Food bio-technology

Food Bio Technology

Biotechnology is defined in accordance with the Convention on Biological Diversity, i.e. “any technological application that uses biological systems, living organisms, or Derivatives thereof, to make or modify products or processes for specific use”
Biotechnology as applied to Food Processing in most developing countries makes use of microbial inoculants to enhance properties such as the taste, aroma, shelf-life, texture and nutritional value of foods.
The process whereby micro-organisms and their ENZYMES bring about these desirable changes in food materials is known as Fermentation-2/”>Fermentation.
Fermentation processing is also widely applied in the production of microbial cultures, enzymes, flavours, fragrances, food additives and a range of other high value-added products.
These high value products are increasingly produced in more technologically advanced developing countries for use in their food and non-food processing applications.
Many of these high value products are also imported by developing countries for use in their food-processing applications.

agriculture & Food Biotechnology

Biotechnology is necessary to maintain our agriculture competitive and remunerative and to achieve Nutrition security in the face of major challenges such as
Declining per capita availability of arable land;
Lower productivity of crops, Livestock and Fisheries-2/”>Fisheries, heavy production losses due to biotic (insects pests, Weeds) and abiotic (salinity, drought, alkalinity) stresses
Heavy postharvest crop damage and declining availability of water as an agricultural input.
Investment in agricultural related biotechnology has resulted in significantly enhanced R&D capability and institutional building over the years.
However, progress has been rather slow in converting the research leads into usable products.
Uncertainties regarding IPR management and regulatory requirements, poor understanding of risk assessment and lack of effective management and commercialization strategies have been significant impediments. India owns very few genes of applied value.
The majority of the genes under use about 40 are currently held by MNCs and have been received under material transfer agreements for R&D purpose without clarity on the potential for commercialization.
The spectrum of biotechnology application in agriculture is very wide and includes
Generation of improved crops, animals, Plants of agro Forestry importance;
Microbes;
Use of molecular markers to tag genes of interest;
Accelerating of breeding through marker assisted selection;
Fingerprinting of cultivars, land raises, germplasm stocks;
DNA based diagnostics for pests / pathogens of crops, farm animals and fish;
Assessment and monitoring of bio diversity;
In vitro mass multiplication of elite planting material;
Embryo transfer technology for animal breeding; food and feed biotechnology.
Plants and animals are being used for the production of therapeutically or industrially useful products, the emphasis being on improving efficiency and lowering the cost of production.
However, emphasis should not be on edible Vaccines for which use in real life condition is difficult.
Nutrition and balanced diet are emerging to be important Health promotional strategies.
Biotechnology has a critical role in developing and processing value added products of enhanced nutritive quality and providing tools for ensuring and monitoring food quality and safety.
It has been estimated that if Biofertilizers were used to substitute only 25% of chemical Fertilizers on just 50% of India’s crops the potential would be 2,35,000 MT.
Today about 13,000 MT of Biofertilizers are used – only 0.36% of the total fertilizer use. The projected production target by 2011 is roughly around 50,000 23 MT.
Biopesticides have fared slightly better with 2.5% share of the total pesticide market of 2700 crores and an annual Growth rate of 10-15 %.
In spite of the obvious advantages, several constraints have limited their wider usage such as products of inconsistent quality, short shelf life, sensitivity to drought, temperature, and agronomic conditions.

CURRENT USE, RESEARCH AND IMPENDING DEVELOPMENT OF FOODS PRODUCED THROUGH MODERN BIOTECHNOLOGY

Foods produced through modern biotechnology can be categorized as follows:

Foods consisting of or containing living/viable organisms, e.g. maize.
Foods derived from or containing ingredients derived from GMOs, e.g. flour, food protein products, or oil from GM soybeans.
Foods containing single ingredients or additives produced by GM Microorganisms (GMMs), e.g. colours, VITAMINS and essential amino acids.
Foods containing ingredients processed by enzymes produced through GMMs, e.g. high-fructose corn syrup produced from starch, using the enzyme glucose isomerase (product of a GMM).

Crops

Crop breeding and the introduction of GM crops for food production

Conventional breeding, especially of crops, livestock and fish, focuses principally on increased productivity, increased resistance to diseases and pests, and enhanced quality with respect to nutrition and food processing.
Advances in cellular genetics and cell biology methods in the 1960s contributed to the so-called ‘Green Revolution’ that significantly increased varieties of staple Food Crops containing traits for higher yield and resistance to diseases and pests in a number of both developed and developing countries.
A key driver of the green revolution was to improve the potential to provide sufficient food for all.
The intensification and expansion of agriculture brought about by these methods and agricultural systems have, however, also resulted in new forms of health and environmental risks through, for example, increased use of agrochemicals and intensified cultivation resulting in Soil erosion.
Various transformation methods are used to transfer recombinant DNA into recipient species to produce a GMO.
For plants, these include transformation mediated by Agrobacterium tumefaciens (a common soil bacterium that contains genetic Elements for infection of plants) and biolistics shooting recombinant DNA placed on microparticles into recipient cells.
The methods used in the transformation of various animal species include microinjection, electroporation and germ-line cells.
The success rate of transformations in animals tends to be lower than in plants, and to vary from species to species, thus requiring the use of many animals.
Genetic modification is often faster than conventional breeding techniques, as stable expression of a trait is achieved using far fewer breeding generations.
It also allows a more precise alteration of an organism than conventional methods of breeding, as it enables the selection and transfer of a specific gene of interest.
However, with the present technology, in many cases it leads to random insertion in the host genome, and consequently may have unintended developmental or physiological effects.
However, such effects can also occur in conventional breeding and the selection process used in modern biotechnology aims to eliminate such unintended effects to establish a stable and beneficial trait.

Livestock and fish

In terms of food production, the application of modern biotechnology to livestock falls into two main areas: animal production and human nutrition.
Many of the applications discussed below are in the early stages of R&D.

Fish

The projected increasing demand for fish suggests that GM fish may become important in both developed and developing countries.
Enhanced-growth Atlantic salmon containing a growth hormone gene from Chinook salmon is likely to be the first GM animal on the food market.
These fish grow 3–5 times faster than their non-transgenic counterparts, to reduce production time and increase food availability.
At least eight other farmed fish species have been genetically modified for growth enhancement. Other fish in which genes for growth HORMONES have been experimentally introduced include grass carp, rainbow trout, tilapia and catfish.
In all cases, the growth-hormone genes are of fish origin.

Livestock and Poultry

Foods derived from GM livestock and poultry are far from commercial use.
Several growth enhancing novel genes have been introduced into pigs that have also affected the quality of the meat, i.e. the meat is more lean and tender.
This research was initiated over a decade ago, but owing to some morphological and physiological effects developed by the pigs, these have not been commercialized. Many modifications to milk have been proposed that either add new proteins to milk or manipulate endogenous proteins.
Recently, researchers from New Zealand developed GM cows that produce milk with increased levels of casein protein. Use of such protein-rich milk would increase the efficiency of cheese production.
Other work aims to reduce the lactose content of milk, with the intent of making milk available to the Population of milk-intolerant individuals.

Microorganisms

Microorganisms as foods

Currently, there are no known commercial products containing live genetically modified microorganisms (GMMs) on the market.
In the United Kingdom, GM yeast for beer production has been approved since 1993, but the product was never intended to be commercialized.
Other microorganisms used in foods (which are in the R&D phase) include starter fermentation cultures for various foods (bakery and brewing), and lactic acid bacteria in cheese.
R&D is also aimed at minimizing infections by pathogenic microorganisms and improving nutritional value and flavour.
Attempts have been made to genetically modify ruminant microorganisms for protecting livestock from poisonous feed components.
Microorganisms improved by modern biotechnology are also under development in the field of probiotics, which are live microorganisms that, when consumed in adequate amounts as part of food, confer a health benefit on the host.

Food and nutrition

R&D would be focused on:
Development of biotechnology tools for evaluating food safety, development of rapid diagnostic kits for detection of various food borne pathogens
Development of analogical methods for detection of genetically modified foods and products derived there from;
Development of nutraceuticals / health food supplements/ functional foods for holistic health;
Development of pre-cooked, ready-to-eat, nutritionally fortified food for school going children;
Development of suitable pro-biotics for therapeutic purposes and development of bio food additives.
It is proposed to set up (under the auspices of Department of Biotechnology) an autonomous institute for nutritional biology and food biotechnology (2006).

Biofertilizers and biopesticides

Priorities would include screening of elite strains of micros-organisms and / or productions of super-strains, better understanding of the dynamics of symbiotic nitrogen fixation, process optimization for fermentor – based technologies, improved shelf life, better quality standards, setting up accredited quality control laboratories and standardization of GMP guidelines.
Integrated nutrient management system would be further strengthened.

Fermentation Bioprocess

The fermentation bioprocess is the major biotechnological application in food processing. It is often one step in a sequence of food-processing operations, which may include cleaning, size reduction, soaking and cooking.
Fermentation bioprocessing makes use of microbial inoculants for enhancing properties such as the taste, aroma, shelf-life, safety, texture and nutritional value of foods.
Microbes associated with the raw food material and the processing Environment serve as inoculants in spontaneous fermentations, while inoculants containing high concentrations of live micro-organisms, referred to as starter cultures, are used to initiate and accelerate the rate of fermentation processes in non-spontaneous or controlled fermentation processes.
Microbial starter cultures vary widely in quality and purity.

Spontaneous inoculation of fermentation processes

In many developing countries, fermented foods are produced primarily at the household and village level, using spontaneous methods of inoculation.
Spontaneous fermentations are largely uncontrolled.
A natural selection process, however, evolves in many of these processes which eventually results in the predominance of a particular type or group of micro-organisms in the fermentation medium

“Appropriate” starter cultures as inoculants of fermentation processes

“Appropriate” starter cultures are widely applied as inoculants across the fermented food sector, from the household to industrial level in low-income and lower-middle-income economies.
These starter cultures are generally produced using a backslopping process which makes use of samples of a previous batch of a fermented product as inoculants

Defined starter cultures as inoculants of fermentation processes

Few defined starter cultures have been developed for use as inoculants in commercial fermentation processes in developing countries.
Nevertheless, the past ten years have witnessed the development and application of laboratory-selected and pre-cultured starter cultures in food fermentations in a few developing countries.
“Defined starter cultures” consist of single or mixed strains of micro-organisms. They may incorporate adjunct culture preparations that serve a food-safety and preservative function.
Adjunct cultures do not necessarily produce fermentation acids or modify texture or flavour, but are included in the defined culture owing to their ability to inhibit pathogenic or spoilage organisms.
Their inhibitory activity is due to the production of one or several substances such as hydrogen peroxide, organic acids, diacetyl and bacteriocins.

Defined starter cultures developed using the diagnostic tools of advanced biotechnologies

The use of DNA-based diagnostic techniques for strain differentiation can allow for the tailoring of starter cultures to yield products with specific flavours and/or textures.
Random amplified polymorphic DNA (RAPD) techniques have been applied in, for example, Thailand, in the molecular typing of bacterial strains and correlating the findings of these studies to flavour development during the production of the fermented pork sausage, nham.
The results of these analyses led to the development of three different defined starter cultures which are currently used for the commercial production of products having different flavour characteristics

GM starter cultures

To date, no commercial GM micro-organisms that would be consumed as living organisms exist.
Products of industrial GM producer organisms are, however, widely used in food processing and no major safety concerns have been raised against them.
Rennet which is widely used as a starter in cheese production across the globe is produced using GM bacteria.

Food additives and processing aids

Enzymes, amino acids, vitamins, organic acids, polyunsaturated fatty acids and certain complex Carbohydrates and flavouring agents used in food formulations are currently produced using GM micro-organisms

National Agri-Food Biotechnology Institute (NABI)

National Agri-Food Biotechnology Institute (NABI) is the first Agri-Food Biotechnology Institute, established in India on 18th February 2010.
The institute aims at catalysing the transformation of Agri – food sector in India.
The institute has the vision to be a nodal organization for knowledge generation and translational science leading to value added products based on Agri-food biotech innovations.
The main research focus of NABI is to harness biotechnological tools in the area of Agriculture Biotechnology, Food and Nutritional Biotechnology so as to provide sustainable and novel solutions towards quality food and nutrition.
Activities undertaken at NABI under different areas includes,

Agricultural Biotechnology
Food and Nutritional Biotechnology
Human resource development
Meeting and Courses
Technology Transfer and Outreach

The institute has developed strong linkages with National and International organizations and industries.
The institute is part of agri-food cluster in the “Knowledge City” of Mohali (Punjab) along with its neighboring institutes.

Food biotechnology is the application of biotechnology to food production and processing. It includes a wide range of techniques, from traditional fermentation to modern Genetic engineering.

Genetic engineering of crops is one of the most well-known applications of food biotechnology. Genetically modified (GM) crops are plants that have been modified using genetic engineering techniques. GM crops are often used to improve crop yields, resistance to pests or diseases, or nutritional value.

Genetic engineering of livestock is another important application of food biotechnology. GM livestock are animals that have been modified using genetic engineering techniques. GM livestock are often used to improve animal health, growth rate, or production of milk or meat.

Fermentation is a traditional food processing technique that has been used for centuries. Fermentation is the process of converting sugars into alcohol or acids using microorganisms. Fermented foods include yogurt, cheese, beer, wine, and sauerkraut.

Food additives are substances that are added to food to improve its taste, texture, appearance, or shelf life. Food additives can be natural or synthetic. Natural food additives include salt, sugar, and spices. Synthetic food additives include preservatives, colorants, and flavor enhancers.

Food processing is the preparation of food for human consumption. Food processing can include a variety of techniques, such as cooking, freezing, canning, and dehydration. Food processing can improve the safety, quality, and convenience of food.

Food safety is the prevention of foodborne illness. Foodborne illness is caused by eating food that is contaminated with bacteria, viruses, or parasites. Food safety can be improved through proper food handling, cooking, and storage.

Nutrition is the study of how food affects the body. Nutrition is important for maintaining health and preventing disease. A healthy diet includes a variety of foods from all food groups.

Sensory evaluation is the scientific study of how people perceive food. Sensory evaluation can be used to test the taste, texture, appearance, and smell of food. Sensory evaluation can help food companies develop new products and improve the quality of existing products.

Sustainable Agriculture is a type of agriculture that meets the needs of the present without compromising the ability of future generations to meet their own needs. Sustainable agriculture practices include using renewable Resources, conserving water, and protecting the environment.

Traceability is the ability to track the movement of food from farm to table. Traceability can help to identify the source of foodborne illness and to recall contaminated food.

Value-added products are foods that have been processed or modified to increase their value. Value-added products can include foods that have been fortified with nutrients, foods that have been packaged in convenient containers, and foods that have been processed to improve their taste or texture.

Waste Management is the process of collecting, treating, and disposing of waste. Waste management is important to protect the environment and to conserve resources.

Water management is the process of managing Water Resources. Water management is important to ensure that there is enough water for human consumption, agriculture, and Industry.

Food biotechnology is a rapidly developing field with the potential to improve food production and processing. However, there are also concerns about the safety and ethical implications of food biotechnology. It is important to weigh the potential benefits and risks of food biotechnology before making decisions about its use.

What is biotechnology?

Biotechnology is the use of living organisms or their components to make or modify products, improve plants or animals, or develop microorganisms for specific uses.

What are the different types of biotechnology?

There are many different types of biotechnology, but some of the most common include:

Agricultural biotechnology: This type of biotechnology is used to improve crops and livestock. For example, agricultural biotechnology can be used to develop crops that are resistant to pests or diseases, or to produce crops that are higher in nutrients.
Medical biotechnology: This type of biotechnology is used to develop new drugs and therapies. For example, medical biotechnology can be used to develop new vaccines, or to create new treatments for cancer.
Environmental biotechnology: This type of biotechnology is used to clean up pollution or to develop new ways to produce energy. For example, environmental biotechnology can be used to develop new methods for treating wastewater, or to create new biofuels.

What are the benefits of biotechnology?

Biotechnology has many potential benefits, including:

Improved food production: Biotechnology can be used to develop crops that are more resistant to pests or diseases, or that produce higher yields. This can help to improve Food Security and reduce hunger.
New drugs and therapies: Biotechnology can be used to develop new drugs and therapies for a variety of diseases. This can help to improve the lives of millions of people around the world.
Clean energy: Biotechnology can be used to develop new ways to produce energy, such as biofuels. This can help to reduce our reliance on fossil fuels and protect the environment.

What are the risks of biotechnology?

Biotechnology also has some potential risks, including:

The creation of new diseases: Biotechnology can be used to create new organisms, some of which may be harmful to humans or the environment.
The misuse of biotechnology: Biotechnology could be misused for harmful purposes, such as developing biological weapons.
The ethical implications of biotechnology: Some people have concerns about the ethical implications of using living organisms for technological purposes.

What is the future of biotechnology?

Biotechnology is a rapidly developing field with the potential to revolutionize many aspects of our lives. In the future, we can expect to see even more applications of biotechnology in areas such as food production, medicine, and energy.

Which of the following is not a type of food biotechnology?
(A) Genetic engineering
(B) Fermentation
(C) Food irradiation
(D) None of the above
Genetic engineering is the process of modifying an organism’s genes. This can be done for a variety of purposes, such as to improve crop yields or to make food more nutritious.
Fermentation is a process that uses microorganisms to convert sugars into alcohol or acids. This process is used to make a variety of foods, such as bread, beer, and wine.
Food irradiation is a process that uses high-energy radiation to kill bacteria and other microorganisms in food. This process is used to extend the shelf life of food and to make it safer to eat.
Which of the following is a benefit of food biotechnology?
(A) Increased crop yields
(B) Improved food nutrition
(C) Safer food
(D) All of the above
Which of the following is a risk of food biotechnology?
(A) The development of new allergens
(B) The transfer of genes from genetically modified organisms to other organisms
(C) The creation of “superweeds” and “superbugs”
(D) All of the above
What is the most common type of food biotechnology?
(A) Genetic engineering
(B) Fermentation
(C) Food irradiation
(D) None of the above
Which of the following is not a genetically modified organism?
(A) Broccoli
(B) Corn
(C) Salmon
(D) Tomato
Which of the following is a genetically modified food?
(A) Roundup Ready soybeans
(B) Arctic apples
(C) Flavr Savr tomatoes
(D) All of the above
What is the future of food biotechnology?
(A) It is difficult to say. There are both potential benefits and risks associated with food biotechnology. It is important to weigh the pros and cons carefully before making any decisions about whether or not to support this technology.)