghor et al., 2020). Isolates showing defective aflatoxin biosynthesis 
genes are then examined for their lack of ability to produce aflatoxins in a crop 
substrate (e.g., maize kernels). Groups identified by SSR analyses are then 
confirmed for the absence of members with toxigenic capability using VCA. 
Incorporation of molecular tools allows faster detection of atoxigenic VCGs 
and provides genetic information to establish phylogenetic relationships within 
and among genotypes of A. flavus and other Aspergillus species. The number 
of isolates belonging to each atoxigenic VCG, the number of crop samples 
from which the members of each VCG are obtained and their distribution in 
different agroecological zones are used as traits to identify widely distributed 
and adapted candidate VCGs for further evaluation.
It is important to determine which atoxigenic VCGs have the best ability to 
prevent aflatoxin contamination when challenged with highly toxigenic fungi. 
Competition experiments in grains of a target crop identify VCGs most likely 
to outcompete toxin producers when infecting the same substrate (Ortega-
Beltran et al., 2019; Probst et al., 2011). It is critical to discard poor competitors. 
Generally, atoxigenic fungi able to limit aflatoxin contamination by 80% or 
more are considered good competitors (Camiletti et al., 2018; Mauro et al., 
2015; Probst et al., 2011). However, there are genotypes that can limit aflatoxin 
contamination by well over 95% (Agbetiameh et al., 2019; Ortega-Beltran 
et al., 2019), and those should receive priority if they fulfill other criteria such 
as adaptation in large areas, repeated detection in multiple crops and ability to 
persist in the environment after application.
Another important criterion for selecting aflatoxin biocontrol agents is 
their ability to move from the field to the treated crop (e.g., maize, groundnut, 
pistachio, sorghum). This is an aspect of biocontrol genotype selection that 
has received little attention. However, there are differences in the abilities of 
atoxigenic genotypes to successfully colonize substrates in the field and then 
move from soil to crops (Agbetiameh et al., 2019). Those differences can 
be revealed when candidate biocontrol genotypes are released on soil and 
their ability to colonize and spread is studied in multiple crops under varied 
agroecologies. The true test of an excellent biocontrol candidate after soil 
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application lies in its ability to be frequently isolated from soil and grain at harvest 
and carry-over to the next season. The best atoxigenic genotypes can result 
in biocontrol products providing large aflatoxin reductions, the ultimate goal 
of aflatoxin biocontrol technology. For example, careful selection of the best 
atoxigenic genotypes native to Ghana resulted in biocontrol products with the 
greatest efficacy reported thus far (Agbetiameh et al., 2020). Almost all treated 
crops contained undetectable aflatoxin levels during two cropping seasons in 
multiple agroecologies, while most untreated crops contained unsafe aflatoxin 
levels, some of them were extremely dangerous. It is important to point out 
that A. flavus, whether toxigenic or atoxigenic, have a weak pathogenic phase, 
which may lead to Aspergillus ear rot (AER) in susceptible crops. However, AER 
is not common and often requires injuries to the ear and a high inoculum dose 
for symptoms to occur. No perceptible (and statistical) difference in AER has 
been observed between biocontrol-treated and untreated fields (Atehnkeng 
et al., 2014).
A major difference in aflatoxin biocontrol products developed in Africa is 
the use of four atoxigenic genotypes instead of one atoxigenic genotype as in 
the United States and Italy. Traditionally, single-genotype products have been 
preferred because they are easier to develop, less demanding to navigate 
through the registration process and less cumbersome to manufacture. In theory, 
the various genotypes in a multigenotype product will allow more efficient filling 
of microniches to which one or another genotype is best adapted. Similarly, as 
environmental conditions change between seasons, the active ingredient best 
suited to conditions will be the most successful. The design of the multigenotype 
products thus provides product plasticity responsive to varying conditions. 
However, the exact conditions favoring the various genotypes are unknown. 
Experiments comparing displacements achieved with multigenotype versus 
single genotype products are difficult to design and have not been reported. 
Multigenotype products are also thought to instill greater complexity to the 
modified A. flavus community resulting from treatments. Associated with this 
greater complexity is a greater tendency to retain the modified structure with 
its greatly reduced average aflatoxin-producing potential (Bandyopadhyay 
et al., 2016). Compositions of communities of A. flavus can change rapidly 
even in the absence of atoxigenic genotype applications and, as discussed 
above, the increased complexity provided by multigenotype products may 
support longer-term residence of modified communities (Ortega-Beltran et al., 
2020; Ortega-Beltran and Cotty, 2018). However, the ability of multigenotype 
products to promote communities with longer-term residence than single-
genotype products has not been tested empirically.
Currently, recommendations for prevention of aflatoxin contamination 
of several crops include one treatment of target crops in a season. However, 
movement of active ingredients between fields and crops and carry-over of 
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Bioprotectants to keep foods safe from aflatoxin contamination 13
products between seasons provide opportunities for additive benefits when 
fields are treated over multiple seasons. Movement and carry-over also offer 
the potential for cost savings through fewer applications. In some regions in the 
United States, movement of atoxigenic genotypes between crops and carry-
over between seasons are innate components of management strategies, for 
example, when pistachio and almond are grown in close proximity to each 
other and harvest practices facilitate movement of conidia between the crops 
(Cotty et al., 2007). Annual treatments rely on carry-over to adequately changed 
communities in the canopy of these perennial tree crops and to prevent 
inadvertent inoculation of nearby orchards with conidia of aflatoxin producers. 
In some parts of Texas, most maize is treated with an atoxigenic genotype-based 
biocontrol product. In those areas, long-term effects may mean that when some 
fields are not treated in a given year, a sufficient amount of the atoxigenic A. 
flavus community remains to provide continuing control (Jaime et al., 2017). 
Some farmers in Texas thus reduce treatments to only a portion of the treated 
crop each season. However, variation in operations, rotations and climate 
between farms and seasons have thus far prevented development of formal 
recommendations to reduce application frequency to below once a season. 
Across Africa, density of treated fields across landscapes is not yet sufficient 
for carry-over to allow recommendation of reduced frequencies of application.
As mentioned earlier, there are VCGs with members known to occur in 
multiple countries. Many atoxigenic VCGs have been found across several SSA 
countries. The Aflasafe Initiative recommends the use of a product developed 
for one country in another country if members of the same VCG in the active 
ingredient coexist in the second (or third) country as well. That was the case with 
Aflasafe SN01, which was developed initially for Senegal (Senghor et al., 2020). 
Subsequently, the active ingredient genotypes of Aflasafe SN01 were found to 
co-occur in The Gambia paving the way for use of the product in Senegal and 
The Gambia (Senghor et al., 2021).
4.3  Registration with regulatory authorities
The registration of aflatoxin biocontrol products in SSA countries varies. This 
was difficult initially because systems to register bioprotectants (the category 
in which aflatoxin biocontrol falls in) were not well developed (Bandyopadhyay 
et al., 2016). Instead of waiting for systems to be put in place (which could have 
taken many years), the Aflasafe Initiative worked with regulatory authorities 
to develop systems, helped by the USDA Foreign Agricultural Service. The 
experience from registering the biocontrol product AF36 with US EPA served 
as a template in discussions with regulators and national policy makers.
The registration process starts before the product is developed. The 
Aflasafe Initiative helps to sensitize regulatory agencies and key policy makers 
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14  Bioprotectants to keep foods safe from aflatoxin contamination
on aflatoxin and its management using biocontrol products (Schreurs et al., 
2019). The problem of aflatoxin and the use of biocontrol with atoxigenic fungi 
were initially poorly understood in many countries. Multiple meetings took place 
in each country to present evidence on aflatoxin contamination and the benefits 
of biocontrol and other management practices. Regulators and scientists 
from national institutes and IITA jointly planned research to develop and test 
products in target areas and crops. Regulators in many cases required particular 
experiments to satisfy efficacy and safety concerns (Bandyopadhyay et al., 2016).
Registration of aflatoxin biocontrol products has been granted after 
submitting the required evidence on the efficacy (Fig. 1), safety, quality and 
social benefits of the technology (Bandyopadhyay et al., 2016). In Nigeria and 
Kenya (where the first registrations of Aflasafe products were granted in 2014 
and 2015, respectively), it was necessary to submit additional toxicological 
and ecotoxicological studies to demonstrate that the products and the active 
ingredients were safe to the environment (e.g., effects on birds, rodents, bees, 
earthworms and soil microbes other than aflatoxin producers). Results from 
those studies revealed that the use of the active ingredient fungi in biocontrol 
formulations do not pose risks to non-target species beyond those already 
taking place throughout the target environments. Only native fungi commonly 
interacting with target crops in target areas are used in formulations. The results 
from the studies conducted in Nigeria and Kenya, along with other studies 
conducted in the United States for registration of atoxigenic products, have 
been accepted by regulatory authorities in CSP-CILSS countries (Senegal, The 
Gambia, Burkina Faso), Ghana, Tanzania, Zambia, Malawi, and Mozambique. 
These countries waived repeating those toxicological and ecotoxicological 
studies based on the equivalence principle.
The validity period of registration of aflatoxin biocontrol product is variable. 
Registrations have been granted for 3 years in CILSS countries and 5 years in 
others. Two products developed for Ghana were initially granted an Experimental 
Figure 1 Aflatoxin concentration in parts per billion (ppb) in grains at harvest and after 
poor storage in biocontrol-treated and untreated (control) fields (left). The effectiveness 
data are means of over 1500 maize and groundnut fields of farmers who either treated 
or did not treat their crops with biocontrol products in multiple countries. A farmer 
broadcasting a biocontrol product in a maize field @ 10 kg/ha 2–3 weeks before flowering 
(right).
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Bioprotectants to keep foods safe from aflatoxin contamination 15
Use Permit for 1 year to gather additional evidence of efficacy under commercial 
use. In 2020, the Ghana EPA provided the regular 3-year registration usually 
granted to approved biopesticides. In some countries, it is necessary to register 
the manufacturing facilities of the biocontrol product. The factories needed to 
comply with environmental, structural and safety parameters.
4.4  Development of biocontrol products in different countries
There are 14 Aflasafe biocontrol products registered for use in 10 countries 
(product name and year of registration in parenthesis) (Moral et al., 2020):
• Nigeria (Aflasafe™; 2014)
• Kenya (Aflasafe KE01™; 2015)
• Senegal and The Gambia (Aflasafe SN01™; 2016)
• Burkina Faso (Aflasafe BF01™; 2016)
• Ghana (Aflasafe GH01™ and Aflasafe GH02™; 2018)
• Zambia (Aflasafe ZM01™ and Aflasafe ZM02™; 2018)
• Tanzania (Aflasafe TZ01™ and Aflasafe TZ02™; 2019)
• Mozambique (Aflasafe MWMZ01™ and Aflasafe MZ02™; 2019)
• Malawi (Aflasafe MWMZ01™ and Aflasafe MW02™; 2020) 
After registration, the technology has been transferred to the private sector 
through Technology Transfer and Licensing Agreements (TTLA) for mass 
manufacture and distribution. Aflasafe is now manufactured in four countries 
(Nigeria, Kenya, Senegal and Tanzania) and is commercially available in Nigeria, 
Kenya, Senegal, Tanzania, Mozambique, The Gambia, Burkina Faso, Malawi and 
Ghana. Product testing is currently underway in Mali, Niger, Rwanda, Burundi, 
Uganda and Togo. Product development is currently being done for Sudan, 
Benin, Cameroon, Zimbabwe and Democratic Republic of Congo. It is expected 
that product development will expand to Sierra Leone, Côte d’Ivoire and Chad, 
among other African countries.
5  Manufacturing development
Aflatoxin biocontrol products are agricultural inputs that must be produced in 
large quantities for use in the field. Unlike spray or seed treatment formulations 
generally used for biocontrol products, all formulations of commercial biocontrol 
products for aflatoxin control are grain-based and applied by broadcasting 
in the field. There are several advantages of grain-based solid formulations. 
These include ease of application and slow release of active ingredients in the 
environment for a long period, aiding competitive displacement of toxigenic 
strains. However, a grain-based formulation is bulky and expensive to transport 
over long distances.
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5.1  The initial manufacturing plant
To test efficacy, products were first manufactured using a laboratory-scale 
adaptation of the industrial manufacturing process developed by USDA-ARS 
and ACRPC (Cotty et al., 2007). This method was laborious, requiring several 
workers to produce around 300 kg of product per week (Atehnkeng et al., 
2014). The process involved sterilization of sorghum grains in an autoclave, 
soaking the autoclaved grains in a spore suspension, incubating the inoculated 
grains for 18 h at 31°C, rapid drying of the grains before sporulation begins, 
and bagging the product. The laboratory method allowed field efficacy trials 
in several hundred fields in Nigeria, Senegal, Zambia and Kenya. However, it 
was evident that a more efficient and cost-effective manufacturing process was 
needed.
In 2011, Bill Gates and senior management of the Bill & Melinda Gates 
Foundation (BMGF) visited IITA station in Kano, Nigeria. Aflasafe was one of 
the technologies showcased. The BMGF delegation recognized the potential 
of the technology, but the technology was out of reach for many farmers. Only 
industrial manufacture and effective partnerships with the private sector could 
realize its potential. A demonstration-scale Aflasafe manufacturing plant was 
thus designed and constructed in IITA-Ibadan (Nigeria) with funds granted by 
BMGF through the PACA (Bandyopadhyay et al., 2016). There were two main 
objectives for constructing the manufacturing facility. The first was to produce 
large quantities of biocontrol products to:
• conduct large-scale efficacy field trials in Senegal, The Gambia, Ghana and 
Burkina Faso
• allow farmers in Nigeria, Senegal, The Gambia and even Kenya to access 
the product to treat hundreds of thousands of hectares.
A second objective was to demonstrate that a commercially viable 
manufacturing facility could be set up in Africa. Without the involvement of 
the private sector, the technology would remain dependent on donor funding, 
would be unsustainable and of limited impact.
5.2  Improved manufacturing processes and facilities
The demonstration-scale Aflasafe manufacturing plant constructed at IITA-
Ibadan consisted of off-the-shelf equipment: grain cleaner, feed roaster, cooling 
equipment, silos, seed treater and packaging machines (Bandyopadhyay et al., 
2016; Schreurs et al., 2019). In contrast to the use of wheat or barley in the United 
States, white sorghum is used as both substrate and carrier for the atoxigenic 
fungi. White sorghum is cheaper, readily available and an excellent substrate 
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Bioprotectants to keep foods safe from aflatoxin contamination 17
for A. flavus reproduction. Moreover, sorghum grains are smaller than those of 
wheat, and a greater number of biocontrol carrier grains are dispersed across 
treated fields. Having more biocontrol formulation grains across a treated field 
can ensure a more even distribution of biocontrol fungi.
A second difference is that an improved dry process is used in African 
environments. In the United States, initially, the AF36 product was prepared 
using a wet process requiring autoclaving the wheat grain, then inoculating 
the grain and incubating it for 18 h. In the case of Aflasafe products, sorghum 
grain is cleaned and then roasted to kill both the embryo and associated 
microorganisms. After cooling, the grain is coated with a spore suspension 
containing appropriate amounts of spores of the atoxigenic genotypes, a blue 
food colorant to differentiate the product from regular sorghum, and a polymer 
to aid in the coating process (Bandyopadhyay et al., 2016). For each ton of 
Aflasafe product, a 10 L spore suspension (4 × 107 spores/ml) is combined with 
1.5 L polymer, 2 L blue dye and 10.5 L sterile water. Roasted, sterile sorghum 
grain is coated with the suspension in a seed treater (Bandyopadhyay et al., 
2016). After the coating, the product is automatically conveyed to a packaging 
system to dispense the product into bags. At full capacity, the plant can produce 
5 tons of Aflasafe per hour. The Afla-guard product is also manufactured using 
a dry process, but the substrate type (barley) and treatment (clay coating of 
carrier) are different from the Aflasafe manufacturing process.
The spore suspension of the active ingredient genotypes is obtained from 
an inoculum production laboratory adjacent to the factory. The active ingredient 
genotypes are inoculated on sterile sorghum grains, incubated, diluted and 
mixed with the other ingredients before transfer to the factory (Agbetiameh 
et al., 2019; Bandyopadhyay et al., 2016). The manufacturing facility also has 
a quality control laboratory to check finished products. Samples are collected 
from each 250 or 500 kg batch to verify the absence of contamination, and that 
only atoxigenic active ingredient genotypes, at the right density, are coated on 
the biocontrol carrier grains. In addition, the sporulation ability of the atoxigenic 
genotypes on the biocontrol formulation is measured.
After the manufacturing facility in Ibadan, another three factories have 
been constructed. In Katumani in Kenya, IITA and partners constructed a 
manufacturing plant to produce Aflasafe KE01. The Katumani production 
process is not continuous (as in Ibadan) but modular and with significant 
improvements in production efficiency. It is made up of the following three 
modules (Fig. 2):
• Module R, where carrier grain cleaning, sterilization (using roaster) and 
cooling (in a cooling silo) occurs
• Module C, for coating of the grain using a seed treater
• Module P, for packaging of the finished product.
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18  Bioprotectants to keep foods safe from aflatoxin contamination
Figure 2 The KALRO/IITA Aflasafe Modular Manufacturing Plant at Kenya Agricultural 
and Livestock Research Organization (KALRO) Katumani Research Station in Kenya. 
(a). A side view of the manufacturing plant. (b). The plant consists of a laboratory 
where the inocula of the active ingredients are produced and combined with a blue 
dye and polymer sticker. (c). Carrier (sorghum) pit (1) from where sorghum is moved 
into a grain cleaner (2) with an auger, then transported to a roaster (3) and finally to 
a cooling silo for cooling and storing the roasted carrier grains. (d). From cooling silo 
(4), the carrier is transported via a pneumatic line into a seed treater (5) where the 
master solution (inoculum, dye and polymer) is coated onto the sorghum grain. (e). 
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Bioprotectants to keep foods safe from aflatoxin contamination 19
The advantage of the modular facilities is that each module can be expanded 
when demand for the biocontrol product increases, meaning it is not necessary 
to make a large investment during the initial years of operation. Similar modular 
facilities in Kahone in Senegal and Arusha in Tanzania were constructed by 
the companies BAMTAARE, S.A. and A to Z Textiles Mills Ltd., respectively. In 
addition, a fifth modular manufacturing facility is currently being constructed by 
the company HarvestField Industries Ltd., the licensee of the Aflasafe product, 
for use in Nigeria. This new facility in Nigeria would be the largest in Africa 
and operational during the third quarter of 2021. New modular manufacturing 
facilities are currently being constructed in the Democratic Republic of Congo, 
Burundi, Sudan and Mozambique. Although highly efficient manufacturing 
facilities have been designed and constructed, investigations are continuing 
to develop and validate new manufacturing technologies that can simplify 
the process to make the products faster to manufacture and cheaper for the 
farmers.
6  Barriers preventing adoption and how to overcome 
them
For decades, many agricultural innovations have been developed for adoption 
by smallholder farmers to achieve higher yields. However, adoption at scale 
is not always successful. There are intrinsic and extrinsic factors impeding 
technology adoption. Some intrinsic factors are linked to limited familiarity with 
the innovations and lack of demonstration of effectiveness in real-life farming 
situations.
Other factors impeding the adoption of technologies include negative 
attitudes to innovation, lack of knowledge, low willingness to adopt innovations 
at the early stage of their development, perceived complexity and relevance 
to smallholder farmers as well as limited availability (Kuntosch and König, 
2018; Naswem and Ejembi, 2017). Broader factors are farmers’ socioeconomic 
characteristics, political conditions, high cost for perceived benefits, limited 
access to inputs, low motivation and adverse attitude toward risk and/or 
change (Meijer et al., 2015). In some cases, causes for low adoption are poor 
Figure 2 (Continued)
The formulated product is then transported via an elevator to the packaging system 
(6) where it is bagged, sealed, baled and finally placed in a storage area (7). (f). The 
final formulated product (i.e., roasted sorghum coated with spores of the four active 
ingredient atoxigenic genotypes, a polymer and a blue food colorant) in an open bag 
for demonstration purpose; a bag of 5 kg of an Aflasafe product contains only 0.1 g of 
active ingredient atoxigenic genotypes.
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20  Bioprotectants to keep foods safe from aflatoxin contamination
communication strategies that fail to clearly convey the value and benefits of 
the innovation.
A particular problem has been low awareness of aflatoxin among farmers, 
traders, regulators and the population in general. Aflatoxins cannot be seen or 
smelt and do not reduce yields. Many markets do not provide incentives for 
production of aflatoxin-safe crops. Policies to prevent trade of contaminated 
crops are often poorly planned and enforced. In some cases, farmers simply do 
not know about and/or do not have access to products.
To deal with these challenges, scaling of aflatoxin biocontrol required 
developing linkages between farmers with aflatoxin-conscious buyers willing 
to pay a premium for high-quality, aflatoxin-safe crops. In addition, aflatoxin 
management requires effective practices across the value chain. This required 
an integrated aflatoxin management system with biocontrol as a cornerstone 
(Bandyopadhyay et al., 2019b).
Large-scale adoption of biocontrol was first attempted in Nigeria, through 
the AgResults Aflasafe Challenge (https://agresults .org /projects /nigeria), 
which converged several elements of aflatoxin management to address the 
problem. The Challenge relied on a pull mechanism in which public or private 
enterprises received incentives only if they delivered predetermined results. 
It is believed that pull mechanisms led by the private sector may be more 
effective than push strategies (upfront payments on the promise that results will 
be delivered) in overcoming constraints in scaling technologies for smallholder 
farmers (Kubzansky et al., 2019). The Challenge offered per-unit cash incentives 
to micro, small and medium enterprises handling Aflasafe-treated maize grains, 
referred to as implementers. The larger the quantity of Aflasafe-treated grains 
the implementers aggregated, the bigger were the incentives and potential 
income from sale of premium, aflatoxin-compliant maize. With time, the per-
unit incentives were reduced.
Between them, the implementers had thousands of smallholder farmer 
customers. They educated farmers on the need for and benefits of aflatoxin 
control, sold/provided biocontrol products to them, trained them how to use 
both the product and other aflatoxin management practices, facilitated access 
to technical knowledge and inputs to increase crop yield, aggregated grains 
from the farmers, got the grain lots tested for aflatoxin content and marketed 
the biocontrol-treated maize to aflatoxin-conscious buyers who offered them a 
premium for the aflatoxin-reduced maize.
The Challenge began in 2013 and ended in September 2019. During 
this period, 41 implementers worked with nearly 76 000 smallholder farmers 
who produced more than 315 333 tons of maize earning more than US$3 m 
in incentives and more than US$ 5.3 m in premiums from the market. Over 
95% grain lots had <20 ppb aflatoxins (US regulatory level); >90% with <4 ppb 
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Bioprotectants to keep foods safe from aflatoxin contamination 21
(EU) regulatory level (https://agresults. org /projects/ nigeria; Bandyopadhyay 
et al., 2019a). An external evaluation of the Challenge found that the annual 
net income from maize grown increased by US$318 (16%) per smallholder, 
and average consumption of Aflasafe-treated maize increased by 0.02 kg 
per day or 13% of daily consumption (Narayan et al., 2020). The Challenge 
also provided opportunities to tens of thousands of maize smallholder 
farmers to move from subsistence to commercial agriculture across 
Nigeria.
7  Scaling up aflatoxin biocontrol technology
Aflasafe products are innovations developed through collaboration between 
international public organizations and national agricultural systems using 
public funding. However, making these products available and accessible to 
users requires commercial investment in a manufacturing plant, distribution 
and marketing. Relying entirely on traditional approaches, which consist of 
transferring the innovation to national agricultural and extension systems to 
promote, may not be necessarily appropriate.
To identify the best pathway for scaling in each country, IITA and partners 
had to ask the right questions. Among them were the following: Is there a 
business case for farmers and other businesses to use the product? If so, is 
there an incentive for the private sector to invest in product manufacturing, 
distribution and market development? If not, is the public sector ready to lead 
the scaling of the innovation? Are there any opportunities for public–private 
partnerships in scaling? Responding to these questions has informed the 
unique three-phase technology transfer and commercialization approach 
employed by IITA and partners through the Aflasafe Technology Transfer and 
Commercialization (ATTC) project to scale up the use of Aflasafe in different 
African countries.
Phase 1. Developing the commercialization strategy. Countries differ 
widely in private sector development, cost of inputs, market structure, 
awareness of the risk from aflatoxin and the existence and enforcement 
of food-safety regulations. A one-size-fits-all approach will not work. 
A commercialization strategy is the first step in tracing the path to take 
Aflasafe to market. The strategy identifies drivers of demand, the options 
to meet demand and the enabling interventions required to increase 
product uptake in each country. It provides key market, economic and 
financial analyses that any potential investor would first want to know 
before considering an investment in manufacturing and distributing 
Aflasafe.
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22  Bioprotectants to keep foods safe from aflatoxin contamination
Phase 2. Selecting investors and transferring the technology. Investor 
selection involves an iterative solicitation and review process to identify 
the most qualified manufacturing and/or distribution firms in the target 
countries following three interrelated steps: (i) hosting the investor forum, 
(ii) selecting the investor and (iii) formally transferring the technology. 
The investor forum mobilizes stakeholders from the public and private 
sectors with interests in the maize, groundnut and sorghum value chains 
and/or agricultural industries. The forum aims to present the investment 
opportunity and attract investor interest. After the forum, IITA sends a call 
for expressions of interest to select investors. Eligible businesses must 
demonstrate their motivation to nurture and grow the Aflasafe business 
line through to delivery to farmers. Shortlisted applicants are invited to 
submit a full business plan with supporting documents for evaluation. 
The next level of screening is the assessment of business plans and a 
pitch competition by investors in front of an advisory board, which selects 
the investor to whom the product manufacturing and distribution is 
licensed. The signing of a TTLA with the chosen investor is the culmination 
of the selection process for formally transferring the technology. This 
legal document sets the terms and conditions under which IITA grants 
limited non-transferable and non-sub-licensable rights for manufacturing, 
distribution and sale of the product in line with CGIAR Principles on 
the Management of Intellectual Assets. The TTLA provides incentives 
for private sector investment, balancing company profit requirements, 
affordability for farmers and IITA’s obligation to disseminate international 
public goods. The TTLA also sets out manufacturing and distribution 
targets that the partner is expected to meet and lays out the period 
covered by the agreement.
Phase 3. Implementing the business plan. Once the TTLA is signed, IITA 
works with the selected partners to transfer the technology know-how and 
additionally provides technical assistance in implementing the business 
plan. The transfer of knowledge takes various forms depending on the 
partner’s capacities and needs. ATTC’s support package includes training 
technical and sales staff on the technology. To grow market demand, IITA 
also provides technical assistance for structured awareness-raising and 
demonstration of the economic and social value of the product to different 
market segments using business case studies. Finally, IITA supports the 
setting up of their factory, quality control and specialized staff training. 
Standard operating protocols for various manufacturing and quality 
control processes are also provided.
In all countries, the commercialization through a public–private partnership 
was the preferred pathway identified by stakeholders. Private companies lead 
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Bioprotectants to keep foods safe from aflatoxin contamination 23
commercial operations upstream and downstream, while the public sector is 
committed to investing in awareness-raising and enabling policies. IITA has 
licensed four private companies to manufacture and distribute Aflasafe products 
in Senegal and The Gambia (both countries constituting one territory), Nigeria, 
Tanzania and Mozambique. The manufacturers in Senegal, Tanzania and Nigeria 
have so far invested more than US$ 5 m in constructing factories. In Kenya, a 
government institution manufactures the product, while a private company has 
the distribution license. Four other private companies are currently distributing 
Aflasafe products in Ghana, Burkina Faso, Malawi, Mozambique and Mali.
Up to December 2020, manufacturers have produced over 4000 tons 
of Aflasafe products, enough to cover more than 400 000 hectares of maize, 
groundnuts and sorghum. Much of the product sale was directed at business-
to-business and business-to-government clients. Usage was concentrated 
in the maize and groundnut value chains where awareness of the negative 
impacts of aflatoxin is high. Aflasafe is rarely sold at the retail level, except 
in Kenya. In most cases, farmers access Aflasafe as out-growers through a 
package of inputs provided by small and medium aggregation businesses. 
When they are not in such contractual relationships, farmers receive the 
product through Ministries of Agriculture that distribute limited quantities 
at a subsidized price to raise awareness about the product. For example, 
the Central Bank of Nigeria has included Aflasafe in the Anchor Borrowers 
Scheme through which farmers receive subsidized products for use in maize 
and groundnut fields. In addition to positive food safety, trade and income 
improvements, there are other positive outcomes. Two examples are shown 
in Boxes 1 and 2.
Box 1 Maize in Kenya
Maize is the major staple of Kenyans. The national government’s 
food security flagship Galana-Kulalu irrigation scheme began in 
2015. The objective of Galana-Kulalu was to make Kenya food 
secure. Unfortunately, Galana-Kulalu is in an aflatoxin-prone area. 
The National Irrigation Board (NIB), which was responsible for 
the project realized that the maize cannot be fed to people unless 
aflatoxin contamination is reduced below the regulatory level of 10 
ppb. Therefore, NIB treated all maize in Galana-Kulalu with the Kenya-
specific biocontrol product. Nearly all (about 99%) of the scheme’s 
5910 tons maize was aflatoxin-compliant by Kenya’s standards, while 
96% met the EU standard of 4 ppb. Without treatment, much of the 
maize would have been lost to aflatoxin, defeating food-security 
goals. The scheme’s aflatoxin-safe harvest was used to feed for 1 
month nearly half a million (492 534) of the regions’ most vulnerable 
people (Bandyopadhyay et al. 2019b).
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24  Bioprotectants to keep foods safe from aflatoxin contamination
Box 2 Groundnut in The Gambia
For decades, people have been suffering from continuous aflatoxin 
exposure. In addition, the country lost the ability to produce groundnut 
with enough quality for premium European markets. The locally 
produced groundnut ends up in the local markets, creating high 
aflatoxin exposure. Recently, farmers working with the National Food 
Security, Processing and Marketing Corporation (NFSPMC) began 
to use biocontrol on groundnut crop and are now able to produce 
aflatoxin-safe crops that meet the EU standards. The re-launch of the 
long-lost groundnut export sector was realized due to the availability 
of Aflasafe coupled with other effective aflatoxin management 
strategies. In addition, safer groundnut is being produced for the local 
population leading to positive health and economic impact.
https://trade4devnews .enhancedif .org /en /impact -story /detoxifying 
-crops -gambia -ground 
The experience of the 18-year process of developing Aflasafe from discovery to 
delivery has provided a number of lessons:
• The balance between the protection of the International Public Good 
(IPG) and private sector investment is critical for sustainability. The TTLA 
has proven to be an effective tool to protect both the IPG and the private 
sector company’s investment. Granting exclusive rights for 5 years was 
necessary to attract private sector investment. This has been possible by 
limiting sub-licensing and transfer of exclusive rights to third parties and 
by introducing key performance indicators, targets and pricing parameters 
in the TTLA.
• The right mix of policy and market incentives is required to accelerate 
uptake. Since food safety is not as rigorously regulated as it should be 
in most countries, the private sector companies interested in upgrading 
the agricultural value chains need to send a strong signal to farmers 
and intermediaries by rewarding quality. To sustain such action and thus 
assure safe food for all, governments should formulate and promote 
appropriate food-safety policies and regulations. Endorsement by 
Ministries of Agriculture increases the trust of users in the technology. 
Finally, collaborative partnerships between the public and the private 
sector to educate value-chain actors and food consumers might increase 
the demand for safe food and, thus for use of biocontrol as a mitigation 
tool.
• Aflasafe is not a traditional agricultural input because it does not increase 
yield, nor is it designed to do so. The marketing strategy for Aflasafe should 
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Bioprotectants to keep foods safe from aflatoxin contamination 25
be innovative since safety improvement through aflatoxin reduction is not 
detectable unless verified by chemical tests. Regardless of its effectiveness, 
it is the businesses’ ability to deliver tangible value to customers that 
will trigger and sustain use at scale. The use of marketing strategies that 
had been successful for other product lines did not work for Aflasafe. A 
period of experimentation with the business model is required to increase 
investors’ confidence to finance manufacturing and distribution.
• Aflasafe scale-up should start with tailored business cases for aflatoxin-
conscious market segments. The level of awareness about aflatoxin is 
low and highly variable within and across countries. As part of business 
development, companies should focus first on segments of the market 
that are most affected and willing to pay for a solution. By first focusing on 
these low-hanging fruit, companies are assured of revenue streams while 
investing and developing strategic partnerships to unlock the other more 
elusive market segments.
8  Current challenges and needs
There are several challenges in large-scale adoption of biocontrol and other 
technologies for aflatoxin mitigation in Africa. Multifaceted challenges are 
sociological, economic, regulatory, institutional, policy related and technical 
in nature. Some of these challenges are common to many agricultural 
technologies in Africa. In addition, several gaps in knowledge about biocontrol 
technology remain. Concerns about biocontrol have been expressed. Some of 
these concerns include:
• use of sorghum (a food crop) as a carrier.
• drought stress impacts on biocontrol performance.
• risk of allergies (e.g., skin, eyes).
• accumulation of other secondary metabolites.
• influence of biocontrol on soil microbiome.
These issues have been discussed in Bandyopadhyay et al. (2016).
Substantial work is necessary to build awareness of the negative 
consequences of aflatoxin contamination on health and trade. Improved 
capacity to monitor, regulate and control aflatoxins is required in many countries 
in SSA. Policies to promote aflatoxin prevention and control are relatively few. 
There is a need to implement policies to develop standards based on dietary 
habits, raise awareness among key stakeholders on control strategies and 
regulations and reinforce food safety risk assessment, analysis and inspection. 
Effective legislation is needed for improving food safety in countries affected 
by aflatoxin contamination.
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26  Bioprotectants to keep foods safe from aflatoxin contamination
The preponderance of informal markets and lack of a price premium for 
aflatoxin-safe crops are major impediments for adoption of aflatoxin control 
technologies. Creation of demand for aflatoxin-safe products at the end 
market can stimulate adoption of aflatoxin management practices, including 
biocontrol, by farmers. Feed, poultry and food-producing companies prefer 
domestic aflatoxin-compliant crops and are willing to pay farmers/organizations 
premium prices for locally produced safe crops, which is cheaper than 
importing crops (Ayedun et al., 2017; Johnson et al., 2020; Migwi et al., 2020). 
Links between farmers/organizations producing safe crops and customers 
need to be facilitated.
In many countries in SSA, the human and infrastructural capacity to test 
crops for aflatoxins is inadequate. This has serious repercussions because 
most crops are commercialized and consumed without knowing if they are 
safe, especially those offered in local, unregulated markets. Regulators need 
to use appropriate sampling protocols and affordable testing systems to 
rapidly monitor and isolate contaminated crops to ensure that unsafe crops 
are not sold. Effective systems are also required to trace grain/crop lots that are 
contaminated to ensure appropriate disposal.
The initial emphasis of the Aflasafe Initiative was on the development 
of locally tailored national Aflasafe products composed of native atoxigenic 
active ingredients. Later, development of regional products containing active 
ingredients co-distributed in multiple countries in a region became a preferred 
approach to hasten development, testing, registration and commercialization 
of products. However, there are challenges for countries to mutually recognize 
product effectiveness, toxicological and ecotoxicological data obtained in 
other countries. There is a need to establish harmonized regional regulatory 
frameworks for biocontrol agents and to consider data already generated 
by neighboring countries to expedite the registration process of biocontrol 
agents. The current practice of naming national Aflasafe with a country suffix 
is also a hindrance to acceptance of regional products. Farmers, policy makers 
and Aflasafe marketing companies in one country (say Burundi) sometimes 
have reservations to use a product with a suffix of another country (e.g., Aflasafe 
KE01 of Kenya). Branding of products must be flexible to avoid problems 
associated with national pride and political considerations.
Despite the efficacy of Aflasafe products and their increased use, some 
basic and practical questions about the technology remain unanswered. These 
are related to agronomic practices, soil processes, product performance, 
product composition/formulation and product safety. A few of these questions 
are as follows:
• What is the influence of intercropping on efficacy? 
• Does pesticide use influence product performance? 
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Bioprotectants to keep foods safe from aflatoxin contamination 27
• Does application of Aflasafe influence soil biological processes and other 
toxigenic fungi? 
• Is 2–3 weeks before flowering the appropriate time for application of 
Aflasafe? 
• What is the optimum dose for field application? 
• How much inoculum is carried over from one season to the next? 
• Is once-a-season application necessary if inoculum is carried over from 
one season to the next?
• What impact will climate change have on product performance?
• What approaches should be explored to improve product performance 
under extended drought?
• How can loss of inoculum in the field be reduced from granivores since the 
carrier of Aflasafe is sorghum grain?
These and other questions demonstrate that it is necessary to critically examine 
various agronomic, biological and environmental factors to better understand 
biocontrol and improve its performance.
Several reports have suggested that the use of biocontrol products could 
result in superior Aspergillus strains with high competitiveness and with high 
aflatoxin production ability due to potential genetic recombination between 
aflatoxin producers and atoxigenic fungi in field conditions (Moore, 2015; 
Damann, 2015; Olarte et al., 2012; Ehrlich et al., 2015). Genetic recombination 
has been reported in multiple laboratory studies and in the field after exposing 
fungi incubated in the lab to natural populations. If genetic recombination does 
occur frequently in a population, we suggest that this would be beneficial in 
field conditions because lower aflatoxin production potentials would result 
in the progeny (Bandyopadhyay et al., 2016). Relatively recently, genetic 
recombination has been reported as beneficial, and atoxigenic genotypes with 
the ability to recombine are being sought in the United States (Moore, 2021; 
Horn et al. 2009b). Despite these challenges and the need for more information, 
the value of biocontrol as a component of aflatoxin mitigation strategy is largely 
accepted (Moore, 2021; Kagot et al., 2019; Sarrocco et al., 2019).
9  Some final thoughts
It has been a long journey toward Aflasafe development and commercialization 
in Africa. There are several key elements in the path to reach the current stage 
of aflatoxin biocontrol development in Africa. Aflatoxin is a critical food safety 
challenge affecting health, trade and food security. About two decades ago, 
aflatoxins were largely unknown to key stakeholders in agriculture and health. 
Meeting this challenge required education of diverse stakeholders to explain the 
negative consequences of aflatoxins on health, income, trade and food security 
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28  Bioprotectants to keep foods safe from aflatoxin contamination
(Bandyopadhyay et al., 2016). Once the dangers of aflatoxins were known 
among key stakeholders, and after a solution to the contamination process was 
developed, champions of aflatoxin mitigation strategies (with biocontrol as a 
centerpiece) emerged because of their understanding of the technology and its 
value for public health. Such champions of aflatoxin control included leaders of 
farmers’ organizations, program officers in the donor community, officers in the 
health and agricultural sectors and high-level researchers and administrators 
who valued aflatoxin control as a key component to achieve national public 
health. Aflatoxin control policies and strategies were then promoted by public 
sector stakeholders and organizations. This sparked the interest of the private 
sector for uptake and scale-up of the technology.
Reaching the current stage would not have been possible without support 
from the donor community and partnerships with numerous institutions for 
development, testing, registration and making aflatoxin biocontrol products 
commercially available to smallholder farmers. Institutions and governments 
that have funded the aflatoxin control program of IITA and partners are 
mentioned in the acknowledgment section. The donor community, through 
diverse projects, allowed the Aflasafe Initiative to create lasting partnerships 
with public sector institutions to develop and register products, public–
private sector investors to manufacture and distribute the Aflasafe biocontrol 
technology and local and regional grain aggregators/exporters/industries to 
be able to procure protected crops from smallholder farmers with access to 
biocontrol.
Although the technology was initially developed by a team of plant 
pathologists supported by laboratory technicians, it was clear since the onset 
of the Aflasafe Initiative that appropriate, scalable aflatoxin management 
strategies needed more than the expertise of scientists. Therefore, over the 
years, a team was built with members from diverse disciplines, many of them 
unconventional for traditional agricultural systems and even less conventional 
for research to benefit smallholder farmers. With a team of plant pathologists, 
food scientists, plant breeders, industrial engineers, postharvest specialists, 
biocontrol experts, social scientists, commercialization specialists, administrative 
specialists, monitoring and evaluation personnel, communication specialists 
field and laboratory technicians, it has been possible to develop, test, register 
and commercialize aflatoxin biocontrol.
The Aflasafe multidisciplinary team had a mission-driven focus to scale 
up innovations beyond product development for the benefit of people with 
the motto: ‘Safe crops, better health and higher income’. That mission is being 
accomplished by convergence of diverse technical, social, regulatory and 
structural solutions to allow moving a research technology/concept into the 
hands of smallholder farmers for their own benefit and the consumers, food 
and feed manufacturers and industries that procure aflatoxin-reduced crops. 
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Bioprotectants to keep foods safe from aflatoxin contamination 29
Such a broad mission is not an easy task or one accomplished in a few years. 
It can take decades to develop technologies and have them available at scale 
and adopted by smallholder farmers.
10  Conclusion
Aflatoxin contamination of several crops continues to be a major problem 
across SSA. However, farmers, civil society, governments, development 
community and private sector, among others are now realizing that there 
is no food security without food safety. Failures in food safety are costly for 
developing countries. We have provided a general review of the aflatoxin 
problem in Africa and the causal agents of contamination, as well as the 
genesis of aflatoxin biocontrol product development in Nigeria, the beginning 
of the manufacturing in the laboratory and its transition to an industrial 
process and its subsequent expansion to >20 countries in Africa using diverse 
approaches. The transition required venturing into unconventional areas for a 
research program and for which the group had to recruit engineers, business, 
commercialization and communication experts. The efficacy of biocontrol and 
other management practices in significantly reducing aflatoxin contamination 
has been extensively proven. Often, technologies designed for use by 
smallholder farmers are developed but are not adopted or scaled up due to 
constraints to make them available to the end users. IITA and partners not only 
improved and adapted aflatoxin biocontrol for Africa but, with the support of 
partners, have also taken these bioprotectants through product development, 
registration, manufacturing and commercialization. In the process, awareness 
of the aflatoxin problem was raised globally and actors across the value 
chain were educated on the health, economic and trade impacts of 
aflatoxin.
Evidence and experience are beginning to show that aflatoxin biocontrol 
is substantially improving the long-term health, well-being and livelihoods of 
millions of rural African farming families. Integrated aflatoxin management 
is making food supplies safer, increasing the value of harvests, improving 
the health and value of livestock and unlocking new markets and economic 
opportunities across value chains. More efforts are needed to have aflatoxin 
management programs used at scale in countries where these practices are 
currently used and to expand those practices to other susceptible crops. In 
addition, similar programs need to be designed, tailored and fine-tuned in 
countries where aflatoxin contamination is prevalent. Because of the importance 
of the problem, the awareness being created and the availability of efficient 
management tools, we are confident that the aflatoxin problem across SSA will 
be systematically addressed to reduce the devastating effects that the toxins 
cause.
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30  Bioprotectants to keep foods safe from aflatoxin contamination
11  Where to look for further information
11.1 F urther reading
• For a comprehensive coverage on mycotoxins with a focus on Africa, see 
J. F. Leslie, R. Bandyopadhyay and A. Visconti (Ed.). (2008), Mycotoxins: 
Detection Methods, Management, Public Health and Agricultural Trade. 
Wallingford: CAB International, pp. 496.
• Scaling up of aflatoxin biocontrol in Africa is covered in the Strategic 
Brief ‘Lessons Learned on Scaling Aflasafe® through Commercialization 
in Sub-Saharan Africa’ available at https://a4nh .cgiar .org /files /2020 /08 /
StrategicBrief _2020 _A4NH_ Aflasafe _web -1 .pdf.
• Visit www .aflasafe .com (specially under the tabs ‘Resources’ and 
‘Multimedia’) for more detailed information of aflatoxin biocontrol in Africa.
• For a good explanation of biocontrol from research to delivery in 
the United States, see Cotty, P. J., Antilla, L. and Wakelyn, P. J. (2007), 
Competitive exclusion of aflatoxin producers: Farmer driven research and 
development, in C. Vincent, N. Goettel and G. Lazarovits, (Eds), Biological 
Control: A Global Perspective. Wallingford: CAB International, pp. 242–253.
• World Health Organization & Joint FAO/WHO Expert Committee on Food 
Additives (83rd, 2017: Geneva, Switzerland). (2017), Evaluation of certain 
contaminants in food: eighty-third report of the Joint FAO/WHO Expert 
Committee on Food Additives. WHO Technical Report Series; 1002 World 
Health Organization. https://apps .who .int/ iris/ handle/ 10665/ 254893
11.2 K ey journals and conferences
• World Mycotoxin Journal, Toxins, Food Additives and Contaminants, and 
Biological Control are journals where aflatoxin biocontrol literature is often 
published. 
• Gordon Conference on Mycotoxins and Phycotoxins and The World 
Mycotoxin Forum organize regular conferences well attended by members 
of the mycotoxin community.
• International Society of Microbiology and African Society of Microbiology 
frequently organize international conferences on various themes related 
to mycotoxins.
• American Phytopathological Society organizes Annual and Divisional 
meetings that sometimes include symposia on biocontrol.
11.3 M ajor international research projects
• The Africa-wide Aflasafe Initiative is composed of multiple projects on 
discovery to delivery of aflatoxin biocontrol products in Africa, https://
aflasafe .com/ 
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Bioprotectants to keep foods safe from aflatoxin contamination 31
• PACA of the African Union Commission is a collaboration that aims 
to protect crops, livestock and people from the effects of aflatoxins. By 
combating these toxins, PACA is contributing to improve food security, 
health and trade across the African continent. https://www .afl atox inpa 
rtnership .org /about/ 
• USDA-ARS research project on Improved Environmental and Crop Safety 
by Modification of the Aspergillus flavus Population Structure, https://www 
.ars .usda .gov /research /project/ ?accnNo= 430864 
• MycoKey was a research project (under European Commission under 
Horizon 2020 programme) on integrated and innovative key actions for 
mycotoxin management in the food and feed chain, http://www .mycokey 
.eu/
• MyToolBox was a research project (under European Commission under 
Horizon 2020 programme) on Safe Food and Feed through an Integrated 
ToolBox for Mycotoxin Management, https://www .mytoolbox .eu/
12  Acknowledgment
The Aflasafe Initiative has been funded by The Bill & Melinda Gates Foundation 
(BMGF; OPP1007117, OPP1133356); the United States Agency for International 
Development (USAID); Meridian Institute on behalf of the Partnership for 
Aflatoxin Control in Africa (PACA); both Agricultural Research Service and 
Foreign Agricultural Service of the United States Department of Agriculture; 
Bundesministerium für wirtschaftliche Zusammenarbeit und Entwicklung 
(BMZ, German Federal Ministry for Economic Cooperation and Development); 
AgResults [a collaborative initiative between BMGF, Australia’s Department of 
Foreign Affairs and Trade (DFAT), the Department for International Development 
of the United Kingdom (DFID), Global Affairs Canada and USAID]; MycoGlobe, 
MycoRed and MycoKey funded by the European Union Commission; Austrian 
Development Cooperation; Commercial Agriculture Development Program of 
the Government of Nigeria; French Development Agency; Royal Government 
of Norway; The World Bank, The Food and Agriculture Organization, CGIAR 
A4NH Research Program, CGIAR MAIZE Research Program, among others. 
We thank numerous officials from the public institutions and private sector for 
providing direct and indirect support to the Initiative. We are grateful to the 
thousands of farmers who graciously and willingly participated in some aspects 
of product development and testing.
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