Insects as food

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Whole, fried edible insects as street food in Germany Speiseinsekten auf deutschem Streetfood-Markt.jpg
Whole, fried edible insects as street food in Germany
Whole, steamed silkworm pupae as street food in South Korea (beondegi) Beondegi.jpg
Whole, steamed silkworm pupae as street food in South Korea ( beondegi )
Digging for Honeypot ants in Australia Yuendumu Gold 04.jpg
Digging for Honeypot ants in Australia

Insects as food or edible insects are insect species used for human consumption. [1] Over 2 billion people are estimated to eat insects on a daily basis. [2] Globally, more than 2,000 insect species are considered edible, though far fewer are discussed for industrialized mass production and regionally authorized for use in food. [3] [4] [5] [6] Many insects are highly nutritious, though nutritional content depends on species and other factors such as diet and age. [7] [8] Insects offer a wide variety of flavors and are commonly consumed whole or pulverized for use in dishes and processed food products such as burger patties, pasta, or snacks. [9] [10] Like other foods, there can be risks associated with consuming insects, such as allergic reactions. [11] As commercial interest in insects as food grows, countries are introducing new regulatory frameworks to oversee their production, processing, marketing, and consumption. [12]

Contents

Benefits

With over 2,000 identified edible insects, there are many options for human consumption. Insects may provide a sustainable option for protein sources containing 13-77% protein by dry weight. Some insects may also be used as a fat source boasting up to 67.25% lipids by dry weight. Insects can provide omega-6 and omega-3, iron (proportionally more iron than other major food sources like beef), and zinc. Besides nutrients, the energy obtained by eating insects can be similar to other food sources like beef and chicken depending on what kind of insect is eaten. [13]

There are also environmental benefits from using insects as a food source: Insects require significantly less feed, can be used in feed, and release fewer CO2 emissions than conventional animal food sources. [14] They can be used to address the issue of depleted agricultural lands as they don't need much space to be reared as compared to livestock. Additionally, food waste is a significant issue with 1/3 of food being wasted globally; Since insects can eat food waste, and they require less feed, they are a good option to address food waste. [15]

Insects may be a sustainable commercial farming option to support populations struggling with food security due to their nutrition and farming capacities, taking less room to cultivate than other protein sources. [14]

Edible insects

Frequently consumed insect species

Human consumption of 2,096 different insect species has been documented. [4]

The table below ranks insect order by number and percentage of confirmed species consumed and presents each insect orders' percentage of known insect species diversity. [4] [16] [17] With the exceptions of orders Orthoptera and Diptera, there is close alignment between species diversity and consumption, suggesting that humans tend to eat those insects that are most available. [18]

Human insect consumption by taxonomic order
Insect orderCommon nameNumber of confirmed species consumed by humans [4] Percentage of insect species consumed by humans (%) [4] Percentage of total insect species (%) [16]
Coleoptera Beetles6963338
Lepidoptera Butterflies, moths3621716
Hymenoptera Bees, wasps, ants3211512
Orthoptera Grasshoppers, locusts, crickets278132
Hemiptera Cicadas, leafhoppers, planthoppers, scale insects, true bugs2371110
Odonata Dragonflies6131
Blattodea Termites, cockroaches5931
Diptera Flies37215
Others-4526

Geography of insect consumption

Number of edible insect species per country Edible insects.png
Number of edible insect species per country

Insect species consumption varies by region due to differences in environment, ecosystems, and climate. [19] [20] The number of insect species consumed by country is highest in equatorial and sub-tropical regions, a reflection of greater insect abundance and biodiversity observed at lower latitudes and their year-round availability. [20] [18] [21]

For a list of edible insects consumed locally see: List of edible insects by country.

Edible insects for industrialized mass production

To increase consumer interest in Western markets such as Europe and North America, insects have been processed into a non‐recognizable form, such as powders or flour. [22] Policymakers, academics, [5] as well as large-scale insect food producers such as Entomofarms in Canada, Aspire Food Group in the United States, [23] Protifarm and Protix in the Netherlands, and Bühler Group in Switzerland, focus on seven insect species suitable for human consumption as well as industrialized mass production: [6]

Cochineal (Dactylopius coccus) is collected to produce carmine, a red dye used for textiles and food. It was largely substituted with synthetic dyes like alizarin. Fears over the safety of artificial food additives renewed the popularity of cochineal dyes, and the increased demand has made cultivation of the insect profitable again, [24] with Peru being the largest producer, followed by Mexico, Chile, Argentina and the Canary Islands. [25]

Nutritional profile

Freeze-dried mealworms and buffalo worms (lesser mealworm) Mealworms as food and Buffaloworms as food-2395.jpg
Freeze-dried mealworms and buffalo worms (lesser mealworm)

The nutritional profiles of edible insects are highly variable given the large number of species consumed. [8] In addition to species differences, nutritional content can be affected by geographic origin and production method (wild or farmed), diet, age, development stage, and sex. [26] [8] For instance, female house crickets ( Acheta domestica ) contain more fat than males, while males contain more protein than females. [27]

Some insects (e.g. crickets, mealworms) are a source of complete protein and provide similar essential amino acid levels as soybeans, though less than casein. [28] [29] They have dietary fiber, essential minerals, vitamins such as B12, [30] riboflavin and vitamin A, and include mostly unsaturated fat. [31] [32]

Locusts contain between 8 and 20 milligrams of iron for every 100 grams of raw locust, whereas beef contains roughly 6 milligrams of iron in the same amount of meat.[ citation needed ] Crickets are also very efficient in terms of nutrients. For every 100 grams of substance crickets contain 12.9 grams of protein, 121 calories, and 5.5 grams of fat. Beef contains more protein, containing 23.5 grams in 100 grams of substance, but also has roughly triple the calories and four times the amount of fat as crickets do in 100 grams.[ citation needed ]

Nutritional value
per 100 g		Mealworms
( Tenebrio molitor )		Buffalo worms
( Alphitobius diaperinus )		House crickets
( Acheta domesticus )		Migratory locust
( Locusta migratoria )
Energy550 kcal / 2303 kJ484 kcal / 2027 kJ458 kcal / 1918 kJ559 kcal / 2341 kJ
Fat
Of which saturated fatty acids		37,2 g
9 g		24,7 g
8 g		18,5 g
7 g		38,1 g
13,1 g
Carbohydrates
Of which sugars		5,4 g
0 g		6,7 g
0 g		0 g
0 g		1,1 g
0 g
Protein45,1 g56,2 g69,1 g48,2 g
Salt0,37 g0,38 g1,03 g0,43 g

Organoleptic characteristics

Chapulines, a popular edible grasshopper of Mexico Chapulines snack grasshopers.jpg
Chapulines, a popular edible grasshopper of Mexico

The organoleptic characteristics of edible insects vary between species and are influenced by environment. [33] For instance, aquatic edible insects such as water boatmen (family Corixidae) and dragonfly larvae have a fish flavor, while diving beetles taste more like clams. [33] [34] [35] Environment is not always a predictor of flavor, as terrestrial edible insects may also exhibit fish-like flavors (e.g. crickets, grasshoppers). [34] [35] Over 400 volatile compounds responsible for the aroma and flavor of edible insects have been identified. [9] Pheromone chemicals contribute to pungent aromas and flavors in some species and the presence of organic acids (like formic acid in ants) makes some species taste sour. [36] Organoleptic characteristics are dependent on the development stage of the insect (egg, larva, pupa, nymph, or adult) and may change significantly as an insect matures. [33] For example, texture can change from soft to crunchy as an insect develops from larva to adult due to increasing exoskeletal chitin. [33] Cooking method is considered the strongest influence on the final flavor of edible insects. [33] [9] Wet-cooking methods such as scalding or steaming remove pheromones and odor compounds, resulting in a milder flavor, while dry-cooking methods such as frying and roasting introduce more complex flavors. [33] [9] [37]

The table below provides common flavor descriptors for a selection of edible insects. [34] [36] Flavors will vary with preparation method (e.g. raw, dried, fried, etc.). Insect development stage is provided when possible.

Flavor descriptors of a selection of edible insects [34] [36] [33]
InsectScientific nameDevelopment stageFlavor
Agave worm (white) Aegiale hesperiaris [38] LarvaeCracklings
Agave worm (red) Comadia redtenbacheri [39] LarvaeSpicy
Ants Family FormicidaeAdultSweet, nutty
Carpenter ant Camponotus spp.AdultCharred lemon
Wood ant Formica spp.AdultKaffir lime
Black witch moth Ascalapha odorataLarvaeHerring
Cockroach Order Blattodea-Mushroom
Cricket Superfamily GrylloideaAdultFish
Corn earworm Helicoverpa zeaLarvaeSweet corn
Dragonfly Infraorder AnisopteraLarvaeFish
Grasshopper Suborder CaeliferaAdultFish
Honey bee Apis spp.BroodButter, milk, herbal, vegetal, meaty, mushroom
Mealworm Tenebrio molitor-Nutty (larvae); whole wheat bread (adult)
Mealybug Family Pseudococcidae-Fried potato
Stinkbug Family PentatomidaeAdultApple
Termite Infraorder IsopteraAdultNutty
Treehopper Family Membracidae-Avocado, zucchini
Wasp Suborder Apocrita-Pine nut
Water boatmen Family Corixidae-Caviar (egg); fish, shrimp (adult)

Farming, production, and processing

Cricket Shelter Modular Edible Insect Farm, designed by Terreform ONE Cricket Shelter Modular Edible Insect Farm IMG 20200219 163454590.jpg
Cricket Shelter Modular Edible Insect Farm, designed by Terreform ONE
Crickets being raised for human consumption Bolikhamxay Thabok Crickets.JPG
Crickets being raised for human consumption

Edible insects are raised as livestock in specialized insect farms. In North American as well as European countries such as the Netherlands or Belgium, insects are produced under strict food law and hygiene standards for human consumption.[ citation needed ]

Conditions such as temperature, humidity, feed, water sources, and housing, vary depending on the insect species.[ citation needed ] The insects are raised from eggs to larvae status (mealworms, lesser mealworms) or to their mature form (crickets, locusts) in industrialized insect farms and then killed via temperature control. [40] [41] Culled insects may be freeze-dried and packed whole, or pulverized to insect powder (insect flour) to be used in other food products such as baked goods or snacks.

In addition to nutritional composition and digestibility, insect species are selected for ease of rearing by the producer based on factors such as disease susceptibility, feed conversion efficiency, rate of development, and generational turnover. [42]

Insect food products

The following processed foods are produced in North America (including Canada), and the EU:

Food and drink companies such as the Australian brewery Bentspoke Brewing Co and the South African startup Gourmet Grubb have introduced insect-based beer, [46] a milk alternative, and insect ice cream. [47]

Food safety

Like other foods, the consumption of insects presents health risks stemming from biological, toxicological, and allergenic hazards. [48] [49] Biological hazards include bacteria, viruses, protozoa, fungi and mycotoxins; toxological risks are poisons, pesticides, heavy metals and antinutrients; allergenic hazards relate to arginine kinase, tropomyosin and α-Amylase. [50]

Chitin, a component of insect exoskeletons and other body parts, induces cytokine production in the digestive systems of humans and other mammals. Enzymes break the chitin down into smaller fragments, which trigger an immune response that results in inflammatory and allergic reactions. [51] The human immune response to chitin is thought to be related to the abundance of dust mites as a cause of airway inflammatory disease and parasites as a cause of numerous diseases. [51]

In general, insects harvested from the wild pose a greater risk than farmed insects, and insects consumed raw pose a greater risk than insects that are cooked before consumption. [48] Feed substrate and growing conditions are the main factors influencing the microbiological and chemical hazards of farmed insects. [52] [53]

The table below combined the data from two studies [54] [55] published in Comprehensive Reviews in Food Science and Food Safety and summarized the potential hazards of the top five insect species consumed by humans.

Insect orderCommon nameHazard categoryPotential hazard
Coleoptera BeetleChemical Hormones
Cyanogenic substances
Heavy metal contamination
Lepidoptera SilkwormAllergic
Chemical Thiaminase
Honeycomb moth Microbial High bacterial count
Chemical Cyanogenic substances
Hymenoptera AntChemical Antinutritional factors (tannin, phytate)
Orthoptera House cricketMicrobialHigh bacterial count
Hemiptera Parasitical Chagas disease
Diptera Black soldier flyParasitical Myiasis

The hazards identified in the above table can be controlled in various ways. Allergens can be labelled on the package to avoid consumption by allergy-susceptible consumers. Selective farming can be used to minimize chemical hazards, whereas microbial and parasitical hazards can be controlled by cooking processes. [55]

As a further guarantee for consumers, quality labeling has been introduced by the Entotrust programme, an independent and voluntary product certification of insect-based foods, which allows producers to communicate the safety and sustainability of their activities. [56]

Challenges

There are challenges associated with the production, processing, and consumption of insects as food. [11]

Production

Mass production in the insect industry is a concern due to a lack of technology and funds to efficiently harvest and produce insects. The machinery would have to house proper enclosure for each life cycle of the insect as well as the temperature control as that is key for insect development. [57]

Processing

The availability of wild-harvested insects can be seasonally dependent. [58] This presents a challenge, as many wild-harvested insects have a short shelf life, sometimes of only a day or two. [59] Identifying methods of processing and storing that extend the shelf life of seasonal insects will improve the efficiency of their harvest and consumption.

Aversion

The concept of eating insects is generally taboo in Western cultures. [60] Backlash against using insects as food has also involved conspiracy theories regarding government control. [61]

Regulation and authorisation

EU

In the European Union, edible insects – whole or in parts, e.g., legs, wings, or heads – fall within the definition of novel food, given by the European Commission. [62] Dossiers for several insect species are currently under review by the European Food Safety Authority.

In August 2018, EFSA published a first risk profile for the house cricket as food. [63] According to a risk assessment published by EFSA on 13 January 2021, the yellow mealworm is safe for human consumption. [64] [65] On 2 July 2021, EFSA published another scientific opinion stating that migratory locust in frozen, dried or ground state is safe for human consumption. [66] On 17 August 2021, EFSA published a safety assessment with view to house crickets (Acheta domesticus) stating that frozen and dried formulations from whole house crickets are safe for consumption. [67] On 4 July 2022, EFSA published an opinion confirming the safety of frozen and freeze-dried formulations of the lesser mealworm (Alphitobius diaperinus in larval state) for human consumption. [68]

Following EFSA's assessment, the European Commission has authorized the following edible insects as novel food in the EU:

Switzerland

On 1 May 2017, Switzerland approved the following insect species as food: [73]

Under certain conditions, these may be offered to consumers whole, pulverized, or processed in food products.

UK

After the Brexit transition period, the regulation regarding edible insects changed in the United Kingdom on 21 January 2021, making them non-marketable without authorization.[ citation needed ] Insect food products that had been on the market had to be recalled. Insect food products have to be authorized by the Food Standards Agency (FSA) in a novel food authorization process. [74] [75] In February 2022, UK insect industry association Woven Network CIC submitted a first dossier for the authorization of house crickets (Acheta domesticus) as novel food to the FSA. [76]

USA and Canada

In the USA and Canada, insects for human consumption are not classified as novel food and the import and sale is permitted.[ citation needed ] In the US, insect food products must comply with FDA standards and food labelling regulations (including allergy risk labelling). [77]

Within the Federal Food, Drug, and Cosmetic Act (FD&C Act), the FDA states that "The term 'food' means (1) articles used for food or drink for man or other animals, (2) chewing gum, and (3) articles used for components of any such article." [78] Thus, with insects falling under said category, they must be safe and may not bear any added poisonous or added deleterious substance that is unsafe. Said items may not be prepared, packed, or held under insanitary conditions, and must be produced in accordance with current Good Manufacturing Practice (GMP), regulations for manufacturing/processing, packing, or holding human food. [79] [80] The FD&C Act also includes requirements that pertain to the labeling of food and preventive controls, as applicable. Manufacturers have a responsibility to ensure that the food they produce for the United States market is safe and complies with the FD&C Act and FDA's implementing regulations. [3]

In Canada, insects are subject to the same standards and guidelines as other foods sold in stores or online. [81]

Singapore

Singapore Food Agency (SFA) has approved 16 species of insects, such as crickets, silkworms and grasshoppers, for human consumption in the second half of 2023. [82]

The approval of the insects for consumption will be subject to food safety requirements, including treatment processes to kill pathogens and ensuring that they are packed and stored safely to prevent contamination. [82]

Awareness

World Edible Insect Day, held on 23 October, was introduced by Belgian entrepreneur Chris Derudder in 2015 to raise awareness globally for the consumption of edible insects, with a focus on Europe, North America, and Australia. [83]

History

Insects have long been a part of the human diet, dating back to prehistoric times. Ancient Roman soldiers may have eaten insects like locusts when resources were low. [84]

See also

Footnotes

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Further reading

Related Research Articles

<span class="mw-page-title-main">Locust</span> Grasshopper that has a swarming phase

Locusts are various species of short-horned grasshoppers in the family Acrididae that have a swarming phase. These insects are usually solitary, but under certain circumstances they become more abundant and change their behaviour and habits, becoming gregarious. No taxonomic distinction is made between locust and grasshopper species; the basis for the definition is whether a species forms swarms under intermittently suitable conditions; this has evolved independently in multiple lineages, comprising at least 18 genera in 5 different subfamilies.

<span class="mw-page-title-main">Mealworm</span> Species of darkling beetle, larval form

Mealworms are the larval form of the yellow mealworm beetle, Tenebrio molitor, a species of darkling beetle.

<span class="mw-page-title-main">Migratory locust</span> Species of grasshopper

The migratory locust is the most widespread locust species, and the only species in the genus Locusta. It occurs throughout Africa, Europe, Asia, Australia and New Zealand. Because of the vast geographic area it occupies, which comprises many different ecological zones, numerous subspecies have been described. However, not all experts agree on the validity of some of these subspecies.

<span class="mw-page-title-main">Huhu beetle</span> Species of insect

The huhu beetle is a longhorn beetle endemic to New Zealand. It is the heaviest beetle found in New Zealand.

<span class="mw-page-title-main">Entomophagy in humans</span> Practice of eating insects in human cultures

Entomophagy in humans or human entomophagy describes the consumption of insects (entomophagy) by humans in a cultural and biological context. The scientific term used in anthropology, cultural studies, biology and medicine is anthropo-entomophagy. Anthropo-entomophagy does not include the eating of arthropods other than insects such as arachnids and myriapods, which is defined as arachnophagy.

<span class="mw-page-title-main">Edible</span> Item safe for human consumption

An edible item is any item that is safe for humans to eat. "Edible" is differentiated from "eatable" because it does not indicate how an item tastes, only whether it is fit to be eaten. Nonpoisonous items found in nature – such as some mushrooms, insects, seaweed, and so forth – are referred to as edible. Processed items that normally are not ingested but are specially manufactured to be so, like edible underwear or edible packaging, are also labeled as edible.

<span class="mw-page-title-main">House cricket</span> Species of cricket

Acheta domesticus, commonly called the house cricket, is a species of cricket most likely native to Southwestern Asia, but between 1950 and 2000 it became the standard feeder insect for the pet and research industries and spread worldwide. They can be kept as pets themselves, as this has been the case in China and Japan.

<span class="mw-page-title-main">Pet food</span> Animal feed for pets

Pet food is animal feed intended for consumption by pets. Typically sold in pet stores and supermarkets, it is usually specific to the type of animal, such as dog food or cat food. Most meat used for animals is a byproduct of the human food industry, and is not regarded as "human grade".

<span class="mw-page-title-main">Live food</span> Pet owner or zoo practice

Live food is living animals used as food for other carnivorous or omnivorous animals kept in captivity; in other words, small preys fed alive to larger predators kept either in a zoo or as a pet.

<span class="mw-page-title-main">Hydroxytyrosol</span> Chemical compound

Hydroxytyrosol is an organic compound with the formula (HO)2C6H3CH2CH2OH. It is a phenylethanoid, i.e. a relative of phenethyl alcohol. Its derivatives are found in a variety of natural sources, notably olive oils and wines. Hydroxytyrosol is a colorless solid, although samples often turn beige during storage. It is a derivative, formally speaking, of catechol.

<span class="mw-page-title-main">Insect farming</span> Raising and breeding insects as livestock

Insect farming is the practice of raising and breeding insects as livestock, also referred to as minilivestock or micro stock. Insects may be farmed for the commodities they produce, or for them themselves; to be used as food, as feed, as a dye, and otherwise.

Selenium yeast is a feed additive for livestock, used to increase the selenium content in their fodder. It is a form of selenium currently approved for human consumption in the EU and Britain. Inorganic forms of selenium are used in feeds. Since these products can be patented, producers can demand premium prices. It is produced by fermenting Saccharomyces cerevisiae in a selenium-rich media.

<i>Alphitobius diaperinus</i> Species of beetle

Alphitobius diaperinus is a species of beetle in the family Tenebrionidae, the darkling beetles. It is known commonly as the lesser mealworm and the litter beetle. It has a cosmopolitan distribution, occurring nearly worldwide. It is known widely as a pest insect of stored food grain products such as flour, and of poultry-rearing facilities and it is a vector of many kinds of animal pathogens. In larval form, it is an approved novel food in the European Union, and also used as animal feed.

<span class="mw-page-title-main">Welfare of farmed insects</span> Form of animal welfare

The welfare of farmed insects concerns treatment of insects raised for animal feed, as food or pet food, and other purposes such as honey and silk.

Insect-based pet food is pet food consisting of, or containing insects digestible by pets such as dogs or cats. A limited, but growing number of products are available on the market, including insect-based cat food, dog food, and pet treats.

<span class="mw-page-title-main">Human interactions with insects in southern Africa</span>

Various cultures throughout Africa utilize insects for many things and have developed unique interactions with insects: as food sources, for sale or trade in markets, or for use in traditional practices and rituals, as ethnomedicine or as part of their traditional ecological knowledge. As food, also known as entomophagy, a variety of insects are collected as part of a protein rich source of nutrition for marginal communities. Entomophagy had been part of traditional culture throughout Africa, though this activity has been diminishing gradually with the influx of Western culture and market economies. Often the collection of insects for food has been the activity of children, both male and female.

<span class="mw-page-title-main">Insects as feed</span>

Insects as feed are insect species used as animal feed, either for livestock, including aquaculture, or as pet food.

<span class="mw-page-title-main">Entomophagy</span> Practice of eating insects by organisms

Entomophagy is the practice of eating insects. An alternative term is insectivory. Terms for organisms that practice entomophagy are entomophage and insectivore.

<span class="mw-page-title-main">Entotrust certification</span> Certification for alternative proteins

The Entotrust certification is a voluntary product certification of insects as food, and related insect-based foods, which allows producers to communicate their food safety and sustainability. Increasingly used, in Europe, Africa, Asia, US, Mexico, and Latam with the mission to recognize and report quality products based on edible insects, the logo can only be used by fully certified producers and farmers.

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