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1 - Eating Wild Animals

Published online by Cambridge University Press:  25 August 2022

Julia E. Fa
Affiliation:
Manchester Metropolitan University and Center for International Forestry (CIFOR), Indonesia
Stephan M. Funk
Affiliation:
Nature Heritage
Robert Nasi
Affiliation:
Centre for International Forestry Research (CIFOR), Indonesia

Summary

In this first chapter we describe the importance of hunting and meat eating to humans and how this has influenced the evolution of the species. This is followed by a brief review of how prevailing ecological conditions influence human’s dependence on plants or animals to survive at different latitudes. We then document which animal species and groups are currently hunted and used for food, discuss the issue of wild meat markets particularly in Africa and set out our current knowledge of rates of wild meat consumption in different parts of the world. The chapter ends with an explanation of why this book has been conceived and how we can use accumulated knowledge on this subject to reduce wild meat exploitation to sustainable levels, by outlining the main pathways that enable us to understand human predatory behaviour and ways of balancing human and wildlife needs in the future.

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Chapter
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Publisher: Cambridge University Press
Print publication year: 2022
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1.1 Introduction

Wild animals, plants and their products are harvested for purposes ranging from food to medicine. Humans have exploited wild animals and plants throughout their evolution (Hill Reference Hawkes, Hill and O’Connell1982) and contemporary aboriginal and rural peoples still rely on them for their daily needs (Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005). The meat of wild animals or wild meat (see Box 1.1) is still a crucial part of the staple diet of millions of families in the tropics and subtropics since it is often the most available and widely used source of animal protein (Abernethy et al. Reference Abernethy, Coad, Taylor, Lee and Maisels2013; Fa et al. Reference Fa, Currie and Meeuwig2003), and is also important for its micronutrient content (Golden et al. Reference Brashares, Golden, Weinbaum, Barrett and Okello2011; Sarti et al. Reference Sarti, Adams and Morsello2015; Sirén & Machoa Reference Sirén and Machoa2008). Wild meat is central to the livelihood strategies of the poor since it can constitute a significant source of revenue, especially for rural families (Brown & Williams Reference Brown and Williams2003; Milner-Gulland & Bennett Reference Milner-Gulland and Bennett2003). It is also consumed regularly by urban peoples more as a commodity product than as a necessity.

Box 1.1 What is wild meat?

For some time, the term bushmeat was used as a catchall phrase for the meat of wild animals. The term, which originated in Africa, referred to the meat from animals found in forests and savannas; these habitats are commonly referred to as ‘bush’, hence the name bushmeat. The expression is assumed to have originated in British colonial times but may pre-date this era. The native catechist, T. C. Brownell, in southeast Liberia, mentioned he was offered on 29 March 1857 something to eat by the head-man of the interior village of Nyambo ‘which he called bush meat, but it had such a human aspect that I laid it aside, and awaited the repast which was preparing’ (quoted in Scott Reference Scott1858, p. 295). Liberia was the first African republic to proclaim its independence in 1822.

Nasi et al. (Reference Nasi, Brown and Wilkie2008) defined bushmeat as any ‘non-domesticated terrestrial mammals, birds, reptiles and amphibians harvested for food’’. Insects, crustaceans, grubs, molluscs and fish are excluded from this classification. But, although the term has been employed to refer to the meat of wild animals from regions other than Africa, there has been a recent move towards using the more generic term ‘wild meat’, since it has no geographical associations. Thus, following its adoption by the IUCN-World Conservation Union General Assembly Resolution 2.64 (IUCN World Conservation Congress 2000), Coad et al. (Reference Coad, Fa and Abernethy2019) use the term wild meat as terrestrial animals used for food in all parts of the world. However, the Convention on Biological Diversity ’s (CBD) (2012) description of wild meat hunting as ‘the harvesting of wild animals in tropical and subtropical countries for food and for non-food purposes, including for medicinal use’ is imprecise since wild meat is only one of the products derived from the hunting of wild animals anywhere in the world.

In this book, we use the Coad et al. (Reference Coad, Fa and Abernethy2019) definition of wild meat as any non-domesticated terrestrial mammals, birds, reptiles and amphibians harvested for food. We concentrate on the consumption and trade of wild animals as food and the implications of these activities on the fauna in the region of the globe found within a band on either side of the equator from 23.5°N, and 23.5°S; the Tropic of Cancer and the Tropic of Capricorn, respectively. This portion of the world known more generally as the tropics is important in not just harbouring most of the Earth’s biodiversity but also millions of peoples who still depend on wild animals for their food security and livelihoods. A more detailed description of the extent and characteristics of the tropics and subtropics are given in Chapter 2.

Although other animals comprise important dietary items in the tropics and subtropics, in this book we focus only on vertebrates because they constitute most of the terrestrial wild animal biomass consumed by humans in these regions. Mammals make up the largest proportion of all animals eaten and traded, both in terms of weight (biomass) and numbers. The cultural preference for wild meat is not due to a lack of awareness or entrepreneurship but ultimately relates to the low productivity of domestic livestock in many tropical and even subtropical conditions. For poor farmers in tropical environments, as seen in the Brazilian Amazon (Carvalho et al. Reference Carvalho, de Aguiar and Amaral2020), raising livestock for their meat has high risks and investment costs, making successful livestock husbandry rarely a feasible option. In situations where livestock can be kept, such as the ever-present domestic chicken, these animals are often more a form of reserve banking, or to satisfy cultural needs. In contrast, wild meat is a resource that is freely available for use, so the cost of its procurement is always lower than the cost of raising livestock. However, in recent decades the exploitation of wild animals for their meat has moved from just being a source of food and income for rural communities or Indigenous Peoples, to a commodity exploited for profit-making reasons by supplying the urban areas. Such increase in demand for wild meat has been brought about by accelerating population growth, use of more modern and efficient hunting techniques, and opening of remote areas to commercial hunters by extractive industries. As will be documented in detail in this book, there is an accumulation of evidence that this is seriously threatening wild animal populations and human food security in many areas.

For the millions of Indigenous and non-Indigenous communities in tropical and subtropical environments, often among the world’s rural poor, wild meat is frequently the most consumed source of protein, vitamins and minerals (Van Vliet et al. Reference Sartoretto, Tomassi, Karpe, Van Vliet, Nguinguiri, Cornelis and Le Bel2017). Wild animal meat can also be traded by and between rural communities and transported beyond its point of extraction. Because of its value-to-weight ratio and great transportability if smoked, the wild meat trade has risen dramatically, fuelling in some cases unsustainable extraction rates (Chapter 6) as shown for West and Central African countries (Fa et al. Reference Fa, Currie and Meeuwig2003; Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001). Commercial hunting for wild meat has grown in importance in recent decades (see Section 1.7), with increasing numbers of hunters currently either earning or supplementing their incomes with the sale of meat (Milner-Gulland & Bennett Reference Milner-Gulland and Bennett2003). This intensifies hunting levels and reduces the sustainability of numerous wildlife species, largely because it enlarges the population density of consumers eating meat from a given habitat area (cf. Bennett & Robinson Reference Auzel, Wilkie, Robinson and Bennett2000). Hunting of wildlife is still the single most geographically widespread form of resource extraction in the tropics (Fa et al. Reference Aviram, Bass and Parker2002, Reference Altrichter2005; Milner-Gulland & Bennett Reference Milner-Gulland and Bennett2003).

Hunting refers to the act of pursuing and taking wild animals by several means and for different purposes. Wildlife can be hunted for food, trophies (most often skins, teeth, antlers and horns), medicines and other traditional uses (most hard and soft body parts) and as pets (especially primates, birds and reptiles). Hunting occurs in a variety of habitats worldwide (Nasi et al. Reference Nasi, Brown and Wilkie2008). Vulnerability of hunted species varies according to their biological characteristics and the state of the habitats they are found in. Coupled with threats from habitat loss (Laurance et al. Reference Elkan, Elkan, Moukassa, Malonga, Ngangoue, Smith, Peres and Laurance2006; Wright & Muller-Landau Reference Wright and Muller-Landau2006), overhunting can result in the extinction of species, especially of larger-bodied species of mammals and birds that have a naturally low intrinsic rate of population increase (see Chapter 5 & 6). This process, referred to as defaunation (Chapter 2; Dirzo et al. Reference Dirzo, Young, Galetti, Ceballos, Isaac and Collen2014) is an anthropogenically driven cause of species and population extirpations and, critically, of declines in local species abundance of seed dispersers and ‘habitat landscapers’ such as in tropical forests. This changes the long-term dynamics and structure of these ecosystems and ecosystem services (Chapter 6).

As we show in Chapter 2, tropical and subtropical landscapes are heterogeneous, containing diverse animal and plant species that make up a variety of wildlife communities that differ in their dynamics, including contrasting human pressures. Important intercontinental differences exist between tropical and subtropical areas worldwide, but there are significant contrasts in how the faunas in each continent have been affected by unsustainable hunting. In Asian tropical forests, already more than 12 large vertebrate species are known to have become extinct in countries such as Vietnam (Bennett & Rao Reference Bennett, Rao, Mainka and Trivedi2002). The problem is perceived to be presently more acute in the heartlands of West and Central Africa, but progressively worsening even in the remotest parts of Latin America (Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001). Such dissimilar trajectories in actual and potential faunal loss between continents follow the major impacts of development and forest loss, essentially linked to human population growth that drive agricultural expansion, logging, development and other human activities. The situation in Asia is also unlike other continents, because of the reliance on large-scale wildlife trade involving long-distance, international supply chains (Duckworth et al. Reference Duckworth, Batters and Belant2012). Demand for land, timber and non-timber forest resources has exploded throughout Asia as a result of rapid economic growth (Bennett & Rao Reference Bennett, Rao, Mainka and Trivedi2002). The region is a key supplier to the international wildlife market, both legal and illegal. Despite there being intercontinental dissimilarities, at a global scale there is now sufficient evidence to highlight that the plight of many species, in particular mammals, is primarily due to overhunting (see Ripple et al. Reference Ripple, Abernethy and Betts2016 p. 20016). We discuss the impact of unsustainable hunting in Chapters 2 and more in detail in Chapter 6 in this book.

We begin this introductory chapter with a description of the importance of hunting and meat eating to humans and how this has influenced the evolution of the species. This is followed by a brief review of how prevailing ecological conditions influence dependence on plants or animals to survive at different latitudes. We then document which animal species and groups are currently hunted and used for food, discuss the issue of wild meat markets especially in Africa and present our current understanding of wild meat consumption by diverse groups of people in different parts of the world. The chapter ends with the reasons for writing this book and explains how we can use the accumulated knowledge on this subject to help reduce wild meat exploitation and ways of balancing human and wildlife needs in the future.

1.2 Meat Eating and Hunting in Human Evolution

Similar to modern chimpanzees, the earliest hominins consumed large quantities of fruit, leaves, flowers, bark, insects and some meat (Watts Reference Watts2008). By at least 2.6 million years ago (YA), a remarkable expansion in this diet occurred; some hominins began incorporating meat and marrow from small to very large animals into their diet. Arguably, it was not until at least one million YA that hominids actively hunted animals for food (Potts Reference Potts1996; Walker & Shipman Reference Walker and Shipman1996). Eating meat from hunted animals or from carcasses provides more calories per unit of search time than the collection of plant products (Hill Reference Hawkes, Hill and O’Connell1982). Carrion is thought to have been an early source of high-quality protein for hominids (Binford Reference Binford1981; Blumenschine et al. Reference Blumenschine, Bunn and Geist1987), who may have lacked appropriate technology to capture vertebrate prey. However, populations of chimpanzees and baboons are known to hunt cooperatively (Stanford & Wrangham Reference Stanford and Wrangham1998). This suggests that hominids may also have been social hunters who shared the obtained prey, in addition to actively stealing carcasses, as do other carnivores.

Human hunters have followed a complex evolutionary process. Bipedalism provided greater autonomy for the search and transport of food. The development of intelligence favoured in the first instance the theft of carcasses from other predators, the formation of groups that operated in a coordinated manner to access larger prey, the sequential development of tools to work the carcasses and weapons to defend and hunt, and the establishment of rules for an equitable distribution of the obtained meat (Stanford Reference Hawkes, Stanford and Bunn2001). Competition with other carnivores could have induced the observed increase in body size of primitive hunters (Arsuaga et al. Reference Arsuaga, Martinez and Arnold2014), strategic cooperation, diurnal habits, rapid manipulation of prey and selective capture of smaller ones, in parallel with the progressive expansion of the neocortex and the improvement of cognitive skills and intragroup communication (Pearce et al. Reference Pearce, Stringer and Dunbar2013; Van Valkenburgh Reference Van Valkenburgh, Stanford and Bunn2001).

The conversion of primitive opportunistic hunters into systematic predators could have taken place in a scenario where optimal prey was abundant and predictable, the availability of other food was scarce or unpredictable and would have led to catches providing meat in surplus to the needs of the hunters (Rose Reference Ambrose2001). Such a change would have required the possession of certain intellectual capacities to make decisions, develop cooperative strategies, and to manufacture and manage tools for capturing and processing game (Pearce et al. Reference Pearce, Stringer and Dunbar2013), separating them from other primates (Hill Reference Hawkes, Hill and O’Connell1982).

Cooperative hunting represents a stable evolutionary strategy from the moment Palaeolithic hunters became specialized in the pursuit of large animals (Boesch Reference Boesch1994) – those whose systematic capture is difficult to imagine without adequate technology and social organization (Hill & Hawkes Reference Hill, Hawkes, Hames and Vickers1983; Stiner Reference Stiner1994). As a consequence, this success gave rise to the adequate capture and processing of carcasses, and the selective transport and distribution of the most desirable parts before being consumed. All this process implies the adoption of decisions related to the management of prey species as can be verified from the fossil record and, with appropriate reservations, inferred from the behaviour observed in current hunter-gatherers.

Beginning around 10,000 BP however, the shift from hunting and gathering to domesticated food sources, both animal and plant, resulted in a narrowing of the diet (Larsen Reference Larsen2003). The consequences of this diet shift, from evidence from archaeological human remains worldwide, was a decline in health, including poorer dental health, increased occlusal abnormalities, increased iron deficiency anaemia, increased infection and bone loss (Larsen Reference Larsen2003). New dietary pressures introduced since the Industrial Revolution some 200 years ago have been the result of people’s diets changing far more quickly than genetic adaptation is able to keep up with this change (Eaton et al. Reference Eaton, Eaton and Konner1997). This discordance hypothesis postulated by Eaton et al. (Reference Eaton, Eaton and Konner1997) has been suggested to explain many of the chronic ‘diseases of civilization’. Modern trends in human nutrition, especially after the Second World War, indicate a greater reliance on high-fat meats that, when eaten in excess, promote cardiovascular disease, especially in combination with the more sedentary lifestyles typical of many modern societies.

1.3 Importance of Wild Animal Foods in Human Diets

The relative importance of wild meat and plant consumption patterns can be determined from information obtained from modern-day hunter-gatherer societies (Box 1.2). The emerging patterns reflect regional and ecological specializations that in some groups probably date back to the late Pleistocene Epoch. Data on what types of food are eaten, and the importance of wild meat in particular, result from research conducted within a wide variety of disciplines. While most dietary data collected are behavioural and quantitative, human biological samples (e.g. urine, stool, saliva, serum, blood, dental calculus and hair) allow further insights into the physiological parameters of various modes of human subsistence (e.g. Gurven et al. Reference Gurven, Trumble and Stieglitz2016; Leonard et al. Reference Leonard, Vashro, O’Connell and Henry2015; Pontzer et al. Reference Pontzer, Raichlen, Wood, Mabulla, Racette and Marlowe2012).

Box 1.2 Hunter-gatherers

The earliest definition of a ‘forager’ or ‘hunter-gatherer’ by Woodburn (Reference Woodburn and Gellner1980) is entirely based on their subsistence mode, describing them as members of societies that obtain their food and other requirements directly from the wild. We use both terms interchangeably in this book. Others elaborated the definition as those peoples who specifically collect wild plant foods and game animals with ‘no deliberate alteration of the gene pool of exploited species’ (Panter-Brick et al. Reference Panter-Brick, Layton and Rowley-Conwy2001). This definition is difficult to apply to all of the food consumed by a given population.

In the 1960s, based on diet alone, foraging populations worldwide (as those who consumed 100% of their diet from wild foods) were considered to account for less than 0.001% of the world’s population (Lee & DeVore Reference Lee and DeVore1968). By the mid-1990s, since few of the remaining hunting and gathering groups depended on an entirely wild diet, a population of foragers was redefined as one that ate approximately 10–15% of domesticated foods (Kelly Reference Kelly1995). Presently, if the criterion that foraging populations must consume a diet of more than 90% wild foods is used, no population would meet the designation (Apicella & Crittenden Reference Apicella, Crittenden and Buss2015). Therefore, in the twenty-first century, almost all forager populations consume a mixed diet that includes varying degrees of farmed foods, wild foods, and in some cases nutritional subsidies from governments and aid organizations (Headland & Blood Reference Headland and Blood2002).

Importantly though, hunter-gatherers have also been classified as peoples exhibiting unique social lives, which includes a degree of mobility, group size and/or kinship systems that impact of the use and sharing of resources (Lee Reference Lee1992). Thus, depending on the environments inhabited in line with their social systems, foragers have been classified as ‘generalized’ or ‘immediate return’ versus ‘complex’ or ‘delayed return.’ Immediate return foragers consume their yield shortly after procurement and delayed return foragers store their food for varying lengths of time (Price & Brown Reference Price, Brown, Price and Brown1985; Woodburn Reference Woodburn and Hann1998).

Ecological factors that shape human population processes determine the distribution and abundance of hunter-gatherers worldwide. Using global ethnographic hunter-gatherer data from Binford (Reference Binford2001), Tallavaara et al. (Reference Tallavaara, Eronen and Luoto2018) explored the effects of key environmental variables (net primary productivity, biodiversity and pathogen stress) on hunter-gatherer population densities. Primary and secondary productivity were shown, at least regionally, to have positive effects on hunter-gatherer population density as well as on population home ranges. Hunter-gatherers access food directly from their surroundings (which can vary widely in energy availability) and thus depend on the productivity of wild plant and animal species, where they appropriate only a small fraction of the production. Additionally, biodiversity was shown to play an important role since it influences ecosystem stability – higher biodiversity is linked to temporal stability of aggregate ecosystem properties, such as biomass and productivity. For hunter-gatherers, increased stability of ecosystem-level biomass production decreases subsistence-related risk, and therefore positively affects hunter-gatherer population densities. In contrast, the effects of pathogens on hunter-gatherer abundance are, as expected, negative. Tallavaara et al. (Reference Tallavaara, Eronen and Luoto2018) conclude that subtropical and temperate forest biomes in particular, rather than tropical forests, have the highest carrying capacity potential for hunter-gatherer populations as a result of the balance between disease risk and habitat productivity. These findings document that environmental factors play a key role in shaping global population density patterns of pre-agricultural humans.

Few hunter-gatherer or forager societies exist today, but many are well documented in the ethnographic record. Forager studies have become more popular over the last several decades, being of particular interest to evolutionary, sociological, demographic and human health science studies, as populations increasingly transition into a wage economy (Headland & Blood Reference Headland and Blood2002). Earlier research on these groups was undertaken by anthropologists who assumed that the modern forager existence was a good analogue of the lifestyle that endured everywhere before 10,000 BP. However, one of the greatest obstacles to using foragers as analogues of our ancient ancestors is that virtually all foragers in the ethnographic record have complex technology compared to premodern hominins (Marlowe Reference Marlowe2005). Moreover, as Lee and DeVore (Reference Lee and DeVore1968) suggest, the foragers described may be a biased sample that have persisted because they occupied marginal habitats less coveted by agricultural people, although this contention has later been refuted. Using global remote sensing data to estimate habitat productivity for a representative sample of societies worldwide Porter and Marlowe (Reference Porter and Marlowe2007) showed that foraging societies do not inhabit significantly more marginal habitats than agriculturalists. Nevertheless, forager societies have not remained static, and many have changed their habits and diets because of their association with more food productive agricultural societies. This is clearly the case for some Pygmy communities in the Congo Basin (Dounias & Froment Reference Dounias and Froment2011).

Overview papers detailing contemporary hunter-gatherer diets have emerged as comprehensive and definitive sources of information on forager diets (Binford Reference Binford2002; Cordain et al. Reference Cordain, Miller, Eaton, Mann, Holt and Speth2000; Marlowe Reference Marlowe2005). An important source of calculations of dietary patterns of surviving hunter-gatherer societies have resulted from George P. Murdock’s Ethnographic Atlas; a database on 1,167 societies coded and published in 29 successive instalments in the journal Ethnology, 1962–1980. While valuable, some critics (e.g. Milton Reference Milton2000) suggest that because the data used in these compilations are non-standardized tabulations from ethnically and geographically widespread human populations, this limits finer-scale comparisons. Despite several limitations, data contained in reviews such as Cordain et al. (Reference Cordain, Miller, Eaton, Mann, Holt and Speth2000) are a valuable entry point for discussion of variation among foragers from different latitudinal living environments. Listed populations are categorized by the percentage of their subsistence dependence on various categories of foods (i.e., wild plant foods and wild meat) even though no consistent unit of measurement has been used for each instance of data collection, as explicitly acknowledged by Cordain et al. (Reference Cordain, Miller, Eaton, Mann, Holt and Speth2000).

As expected, the composition of the human diet is extrinsically conditioned by biogeographical and ecological factors. The majority of hunter-gatherer societies, as used in Cordain et al. (Reference Cordain, Miller, Eaton, Mann, Holt and Speth2000), obtained 56–65% of their subsistence (energy) from animal foods (Fig. 1.1a), and predicted macronutrient energy intake ranges were carbohydrate 22–40%, protein 19–35% and fat 28–47% (Mann Reference Mann2007). Because humans target different prey species depending on latitude and habitat type Marlowe (Reference Marlowe2005) suggests, from a trophic point of view, that they resemble different species more than conspecific populations. This adaptation of the diet to the regional and local availability is typical of predatory species that have a wide geographical distribution. As a corollary, plant-to-animal subsistence ratios vary significantly by latitude in response to differences in available primary productivity and biodiversity. Estimates of carbohydrate intake as a percentage of the total energy in 229 hunter-gatherer diets throughout the world vary from approx. 3% to 50% (Ströhle & Hahn Reference Ströhle and Hahn2011). Over a wide range of latitude intervals (11°–40° north or south of the equator) carbohydrate intake remains similar (30–35%) but decreases markedly from around 20% to 9% or less of the total energy with increasing latitude intervals from 41° to greater than 60° (Fig. 1.1b). Hunter-gatherers living in desert and tropical grasslands consumed the most carbohydrates (approx. 29–34% of the total energy). Diets of hunter-gatherers living in northern areas (tundra and northern coniferous forest) contained a very low carbohydrate content (≤15% of the total energy) where hunting and fishing predominate over the collection of plant products (Mussi Reference Mussi and Roebroeks2007; Ströhle & Hahn Reference Ströhle and Hahn2011). Hunter-gatherers in higher latitudes, where plant growth is greatly curtailed, have adapted to living largely or entirely on raw animal matter, both meat and fat. As shown for the Indigenous Peoples in Greenland, the Inuit, genetic and physiological adaptations to a diet rich in polyunsaturated fatty acids are clearly reflected in their genome (Fumagalli et al. Reference Fumagalli, Moltke and Grarup2015).

Figure 1.1 (a) Frequency distribution of subsistence dependence upon total (fished and hunted) animal foods in worldwide hunter-gatherer societies (n = 229). Frequency indicates the number of societies at that percentage dependence on animal foods. Median = 56–65%, mode = 56–65% (data from Cordain et al. Reference Cordain, Miller, Eaton, Mann, Holt and Speth2000; figure adapted from Mann Reference Mann2007 with permission from John Wiley & Sons). (b) Effects of latitude on carbohydrate intake (% of energy) for 229 hunter-gatherer diets shown as the minimum and maxiimum percentage recorded for each latitude intervals; maximum values were not available for >60 latitude.

(redrawn from data in Ströhle & Hahn Reference Ströhle and Hahn2011)

1.4 Species Hunted for Wild Meat

Animals as small as caterpillars and land snails to the largest land mammal, the elephant, are consumed throughout the tropics and subtropics (Fig. 1.2). According to Redmond et al. (Reference Redmond, Aldred, Jedamzik and Westwood2006), a total of 2,000 different animals are hunted for wild meat across the world. Of these, as many as 55% are terrestrial vertebrates (amphibians, reptiles, birds, mammals), of which 638 species are hunted in the world’s tropical and subtropical regions (Table 1.1). Almost 50% of all vertebrates used for wild meat are mammals, followed by birds (34.8%), then reptiles (13.8%) and amphibians (5.6%). The distribution of the different taxonomic groups by region reflects the biogeographic idiosyncrasies of each area of the world (Table 1.1). For example, because Oceania is composed primarily of islands it is species-rich in birds but species-poor in reptiles and amphibians, with most mammals being bats. Also, as sub-Saharan Africa includes open, mammal-rich savannas, not common in Asia or South America (see Chapter 2), the numbers of mammal species hunted for wild meat in this region is significantly higher than in the others.

Figure 1.2 Examples of animal species consumed by peoples in tropical forest areas in different parts of the world. (a) Frogs on skewers for sale at the Vientiane market, Republic of Lao (photo: J. M. Touzet); (b) Lowland tapir dressed for sale in Amazonia (photo: H. El Bizri); (c) Lizards for sale at the Vientiane market, Republic of Lao.

(photo: J. M. Touzet)

Table 1.1 Number of terrestrial vertebrate species hunted and consumed for their wild meat in tropical and subtropical regions

Vertebrate groupOceaniaSouth AmericaSouth/SE AsiaSub-Saharan AfricaTotal
Amphibians33141636
Reptiles0676688
Birds34537560222
Mammals65323210292

1.4.1 Mammals

Most hunted mammals are large-bodied primates, ungulates and rodents, with an average adult body mass equal to or greater than 1 kg (Robinson & Bennett Reference Robinson and Bennett2004; Robinson & Redford Reference Robinson, Redford, Robinson and Redford1991b). These species are considered to provide a greater return for the energy invested in hunting because of their size, but also because of their greater susceptibility to the more commonly used hunting techniques, such as snares and projectile weapons, particularly firearms (Chapter 3). As larger animals are often the most lucrative species to hunt, they are typically targeted first by hunters (Chapter 4). As populations of the larger animals decline, the time and effort required to hunt these species will eventually outweigh the potential gain. As a result, hunters change to targeting mid-size species until finally, if overexploitation is sustained, the hunt will primarily target small species (Jerozolimski & Peres Reference Jerozolimski and Peres2003). However, throughout this process, the largest species will continue to be opportunistically captured whenever encountered, preventing their recovery, even though the primary target is now a smaller species (Robinson & Bennett Reference Robinson and Bennett2004). In addition, snares, which are largely indiscriminate in what they catch, extensively deployed in Africa and Asia, are able to almost empty areas of a large number of animals in a short space of time (Fa et al. Reference Fa, Ryan and Bell2005; Harrison et al. Reference Harrison, Sreekar and Brodie2016; Noss Reference Noss1998b). The use of snares varies by continents in relation to the availability and distribution of ground and arboreal prey species. In South American moist forests, because there are relatively fewer abundant ground-dwelling species than in African and Asian forests, ground snares are consequently less profitable and not widely employed (see Chapter 2). The distribution of hunted mammals in South American, African and Asia moist forests clearly indicates the preponderance of smaller prey species in South America compared to Africa and Asia (Fig. 1.3, Corlett Reference Corlett2007; Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001).

Figure 1.3 Distribution of body mass of hunted mammal species in Asian, African and South American forests.

Thus, larger prey size and greater accessibility to hunters may explain the wider range of mammal species hunted in African forests compared to South American ones; 55% of a total of 284 African forest mammals are hunted in contrast to only 28% of the 192 species recorded in South American (Amazonian) forests (Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001). The predominance of terrestrial large-bodied mammals in African forests can also explain their greater vulnerability to indirect hunting techniques, e.g. traps, nets, snares (Chapter 3). The use of snares has been a widespread practice in African forests, accounting for the extraction of more species (and biomass) than firearms (Kümpel Reference Balée and Erickson2006; Noss Reference Noss, Robinson and Bennett2000, Reference Noss1998b). Similarly, home-made snares are increasingly used across large areas of Southeast Asia (O’Kelly Reference Kelly2013; Wilkinson Reference Wilkinson2016) with devastating effects on the fauna (Gray et al. Reference Fiedel and Haynes2018). In contrast, snare hunting is virtually absent in the Amazon Basin, probably because lower population densities recorded for Neotropical forest mammals render this trapping method relatively unprofitable (Fa & Purvis Reference Fa and Purvis1997; Peres Reference Peres2000).

1.4.2 Birds

Primarily large but also smaller birds are hunted and eaten in tropical regions worldwide. In large areas of Latin America, some birds contribute significantly to the subsistence of rural families that depend on wildlife for their food. Groups such as cracids, large arboreal galliform birds (chachalacas, guans and curassows), are traditionally considered the most important birds for subsistence hunting for many Indigenous Amazonian communities. In a 5-year study of 35 Pano villages in Acre State, Brazilian Amazon, as many as 25 different bird taxa were hunted (Constantino Reference Constantino2016). Although the preferred prey were typically large species of ungulates, primates and reptiles, over the study period birds supplied 11% of all animals taken and 2% of all animal biomass hunted. Of all the bird taxa hunted, four species, the Spix’s guan, large tinamou, pale-winged trumpeter and razor-billed curassow, contributed almost all the bird numbers and biomass. Macaws, parrots, toucans, rails, doves, wood quails, ducks, kites, aracari, jabiru stork and even harpy eagles were also recorded as hunted. In other areas of the Amazon, such as in the Pacaya-Samiria National Reserve (Peru) and its surroundings as many as 47 bird species are hunted for food (Gonzalez Reference Gonzalez, Silvius, Bodmer and Fragoso2004). The most commonly hunted bird species included tinamou, anhinga, razor-billed curassow, Muscovy ducks and olivaceous cormorants but bird eggs are also an important source of food (Gonzalez Reference Gonzalez, Silvius, Bodmer and Fragoso2004). In contrast to the moist forests regions, in the semi-arid habitats, the Caatinga in Brazil for example (de Albuquerque et al. Reference De Albuquerque, de Lima Araújo and El-Deir2012), although wild mammals still make up most of the animals and biomass hunted, doves, pigeons and tinamous are common birds used for food (Barboza et al. Reference Barboza, Lopes, Souto, Fernandes-Ferreira and Alves2016).

Although birds are less commonly hunted in African forests, a large number of species are killed and traded for both meat and traditional medicine. Petrozzi (Reference Petrozzi2018) documented a total of 302 different species of 24 orders on sale in wild meat markets in 10 sampled West African countries. Most recorded species were Least Concern, with 23% Threatened according to the IUCN Red List. However, in a study of semi-permanent hunting camps in the Ebo Forest, Cameroon, birds constituted 55%, more than mammals (43%) and other taxa (2%). The study recorded several species of birds rarely reported elsewhere (Whytock et al. Reference Whytock, Buij, Virani and Morgan2016). Offtake of larger bird species was greater than for smaller taxa, but some bird species may be hunted more frequently than previous research suggests. This has important conservation implications for larger-bodied species such as raptors and hornbills (see Trail Reference Trail2007).

1.4.3 Reptiles and Amphibians

Reptiles serve as an important source of animal protein for people around the world, but exploitation of this group for food is heaviest in the tropical and subtropical regions. By contrast, although amphibians are consumed on a smaller scale than reptiles, Mohneke et al. (Reference Mohneke, Onadeko and Rödel2009) highlighted that at least 32 species (3 Urodela and 29 Anura) are used as food globally.

Of all reptiles, chelonians (turtles and tortoises) are the most heavily exploited (Klemens & Thorbjarnarson Reference Klemens and Thorbjarnarson1995). High levels of exploitation for food but also for pets and medicine are directly responsible for the precarious conservation status of as many as 11 (44%) of the 25 most threatened taxa (species and subspecies combined) of turtle and tortoise species in the world (Stanford et al. Reference Stanford, Iverson and Rhodin2020). Crocodile and alligator meat are considered a delicacy in many parts of the tropics and subtropics (Huchzermeyer Reference Huchzermeyer2003), and are consumed extensively (Hoffman & Cawthorn Reference Hoffman and Cawthorn2012). The consumption of snakes is generally opportunistic, but in Asian countries (China, Taiwan, Thailand, Indonesia, Vietnam and Cambodia) and West Africa, these animals are important sources of wild meat (Brooks et al. Reference Brooks, Allison, Gill and Reynolds2010; Hoffman & Cawthorn Reference Hoffman and Cawthorn2012).

Within the Amazon region, a number of chelonian species, but also their eggs, are heavily exploited for food (Alves et al. Reference Alves, Gonçalves and Vieira2012; Pezzuti et al. Reference Pezzuti, Lima, da Silva and Begossi2010). The giant Amazon River turtle, the largest South American river turtle, but especially the more abundant, yellow-spotted river turtle are widely harvested for their eggs and adults for food (Arraes et al. Reference Arraes, Cunha and Tavares-Dias2016). Similarly, in many tropical regions of sub-Saharan Africa, tortoises alongside other reptiles, but also amphibians, are collected for food. For example, in the Niger Delta in Nigeria, Akani et al. (Reference Akani, Luiselli, Angelici and Politano1998) reported 4 frog species and 14 reptiles for sale in wild meat markets, that are consumed regularly; the latter group included two crocodiles, five snakes, one lizard and two tortoises. In this study, the Goliath frog, the largest living frog, was commonly consumed, as reported in other parts of Africa (Gonwouo & Rödel Reference Gonwouo and Rödel2008).

Information on reptile and amphibian consumption in Asia, although less formally documented, points to numerous species of chelonians, snakes and lizards being used as locally important food sources. By contrast, the medicinal trade of reptiles, especially turtles and snakes in Southeast Asia, poses a greater threat to this group than consumption.

1.5 Regional Differences in Species Hunted for Wild Meat

A meta-analysis of the characteristics of vertebrates hunted and consumed in West and Central African moist forests showed that a total of 129 species were recorded in the literature over a 40-year period (1971–2010) in five countries (Petrozzi et al. Reference Petrozzi, Amori and Franco2016). By class, significant differences in the number of species appeared; 91 mammals dominating, followed by reptiles (n = 19), birds (n = 14) and amphibians (n = 2). Mammals were also the most numerous in terms of the number of individuals and overall biomass traded, ungulates and large rodents in particular. Herbivores and frugivores were the most common trophic animal guild. Forest-specialists were the most abundant, and in riverine habitats reptile biomass was almost as important as mammals. Most species and individuals were non-threatened according to the IUCN Red List.

Information on species hunted for wild meat in African savannas has received comparatively little attention in comparison to forests (Lindsey et al. Reference Lindsey, Balme and Becker2013). Because of their high abundance in these more open habitats, ungulates are the most hunted species (Lindsey et al. Reference Lindsey, Romañach, Tambling, Chartier and Groom2011b, Reference Kamins, Restif and Ntiamoa-Baidu2011a). The more commonly hunted species in these habitats include abundant species such as impala and blue wildebeest but also plains zebra, as recorded in the Savé Valley Conservancy in the southeast Lowveld of Zimbabwe (Lindsey et al. Reference Lindsey, Romañach, Matema, Matema, Mupamhadzi and Muvengwi2011a). In a nationwide study in Tanzania, Ceppi and Nielsen (Reference Ceppi and Nielsen2014) showed that a total of 25 taxa were consumed in 10 tribal areas. Antelope was the most frequently mentioned type of wild meat in all ecoregions, with dik-dik and duikers making up the majority of records. This was followed by hare and Guinea fowl. Dik-diks and duikers make up most records but larger species such as the bushbuck and the African buffalo are consumed only rarely. The larger animals require more sophisticated hunting techniques and adequate firearms which are often limited and more difficult to acquire.

There is a large number of studies on the hunting and gathering of vertebrates in Latin America (Alves & Van Vliet Reference Alves, van Vliet, Alves and Albuquerque2018). In a meta-analysis of 78 different hunting studies, from sites in Central America, Amazonia and the Guiana Shield, a total of 90 hunted mammal species were recorded (Stafford et al. Reference Stafford, Preziosi and Sellers2017a). This number included 12 genera of primates, 6 of ungulates and 8 rodent genera. As in Africa, ungulates and rodents make up the majority of the wild meat offtake in Neotropical communities. Within the Amazon Basin, the largest rainforest block in the world, much of the wild meat offtake is comprised of medium-sized ungulates such as white-lipped peccary, collared peccary, white-tailed deer and various brocket deer species, but also large rodents like the paca and agoutis (Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001; Mesquita & Barreto Reference Mesquita and Barreto2015; Stafford et al. Reference Stafford, Preziosi and Sellers2017b). Tapirs (South American tapir in lowland South American forests, Baird’s tapir in Central America and Andean tapir in Andean forests) are the largest mammals in South and Central American forests (ca. 200 kg), and a sought-after prey species (Jerozolimski & Peres Reference Jerozolimski and Peres2003; Nasi et al. Reference Nasi, Taber and Van Vliet2011; Suárez et al. Reference Fuentes-Montemayor, Cuarón, Vázquez-Domínguez, Benítez-Malvido, Valenzuela-Galván and Andresen2009). Primates are also the main targets for hunters in Central and South America, but overall standing biomass is less than ungulates and rodents combined. Typically, primates such as large cebid monkeys of which there are six Alouttinae monkey species and seven Atelinae species, are actively hunted for meat throughout their ranges (Ráez-Luna Reference Ráez-Luna1995). Species hunted and consumed will vary according to habitat and region but also according to the type of hunter involved. In the Amazon, colonists and Indigenous Peoples pursue different animals (Redford & Robinson Reference Redford and Robinson1987), the latter group concentrating on primates (Cormier Reference Cormier2006; Ojasti Reference Ojasti1996). The Wai Wai indigenous communities in Guyana mostly hunt black spider monkeys, paca and curassow (Shaffer et al. Reference Shaffer, Milstein, Yukuma, Marawanaru and Suse2017).

Regional differences in animals hunted occur, as observed in the different regions of Colombia (Vargas-Tovar Reference Vargas-Tovar and Restrepo2012). For all regions pooled, only three species, the collared peccary, the tapir and the paca contributed more than half of all the hunted biomass, but other species such as caiman appear important in the Orinoco region and iguanas and white-tailed deer in the Pacific region (Vargas-Tovar Reference Vargas-Tovar and Restrepo2012). A study by Van Vliet et al. (Reference Sartoretto, Tomassi, Karpe, Van Vliet, Nguinguiri, Cornelis and Le Bel2017) of animals on sale in markets in the five main ecoregions in Colombia indicated that even though as many as eighty five different species were sold for food, three or four out of six main species for the entire country (the paca, red and grey brocket deer, capybara, armadillo and black agouti) dominated markets in each region. In the more open Brazilian cerrado, tapir, white-lipped and collared peccary as well as various deer species (marsh deer, pampas deer, grey brocket deer, red brocket deer) and the giant anteater were commonly hunted (Welch Reference Welch2014).

Information on wild meat extraction in Asian habitats remains scant (Lee et al. Reference Lee, Sigouin, Pinedo-Vasquez and Nasi2014) but some general patterns are available. According to Corlett (Reference Corlett2007), over 160 species of mammal species of >1 kg are hunted in Asian forests where pigs contribute the largest proportion both in terms of individuals and biomass (Gray et al. Reference Fiedel and Haynes2018; Harrison et al. Reference Harrison, Sreekar and Brodie2016; Morrison et al. Reference Morrison, Sechrest, Dinerstein, Wilcove and Lamoreux2007; Wilcove et al. Reference Morrison, Sechrest, Dinerstein, Wilcove and Lamoreux2013). As in other tropical and subtropical regions in Africa and the Neotropics, hunting of vertebrates, not just mammals in Asia and especially in Southeast Asia is common; hunting constitutes the greatest current threat to wild vertebrates in the region. This is primarily to supply ever-expanding local, regional and even global markets. Even in areas where good-quality forest remains intact, only a small proportion of the former vertebrate diversity and abundance is still found (Harrison et al. Reference Harrison, Sreekar and Brodie2016). Only 1% of the land supports an intact fauna of mammals >20 kg (Morrison et al. Reference Morrison, Sechrest, Dinerstein, Wilcove and Lamoreux2007) and defaunation effects have been confirmed in a number of different localities (Aiyadurai et al. Reference Aiyadurai, Singh and Milner-Gulland2010; Johnson et al. Reference Johnson, Singh, Dongdala, Vongsa, Bouahom, Glendinning, Nilsson and Victor2003; Rao et al. Reference Rao, Htun, Zaw and Myint2010).

1.6 Indigenous and Rural Peoples Hunt Differently

Rural and Indigenous Peoples throughout the world still rely, to varying extents, on terrestrial animals (and fish) as food in the different habitats they inhabit. Levels of dependence on wildlife for food are affected by the ecological conditions in which people live. Where systematic comparisons have been undertaken for mammals in rainforest ecosystems, the most hunted group, in the Congo Basin in Central Africa and in the Amazon Basin in South America, inter-continental differences can be largely explained by the productivity of these ecosystems (see Chapter 2). However, because the standing biomass of mammals in Central African forests is considerably higher than in South America (Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001), reliance on terrestrial wild meat is potentially greater for hunters in the former ecosystem. Yet, the high ratio of land area to rivers in the Amazon Basin, increases the possibility for penetration by inland fisheries and thus accounts for the higher proportion of fish. The possibility of exploiting more fish actually compensates for the lower contribution of mammalian meat in the diets of Amazonian peoples compared to those in Central African forests (Robinson & Bennett Reference Robinson and Bennett1999b). Beyond the ecological reasons for the availability of wild meat for peoples living in tropical environments, understanding the cultural and socioeconomic drivers of different hunter groups may help determine levels of wildlife extraction and the motives for these. In the following section, we describe the differences in prey species and extraction levels of Indigenous and non-Indigenous Peoples living in Amazonian and Congo Basin forests.

Differences in the types of prey species hunted by Indigenous Peoples and rural communities have been studied in Neotropical and African settings. Using an index of the number of animals taken per consumer year, Redford and Robinson (Reference Redford and Robinson1987) and later Redford (Reference Redford, Hladik, Hladik, Linares, Pagezy, Semple and Hadley1993) described contrasts in the nature and intensity of hunting by Indigenous Peoples and colonists in tropical and subtropical forests in South America. For Indian communities in the Amazon, mammals constituted the most important type of game, with birds second and reptiles third; during a comparable time period, data for colonists, mammals were first, reptiles second and birds third. However, indigenous groups took on average a higher number of animals per consumer year than did colonists. Moreover, preferences between Indian and colonist groups in the types of mammals hunted were different, with primates being the most frequently taken order for Indians and rodents for colonists. In another meta-analysis in the Congo Basin, Fa et al. (Reference Bartlett, Williams and Prescott2016) showed that there were significant differences in species hunted and extraction rates between indigenous Pygmy and non-Pygmy groups. Overall, Pygmies hunted a smaller range of taxa but took a higher proportion of prey of a greater mean body mass than non-Pygmies. Harvest rates, animals per inhabitant, were almost twice as high in non-Pygmy sites than in Pygmy sites, as were extraction rates, the number of animals hunted per unit area. There were no significant differences in biomass values, due to the higher body mass of species hunted by Pygmies. However, when converted to extraction per hunter per km2, non-Pygmy sites harvested more per unit area than Pygmy groups.

The general picture that emerges from these two contrasting studies is that although variation in what Indigenous Peoples and other groups hunt may be to some extent explained by differences in the ecological context and hunting technologies used by each group, contrasting preferences for prey animals can also account for such variation. Although estimates of hunting impact by indigenous versus non-indigenous groups in different parts of the world are still lacking, Fa et al. (Reference Bartlett, Williams and Prescott2016) have shown that given their lower numbers and estimated extraction rates, Pygmies in the Congo Basin have a substantially lower impact on prey populations than other groups. The most alarming difference between these two groups is in the proportion of hunted animals that are traded for profit with significantly higher volumes of game sold by non-Pygmies than by Pygmies (Fa et al. Reference Bartlett, Williams and Prescott2016).

1.7 Understanding Urban Wild Meat Markets

The sale of hunted animals, often to neighbours or passersby, is motivated by the need to earn some income for the family to buy goods (Nasi et al. Reference Nasi, Brown and Wilkie2008; Ávila Martin et al. Reference Ávila Martin, Ros Brull, Funk, Luiselli, Okale and Fa2020). In other circumstances, hunters can be driven or choose to sell their quarry to middlemen for sale beyond their immediate neighbourhoods. If hunters enter the broader and more elaborate commercialization of wild meat, they participate in a commodity chain driven primarily by demand by urban residents who are willing to pay a premium (Bowen-Jones et al. Reference Bowen-Jones, Brown and Robinson2003). Although reliable information on the scale of the international wild meat trade is still patchy, in Europe some studies suggest that the amount of wild meat imported here is substantial (Chaber et al. Reference Chaber, Allebone-Webb, Lignereux, Cunningham and Rowcliffe2010; Falk et al. Reference Falk, Dürr and Hauser2013). For example, in a survey at Roissy-Charles de Gaulle airport (Paris, France), 7% of the inspected passengers from West and Central African countries were carrying wild meat (over 20 kg on average and up to 51 kg), and 25% had domestic meat (average 4 kg) in their luggage (Chaber et al. Reference Chaber, Allebone-Webb, Lignereux, Cunningham and Rowcliffe2010). These and more recent studies (Gombeer et al. Reference Gombeer, Nebesse and Musaba2021) indicate that wild meat is not only imported for personal use but also to supply an organized illegal luxury market for African wild meat in many cities in Europe. Moreover, as suggested by Morrison-Lanjouw et al. (Reference Morrison-Lanjouw, Coutinho, Boahene and Pool2021) in the Netherlands and Walz et al. (Reference Walz, Wilson and Stauffer2017) in the USA, culture, taste preferences, the perception that wild meat is more healthy than other meats (and therefore of lower disease risk) as well as an increase in disposable income may all be driving the local demand for African wild meat in expatriate communities.

There is little evidence that exports of wild meat from Latin America or Asia are significant. Even though the international wild meat trade may be minimal in these continents, there is growing proof that there has been a clear rise in commercial hunting within tropical countries. Although urban wild meat was originally considered a more important issue in the African context, increased urbanization within other parts of the tropics is resulting in a greater demand for wild meat from cities and large towns. In South America, for example, the consumption of wild meat in urban centres had been considered minimal compared to in Africa (Nasi et al. Reference Nasi, Taber and Van Vliet2011; Rushton et al. Reference Rushton, Viscarra, Viscarra, Basset, Baptista and Brown2005). However, recent studies suggest that there are non-negligible city markets in which a large number of wild animals are sold for human consumption (Bodmer & Lozano Reference Bodmer and Lozano2001; Chaves Baía Júnior et al. Reference Chaves Baía Júnior, Anelie Guimarães and Le Pendu2010; Parry et al. Reference Parry, Barlow and Pereira2014; Van Vliet et al. Reference Van Vliet, Cruz and Quiceno-Mesa2015, Reference Van Vliet, Schulte-Herbrüggen, Muhindo, Nebesse, Gambalemoke and Nasi2017). In a recent study in cities in Amazonas, Brazil, El Bizri et al. (Reference El Bizri, Morcatty and Valsecchi2019) demonstrated that wild meat is an important item in the diet of residents in urbanized Central Amazonia since a very large proportion of interviewees in the study ate wild meat and large numbers of animals are harvested every year to supply urban consumers. But, as shown in a study of the availability of wild meat and domestic meats in Kinshasa and Brazzaville – the two capital cities in Central Africa accounting for around 15 million inhabitants (Fa et al. Reference Auzel2019) – wild meat consumption can be considerable, despite the offer of domestic meat. The often-repeated suggestion that the solution could be the replacement of wild meat by domestic meat at more affordable prices, as suggested by Rushton et al. (Reference Rushton, Viscarra, Viscarra, Basset, Baptista and Brown2005) and others, may not be sufficient to solve the problem.

The greatest impact of commercial hunting on native vertebrate fauna is arguably occurring in Central Africa. In this region, populations of many hunted species are rapidly extirpated and sanctuaries for wildlife are dwindling since almost all Central Africa’s forests are now accessible to hunters (Abernethy et al. Reference Abernethy, Coad, Taylor, Lee and Maisels2013). Based on wild mammal meat removal rates estimated for the Amazon and Congo Basins (Nasi et al. Reference Nasi, Taber and Van Vliet2011), Central African forests are subjected to four times higher extraction of wild animals than in the Amazon. This contrast is not just a reflection of the greater standing mammalian biomass in African moist forests but the higher density of people which drives the demand for wild meat. Historic data on changes in hunting pressure in Central Africa are not available but hunter numbers are likely to have increased relative to the rise in overall human population densities. In parallel, while only 1 in 10 people lived in urban areas in 1900, almost half of all sub-Saharan inhabitants now live in towns and cities (United Nations 2014). Urban inhabitants, especially those recently arrived from rural areas into cities, have a desire to carry on consuming wild meat (because it something they are accustomed to) even though domestic meats are more available and for most families affordable (Cowlishaw et al. Reference Cowlishaw, Mendelson and Rowcliffe2004; Cronin et al. Reference Cronin, Woloszynek and Morra2015; Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005). Consequently, urban wild meat markets thrive in Central Africa, even in countries where it may be illegal to sell some wild species as food. As a result, demand for wild meat in towns and cities has increased and is expected to grow even more with increasing urbanization. The urban population in Africa is projected to rise to 1.339 billion in 2050 from 395 million in 2010, 21% of the world’s projected urban population (Güneralp et al. Reference Allan, Venter and Watson2017). Much of the upsurge is taking place in small- and medium-sized provincial towns in mid-latitude Africa, as rural youth leave to seek a better life (Lwasa Reference Lwasa2014). This demographic change implies a much greater demand on domesticated and wild food production systems, which can have far-reaching impacts.

Urban consumers of wild meat live either in (a) provincial towns close to sources of wildlife where livestock production is uncommon and market access makes imported animal source foods unavailable or unaffordable, or (b) large metropolitan areas far from sources of wildlife where wild meat is no longer a dietary necessity and more a cultural desire to connect to a rural past (Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005). Vigorous trading of wild meat to satisfy urban demand is widespread in all major West and Central African cities (Bennett Hennessey & Rogers Reference Bennett Hennessey and Rogers2008; Chausson et al. Reference Chausson, Rowcliffe, Escouflaire, Wieland and Wright2019; Edderai & Dame Reference Edderai and Dame2006; Luiselli et al. Reference Luiselli, Petrozzi and Akani2017; Malonga Reference Malonga1996; Mbayma Reference Mbayma2009; Mbete et al. Reference Mbete, Banga-Mboko and Racey2011) and the purchase of wild meat is common in even relatively small towns. The certainty of demand, ease of entering the market and low risk of penalties have encouraged villagers in subsistence economies across the region to use local wildlife as a cash crop.

In large metropolitan cities in Africa, consumers usually have the choice of several sources of domestic animal protein, but many opt for wild meat for reasons other than its nutritional importance. City dwellers may eat wild meat as a means of culturally reconnecting to their place of origin, where they or their parents consumed wild meat (Luiselli et al. Reference Luiselli, Petrozzi and Akani2017, Reference Afelt, Frutos and Devaux2018, Reference Adu, Asafu-Adjaye and Hagan2019). Although consumers in some provincial towns (particularly isolated ones) may buy wild meat because it is the cheaper meat and more readily available (Fargeot et al. Reference Fargeot, Drouet-Hoguet and Le Bel2017; Van Vliet et al. Reference Van Vliet, Nebesse and Nasi2010b), wild meat in metropolitan cities throughout the tropics for some groups of consumers is more of a luxury item and status symbol (Cao Ngoc & Wyatt Reference Cao Ngoc and Wyatt2013; Shairp et al. Reference Shairp, Veríssimo, Fraser, Challender and MacMillan2016; Wilkie et al. Reference Sirén and Wilkie2016). As a luxury commodity, city dwellers pay higher prices than rural consumers for the same animal. Urban consumer willingness to pay relatively high prices encourages rural hunters to increase the amount they take and the proportion they sell to gain income as well as food (Bennett et al. Reference Bennett, Blencowe and Brandon2007; de Merode et al. Reference De Merode, Homewood and Cowlishaw2004; Grande-Vega et al. Reference Grande-Vega, Farfán, Ondo and Fa2016). It also encourages non-local hunters to enter the market. Perhaps more significantly, many rural peoples have shifted from being traditional subsistence hunters to supplying cities.

Although there are clear multigenerational issues affecting consumption of wild meat in cities, younger generations are less predisposed as shown in a study in West African cities by Luiselli et al. (Reference Luiselli, Hema and Segniagbeto2018, Reference Adu, Asafu-Adjaye and Hagan2019), most people eat wild meat because they prefer its taste. The perception that wild meat is a luxury item is often cited but studies such as Kümpel et al. (Reference Adams and Hutton2007) in the city of Bata in Equatorial Guinea, showed that consumption of fresh foods, including wild meat, increased with income while eating of frozen produce tended to decline. In some situations, however, such as in post-depletion scenarios (see Cowlishaw et al. Reference Cowlishaw, Mendelson and Rowcliffe2005), wild meat is consumed as a bonus. In Ghana, wild meat was more expensive than domestic meat or fish since wild meat production was low in volume and occurred at considerable distances from urban centres, whereas domestic meat production was high in volume and near city markets (Cowlishaw et al. Reference Cowlishaw, Mendelson and Rowcliffe2005). In Nigeria and Gabon, wild meat is also a luxury item, more expensive than imported beef, for which individuals are willing to pay a premium over other sources of animal protein (Ladele et al. Reference Ladele, Joseph, Omotesho and Ijaiya1996; Starkey Reference Starkey2004). Wealth is known to affect wild meat consumption in some rural settings where intake was higher in wealthier households (de Merode et al. Reference De Merode, Homewood and Cowlishaw2004; Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005) because poorest households could not afford hunting tools or somebody able to hunt. In contrast, in cities like Kisangani in the Democratic Republic of Congo (DRC) where households no longer have access to free natural resources, the poorest seek the most inexpensive source of protein available in the market. Smoked wild meat is one of the cheapest sources of protein year-round but other sources of animal protein, except pork and caterpillars, are significantly more expensive. In the Kisangani market, wild meat was sold in small piles costing <USD 0.10 each, whereas domestic meat was sold in piles of 500 g to 1 kg (Van Vliet et al. Reference Van Vliet, Nebesse, Gambalemoke, Akaibe and Nasi2012). Despite the existence of sharp socioeconomic structuring between rural and urban consumers, but also within them, there is the acceptance that the burgeoning urban populations, not just in Africa (see El Bizri et al. Reference El Bizri, Fa and Lemos2019 for the Amazon), fuels an ever-increasing, lucrative trade of wild animals from rural and protected areas (Chapter 5). This trade is now the most significant immediate threat to wildlife but also to the food security of people who have hunted them. Subsistence hunting and fishing do not usually pose a significant threat at low human densities to the abundant wildlife species living around rural forest communities.

Wild meat is sold as fresh carcasses or smoked meat in markets, at roadsides, in hunters’ homes or as cooked dishes in restaurants. In all continents where wild meat is traded, it is available at several entry points in the commercial chain, where it passes from the hunter to the consumer. In some situations, hunters may sell their kill as whole animals to a trader or directly to a restaurant operator, who then retails it in smaller pieces. Hunters may also dress the carcass and sell pieces direct to consumers in their village. But, more commonly hunters or their emissaries may carry the meat to the point of sale, often the nearest town or city, though in the case of professional hunters operating from hunting camps, traders may travel to the camp to buy the smoked meat.

The main concentration sites for the sale of wild meat, on a regular basis, are without any doubt within markets. In Africa, such public gatherings, where the buying and selling of merchandise, including wild meat take place, occur in almost every sizeable village or town. Here, wild meat can be traded and displayed on makeshift counters, or in larger cities on more permanent stalls within purpose-built market buildings. Some, like the Atwemonon market in Ghana (Crookes et al. Reference Crookes, Humphreys, Masroh, Tarchie and Milner-Gulland2014; Ntiamoa-Baidu Reference Ntiamoa-Baidu1997), are highly organized and the wild meat trade and associated chain of small restaurants, known as chop bars, are handled as small-scale family businesses handed down from parents to children. In all studied areas in Africa (Cowlishaw et al. Reference Cowlishaw, Mendelson and Rowcliffe2005; East et al. Reference East, Kümpel, Milner-Gulland and Rowcliffe2005; Fa Reference Broughton1999), there are five main actor groups identified in the wild meat trade: farmer hunters or mainly subsistence hunters, commercial hunters, wholesalers, market traders and small restaurant operators. Commonly, hunters and intermediaries are men, whilst sellers are women (Tagg et al. Reference Tagg, Maddison and Dupain2018). Hunters live and work in rural areas and capture their prey using snares and shotguns. Commercial hunters depend entirely on wild meat for their livelihood, whereas farmer hunters sell wild meat to supplement their income from agricultural produce. The women traders – wholesalers, market traders and restaurant and bar operators – live and work in the city. Wholesalers work from home. They buy meat in bulk from the hunters and sell to the retailers: the market traders and small restaurants or bars. Market traders operate from stalls in the market, whereas chop bars, a term used in West Africa for small establishments, are scattered across the city. Women form the main clientele for market traders, whereas men are more likely to frequent chop bars. The primary route of trade is from commercial hunters to restaurants and bars via wholesalers, although there is also substantial trade along other routes. Each trader has her own set of hunters who supply her with meat and whom she rewards by granting loans. The trade provides income for a large number of people – hunters and traders – but it is a fairly closed system. Most wild meat markets are largely unregulated by either state or local institutions. In a number of countries, some wildlife species (e.g. endangered species) nominally protected from hunting by legislation are still consumed as wild meat. Wild meat sold openly to the public is a typical feature of many African countries, and markets are found in almost every village or town in the region. Wild meat markets are particularly well developed in West and Central Africa, which is also the area where the trade has been best documented since as long ago as the 1970s (see Asibey Reference Asibey1977; Jeffrey Reference Jeffrey1977).

The study of wild meat markets in urban and rural spaces can provide researchers with relatively easily obtainable data on carcass numbers and price by species, and sometimes information on the origin of the meat (see e.g. Dupain et al. Reference Dupain, Nackoney and Mario Vargas2012). Such data has been used to infer hunting sustainability although there are limitations to their use (Chapter 5). This is because there are varying reasons why animals are traded or retained by hunters e.g. the hunters need for cash (de Merode et al. Reference De Merode, Homewood and Cowlishaw2004) or the relative prices of wild meat species and domestic meat (Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005; Wilkie & Godoy Reference Wilkie and Godoy2001) and transport costs to town (Crookes & Milner-Gulland Reference Crookes and Milner-Gulland2006). As a result, the numbers and species appearing in markets is a subset of the total hunted in the production habitats. Despite potential drawbacks, the data emerging from wild meat market studies can be informative in assessing trends, such as the impact of Ebola on consumption of different species (Funk et al. Reference Fa, Nasi and Funk2021) and as argued by Fa (Reference Albrechtsen, Macdonald, Johnson, Castelo and Fa2007) if large market numbers can be monitored, these represent the best compromise between economy of collection effort, and precision and accuracy of estimates based on population indices. By standardizing data collection protocols and optimal sampling periods (as indicated in Fa et al. Reference Fa, Johnson, Dupain, Lapuente, Köster and Macdonald2004) comparisons between areas and with other studies are possible. Data quality ultimately depends on the continued dedication and adequate training of observers, the cooperation of various agencies and the rapid and accurate compilation of results.

The sale of wild meat in different parts of the tropics and subtropics merits particular attention since this activity has important implications for the livelihood strategies of the poor, and it is relevant to wider issues of public governance (Brown & Williams Reference Brown and Williams2003). Although these issues will be discussed further in Chapter 5, in this section we focus on the phenomenon of wild meat trade from the viewpoint of who sells wild meat and which wild meat is commercialized. At a landscape level, at least in tropical forest areas, evidence points to wild meat consumption and hunting being positively associated with increasing forest cover (both correlated with greater animal prey availability) which in turn is often negatively related with access to markets. As demonstrated by Carignano Torres et al. (Reference Carignano Torres, Morsello and Parry2018) for households in post-frontier Amazonia, people living in remote, forested areas are likely to be the most dependent on wild meat. However, those living in more populous, peri-urban areas are likely to be the actors contributing most to total hunting effort, due to the greater market access. Market access also increases the opportunity for hunters to transition from a barter-based to a monetary economy, leading to greater wealth and livelihood diversification for them (Chaves et al. Reference Chaves, Wilkie, Monroe and Sieving2017). By increasing the supply of wild meat to markets, these hunters are effectively changing consumer behaviour, ultimately boosting the demand from consumers.

Data on actual wild meat volumes for sale, taken from the literature, generally indicate a very large variation in amounts traded per site. From more extensive, multiple-site studies (Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006; Starkey Reference Starkey2004; Wilkie et al. Reference Wilkie, Starkey, Abernethy, Effa, Telfer and Godoy2005) amounts traded ranged from about 100 to 9,000 carcasses per annum. When wild meat volume traded per site is adjusted by the number of inhabitants in each site (data from Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006), about 20 kg (median 7.7, range 0.1–392) is available per person per annum, but highly skewed, as 45% of all studied sites had between 0 and 4 kg of wild meat per inhabitant per annum. The more populated sites did not have more wild meat on sale (in fact, wild meat availability fell with larger settlements), but wild meat volume on sale per site was negatively correlated with mean body mass of the animals on sale (Fa Reference Albrechtsen, Macdonald, Johnson, Castelo and Fa2007).

Market studies encompassing large numbers of monitored sites, as in the Cross-Sanaga region of Nigeria and Cameroon (35,000 km2), estimated that over a million carcasses were traded in 89 urban and rural markets in a year (Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006). Typically (see Section 1.4), almost all animals traded were mammals, of which around 40% were ungulates (duikers and pigs), 30% rodents and close to 15% were primates. Information on wild meat volume traded within other markets in African forest areas has been published for Ghana (Cowlishaw et al. Reference Cowlishaw, Mendelson and Rowcliffe2005; Crookes et al. Reference Crookes, Humphreys, Masroh, Tarchie and Milner-Gulland2014; Ntiamoa-Baidu Reference Ntiamoa-Baidu1997), Bioko (Cronin et al. Reference Cronin, Woloszynek and Morra2015; Fa et al. Reference Dublin, Sinclair and Arcese1995), Rio Muni (East et al. Reference East, Kümpel, Milner-Gulland and Rowcliffe2005; Fa et al. Reference Dublin, Sinclair and Arcese1995), DRC (Colyn et al. Reference Colyn, Dudu and Mbaelele1987), the Cross-Sanaga region of Nigeria and Cameroon (Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006) and Gabon (Starkey Reference Starkey2004). From these sources, most markets sell largely ungulates and rodents, but primates can constitute more than 20% (Fig. 1.4). As indicated above, these three taxonomic groups are the most important for human consumption in all areas where the trade has been documented (see also studies in Bennett & Robinson Reference Auzel, Wilkie, Robinson and Bennett2000), but significant variation in the proportions of ungulates, rodents and primates is typical. The relative contributions of these taxa are highly uneven, as often a limited number of taxa alone – small duikers such as blue duiker in Central Africa and Maxwell’s duiker in West Africa, large rodents such as the cane rat and the brush-tailed porcupine – constitute over 50% of the total weight traded.

Figure 1.4 Ternary plot of proportions of the three most common mammal taxa for sale in wild meat markets in West and Central Africa. A ternary plot is a specialization of a barycentric plot for three variables, which graphically depicts the ratios of three proportions.

(Data sources: Bioko, Fa et al. Reference Dublin, Sinclair and Arcese1995; Cameroon, Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006; Central African Republic (CAR), Noss Reference Noss1995; Democratic Republic of Congo (DRC), Colyn et al. Reference Colyn, Dudu and Mbaelele1987; Gabon, Steel Reference Steel1994; Nigeria, Fa et al. Reference Fa, Seymour, Dupain, Amin, Albrechtsen and Macdonald2006; Rio Muni, Fa et al. Reference Dublin, Sinclair and Arcese1995; figure from Fa Reference Fa, Davies and Brown2007, adapted with permission from John Wiley & Sons.)

Observed differences in the volume of wild meat traded may of course reflect hunting pressure, the number of hunters operating, which in turn may be related to the population status of the prey species in the area (Fa et al. Reference Fa, Ryan and Bell2005). As Ling and Milner-Gulland (Reference Crookes and Milner-Gulland2006) argue, because open-access hunting is a dynamic system in which individual hunters respond to changes in hunting costs and prices obtained for their catch, resulting offtakes will reflect human processes as well as ecological ones, for example, prey abundance. Assessing underlying factors rather than proximate outcome variables is complicated, but the trade-off in choosing to assess one or the other is between the potential for reduced monitoring frequency due to longer-term predictions and greater uncertainty through the introduction of additional assumptions (Ling & Milner-Gulland Reference Crookes and Milner-Gulland2006). Investing in characterizing supply and demand functions may not be essential if they are likely to change rapidly because of external economic or social processes or if effort and offtake can be manipulated directly. Assessing supply and demand, on the other hand, may be easier in a commercial market setting, because point demand is readily measured, and elasticity of demand can be inferred from knowledge of cultural and economic conditions. Ling and Milner-Gulland (Reference Crookes and Milner-Gulland2006) suggest that to determine sustainability reliably, some investment into modelling alternative monitoring and management strategies (with appropriate treatments of measurement error, system uncertainty and stochasticity), similar to those already being developed for fisheries, is necessary. Although this is an approach that definitely requires developing, its application may be more suited to small-scale analyses. In order to scale up to the level of large geographical areas, it may be necessary to sacrifice accuracy to gain a broader picture of the impact of hunting on wild meat species.

1.8 How Much Wild Meat Do People Eat?

Per capita wild meat consumption in different tropical regions has been measured in a number of studies in the Congo Basin and for Central and South America (Table 1.2). For Asia, there are no published studies on amounts of wild meat consumed by tropical forest peoples. Recent assessments of amounts of wild meat consumed by rural or indigenous communities in tropical and subtropical areas are scant. Most available estimates are dated (Table 1.2) and are somewhat problematic to compare since methods used differ in terms of level of accuracy of quantities eaten (ranging from less precise interview techniques such as 24-hour recalls to weighed amounts of foods consumed). Moreover, emerging values of wild meat consumed could reflect differences in the study population’s dependence on game meat versus fish (or other non-vertebrate protein such as caterpillars), but also could reflect differences in the time of year in which the studies were undertaken. Often, there is not sufficient information reported to assess these potential sources of error. Despite these caveats, the data existing from the 40 published studies in Table 1.2 can be used to give an approximation of amounts of wild meat consumed per person per day by forest communities in South America and Africa. In general, we would assume that consumption of wild meat is likely to vary due to differences in: (a) the productivity and depletion levels of the landscape; (b) the price and availability of alternatives; (c) the wealth of the consumer and (d) consumer preference for wild meat.

Table 1.2 Reported amounts of fresh edible wild meat and protein intake from hunting in selected rural South American and African communities. Values are in grams per person per day. We used a meat to protein conversion of 0.194 g of protein per gram of meat from Ojasti (Reference Ojasti1996)

Group or localityCountryFresh meatProteinSource
South America
CuibaColombia525.0105.0Arcand (Reference Arcand1976)
Siona, SecoyaEcuador326.065.0Vickers (Reference Vickers, Vickers and Kensinger1980)
Río PachiteaPeru299.049.5Pierret and Dourojeanni (Reference Pierret and Dourojeanni1966)
JívaroPeru/Ecuador278.056.0Ross (Reference Ross, Arnott and Basso1978)
SharanahuaPeru273.054.0Siskind (Reference Siskind1973)
SirinóBolivia219.044.0Holmberg (Reference Holmberg1969)
Siona-SecoyaEcuador205.041.0Vickers (Reference Vickers1984)
YékwanaVenezuela159.032.0Hames (Reference Hames1979)
Río PachiteaPeru153.020.6Pierret and Dourojeanni (Reference Pierret and Dourojeanni1966)
YanomanoVenezuela143.029.0Hames (Reference Hames1979)
TrioSuriname130.026.0Lenselink (Reference Lenselink1972)
BariColombia98.019.0Beckerman (Reference Beckerman, Vickers and Kesinger1980)
KaingangBrazil95.019.0Henry (Reference Henry1964)
MiskitoNicaragua86.017.0Nietschmann (Reference Nietschmann1972)
Jenaro HerreraPeru75.815.2Ríos et al. (Reference Ríos, Douroujeanni and Tovar1975)
Río UcayaliPeru52.010.4Pierret and Dourojeanni (Reference Pierret and Dourojeanni1967)
ShipiboPeru47.09.0Bergman (Reference Bergman1974)
Río UcayaliPeru35.07.1Pierret and Dourojeanni (Reference Pierret and Dourojeanni1967)
Leonardo da VinciBrazil31.06.2Smith (Reference Smith1976)
YukpaVenezuela28.06.5Paolisso and Sackett (Reference Paolisso and Sackett1985)
Nova FronteiraBrazil26.05.2Smith (Reference Smith1976)
Rio ParaguaVenezuela25.05.2Ojasti et al. (Reference Ojasti, Febres Fajardo, Cova and Aguilar1986)
Rio Aripuana, DardanelosBrazil22.04.4Ayres and Ayres (Reference Ayres and Ayres1979)
Coco ChatoBrazil3.60.7Smith (Reference Smith1976)
Africa
Kola PygmiesCameroon290.056.3Koppert et al. (Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993)
LiberiaLiberia280.054.3Anstey (Reference Anstey1991)
BomassRepublic of Congo230.044.6Auzel (Reference Auzel1996)
Forest MvaeCameroon200.038.8Koppert and Hladik (Reference Koppert, Hladik, Hladik, Bahuchet and de Garine1990)
Farmers, Campo ReserveCameroon190.036.9Koppert et al. (Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993)
Ituri forestDRC160.031.0Bailey and Peacock (Reference Bailey, Peacock, de Garine and Harrison1988)
DibaCAR160.031.0Del Vingt (Reference Del Vingt1997)
Ogooué-IvindoGabon140.027.2Lahm (Reference Lahm, Hladik, Hladik, Pagezy, Linares, Koppert and Froment1993)
Ituri forestDRC120.023.3Aunger (Reference Aunger1992)
OlemeCAR120.023.3Del Vingt (Reference Del Vingt1997)
DjaCameroon120.023.3Del Vingt (Reference Del Vingt1997)
KenareCAR90.017.5Del Vingt (Reference Del Vingt1997
Coastal MvaeCameroon90.017.5Koppert et al. (Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993)
EkomCAR80.015.5Del Vingt (Reference Del Vingt1997)
BabenjeleCAR50.09.7Noss (Reference Noss1995)
YassaCameroon30.05.8Koppert et al. (Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993)

For all South American tropical forest communities (Table 1.2), average amounts of wild meat were 138.9 ± 128.1 g/person/day (median = 96.5) or 27.0 ± 25.1 g/person/day (median = 19.0) of animal protein. In African communities, amounts of wild meat consumed (146.9 ± 75.9 g/person/day, median = 130.0) were higher than in the studied South American localities. Protein consumption in African sites was 28.5 ± 14.7 g/person/day (median = 25.2). Differences between the groups appear in both continental comparisons. In the South American sites, consumption varies from 3 to over 500 g/person/day, despite all localities occurring within similar tropical forest types. These disparities may be attributable to differences in the availability of wild meat. Availability of these resources will depend on the productivity of the habitat and perhaps more importantly on the existing or past hunting pressure. Hunting pressure is likely to be inversely correlated with the availability of animal protein other than terrestrial game species (Jerozolimski & Peres Reference Jerozolimski and Peres2003). In these terms, a settlement close to a highly productive river and enjoying a reliable source of fish would be less reliant on forest wildlife than those deprived of this resource (Calouro Reference Calouro1995; Endo et al. Reference Endo, Peres and Haugaasen2016; Ross et al. Reference Ross, Arnott and Basso1978). Although a few tribal communities of native Amazonians may acquire as much as 45% of their protein from fish, for most upland communities fish may be highly seasonal, and contributes only 20% or less of their protein intake (Balée Reference Balée1985).

Differences in wild meat consumption in the Congo Basin are much more attributable to contrasts in lifestyles, although the effect of different habitats or hunting pressure cannot be overruled. For example, the amount of wild meat consumed by Efe foragers in the Ituri forest of northeastern DRC) was estimated at 160 g/person/day (Bailey & Peacock Reference Bailey, Peacock, de Garine and Harrison1988); not that different to farmers reported to consume around 120 g/person/day (Aunger Reference Aunger1994). In contrast, estimates for different localities given in Chardonnet et al. (Reference Chardonnet, Fritz, Zorzi, Feron, Bissonette and Krausman1995) show that amounts of wild meat consumed by different groups vary considerably, from an average of 104 g/person/day in foragers to 430 g/person/day in farmers. Similar differences between foragers and farmers can be seen when comparing Lahm’s (Reference Lahm, Hladik, Hladik, Pagezy, Linares, Koppert and Froment1993) value’s for wild meat consumption in the Ogooué-Ivindo, Gabon (100–170 g/person/day) with the much lower amounts eaten by Babenjele net-hunters in Mossapoula, Central African Republic (CAR) of 50 g/person/day (Noss Reference Noss1995). Wild meat consumption in villages surrounding the Dja Biosphere Reserve in Cameroon, Odzala National Park in the Republic of Congo and the Ngotto forest in the CAR range from 80 to 160 g/person/day (Del Vingt Reference Del Vingt1997) while farmers in the Campo Reserve in southwestern Cameroon consume on average around 19 g/person/day (Koppert et al. Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993). The Yassa, Mvae and Bakola from coastal southern Cameroon consume between 20 and 200 g/person/day of wild meat (Koppert et al. Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993). Higher wild meat consumption rates have been reported by Auzel (Reference Auzel1996) for families living in northern Congo (160–290 g/person/ day); by Koppert et al. (Reference Koppert, Dounias, Froment, Pasquet, Hladik, Pagezy, Linares, Hladik, Semple and Hadley1993) for forest hunter-gatherers (290 g/person/day) and by Anstay (Reference Anstey1991) for rural Liberians (280 g/person/day). Chardonnet et al. (Reference Chardonnet, Fritz, Zorzi, Feron, Bissonette and Krausman1995) report that urban populations in Gabon, DRC and the CAR consumed, on average, 13 g/person/day – which is less than 10% of the wild meat eaten by hunter-gatherers living in the forest. However, total meat consumption was higher in urban areas compared with rural areas (Chardonnet et al. Reference Chardonnet, Fritz, Zorzi, Feron, Bissonette and Krausman1995), given their higher population density.

Presently available estimates indicate that 5–8 million people in South America (ca. 1.4–2.2% of the total population) regularly rely on wild meat as a protein source, with many being amongst the poorest of the region (Rushton et al. Reference Rushton, Viscarra, Viscarra, Basset, Baptista and Brown2005). Among the Caiçaras people in the Atlantic forest of Brazil, the dependency on wild meat is not constant throughout the year, but occasional hunting represents a complimentary source of animal protein (Nasi et al. Reference Nasi, Brown and Wilkie2008). In Venezuela, a study by Señaris and Ferrer (Reference Señaris and Ferrer2012) found that hunting fulfilled mainly subsistence purposes in indigenous communities and contributed between 40% and 100% of the meat consumed, whereas in mestizo (mixed heritage) communities, wild meat contributed to 10–30% of meat intake. In semi-arid regions, such as the Brazilian Caatinga, wild mammal meat can be a vital source of animal protein for human communities since freshwater fish is limited in the region. Here, wild meat can be especially critical during the early drought periods, when crops are scarce and domestic animals may die from starvation and dehydration (Alves et al. Reference Alves, Mendonça, Confessor, Vieira and Lopez2009; Barboza et al. Reference Barboza, Lopes, Souto, Fernandes-Ferreira and Alves2016; Fernandes-Ferreira et al. Reference Fernandes-Ferreira, Mendonça, Albano, Ferreira and Alves2012; Miranda & Alencar Reference Miranda and Alencar2007; Pereira & Schiavetti Reference Pereira and Schiavetti2010). Similarly, in the Yucatan Peninsula of southern Mexico, a less arid area but still water-limited because of the predominant limestone soils which restrain the occurrence of surface water bodies and agriculture, wildlife is an important food resource for people living in small, isolated and poor villages surrounding extensive forest areas (Santos-Fita et al. Reference Santos-Fita, Naranjo and Rangel-Salazar2012). Because hunting is also practiced to prevent or mitigate crop damage by wildlife, a high proportion of abundant and generalist species, such as doves, armadillos, coatis, collared peccaries and white-tailed deer, are taken in agricultural areas, surrounding fallows, gardens and forest patches (Santos-Fita et al. Reference Santos-Fita, Naranjo and Rangel-Salazar2012). Several studies have shown that wild meat from the most commonly hunted Neotropical species contributes to healthy diets (see Van Vliet et al. Reference Sartoretto, Tomassi, Karpe, Van Vliet, Nguinguiri, Cornelis and Le Bel2017 for a review) and that the nutritional content of wild meat is difficult to replace by most affordable sources of meat from domestic and industrial origin (Gálvez et al. Reference Gálvez, Arbaiza, Carcelén and Lucas1999). In addition, wild meat constitutes what could be called a festival food (León & Montiel Reference León and Montiel2008; Sirén Reference Gow2012; Van Vliet et al. Reference Van Vliet, Cruz and Quiceno-Mesa2015), understood as a food choice that may be related to identifying with one’s ethnic background (Chapman et al. Reference Chapman, Ristovski-Slijepcevic and Beagan2011), or as a comfort food consumed in positive social contexts and resulting in an affirmative association between food and emotional well-being.

Estimates of wild meat consumption by a number of rural communities in the Amazon and the Congo Basin in Nasi et al. (Reference Nasi, Taber and Van Vliet2011) suggest that as much as 63 kg/year/person (170 g per day) and 51 kg/year/person (140 g/person/day) of wild meat is consumed respectively. The authors indicate that the total protein requirement is almost entirely satisfied by wild meat for these communities. A study by Fa et al. (Reference Fa, Currie and Meeuwig2003) calculated that meat supply from wild meat hunting in Central Africa might be higher (at 48 g/person/day) than the non-wild meat protein supply locally generated or imported (34 g/person/day) in the region. These general approximations of the importance of wild meat to people’s food security can be reinforced by making comparisons between the recommended daily amounts of protein required to maintain a healthy person and the reported amounts of wild meat protein consumed, albeit with known methodological limitations.

According to the FAO/WHO/UNU Expert Consultation on Protein and Amino Acid Requirements in Human Nutrition (FAO/WHO/UNU Reference Adams and Hutton2007) the dietary reference intake (DRI), is 0.8 g of protein per kilogram of body weight. This amounts to 56 g/day for the average sedentary man and 46 g/day for the average sedentary woman. From the available information in Table 1.2, we note that the minimum requirement is unmet in 20 out of the 24 studies for South America, and not covered in any sites for Africa, except one. As mentioned above, it is possible that the DRI for Amazonian sites in Table 1.1 is likely met given the importance of fish these Amazonian communities. Thus, the consumption of wild meat by rural communities in South America, and even throughout Latin America, is not high in terms of quantity, but remains an important component of household food security, and a key element in diet, income diversification, and socially and culturally.

1.9 The Aim of This Book

As suggested at the beginning of this chapter, the overexploitation of wild meat in many parts of the world is a concern for conservationists, development scientists, policy makers and NGOs dealing with wildlife exploitation and human livelihoods issues. In the tropics and subtropics, increasing human populations and the rising trade of wild meat from rural to urban areas, often compounded by the lack of any sizeable domestic meat sector, drive unsustainable hunting levels. Evidence from the Congo and Amazon Basin forests suggests that annual levels of wild meat extraction in these environments are unsustainable. Solving this worldwide problem is one that must embrace ecological, socio-economic and cultural perspectives. These priorities need to be in balance in order to ensure that wild meat consumption does not lead to the extirpation of wildlife, and that its ongoing rational use continues to provide food security and livelihoods for the millions of rural and Indigenous Peoples that still depend on it. The study of wild meat use in all parts of the world is therefore as important as disciplines relating to the dynamics of disease, wildfire, carbon sequestration, invasive species and biogeochemical cycles (Terborgh & Estes Reference Terborgh and Estes2010). ‘Wild meat biology’, if we were to give this discipline a name, is not just understanding the impact of global, local or functional extinction of animal populations or species on ecosystem functioning – defaunation processes primarily driven by overhunting (Chapter 2) – but also the consequences on food security of those still dependent on wild meat as a source of food.

Research on any aspect of wild meat use and hunting has been distributed over a large number of academic journals. As of 31 December 2021 a total of 1,243 papers have been published containing the key words ‘bushmeat‘ or ‘wild meat’ as a topic in the Web of Science. These papers were published in 308 academic journals. A total of 284 journals published eight or fewer papers whilst only 24 journals published more than eight (Fig. 1.5).

Figure 1.5 Number of scientific articles published on bushmeat and wild meat from 1983 until 2021 appearing in different journals. The most important journals in terms of papers published are shown on the graph.

(data from citations in the Web of Science)

Although all publications focused on wild meat, quite a broad spectrum of academic disciplines is involved. The first research paper was published in 1983. Since the turn of the millennium, the yearly number of papers has increased steadily and has now reached over 100 per annum (Fig. 1.6). Additionally, there are many papers that deal with the consequences of wild meat hunting, especially zoonotic transmission of diseases (e.g. anthrax, HIV/AIDS, Ebola, monkeypox, SARS, COVID-19 and many more). Moreover, numerous papers in the hunting literature deal with wild meat without explicitly mentioning ‘bushmeat’ or ‘wild meat’ in the title or abstract, and thus are not included in Fig. 1.5 or Fig. 1.6.

Figure 1.6 Annual number of papers published relating to wild meat or bushmeat since 1983.

(data from citations in Web of Science)

Early studies were mostly descriptive, but the assortment of subjects covered has increased considerably. Alongside this burgeoning scientific interest, there has been much interest in advancing policies and actions that remedy the growing concern for the loss of biodiversity due to overexploitation of species for food. Campaigns around the so-called ‘bushmeat crisis’, that emerged in the early 1990s (e.g. the Bushmeat Task Force, Eves et al. Reference Eves, Hutchins, Bailey, Stoinski, Steklis and Mehlman2008) were primarily ensconced in protectionist measures toward wildlife consumption or an understandable concern for the fate of great apes. These initiatives have been replaced with those that seek to develop alternative livelihoods to replace the demand for wild meat (Alves & Van Vliet Reference Alves, van Vliet, Alves and Albuquerque2018; Wicander & Coad Reference Wicander and Coad2018) and to discover more comprehensive and context-specific biological and policy responses to prevent wildlife declines and to promote human well-being (CBD Reference Allan, Venter and Watson2017; Nasi & Fa Reference Apicella, Crittenden and Buss2015). Technical documents have summarized our knowledge of the wild meat issue, such as Robinson and Bennett’s (Reference Alvard, Robinson and Bennett1999a) seminal book. Bakarr’s et al. (Reference Bakarr, Oduro, Adomako, Bailey, Eves, Stefan and Stein2001) collection of papers on wild meat use in West and Central Africa has been followed by others aimed at providing guidance for better governance towards a more sustainable wild meat sector (Coad et al. Reference Coad, Fa and Abernethy2019; Nasi et al. Reference Nasi, Brown and Wilkie2008). The latter document was presented to the Subsidiary Body on Scientific, Technical and Technological Advice (SBSTTA), to the CBD at their 21st meeting, 11–14 December 2017, with recommendations for consideration by the Parties to the Convention.

This book summarizes a large volume of information related to what is known about wild meat use in tropical and subtropical regions of the world (Chapters 1, 2 and 3). It also focuses on two key biological and sociological topics: what decisions hunters make when hunting (Chapter 4) and on the more intractable subject of how to measure sustainability (Chapter 5). The following chapters reviews what we know of the impact of overhunting on wildlife and the people that depend on it (Chapter 6) and the link between zoonotic diseases and wild meat (Chapter 7). We end the book (Chapter 8) by offering reflections on how best science and policy can intertwine to come up with possible solutions to the problem at hand. This textbook is not a policy recommendation document but a more updated primer that can find itself in the hands of students and of practitioners who are still developing their paradigms and perspectives.

Figure 0

Figure 1.1 (a) Frequency distribution of subsistence dependence upon total (fished and hunted) animal foods in worldwide hunter-gatherer societies (n = 229). Frequency indicates the number of societies at that percentage dependence on animal foods. Median = 56–65%, mode = 56–65% (data from Cordain et al. 2000; figure adapted from Mann 2007 with permission from John Wiley & Sons). (b) Effects of latitude on carbohydrate intake (% of energy) for 229 hunter-gatherer diets shown as the minimum and maxiimum percentage recorded for each latitude intervals; maximum values were not available for >60 latitude.

(redrawn from data in Ströhle & Hahn 2011)
Figure 1

Figure 1.2 Examples of animal species consumed by peoples in tropical forest areas in different parts of the world. (a) Frogs on skewers for sale at the Vientiane market, Republic of Lao (photo: J. M. Touzet); (b) Lowland tapir dressed for sale in Amazonia (photo: H. El Bizri); (c) Lizards for sale at the Vientiane market, Republic of Lao.

(photo: J. M. Touzet)
Figure 2

Table 1.1 Number of terrestrial vertebrate species hunted and consumed for their wild meat in tropical and subtropical regions

(data from Redmond et al. 2006)
Figure 3

Figure 1.3 Distribution of body mass of hunted mammal species in Asian, African and South American forests.

(data from Corlett 2007 and Fa & Peres 2001)
Figure 4

Figure 1.4 Ternary plot of proportions of the three most common mammal taxa for sale in wild meat markets in West and Central Africa. A ternary plot is a specialization of a barycentric plot for three variables, which graphically depicts the ratios of three proportions.

(Data sources: Bioko, Fa et al. 1995; Cameroon, Fa et al. 2006; Central African Republic (CAR), Noss 1995; Democratic Republic of Congo (DRC), Colyn et al. 1987; Gabon, Steel 1994; Nigeria, Fa et al. 2006; Rio Muni, Fa et al. 1995; figure from Fa 2007, adapted with permission from John Wiley & Sons.)
Figure 5

Table 1.2 Reported amounts of fresh edible wild meat and protein intake from hunting in selected rural South American and African communities. Values are in grams per person per day. We used a meat to protein conversion of 0.194 g of protein per gram of meat from Ojasti (1996)

Figure 6

Figure 1.5 Number of scientific articles published on bushmeat and wild meat from 1983 until 2021 appearing in different journals. The most important journals in terms of papers published are shown on the graph.

(data from citations in the Web of Science)
Figure 7

Figure 1.6 Annual number of papers published relating to wild meat or bushmeat since 1983.

(data from citations in Web of Science)

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