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Entomophagy and human food security

Published online by Cambridge University Press:  28 September 2011

R.T. Gahukar*
Affiliation:
Arag Biotech Private Limited, Plot 220, Reshimbag, Nagpur440 009, India

Abstract

Food security is a problem in many developing and less developed countries due to increase in human population and decrease in crop productivity and food availability. Edible insects are a natural renewable resource of food providing carbohydrates, proteins, fats, minerals and vitamins. As such, entomophagy is common in ethnic groups in South America, Mexico, Africa and Asia, where indigenous insects are easily available and are consumed in various forms (raw/processed) or used as an ingredient or supplement in modern recipes. Entomophagy therefore offers an opportunity to bridge the protein gap of human foods irrespective of a few constraints that are discussed. Concerning food security, more attention is needed to assess and revalidate entomophagy in the context of modern life. Further research would be necessary to exploit insect biodiversity and ethno-entomophagy, stop overexploitation of these insects, and initiate actions for insect conservation.

Type
Review Article
Copyright
Copyright © ICIPE 2011

Introduction

Food security is fast becoming a problem for human beings because of booming populations, increase in consumption growth and possible decline in food availability. The productivity of agricultural crops is nearly stagnant and chronic malnutrition is rampant in many poor nations. Natural factors such as climate change, energy crisis, decreasing soil fertility, incidence of pests and plant diseases, and man-made situations such as increased food prices, non-availability of foods, lack of purchasing power of consumers, disparity in food distribution, and so on seem to be responsible for food insecurity (Gahukar, Reference Gahukar2009, Reference Gahukar2011; Kumar, Reference Kumar2010), while global demand for food will increase for at least another 40 years. For example, by 2030, with the human population rising by six million every month and with current food reserves at a 50-year low, the demand for food will increase by 50% (Beddington, Reference Beddington2010). Searching for new available sources to substitute food can be a viable and requisite step. Likewise, efforts for improving food supply through new technologies would take some time for their application on a large scale to make them feasible/practical, cost-effective and ecofriendly (e.g. genetically modified crops; geo-engineering; crop genotypes with resistance to pests, diseases and drought; plants with the capacity of reflecting sunlight (albedo effect); new chemical molecules; integrated plant nutrient and pest management techniques, etc.). As a global responsibility, at least for member countries, the Food and Agriculture Organization (FAO) of the United Nations took an initiative to create a policy and proposed the programme of feeding people with alternative sources including insects (FAO, 2010a, Reference Durst, Johnson, Leslie and Shonob). The organization stresses both physical and economic access to food that meets people's needs as well as their preference, even though the globalization of the world economy can affect food security especially in Africa (Kent, Reference Kent2002).

Entomophagy is the term used to describe the process of eating insects as food. Although ‘micro-livestock/mini-livestock’ are not equivalent words to entomophagy, they are sometimes used to categorize the insects that can be eaten by human beings (Paoletti and Dufour, Reference Paoletti, Dufour and Pimental2002; Paoletti, Reference Paoletti2005; Srivastava et al., Reference Srivastava, Babu and Pandey2009). At present, edible insects are a natural food resource to many ethnic groups in Asia, Africa, Mexico and South America where entomophagy can be sustainable and has economic, nutritional and ecological benefits for rural communities. However, entomophagy is becoming uncommon in some regions due to increasing adoption of modern foods, changed social structures and changes in demography (Yen, Reference Yen, Durst, Johnson, Leslie and Shono2010). Preference of edible insect species differs as per taste, nutritional value, ethnic customs, local prohibition, family background and easy availability (van Huis, Reference van Huis2003). Ramos-Elorduy (Reference Ramos-Elorduy1997a) reported 1391 insect species eaten worldwide. Later, the same author reported 1681 species in 14 insect orders (Ramos-Elorduy, Reference Ramos-Elorduy and Paoletti2005) and recently, 2086 insect species that are consumed by 3071 ethnic groups in 130 countries (Ramos-Elorduy, Reference Ramos-Elorduy2009). Likewise, the number of edible insects differs in a region and countries within a region, namely 348 species in Mexico (Ramos-Elorduy, Reference Ramos-Elorduy1997b), 250 species in sub-Saharan Africa (van Huis, Reference van Huis2003), 187 species in China (Chen et al., Reference Chen, Feng and Chen2009), 96 species in the Central African Republic (Roulon-Doko, Reference Roulon-Doko1998), 83 species in Ecuador (Onore, Reference Onore1997), 60 species in India (Chakravorty, Reference Chakravorty2009) and Borneo (Chung et al., Reference Chung, Chey, Unchi, Tinge and Won2001), 55 species in Japan (Nonaka, Reference Nonaka2005), 50 species in Thailand (Yhoung-aree et al., Reference Yhoung-aree, Puwastien and Attig1997) and 40 species in Nigeria (Banjo et al., Reference Banjo, Lawal and Songonuga2006a). Although different figures are available for different insect orders, the majority of edible insects belong to Lepidoptera, Orthoptera, Coleoptera and Hymenoptera. Other common insect orders are Isoptera, Homoptera, Heteroptera, Diptera and Odonata (Ramos-Elorduy, Reference Ramos-Elorduy1997b, Reference Ramos-Elorduy and Paoletti2005; Van Huis, Reference van Huis2003).

Worldwide, entomophagy plays a major role in human food security and has already been reviewed by Illgner and Nel (Reference Illgner and Nel2000), Craig and Bunn (Reference Craig and Bunn2001), Morris (Reference Morris2004), Nonaka (Reference Nonaka2005), Bukkens (Reference Bukkens and Paoletti2005), and recently by Raffles (Reference Raffles2010). Likewise, best sources of information on edible insects are the proceedings of the FAO workshop (FAO, Reference Durst, Johnson, Leslie and Shono2010b) and ‘The Food Insects Newsletter’ which is no longer published but a compilation of 13 volumes in a book can be referred to (DeFoliart et al. Reference DeFoliart, Dunkel and Gracer2009). In future, there is need of improved nutrition and food security. Thus, considering entomophagy as one of the practical and viable solutions to food security, this review presents recent developments to provide supplementary information to earlier reports, discusses major challenges and envisages future steps in order to feed people by suggesting to include entomophagy in future food security plans and initiatives.

Why entomophagy?

Entomophagy is practised generally for the following reasons:

(1) Insects are found easily in forestland and water resources and can be mass-collected in a short time whenever their populations are abundant.

(2) Insects can be reared and multiplied easily in small spaces and a short period due to their short life cycle and high intrinsic growth rate. Edible insects need not be fed on grains so rearing is more environmentally friendly than traditional livestock (Oonincx et al., Reference Oonincx, Itterbeeck, Heetkamp, van den Brand, van Loon and van Huis2010). Insects reproduce faster than traditional livestock. For example, the female house cricket Acheta domesticus L. (Orthoptera: Gryllidae) can lay from 1200 to 1500 eggs in 3–4 weeks and its water requirement is very low, while for beef, the ratio is four breeding animals for each animal marketed (Capinera, Reference Capinera2004). Further, the efficiency of conversion of ingested food (ECI) is higher (up to 44% in some insects) than for traditional meats (Gordon, Reference Gordon1998; Callavo et al., Reference Callavo, Glew, Huang, Chuang, Bosse, Paoletti and Paoletti2005; Chakravorty, Reference Chakravorty2009). For instance, the house cricket has an ECI twice as efficient as pigs and broiler chickens, four times greater than that of sheep and six times higher than a steer when losses in carcass trim and dressing percentage are accounted for (Capinera, Reference Capinera2004).

(3) In low-income areas, only insects are available in the period of food shortage, particularly at the beginning of the rainy season when livestock is lean, new crops have just been sown and the stocks of stored produce from the previous crop season become limited. Consequently, local markets are flooded with insects packed in plastic bags and sold as food articles during the planting season (Yen, Reference Yen2009a). Similarly, in case of natural disasters (floods, droughts, epidemics of human diseases), ethnic clashes and wars, packets of insects can be easily distributed as an emergency food security measure.

(4) Insects are mostly mixed with, or often consumed as, supplement to predominant diets based on maize, cassava, sorghum, millet, beans and rice, and form an ingredient to produce other food items (Bukkens, Reference Bukkens and Paoletti2005). In Mexico, a ‘tortilla’ (a thin flat bread made from finely ground maize) is supplemented with ground mealworm (Tenebrio molitor L. (Coleoptera: Tenebrionidae)) larvae (Aguilar-Miranda et al., Reference Aguilar-Miranda, Lopez, Escamilla-Santana and Barba de la Rosa2002), whereas the termite Microtermes bellicosus Smeathman (Isoptera: Termitidae: Macrotermitinae) supplements maize protein alone in Nigeria (Bukkens, Reference Bukkens1997).

(5) Insect preparations include frying, braising, stewing, stewing after frying, boiling and roasting. Eggs to adults are eaten but larvae and pupae are regularly sold in restaurants, and local and retail markets in urban areas (Chen et al., Reference Chen, Feng and Chen2009). For example, fried grasshoppers in cans and chocolate-covered ants are sold in Mexico, chocolate chirpy chips or popcorn with roasted crickets and grasshoppers (known as chapulines) in the USA, ants with popcorn in Colombia and maggot cheese in Italy are a local delicacy (Capinera, Reference Capinera2004; Kittler and Sucher, Reference Kittler and Sucher2008). Some restaurants in the USA are incorporating insects into their recipe books and menus such as stir-fried mealworms and caterpillar crunch (a combination of trail mix and fried caterpillars; Capinera, Reference Capinera2004; Gracer, Reference Gracer, Durst, Johnson, Leslie and Shono2010).

(6) Apart from local markets, export of insects in the form of beetle juice, canned silkworm pupae, caterpillars of hesperid butterflies and immature stages of ants has been initiated by the food industries in developed countries (Ramos-Elorduy, 1998).

(7) Entomophagy had been used regularly by tribes for centuries as medical treatments and the same practice is being continued in certain countries (Fosaranti, Reference Fosaranti1997; Pemberton, Reference Pemberton1999; Costa-Neto, Reference Costa-Neto2000; Chung et al., Reference Chung, Chey, Unchi, Tinge and Won2001; Padmanabhan and Sujana, Reference Padmanabhan and Sujana2008; Feng et al., Reference Feng, Zhao, He, Chen and Sun2009; Srivastava et al., Reference Srivastava, Babu and Pandey2009; Chakravorty et al., Reference Chakravorty, Ghosh and Meyer-Rochow2011). Ayieko and Oriaro (Reference Ayieko and Oriaro2008) reported that lake flies (Chaoborus spp. (Diptera: Chaoboridae) and Chironomus spp. (Diptera: Chironomidae)) are fed to weak children with ‘insect biscuits’ to gain strength.

(8) Insects produce much smaller quantities of greenhouse gases (GHG, particularly methane and nitrous oxide) per kilogram of meat than conventional livestock (Oonicx et al., Reference Oonincx, Itterbeeck, Heetkamp, van den Brand, van Loon and van Huis2010). A pig produces up to 100 times more GHG compared with mealworms. Emission of ammonia, which causes the acidification and eutrophication of ground water, also appears to be significantly lower. A pig produces 8–12 times more ammonia compared with crickets and up to 50 times more than locusts (Oonincx et al., Reference Oonincx, Itterbeeck, Heetkamp, van den Brand, van Loon and van Huis2010).

Nutritive value of insects

Apart from the reasons mentioned above, insects have been well recognized worldwide as nutritious food since insects provide proteins (amino acids including methionine, cysteine, lysine, and threonine), carbohydrates, fats, some minerals and vitamins, and have energy value (Capinera, Reference Capinera2004; Johnson, Reference Johnson, Durst, Johnson, Leslie and Shono2010; Xiaoming et al., Reference Xiaoming, Ying, Hong, Durst, Johnson, Leslie and Shono2010). For example, caterpillars contain proteins to the extent of 50–60 g/100 g dry weight, the palm weevil grubs contain 23–36 g, Orthoptera contain 41–91 g, ants contain 7–25 g and termites contain 35–65 g/100 g (Bukkens, Reference Bukkens1997; Ramos-Elorduy, Reference Ramos-Elorduy and Paoletti2005). This quantity is more than in ground beef (27.4 g) or broiled cod fish (28.5 g) (Banjo et al., Reference Banjo, Lawal and Songonuga2006a; Okaraonye and Ikewuchi, Reference Okaraonye and Ikewuchi2008). Maximum contents of 100 g amino acids/100 g dry weight of silkworms' pupae followed by the bamboo caterpillar Omphisa fuscidentalis Hmps. (Lepidoptera: Crambidae) (77.5 g) and the house cricket (68.7 g) have been reported (Yhoung-aree, Reference Yhoung-aree, Durst, Johnson, Leslie and Shono2010). Caterpillars, grubs of palm weevils (Rhynchophorus spp. (Coleoptera: Curculionidae)) and termites are rich in fat (Bukkens, Reference Bukkens1997). Maximum contents of calcium of 61.3, 72.4 and 76 g/100 g dry weight have been recorded, respectively, in dung beetle (Oryctes sp. (Coleoptera: Scarabaeidae)) grubs (Banjo et al., Reference Banjo, Lawal and Songonuga2006a), palm weevil grubs (Onzikou et al., Reference Onzikou, Memba, Mvoula-Tsieri, Diabangonaya-Batela, Malela, Kimbonguila, Ndangui, Pambou-Tobi, Silou and Desobry2010) and adult house crickets (Vogel, Reference Vogel2010). Maximum contents of iron of 27–29 and 35.5 g/100 g dry weight have been found in termites and caterpillars, respectively (Banjo et al., Reference Banjo, Lawal and Songonuga2006a). Similarly, maximum contents of phosphorus of 226–238 g/100 g are present in grasshoppers and the giant water bug Lethocerus indicus Lepeletier & Seville (Hemiptera: Belostomatidae; Feng et al., Reference Feng, Chen, Wang, Ye and Chen2000). A high content of magnesium (7.54–8.21 g/100 g) has been found in grasshoppers and weevils (Banjo et al., Reference Banjo, Lawal and Songonuga2006a). Eggs, larvae and pupae of honeybees have a high amount of vitamins A, B2 and C to the extent of 12.44 μg/100 g, 3.24 mg/100 g and 10.25 mg/100 g, respectively (Bukkens, Reference Bukkens1997). Calories obtainable from insects run as high as 776.9 kcal/100 g of insects, often exceeding those from soybean, maize and beef (Ramos-Elorduy, Reference Ramos-Elorduy and Paoletti2005).

A bread containing grubs of the African palm weevil Rhynchophorus phoenicis (F.) provides the major and minor nutrients essential for body growth (Ekpo and Onigbinde, Reference Ekpo and Onigbinde2005). In a recent study in Kenya, wheat buns enriched (5% mix) with the termite Macrotermes subhyalinus Rambur (Isoptera: Termitidae) were better than ordinary breads for some attributes (e.g. size, colour, texture, aroma) and consumers' preference. Further, Kinyuru et al. (Reference Kinyuru, Kenji and Njoroge2009) found higher contents of riboflavin (0.17 versus 0.26 mg), niacin (0.90 versus 1.11 mg), folic acid (0.30 versus 0.33 mg), calcium (10 versus 10.83 mg), iron (1.20 versus 1.80 mg) and zinc (2.78 versus 3.23 mg) than in ordinary bread. The oil extracted from R. phoenicis grubs contains a high level of unsaturated components and exhibits good physiological properties due to which it is used as edible oil (Okaraonye and Ikewuchi, Reference Okaraonye and Ikewuchi2008; Onzikou et al., Reference Onzikou, Memba, Mvoula-Tsieri, Diabangonaya-Batela, Malela, Kimbonguila, Ndangui, Pambou-Tobi, Silou and Desobry2010). In the case of silkworm caterpillars, eating them can be sufficient for daily requirements of copper, zinc, iron, thiamin and riboflavin, and the deficiency of riboflavin can be fulfilled by eating those insects containing this amino acid (Gordon, Reference Gordon1998). Protein production from insects is also ecologically sustainable and consumes fewer resources than animal protein (Gordon, Reference Gordon1998). Further research is needed to ascertain whether the production of a kilogram of insect protein is also more environmentally friendly than conventional animal protein when the entire production chain is taken into account.

Recent developments in insect collection

Techniques and entomophagy

Coleoptera

The grubs of R. phoenicis and the coconut rhinoceros beetles Oryctes rhinoceros L. and O. boas F. (Scarabaeidae) are a common food in the Democratic Republic of Congo (DRC) (Onyeike et al., Reference Onyeike, Ayalogu and Okaraonye2005; Onzikou et al., Reference Onzikou, Memba, Mvoula-Tsieri, Diabangonaya-Batela, Malela, Kimbonguila, Ndangui, Pambou-Tobi, Silou and Desobry2010) and Nigeria (Ekpo and Onigbinde, Reference Ekpo and Onigbinde2005). Dung beetles including Heliocopris bucephalus F. (Scarabaeidae) are collected generally in the morning by digging them out from cattle dung, placed into a container filled with water to soak for 12 h or until no more food remains in their intestines before they can be cooked (Hanboonsong, Reference Hanboonsong, Durst, Johnson, Leslie and Shono2010). In the Philippines, grubs of June beetle, Phyllophaga spp. (Scarabaeidae), are fried, stewed, grilled or roasted and often condiments including onions, pepper and salt are added. Dried grubs are often incorporated into a paste and clarified fat is used as butter (Adalla and Cervancia, Reference Adalla, Cervancia, Durst, Johnson, Leslie and Shono2010). Frying (after removing the gut content) of the red palm weevil grub/sago grub Rhynchophorus ferrugineus and the scarabaeid Chalcosoma atlas L. (Scarabaeidae) is common in Java (Lukiwati, Reference Lukiwati, Durst, Johnson, Leslie and Shono2010), whereas the most common edible insect in Papua (Indonesia) is the black palm weevil R. bilineatus Montrouzier. Grubs are generally consumed raw or after some roasting (Ramandey and Mastrigt, Reference Ramandey, Mastrigt, Durst, Johnson, Leslie and Shono2010). Similarly, cetonid beetles (Cotilis spp. (Cetoniidae)) and cerambycid beetles (Rosenbergia mandibularis Ritsema (Cerambycidae)) resting on tall flowering trees are collected, skewered on a small stick and roasted. The longicorn beetle Batocera wallacei Thomson (Cerambycidae) is roasted, often before removing the legs and wing casings and consuming the fat-filled abdomen (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010; Ramandey and Mastrigt, Reference Ramandey, Mastrigt, Durst, Johnson, Leslie and Shono2010). The sago grubs (collected from sago plants) are used as porridge with thin slices of ginger or they are stir-fried with soybean sauce and shallots (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). Exceptionally, the eggs of the stick insect Haaniella grayii grayii (Westwood) (Phasmatodea: Heteropterygidae) are eaten as a delicacy in Borneo (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

In the Kalahari region in South Africa, the San people collect the beetle Sternocera orissa Buquet (Buprestidae) during its outbreaks. The quarry is roasted in hot ash and sand, and hind wings are removed before being consumed. The heads are picked off if they are eaten directly. Often, powder is prepared and mixed with fruits or leaves of wild plants to form a paste (Nonaka, Reference Nonaka1996; van Huis, Reference van Huis2003). Tribes in the Central African Republic relish the grubs of cerambycids and dung beetles, which are searched for near the roots of banana plants or collected near tree trunks (Roulon-Doko, Reference Roulon-Doko1998).

Diptera

Lake flies, Chaoborus edulis Edwards, Chaoborus spp. (Chaoboridae) rise like clouds from Lake Victoria in East Africa. Natives sweep them off from bushes and rocks and collect them by whirling baskets. Cake is prepared by grinding the flies, which is then sun-dried (van Huis, Reference van Huis2003).

Heteroptera

Collecting water bugs around lights at night near water sources is an age-old practice in Mexico where bug eggs are well known for their taste. Two rice bugs, Leptocorisa oratorius F. (Coreidae) and Nezara viridula L. (Pentatomidae), are relished by farmers in Borneo. They mash the bugs with chillies and salt and cook them in hollow bamboo stems. The dish is served as a condiment (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). In China, the giant water bug L. indicus is roasted and eaten whole or ground into a paste with chillies before eating (Feng et al., Reference Feng, Chen, Wang, Ye and Chen2000). In Sudan, the millet bug Agonoscelis versicolor F. (Pentatomidae) is roasted and consumed. Also, oil made from these bugs is used in food preparations (Van Huis, Reference van Huis2003).

Homoptera

In Papua (Indonesia) and Borneo, green and brown cicadas (Cicadidae) including Cosmopsaltria waine Duffels, Pomponia merula Distant, Orientopsaltria spp. and Dundubia spp. are collected in the morning as adults emerge from the underground pupae (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010; Ramandey and Mastrigt, Reference Ramandey, Mastrigt, Durst, Johnson, Leslie and Shono2010). At night, a fire is set beneath the host trees (such as Pongamia spp.), and cicadas eventually drop onto the ground while the tree is being smoked (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). A plastic bag containing some cotton tied to a long stick is used to collect cicadas in Thailand (Hanboonsong, Reference Hanboonsong, Durst, Johnson, Leslie and Shono2010). After removing the wings, they are roasted over an open fire before eating. Sometimes insects are stir-fried with some salt and other flavouring, but always without oil (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

Hymenoptera

Larvae and pupae (and rarely adults) of honeybees and social wasps are roasted/grilled over a fire and eaten, whereas adult wasps are canned or rice is cooked with wasps or honeybees in Japan, China and Java (Edwards, Reference Edwards1998; Feng et al., Reference Feng, Chen, Sun, Che, Durst, Johnson, Leslie and Shono2010). Larvae and pupae of the social honeybee Apis cerana F., the giant honeybee A. dorsata F., the dwarf honeybee A. florea F. and the stingless bee Trigona biroi Friese (Apidae) are boiled with porridge or rice, stir-fried or drunk together with honey. Sometimes the brood together with the hive is squeezed to extract liquid which is then boiled (Adalla and Cervancia, Reference Adalla, Cervancia, Durst, Johnson, Leslie and Shono2010; Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). In the case of the drury bee Xylocopa latipes Drury (Apidae), inhabiting cavities of bamboo or other trees, larvae and pupae are taken from nests and are fried with butter or onion and salt (Lukiwati, Reference Lukiwati, Durst, Johnson, Leslie and Shono2010). Broods of the wild honeybees are either fried or sautéed with vegetables (Adalla and Cervancia, Reference Adalla, Cervancia, Durst, Johnson, Leslie and Shono2010; Nandasena et al., Reference Nandasena, Disanayake, Weeratunga, Durst, Johnson, Leslie and Shono2010).

Non-honey food uses in Thailand include capped brood mixed with pollen that is cut into pieces and macerated in alcohol to produce a liquid. Capped brood may also be roasted without pollen and eaten directly (Boongrid, Reference Boongrid, Durst, Johnson, Leslie and Shono2010).

Worker wasps are attracted with bait containing a meatball, then the entrance to the nest is disconnected and smoke is generated to sedate the wasps inside the nest. In Japan, some people tie a tiny white ribbon around the waist of the worker wasp while it is eating the bait. Others prefer to collect them at night when the worker wasps are sleeping (Nonaka, Reference Nonaka, Durst, Johnson, Leslie and Shono2010). In mountainous areas in Japan, pupae of the common wasp Vespula flavipes L., the Asian giant hornet Vespa mandarinia Smith, Vespa spp. and Ropalidia spp. (Vespidae) are boiled with soybean sauce or fried with salt while larvae are boiled to a hard consistency with soybean sauce, sugar and saké. The cooked larvae are then mixed with rice (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010; Nonaka, Reference Nonaka, Durst, Johnson, Leslie and Shono2010).

Generally, ants are collected by excavating holes in the plants on which ant nests are found. In the Central African Republic, women collect ant eggs by brushing them in a receptacle or by digging the stored eggs out of the nest. Eggs are eaten raw or fried (Roulon-Doko, Reference Roulon-Doko1998). In the Kalahari region (South Africa), the San tribe collect ant species of the genus Camponotus (Formicidae) by poking a nest with a digging stick and tapping the ground by hand around the nest. The San tribe prepare a powder of wild plants, mix it with ants and add a sweet-sour flavour to the mixture before eating (Nonaka, Reference Nonaka1996). Ants fried with butter or onions and garlic are served routinely in the restaurants in China (Luo, Reference Luo1997). In Malaysia, natives use the giant forest ant Camponotus gigas Latreille (Formicidae) as a flavouring because it contains a high concentration of formic acid (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). Eggs of Camponotus species are collected from tree trunks without disturbing adult ants and are cooked with spices or sautéed in garlic and onions, and are served in restaurants in the Philippines (Adalla and Cervancia, Reference Adalla, Cervancia, Durst, Johnson, Leslie and Shono2010). In Colombia, the leaf-cutting ant Atta laevigata F. Smith (Formicidae) (locally known as ‘bachaco’) is boiled in salt water and roasted in ceramic pans or ground up to use as a spread on bread (DeFoliart, Reference DeFoliart1999; Paoletti et al., Reference Paoletti, Buscardo, Vanderjagt, Pastuszyn, Pizzoferrato, Hunag, Chung, Millson, Cerda and Glew2003). In India, eggs are collected from the trees and fried with salt, chillies, spices and mustard oil, and eaten (Srivasatava et al., Reference Srivastava, Babu and Pandey2009). People in Mexico keep the immature stages of the tree ant Liometopum apiculatum Mayr. (Formicidae) (locally known as ‘escamoles’ ants) alive for a day before eating. These insects are then fried with onions and garlic or with black butter and served (Ramos-Elorduy, Reference Ramos-Elorduy1997a, b). Adults of the weaver ant Oecophylla smaragdina F. (Formicidae) are mixed with chillies and salt and served as condiments while the brood is eaten raw or cooked with rice or porridge (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

Isoptera

Large colonies of termites are found in arid and humid areas of Central Africa and Australia. Eating of the queen and the reproductive forms is common globally, whereas soldiers are preferred in Venezuela (Paoletti et al., Reference Paoletti, Buscardo, Vanderjagt, Pastuszyn, Pizzoferrato, Hunag, Chung, Millson, Cerda and Glew2003). Roulon-Doko (Reference Roulon-Doko1998) and van Huis (Reference van Huis2003) reviewed various methods of termite collection in Africa. The most popular and easy way used in the tropics is to collect them during the evening hours by placing a basin of water right under the light source. As light is reflected on the water, termites are attracted and trapped on the water surface (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). The tribes of Africa, especially those in Zambia, the Central African Republic, Angola and the DRC, collect winged sexual forms at the time of nuptial flights of termite species, Macrotermes falciger Gerstacker and M. subhyalinus (Isoptera: Termitidae), when adults emerge in large numbers from the termitaria after the first rains (Mbata, Reference Mbata1995; Malaisse, Reference Malaisse and Paoletti2005). In the DRC, a basket is put upside down over an emergence hole of the mound or a dome-shaped framework of sticks is built up or elephant grass is covered with banana leaves or a blanket to cover part of the emergence hole near which a receptacle is placed to collect flying termites. Continuous beating and drumming on the ground around the hill triggers certain termite species to emerge (van Huis, Reference van Huis2003). To extract soldiers from the mound, women and children push grass blades or parts of tree pods or the bark into the shafts of a termite mound, or prepare smoke from charcoal from certain trees and blow it into the opening; soldiers stripped into a container are then collected. Sometimes nests are dug up to collect queens (van Huis, Reference van Huis2003).

In Africa, termites are eaten raw soon after catching or fried lightly or gently roasted to make them slightly crispy, or smoked/steamed in banana leaves, or simply sun-dried. Oil is not used as termites have a high content of oil in their body. In the DRC and Central African Republic, insects are squeezed or pressed in a tube to form a colourless oil for frying. In Botswana, winged reproductive forms of the harvester termite Hodotermes mossambicus Hagen (Hodotermitidae) are roasted in hot ash and sand before being consumed (Nonaka, Reference Nonaka1996). In India (Odisha state), termites are eaten as snacks alone or together with rice (Srivasatava et al., Reference Srivastava, Babu and Pandey2009). Chinese gulp raw termites with liquor or dip them in alcohol before swallowing (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). Eating raw termites with their wings removed is also common in Borneo (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

Lepidoptera

Caterpillars of moths and butterflies have been popular dishes in many parts of the world, whereas pupae of the eri silkworm Samia ricini Donovan, the Chinese oak silk moth Antheraea pernyi Guerin-Meneville and the mulberry silkworm Bombyx mori L. (Saturniidae) are consumed by locals in many Asian countries (Zhou and Han, Reference Zhou and Han2006; Sirimungkarakat et al., Reference Sirimungkarakat, Saksirirat, Nopparat, Natongkham, Durst, Johnson, Leslie and Shono2010; Sarmah, Reference Sarmah2011).

In equatorial Africa, natives collect full-grown caterpillars of Anaphe venata Butler and Anaphe spp. (Thaumetopoeidae), and sell them with cocoons in the local markets (Latham, Reference Latham1999). When caterpillars of the emperor moths (namely Imbrasia ertli Rebel, Gonimbrasia (Imbrasia) belina Westwood, Cirina forda Westwood, Antheua insignata Gaede and mumpa caterpillar Gynanisa maja (Klug) (Saturniidae)) descend from the top to the base of their food plants (often for pupation in the soil), the whole colony is collected. Sometimes fire/smoke is made so that caterpillars drop to the ground. Prior to serving, spines or long hairs on the body are removed or burned off. Caterpillars are then boiled in water or fried with groundnut butter and mixed with cassava leaves, or cooked with pumpkin and sesame seeds, or simply fried with salt and a few hot peppers (Mbata and Chidumayo, Reference Mbata and Chidumayo1999; Latham, Reference Latham2001). Native women in the Kalahari region of South Africa squeeze out the intestines of caterpillars, and roast them in hot ash and sand. They store sun-dried caterpillars in bags for consumption whenever the need arises. For this purpose, dried caterpillars are often pounded into powder and mixed together with stewed watermelon (Nonaka, Reference Nonaka1996). In Botswana and South Africa, fourth and fifth instars of the mopani/mopane caterpillar G. belina are degutted, cooked in brine and sun-dried to make an edible product and preserved for later consumption or canned for export (Mulhane et al., Reference Mulhane, Gashe, Allotey, Siame, Teferra and Ditlhogo2001).

Caterpillars of giant skippers, Agathymus spp. and Megathymus spp. (Megathymidae), and the hesperid butterfly Aegiale hesperiaris Kirby (Hesperiidae) are collected from leaves of their various food plants including Agave spp. in Mexico. Caterpillars are swallowed whole in a preserved state in a bottle of liquor ‘tequila’ (a national drink prepared from the blue agave plant), or cooked and eaten by putting one caterpillar per bottle for flavour to a ‘tortilla’ (McKenzie, Reference McKenzie2002). Eating of the bamboo caterpillar O. fuscidentalis and the cassia butterfly Catopsila pomona F. (Pieridae), both rich in proteins (25 mg/100 g dry weight), has been reported in Southeast Asia (Yhoung-aree et al., Reference Yhoung-aree, Puwastien and Attig1997). In Java, cocoons of the teak caterpillar Hyblaea puera Cramer (Hyblaeidae) are fried in palm or coconut oil before being consumed (Lukiwati, Reference Lukiwati, Durst, Johnson, Leslie and Shono2010). Local people collect sphingid caterpillars from Colocasia sp. (Araceae) leaves and consume them after some roasting in Papua (Ramandey and Mastrigt, Reference Ramandey, Mastrigt, Durst, Johnson, Leslie and Shono2010), or after boiling until dry in Borneo (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

Odonata

Dragonflies including the larger green emperor dragonfly Anax guttatus Burm. (Aeshnidae) and the red-veined dropwing Trithemis arteriosa Burm. (Libellulidae) are collected in paddy fields in the DRC (Malaisse, 1997), the Philippines, north and northeast Thailand (Pemberton, Reference Pemberton1995), and China (Feng et al., Reference Feng, Chen, Wang, Ye and Chen2001). Nymphs are often stir-fried or boiled before eating.

Orthoptera

Grasshoppers, crickets and locusts are eaten by Africans as delicacies (Mbata, Reference Mbata1995). Grasshoppers (Acrididae) including Acanthacris ruficornis Fb., A. nigrovariegata Bolivar, Locusta migratoria migratoriodis (L.), Nomadacris septempunctata Serville, Cyrtacanthacris tatarica Linn., Lamarckiana cucullata Stoll and other jumping insects are collected in the early morning and evening when insects gather and are inactive. Villagers use brooms made from leaves or branches of local trees to chase grasshoppers from trees and huts (Mbata, Reference Mbata1995; Nonaka, Reference Nonaka1996; Roulon-Doko, Reference Roulon-Doko1998). In Borneo, grasshoppers are collected when cleaning the fields for paddy planting is undertaken (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). Small grasshoppers are first lightly salted, boiled in a little water and then simmered until dry. Sometimes they are stir-fried, while the bigger ones are deep-fried until crispy and are served without mixing with vegetables or meat (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). After removing the spiny legs, head, internal organs and wings, insects are cooked, fried or roasted in hot ash and sand (Nonaka, Reference Nonaka1996). The tettigonids are fried (after removing antennae, legs and wings) and consumed by Mofu tribes in Uganda (Seignobos et al., Reference Seignobos, Dequine and Aberlen1996). In northeast India, grasshoppers are usually collected after the harvest of paddy, especially at night. Insects are roasted or fried in vegetable oil after removing wings and the stomach and washing them with clean water. Ingredients such as ginger, garlic, chillies, salt, onions or fermented bamboo shoots are added for taste (Srivastava et al., Reference Srivastava, Babu and Pandey2009). Some tribes in India eat fried grasshoppers only with salt or they put insects in a bamboo pipe for smoking for 3–4 days and eat them with chillies and salt, and/or mix them with rice (Chakravorty, Reference Chakravorty2009). In Java, grasshoppers found in rubber and teak plantations or near paddy fields are roasted after removing the wings and the legs. For taste and flavour, seasoning is done with onion, garlic, chillies and soybean sauce (Lukiwati, Reference Lukiwati, Durst, Johnson, Leslie and Shono2010). Japan is one of the major consumers of grasshoppers (Mitsuhashi, Reference Mitsuhashi1997). Whole insects are boiled before being cleaned and salted; legs are ground and eaten with groundnut butter and salt. Roasting and sautéing are common methods of cooking, after removing the wings and the legs. Seasoning with onions, garlic, cayenne and chillies peppers, or soybean sauce is done for taste. Candied grasshoppers are a favourite cocktail in Japan (Mitsuhashi, Reference Mitsuhashi1997). In the off-season, locusts and grasshoppers are sun-dried before storage, pounded into powder and eaten with maize flour in porridge in sub-Saharan Africa (van Huis, Reference van Huis2003).

Mole crickets including the common species Gryllotalpa longipennis (Burm.) (Gryllotalpidae) are collected mostly during summer flights or from fields of paddy, maize or sugarcane while ploughing before planting (Chakravorty, Reference Chakravorty2009; Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010). In Thailand, a small hole is made in the ground near the nest and water is poured into it. The crickets come out to the surface and are easily collected by hand (Hanboonsong, Reference Hanboonsong, Durst, Johnson, Leslie and Shono2010). Farmers stir-fry the insects without oil (Chung, Reference Chung, Durst, Johnson, Leslie and Shono2010).

Early morning when crickets rest on grasses or low tree branches is the ideal time for collection. In Africa, common species of field crickets (Gryllidae) include Acheta spp., Brachytrupes membranaceus (Drury) and Gryllus bimaculatus DeGeer, which are trapped with baits using fruits (Mbata, Reference Mbata1995; Seignobos et al., Reference Seignobos, Dequine and Aberlen1996). In the case of Asian dune crickets, Schizodactylus monstrosus (Drury) and S. tuberculatus Andre (Schizodactylidae), adults are collected and put inside a bamboo pipe and smoked-dried for a week, then crushed into powder and mixed with chillies, salt and bamboo shoots. Otherwise, this powder is taken with rice or with ‘apung’ (a local drink; Chakravorty, Reference Chakravorty2009). In the Philippines, crickets are sautéed in garlic and onions and seasoned with soybean sauce, vinegar and hot pepper. In some areas, coconut milk is added to create a thick sauce (Adalla and Cervancia, Reference Adalla, Cervancia, Durst, Johnson, Leslie and Shono2010).

Current challenges and perspectives

(1) Export figures are rarely published. As such, an import of dried caterpillars from the DRC to the extent of 5 tonnes by France and 3 tonnes by Belgium (Johnson, Reference Johnson, Durst, Johnson, Leslie and Shono2010), and wasp foods by Japan from Korea, China and New Zealand (Nonaka, Reference Nonaka, Durst, Johnson, Leslie and Shono2010) has been reported. Thus, business firms should exploit the export potential of insects as it is being practised for tortillas through the Torti Mundo Company and Atlanta Bread Company International, Inc. in Mexico and the USA, respectively (Munoz, Reference Munoz2008). The stir-fried coconut rhinoceros beetle grub (known as ‘dunag’ in Thai) is a delicacy in the Krabi Province, a top tourist destination in Thailand (Ratcliffe, Reference Ratcliffe2006). Bugs as a snack with beer is a popular dish in Laos (Boulidam, Reference Boulidam, Durst, Johnson, Leslie and Shono2010). Several recipes based on edible insects are now readily available (Gordon, Reference Gordon1998; Ramos-Elorduy, Reference Ramos-Elorduy1998).

To attract tourists by improving palatability of edible insects, insects can be pounded into baking powder, which may be appreciated by those who do not like to see insects (Cerda et al., Reference Cerda, Martinez, Briceno, Pizzoferrato, Manzi, Tommaseo Ponzetta, Martin and Paoletti2001). Similarly, flavour is one of the essential determinants by which insects are considered edible (MacEvilly, Reference MacEvilly2000). Crickets, silkworm larvae/pupae, ant pupae, giant water bug and cicadas cooked with rice and vegetables are now served in local eateries in the USA (Gracer, Reference Gracer, Durst, Johnson, Leslie and Shono2010). Also, commercial value addition is possible by way of new preparations, such as lollipops with ants, insects as a condiment in modern recipes, feed for chicken and dead insects as decorative items (Fairman, Reference Fairman2010). To incorporate entomophagy in Western diets, insect clubs are being established in the USA where insects can be sold as food packets along with other food items. This venture may be interesting for poor countries as a new source of family income.

Along with insects, eating of spiders is a traditional practice in several ethnic groups in northeast India, Papua New Guinea, Australia, New Zealand (Meyer-Rochow, Reference Meyer-Rochow and Paoletti2005) and central African countries (van Huis, Reference van Huis2003). These local products, by-products and recipes can be promoted, as opportunities exist for improved packaging and marketing (Ramos-Elorduy, Reference Ramos-Elorduy1998). Also, the intellectual property issues are to be applied to insect recipes (Sirimungkarakat et al., Reference Sirimungkarakat, Saksirirat, Nopparat, Natongkham, Durst, Johnson, Leslie and Shono2010).

(2) Locals know which insects are edible as well as where and when to find them, and how to catch them. Therefore, indigenous people practising entomophagy should be involved in future projects. In fact, farming communities are willing to rear insects for sale with a hope of removing the negative stigma associated with eating insects and show urban consumers how healthy the habit of eating insects is. For this venture, large-scale production and marketing networks are essential. The basic idea is to design factories in future where insects would be mass-reared, harvested and processed in an industrial way. This may result in cheap and controlled food production and poor people can afford it at least in a period of general food shortage.

(3) Knowledge of the potential of edible insects is to be disseminated for new consumers, especially in urban areas. This gap in information can be filled by documentation of rural livelihoods depending on entomophagy and traditional knowledge. Also, ecological knowledge can provide an opportunity for insect conservation and ultimately food security (DeFoliart, Reference DeFoliart and Paoletti2005). Creating awareness in the Western world that insects are a traditionally and nutritionally important food for many tribes may increase pride in ethnic roots and traditions, and raise concern about a healthy environment and overuse of pesticides; and may foster communication among scientists who are interested in the subject.

(4) What is needed is to link forest management with insect conservation to facilitate sustainable harvesting of wild insect populations because entomophagy can make a significant contribution to insect conservation if insects are substantially harvested in conjunction with habitat management, including biodiversity preservation, which is an important factor for maintaining insect populations (DeFoliart, Reference DeFoliart and Paoletti2005). This strategy can be implemented by integrating traditional and ecological knowledge that results in economical values (Losey and Vaughan, Reference Losey and Vaughan2006; Charnley et al., Reference Charnley, Fischer and Jones2007). Management practices for major host plants of edible insects should be developed to continuously supply food to them. Wood exploitation from forest areas results in reduction in the forest cover (Reid et al., Reference Reid, Huq, Inkinen, MacGregor, Macqueen, Mayers, Murrey and Tipper2004) wherein most of the edible insects live and their population density is maintained. An ideal forest management involving the adoption of rotational burning, promotion of green vegetation, controlled mosaic burning and reduction of insect harvestings can enhance insect survival and augmentation. This policy needs efforts of government departments by way of subsidy or financial incentive for conservation of natural resources because despite community efforts, there has been degradation in insect resources due to reduction of areas under forests that are being used by tribal communities for fuel wood.

Insect populations are often diminished due to commercial exploitation, bush fire, unfavourable climatic factors and attack of natural enemies (Yen, Reference Yen2009b). In Mexico, 14 insect species are considered as threatened because they are overexploited for food in restaurants and for export purpose rather than as a source of food for locals (Ramos-Elorduy, Reference Ramos-Elorduy2006). On the contrary, whenever there is explosion in insect populations, the pests attack and damage food crops. This situation may create conflicts between farmers and foresters who eradicate insects and local people who rely on the availability of insects for food. Measures to preserve the edible insects, particularly those which are threatened, are needed. For this purpose, research on biodiversity of insects in forest ecosystems on the basis of traditional regulation should be intensified and promoted, for instance along the principles practised by the Bisa community in northern Zambia (Mbata et al., Reference Mbata, Chidumayo and Lwatula2002). Collecting insects by people migrating from neighbouring regions has been reported from Mexico by Ramos-Elorduy (Reference Ramos-Elorduy2008). This practice may no longer be allowed by adopting a legal code.

Overexploitation has degraded the ecosystems, resulting in unstable abundance of insects (Ferreira, Reference Ferreira1995). For the effective management of insects and forests, Mbata et al. (Reference Mbata, Chidumayo and Lwatula2002) suggested a workplan for the preservation of commercial caterpillars in Zambia, namely studying the ecology and monitoring the population dynamics of these insects on at least 20 tree species, protecting their host plants against late bush fires, and restricting insect harvesting. Thus, the mopane caterpillars are now studied to see whether more sustainable harvest will result in enhanced economic stability and conservation becomes stable (Frears, Reference Frears1995).

(5) Forests are preferred for insect harvesting because there is no insecticide use. Their collection in established crops or horticultural systems is also practical (Banjo et al., Reference Banjo, Lawal and Songonuga2006a) since insects can be mass-collected by hand and through use of light or pheromone traps. By this way, insect populations are reduced in the crop, and often, curative measures are no longer needed (Hunter, Reference Hunter2004; DeFoliart, Reference DeFoliart and Paoletti2005). For example, the egg density of a grasshopper Sphenarium purpurescens Charpentier (Acrididae) in Mexico was lesser in fields where mechanical picking of insects was practised than in those fields with insecticide applications, and hand collection of the Bombay locust Patanga succinta L. (Acrididae) from maize fields reduced pest infestation levels in Thailand (Boongrid, Reference Boongrid, Durst, Johnson, Leslie and Shono2010). In such cases, expenses on plant protection are reduced because less quantity of pesticides is needed, and the risk of soil and water contamination is minimized (Cerritosa and Cano-Santana, Reference Cerritosa and Cano-Santana2008). Therefore, entomophagy may be integrated effectively and practically in existing integrated pest management strategies. This possibility, however, needs to be thoroughly studied before any recommendation is made to farmers because hand-picking becomes expensive whenever labour is expensive or not available.

(6) Silkworm pupae contain proteins, peptides and amino acids and are generally considered safe for human consumption (Zhou and Han, Reference Zhou and Han2006). However, some insects may be toxic to humans. Traditional methods are, therefore, used to remove the poison before eating (van Huis, Reference van Huis2003). Allergic reactions after consuming silkworm pupae (Liu et al., Reference Liu, Tian and Chen2001) or grasshoppers (Vetter, Reference Vetter1995; Srivastava et al., Reference Srivastava, Babu and Pandey2009), or cocoons of the teak caterpillar H. puera (Lukiwati, Reference Lukiwati, Durst, Johnson, Leslie and Shono2010) have been reported. Eating poisonous beetles and caterpillars can result in lead poisoning (Phillips and Burkholder, Reference Phillips and Burkholder1995). Similarly, undifferentiated schizophrenia had been observed in local populations in south India (Lingeswaran et al., Reference Lingeswaran, Vijayakumar and Dinesh2009). Poisoning may occur due to misidentification of edible species. For example, eating of a blister beetle (Mylabris phalerata Pallas (Coleoptera: Meloidae)), which contains the toxin canthardin, resulted in human death in Thailand (Hanboonsong, Reference Hanboonsong, Durst, Johnson, Leslie and Shono2010). It is speculated that excessive consumption of insects with chitin, protein or fat carries a risk of urinary tract stone formation and development of chronic degenerative disease (Yhoung-aree, Reference Yhoung-aree, Durst, Johnson, Leslie and Shono2010). As a preventive measure, MacEvilly (Reference MacEvilly2000) suggested that insects should not be eaten with nuts or shellfish as both have been shown to trigger allergic responses in hypersensitive individuals. These assumptions need further studies to verify and conclude ill effects of entomophagy.

(7) Pesticides (insecticides, acaricides, rodenticides, fungicides, herbicides and molluscicides) used in controlling various pests, weeds and plant diseases of food crops or forest trees can make insects unsuitable for human consumption because their residues are accumulated in the tissue (Capinera, Reference Capinera2004; Chakravorty, Reference Chakravorty2009). Yet, consumers often eat pesticide-contaminated insects without prior knowledge (unintentional entomophagy). In future, it would be better if insects are consumed with no or low pesticide residues, but the challenge will be how and where to procure pesticide-free insects.

(8) In the USA and Europe, entomophagy is uncommon and even a taboo in many cultures (Yen, Reference Yen2009a; Meyer-Rochow, Reference Meyer-Rochow2009). This cultural bias against eating insects is still unclear (DeFoliart, Reference DeFoliart1999; Ratcliffe, Reference Ratcliffe2006). On the contrary, in certain African countries such as Botswana, South Africa and Zimbabwe, both animal husbandry and eating of mopane worms and other insects have co-existed for centuries. This perspective has to be studied for long-term economical and ecological benefits, and perpetuated by local traditions.

(9) It is impossible to completely eliminate insects from the human food chain, as they are carried in storage places or market yards along with the harvested crop produce (food grains, vegetables and fruits). Sometimes immature stages (live or dead) or insect fragments are present since they could not be killed or removed in the field or in the storage structures. In many instances, insects have been ground up into tiny pieces in food items. Of course, these insects may make food products nutritious and provide some minerals and vitamins, but, again, eating them may pose health hazards. Therefore, precautions are to be followed before eating.

(10) The small size of insects makes the collection, rearing and processing (including removal of all organs containing waste products that may be poisonous) rather difficult. In the case of large insects, proper disposal of intestinal contents and maintenance of good sanitary conditions in production should be followed (Allotey and Mpuchane, Reference Allotey and Mpuchane2003) because during harvesting, handling, processing/drying and storage, insects can come in contact with soil and can be contaminated with pathogenic micro-organisms causing spoilage (Banjo et al., Reference Banjo, Lawal and Adeyemi2006b). Some insects serve as vectors or intermediate hosts for vertebrate pathogens such as bacteria, protozoa, viruses and helminths, thereby increasing the risk of disease transmission to humans. Naturalists and amateurs claim that insects consume clean fresh green leaves and so contamination is prevented. In reality, edible insects can be contaminated with bacteria, fungi and pesticide residues. Therefore, food safety guidelines should be available to assist both vendors and consumers. The food regulatory laws against insect contamination in many countries are in practice, and foods derived from insects are inspected or tested and approved as safe food (Mulhane et al., Reference Mulhane, Gashe, Allotey, Siame, Teferra and Ditlhogo2001; Ministry of Health, 2003; Zhou, Reference Zhou2004). In the case of defaulters, the Food and Drug Administrations take appropriate legal action on this matter (Zhou, Reference Zhou2004; Srivastava et al., Reference Srivastava, Babu and Pandey2009).

(11) When control measures are applied against insects, some populations survive. The survivors increase due to adaptation to the local environment and their population, though at a low level, is maintained in the ecosystem. The availability of insects is thus assured to locals. Traditional dishes that are under threat as new generations imitate the Western taste for meat may be brought back in the mainstream of entomophagy by way of promotion by organizing shows, interactive displays, street plays and exhibitions (Fairman, Reference Fairman2010). To exploit marketing, existing technologies for the processing of edible insects are to be improved and disseminated to tribal communities. Insect species with high nutritional content ought to be reared with modern techniques to increase their commercial value and availability to consumers. Awareness needs to be encouraged with thrusts on environmental benefits, nutritional value, availability of insects in the period of food shortage and for ritual ceremonies, and so on. This would possibly give access to improvement in insect rearing, quality control and to the avoidance of pesticide contamination. Further, these initiatives would create marketing avenues particularly in cities and towns where product quality, labelling and attractive packaging are necessary for value addition.

Conservation and collection of insects in nature

Van Huis (Reference van Huis2003) discussed various methods of collection and capture of edible insects. Harvesting of insects is often done by women and in some regions, by children, for whom insect farming can be a low-input sustainable form of agriculture. The way of collecting depends on the insects' behaviour. For example, low temperatures in the morning make insects comparatively inactive and catching them is easy; nocturnal insects (termites and grasshoppers) can be caught in light traps as they are attracted to light; artificial breeding sites are useful for attracting palm weevils, whereas crickets and cicadas can be traced by the sound they make (van Huis, Reference van Huis2003).

Getting a large number of insects in the wild is often uncertain due to their unpredictable locations and population density. Research on management potential of wild edible insects will enhance harvests, ensure sustainability in nature and create potential and economic feasibility of mass collection of promising species by local people who can eventually contribute to rural food stocks and earn their livelihood as demonstrated by Munyuli Bin Mushambanyi (Reference Munyuli Bin Mushambanyi2000) for the brown silkworm Anaphe infracta Walsingham (Lepidoptera: Notodontidae) in the DRC. Shifting crop cultivation is another way to improve caterpillar production in northern Zambia (Chidumayo and Mbata, Reference Chidumayo and Mbata2002).

Insect mass rearing in captivity at village level

Development of economically feasible ways of mass rearing in closed environments is crucial since most insects are only seasonally available in nature (Callavo et al., Reference Callavo, Glew, Huang, Chuang, Bosse, Paoletti and Paoletti2005; Feng et al., Reference Feng, Zhao, He, Chen and Sun2009; Sileshi and Kenis, Reference Sileshi and Kenis2010). Rearing of insects in captivity (cages, potted plants and rooted food plants) at village level can allow a continuous supply rather than relying on natural harvesting. For example, the hepialid caterpillar Wiseana copularis Meyrick (Lepidoptera: Hepialidae) (Allan et al., Reference Allan, Wang, Jimenez-Perez and Davis2002) and the South American palm weevil Rhynchophorus palmarum L. (Cerda et al., Reference Cerda, Martinez, Briceno, Pizzoferrato, Manzi, Tommaseo Ponzetta, Martin and Paoletti2001) can be reared on alternative host plants or artificial diets (semi-synthetic/synthetic). Indoor rearing by farmers of the eri silkworm and mulberry silkworm in houses in India (Sathe et al., Reference Sathe, Jadhav, Kamadi and Undale2008; Chakravorty et al., Reference Chakravorty, Ghosh and Meyer-Rochow2011; Sarmah, Reference Sarmah2011), the giant hornets (Vespula spp.) in wooden hive boxes in Japan (Nonaka, Reference Nonaka, Durst, Johnson, Leslie and Shono2010) and the eri silkworm on cassava leaves in Thailand (Sirimungkarakat et al., Reference Sirimungkarakat, Saksirirat, Nopparat, Natongkham, Durst, Johnson, Leslie and Shono2010) has been quite successful and has become a routine commercial activity. In Thailand, farmers use cement tanks or wooden containers covered with a plastic sheet for cricket farming (Hanboonsong, Reference Hanboonsong, Durst, Johnson, Leslie and Shono2010). A layer of sandy loam soil is added and is covered with dry grasses, bamboo shoots or egg cartons to provide shade for the crickets. Egg masses are introduced and containers are covered with nylon nets. An artificial diet, containing chickfeed along with grasses or weeds, and water are provided. After 4–6 weeks, adult crickets are ready to be harvested (Jamjanya et al., Reference Jamjanya, Thavornaukulkit, Klibsuwan and Totuyo2001).

It is possible that the sale of insects yields more revenue for farmers than millet in the Sahel (van Huis, Reference van Huis2003), where small-scale production units with simple techniques of mass rearing can be started. If insects are reared or collected in surplus, preservation by drying can promote cottage industries through remunerative business. Thus, controlled rearing should move from small units to an industrial phase with adoption of economical mass production on a large scale (Hardouin, Reference Hardouin1995). Of course, commercialization is hampered by taxonomic uncertainty and lack of information on the biology of certain insects (Yen, Reference Yen, Durst, Johnson, Leslie and Shono2010). New research should therefore tackle insect identification, ecology and nutritive value of insect species that have short life cycles, and are thus most suitable for mass rearing. Recently, low cost techniques for mass rearing of edible insects, including crickets, grasshoppers, ants and the giant water bug, have been successfully developed in China, Korea and Thailand (Kim et al., Reference Kim, Kim and Oh2008; Feng et al., Reference Feng, Zhao, He, Chen and Sun2009; Boulidam, Reference Boulidam, Durst, Johnson, Leslie and Shono2010).

Documentation on edible insects is scattered and not easily available. Compilation of recent research findings on consumption, traditional harvesting and management practices is essential. Promotional and educational aspects through extension services should include assurance of quality and safety of insect products. The World Conservation Monitoring Centre in the UK maintains conservation status of insect species under threat/extinction. Similar efforts are needed for edible insects. Developing protocols for recording data on edible insects and establishing a centralized database or a collaborative network can facilitate sharing of information and exchange of insects and insect products. At government level, efforts are needed to include edible insects in the government policies on food security, and rural development strategies should be based on their diversification in agriculture and forestry. Establishment of a global bank of edible insects may open new avenues in research and development, ultimately proving advantageous for food security projects.

Chitin/chitosan comprises 10% of whole dried insects, which can be extracted from the host cuticle in a much easier way than that of crustaceous chitin (Duan, Reference Duan1998). Experiments on the silkworm pupa have demonstrated the significant value of chitin as a source of fibre and calcium (Zhang et al., Reference Zhang, Haga, Sekiguchi and Hirano2000; Paulino et al., Reference Paulino, Simionato, Garcia and Nozaki2006). Thus, protein concentrates from de-chitinized insects can be produced on a large scale and fed to animals.

Insects are considered as an alternative source of diet not only for space agriculture for eventual habitation on Mars (Katayama et al., Reference Katayama, Yamashita, Wada and Mitsuhashi2005) but also for any close space environment (Mitsuhashi, Reference Mitsuhashi2007). The aeronautical prospects being bright, insects should be considered as a nutritious food for astronauts and as a key to space agriculture (Katayama et al., Reference Katayama, Ishikawa, Takaoki, Yamashita, Nakayama, Kiguchi, Kok, Wada and Mitsuhashi2008). For this purpose, rearing techniques for silkworms, termites and flies have been developed and continuous cell-culture systems have been recently created (Mitsuhashi, Reference Mitsuhashi, Durst, Johnson, Leslie and Shono2010).

Among insects used in entomophagy, mealworms, the house cricket, acridids and the silkworm C. forda (Westwood) (Lepidoptera: Saturniidae) can be raised as a valuable and cheap protein feed for fish and poultry (Ramos-Elorduy et al., Reference Ramos-Elorduy, Gonzalez, Hernandez and Pino2002; Oyegoke et al., Reference Oyegoke, Akintola and Fasoranti2006; Anand et al., Reference Anand, Ganguly and Haldou2008). Farmers also will earn extra income from this enterprise.

Conclusion

Awareness of entomophagy among consumers and insect-rearing entrepreneurs is necessary (Nonaka, Reference Nonaka2005). In some instances, consumers are willing to pay a premium for the safety of street foods including insect preparations if prepared, stored and sold in a hygienic condition (Akinbode et al., Reference Akinbode, Dipeolu and Okuneye2011). Such an attempt was made in 2010 in the USA by organizing an international seminar on ‘The potential of edible insects’ at Linvile, Alabama, USA, by the Southern Institute for Appropriate Technology. Similarly, a workshop at Chiang-Mai in Thailand on ‘Edible insects’ co-organized by the FAO in 2008 was a great success. After all, entomophagy can be revalidated by worldwide campaigns that are to be launched in those countries that are facing acute food shortage. Joint concerted efforts to popularize entomophagy through collaboration among developed and developing nations should be initiated. Extensive surveys of insects, search of literature, research on nutritional value of unknown species as well as socio-economic aspects (including acceptance of these foods by consumers) would open new vistas for food security. A multi-faceted and linked global strategy is, therefore, needed to ensure sustainable and equitable food security (FAO, 2010a), and entomophagy can play an inter-disciplinary role associated with forestry, traditional medicine, agriculture and animal husbandry.

References

Adalla, C. B. and Cervancia, C. R. (2010) Philippine edible insects: a new opportunity to bridge the protein gap of resource-poor families and to manage pests, pp. 151160. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Aguilar-Miranda, F. D., Lopez, M. G., Escamilla-Santana, C. and Barba de la Rosa, A. P. (2002) Characteristics of maize flour tortilla supplemented with ground Tenebrio molitor larvae. Journal of Agriculture and Food Chemistry 50, 192195.Google Scholar
Akinbode, S. O., Dipeolu, A. O. and Okuneye, P. A. (2011) Willingness to pay for street food safety in Ogun state, Nigeria. Journal of Agricultural and Food Information 12, 154166.CrossRefGoogle Scholar
Allan, R. A., Wang, Q., Jimenez-Perez, A. and Davis, L. K. (2002) Wiseana copularis larvae (Lepidoptera: Hepialidae): laboratory rearing procedure and effect of temperature on survival. New Zealand Journal of Agricultural Research 45, 7175.CrossRefGoogle Scholar
Allotey, J. and Mpuchane, S. (2003) Utilization of useful insects as food source. African Journal of Food, Agriculture, Nutrition and Development 3, 18.Google Scholar
Anand, H., Ganguly, A. and Haldou, P. (2008) Potential value of acridids as high protein supplement for poultry feed. International Journal of Poultry Science 7, 722725.CrossRefGoogle Scholar
Ayieko, M. A. and Oriaro, V. (2008) Consumption, indigenous knowledge and cultural values of the lake fly species within the Lake Victoria region. African Journal of Environmental Science and Technology 2, 282286.Google Scholar
Banjo, A. D., Lawal, O. A. and Songonuga, E. A. (2006 a) The nutritional value of fourteen species of edible insects in southwestern Nigeria. African Journal of Biotechnology 5, 298301.Google Scholar
Banjo, A. D., Lawal, O. A. and Adeyemi, A. J. (2006 b) The microbial fauna associated with the larvae of Oryctes monoceros. Journal of Applied Sciences Research 2, 837843.Google Scholar
Beddington, J. (2010) Global food and farming futures. (Preface) Philosophical Transactions of the Royal Society (B). Biological Sciences 365, 2767.Google Scholar
Boongrid, S. (2010) Honey and non-honey foods from bees in Thailand, pp. 165172. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Boulidam, S. (2010) Edible insects in a Lao market economy, pp. 131140. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Bukkens, S. G. F. (1997) The nutritional value of edible insects. Ecology of Food and Nutrition 36, 287319.CrossRefGoogle Scholar
Bukkens, S. G. F. (2005) Insects in the human diet: nutritional aspects, pp. 545577. In Ecological Implications of Minilivestock (edited by Paoletti, M. G.). Science Publishers, Enfield, NH.Google Scholar
Callavo, A., Glew, R. H., Huang, Y. S., Chuang, L. T., Bosse, R. and Paoletti, M. G. (2005) House cricket small-scale farming, pp. 519544. In Ecological Implications of Minilivestock (edited by Paoletti, M. G.). Science Publishers, Enfield, NH.Google Scholar
Capinera, J. L. (Ed.) (2004) Encyclopedia of Entomology. Vol. 1–3. Kluwer Academic Publishers, Dordrecht. 258 pp.Google Scholar
Cerda, H., Martinez, R., Briceno, N., Pizzoferrato, L., Manzi, P., Tommaseo Ponzetta, M., Martin, O. and Paoletti, M. G. (2001) Palm worm (Rhynchophorus palmarum), traditional food in Amazonas, Venezuela: nutritional composition, small scale production and tourist palatability. Ecology of Food and Nutrition 40, 1332.Google Scholar
Cerritosa, R. and Cano-Santana, C. (2008) Harvesting grasshoppers, Sphenarium purpurascens in Mexico for human consumption: a comparison with insecticidal control for managing pest outbreaks. Crop Protection 27, 473480.CrossRefGoogle Scholar
Chakravorty, J. (2009) Entomophagy – an ethnic cultural attribute can be exploited to control increased insect population due to global climate change: a case study. Paper presented at the International Human Dimensions Programme, Seventh International Science Conference on Human Dimensions of Global Environmental Change, held at Bonn, Germany, 26–30 April 2009.Google Scholar
Chakravorty, J., Ghosh, S. and Meyer-Rochow, V. B. (2011) Practices of entomophagy and entomotherapy by members of the Nyishi and Galo tribes, two ethnic groups of the state of Arunachal Pradesh (North-East India). Journal of Ethnobiology and Ethnomedicine 7, 114.Google ScholarPubMed
Charnley, S., Fischer, A. P. and Jones, E. T. (2007) Integrating traditional and local ecological knowledge into forest biodiversity conservation in the Pacific Northwest. Forest Ecology and Management 246, 1428.CrossRefGoogle Scholar
Chen, X., Feng, Y. and Chen, Z. (2009) Common edible insects and their utilization in China. Entomological Research 39, 299303.CrossRefGoogle Scholar
Chidumayo, E. N. and Mbata, K. J. (2002) Shifting cultivation, edible caterpillars and livelihoods in the Kopa area of northern Zambia. Insects, Trees and Livelihoods 12, 175193.CrossRefGoogle Scholar
Chung, A. Y. C. (2010) Edible insects and entomophagy, pp. 141150. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Chung, A. Y. C., Chey, V. K., Unchi, S., Tinge, K. S. and Won, A. (2001) A survey of traditional use of insects and insect products as medicine in Sabah. Malaysian Naturalist 55, 2429.Google Scholar
Costa-Neto, E. M. (2000) Cockroach is good for asthma: zootherapeutic practices in northeastern Brazil. Human Ecology Review 7, 4151.Google Scholar
Craig, B. and Bunn, H. T. (eds) (2001) Meat-eating and Human Evolution. Oxford University Press, London. 384 pp.Google Scholar
DeFoliart, G. R. (1999) Insects as food: why the western attitude is important. Annual Review of Entomology 44, 2150.CrossRefGoogle ScholarPubMed
DeFoliart, G. R. (2005) Overview of role of edible insects in preserving biodiversity, pp. 123140. In Ecological Implications of Minilivestock: Potential of Insects, Rodents, Frogs and Snails (edited by Paoletti, M. G.). Science Publishers Inc., Enfield, NH.Google Scholar
DeFoliart, G. R., Dunkel, F. V. and Gracer, D. (2009). The Food Insects Newsletter: Chronicle of Changing Culture. Aardvark Global Publishing, Salt Lake City, UT, USA. 414 pp.Google Scholar
Duan, X. (1998) Introduction of research situation about chitin and chitosan and their application in agriculture and forestry. World Forest Research 11, 914.Google Scholar
Edwards, J. S. (1998) Cooking of honey bee brood in East Java. Honey Bee Science 19, 149154.Google Scholar
Ekpo, K. E. and Onigbinde, A. O. (2005) Nutritional potentialities of the larvae of Rhynchophorus phoenicis (F.). Pakistan Journal of Nutrition 4, 287290.CrossRefGoogle Scholar
Fairman, R. J. (2010) Instigating an education in insects: the eating creepy crawlies' exhibition. Antenna 34, 169170.Google Scholar
FAO (2010 a) The State of Food Insecurity in the World (2009) Economic and Social Development Department, Food & Agriculture Organization, Rome(February 2010).Google Scholar
FAO (2010 b) In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Feng, Y., Chen, X., Wang, S., Ye, S. and Chen, Y. (2000) The common edible insects of Hemiptera and their nutritive value. Forest Research 13, 608612.Google Scholar
Feng, Y., Chen, X., Wang, S., Ye, S. and Chen, Y. (2001) Three edible Odonata species and their nutritive value. Forest Research 14, 421424.Google Scholar
Feng, Y., Chen, X., Sun, L. and Che, Z. Y. (2010) Common edible wasps in Yunnan Province, China and their nutritional value, pp. 9398. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Feng, Y., Zhao, M., He, Z., Chen, Z. and Sun, L. (2009) Research and utilization of medicinal insects in China. Entomological Research 39, 313316.Google Scholar
Ferreira, A. (1995) Saving the mopane worm: South Africa's wiggly protein snack in danger. The Food Insects Newsletter 8, 6.Google Scholar
Fosaranti, J. O. (1997) The place of insects in the traditional medicine of southwestern Nigeria. The Food Insects Newsletter 10, 15.Google Scholar
Frears, S. L. (1995) Physiological ecology of the mopane worm, Imbrasia belina (Westwood) (Lepidoptera: Saturniidae), p. 55. Proceedings of the Tenth Entomological Congress, 3–7 July 1995, Grahamstown, South Africa. Entomological Society of Southern Africa, Pretoria.Google Scholar
Gahukar, R. T. (2009) Food security: the challenges of climate change and bioenergy. Current Science 96, 2628.Google Scholar
Gahukar, R. T. (2011) Food security in India: the challenge of food production and distribution. Journal of Agricultural and Food Information 12 (in press).CrossRefGoogle Scholar
Gordon, D. G. (1998) The Eat-A-Bug Cookbook. Ten Speed Press, Berkeley, CA. 102 pp.Google Scholar
Gracer, D. (2010) Filling the plates: serving insects to the public in the United States, pp. 217220. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Hanboonsong, Y. (2010) Edible insects and associated food habits in Thailand, pp. 173182. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Hardouin, J. (1995) Minilivestock: from gathering to controlled production. Biodiversity and Conservation 4, 220232.CrossRefGoogle Scholar
Hunter, D. M. (2004) Advances in the control of locusts (Orthoptera: Acrididae) in eastern Australia: from crop protection to preventive control. Australian Journal of Entomology 43, 293303.Google Scholar
Illgner, P. and Nel, E. (2000) The geography of edible insects in sub-Saharan Africa: a study of the mopane caterpillar. The Geographical Journal 166, 336351.Google Scholar
Jamjanya, T., Thavornaukulkit, C., Klibsuwan, V. and Totuyo, P. (2001) Mass Rearing of Crickets for Commercial Purposes. Faculty of Agriculture, Khon Kaen University, Khon Kaen.Google Scholar
Johnson, D. V. (2010) The contribution of edible forest insects to human nutrition and to forest management: current status and future potential, pp. 522. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Katayama, N., Ishikawa, Y., Takaoki, M., Yamashita, M., Nakayama, S., Kiguchi, K., Kok, R., Wada, H. and Mitsuhashi, J. (2008) Entomophagy: a key to space agriculture. Advances in Space Research 41, 701705.Google Scholar
Katayama, N., Yamashita, M., Wada, H. and Mitsuhashi, J. (2005) Entomophagy as part of a space diet for habitation on Mars. Journal of Space Technology and Science 21, 2738.Google Scholar
Kent, G. (2002) Africa's food security under globalization. African Journal of Food and Nutritional Sciences 2, 2229.Google Scholar
Kim, S. A., Kim, K. M. and Oh, B. J. (2008) Current status and perspectives of the insect industry in Korea. Entomological Research 38, 7985.Google Scholar
Kinyuru, J. N., Kenji, G. M. and Njoroge, M. S. (2009) Process development, nutrition and sensory qualities of wheat buns enriched with edible termites (Macrotermes subhyalinus) from Lake Victoria region, Kenya. African Journal of Food, Agriculture, Nutrition and Development 9, 17391750.CrossRefGoogle Scholar
Kittler, P. G. and Sucher, K. (2008) Food and Culture. 5th edn.Wadsworth, Belmont, CA. 576 pp.Google Scholar
Kumar, P. (2010) Functioning of public distribution system in India: an empirical evaluation. Outlook on Agriculture 39, 177184.CrossRefGoogle Scholar
Latham, P. (1999) Edible caterpillars of the Bas Congo region of the Democratic Republic of Congo. Antenna 23, 134139.Google Scholar
Latham, P. (2001) Edible Caterpillars and Their Food Plants in Bas Congo, Democratic Republic of Congo. Forneth, London. 41 pp.Google Scholar
Lingeswaran, A., Vijayakumar, V. and Dinesh, J. (2009) Entomophagy and coprophagy in undifferentiated schizophrenia. Indian Journal of Psychological Medicine 31, 5263.Google Scholar
Liu, X. D., Tian, J. J. and Chen, D. M. (2001) An allergic shock case that resulted from consuming silkworm pupae. Chinese Recuperative Medicine 10, 80.Google Scholar
Losey, J. and Vaughan, M. (2006) The economic value of ecological services provided by insects. Bioscience 56, 311323.Google Scholar
Lukiwati, D. R. (2010) Teak caterpillars and other edible insects in Java, pp. 99104. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Luo, Z. Y. (1997) Insects as food in China. Ecology of Food and Nutrition 25, 267268.Google Scholar
MacEvilly, C. (2000) Bugs in the system. Nutrition Bulletin 25, 267268.Google Scholar
Malaisse, F. (2005) Human consumption of Lepidoptera, termites, Orthoptera and ants in Africa, pp. 175230. In Ecological Implications of Minilivestock: Potential of Insects, Rodents, Frogs and Snails for Sustainable Development (edited by Paoletti, M. G.). Science Publishers Inc., Enfield, NH.Google Scholar
Mbata, K. J. (1995) Traditional uses of arthropods in Zambia: I. The food insects. The Food Insects Newsletter 8, 57.Google Scholar
Mbata, K. J. and Chidumayo, E. N. (1999) Emperor moth caterpillars (Saturniidae) for a snack: traditional processing of edible caterpillars and sale in the Kopa area of Zambia. The Food Insects Newsletter 12, 15.Google Scholar
Mbata, K. J., Chidumayo, E. N. and Lwatula, C. M. (2002) Traditional regulation of edible caterpillar exploitation in the Kopa area of Mpika district in northern Zambia. Journal of Insect Conservation 6, 115130.Google Scholar
McKenzie, D. (2002) Are tortillas a Giffen good in Mexico? Economics Bulletin 15, 17.Google Scholar
Meyer-Rochow, V. B. (2005) Traditional food insects and spiders in several ethnic groups of northeast India, Papua New Guinea, Australia and New Zealand, pp. 389413. In Ecological Implications of Minilivestock: Potential of Insects, Rodents, Frogs and Snails for Sustainable Development (edited by Paoletti, M. G.). Science Publishers Inc., Enfield, NH.Google Scholar
Meyer-Rochow, V. B. (2009) Food taboos: their origins and purposes. Journal of Ethnobiology and Ethnomedicine 5, 110.Google Scholar
Ministry of Health (2003) Technical Methods for Testing and Assessment of Healthy Food. Ministry of Health, Beijing.Google Scholar
Mitsuhashi, J. (1997) Insects as traditional foods in Japan. Ecology of Food and Nutrition 36, 187199.CrossRefGoogle Scholar
Mitsuhashi, J. (2007) Use of insects in closed space environment. Biological Sciences in Space 21, 124128.Google Scholar
Mitsuhashi, J. (2010) The future use of insects as human food, pp. 115122. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Morris, B. (2004) Insects and Human Life. Berg Publishers, Oxford. 320 pp.Google Scholar
Mulhane, S., Gashe, B. A., Allotey, J., Siame, A. B., Teferra, G. and Ditlhogo, M. (2001) Quality determination of Phane, the edible caterpillar of an Emperor moth, Imbrasia belina. Food Control 11, 453458.Google Scholar
Munoz, C. B. (2008) Transnational Tortillas (Race, Gender and Shop-floor Politics in Mexico and the United States). Cornell University Press, Ithaca, NY. 202 pp.Google Scholar
Munyuli Bin Mushambanyi, T (2000) Etude preliminaire orientee vers la production des chenilles consommables par l'elevage des papillons Anaphe infracta (Thaumetopoeidae) a Lwiro, Sud-Kivu, Republique Democratique du Congo. Tropiculture 18, 208211.Google Scholar
Nandasena, M. R. M. P., Disanayake, D. M. S. K. and Weeratunga, L. (2010) Sri Lanka as a potential gene pool of edible insects, pp. 161164. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Nonaka, K. (1996) Ethnoentomology of the central Kalahari San. African Study Monographs (Supplement) 22, 2946.Google Scholar
Nonaka, K. (2005) Ethnoentomology: Insect Eating and Human–Insect Relationship. University of Tokyo Press, Tokyo.Google Scholar
Nonaka, K. (2010) Cultural and commercial roles of edible wasps in Japan, pp. 123130. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Okaraonye, C. C. and Ikewuchi, J. C. (2008) Rhynchophorus phoenicis (F.) larval meal: nutritional value and health implications. Journal of Biological Science 8, 122125.Google Scholar
Onore, G. (1997) A brief note on edible insects in Ecuador. Ecology of Food and Nutrition 36, 277285.Google Scholar
Onyeike, E. N., Ayalogu, E. O. and Okaraonye, C. C. (2005) Nutritive value of the larvae of raphia palm beetle (Oryctes rhinoceros) and weevil (Rhychophorus phoenicis). Journal of the Science of Food and Agriculture 85, 18221828.CrossRefGoogle Scholar
Onzikou, J. M., Memba, F., Mvoula-Tsieri, M., Diabangonaya-Batela, B., Malela, K. E., Kimbonguila, A., Ndangui, C. B., Pambou-Tobi, N. P., Silou, T. and Desobry, S. (2010) Characterization and nutritional potentials of Rhyncophorus phoenicis larva consumed in Congo-Brazzaville. Current Research Journal of Biological Sciences 2, 189194.Google Scholar
Oonincx, D. G., Itterbeeck, J., Heetkamp, M. J., van den Brand, H., van Loon, J. J. and van Huis, A. (2010) An exploration on greenhouse gas and ammonia production by insect species suitable for animal or human consumption. PLoS One 5 (12) e14445. (29 December 2010). doi: 10.1371/journal.pone.001445.Google Scholar
Oyegoke, O. O., Akintola, A. J. and Fasoranti, J. O. (2006) Dietary potentials of the edible larvae of Cirina forda (Westwood) as a poultry feed. African Journal of Biotechnology 5, 17991802.Google Scholar
Padmanabhan, P. and Sujana, K. A. (2008) Animal products in traditional medicine from Allapady hills in Western Ghats. Indian Journal of Traditional Knowledge 7, 326329.Google Scholar
Paoletti, M. G. (ed.) (2005) Ecological Implications of Minilivestock: Potential of Insects, Rodents, Frogs and Snails for Sustainable Development. Science Publishers Inc., Enfield, NH. 648 pp.Google Scholar
Paoletti, M. G. and Dufour, D. L. (2002) Minilivestock, Vol. 1. pp. 487492. In Encyclopedia of Pest Management (edited by Pimental, D.). Marcel Dekker, New York, NY.Google Scholar
Paoletti, M. G., Buscardo, E., Vanderjagt, D. J., Pastuszyn, A., Pizzoferrato, L., Hunag, V., Chung, T., Millson, M., Cerda, H. and Glew, R. H. (2003) Nutrient content of termites (Syntermes) soldiers consumed by Markiritare Amerindians of Alto Orinoco of Venezuela. Ecology of Food and Nutrition 42, 173187.CrossRefGoogle Scholar
Paulino, A. T., Simionato, J. I., Garcia, J. C. and Nozaki, J. (2006) Characterization of chitosan and chitin produced from silkworm chrysalides. Carbohydrate Polymers 64, 98103.Google Scholar
Pemberton, R. W. (1995) Catching and eating dragonflies in Bali and elsewhere in Asia. American Entomologist 4, 9799.Google Scholar
Pemberton, R. W. (1999) Insects and other arthropods used as drugs in Korean traditional medicine. Journal of Ethnopharmacology 65, 207216.Google Scholar
Phillips, J. and Burkholder, W. (1995) Allergies related to food insect production and consumption. Food Insects Newsletter 8 (http://www.food-insects.com ).Google Scholar
Raffles, H. (2010) Insectopedia. Pantheon Books, Random House Inc., New York, NY. 465 pp.Google Scholar
Ramandey, E. and Mastrigt, H. (2010) Edible insects in Papua, Indonesia: from delicious snack to basic need, pp. 105114. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Ramos-Elorduy, J. (1997 a) Insects: a sustainable source of food. Ecology of Food and Nutrition 36, 247276.Google Scholar
Ramos-Elorduy, J. (1997 b) Importance of edible insects in the nutrition and economy of people of the rural areas of Mexico. Ecology of Food and Nutrition 36, 347366.Google Scholar
Ramos-Elorduy, J. (1998) Creepy Crawly Cuisine; the Gourmet Guide to Edible Insects. Park Street Press, Rochester, VT. 150 pp.Google Scholar
Ramos-Elorduy, J. (2005) Insects: a hopeful food source, pp. 263291. In Ecological Implications of Minilivestock: Potential of Insects, Rodents, Frogs and Snails for Sustainable Development (edited by Paoletti, M. G.). Science Publishers Inc., Enfield, NH.Google Scholar
Ramos-Elorduy, J. (2006) Threatened edible insects in Hidalgo, Mexico and some measures to preserve them. Journal of Ethnobiology and Ethnomedicine 2, 51.CrossRefGoogle Scholar
Ramos-Elorduy, J. (2008) Energy supplied by edible insects from Mexico and their nutritional and ecological importance. Ecology of Food and Nutrition 47, 280297.CrossRefGoogle Scholar
Ramos-Elorduy, J. (2009) Anthropo-entomophagy: cultures, evolution and sustainability. Entomological Research 39, 271288.Google Scholar
Ramos-Elorduy, J., Gonzalez, E. A., Hernandez, A. R. and Pino, J. M. (2002) Use of Tenebrio molitor (Coleoptera: Tenebrionidae) to recycle organic wastes and as feed for broiler chickens. Journal of Economic Entomology 95, 214220.CrossRefGoogle ScholarPubMed
Ratcliffe, B. C. (2006) Scarab beetles in human culture. Coleopterists' Society Monographs 5, 85101.Google Scholar
Reid, H., Huq, S., Inkinen, A., MacGregor, J., Macqueen, D., Mayers, J., Murrey, L. and Tipper, R. (2004) Using Wood Products to Mitigate Climate Change. International Institute for Environment and Development, London. 81 pp.Google Scholar
Roulon-Doko, P. (1998) Les activites de cueillete, Chasse, Cueillette et Culture chez les Gbaya de Centrafrique. Editions Harmattan, Paris. pp. 247342.Google Scholar
Sarmah, K. (2011) Eri pupa: a delectable dish of North East India. Current Science 100, 279.Google Scholar
Sathe, T. V., Jadhav, A. D., Kamadi, N. G. and Undale, J. P. (2008) Low cost rearing techniques for mulberry silkworm (PM × NB4D2) by using nylon and indigenous shelves. Biotechnological Approaches in Entomology 5, 205211.Google Scholar
Seignobos, C., Dequine, J. P. and Aberlen, C. H. P. (1996) Les Mofu et leurs insectes. Journal d'Agriculture traditionelle et de Botanique appliquee 28, 125187.Google Scholar
Sileshi, G. W. and Kenis, M. (2010) Food security: farming insects. Science 327, 797.Google Scholar
Sirimungkarakat, S., Saksirirat, W., Nopparat, T. and Natongkham, A. (2010) Edible products of eri silkworm (Samia ricini D.) and mulberry silkworm (Bombyx mori L.) in Thailand, pp. 189200. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Srivastava, S. K., Babu, N. and Pandey, N. (2009) Traditional insect bioprospecting as human food and medicine. Indian Journal of Traditional Knowledge 8, 485494.Google Scholar
van Huis, A. (2003) Insects as food in sub-Saharan Africa. Insect Science and Its Application 23, 163185.Google Scholar
Vetter, R. (1995) A case of ingestant allergy from eating a grasshopper. The Food Insects Newsletter 8, 5.Google Scholar
Vogel, G. (2010) For more protein, filet of cricket. Science 327, 811.Google Scholar
Xiaoming, C., Ying, F. and Hong, Z. (2010) Review of the nutrition value of edible insects, pp. 8592. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Yen, A. L. (2009 a) Edible insects: traditional knowledge or western phobia? Entomological Research 39, 289298.Google Scholar
Yen, A. L. (2009 b) Entomophagy and insect conservation: some thoughts for digestion. Journal of Insect Conservation 13, 667670.Google Scholar
Yen, A. L. (2010) Edible insects and other invertebrates in Australia: future prospects, pp. 6583. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Yhoung-aree, J. (2010) Edible insects in Thailand: nutritional values and health concerns, pp. 201216. In Forest Insects as Food: Humans Bite Back. Proceedings of a Workshop on Asia–Pacific Resources and Their Potential for Development, 19–21 February 2008, FAO, Chiang-Mai, Thailand (edited by Durst, D. B., Johnson, D. V., Leslie, R. N. and Shono, K.). FAO Regional Office for Asia and the Pacific, Bangkok(Publication No. 2010/02).Google Scholar
Yhoung-aree, J., Puwastien, P. P. and Attig, G. A. (1997) Edible insects in Thailand: an unconventional protein source? Ecology of Food and Nutrition 36, 133149.Google Scholar
Zhang, M., Haga, A., Sekiguchi, H. and Hirano, S. (2000) Structure of insect chitin isolated from beetle larva cuticle and silkworm (Bombyx mori) pupa exuvia. International Journal of Biological Macromolecules 27, 99105.CrossRefGoogle ScholarPubMed
Zhou, J. X. (2004) Health food derived from silkworm pupae approved. Food Information and Technology 4, 64.Google Scholar
Zhou, J. X. and Han, D. (2006) Safety evaluation of protein of silkworm (Antheraea pernyi) pupae. Food and Chemical Toxicology 44, 11231130.Google Scholar