Foreword
Page: i-i (1)
Author: K.R.S SAMBASIVA RAO
DOI: 10.2174/9789815196115124010001
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Preface
Page: ii-ii (1)
Author: Sagarika Devi, Gokul Shankar Sabesan and Sultan Ahmed Ismail
DOI: 10.2174/9789815196115124010002
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Food Biotechnology – Future Prospective in Food Biotechnology
Page: 1-16 (16)
Author: Antony V. Samrot*, D. Rajalakshmi and M. Bavanilatha
DOI: 10.2174/9789815196115124010004
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Abstract
The development of biotechnology has led to improvements in the
nutritional value and quality of foods consumed by humans, thereby benefiting their
health. Globally, foods developed through biotechnology are heavily studied and
judged by governments, health authorities, and scientists. By applying food
biotechnology, we can reduce the number of naturally occurring poisons and allergies
in food. Food biotechnology can be used by farmers and food producers to provide a
safe, convenient, and affordable food supply posing new challenges and opportunities
for the prevention of disease. It mainly involves the use of genes from plants, microbes,
and animals with a view to enhance productivity and nutritional benefits. The
interdisciplinary field of food biotechnology employs modern biotechnology principles
to produce, process and manufacture foodstuffs. A variety of tools are used in food
biotechnology, including traditional breeding methods such as cross-breeding. There
are also various modern techniques including genetic engineering which increase the
yield. The aim of food biotechnology is to increase the crop yield for the welfare of
farmers and to provide nutritional foods for people around the world. There are various
concerns associated with the development of food biotechnology. In this paper, the
future prospects of food biotechnology are discussed.
Developing Functional Properties of Food Through Biotechnology
Page: 17-36 (20)
Author: Chaleeda Borompichaichartkul* and Putthapong Phumsombat
DOI: 10.2174/9789815196115124010005
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Abstract
Functional foods and ingredients offer health benefits that extend beyond
their nutritional value. To develop functional foods, often functional ingredients or
supplements are added to create desired properties, especially in the area of health
improvement. Many well-known functional ingredients can be obtained from
biological processes including probiotics, prebiotics, beta-glucan, enzymes, peptides,
antioxidants, medium or short-chain fatty acids, vitamins, etc. Therefore, it is necessary
to understand the biotechnological process that is used to create high-quality functional
ingredients. This chapter gives an overview of functional foods and ingredients in
terms of definition, category, biological production, safety, and future functional foods.
Functional food can not only prevent nutrient deficiencies but also protect against
diseases and promote proper growth and development, as well as enhance health by
boosting the intake of important nutrients. Innovations in functional foods and
ingredient development would result from understanding more about their
biotechnological manufacturing.
The Role of Food Biotechnology Industry in Food Security upon Climate Change, and Future Perspective - A Case Study in Vietnam
Page: 37-67 (31)
Author: Sao-Mai Dam* and Hoang-Duy Truong
DOI: 10.2174/9789815196115124010006
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Abstract
The world’s population is expected to reach 9.8 billion in 2050. In order to
feed the number of people sustainably by 2050, we need to increase 56 percent of crop
production. However, the impact of climate change, including temperature increase,
changes in rainfall patterns, and outbreaks of pests and diseases, will affect agricultural
productivity and the agricultural industry to adapt to changes in technology and
demand for food. Biotechnology has been applied in crop production for many years.
However, industrial food biotechnology is still neglected. Advances in the food
biotechnology industry can lead to cutting-edge technologies in agriculture adapting to
climate change while reducing the impact on the climate. This review brings out the
role of industrial food biotechnology in improving food quality upon climate change,
especially in Vietnam. This also demonstrates industrial food biotechnology as part of
the solution to climate change to reduce greenhouse gas emissions; then, we
recommended technological progress in industrial food biotechnology with the future
vision: Vietnam’s green economy.
Potential and Challenges of Applied Biotechnology in Mushroom Bio-based Products in the Food Industry
Page: 68-88 (21)
Author: Trung-Au Vo, Thien-Hoang Ho and Sao-Mai Dam*
DOI: 10.2174/9789815196115124010007
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Abstract
Mushrooms are popular because of their high nutritional value.
Biotechnology provides powerful tools for the sustainable development of mushrooms.
Many advances in the non-meat-based food industry represent the significant role of
mushroom biotechnology. Mushrooms are a rich source of proteins and have low or
zero fat and cholesterol. In addition, some mushrooms are a source of bioactive
compounds. Therefore, mushroom-based products have become widely accepted foods
worldwide. The new techniques used to meet the consumer requirements of the
mushroom increase the quality and convenience to use new product development.
Technological developments have generally witnessed increasing crop production
capacities in cultivation technologies. Besides that, new mushroom-based food
products are developing; and the production techniques are innovated to improve the
quality of final mushroom-based goods. The mushroom-based products are mainly
produced as a result of contributions from mushroom cultivation in developing
countries such as China, Europe, India, USA, and Vietnam. The challenge is finding
opportunities to increase mushroom and mushroom-based product consumption
capabilities with increasing world population and non-meat-based food consumption.
This chapter reviews the recent advances and challenges for sustainable production of
mushroom-based products as a non-meat food source in the food industry.
Potential and Challenges of Applied Biotechnology in Aquatic Products Production - A Case Study in Vietnam
Page: 89-115 (27)
Author: Sao-Mai Dam*, Duc-Vuong Nguyen and Hoang-Duy Truong
DOI: 10.2174/9789815196115124010008
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Abstract
Biotechnology is making essential contributions and poses significant
challenges to aquaculture and fisheries' new product development via enhancing taste,
shell life, nutrition, and quality and reducing waste. Aquatic products biotechnology
might be regarded as reliable for enhancing and expanding the production and
processing of sustainable food products created for the future of the expanding global
population. Aquatic product biotechnology consists of (1) new technological
applications in aquatic farming to improve productivity and feed utilization, (2)
commercial packaging technology for preservation, and (3) effective use of byproducts or wastes and the process of product innovation. Some insights into the
biotechnological development of aquatics production in Vietnam are reviewed in this
chapter.
Potential and Challenges of Applied Biotechnology in the Plant-Based Food Industry
Page: 116-157 (42)
Author: Duc-Vuong Nguyen and Sao-Mai Dam*
DOI: 10.2174/9789815196115124010009
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Abstract
Recently, many advances in plant-based food biotechnology are a wideranging science that uses modern technologies to produce food products.
Biotechnologists and food scientists' new instruments, methods, industry, and products
enhance taste, shell life, nutrition, and food quality. Food biotechnology is as ancient as
civilization, via fermentation, to produce food products such as beer, wine, vinegar,
sauce, fermented vegetables, etc. Besides that, genetically modified (GM) yeasts and
bacteria are used to enhance the products' quality and produce enzymes for improving
the quality of plant-based food products. This chapter summarizes the roles and some
of the applications of biotechnology in plant-based food processing and food
preservation.
Potential and Challenges of Microalgae Peptides-An Overview
Page: 158-182 (25)
Author: Thien-Hoang Ho and Sao-Mai Dam*
DOI: 10.2174/9789815196115124010010
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Abstract
Microalgae technology has made significant advances in recent decades.
Initially, Microalgae attracted the interest and attention of the scientific community as a
renewable resource for biofuels. Besides, it also has the potential to accumulate lipids
and biomass significantly in a short period. Recent studies have shown that
microalgae's bioactive peptide could be well-suited with great potential in human
nutritional support. Therefore, a bioactive peptide derived from various strains of
microalgae could be a potentially significant source for developing novel nutraceuticals
and functional foods that can reduce the risk of cardiovascular disease, cancer, and
arteriosclerosis. The bioactive peptide has also been used in anti-wrinkle and anti-aging
skincare products, where it serves to stimulate the creation of proteins in the skin.
Although some microalgae have reported antimicrobial and antivirus peptides, the
understanding of peptides with these properties is still unclear and not described.
Interest in microalgae-derived peptides is overgrowing. This review highlights and
discusses the cutting-edge features of their research and applications to develop new
therapeutic drugs, cosmetics, and other valuable products. It is also exploring the
technology for microalgae peptide extraction and purification.
Bioremedial Approach to the Mitigation of Environmental Pollution
Page: 183-206 (24)
Author: S. K. Jasmine Shahina* and Summera Rafiq
DOI: 10.2174/9789815196115124010011
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Abstract
Anthropogenic events have caused environment all around the world to
deteriorate, rendering them unsuited for the existence of indigenous biological species.
Over the last few decades, environmental contamination seems to have been a
prominent subject of concern, affecting the wellbeing of people. The environments
have been gravely damaged by excessive industrialization, inappropriate farming
techniques, and unregulated release of contaminants into soil and aquatic bodies. As a
result, there has been poor utilization of natural resources, increase in deforestation, a
decline of flora and fauna, drinking water scarcity, and significant economic losses
which are challenging. The need to develop innovative, eco-friendly, low-cost, and
much more effective environmental remediation technologies emerged as a result of
environmental pollution. Microbes are well recognised for their propensity to degrade
and absorb a broad range of organic chemicals and are now utilized to clean up
environmental pollution through the process of 'bioremediation'. The bioremediation
process involves a variety of microorganisms that help in degradation, eradication,
immobilization, or detoxification of different chemical pollutants from the
environment. Bioremediation methods are widely used and are still increasing at an
enormous speed nowadays. Entrepreneurship can be developed by commercializing
bioremediation in saving the environment.
Industrial Biotechnology - Scope and Risks in Establishing an Enterprise
Page: 207-223 (17)
Author: Antony V. Samrot*, M. Sathiyasree and P. Prakash
DOI: 10.2174/9789815196115124010012
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Abstract
The use of enzymes, microorganisms, and plants to create energy, and
industrial chemicals for consumers is industrial biotechnology. This sector utilizes
natural processes to maximise and improve biochemical pathways that can be used in
the manufacturing process. The integration of biotechnology into industrial processes is
changing not only how we produce goods but also bringing us new goods that were
unthinkable just a few years ago and has created a lot of room for innovation and
entrepreneurship. The commercial aspects of industrial biotechnology as well as the
possible fundamental strategies associated with working biotech entrepreneurs and
professionals in addition to its scope and risk involved in it are discussed here.
Generating Successful Start-up & Research Opportunities in Industrial Biotechnology
Page: 224-236 (13)
Author: Chidhambara Priya Dharshini K. and S. Umamaheswari*
DOI: 10.2174/9789815196115124010013
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Abstract
Industrial Biotechnology is concerned with the sustainable production of
materials from renewable sources. It is one of the widely recognized fields of
biotechnology as it is associated with a decreased utilization of energy sources and
reduced emission of greenhouse gases and its popularity in terms of economic value in
recent years. With such concerns, the current chapter provides an insight into the
opportunities for building start-ups and research scope in the field of Industrial
Biotechnology and focuses on the various opportunities for initiating a start-up related
to the field of Industrial Biotechnology. Moreover, it highlights the attractive
approaches for setting up and developing the start-ups and government schemes
associated with them. The scope of research and various research opportunities for
students and scholars are highlighted in the field of Industrial Biotechnology. Since
entrepreneurship based on innovation has immense potential in any field, the chapter
highlights the essential entrepreneurial skills and various innovations happening in this
era of Industrial Revolution.
Biopharmaceuticals: Present and Prospects
Page: 237-257 (21)
Author: Subramani Parasuraman*, Krishnamoorthy Venkateskumar*, Thanapakiam Ganeson and Kamini Vijeepallam
DOI: 10.2174/9789815196115124010014
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Abstract
Biopharmaceuticals include vaccines, bioengineering drugs, blood products,
genetic engineering drugs, microecological preparations, and recombinant therapeutic
proteins. They are intended for the prevention, diagnosis, and treatment of human
diseases. Biopharmaceuticals are delivered using different drug delivery methods
which include nanoparticles, microparticles, jet injections, depot injections, and pumps.
It can be administered orally or in injectable form. In recent years, most of the
biopharmaceuticals including monoclonal antibodies are available as liquid
formulations. The emergence and re-emergence of infectious diseases require the
development of newer diagnostic tools and pharmacotherapeutic approaches. The
traditional approach may take a long time to get a new lead, whereas the
biotechnological applications may give highly specific antibodies which can minimize
the time of the drug discovery process and these molecules may have high specificity.
In the last few decades, many biopharmaceuticals have been approved for various
indications including cancer treatment. Many countries consider the biopharmaceutical
sector to be one of the most important industries for national growth.
Biopharmaceuticals have wider applications and it is gaining much more attention
clinically than conventional pharmaceuticals. The purpose of the chapter is to highlight
the importance of biopharmaceuticals and their prospects.
Octocorals in Turbid Waters – An Untapped Source of Potential Bioactive Molecules
Page: 258-270 (13)
Author: R. Chandran*, K. Padmakumar, Ch. Satyanarayana and R. Senthil Kumaran
DOI: 10.2174/9789815196115124010015
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Abstract
Discovering new secondary metabolites is an especially urgent task due to
the rapid spread of bacterial resistance and the emergence of multi-resistant pathogenic
strains of infectious diseases. Octocorals (soft corals and gorgonians) are a highly
diverse group of marine organisms, which are known to contain a rich variety of rare
and unusual secondary metabolites. These substances show not only great significance
in chemical ecology but also various biological activities. Despite the intense interest in
the isolation of novel compounds from octocorals, little is known about within and
between-habitat variability in the levels and types of compounds in these species.
Marine organisms living in extreme environments evolve unique strategies by
biosynthesizing more diverse compounds than their counterparts living in moderate
environments. Coral reefs of the Gulf of Mannar in India have a more moderate
environment (with a sedimentation rate of 12.31 mg.cm-2day-1); whereas the Gulf of
Kachchh is a marginal reef experiencing arid climate and heavy sedimentation rate
(upto119.60 mg.cm-2d
-1). In a preliminary cytotoxicity assay, carried out to evaluate the
bioactivity of selected soft corals from the Gulf of Mannar and the Gulf of Kachchh,
the highest cytotoxicity was exhibited by Mannar soft corals, Sinularia leptoclados
(LC50=25.15μg/ml) followed by Sarcophyton ehrenbergi (LC50=43.76μg/ml). Whereas
soft corals collected from the Gulf of Kachchh exhibited higher cytotoxicity than the
Mannar samples (Si. leptoclados (LC50=19.24μg/ml) followed by Si. polydactyla
(LC50=24.50μg/ml). Extreme physico-chemical and biological conditions in the
Kachchh are the drive for the production of variant molecules with specific adaptations.
Hence, soft corals inhabited in extreme waters may yield more effective compounds that may potentially be useful in drug development for existing and emerging human
ailments.
Biogenic Nanoparticles: A Functional Platform for Antiviral Activity – An Entrepreneurial Approach
Page: 271-290 (20)
Author: Ranjit Singh A. J. A.*, P. Dhasararthan, Gokul Shankar Sabesan and Bibin G. Anand
DOI: 10.2174/9789815196115124010016
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Abstract
Science-based businesses are taking a new dimension today.
Biotechnological innovations and inventions are given much attention in transforming
laboratory findings into business. Vaccine technology, since the pandemic 2019, has
become a billion-dollar business. An integrated approach of nanotechnology and
biotechnology as a single unit called Nano biotechnology opens a promising avenue for
business opportunities in health care. After the SARS-CoV-2 threat emerged, intensive
searches were accelerated to find remedial measures from different systems of
medicine. In this search, nanoparticles of both organic and inorganic origin are
prioritized, and research in nano -biotechnology gets immediate attention. Laboratory
research is intensified to formulate and patent some products to fight against the
coronavirus attack. Bio-inspired inorganic nanoparticles are reasonable in using
nanoparticles as a workhorse for biomedical applications. The biosynthesized
nanoparticles and quantum dots of gold, silver, cadmium, titanium, etc., have multiple
biomedical applications. The biogenic nanometal products enhance immunity, fight
against viruses, help in diagnosis, and play a role in preparing antiviral dressings, face
masks, and drug carriers. This venture promotes promising business avenues.
Biopharma industries are interested in developing the nanotechnology-based
therapeutic drug dexamethasone for SARS-CoV-2 drugs; nano-based vaccination to
boost immune responses is also progressing. The global market for nanobiotechnology
is expected to reach $68.4 billion by 2026. As nanobiotechnology-based business is
becoming a promising area for start-ups and entrepreneurs, the stakeholders can utilize
the opportunity as quoted “make hay while the sun shines”.
Medical Biotechnology - Approaches to become an Entrepreneur in Medical Biotechnology
Page: 291-308 (18)
Author: Antony V. Samrot*, Sanjay Preeth R. and M. Bavanilatha
DOI: 10.2174/9789815196115124010017
PDF Price: $15
Abstract
Medical biotechnology is one of its branches which involves the application
of medicine and biotechnology resources. Entrepreneurship is said to be the
development of a new business making profits where innovation and creditability are
considered as the backbone for its expansion. In the field of medical biotechnology, the
innovation of new medicines, methods for the identification and analysis of new
diseases, discovery of new solutions for a complex problem by satisfying the specific
needs, etc., are involved. In this chapter, various approaches and ideas for becoming an
entrepreneur in the field of medical biotechnology are discussed briefly.
Promising Roadmap in the Development and Commercialization of Pharmaceutical Products for Early Career Researchers
Page: 309-337 (29)
Author: Saranga Rajesh, Selva Sudha N., Raksha Goswami, Kunal Kishore and Hannah R. Vasanthi*
DOI: 10.2174/9789815196115124010018
PDF Price: $15
Abstract
Translational research by budding scientists in the pharmaceutical and
biotechnological field demands the application of their knowledge to a bedside medical
problem. Career opportunities in the pharmaceutical sector range from bench-side
research which includes screening, discovery and development, and operational
activities to manufacture, quality control, and marketing, including pharmacovigilance.
The success of trials leading to commercialization is determined by the quality of
research conducted in academia with the ultimate goal of moving the product ahead.
Early career researchers should have a deep understanding of pharmaceutical products,
particularly advanced drug delivery systems (DDS). Advanced DDS such as niosomes,
liposomes, dendrimers, nanoparticles, and others are developed to increase drug
distribution and bioavailability. DDS can accomplish localized or systemic drug
distribution by careful selection of excipients. DDS could be used to deliver all types of
therapeutic molecules, including biological macromolecules, to the site of action with
more stability. However, one must be aware of several factors, including the
physicochemical properties of the drug, formulation parameters, physiological
considerations, intersubject variability, and the choice of an appropriate animal model
for in vivo studies. In addition, the in vitro and in-vivo correlation (IVIVC) should be
considered, as it confidently converts the bench trial to a market level for bedside
applications. Accordingly, this review focuses on factors that influence drug delivery,
approaches to drug delivery systems, excipient selection strategies, ways to translate
the pilot scale to industrial scale, and the basic requirements of the pharmaceutical
sector for product commercialization. Furthermore, this chapter will also discuss some
of the possible funding avenues to nurture drug discovery and development to motivate
early-career entrepreneurs.
Subject Index
Page: 338-343 (6)
Author: Sagarika Devi, Gokul Shankar Sabesan and Sultan Ahmed Ismail
DOI: 10.2174/9789815196115124010019
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Introduction
Opportunities for Biotechnology Research and Entrepreneurship explores the intersection of scientific innovation and entrepreneurial endeavors in the field of biotechnology. With a focus on addressing real-world challenges and creating transformative solutions, this book offers valuable insights into the diverse applications of biotechnology across ecology, food, industrial, and medical sciences. Comprising 20 chapters, this edited volume brings together contributions from experts around the globe, offering a comprehensive overview of emerging research trends and techniques. Each chapter provides necessary background information and presents current and future applications of biotechnology, making it an ideal resource for students, researchers, and industry professionals. Key features include global perspectives, concise summaries tailored for easy understanding, and updated data accompanied by illustrations and flow charts. Whether exploring environmental sustainability, enhancing food security, optimizing industrial processes, or advancing medical treatments, this book serves as a valuable reference for those interested in the dynamic field of biotechnology.