ARTIFICIAL MEAT OR IN VITRO OR LAB-GROWN MEAT : AN EMERGING INDUSTRY

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ARTIFICIAL MEAT OR IN VITRO OR LAB-GROWN MEAT : AN EMERGING INDUSTRY

To satisfy the increasing demand for food by the growing human population, cultured meat (also called in vitro, artificial or lab-grown meat) is presented by its advocates as a good alternative for consumers who want to be more responsible but do not wish to change their diet. What if all our meat products came from a lab instead of a slaughterhouse? Lab-grown meats have become a reality, and will surely be hitting grocery store shelves in the future.

What is Lab-Grown Meat?

Lab-grown meat, or cultured meat, is produced through the cultivation of animal cells in vitro. Since lab-grown meats are grown from cells, it’s a solution to the ethical issues surrounding livestock agriculture. Cultured meat is produced in a controlled environment, free from bacteria and diseases.

Despite being grown in a lab, lab-grown meat is close to “real” meat, as it is made from animal cells. Although cultured meats are not yet commercially available, research in ongoing on making these marketable in the next few years.

The History of Cultured Meat

Who came up with the idea of cultured meat, and how did it become something that might be hitting grocery store shelves soon? Through years of research and trials, and countless hours of work by numerous scientists, lab-grown meats were created.

Here is a timeline of how and when genetically made meat came about:

Year Event
1998 Jon Vein secures a patent for the production of lab-grown meat tissue for the purpose of human consumption.
2001 NASA begins experiments producing cultured meats with starter cells from turkeys.
2001 Medical doctor Willem van Eelen, businessman Willem van Kooten, and dermatologist Wiete Westerhof, collectively file a patent for their process of producing cultured meat for consumption.
2002 The first edible lab-grown meat sample is produced: a fish fillet made from cultured goldfish cells.
2003 Tissue Culture and Art Project and Harvard Medical School used stem cells from frogs to create tissue that resembled a steak.
2008 PETA offers one million dollars to the first company that can bring lab-grown chicken to the food industry.
2009 Time magazine labels cultured meat one of the breakthrough ideas of the year.
2013 The first lab-grown beef hamburger was consumed at a press event. The burger was created by Dr. Mark Post at Maastricht University in the Netherlands, and the event was hosted in London, England.
2015 Maastricht University held their first International Conference on Cultured Meat.
2016 An engineered meat startup company, Memphis Meats, posts a promo video showcasing their lab-grown meatballs.
2016 An Isreali company, SuperMeat, runs a crowdfunding campaign to raise money for their efforts to bring lab-grown poultry products to market.
2017 Finless Foods announces that they expect to bring sustainable, lab-grown seafood to consumer markets within 2 years.
2018 Dutch startup company Meatable claims they will be able to produce cultured meat from stem cells sourced from animal umbilical cords, solving the problem of needing to kill an animal initially to get starter cells for production.

How is Lab Meat Made?

Lab grown meat is made by the controlled culture of animal cells. Scientists commonly grow cells in the lab, and this process is not too different. While the specifics behind how lab meat is grown in companies is proprietary, the basics behind it consists of keeping cells happy in a culture environment to promote their survival and continued growth.

Lab grown meat starts with animal cells, typically muscle or fat cells, or stem cells that are forced to differentiate into muscle cells. These cells are cultured using the appropriate growth medium that contains nutrients that promote its growth and survival. To aid in the growth of culture as it begins to expand, edible scaffolding is sometimes used. Finally, cells are allowed to divide and expand until ready to use, all the while being monitored consistently for harmful bacterial contamination.

Challenges of Working with Lab Cultured Meat

In addition to the societal stigma that lab made meat faces, there are other challenges that come along with creating meat products that resemble traditionally-sourced meats, including replicating texture, appearance, and taste. Here are some of the main difficulties:

  • Speed and density of cell growth

This is a challenge because while individual cells can grow quickly, it can take some time for a larger tissue segment to form. In addition, if the cells aren’t forming together at the same density as traditionally sourced meat, the texture of the product won’t come out the same way.

  • Growth medium requirements

Cells require proper growth medium rich in nutrients in order to survive and grow. Since lab grown meat is ultimately meant for human consumption, the high quality growth medium free of common allergens are necessary.

  • Lack of blood vessels

Blood vessels normally deliver blood to tissue to survive. In lab-grown tissues, blood vessels are not present, so scientists must think of new ways to deliver nutrients, taking the place of naturally occurring blood vessels.

  • Cost to produce

Lab-grown meats are still only being produced on a fairly small scale, and though the cost to make them has drastically decreased from the $330,000+ it used to cost, lab meat is very expensive to produce at around $2400/pound of lab beef, according to Memphis Meats. If adopted by larger companies and produced on a large scale, the cost will be reduced significantly.

  • Replicating the taste of traditional meat

To motivate meat lovers to switch to lab-grown meat, the taste needs to be the same or very close to that of traditional meat. Many people would be quite put off if the taste leaves too much to be desired. More work is needed to ensure that the taste of cultured meat will please the foodies of the world.

 Companies Producing Lab Cultured Meats

There are now several companies working on bringing lab-grown meat and seafood products to consumer markets worldwide. Here’s a rundown of five awesome companies creating these products:

  • Memphis Meats

 

Memphis Meats had the idea for cell-based meats and poultry products in 2005, and in 2015, they finally launched and began producing the meats. They created the world’s first cell-based meatball in 2016, with poultry following shortly after in 2017.

Under the vision and execution of CEO & founder Dr. Uma Valeti, Memphis Meats hopes to scale in such a way that less land, water, energy, and food inputs are consumed by the meat industry, and quality, healthy, and safe cell-based meats can reach grocery stores in coming years.

  • Finless Foods

 

As their slogan states, Finless Foods offers you “sustainable seafood, without the catch.” They are bringing sustainable, cell-based seafood products to your table, starting with bluefin tuna. This achievement would help solve the environmental problem that commercial fishing is causing, and would improve the nutritional quality of the fish being consumed.

  • Meatable

 

Meatable is creating hamburgers from single animal cells, in a much faster, cleaner, and more sustainable way than traditional livestock-sourced burgers. Their process claims to produce a hamburger in 3 weeks or less, which, when compared to the minimum 3 years traditional meat takes, is a significant improvement. You can check out their product creation cycle to learn more about the timeline of this process.

  • SuperMeat

 

SuperMeat got started through a crowdfunding campaign on Indiegogo. They’re working to create animal-friendly meat products in partnership with PHW-Gruppe, one of Europe’s largest poultry producers.

READ MORE :  Application of Essential Oils as Natural Preservatives in Meat Products

Like all the other companies here, their product will help solve the environmental impact issues of the meat industry, but SuperMeat’s marketing and branding also focuses on the humanity of how this type of meat production will prevent the slaughter of animals.

  • Mosa Meat

 

Mosa Meat was the groundbreaking company responsible for the first lab-grown hamburger showcased in 2013. Since then, they’ve been hard at work to get their products ready for commercial production, and are aiming to make them available to consumers within the next few years.

Their main goal is to bring cultured meat (or “clean meat” as they call it) to the mass market to help satisfy the growing demand for meat, which they believe will hit a critical stage by 2050. They also claim that while the process is very expensive now, over time, they will be able to reduce the price to about the same as a typical beef hamburger in the supermarket.

How is Lab Meat Different from Plant-Based Meats?

A new wave of meatless meats are becoming more popular since coming to the market in the last few years, however it is important to distinguish that those are not the same as cultured meat. The meatless meats you might be familiar with are plant-based ‘meats’ and contain no animal tissue whatsoever, though can sometimes contain animal byproducts like eggs.

The ingredients listed in a lab meat hamburger would be “ground beef” while common ingredients in a plant-based burger made famous by companies like Impossible Foods or Beyond Meat include soy, beans, tofu, vegetables, grains, mushrooms, and other non-meat products.

Cultured meat is not synonymous with vegetarian or vegan-safe foods, as it contains animal cells. While lab cultured meats are not vegetarian, they provide a more friendly alternative for those who choose to refrain from eating meat because of animal cruelty or environmental reasons.

How is Lab Grown Meat Different from Conventional Meat?

If lab produced meats are similar in appearance, texture, and taste to conventional meat, how are they different? Are the products the same? Is there a reason to choose one over the other?

Here are the ways cultured meat differs from traditionally-sourced meat:

Lab Meat Conventional Meat
Artificiality Grown from animal cells in vitro i.e. in controlled lab conditions Comes directly from animals that have been sacrificed for consumption
Impact on environment More environmentally friendly due to lack of greenhouse gas production High environmental impact with land occupancy and greenhouse gas emissions
Ethics A more ethical alternative as animal cells are used Killing animals for consumption raises ethical issues
Health Harmful additives are minimized in lab grown meats May contain additives like growth hormones, antibiotics, and other chemicals
Cost to produce Due to its process, lab grown meat is currently very expensive to produce Traditional meat is fairly affordable for an average person to buy

 

Meat consumption is an essential part of the human diet. Meat for consumption is traditionally obtained from animals that are reared and slaughtered on farms. With the increase in human population and urbanization across the world, it is predicted that consumption of meat would be doubled by 2050 and the conventional meat alone would be inadequate to meet the demand. Moreover, limited land resources and the negative perception to animal slaughter are encouraging scientists to develop innovative techniques to produce meat without rearing animals.

Artificial meat

In 1932, Winston Churchill, Former British Prime Minister predicted that “Fifty years hence we shall escape the absurdity of growing a whole chicken, in order to eat the breast or wing by growing these parts separately under a suitable medium”

Almost after eighty years, science may finally be getting close to producing In-vitro meat muscle tissue grown in the laboratory without using any animal (Bhat et al. 2015).

Artificial meat is the idea of manufacturing meat and meat products through tissue engineering technology without using an actual animal. Artificial meat can also be termed as In vitro meat/ Cultured meat/Synthetic meat/Laboratory grown meat/Factory grown meat/Shmeat/Hydroponic meat/Test tube meat/Vat grown meat/Cell based meat /Victimless meat/Clean meat (Bonny et al. 2015;Verbeke et al. 2015).

Drawbacks of Convectional Meat Production

Meat is an important nutritional and social factor for the human race and meat consumption is expected to increase in coming years. Convectional meat production may not be capable of feeding the increasing population. In 2019, the World population estimated to be 7.7 billion (US census) also 1.05% increase rate per year i.e. 81 million people per year has been showed. Global hunger continues to rise as new UN Report says 821 million people are now hungry and over 150 million children stunted, putting hunger eradication goal at risk (WHO, 2017) which is one of the Goals of the Sustainable Development Goals to be achieved by 2030.

FAO baseline projected (Bruinsma, 2009) 70% increase in global food demand by 2050 due to population growth and change of dietary pattern. FAO projected that by 2050, average per capita meat consumption to be increase by more than 70% higher than that in 2010 which would cause change of 553  million tons increase in the demand for feed, which represents half of the total demand increase for coarse grain between 2000- 2050. There has been noticeable change i.e. increase in crop production to meet the increase feed demand. This has resulted in widespread deforestation and displacement of farmers and a major contributor to climate change and environmental destructions. One-third of global arable land is used to grow feed, while 30% of the Earth’s ice-free terrestrial surface is used for grazing. (Food and Drink Report, 2018-19). Calories that are lost by feeding cereals to animals and poultry could theoretically feed an extra 3.5 billion people (United Nations Environment Programme). It takes more than 3 Kg feed to produce 1 Kg chicken, 4kg for 1 Kg pork, 7 Kg for 1 Kg beef (United Nations Environment Programme).

Large amount of fossil fuels are burned throughout the process of meat production including housing, transportation, slaughter of livestock etc. Fossil energy is used for the production of feeds (land preparation, fertilizers, pesticides, harvesting, drying, etc.), their bulk transport (rail and/or sea flight), storage, and processing (milling, mixing, extrusion, pelleting, etc.) and their distribution to individual farms. Transport of products (meat animals to abattoirs; meat to processing plants; eggs to storage), processing (slaughtering, processing, and manufacture of meat products), storage and refrigerated transport also require fossil fuels. Finally, the distribution to the consumer and the final cooking process may also require expenditures of fossil fuels.

Table 01: Consumption of fossil fuel for conventional meat production

PRODUCT FOSSIL

ENERGY

COST

UNITS SOURCE
Poultry meat 2.59 MJ×kg-1 live wt Whitehead & Shupe, 1979
Pork – fresh 3.76 MJ×kg-1 carcass Singh, 1986
Processed meats 6.30 MJ×kg-1 meat Singh, 1986
Sheep meat 10.4 MJ·kg-1 carcass McChesney et al., 1982
Frozen 0.432 MJ·kg-1 meat Unklesbay & Unklesbay, 1982
Beef 4.37 MJ·kg-1 carcass Poulsen, 1986
Frozen 0.432 MJ·kg-1 meat Unklesbay & Unklesbay, 1982

Another natural resource which remains extensively in use in production of farm animals is water. Consumption of Water (litre/Kg) for conventional meat production ( Mekonnen and Hoekstra ,2010)

Meat type Water consumption, litres
Beef 15,415
Mutton 10,412
Pork 5988
Chicken 4325

Raising livestock produces 20% of greenhouse gas emissions (United Nations Food and Agriculture Organization). Global emissions from livestock supply chains by category of emissions (Gerber et al.2013; GLEAM).

Contamination with bacteria like Salmonella, E.coli and other organisms could be possible which would come due to contact with animal contaminants like faeces, urine, offals etc. This might increase the chance of food borne diseases through contaminated meat and meat products and these are of public health concern.

Moreover “cruelty is never justified” i.e. 72 billion animals are killed every day for human consumption, i.e. 50 billion of these animals are chickens, 1.5 billion pigs, 546 million sheep, 444.2 goats, 300 million cattle. Many argue that there is no “humane” way to kill an animal. Many livestock and poultry are raised in pens and cages without room (UN Food and Agriculture Organization, 2017).

The idea of In-vitro meat production was introduced in 1932. Later on many scientists tried to work and produced this type of cultured meat under laboratory conditions. In 1995 in-vitro meat production idea got boosted up as NASA wanted improvements in food for Astronauts in space, technique and it also got FDA approval. In 1943, a French science fiction author Rene Barjavel described in-vitro production of meat in restaurants in his novel ‘Ravage’ in 1943 later translated as ‘Ashes, Ashes’ in 1967. In 1999 Van Eelens theoretical idea was patented. Benjaminson et al. (2002) cultured muscle tissue from the common goldfish (Carassius auratus) in Petri dishes. John F Vein possessed a patent on tissue engineered meat for humans.

In India, Kartik Dixit, an entrepreneur from Nagpur, while researching meat consumption felt it was necessary to tie up with food scientists and researchers to come up with an alternative meat product. He along with Dr. Pavan Dhar and Dr. Siddarth Manvati, two scientists at Jawaharlal Nehru University (JNU), in 2018 tried to grow cells in a lab and clump them into protein. And thus, ClearMeat was born in 2018 in Delhi, India’s first clean chicken meat startup. It uses chicken cells to artificially produce meat in an attempt to help end animal slaughter in India. In February 2019, the Good Food Institute and Institute of Chemical Technology, Mumbai signed an agreement to set up a cell-based meat research facility in Maharashtra and within a year of the MoU, the Centre for Cellular and Molecular Biology was awarded a substantial grant of ₹4.5 crore from the DBT towards the development of cell-based meat “Ahimsa Meat” in March 2019, with National Research Centre on Meat, Hyderabad playing a supporting role.

Another milestone was achieved by researchers Dr. Biman B Mandal and Dr. Suvro Kanti Choudhury from IIT-Guwahati who introduced nutritious tissue engineered edible meat (Patent Application 201831047999, August 2019).

Requirements for producing artificial meat

Cell source: Most practical cell source are embryonic Myoblasts called as Satellite cells or Myosatellite cells. Myosatellites are precursor to skeletal muscle cells, able to give rise to differentiated skeletal muscle cells (Benjaminson et al. 2002; Mouly et al. 2005;Le Grand and Rudnicki, 2007). These cells have high proliferative potential can be isolated and collected by Biopsy Procedure( Danoviz and Yablonka-Reuveni, 2012). Myosatellites are located between the basal lamina and sarcolemma of muscle fibre (Kuang and Rudnicki 2008; Roobrouck et al. 2008). To improve the quality of cultured meat, it may be desirable to co-culture adipocytes (fat cells) with myofibrils in order to enhance the texture, flavor and tenderness of cultured meat by effectively increasing the intramuscular fat (Hocquette et al. 2010). Tissue engineering of adipose cultured cells has been described by Frerich et al. (2011), Dodson et al. (2012) and Verseijden et al. (2012).

Scaffold

Myosatellite cells are attachment dependent so requires a Substratum or a Scaffold. Scaffolds are edible and derived from non animal sources. Mechanically Scaffold should stretchable, flexible, biocompatible and biodegradable. Scaffolds should provide large surface area and be flexible to allow for contraction, maximize medium diffusion and be easily dissociated from the meat culture. Cytodex-3, micro carrier beads have been used as scaffolds in rotary bioreactors. E.g Collagen, Chitosan, Alginate (Van Eelen et al. 1999; Edelman et al. 2005, Gaydhane et al. 2018).

Culture Medium and Growth Factors

One of the challenging task in in vitro meat production is the right formulation of culture medium. The medium should support and promote growth while being made of afordable, edible components available in large quantities. Fetal bovine serum- in vivo source is variable in composition and is a potential carrier for pathogenic agents. Another standardized media and serum-free media is Ultroser G. The composition of Ultrosr G mainly consists of growth factor, adhesion factor, binding protein, vitamins, minerals and hormones which are necessary for the growth of cells but the cost is on little higher side (Coecke et al. 2003; Houdebine LM (2009); Gaydhane et al. 2018). Purifed growth factors or hormones may be added to the culture media from plants, animals or transgenic bacterial species which generates recombinant proteins. Co-cultured hepatocytes can produce insulin-like growth factors which promote myoblast proliferation and differentiation and also myosatellite cell proliferation in some animals.

Bioreactors

Large bioreactors are required as stem cells and skeletal muscle cells need a solid surface for culturing where controlled environment is maintained such as pH 7.2–7.4, temperature 37°C (Carrier et al., 2002; Allan et al.2019). NASA has developed rotating bioreactors for the production of skeletal muscle tissue (Van der Weele and Tramper, 2014).

Rotating wall vessel bioreactor rotates in such a way that its speed balances the centrifugal force, drag force and gravitational force and allows the three-dimensional culture to submerge in the medium which helps in developing the structure of tissue similar to that of in vivo.

The fields:  The fields used are: Mechanical, Electromagnetic, Gravitational and Fluid flow. The fields affect differentiation and proliferation of myoblasts. Repetitive stretch and relaxation equal to 10%, 6 times per hour increased differentiation of myoblasts (Powell et al. 2002).

Techniques used:

Cell culture or Scafolding technique : A scaffold based in vitro meat production system would involve isolation of embryonic myoblasts or adult skeletal muscle satellite cells from the farm animals like cattle, sheep, pig, etc., which would be allowed to grow inside a stationary or rotating bioreactor using a plant origin growth medium. These cells would divide and re-divide for weeks and months together and would be finally differentiated into the muscle fibers onto a scaffold inside the bioreactor. Attached to a scaffold or carrier such as a collagen meshwork or microcarrier beads, stem cells fuse into myotubes, which can then differentiate into myofibers by introducing a variety of environmental cues (Kosnik et al. 2003). The resulting myofibers may then be harvested, processed, cooked, and consumed as emulsion or ground meat products. This technique produces soft consistency meat or boneless meat which can be used to prepare hamburger and sausages etc.The main drawback associated with this technique is it cannot produce highly structured or 3D structured meat for e.g. Steaks.

Self‑organizing or tissue culture technique : Potential method of creating In-Vitro meat where tissue sample or explants are collected. This method was 1st described by Benjaminson et al. 2002 where he collected muscle tissue from the common goldfish. The self-organizing technique creates highly realistic 3-D structured meat like natural conformation meat. Only drawback associated with self-organizing technique is if cells are separated from nutrient media, it makes them necrotic due to insufficient blood supply.(Bhat et.al 2015).

Organ Printing : This technique involves the spraying of live cells or balls of cells in layers over the gel that acts as a printing paper and the cells get fuse to create 3D structure of any shape even has the capability of producing entire organ.0.8-1% Aqueous Alginate solution with 2% CaCl2 Solution forms the Hydrogel. An advanced technique which can take care of meat consistency, vascularization, fat marbling and other elements of conventional meat like taste and appearance.  The only drawback with this technique is it is expensive and is still under development. (Boland et al. 2003; Hopkins, 2015)

Biophotonics: This is the probable technique which uses laser light to hold the cells and allow them to coax and grow in an organized structure. It eliminates the use of scaffold for production of tissues by holding the cells together using laser light (Hopkins et al.2008, Noor et.al.2016).

Nanotechnology : Nanotechnologists are working on to create Nanorobots or Assembler which can selectively group the similar atoms or molecules forming the entire structure. It can virtually create any substance of any desired shape in a primitive state (Mullins, 2006; Bhat et.al.2015; Noor et al. 2016; Gaydhane et al. 2018).

Merits of Artificial meat over the conventional meat

  • Artificial meat can be influenced by changing the composition of culture medium, Fatty acid and nutrients to make it healthy. For example, replacing harmful fats with healthy fats like omega-3 can prevent cardiovascular disease
  • Artificial meat takes only several weeks to culture and harvest
  • Artificial meat does not involve killing of animals as it takes only a small sample of muscle cells from the donor animal
  • Reduction in resource use, environment friendly Artificial meat production will reduce the emission of GHG and also reduce the use of energy, land and water recourses
  • It has a strong support from scientific community, animal rights (PETA), and environmental communities when animal killing and welfare is concern.
  • Reduction in land use opens the prospect for land reforestation and restoration of wildlife and endangered species
  • As production of artificial meat requires only stem cells of the desired animal, cells from endangered animals or even sample of extinct animal cell could be used to produce exotic meat
  • People who are vegetarian due to moral and health issues can eat artificial meat as it not associated with killing of animals and are healthy foods
  • Controlled ecological life support system would provide fresh food to the astronauts and use in Space missions and settlements

Nutrient content of different meat and cultured meat (World economic forum, 2019)

Nutrient  (g) Beef Pork Chicken Cultured meat
Calories (kcal) 200 200 200 200
Grams 83 67 140 83
Protein 20.89 17.30 24.39 20.89
Carbohydrates 0.52 0.06 0.52
Fat 12.11 13.99 11.33 12.11
Sat. fatty acid 4.67 5.20 3.22 2.33
Mon. fatty acid 5.33 6.23 5.05 5.33
Poly. fatty acid 0.41 1.26 2.11 2.74
Cholesterol mg 70.00 63.30 70.00
Calcium mg 20.83 14.81 8.39 20.83
Iron mg 2.23 0.87 1.15 2.23
Heme mg 0.78 0.44 0.52 0.78
Magnesium mg 18.33 16.16 29.37 18.33
Phosphorus mg 177.50 152.19 248.95 177.50
Potassium mg 294.17 243.77 730.07 294.17
Sodium mg 70.83 49.16 83.92 70.83
Zinc mg 5.16 2.16 2.06 5.16
Copper mg 0.07 0.03 0.09 0.07
Thiamin mg 0.04 0.48 0.15 0.04
Riboflavin  mg 0.15 0.15 0.34 0.15
Niacin mg 4.74 2.83 7.80 4.74
Pantothen. mg 0.57 0.35 1.53 0.57
Vitamin B6 μg 0.32 0.26 0.72 0.32
Folate μg 7.50 4.04 1.40 7.50
Vitamin B12 μg 2.28 0.36 0.78 2.28
Vitamin A μg 5.83 1.35 5.83

Constraints in artificial meat production

  • Sensorial characteristics: Its sensorial characteristics (taste, color, appearance, and texture), which were different from conventional meat.
  • Cost:Optimization of cell culture for large-scale production can ultimately lower the cost.
  • Public Psychological unacceptance: considered as unnatural and rejected by few people, there is also the group of people who appreciated it as it is animal- friendly, healthy and safe.
  • Policy:In order to improve acceptability of cultured meat and channelize research and development efforts for quick commercialization, food regulatory bodies need to focus on formulating guidelines.
  • Hazards : Laboratory contamination of substrates and culture medium
  • Expensive:Large expensive bioreactors are needed. Also need a cheaper substitute for animal sera

Cultured meat towards commercialization

In 2015, the makers of lab-grown burger announced that the price of burger had dropped down from $325,000 to $11.36 or $80 per kilogram of in vitro meat (Crew B, 2015). The current prices of natural protein sources per kilogram are ground beef $5.6, boneless beef $9, pork on the bone $7.4, and whole chicken $2.6 (Anonymous, 2017). Small start-ups like Impossible Foods (US), Memphis Meat (San Francisco, California) –Meat balls , Super Meat (Israel) and Mosa Meat (The Netherlands) – Beef patty have come forward to serve the clean Artificial meat to the society (Devitt, 2016; Shoemaker, 2016 ;Stone, 2016).

Future perspectives of cultured meat

Meat substitutes like Quorn and Tofu got accepted and the people have shift to semi-vegetarian, it may also not be difficult to accept the cultured meat in future. It can also be use as a ‘medicinal’ meat for its more nutrient content. Increasing awareness and consciousness towards environment amongst masses can urge people to shift to consumption of cultured meat. Technological development to scale-up production and processing in terms of storage, packaging, stability, and quality also needs attention. Governments also need to work on regulatory guidelines for aiding acceptance of cultured meat and keeping a check on quality and purpose before the commercial success of these products.

Conclusion

Conventional meat production systems are associated with several problems. Whereas artificial meat holds great potential to replace slaughtered animal meat and meat-based products. With increase demand for meat, Cultured meat production should be promoted to provide eco-friendly and disease-free meat to consumers. However, it is also important to conduct in-depth research and develop strong technical knowledge to further refine the technology and make it economically feasible and commercially viable to develop healthy and safe meat for consumers.

References

Anonymous(2017) Food Prices in USA grocery stores. In: GlobalPrice.Info. http://www.globalprice.info/en/?p=usa/food- prices-in-usa.

Benjaminson MA, Gilchriest JA, Lorenz M (2002) In vitro edible muscle protein production system (MPPS). Acta Astronaut 51:879–889

Bhat ZF, Kumar S, Bhat HF (2015) In vitro meat : a future animal-free harvest. Crit Rev Food Sci Nutr. https://doi. org/10.1080/10408398.2014.924899

Boland T, Mironov V, Gutowska A et al (2003) Cell and organ printing 2: fusion   of cell aggregates in three-dimensional gels. Anat Rec 502:497–502. https://doi.org/10.1002/ar.a.10059

Coecke S, Balls M, Bowe G et al (2005) Guidance on good cell culture practice. a report of

 

COMPILED BY- DR GAUTAM TIWARY,ALANA

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