TY  - CONF
AU  - Петровић-Обрадовић, Оливера
AU  - Спасић, Радослава
AU  - Игњатовић-Ћупина, Александра
AU  - Главендекић, Милка
AU  - Кљајић, Петар
AU  - Танасковић, Снежана
AU  - Црвковић, Татјана
AU  - Коњевић, Александра
AU  - Миловац, Жељко
AU  - Стојановић, Дејан В.
PY  - 2022
UR  - https://dais.sanu.ac.rs/123456789/16113
AB  - Ентомологија је веома значајна научна дисциплина која својим
сазнањима доприноси развоју биљне производње и природних ресурса.
Иако су ентомолошка истраживања на подручју Србије обављана и много
раније, оснивачем ентомологије сматра се академик Јосиф Панчић, који је
1883. године објавио монографију Orthoptera Србије, описавши у њој 137 вр-
ста, од чега су две врсте нове за науку. У исто то време, у Србији је регистро-
вано присуство филоксере, велике штеточине винове лозе, па је те исте 1883.
године донет и први закон о овој карантинској штеточини.
Значајнији и свеобухватнији рад у области ентомологије, али и њен
развој, почиње са оснивањем Пољопривредног факултета у Београду 1919.
године. Први професор ентомологије био је др Јулије Вагнер, његов сарадник
и оснивач модерне ентомологије био је др Михајло Градојевић. У периоду
између два рата велики допринос ентомологији дали су академик др Павле
Вукасовић и др Светислав Живојиновић. Они су се бавили систематиком
инсеката, фаунистичким истраживањима и примењеном ентомологијом. Го-
дине 1938. основан је Институт за ратарство и повртарство у Новом Саду; после Другог светског рата оснивају се Институт за заштиту биља у Бео-
граду, Институт за пестициде и заштиту животне средине у Земуну, Ин-
ститут за шумарство у Београду и Завод за тополе у Новом Саду. Такође,
Шумарски факултет у Београду одвојио се као засебан 1949. године, а осно-
вани су и Пољопривредни факултет у Новом Саду, Агрономски факултет
у Чачку и Пољопривредни факултет у Приштини. Временом се повећава
број истраживања у области ентомологије и образују се инжењери зашти-
те биља и инжењери шумарства са специјализацијама из ентомологије и
заштите шума. Са повећањем производње, сложенији постају проблеми
које инсекти стварају у пољопривреди и шумарству. У Србији долази до
појаве адвентивних и инвазивних врста, као што су кромпирова златица,
дудовац, калифорнијска штитаста ваш и крвава ваш, неколико масовних
појава губара захватају велике шумске комплексе и пољопривредне усеве.
Ентомолози раде на проучавању природних непријатеља инсеката и уводи
се у праксу биолошка заштита биља и систем интегралних мера заштите од
штетних инсеката. Веома запажен допринос у образовању нових стручњака
и развоју струке и науке дали су проф. Гвидо Нонвеје, проф. Константин
Васић, др Драгић Томић, проф. Љубодраг Михајловић, академик Душан
Чампраг, проф. Никола Танасијевић, др Љубиша Васиљевић, проф. Жив-
ко Срдић, проф. Душка Симова-Тошић, проф. Радосав Секулић, др Илија
Перић, др Ћирил Сидор, др Иштван Јодал, др Марко Ињац, др Фрања Бача,
др Сретен Стаменковић, али и многи други ентомолози. Последњих година
велики проблем у биљној производњи представљају нове инвазивне инсе-
катске врсте као штеточине и преносиоци патогена. Примена технолошки
савремених метода у ентомологији, попут молекуларних техника, доприно-
си бржој идентификацији узрочника штета у пољопривреди и шумарству,
али и решавању штета које наносе.
Развој ентомологије у Србији обављао се у више праваца, а најзна-
чајнији су: таксономска и фаунистичка проучавања, проучавања биологије
и екологије економски значајних врста, интегрално сузбијање штеточи-
на, проучавање корисних организама и њихове улоге у биолошкој контро-
ли штетних врста, проучавање векторске улоге инсеката у епидемиологији
фитоплазматичних и вирусних болести биљака. У раду ће бити приказана
најзначајнија достигнућа наведених праваца истраживања.
AB  - Entomology is an important scientific discipline, which, with the knowledge
it provides, contributes to the development of plant production and preservation
of natural resources. Although entomological research in Serbia was
conducted years earlier, it is considered that the founder of entomology was Josif
Pančić, who published a monograph in 1883, titled “Orthoptera in Serbia”, describing
137 insect species in it, two of them new for science. At the same time, the presence of phylloxera, a significant grape pest, was registered in Serbia, which
led to the passing of the first law concerning this quarantine pest, in the same year.
A more significant and comprehensive work in this field, and also its development,
began in 1919, with the founding of the Faculty of Agriculture in Belgrade.
The first entomology professor was Dr. Julije Vagner and his associate Dr.
Mihajlo Gradojević was the founder of modern entomology. Between the two
world wars, academicians Dr. Pavle Vukasović and Dr. Svetislav Živojinović made
a big contribution to entomology, concerning insect systematics, faunal research
and applied entomology. The Institute of Field and Vegetable Crops was founded
in Novi Sad in 1938, followed by the establishing of the Institute for Plant Protection
in Belgrade, the Institute of Pesticides and Environmental Protection in
Zemun, the Institute of Forestry in Belgrade, and the Poplar Research Institute in
Novi Sad, after World War II. The Faculty of Forestry in Belgrade was separated
from the Faculty of Agriculture in 1949, after which the Faculty of Agriculture
in Novi Sad, the Faculty of Agronomy in Čačak and the Faculty of Agriculture
in Priština were founded. Over time, owing to increased research and education,
more plant protection engineers and forestry engineers have been specializing
in entomology and forest protection. With expanding productions, the problems
that insects have been causing in agriculture and forestry have become more elaborate.
New adventives and invasive species have been arriving to Serbia, such as
the Colorado potato beetle, paper mulberry, San Jose scale and wooly apple aphid.
Entomologists have been studying natural enemies of insects, working on their
introduction as biological plant protection agents and creating a system of integrated
plant protection measures. The following experts made an important contribution
to the education of new experts and the development of both practice
and science: professor Guido Nonveiller, professor Konstantin Vasić, Dr. Dragić
Tomić, professor Ljubodrag Mihajlović, academician Dušan Čamprag, professor
Nikola Tanasijević, Dr. Ljubiša Vasiljević, professor Živko Srdić, professor Duška
Simova-Tošić, professor Radosav Sekulić, Dr. Ilija Perić, Dr. Ćiril Sidor, Dr. Ištvan
Jodal, Dr. Marko Injac, Dr. Franja Bača, Dr. Sreten Stamenković, and many other
entomologists. In recent years, some new invasive insect species have become a
major problem in plant production, as pests and vectors of plant pathogens. Contemporary
methods in entomology, such as molecular techniques, contribute to
faster identification of pests causing damage in agriculture and forestry, and also
to solving the problems they cause.
The development of entomology in Serbia has been carried out in several
directions, the most important being: taxonomic and faunal studies, studies of
biology and ecology of economically important species, integrated pest control,
studies of beneficial organisms and their role in biological control of harmful species,
studies of insects as vectors of pathogens causing viral diseases. This paper
presents the most important achievements of this research.
PB  - Београд : Српска академија наука и уметности
C3  - Заштита здравља биљака : зборник радова са научног скупа одржаног 27. октобра 2020. године : примљено на I скупу Одељења хемијских и биолошких наука од 18. фебруара 2022. године
T1  - Развој и достигнућа ентомологије у области биљне производње у Србији
T1  - Development and achievements of entomology in the field of plant production in Serbia
SP  - 53
EP  - 76
UR  - https://hdl.handle.net/21.15107/rcub_dais_16113
ER  - 

@conference{
author = "Петровић-Обрадовић, Оливера and Спасић, Радослава and Игњатовић-Ћупина, Александра and Главендекић, Милка and Кљајић, Петар and Танасковић, Снежана and Црвковић, Татјана and Коњевић, Александра and Миловац, Жељко and Стојановић, Дејан В.",
year = "2022",
abstract = "Ентомологија је веома значајна научна дисциплина која својим
сазнањима доприноси развоју биљне производње и природних ресурса.
Иако су ентомолошка истраживања на подручју Србије обављана и много
раније, оснивачем ентомологије сматра се академик Јосиф Панчић, који је
1883. године објавио монографију Orthoptera Србије, описавши у њој 137 вр-
ста, од чега су две врсте нове за науку. У исто то време, у Србији је регистро-
вано присуство филоксере, велике штеточине винове лозе, па је те исте 1883.
године донет и први закон о овој карантинској штеточини.
Значајнији и свеобухватнији рад у области ентомологије, али и њен
развој, почиње са оснивањем Пољопривредног факултета у Београду 1919.
године. Први професор ентомологије био је др Јулије Вагнер, његов сарадник
и оснивач модерне ентомологије био је др Михајло Градојевић. У периоду
између два рата велики допринос ентомологији дали су академик др Павле
Вукасовић и др Светислав Живојиновић. Они су се бавили систематиком
инсеката, фаунистичким истраживањима и примењеном ентомологијом. Го-
дине 1938. основан је Институт за ратарство и повртарство у Новом Саду; после Другог светског рата оснивају се Институт за заштиту биља у Бео-
граду, Институт за пестициде и заштиту животне средине у Земуну, Ин-
ститут за шумарство у Београду и Завод за тополе у Новом Саду. Такође,
Шумарски факултет у Београду одвојио се као засебан 1949. године, а осно-
вани су и Пољопривредни факултет у Новом Саду, Агрономски факултет
у Чачку и Пољопривредни факултет у Приштини. Временом се повећава
број истраживања у области ентомологије и образују се инжењери зашти-
те биља и инжењери шумарства са специјализацијама из ентомологије и
заштите шума. Са повећањем производње, сложенији постају проблеми
које инсекти стварају у пољопривреди и шумарству. У Србији долази до
појаве адвентивних и инвазивних врста, као што су кромпирова златица,
дудовац, калифорнијска штитаста ваш и крвава ваш, неколико масовних
појава губара захватају велике шумске комплексе и пољопривредне усеве.
Ентомолози раде на проучавању природних непријатеља инсеката и уводи
се у праксу биолошка заштита биља и систем интегралних мера заштите од
штетних инсеката. Веома запажен допринос у образовању нових стручњака
и развоју струке и науке дали су проф. Гвидо Нонвеје, проф. Константин
Васић, др Драгић Томић, проф. Љубодраг Михајловић, академик Душан
Чампраг, проф. Никола Танасијевић, др Љубиша Васиљевић, проф. Жив-
ко Срдић, проф. Душка Симова-Тошић, проф. Радосав Секулић, др Илија
Перић, др Ћирил Сидор, др Иштван Јодал, др Марко Ињац, др Фрања Бача,
др Сретен Стаменковић, али и многи други ентомолози. Последњих година
велики проблем у биљној производњи представљају нове инвазивне инсе-
катске врсте као штеточине и преносиоци патогена. Примена технолошки
савремених метода у ентомологији, попут молекуларних техника, доприно-
си бржој идентификацији узрочника штета у пољопривреди и шумарству,
али и решавању штета које наносе.
Развој ентомологије у Србији обављао се у више праваца, а најзна-
чајнији су: таксономска и фаунистичка проучавања, проучавања биологије
и екологије економски значајних врста, интегрално сузбијање штеточи-
на, проучавање корисних организама и њихове улоге у биолошкој контро-
ли штетних врста, проучавање векторске улоге инсеката у епидемиологији
фитоплазматичних и вирусних болести биљака. У раду ће бити приказана
најзначајнија достигнућа наведених праваца истраживања., Entomology is an important scientific discipline, which, with the knowledge
it provides, contributes to the development of plant production and preservation
of natural resources. Although entomological research in Serbia was
conducted years earlier, it is considered that the founder of entomology was Josif
Pančić, who published a monograph in 1883, titled “Orthoptera in Serbia”, describing
137 insect species in it, two of them new for science. At the same time, the presence of phylloxera, a significant grape pest, was registered in Serbia, which
led to the passing of the first law concerning this quarantine pest, in the same year.
A more significant and comprehensive work in this field, and also its development,
began in 1919, with the founding of the Faculty of Agriculture in Belgrade.
The first entomology professor was Dr. Julije Vagner and his associate Dr.
Mihajlo Gradojević was the founder of modern entomology. Between the two
world wars, academicians Dr. Pavle Vukasović and Dr. Svetislav Živojinović made
a big contribution to entomology, concerning insect systematics, faunal research
and applied entomology. The Institute of Field and Vegetable Crops was founded
in Novi Sad in 1938, followed by the establishing of the Institute for Plant Protection
in Belgrade, the Institute of Pesticides and Environmental Protection in
Zemun, the Institute of Forestry in Belgrade, and the Poplar Research Institute in
Novi Sad, after World War II. The Faculty of Forestry in Belgrade was separated
from the Faculty of Agriculture in 1949, after which the Faculty of Agriculture
in Novi Sad, the Faculty of Agronomy in Čačak and the Faculty of Agriculture
in Priština were founded. Over time, owing to increased research and education,
more plant protection engineers and forestry engineers have been specializing
in entomology and forest protection. With expanding productions, the problems
that insects have been causing in agriculture and forestry have become more elaborate.
New adventives and invasive species have been arriving to Serbia, such as
the Colorado potato beetle, paper mulberry, San Jose scale and wooly apple aphid.
Entomologists have been studying natural enemies of insects, working on their
introduction as biological plant protection agents and creating a system of integrated
plant protection measures. The following experts made an important contribution
to the education of new experts and the development of both practice
and science: professor Guido Nonveiller, professor Konstantin Vasić, Dr. Dragić
Tomić, professor Ljubodrag Mihajlović, academician Dušan Čamprag, professor
Nikola Tanasijević, Dr. Ljubiša Vasiljević, professor Živko Srdić, professor Duška
Simova-Tošić, professor Radosav Sekulić, Dr. Ilija Perić, Dr. Ćiril Sidor, Dr. Ištvan
Jodal, Dr. Marko Injac, Dr. Franja Bača, Dr. Sreten Stamenković, and many other
entomologists. In recent years, some new invasive insect species have become a
major problem in plant production, as pests and vectors of plant pathogens. Contemporary
methods in entomology, such as molecular techniques, contribute to
faster identification of pests causing damage in agriculture and forestry, and also
to solving the problems they cause.
The development of entomology in Serbia has been carried out in several
directions, the most important being: taxonomic and faunal studies, studies of
biology and ecology of economically important species, integrated pest control,
studies of beneficial organisms and their role in biological control of harmful species,
studies of insects as vectors of pathogens causing viral diseases. This paper
presents the most important achievements of this research.",
publisher = "Београд : Српска академија наука и уметности",
journal = "Заштита здравља биљака : зборник радова са научног скупа одржаног 27. октобра 2020. године : примљено на I скупу Одељења хемијских и биолошких наука од 18. фебруара 2022. године",
title = "Развој и достигнућа ентомологије у области биљне производње у Србији, Development and achievements of entomology in the field of plant production in Serbia",
pages = "53-76",
url = "https://hdl.handle.net/21.15107/rcub_dais_16113"
}

Петровић-Обрадовић, О., Спасић, Р., Игњатовић-Ћупина, А., Главендекић, М., Кљајић, П., Танасковић, С., Црвковић, Т., Коњевић, А., Миловац, Ж.,& Стојановић, Д. В.. (2022). Развој и достигнућа ентомологије у области биљне производње у Србији. in Заштита здравља биљака : зборник радова са научног скупа одржаног 27. октобра 2020. године : примљено на I скупу Одељења хемијских и биолошких наука од 18. фебруара 2022. године
Београд : Српска академија наука и уметности., 53-76.
https://hdl.handle.net/21.15107/rcub_dais_16113

Петровић-Обрадовић О, Спасић Р, Игњатовић-Ћупина А, Главендекић М, Кљајић П, Танасковић С, Црвковић Т, Коњевић А, Миловац Ж, Стојановић ДВ. Развој и достигнућа ентомологије у области биљне производње у Србији. in Заштита здравља биљака : зборник радова са научног скупа одржаног 27. октобра 2020. године : примљено на I скупу Одељења хемијских и биолошких наука од 18. фебруара 2022. године. 2022;:53-76.
https://hdl.handle.net/21.15107/rcub_dais_16113 .

Петровић-Обрадовић, Оливера, Спасић, Радослава, Игњатовић-Ћупина, Александра, Главендекић, Милка, Кљајић, Петар, Танасковић, Снежана, Црвковић, Татјана, Коњевић, Александра, Миловац, Жељко, Стојановић, Дејан В., "Развој и достигнућа ентомологије у области биљне производње у Србији" in Заштита здравља биљака : зборник радова са научног скупа одржаног 27. октобра 2020. године : примљено на I скупу Одељења хемијских и биолошких наука од 18. фебруара 2022. године (2022):53-76,
https://hdl.handle.net/21.15107/rcub_dais_16113 .

TY  - CONF
AU  - Кавран, Михаела
AU  - Игњатовић Ћупина, Александра
AU  - Згомба, Марија
AU  - Петрић, Душан
PY  - 2018
UR  - https://dais.sanu.ac.rs/123456789/10699
AB  - Инсекти спадају у групу најуспешнијих организама на
планети пре свега због специфичне грађе и величине тела, високог репродук-
ционог потенцијала и способности адаптације. Они су нуклеус развоја свих копнених и слатководних станишта и омогућавају опстанак живота на Земљи. Као
полинатори имају пресудну улогу у опстанку многих биљака, спречавају наго-
милавање органске материје у природи, чине важне делове у ланцима исхране
али исто тако могу да поједу 25% бруто националног дохотка у земљама у раз-
воју, а само комарци (најопасније животиње на свету), преношењем патогена,
годишње „убијају“ 725 000 људи. Међутим, огромни благотворни потенцијал
ових организама само је малим делом искоришћен. Инсекти представљају бо-
гат извор протеина и других корисних материја за развој човека и животиња.
Пораст светске популације људи ће несумњиво изазвати повећану продукцију
хране, што ће неизбежно угрозити већ лимитиране ресурсе за њену производњу
(земљиште, вода, ђубриво и енергија). Ентомофагија (исхрана инсектима) може
бити једно од решења проблема предвиђене несташице хране, те се све чешће
предлаже коришћење инсеката за исхрану људи, стоке, кућних љубимаца и риба.
Организација за пољопривреду и храну Уједињених нација (FAO) је почетком
века почела са промовисањем употребе инсеката у исхрани која је у неким раз-
вијеним земљама (Холандија) већ добро прихваћена. До сада се у индустријским постројењима масовно и успешно гаје врсте Hermetia illucens, Musca domestica,
Tenebrio molitor и Acheta domesticus. Гајење инсеката у ове сврхе је вишеструко
корисно јер осим продукције хране може да реши проблем уклањања органс-
ког отпада и отпуштања гасова стаклене баште, продукције ђубрива и фарма-
цеутских производа и допринесе уштеди енергије и развоју предузетништва.
За практичну примену ове идеје у Србији потребно је подстаћи примењена
истраживања и подићи ниво знања о сакупљању и могућностима гајења ових
организама. Молестанти као што су комарци, муве, хирономиде, штеточине у
пољопривредној и шумарској производњи и поред честих масовних појава и биомасе коју том приликом продукују још увек нису искоришћени у нашој земљи.
AB  - This paper describes the contribution of insects to food security and
survey future prospects for raising insects at a commercial scale to improve
food and feed production, diversify diets, and support livelihoods in both
developing and developed countries. It indicatеs some traditional and potential
uses of insects for direct human consumption and the opportunities for and
constraints to farming them for food and feed.
The concept of sustainable diets, with biodiversity and at its core, has
recently received renewed attention as the world struggles with many natural and
man-made disasters. Sustainable diets are those diets with low environmental
impacts which contribute to food and nutrition security and to healthy life for
present and future generations. Sustainable diets are protective and respectful
of biodiversity and ecosystems, culturally acceptable, accessible, economically
fair and affordable; nutritionally adequate, safe and healthy; while optimizing
natural and human resources [222]. Edible insects have always been a part
of human diets. Although the majority of consumed insects are gathered in
forest habitats, mass-rearing systems are being developed in many countries.
Insects offer a significant opportunity to merge traditional knowledge and
modern science to improve human food security worldwide. However, the
urbanization has led to new human bahaviour that is far from natural resources
and distant to the wild environment. Additionally, in some societies there is a
degree of distaste for inscts consumption that further developed a standstill of
the grasshopers in the Nile vally (Amar, 2003). Although the majority of edible
insects are gathered from forest habitats, innovation in mass-rearing systems
has begun in many countries. Insects offer a significant opportunity to merge
traditional knowledge and modern science in both developed and developing
countries. Edible insects as food fit comfortably within this environmentally
sound scenario and, by extension, ought to be considered prime candidates as
both food staples and supplements, as well as more generally for their role in
sustainable diets.
Sustainability of food and agriculture activities upon which 2.4 billion
people depend for livelihoods was considered a key driver in the transition
towards a green economy, due to its dual positive impact on ecosystem services
and poverty alleviation [222, 229]. Recent studies confirm that the insects are potentially an important energy
efficient source of protein for humans, either through a direct consumption or
as food supplements for stock. The high protein content is an indication that
the insects can be of value in man and animal ration and can eventually replace
higher animal protein usually absent in the diet of rural dwellers in developing
countries [87]. The protein content varies by species of insects, but generally is
of a good quality and high digestibility [48]. Analyses showed that in egg, larva,
pupa and adult stages, the raw protein content is generally 15–81% / dry basis.
With a daily growing world population, there are now more than 3.7
billion people suffering from malnutrition, mainly due to lack of protein and
energy from food. Associated with the declining availability of land, water
and energy resources per capita [35], we need to conserve and manage these
resources to produce more food. Animal husbandry competes for these vital
resources, as the land is occupied by the production of feed and cannot be
used to produce food for humans [18]. Livestock production is very expensive
because it requires a large input of water, grain and fodder as well as human
effort and energy from fossil resources [35]. Utilization of insects as a protein
source could benefit insect conservation through habitat protection [18]. Insects
are essential agents feeding on organic matter in nature, and they efficiently
exploit all organic sources. It is also important that insects are able to recycle
organic waste and provide nutrients for farm animals [1, 179, 191]. Hence,
insects could be used as efficient biotransformers to convert abundant, low cost
organic wastes into animal biomass rich in proteins and suitable for use in
animal nutrition. In a world as it is today, insects can contribute to human
nutrition. Raising insects using waste biomass is already being implemented
and managed today, with minimal infrastructure. Furthermore, insect culture
requires little areas. Many of the edible insect species do not compete with
human beings for food resources. The energetic cost of collecting edible insects
is lower than that for vertebrates. Hence, insects may efficiently provide the
necessary energy for the vital functions of our organism. Some species of edible
insects have mostly the polyunsaturated fat type, as they feed on vegetables
with largely unsaturated fats [1].
Mostly, the fat content of edible insects is between 10–50%. The fat
content of insects depends on many factors such as species, reproductive
stages, season, age (life stage), or sex, habitat and diet. For example, the fat
content is higher in the larva and pupa stages; at the adult stage, the fat content
is relatively lower. Female insects contain more fat than male insects. As a
general statement it could be said that insects are not inferior to other sources
of protein such as fish, chicken or beef.
Insects can partly replace the increasingly expensive protein ingredients
of compound feeds in the livestock, poultry and aquaculture industries.
Grains now used as livestock feed, which often comprise half the cost of meat
production, could then be used for human consumption [182]. In 2011, combined world feed production was estimated at 870 million
tonnes, with revenue from global commercial feed manufacturing generating
approximately US$350 billion globally. FAO estimates that production will
have to increase by 70 percent to be able to feed the world in 2050, with meat
outputs (poultry, pork and beef) expected to double [19].
A major constraint to further development are the prohibitive costs of
feed, including meat meal, fishmeal and soybean meal, which represent 60–70
percent of production costs. Another problem is manure disposal, which is
becoming a serious environmental problem; large amounts of manure to be
stockpiled in open-air, swarming with flies and potential human health hazards.
It is striking to realize that the agricultural sector is the leading cause
of human-induced climate change. Roughly one-third of all greenhouse gas
emissions are due to agriculture, if we include the carbon dioxide emissions
from deforestation (mainly to clear land for farming and pasture), energy use in
agriculture (including the production of chemical fertilizers), methane released
by ruminant livestock and rice paddies, and nitrous oxide released by the heavy
use of nitrogen fertilizers. We will need new technologies, and new patterns of
food consumption, based on healthier and more sustainable diets [20].
There is a wealth of traditional and cultural knowledge on the uses
of edible insects as food in tropical countries, yet production is largely
concentrated in household and small-scale operations. In temperate countries,
processing technology is virtually nonexistent because edible insects are
not recognized food and feed sources. If insects are to become a useful and
profitable raw material in the food and feed industries, large quantities of
quality insects will need to be produced on a continuous basis. This requires
both introducing new farming and processing methods, which remains a
challenge for the development of the sector. However, major requirements are
rearing practices in tropical countries should employ local species because they
pose virtually no risk to the environment, there is no need for climate control,
and such local species are likely to be more culturally accepted. Selection
criteria should involve ease of rearing, taste, colour and whether they can be
used as feed. In temperate zones, cosmopolitan species like the house cricket
(Acheta domesticus) should be used, or those that do not pose environmental
risks. Species destined for mass production, moreover should possess certain
characteristics, including a high intrinsic rate of increase; a short development
cycle; high survival of immatures and high oviposition rate; a high potential of
biomass increase per day (i.e. weight gain per day); a high conversion rate (kg
biomass gain per kg feedstock); the ability to live in high densities (kg biomass
per m2); and low vulnerability to disease (high resistance). Good candidates
were considered to be the black soldier fly (Hermetia illuscens) for feed and the
yellow mealworm (Tenebrio molitor) for both food and feed [1]. Additionally,
insect animal feed developed from manure and related organic waste streams
raises bacteriological, mycological and toxicological concerns. The polarity of views surrounding the practice of entomophagy requires
tailor-made communication approaches. In parts of the world where entomophagy
is well established, such as the tropics, communication strategies need to promote
and preserve edible insects as valuable sources of nutrition in order to counter the
growing westernization of diets. In areas where food security is fragile, edible
insects need to be promoted as key foods and feeds for nutritional, cultural and
economic reasons. However, Western societies still largely averse to the practice
of eating insects will require tailored strategies that address the disgust factor and
break down common myths surrounding the practice. In general, education is the
key instrument for creating public awareness of the potential roles of insects and
in influencing consumer choices towards a more balanced and favourable outlook
on insects as food and feed.
Research on the contribution of edible insects to nutrition and economy,
on insect species’ biology and ecology has to be implemented in projects on
sustainable agriculture/food. Additionally, addressing the entomophagy disgust
factor in Western societies might depend largely on the ability to involve the entire
educational community. The past decade, however, has seen a slow but steady
rise in food insects in formal education. As of the end of 2011, 46 percent of the
universities in the United States – the main food and agricultural universities in
the country – had at least one course in their curricula that featured food insects.
In the Netherlands, the Laboratory of Entomology at Wageningen University
offers “insects and society” courses including entomophagy. The Laboratory has
an outstanding reputation in multitrophic interactions, biological control, malaria
vector research and entomophagy, and draws worldwide attention to the issue of
entomophagy. The objective is to explore the potential sustainable production
of edible insects and insect-derived products, particularly proteins, as a reliable
and high-quality food source with a lower negative environmental impact than
conventional meat production. Governmental bodies have important roles to play
in promoting insects as food and feed. In particular, the development of this new
sector as a viable (and environmentally friendly) alternative to the conventional
food and feed. Experts from international agencies, scientific institutions and
private-sector stakeholders, together with staff from relevant FAO sectors
created webportal on edible insects since 2010. It provides basic information
on the use and potential of edible insects as well as relevant weblinks, such as
to the proceedings of the conferences, information on the Expert Consultation
Meetings and other relevant technical information, videos and media coverage.
The address of the webportal is www.fao.org/forestry/edibleinsects.
In developed countries, insect rering occurs mainly on family-operated
farms. Presently, there are only a few large-scale industrial plans that rear
insects. The most common insects that were collected or reared within Europe
are: Acheta domesticus, Bombyx mori, Galleria mellonella, Gryllus assimillis,
Hermetia illucens, Locusta migratoria, Musca domestica, Schistocerca gregaria,
T. molitor and Zophobas atratus [225]. The H. illucens reperesent the species of good rearing potential because it
substantially reduce biowaste and house fly breeding and additionally can be used
as animal food [226]. Except this invasive species, few native species as grass
hopers, crickets, and mealworms, are significant source of proteins. A number
of species in Serbia are highly abundant and pose a molesting problem. This is
a case with flood water mosquitoes, insects of Chironomidae family and house
flies. Resarch on their mass production as potential food source for house pets,
animals or as a part of organic fertilazers could support a small scale of organic
farming production in rural regions. Additionally, it should not be forgotten that
some of the species have important impact in waste decomposition, hence create
additional value to the family-operated farms. Insect rearing is easy, does not
require much of technical knowledge nor high investments, therefore accessable
to a majority of rural inhabitants of a law income.
The production and consumption of insects should also be analysed from
the viewpoint of their potential impact on health and biodiversity and the potential
environmental hazards associated with insect production and release, including
the accidental release of insect species not indigenous to the area of production.
People, especially in areas where insects were not consumed for a long
time, prefer incorporating insects into the food in a way they are not visible, so
they accept only the idea that the insects have a nutritional value. This shows
that people especially in North America and Europe can eat insects if they do
not know what they are eating.These factors suggest that insect transformation
will facilitate its consumption in the future. In practice, dried insects may be
crushed or pulverized, and raw or boiled insects ground or mashed, making
their insect form unrecognizable [9].
Much work still needs to be done and many issues taken into account when
elaborating normative frameworks and adjusting for insect-inclusive food laws.
At the Expert FAO Meeting in 2012, therefore, a working group developed the
following proposals for elaborating regulatory frameworks [59].
Private and public standards may establish the basis of harmonized
regulatory practices on the use of insects as food and feed. Legal frameworks
should be developed to consolidate and set binding provisions and to ensure
the implementation and enforcement of such provisions throughout the sector.
It is necessary to promote the establishment of appropriate international and
national standards and legal frameworks to facilitate the use of insects as food
and feed and the development and formalization of the sector. It is also very
important to take into consideration the potential effects of insect production
and rearing on the environment, and the environmental and trade implications
of the international movement of insects. Develop a clear and comprehensive
legal framework at the (inter-) national level that can pave the way for production
and trade in insect products for food and feed internationally.
In the Western world, consumer acceptability will be determined, in
large part, by pricing, perceived environmental benefits, and the development by the catering industry of tasty insect-derived protein products. Preservation
and processing techniques are needed to increase shelf life, conserve quality
and increase the acceptability of insect food products; processing procedures
are also needed to transform insects into protein meal for animal/fish feedstock
and for the extraction of insect proteins to be used as ingredients in the food
industry.
Considering the immense quantities of insect biomass needed to replace
current protein-rich ingradients such as meal and oil from fish and soybeans,
automated massrearing facilities that produce stable, reliable and safe products
need to be developed. The challenge for this new industry will be to ensure the
cost-effective, reliable production of an insect biomass of high and consistent
quality. Regulatory frameworks need to be developed. The close collaboration
of government, industry and academia will be essential for success.
PB  - Београд : Српска академија наука и уметности
C3  - Eколошки и економски значај фауне Србије : зборник радова са научног скупа 17. новембар 2016.
T1  - Јестиви инсекти - безбедна храна за људе и домаће животиње
T1  - Edible insects - safe food for humans and livestock
SP  - 251
EP  - 300
UR  - https://hdl.handle.net/21.15107/rcub_dais_10699
ER  - 

@conference{
author = "Кавран, Михаела and Игњатовић Ћупина, Александра and Згомба, Марија and Петрић, Душан",
year = "2018",
abstract = "Инсекти спадају у групу најуспешнијих организама на
планети пре свега због специфичне грађе и величине тела, високог репродук-
ционог потенцијала и способности адаптације. Они су нуклеус развоја свих копнених и слатководних станишта и омогућавају опстанак живота на Земљи. Као
полинатори имају пресудну улогу у опстанку многих биљака, спречавају наго-
милавање органске материје у природи, чине важне делове у ланцима исхране
али исто тако могу да поједу 25% бруто националног дохотка у земљама у раз-
воју, а само комарци (најопасније животиње на свету), преношењем патогена,
годишње „убијају“ 725 000 људи. Међутим, огромни благотворни потенцијал
ових организама само је малим делом искоришћен. Инсекти представљају бо-
гат извор протеина и других корисних материја за развој човека и животиња.
Пораст светске популације људи ће несумњиво изазвати повећану продукцију
хране, што ће неизбежно угрозити већ лимитиране ресурсе за њену производњу
(земљиште, вода, ђубриво и енергија). Ентомофагија (исхрана инсектима) може
бити једно од решења проблема предвиђене несташице хране, те се све чешће
предлаже коришћење инсеката за исхрану људи, стоке, кућних љубимаца и риба.
Организација за пољопривреду и храну Уједињених нација (FAO) је почетком
века почела са промовисањем употребе инсеката у исхрани која је у неким раз-
вијеним земљама (Холандија) већ добро прихваћена. До сада се у индустријским постројењима масовно и успешно гаје врсте Hermetia illucens, Musca domestica,
Tenebrio molitor и Acheta domesticus. Гајење инсеката у ове сврхе је вишеструко
корисно јер осим продукције хране може да реши проблем уклањања органс-
ког отпада и отпуштања гасова стаклене баште, продукције ђубрива и фарма-
цеутских производа и допринесе уштеди енергије и развоју предузетништва.
За практичну примену ове идеје у Србији потребно је подстаћи примењена
истраживања и подићи ниво знања о сакупљању и могућностима гајења ових
организама. Молестанти као што су комарци, муве, хирономиде, штеточине у
пољопривредној и шумарској производњи и поред честих масовних појава и биомасе коју том приликом продукују још увек нису искоришћени у нашој земљи., This paper describes the contribution of insects to food security and
survey future prospects for raising insects at a commercial scale to improve
food and feed production, diversify diets, and support livelihoods in both
developing and developed countries. It indicatеs some traditional and potential
uses of insects for direct human consumption and the opportunities for and
constraints to farming them for food and feed.
The concept of sustainable diets, with biodiversity and at its core, has
recently received renewed attention as the world struggles with many natural and
man-made disasters. Sustainable diets are those diets with low environmental
impacts which contribute to food and nutrition security and to healthy life for
present and future generations. Sustainable diets are protective and respectful
of biodiversity and ecosystems, culturally acceptable, accessible, economically
fair and affordable; nutritionally adequate, safe and healthy; while optimizing
natural and human resources [222]. Edible insects have always been a part
of human diets. Although the majority of consumed insects are gathered in
forest habitats, mass-rearing systems are being developed in many countries.
Insects offer a significant opportunity to merge traditional knowledge and
modern science to improve human food security worldwide. However, the
urbanization has led to new human bahaviour that is far from natural resources
and distant to the wild environment. Additionally, in some societies there is a
degree of distaste for inscts consumption that further developed a standstill of
the grasshopers in the Nile vally (Amar, 2003). Although the majority of edible
insects are gathered from forest habitats, innovation in mass-rearing systems
has begun in many countries. Insects offer a significant opportunity to merge
traditional knowledge and modern science in both developed and developing
countries. Edible insects as food fit comfortably within this environmentally
sound scenario and, by extension, ought to be considered prime candidates as
both food staples and supplements, as well as more generally for their role in
sustainable diets.
Sustainability of food and agriculture activities upon which 2.4 billion
people depend for livelihoods was considered a key driver in the transition
towards a green economy, due to its dual positive impact on ecosystem services
and poverty alleviation [222, 229]. Recent studies confirm that the insects are potentially an important energy
efficient source of protein for humans, either through a direct consumption or
as food supplements for stock. The high protein content is an indication that
the insects can be of value in man and animal ration and can eventually replace
higher animal protein usually absent in the diet of rural dwellers in developing
countries [87]. The protein content varies by species of insects, but generally is
of a good quality and high digestibility [48]. Analyses showed that in egg, larva,
pupa and adult stages, the raw protein content is generally 15–81% / dry basis.
With a daily growing world population, there are now more than 3.7
billion people suffering from malnutrition, mainly due to lack of protein and
energy from food. Associated with the declining availability of land, water
and energy resources per capita [35], we need to conserve and manage these
resources to produce more food. Animal husbandry competes for these vital
resources, as the land is occupied by the production of feed and cannot be
used to produce food for humans [18]. Livestock production is very expensive
because it requires a large input of water, grain and fodder as well as human
effort and energy from fossil resources [35]. Utilization of insects as a protein
source could benefit insect conservation through habitat protection [18]. Insects
are essential agents feeding on organic matter in nature, and they efficiently
exploit all organic sources. It is also important that insects are able to recycle
organic waste and provide nutrients for farm animals [1, 179, 191]. Hence,
insects could be used as efficient biotransformers to convert abundant, low cost
organic wastes into animal biomass rich in proteins and suitable for use in
animal nutrition. In a world as it is today, insects can contribute to human
nutrition. Raising insects using waste biomass is already being implemented
and managed today, with minimal infrastructure. Furthermore, insect culture
requires little areas. Many of the edible insect species do not compete with
human beings for food resources. The energetic cost of collecting edible insects
is lower than that for vertebrates. Hence, insects may efficiently provide the
necessary energy for the vital functions of our organism. Some species of edible
insects have mostly the polyunsaturated fat type, as they feed on vegetables
with largely unsaturated fats [1].
Mostly, the fat content of edible insects is between 10–50%. The fat
content of insects depends on many factors such as species, reproductive
stages, season, age (life stage), or sex, habitat and diet. For example, the fat
content is higher in the larva and pupa stages; at the adult stage, the fat content
is relatively lower. Female insects contain more fat than male insects. As a
general statement it could be said that insects are not inferior to other sources
of protein such as fish, chicken or beef.
Insects can partly replace the increasingly expensive protein ingredients
of compound feeds in the livestock, poultry and aquaculture industries.
Grains now used as livestock feed, which often comprise half the cost of meat
production, could then be used for human consumption [182]. In 2011, combined world feed production was estimated at 870 million
tonnes, with revenue from global commercial feed manufacturing generating
approximately US$350 billion globally. FAO estimates that production will
have to increase by 70 percent to be able to feed the world in 2050, with meat
outputs (poultry, pork and beef) expected to double [19].
A major constraint to further development are the prohibitive costs of
feed, including meat meal, fishmeal and soybean meal, which represent 60–70
percent of production costs. Another problem is manure disposal, which is
becoming a serious environmental problem; large amounts of manure to be
stockpiled in open-air, swarming with flies and potential human health hazards.
It is striking to realize that the agricultural sector is the leading cause
of human-induced climate change. Roughly one-third of all greenhouse gas
emissions are due to agriculture, if we include the carbon dioxide emissions
from deforestation (mainly to clear land for farming and pasture), energy use in
agriculture (including the production of chemical fertilizers), methane released
by ruminant livestock and rice paddies, and nitrous oxide released by the heavy
use of nitrogen fertilizers. We will need new technologies, and new patterns of
food consumption, based on healthier and more sustainable diets [20].
There is a wealth of traditional and cultural knowledge on the uses
of edible insects as food in tropical countries, yet production is largely
concentrated in household and small-scale operations. In temperate countries,
processing technology is virtually nonexistent because edible insects are
not recognized food and feed sources. If insects are to become a useful and
profitable raw material in the food and feed industries, large quantities of
quality insects will need to be produced on a continuous basis. This requires
both introducing new farming and processing methods, which remains a
challenge for the development of the sector. However, major requirements are
rearing practices in tropical countries should employ local species because they
pose virtually no risk to the environment, there is no need for climate control,
and such local species are likely to be more culturally accepted. Selection
criteria should involve ease of rearing, taste, colour and whether they can be
used as feed. In temperate zones, cosmopolitan species like the house cricket
(Acheta domesticus) should be used, or those that do not pose environmental
risks. Species destined for mass production, moreover should possess certain
characteristics, including a high intrinsic rate of increase; a short development
cycle; high survival of immatures and high oviposition rate; a high potential of
biomass increase per day (i.e. weight gain per day); a high conversion rate (kg
biomass gain per kg feedstock); the ability to live in high densities (kg biomass
per m2); and low vulnerability to disease (high resistance). Good candidates
were considered to be the black soldier fly (Hermetia illuscens) for feed and the
yellow mealworm (Tenebrio molitor) for both food and feed [1]. Additionally,
insect animal feed developed from manure and related organic waste streams
raises bacteriological, mycological and toxicological concerns. The polarity of views surrounding the practice of entomophagy requires
tailor-made communication approaches. In parts of the world where entomophagy
is well established, such as the tropics, communication strategies need to promote
and preserve edible insects as valuable sources of nutrition in order to counter the
growing westernization of diets. In areas where food security is fragile, edible
insects need to be promoted as key foods and feeds for nutritional, cultural and
economic reasons. However, Western societies still largely averse to the practice
of eating insects will require tailored strategies that address the disgust factor and
break down common myths surrounding the practice. In general, education is the
key instrument for creating public awareness of the potential roles of insects and
in influencing consumer choices towards a more balanced and favourable outlook
on insects as food and feed.
Research on the contribution of edible insects to nutrition and economy,
on insect species’ biology and ecology has to be implemented in projects on
sustainable agriculture/food. Additionally, addressing the entomophagy disgust
factor in Western societies might depend largely on the ability to involve the entire
educational community. The past decade, however, has seen a slow but steady
rise in food insects in formal education. As of the end of 2011, 46 percent of the
universities in the United States – the main food and agricultural universities in
the country – had at least one course in their curricula that featured food insects.
In the Netherlands, the Laboratory of Entomology at Wageningen University
offers “insects and society” courses including entomophagy. The Laboratory has
an outstanding reputation in multitrophic interactions, biological control, malaria
vector research and entomophagy, and draws worldwide attention to the issue of
entomophagy. The objective is to explore the potential sustainable production
of edible insects and insect-derived products, particularly proteins, as a reliable
and high-quality food source with a lower negative environmental impact than
conventional meat production. Governmental bodies have important roles to play
in promoting insects as food and feed. In particular, the development of this new
sector as a viable (and environmentally friendly) alternative to the conventional
food and feed. Experts from international agencies, scientific institutions and
private-sector stakeholders, together with staff from relevant FAO sectors
created webportal on edible insects since 2010. It provides basic information
on the use and potential of edible insects as well as relevant weblinks, such as
to the proceedings of the conferences, information on the Expert Consultation
Meetings and other relevant technical information, videos and media coverage.
The address of the webportal is www.fao.org/forestry/edibleinsects.
In developed countries, insect rering occurs mainly on family-operated
farms. Presently, there are only a few large-scale industrial plans that rear
insects. The most common insects that were collected or reared within Europe
are: Acheta domesticus, Bombyx mori, Galleria mellonella, Gryllus assimillis,
Hermetia illucens, Locusta migratoria, Musca domestica, Schistocerca gregaria,
T. molitor and Zophobas atratus [225]. The H. illucens reperesent the species of good rearing potential because it
substantially reduce biowaste and house fly breeding and additionally can be used
as animal food [226]. Except this invasive species, few native species as grass
hopers, crickets, and mealworms, are significant source of proteins. A number
of species in Serbia are highly abundant and pose a molesting problem. This is
a case with flood water mosquitoes, insects of Chironomidae family and house
flies. Resarch on their mass production as potential food source for house pets,
animals or as a part of organic fertilazers could support a small scale of organic
farming production in rural regions. Additionally, it should not be forgotten that
some of the species have important impact in waste decomposition, hence create
additional value to the family-operated farms. Insect rearing is easy, does not
require much of technical knowledge nor high investments, therefore accessable
to a majority of rural inhabitants of a law income.
The production and consumption of insects should also be analysed from
the viewpoint of their potential impact on health and biodiversity and the potential
environmental hazards associated with insect production and release, including
the accidental release of insect species not indigenous to the area of production.
People, especially in areas where insects were not consumed for a long
time, prefer incorporating insects into the food in a way they are not visible, so
they accept only the idea that the insects have a nutritional value. This shows
that people especially in North America and Europe can eat insects if they do
not know what they are eating.These factors suggest that insect transformation
will facilitate its consumption in the future. In practice, dried insects may be
crushed or pulverized, and raw or boiled insects ground or mashed, making
their insect form unrecognizable [9].
Much work still needs to be done and many issues taken into account when
elaborating normative frameworks and adjusting for insect-inclusive food laws.
At the Expert FAO Meeting in 2012, therefore, a working group developed the
following proposals for elaborating regulatory frameworks [59].
Private and public standards may establish the basis of harmonized
regulatory practices on the use of insects as food and feed. Legal frameworks
should be developed to consolidate and set binding provisions and to ensure
the implementation and enforcement of such provisions throughout the sector.
It is necessary to promote the establishment of appropriate international and
national standards and legal frameworks to facilitate the use of insects as food
and feed and the development and formalization of the sector. It is also very
important to take into consideration the potential effects of insect production
and rearing on the environment, and the environmental and trade implications
of the international movement of insects. Develop a clear and comprehensive
legal framework at the (inter-) national level that can pave the way for production
and trade in insect products for food and feed internationally.
In the Western world, consumer acceptability will be determined, in
large part, by pricing, perceived environmental benefits, and the development by the catering industry of tasty insect-derived protein products. Preservation
and processing techniques are needed to increase shelf life, conserve quality
and increase the acceptability of insect food products; processing procedures
are also needed to transform insects into protein meal for animal/fish feedstock
and for the extraction of insect proteins to be used as ingredients in the food
industry.
Considering the immense quantities of insect biomass needed to replace
current protein-rich ingradients such as meal and oil from fish and soybeans,
automated massrearing facilities that produce stable, reliable and safe products
need to be developed. The challenge for this new industry will be to ensure the
cost-effective, reliable production of an insect biomass of high and consistent
quality. Regulatory frameworks need to be developed. The close collaboration
of government, industry and academia will be essential for success.",
publisher = "Београд : Српска академија наука и уметности",
journal = "Eколошки и економски значај фауне Србије : зборник радова са научног скупа 17. новембар 2016.",
title = "Јестиви инсекти - безбедна храна за људе и домаће животиње, Edible insects - safe food for humans and livestock",
pages = "251-300",
url = "https://hdl.handle.net/21.15107/rcub_dais_10699"
}

Кавран, М., Игњатовић Ћупина, А., Згомба, М.,& Петрић, Д.. (2018). Јестиви инсекти - безбедна храна за људе и домаће животиње. in Eколошки и економски значај фауне Србије : зборник радова са научног скупа 17. новембар 2016.
Београд : Српска академија наука и уметности., 251-300.
https://hdl.handle.net/21.15107/rcub_dais_10699

Кавран М, Игњатовић Ћупина А, Згомба М, Петрић Д. Јестиви инсекти - безбедна храна за људе и домаће животиње. in Eколошки и економски значај фауне Србије : зборник радова са научног скупа 17. новембар 2016.. 2018;:251-300.
https://hdl.handle.net/21.15107/rcub_dais_10699 .

Кавран, Михаела, Игњатовић Ћупина, Александра, Згомба, Марија, Петрић, Душан, "Јестиви инсекти - безбедна храна за људе и домаће животиње" in Eколошки и економски значај фауне Србије : зборник радова са научног скупа 17. новембар 2016. (2018):251-300,
https://hdl.handle.net/21.15107/rcub_dais_10699 .