The key focuses of the National Biotechnology Development Strategy 2021-2025 are to build human and infrastructure capacities, implement biotech missions aligned with national and global priorities, build a self-reliant India through biotech interventions, leverage strategic partnerships, prepare for the future by building knowledge, take science to society, improve outreach and communication, conduct global benchmarking and implement policy enablers. The strategy aims to make India a global biomanufacturing hub and $150 billion bioeconomy by 2025 through focusing on building skilled workforce, strengthening infrastructure, promoting innovation and entrepreneurship, and facilitating product development and commercialization.
The Protein Data Bank (PDB) is a database for the three-dimensional structural data of large biological molecules, such as proteins and nucleic acids. This presentation deals with what, why, how, where and who of PDB. In this presentation we have also included briefing about various file formats available in PDB with emphasis on PDB file format
This document discusses biological databases and nucleic acid sequence databases. It describes the three primary nucleotide sequence databases: GenBank, EMBL, and DDBJ. GenBank is hosted by the National Center for Biotechnology Information and contains over 286 million bases and 352,000 sequences. EMBL is hosted by the European Molecular Biology Laboratory and mirrors data daily with GenBank and DDBJ. DDBJ is the DNA Data Bank of Japan and also mirrors data daily with the other two databases. Biological databases are important tools for scientists to understand biology at multiple levels.
This document provides an introduction to biological databases. It discusses what databases are and features of an ideal database. It describes the relationships between primary sequence databases like GenBank that contain original submissions, and derived databases like RefSeq that are curated by NCBI. Key databases at NCBI are described, including GenBank, RefSeq, and Entrez, which allows integrated searching across multiple databases. The benefits of data integration through linking related information are highlighted.
Rashi Srivastava presented on the KEGG database in biotechnology. KEGG is a database that contains genomic, chemical, and systems information to understand biological functions from the molecular level up. It includes pathways, genes, compounds, diseases, drugs, and organisms. KEGG can be searched through its flat file format using DBGET or through its relational database format for more complex queries. It also contains the KEGG MEDICUS search tool and direct SQL searches of its relational database.
The document provides an introduction to BLAST (Basic Local Alignment Search Tool), which is an algorithm used to compare gene and protein sequences to those in public databases. It discusses the types of BLAST programs, the BLAST algorithm, input/output, how to perform a BLAST search, and the functions and objectives of BLAST. Specifically, BLAST is faster than previous sequence comparison methods, it outputs alignments and statistical values to evaluate matches, and its main objectives are to identify related sequences and locate domains through local alignments.
1. Yeast plasmids like the 2 micron circle have been extensively studied and developed into yeast cloning vectors.
2. Shuttle vectors like YEp vectors contain selectable marker genes like LEU2 and bacterial plasmid origins of replication like pBR322, allowing them to replicate in both E. coli and yeast.
3. The 2 micron circle is a 6kb endogenous yeast plasmid that replicates autonomously through an ARS sequence and is maintained at 50-100 copies per cell.
This presentation gives you a detailed information about the swiss prot database that comes under UniProtKB. It also covers TrEMBL: a computer annotated supplement to Swiss-Prot.
Composite: It compile and filter sequence data from primary database.
Specialized : database—allows targeted searching on one or more specific subject areas
The Protein Data Bank (PDB) is a database for the three-dimensional structural data of large biological molecules, such as proteins and nucleic acids. This presentation deals with what, why, how, where and who of PDB. In this presentation we have also included briefing about various file formats available in PDB with emphasis on PDB file format
This document discusses biological databases and nucleic acid sequence databases. It describes the three primary nucleotide sequence databases: GenBank, EMBL, and DDBJ. GenBank is hosted by the National Center for Biotechnology Information and contains over 286 million bases and 352,000 sequences. EMBL is hosted by the European Molecular Biology Laboratory and mirrors data daily with GenBank and DDBJ. DDBJ is the DNA Data Bank of Japan and also mirrors data daily with the other two databases. Biological databases are important tools for scientists to understand biology at multiple levels.
This document provides an introduction to biological databases. It discusses what databases are and features of an ideal database. It describes the relationships between primary sequence databases like GenBank that contain original submissions, and derived databases like RefSeq that are curated by NCBI. Key databases at NCBI are described, including GenBank, RefSeq, and Entrez, which allows integrated searching across multiple databases. The benefits of data integration through linking related information are highlighted.
Rashi Srivastava presented on the KEGG database in biotechnology. KEGG is a database that contains genomic, chemical, and systems information to understand biological functions from the molecular level up. It includes pathways, genes, compounds, diseases, drugs, and organisms. KEGG can be searched through its flat file format using DBGET or through its relational database format for more complex queries. It also contains the KEGG MEDICUS search tool and direct SQL searches of its relational database.
The document provides an introduction to BLAST (Basic Local Alignment Search Tool), which is an algorithm used to compare gene and protein sequences to those in public databases. It discusses the types of BLAST programs, the BLAST algorithm, input/output, how to perform a BLAST search, and the functions and objectives of BLAST. Specifically, BLAST is faster than previous sequence comparison methods, it outputs alignments and statistical values to evaluate matches, and its main objectives are to identify related sequences and locate domains through local alignments.
1. Yeast plasmids like the 2 micron circle have been extensively studied and developed into yeast cloning vectors.
2. Shuttle vectors like YEp vectors contain selectable marker genes like LEU2 and bacterial plasmid origins of replication like pBR322, allowing them to replicate in both E. coli and yeast.
3. The 2 micron circle is a 6kb endogenous yeast plasmid that replicates autonomously through an ARS sequence and is maintained at 50-100 copies per cell.
This presentation gives you a detailed information about the swiss prot database that comes under UniProtKB. It also covers TrEMBL: a computer annotated supplement to Swiss-Prot.
Composite: It compile and filter sequence data from primary database.
Specialized : database—allows targeted searching on one or more specific subject areas
pBR322 is a 4,361 base pair plasmid vector originally constructed in 1977 for use in cloning experiments. It contains genes conferring resistance to ampicillin and tetracycline, which allow selection of recombinant clones, as well as an E. coli origin of replication. Recombinant selection involves insertional inactivation of the tetracycline resistance gene, rendering clones sensitive to tetracycline but resistant to ampicillin. pBR322 was widely used for cloning due to its small size, two selectable markers, and ability to be amplified in host cells. However, it is limited by its mobility between cells and small carrying capacity.
Rasmol and Swiss-PDB viewer are molecular visualization tools that allow users to view and analyze protein structures. Rasmol can display molecules in various representations like wireframe, cylinders, or ribbons. It supports common file formats like PDB and can rotate, zoom, and translate structures. Swiss-PDB viewer is tightly integrated with homology modeling and allows users to build models, compare structures, and view electron density maps. It utilizes template structures from the PDB to generate models and assess their quality. Both tools provide publication-quality images and interactive visualization of biomolecular structures.
The USEPA defines biodegradation as a process by which microbial organisms transform or alter (through metabolic or enzymatic action) the structure of chemicals introduced into the environment.
According to the definition by the International Union of Pure and Applied Chemistry, the term biodegradation is “Breakdown of a substance catalyzed by enzymes in vitro or in vivo.
The term is often used in relation to ecology, waste management, biomedicine, and the natural environment (bioremediation) and is now commonly associated with environmentally friendly products that are capable of decomposing back into natural elements.
Biodegradable matter is generally organic material such as plant and animal matter and other substances originating from living organisms, or artificial materials that are similar enough to plant and animal matter to be put to use by microorganisms.
This document discusses multiple sequence alignment techniques. It begins with definitions of key terms like homology, similarity, and conservation. It then describes pairwise alignment and its applications. The rest of the document focuses on multiple sequence alignment methods like progressive alignment, iterative refinement, tree alignment, star alignment, and using genetic algorithms. It provides examples and explanations of popular multiple sequence alignment tools like Clustal W and T-Coffee.
This document discusses the production of recombinant therapeutic proteins. It outlines three main methods: microbial bioreactors like E. coli, mammalian cell culture bioreactors like CHO cells, and transgenic animal bioreactors. Transgenic animals are produced via DNA microinjection into embryos to incorporate expression vectors for target proteins. Their milk can then produce large quantities of complex proteins through scale-up. While advantageous for production scale, transgenic systems have limitations regarding animal health effects and post-translational modifications. Examples of therapeutic proteins produced include antithrombin in transgenic goats and alpha-1-antitrypsin in transgenic sheep.
DNA sequencing determines the order of nucleotides in a DNA molecule. There are several methods of DNA sequencing including chain termination and cycle sequencing. Automated DNA sequencing uses fluorescent labels instead of radioactive labels and detects bands in real time during electrophoresis. In the four dye system, each dideoxynucleotide has a different fluorophore. In capillary array electrophoresis, labeled fragments are detected as they emerge from capillaries. Pyrosequencing determines incorporated bases by detecting pyrophosphate release using an enzyme cascade that emits light. Microarrays are used for resequencing and detecting mutations using hybridization.
The document discusses oxygen transfer in aerobic fermentation processes. It states that the majority of fermentation processes require oxygen, which has low solubility in water. For efficient oxygen transfer, dissolved oxygen must be continuously supplied to microorganisms at a rate equal to their demand. Key factors that influence oxygen transfer rate include bubble size, agitation intensity, viscosity, foaming, and vessel geometry. Equations are provided to characterize oxygen transfer rates and model maximum cell densities supported by reactors based on process conditions. Scale-up of fermentation processes requires matching critical environmental parameters like dissolved oxygen levels between small and large scales.
This document provides an overview of protein databases. It discusses the importance of protein databases for storing and analyzing protein sequence, structure, and functional data generated by modern biology. It summarizes several major public protein databases, including UniProt, NCBI RefSeq, PDB, InterPro, and Pfam, which contain protein sequences, structures, families, domains, and functional annotations. Searching and comparing sequences in these databases is an important first step in studying new proteins.
This document provides an overview of bioprocess engineering. It defines a bioprocess as a process that uses living cells or their components to produce desired products. Bioprocess engineering deals with designing equipment and processes for producing items like pharmaceuticals, chemicals, and polymers using bioprocesses. The document then describes the major components of bioprocesses, including upstream processing, fermentation, and downstream processing. It provides examples of products produced through various bioprocesses.
This document discusses different strategies for cloning DNA fragments from complex sources like genomic DNA or cDNA. There are two major approaches - cell-based cloning, which divides the DNA into fragments that are cloned to create a library, and directly amplifying target sequences using PCR. The document focuses on cDNA library construction, explaining that cDNA libraries reveal gene expression profiles. It describes early cDNA cloning methods and their limitations, as well as improved directional and non-directional cloning techniques. Finally, it discusses various screening methods for identifying clones of interest from cDNA libraries, including colony hybridization, plaque lifts and immunological screening.
Crystallization and whole broth processing are important industrial techniques. Crystallization involves forming solid crystals from a solution, melt, or vapor and is widely used in pharmaceutical and chemical purification. It allows isolation of products with high purity at low cost. Whole broth processing recovers metabolites directly from unfiltered fermentation broth using methods like ion exchange resins, dialysis, expanded-bed adsorption, or resin absorption to minimize inhibitory effects during fermentation. Common equipment for crystallization includes tank crystallizers and forced circulation crystallizers.
Secondary structure prediction tools analyze a protein's amino acid sequence to predict its 3D structure and function. These tools use various methods like Chou-Fasman, GOR, neural networks, and hidden Markov models to identify alpha helices and beta sheets based on characteristics like residue propensity values, sequence homology, and patterns in windows of amino acids. Accurate prediction of secondary structure is important for determining a protein's tertiary structure and biological role.
Types of animal cell culture; characterization & Their preservation.Santosh Kumar Sahoo
This document provides an overview of animal cell culture, including the different types (primary and secondary cell culture, cell lines), techniques used for primary culture, and characterization and preservation of animal cells. It discusses how primary cell culture involves separating cells directly from tissue and allowing them to grow under controlled conditions. Secondary cell culture refers to sub-culturing primary cells by transferring them to new vessels with fresh media. Cell lines can be propagated repeatedly and sometimes indefinitely. The document also describes cryopreservation as a method for preserving live cells and tissues at ultra-low temperatures in liquid nitrogen.
The SCOP database classifies protein structures hierarchically and describes evolutionary relationships between proteins. It was created in 1994 at the Centre for Protein Engineering and is maintained manually. SCOP links to the Protein Data Bank to obtain structural classifications for each protein structure directly and can also be searched to find a protein's structural class, fold, and domain information.
G.N. Ramachandran developed the Ramachandran plot in 1963 to visualize allowed backbone dihedral angles (phi and psi) of amino acid residues in protein structures. The plot shows sterically allowed and disallowed regions for phi-psi torsion angles based on collisions between atoms treated as hard spheres. It has since been used for protein structure validation and improvement of structure determination methods. The favored regions correspond to common secondary structure motifs like alpha helices and beta sheets.
The document discusses inoculum development and production media for industrial fermentation. It defines inoculum as a culture of microbes used to inoculate production-scale fermentations. Successful fermentations require developing inoculum to an active, healthy state in appropriate density. The document outlines factors that affect fermentation and discusses various media components like carbon sources, nitrogen sources, and trace elements. It also covers inoculum development methods for bacterial and mycelial cultures, preservation techniques, examples of media used for specific inocula, and criteria for a good inoculum.
The r-DNA Biosafety Guidelines of India classify research activities into three categories based on risk. Category I requires only intimation, Category II requires prior permission, and Category III requires review and approval before starting. The guidelines aim to regulate research safely and minimize accidental release of GMOs. Implementation occurs through four committees - RDAC provides regulatory oversight, IBSC monitors research, RCGM reviews risks and permissions, and GEAC approves large-scale use and environmental release. The guidelines establish containment levels and procedures to safely conduct r-DNA research and ensure biosafety.
This document discusses research and development (R&D) in biotechnology in Malaysia. It provides background on biotechnology and phases of Malaysia's biotechnology development plan from 2005-2020. Key areas that support R&D are discussed, including funding, expertise, intellectual property resources, and collaborations. The advantages of R&D in biotechnology are outlined as leading to industrial development, human capital development, strategic positioning and competitive advantages, engaging professional participation, and future economic growth through financial infrastructure development. The conclusion states that with Malaysia's biodiversity and support for R&D, biotechnology is expected to be a key driver of growth and generate significant revenue by 2020, and that investment in R&D is better than foreign technology
SINGAPORE'S BIOMEDICINE INITIATIVE PRESCRIPTION OF GROWTHANIRBAN CHOUDHURY
The document summarizes Singapore's strategy to develop its biomedical industry through significant government investment and infrastructure support. Key aspects of the strategy include building research facilities like the Biopolis science park; providing tax incentives; improving education; and creating a supportive environment through advanced telecommunications, lifestyle amenities, and strong intellectual property protection. The strategy has helped grow Singapore's biomedical manufacturing output and attract major international companies to establish operations in Singapore to take advantage of these resources and incentives.
pBR322 is a 4,361 base pair plasmid vector originally constructed in 1977 for use in cloning experiments. It contains genes conferring resistance to ampicillin and tetracycline, which allow selection of recombinant clones, as well as an E. coli origin of replication. Recombinant selection involves insertional inactivation of the tetracycline resistance gene, rendering clones sensitive to tetracycline but resistant to ampicillin. pBR322 was widely used for cloning due to its small size, two selectable markers, and ability to be amplified in host cells. However, it is limited by its mobility between cells and small carrying capacity.
Rasmol and Swiss-PDB viewer are molecular visualization tools that allow users to view and analyze protein structures. Rasmol can display molecules in various representations like wireframe, cylinders, or ribbons. It supports common file formats like PDB and can rotate, zoom, and translate structures. Swiss-PDB viewer is tightly integrated with homology modeling and allows users to build models, compare structures, and view electron density maps. It utilizes template structures from the PDB to generate models and assess their quality. Both tools provide publication-quality images and interactive visualization of biomolecular structures.
The USEPA defines biodegradation as a process by which microbial organisms transform or alter (through metabolic or enzymatic action) the structure of chemicals introduced into the environment.
According to the definition by the International Union of Pure and Applied Chemistry, the term biodegradation is “Breakdown of a substance catalyzed by enzymes in vitro or in vivo.
The term is often used in relation to ecology, waste management, biomedicine, and the natural environment (bioremediation) and is now commonly associated with environmentally friendly products that are capable of decomposing back into natural elements.
Biodegradable matter is generally organic material such as plant and animal matter and other substances originating from living organisms, or artificial materials that are similar enough to plant and animal matter to be put to use by microorganisms.
This document discusses multiple sequence alignment techniques. It begins with definitions of key terms like homology, similarity, and conservation. It then describes pairwise alignment and its applications. The rest of the document focuses on multiple sequence alignment methods like progressive alignment, iterative refinement, tree alignment, star alignment, and using genetic algorithms. It provides examples and explanations of popular multiple sequence alignment tools like Clustal W and T-Coffee.
This document discusses the production of recombinant therapeutic proteins. It outlines three main methods: microbial bioreactors like E. coli, mammalian cell culture bioreactors like CHO cells, and transgenic animal bioreactors. Transgenic animals are produced via DNA microinjection into embryos to incorporate expression vectors for target proteins. Their milk can then produce large quantities of complex proteins through scale-up. While advantageous for production scale, transgenic systems have limitations regarding animal health effects and post-translational modifications. Examples of therapeutic proteins produced include antithrombin in transgenic goats and alpha-1-antitrypsin in transgenic sheep.
DNA sequencing determines the order of nucleotides in a DNA molecule. There are several methods of DNA sequencing including chain termination and cycle sequencing. Automated DNA sequencing uses fluorescent labels instead of radioactive labels and detects bands in real time during electrophoresis. In the four dye system, each dideoxynucleotide has a different fluorophore. In capillary array electrophoresis, labeled fragments are detected as they emerge from capillaries. Pyrosequencing determines incorporated bases by detecting pyrophosphate release using an enzyme cascade that emits light. Microarrays are used for resequencing and detecting mutations using hybridization.
The document discusses oxygen transfer in aerobic fermentation processes. It states that the majority of fermentation processes require oxygen, which has low solubility in water. For efficient oxygen transfer, dissolved oxygen must be continuously supplied to microorganisms at a rate equal to their demand. Key factors that influence oxygen transfer rate include bubble size, agitation intensity, viscosity, foaming, and vessel geometry. Equations are provided to characterize oxygen transfer rates and model maximum cell densities supported by reactors based on process conditions. Scale-up of fermentation processes requires matching critical environmental parameters like dissolved oxygen levels between small and large scales.
This document provides an overview of protein databases. It discusses the importance of protein databases for storing and analyzing protein sequence, structure, and functional data generated by modern biology. It summarizes several major public protein databases, including UniProt, NCBI RefSeq, PDB, InterPro, and Pfam, which contain protein sequences, structures, families, domains, and functional annotations. Searching and comparing sequences in these databases is an important first step in studying new proteins.
This document provides an overview of bioprocess engineering. It defines a bioprocess as a process that uses living cells or their components to produce desired products. Bioprocess engineering deals with designing equipment and processes for producing items like pharmaceuticals, chemicals, and polymers using bioprocesses. The document then describes the major components of bioprocesses, including upstream processing, fermentation, and downstream processing. It provides examples of products produced through various bioprocesses.
This document discusses different strategies for cloning DNA fragments from complex sources like genomic DNA or cDNA. There are two major approaches - cell-based cloning, which divides the DNA into fragments that are cloned to create a library, and directly amplifying target sequences using PCR. The document focuses on cDNA library construction, explaining that cDNA libraries reveal gene expression profiles. It describes early cDNA cloning methods and their limitations, as well as improved directional and non-directional cloning techniques. Finally, it discusses various screening methods for identifying clones of interest from cDNA libraries, including colony hybridization, plaque lifts and immunological screening.
Crystallization and whole broth processing are important industrial techniques. Crystallization involves forming solid crystals from a solution, melt, or vapor and is widely used in pharmaceutical and chemical purification. It allows isolation of products with high purity at low cost. Whole broth processing recovers metabolites directly from unfiltered fermentation broth using methods like ion exchange resins, dialysis, expanded-bed adsorption, or resin absorption to minimize inhibitory effects during fermentation. Common equipment for crystallization includes tank crystallizers and forced circulation crystallizers.
Secondary structure prediction tools analyze a protein's amino acid sequence to predict its 3D structure and function. These tools use various methods like Chou-Fasman, GOR, neural networks, and hidden Markov models to identify alpha helices and beta sheets based on characteristics like residue propensity values, sequence homology, and patterns in windows of amino acids. Accurate prediction of secondary structure is important for determining a protein's tertiary structure and biological role.
Types of animal cell culture; characterization & Their preservation.Santosh Kumar Sahoo
This document provides an overview of animal cell culture, including the different types (primary and secondary cell culture, cell lines), techniques used for primary culture, and characterization and preservation of animal cells. It discusses how primary cell culture involves separating cells directly from tissue and allowing them to grow under controlled conditions. Secondary cell culture refers to sub-culturing primary cells by transferring them to new vessels with fresh media. Cell lines can be propagated repeatedly and sometimes indefinitely. The document also describes cryopreservation as a method for preserving live cells and tissues at ultra-low temperatures in liquid nitrogen.
The SCOP database classifies protein structures hierarchically and describes evolutionary relationships between proteins. It was created in 1994 at the Centre for Protein Engineering and is maintained manually. SCOP links to the Protein Data Bank to obtain structural classifications for each protein structure directly and can also be searched to find a protein's structural class, fold, and domain information.
G.N. Ramachandran developed the Ramachandran plot in 1963 to visualize allowed backbone dihedral angles (phi and psi) of amino acid residues in protein structures. The plot shows sterically allowed and disallowed regions for phi-psi torsion angles based on collisions between atoms treated as hard spheres. It has since been used for protein structure validation and improvement of structure determination methods. The favored regions correspond to common secondary structure motifs like alpha helices and beta sheets.
The document discusses inoculum development and production media for industrial fermentation. It defines inoculum as a culture of microbes used to inoculate production-scale fermentations. Successful fermentations require developing inoculum to an active, healthy state in appropriate density. The document outlines factors that affect fermentation and discusses various media components like carbon sources, nitrogen sources, and trace elements. It also covers inoculum development methods for bacterial and mycelial cultures, preservation techniques, examples of media used for specific inocula, and criteria for a good inoculum.
The r-DNA Biosafety Guidelines of India classify research activities into three categories based on risk. Category I requires only intimation, Category II requires prior permission, and Category III requires review and approval before starting. The guidelines aim to regulate research safely and minimize accidental release of GMOs. Implementation occurs through four committees - RDAC provides regulatory oversight, IBSC monitors research, RCGM reviews risks and permissions, and GEAC approves large-scale use and environmental release. The guidelines establish containment levels and procedures to safely conduct r-DNA research and ensure biosafety.
This document discusses research and development (R&D) in biotechnology in Malaysia. It provides background on biotechnology and phases of Malaysia's biotechnology development plan from 2005-2020. Key areas that support R&D are discussed, including funding, expertise, intellectual property resources, and collaborations. The advantages of R&D in biotechnology are outlined as leading to industrial development, human capital development, strategic positioning and competitive advantages, engaging professional participation, and future economic growth through financial infrastructure development. The conclusion states that with Malaysia's biodiversity and support for R&D, biotechnology is expected to be a key driver of growth and generate significant revenue by 2020, and that investment in R&D is better than foreign technology
SINGAPORE'S BIOMEDICINE INITIATIVE PRESCRIPTION OF GROWTHANIRBAN CHOUDHURY
The document summarizes Singapore's strategy to develop its biomedical industry through significant government investment and infrastructure support. Key aspects of the strategy include building research facilities like the Biopolis science park; providing tax incentives; improving education; and creating a supportive environment through advanced telecommunications, lifestyle amenities, and strong intellectual property protection. The strategy has helped grow Singapore's biomedical manufacturing output and attract major international companies to establish operations in Singapore to take advantage of these resources and incentives.
The document discusses the Indian biotechnology landscape from an international perspective. It finds that India has become a prominent global player in biotechnology, and its contribution to the global market is expected to grow significantly by 2025. However, it also identifies several issues that could hamper growth, such as low R&D spending, a lack of coordination between regulatory bodies, and insufficient industry-academia linkages. The document provides recommendations to address these issues, including increasing private sector investment in R&D, improving research quality and infrastructure, developing biotechnology clusters, and streamlining the regulatory environment.
This document provides an overview of the activities covered in the annual report of the Department of Biotechnology in India for the year 2020-2021. It discusses the department's efforts in building human resource capacities through various educational and training programs. It also summarizes the research and development activities conducted across different domains like agriculture, healthcare, bioresources and industrial biotechnology. The document highlights key initiatives taken by the department like Atal Jai Anusandhan Biotech Mission and its programs in healthcare, agriculture and clean energy. It briefly describes some notable achievements in agriculture and allied areas in developing crop varieties, diagnostics and vaccines.
This document outlines the draft National Biotechnology Development Strategy for India. It discusses developing human resources and infrastructure to support the biotechnology sector. Key recommendations include assessing training needs, improving curricula, strengthening university research, and attracting talent. The strategy also aims to develop infrastructure for R&D and manufacturing through public-private partnerships. The overall vision is for biotechnology to generate jobs and revenue while helping agriculture, healthcare, and the environment.
The document discusses India's ranking and performance in global innovation indices. Some key points:
- India ranked 40th in the Global Innovation Index in 2022, up from 81st in 2015, showing steady improvement.
- India leads among lower-middle income countries and scores highly in indicators like venture capital, finance for startups, graduates in STEM fields, and productivity growth.
- Government initiatives like increased funding for research and development, national innovation policies, and programs to link universities and industry have helped boost India's innovation ranking.
- While India is improving, it still lags major countries in areas like research spending and researchers per capita, but its total numbers of universities, institutes, and
The document outlines India's Vision 2020 plan to transform into a developed nation by 2020. It discusses key goals of the vision, including improving quality of life, increasing GDP share, and reducing population growth rate. It describes prerequisites like strong political and public commitment. Operations research models could help with planning, implementation, and optimizing resource allocation for projects across sectors like infrastructure, agriculture, manufacturing, and services to achieve the vision. The document provides examples of how OR has evolved and could be applied in three stages to help assess options, optimize efficiency and effectiveness, and guide competitive decision making.
The State of Odisha has vast scope for development of Biotechnology. With its rich biodiversity and vast natural resources, coupled with industry friendly policy measures, the State offers tremendous potential to become a major destination for investments in the Biotechnology Sector. Get information on the Biotechnology Policy in this presentation.
EurekaConnect Executive Forum Sept 2015 Summary and updateCurtis Sprouse
The document discusses the gap between medical research and implementation of new technologies and treatments. It summarizes a conference that brought together leaders from industry, academia, investment, and government to address this gap. The conference participants agreed to establish two initiatives: 1) an educational non-profit called the Institute for Biomedical Entrepreneurship to train researchers in commercialization, and 2) a for-profit development corporation to fund and support translation of innovations to products. Initial steps have been taken to incorporate these organizations, including electing boards and identifying executive directors. The initiatives aim to launch educational programs in 2017 and begin funding projects to bridge the gap between research and real-world impact.
In the fast-evolving landscape of biotechnology, analyzing the Indian market holds significant importance. Our comprehensive biotech industry analysis delves deep into the dynamic realm of Indian biotechnology, uncovering key trends, market dynamics, and emerging opportunities.
With a focus on India's unique ecosystem, our analysis sheds light on the advancements in biotechnology, encompassing areas such as pharmaceuticals, genomics, healthcare, and life sciences. We explore the latest research and development initiatives, innovative startups, and disruptive technologies shaping the industry.
By examining the market landscape, regulatory environment, and competitive landscape, our analysis provides valuable insights for stakeholders seeking to understand the Indian biotech sector. From investors and entrepreneurs to policymakers and researchers, our research helps make informed decisions and identifies potential areas of growth and collaboration.
With an emphasis on industry trends, market projections, and emerging challenges, our analysis equips professionals with the knowledge needed to navigate the dynamic biotech landscape in India. Stay informed, make strategic moves, and unlock the immense potential offered by the Indian biotech industry with our in-depth analysis.
The document provides an overview of the biotechnology industry in India. Some key points:
- The biotechnology industry in India is expected to increase dramatically from $7 billion in 2015 to $100 billion by 2025, driven by factors like growing demand, R&D investments, and government support.
- The biotechnology industry is comprised of several segments - bio-pharmaceuticals accounts for 64% of the market, followed by bio-services at 18% and bio-agriculture at 14%.
- The government has implemented several initiatives to support the growth of the biotechnology sector like increased funding, new policies, and establishing research institutions and biotech parks.
This document discusses opportunities for investment in India's growing life sciences sector. It notes that India is transitioning from an outsourcing destination to an intellectual powerhouse. It highlights several areas poised for high growth, including clinical research and manufacturing, agribiotechnology, and addressing India's unmet medical needs. It proposes strategies for venture capitalists to enter the market, such as supporting grassroots innovation through partnerships with academic institutions and incubators. This would help nurture entrepreneurship and position the venture capitalists as thought leaders in the Indian life sciences field.
The document discusses the strong historical and cultural ties between India and Japan, and highlights opportunities for cooperation between the two countries in the biotechnology sector. It notes that both countries have progressed well in biotechnology and can benefit from sharing strengths and expertise. India represents a large market and skilled workforce for R&D and product development, while Japan has the world's second largest pharmaceutical market and potential for Indian companies to cooperate. The government of both countries actively promote R&D in biotechnology through various schemes and initiatives.
The document discusses the scope for enhanced cooperation between Indian and German companies in the biotechnology sector. It provides an overview of the biotechnology industry in both countries, highlighting key areas like biopharmaceuticals, bioservices, bio-agri, and bioinformatics. The biotechnology market in India has grown significantly in the last decade and is projected to reach $100 billion by 2025, driven by factors like increasing government support and investments. The document identifies potential areas of collaboration between the two countries, including promoting academia-industry links, bilateral conferences, mentoring of Indian startups, and strengthening of clusters and incubators.
Explore the transformative potential of the Billionaire Biotech Code, a pioneering program designed to merge the realms of advanced biotechnology and visionary entrepreneurship. This article delves into how the program serves as a catalyst for innovation, offering participants a unique blend of scientific knowledge and business acumen. Discover how the Billionaire Biotech Code aims to incubate world-changing innovations, address humanity's greatest challenges, and promote sustainable prosperity. Join us in exploring a movement towards a future where the power of biosciences and entrepreneurial spirit combine to forge a new era of scientific breakthroughs and shared, sustainable wealth. Whether you're a scientist, entrepreneur, or dreamer, find out how this program can be your gateway to making a significant impact and achieving unparalleled success in the biotech world.
India declared 2010-2020 as the 'Decade of Innovation' and aims to be among the top five global scientific powers by 2020. This will require increased investment in scientific research and development, currently only around 1% of GDP. Barriers include a lack of clear research priorities, underfunding of public research institutions, and low private sector investment. The government plans to focus resources and public-private partnerships on priority technologies to promote innovation and achieve targets in areas like employment, GDP investment in R&D, climate change and education. Major goals are setting research priorities, increasing R&D funding as a percentage of GDP, and strengthening knowledge transfer between research institutions and the private sector.
Modern biotechnology Dr Nataporn Chanvarasuthcosti2014
The document discusses policy and institutional frameworks needed to support biotechnology innovation systems. It outlines that the 2030 bioeconomy will likely involve advanced biological knowledge, renewable biomass, and integration of biotechnology across sectors. Specific characteristics of the biotech business are described, such as its knowledge-based and long-term nature. The importance of innovation ecosystems and clusters in supporting commercialization is emphasized. Examples of policy approaches from different countries to provide suitable environments, expedite technology transfer, maintain biotech markets, and support science and innovation are given. Infrastructure and facilities to enable knowledge business are also summarized.
Established in 2002, Bioinformatics Institute of India (BII) is first of its kind with solely focusing on Bioinformatics and other applied life sciences domains.
BII is, resolute visionary, committed to provide world class technical and scientific education in life sciences domain. The aim behind the establishment of BII was to synergize theoretical knowledge and practical skills to promote all round professional competence due to which now BII has acquired a unique status in the country and globally.
The document provides an overview of the biotechnology industry in India. Some key points:
- The biotechnology industry in India is expected to increase in value from USD11 billion in FY2016 to USD100 billion by FY2025.
- The government aims to spend USD3.7 billion on biotechnology in the 12th Five-Year Plan, compared to USD1.1 billion in the 11th plan.
- Major segments of the biotechnology industry include bio-pharmaceuticals, bio-services, bio-agriculture, bio-industrial and bio-informatics.
- The bio-pharmaceutical segment accounts for the largest share, around 64% of the industry, and is
The document provides an overview of the biotechnology industry in India. Some key points:
- The biotechnology industry in India is expected to increase in value from USD11 billion in FY2016 to USD100 billion by FY2025 due to favorable business conditions and government support.
- The government aims to spend USD3.7 billion on biotechnology in the 12th Five-Year Plan, compared to USD1.1 billion in the previous plan, in order to further industry growth.
- India has a large population that offers a major market for biotechnology products and services. The country also benefits from low costs and a skilled workforce.
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NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY_01.04 (1).pdf
1.
2.
3. Table of Content
Summary
Vision & Mission
Introduction
Biotechnology As A Key Driver For A Knowledge-Based Economy
Impact Of Covid On Biotechnology Sector
The Genesis
Quantum Jump From The Nbds 2015-20
Key Strategies
(1) Building Capacities – A Skilled Workforce And Strengthened
State Of The Art Infrastructure
(2) Unati Biotech Missions – Aligned With National And Global Priorities
(3) Building A Self-Reliant India (Atmanirbhar Bharat) Through Biotech
Interventions – Affordable And Accessible Products And Technologies
A. Moving Technology From Lab To Market
B. Scaling The Innovation Ecosystem
(4) Leveraging The Strength Of Strategic Partnerships –
National And International
(5) Preparing For The Future – Building The Knowledge Base
(6) Taking Science To Society – Empowering The Rural Sector
(7) Effective Outreach And Communication– Building The Public Trust
(8) Global Benchmarking And Performance Measurement –
A Measurement Matrix To Build Quality
(9) Policy Enablers
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4. Over these last few years, we have seen a very encouraging growth in the Biotechnology Sector.
This has been primarily due to a strong foundation, which has been established over few
decades from research and education to translation and product development. An effort has
been made to engage with all stake holders and provide not just financial support but bring in
key policy changes with strong enablers and drivers for this ecosystem.
The Department of Biotechnology, which was setup in 1986, laid out its first Vision Document in
2000 and the Biotechnology Strategy in 2007 and then the Biotech Strategy-II in 2015. Through
these Vision and Strategy documents over 20 years the effort has been to create a strong
enabling environment to promote the growth of the sector and to ensure that the technologies
and products developed through the intervention of cutting edge frontier Biotechnologies are
delivered in the service of human kind.
As we move into the next 5 years from 2021 to 2025, we have set out for ourselves an ambitious
target of Biotechnology contributing to a “knowledge and innovation driven Bioeconomy”. With
the current growth trajectory of the sector we are confident that India will be within the top 5
countries globally and be recognized as a Global Biomanufacturing Hub by 2025, with the Sector
growing exponentially to achieve a growth of $150 Billion. This will be possible through a very
well-articulated Vision/Mission and Goals, driven through a set of well-defined strategies and
a clearly laid out implementation Action plan. This strategy document brings out this plan and
also lays emphasis on the new initiatives to be taken along with certain policy changes which
are required to deliver this target.
The recent COVID example has clearly indicated that our focus has to continue to be on 4 major
verticals:
• Building capacities both human resource and infrastructure to cater to the current needs and
also to the future emerging technologies
• Strengthening and nurturing of a strong basic research innovation driven ecosystem across
Research Institutes and Laboratories, both public and private sector, with complete
engagement of Startups, Small Industry, Large Industry and also reaching out to tier 2 and
tier 3 cities.
• The third major focus is on promoting the translation and product development
commercialization ecosystem which necessarily needs to engage public and private sector
and also encourage PPP models of co- development. This will require special focus on moving
research leads from Laboratory towards technology development.
• The balance between basic and translational research needs to be maintained to ensure that
we have a robust pipelines of new knowledge, which helps us to take the translational work
forward.
The strength of the research and translation is further enhanced through strategic partnerships
and this has also been clearly listed in this document. In addition to innovation on process,
technology and product, there is a need for innovation in models of governance and partnerships
which have been highlighted. The vibrancy of ecosystem for delivery of product needs a strong
regulatory environment with key policy drivers and enablers. This Strategy Document outlines
India’s strength and confidence in delivering a knowledge driven Bioeconomy.
SUMMARY
|| NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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5. Vision:
To harness the potential of biotechnology as a premier precision tool for national development
and well-being of society
Mission:
To make India globally competitive in biotechnology research, innovation, translation,
entrepreneurship and industrial growth and be a USD 150 billion Bioeconomy by 2025.
Goals and Objectives:
• To build and strengthen a strong education, research and translation ecosystem across the
country.
• To make India a global player for the development and deployment of new and emerging
technologies.
• To build and nurture a vibrant start-up, entrepreneurial and industrial base in the country,
connecting the academia and industry.
• To position India as a strong bio-manufacturing hub for innovative, affordable and accessible
products for the society and also for global markets.
Vision & Mission
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6. Biotechnology deals with the application of biological knowledge and techniques pertaining
to molecular, cellular and genetic processes to develop significantly improved products and
services. Biotechnology products and processes have ensured ease of living, improved health
care, agriculture output and created livelihood opportunities, etc.
India is ranked amongst the top 12 biotech destinations in the world and ranks 3rd in Asia. The
Indian biotech industry is likely to experience significant growth due to increasing economic
prosperity, health consciousness and a billion-plus population base. Current estimates value
the industry at USD 63 billion in FY2019-20, which is expected to grow to USD 150 billion by
FY25. At present, the biotechnology industry in India comprises >3500 biotech start-ups and
is estimated to reach 10,000 by 2024-25. The biotech sector is primarily divided into five major
segments: bio-pharma, bio-services, bio-agri, bio-industrial and bio-informatics, which together
contribute to the Bioeconomy. Biotechnology industry growth in India is primarily driven by
vaccines and recombinant therapeutics at present.
INTRODUCTION
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OUR KEY STRENGTHS
• Large reservoir of scientific human resource including scientists and engineers
• Cost-effective manufacturing capabilities
• ~3500 biotech start-ups
• Large number of national research laboratories; centres of academic excellence in biosciences
• Biotechnology parks and incubators established across the country to translate research into
products and services by providing necessary infrastructure support
• Several universities, professional colleges, educational and training institutes offering degrees
and diplomas in biotechnology, bio-informatics and biological sciences
• Presence of a well-defined and vibrant drug and pharmaceutical industry
• Highest number of USFDA approved manufacturing plants outside the U.S.
• Rich Biodiversity: India’s human gene pools offer an exciting opportunity for genomics
• Fastdevelopingclinicalcapabilitieswiththecountrybecomingapopulardestinationforclinical
trial and contract research
Strengths
• Building a strong Research Academic partnership
• Enhancing venture capital for high risk science
• Enhancing R&D expenditure by industry
• Strengthening the link between research and commercialisation
• Ensuring Quality assurance of Indian products as per international standards
• Ensuring Educational curriculum needs to be aligned to prepare students as per industry
demands
• Creating and strengthening State-of-the-art research facilities and translational centres
We however need to focus on
8. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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Biotechnology as Driver for
Knowledge-Based Economy
In the last several decades, life sciences per se has changed monumentally than virtually any
other field of science or engineering. Until recently, the objective of most basic research was to
generate new knowledge and advance understanding of biological and biochemical processes.
The steady, incremental advance of the life sciences has now started yielding important benefits
of healthcare, particularly through the pharmaceutical industry focusing on new healthcare
interventions and delivering innovation and greatly enhanced agricultural production and
productivity through improved process innovation and new technology. Discoveries from the
basic research undertaken in publicly/private funded research institutions are now being applied
more rapidly and broadly for societal impact. Key among the changes in the Indian context was
the setting up of BIRAC by DBT in 2012 that provided the impetus and a mechanism for nurturing
and support intellectual property rights and work with companies seeking to commercialize the
inventions coming from academic universities and institutions.
Worldoverbiotechindustrieshaveforayedintowide-rangingapplicationsinmedicine,agriculture
and foods, informatics, nano and forensics, among others. However, moving forward there would
be advances that are yet to be imagined. Industries will adopt new technologies and there will be
newdiscoveriesmade,thatwouldimpacteveryaspectofourlives–fromhealthtofoodproduction,
climate, and environment. Therefore, to create favorable conditions for sustainable development
and deployment of biotechnologies to act as an engine for the knowledge-based bio-economy, it
is imperative to have a strategy rooted in the Indian perspective to drive Biotechnology to the next
level.
9. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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Impact of COVID on Biotechnology Sector
In the past few months, the COVID-19 pandemic has impacted every sector of our economy.
However, despite the many challenges that have emerged due to the pandemic, biotechnology’s
key growth drivers have remained intact. Notably, the industry continues to generate innovative
new products in both the short and the long term.
The pandemic has presented some significant challenges to the scientific community.
However, at the same time, this offered opportunities for the pursuit of new scientific activities,
particularly in biotechnology. As a society, we have finally begun to reap the benefits of the
various scientific and medical advancements made in the past decade. The classic example
is the recent surge in novel drugs and treatment modalities that is apparent from the fact that
the vaccine for the SARS-CoV-2 coronavirus is the fastest any vaccine had previously been
developed, right from viral sampling to approval for use. Advances in genomics and proteomics,
as well as in DNA sequencing technologies, have enabled a more informed and targeted
approach to designing of drugs. Scientists and researchers are also now better equipped than
ever before to identify new mutations that drive diseases; to design new drugs with better
efficacy and safety; and to improve diagnosis of patients so that the best treatment options
can be found to improve clinical outcomes at a comparable timescale. India is also looking to
be self-reliant in developing and producing COVID-19 vaccine as the world races to mitigate
this deadly pandemic. Led by the Department of Biotechnology (DBT), Government of India, and
implemented by a dedicated Mission Implementation Unit at Biotechnology Industry Research
Assistance Council (BIRAC), the existing activities under National Bio-Pharma Mission (NBM)
and Ind-CEPI Mission are also providing complementary strengths to Mission COVID Suraksha
- The Indian COVID-19 Vaccine Development Mission that facilitates preclinical development,
clinical development and manufacturing and regulatory facilitation for deployment, and
consolidate all available resources towards accelerated product development. The highlights
of the COVID-19 R&D efforts include support for >100 projects in the thematic areas of vaccines,
diagnostics and therapeutics, enabling 7 vaccine candidates by industry and 8 candidates by
academia, development of clinical trial sites and centralised laboratories to facilitate vaccine
development and leveraging international partnerships, COVID 19 testing at 9 DBT Autonomous
institutes, approved as Hubs for their respective City/Regional clusters, rapid scale-up of
manufacturing of indigenous COVID-19 diagnostic kits with a production capacity of about15
Lakh kits/day, deployment of nation’s first infectious disease mobile laboratory in Haryana, 5
COVID19 Biorepositories with more than 40,000 samples available to researchers and industry,
development of therapeutics from natural products in partnership with M/o AYUSH and nearly 50
BIRAC supported startups have developed innovative products for COVID-19.
This leads the way forward for achieving success in all other areas even beyond COVID
10. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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Quantum jump from the NBDS 2015-20:
Department of Biotechnology announced the National Biotechnology Development Strategy-I
2015-2020 at the culmination of highly successful Biotech Strategy 2007. NBDS 2015-2020
resulted from formal and informal consultations with over 300 stakeholders including
scientists, educators, policymakers, leaders of industry and civil society, voluntary and non-
government organisations, regulators and international experts. Post announcement of the
NBDS 2015-20, the focus has been on the generation of biotech products, processes and
technologies to enhance efficiency, productivity, safety and cost-effectiveness of agriculture,
food and nutritional security; affordable health and wellness; environmental safety; clean energy
and biofuel; and bio-manufacturing. There has also been a major thrust on building a skilled
workforce to meet the national requirements. Emphasis has also been laid on technology-
oriented research aimed at improving lives and living of millions.
The transition from the NBDS 2015-20 to NBDS 2021-25 comes when India is aiming to become
a USD 5 trillion economy; making for India and the world, ensuring ease of living for the citizens,
skilling its youth to become entrepreneurs and job-creators and ensuring equitable and
sustainable development. The new strategy will allow the biotech sector to make a quantum
jump in addressing these priority areas.
DBT remains committed to providing a special impetus to new knowledge generation and
discovery, launching major strategically driven and directed missions, empowering the
country’s human resource scientifically and creating a strong ecosystem for research,
development, translation and commercialization to create a robust bio-economy. The era of
biotechnology-driven, socially relevant innovation and technology development has arrived
especially in the wake of COVID-19 outbreak. It will be the key driver of the NBDS 2021-25. DBT
would strengthen and widen its strategic partnerships globally, nationally and with the private
sector for achieving its ambitious targets.
The consultations held have helped identify the verticals that will drive the NBDS 2021-25 and
the instruments for their implementation. These are outlined in the key elements section.
The Genesis
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Key Strategies:
• Building Capacities – A skilled workforce and strengthened state of the art infrastructure
• UNATI Biotech Missions – aligned with National and Global priorities
• Building a Self-reliant India (Atmanirbhar Bharat) through Biotech Interventions –
Affordable and accessible products and technologies
• Leveraging the Strength of Strategic Partnerships – National and International
• Preparing for the Future – Building the knowledge base
• Taking Science to Society – Empowering the Rural sector
• Effective Outreach and Communication – Building the Public Trust
• Global Benchmarking and Performance Measurement – A Measurement matrix to build quality
• Policy enablers
Implementation Plan to Drive the Strategy:
Developing guiding principles are critical for creating an environment that will take the
biotechnology sector on a higher growth trajectory. Consultations with various stakeholders
have led to the identification of the following guiding principles that shall drive the National
Biotechnology Development Strategy 2021-2025. It is imperative that these guiding principles
are implemented through a well-defined Action Plan with identified deliverables and
assessment benchmarks with performance indicators and risk mitigation strategies.
12. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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Building Capacities – A Skilled Workforce and
Strengthened State of the Art Infrastructure
(1)
A skilled human resource and state of the art infrastructure are critical to meet the needs of
the growing biotechnology sector. To stay ahead and drive excellence, the sector would require
a sustenance plan with a focus on skill up-gradation, skilling for the future, ensuring quality at
par with global standards, nurturing future leaders in the field, creating a workforce that is ready
to adopt the new and emerging technologies and setting up state of the art infrastructure to
facilitate translational research while ensuring principles of equity and social justice.
• Build a skilled workforce to cater to the needs of the Biotech Industry and to enhance
employability.
• Ensure quality of the human resource across UG to post-doctoral is at par with the global best.
• Ensure a gender sensitive capacity building approach.
• Expand HRD activities to ensure pan-India coverage and increased footprint in Tier-II and
Tier-III cities.
• Create human resource in strategic areas such as data science, synthetic biology, cell and
regenerative medicines, gene editing, artificial intelligence, computation and structural
biology quantum biology, among others and which is future-ready to adopt emerging
technologies.
• Update the biotechnology curriculum with special emphasis on interdisciplinary areas, IPR
and regulatory aspects and periodic assessment of different training programs to keep pace
with contemporary developments and to enable seamless movement from one level to the next.
• Build future leaders in the field through post-doctoral programmes that include industry
exposure and partnerships.
• Promote shared infrastructure by creating centres which act as a nucleus to connect
universities, institutions and colleges.
13. • Programmes on Skill Vigyan for Life Sciences and Biotechnology in partnership with
State Science/Biotechnology Councils to be expanded to all States and UT’s across
the country.
• Create UDAAN Centers for Future Technologies to train and nurture young researchers in
futuristic technologies as our next generation leader.
• Model course curriculum to be developed with a focus on learning outcomes and
industry ready skills to match with regional, societal and national needs. Build an
accreditation mechanism in discussion with related Departments/agencies.
• DBT BRITE Awards and Fellowships as Young Researcher Fellowship Programmes to offer
an independent research grant to young Post-Doctoral Fellows to enable them to emerge
as future leaders and take up cutting edge research in areas of Biotechnology and allied
areas.
• Expansion of Star College Programme to Tier-II and Tier-III cities to build a biotechnology
base at undergraduate level.
• Initiate SPARK in collaboration with relevant agencies on the line of BEST (Biotechnology
Entrepreneurship Student Teams) programme to foster the entrepreneurial spirit in the
UG students from DBT-Star Colleges.
• Initiate a Biotech IMPRINT programme along with the Ministry of Education (MoE) to
build research capacities in universities and research institutes.
• Ensure access to the state of art research facilities, research platforms and equipments
for researchers across the country through a nearly ten-fold expansion of the DBT SAHAJ
programme.
• New Partnership Centers for Research (PaCeR) to be established for augmenting
and strengthening institutional research capacity in specific areas of life sciences
biotechnology to boost top-quality research with special emphasis on harnessing
benefits from across disciplines of physical sciences, engineering and medical
sciences to evolve robust interdisciplinary research programs.
• Development of innovative service models to offer services out of existing facilities at
competitive market rates.
• Build strong Human Resource and Infrastructure strengthening at Universities though
expansion of BUILDER programme.
• Set up strategically required Infrastructure for meeting cutting edge research needs for
indigenous product developed.
• To ensure open access policy to all the education & research institutes supported in
biotechnology across the country.
• Mobility/ sabbatical fellowship for scientists in industry to research centres/ academic
institute and vice versa.
Instruments of
Implementation
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Biotech Missions have been launched to align with the national and global priorities and give
a fillip to the National Development Plans (NDP) and Sustainable Development Goals (SDG).
Biotech missions thus ensure that the efforts made in the field of biotechnology converge
with other socio-economic efforts being made towards the end goal of achieving sustainable
development.
Special Atal Jai Anusandhan Biotech (UNaTI) Missions have been launched on significant
national and global challenges of Maternal and Child Health, AMR, Vaccines for infectious
disease, Food and Nutrition, Clean Technologies. In future, mechanisms will be put in place to:
A) Identify national priorities which stand to benefit from a focused biotechnology mission
such as:
• Mitigation of climate change with a special focus on controlling methane emission from
ruminants, solutions for controlling emerging pollutants like microplastics, antibiotics,
pesticides in soil and water, recycling of wastewater, rejuvenation of wetlands and
restoration of degraded land, unlocking the rich biodiversity of India’s 7517 km long
coastline, explorations of cold desert/extremophilic microbial biodiversity.
• Climate-resilient crops towards the second green revolution, nutrient-rich crops with
greater bioavailability, developing affordable technologies for cattle semen sexing and
sorting, strategies for milk yield improvement.
Atal Jai Anusandhan Biotech (UNATI) Mission
UNATI Biotech Missions – Aligned with
National and Global Priorities
(2)
15. • Addressing food security, balanced nutrition to tackle various deficiencies, concerted
public health nutrition research to develop evidence-based solutions and scale-up of leads
in consonance with the regulatory framework of FSSAI, enhance food availability by
decreasing wastage, develop functional foods to tackle the epidemic of lifestyle disorders.
• Novel platform technologies for thermo-stable vaccines, biologicals and biosimilars to
increase affordability, formulation/targeted-delivery of monoclonal antibodies/therapeutic
proteins/natural products, introduce mechanisms to bridge the gaps in progression of NCEs
Phytopharma /New Biologicals.
• Establish National Phytochemical Repositories preferably in collaboration with industrial
participation to serve as “National reference standards” for Indian Pharmacopoeia and
Ayurvedic Pharmacopoeia of India, translational programme on medicinal aromatic plants
and aquatic resources.
• Development of aquaculture/mariculture related biotechnology application for breeding,
larval rearing, growth and disease management to promote fish protein production.
• Tapping into the Blue Economy and associated biodiversity in the oceans.
Some Key Missions:
• Mission on Precision Healthcare adopting latest technologies for affordable and
accessible Health Care intervention through early predictive diagnosis, new and novel drug
discovery and development preventive Health Care.
• New Mission Programmes on improved crop varieties through Marker-Assisted Selection for
Climate resilience, Disease resistance and Nutritional enhancement.
• Mission Programme on Improved Crop Varieties through Gene Editing.
• Cattle Genomics initiative.
• One Health Mission on AMR for livestock and zoonotic Diseases.
• Mission on Management & Treatment of Rare & Genetic Disorders; Establishment of NIDAN
Kendras under UMMID program covering all Aspirational districts.
• National Nutrition Mission on Fortified and Functional Foods.
• Phytopharma Mission for development of phytopharmaceutical drugs as innovative future
affordable drugs.
• Mission on the scaling of indigenous cellulolytic enzymes for 2G Ethanol and development
of technologies for next-generation clean fuels including Bio-Butanol, Bio-Hydrogen and
Bio-Jet fuel.
• Mission on Waste to Value Technologies: Operationalise technology platforms designed
to convert different solid, liquid and gaseous wastes into renewable fuels, energy and useful
products like food, feed and polymers & chemicals.
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• Expand current missions to achieve SDGs and NDPs by working closely with line
ministries/ departments/ agencies with focus on deliverables.
• Adoption and introduction of new technologies/ products to ensure the success of
existing missions.
• Special emphasis on integrated Missions addressing national and global priorities in
Health, Agriculture, Clean Energy & Environment, HRD and entrepreneurship.
• Engage all stakeholders and forge partnerships of young researchers, women scientists,
start-ups, entrepreneurs and industries in these Missions.
• Directed funding towards new areas of biology such as Synthetic Biology, Quantum
Biology, Nutrigenomics, Personalized Medicine, Microbiome technologies etc. and blue
sky research linked to SDGs and NDPs.
Instruments of
Implementation
17. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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The development and deployment of indigenous technologies/ solutions in the field of
biotechnology will go a long way in achieving Atmanirbharata. The indigenous technologies/
solutions should be cost-effective and meet global standards of quality. In keeping with the
Hon’ble Prime Minister’s vision of marching towards ‘Atmanirbhar Bharat’, in a short span of two
months 100% indigenisation was achieved with respect to the production of COVID-19 diagnostic
kits through efforts in the field of biotechnology during the recent COVID-19 pandemic. National
Biomedical Resource Indigenisation Consortium (NBRIC), a PPP (Public-Private Partnership)
initiative of DBT in partnership with Association of Biotechnology Led Enterprises (ABLE)
and Confederation of Indian Industry (CII) was also set up to foster indigenous innovation
and bio-manufacturing with a focus on developing reagents, diagnostics and therapeutics
for COVID-19. Indian start-up ecosystem offers the unique ability to develop frugal innovative
products and platform technologies that are globally competitive to address unmet needs.
Knowledge translation through the integration of universities, research institutions and industry
along with critical enabling support is the need of the hour. India can emerge as a major bio-
manufacturing hub and a key player in the global supply chain by promoting indigenous
production of socially relevant interventions. During the inaugural address of ‘Indian Science
Congress 2020’, the Hon’ble Prime Minister announced India to become a world-class USD 100
billion bio-manufacturing hub. Currently, the Indian market in Biotechnology is less than 5% of
the global market. In the next 5 years, we hope to achieve USD 150 billion bio-economy against
world estimate of USD 725 billion by 2025, which will be about 21 % of the global market share. To
further the goal of Atmanirbhar Bharat through biotechnology interventions, the following will
be the key focus areas:
A) Moving Technology from Lab to Market
• Enabling support to Start-ups to propel their technology from proof of concept to
manufacturing, prioritisation and indigenisation of technologies, self-reliance in
consumables, equipments, reagents, instruments etc. for R&D.
• Two-pronged approach of import substitution of key reagents/ products/ instruments while
increasing the export of Made in India biotechnology goods and services.
• Clustering approach with flexible governance models with enhanced private sector
investment and promoting co-location and co-development of market-driven interventions
within academic laboratories through industry-academia partnerships.
• Setting-up of Translational centers and Technology Transfer offices (TTOs) to strengthen
India’s IPR landscape.
• Strengthen biotech-driven microenterprises in Tier-II and Tier-III cities.
Building a Self-reliant India (Atmanirbhar Bharat)
through Biotech Interventions – Affordable and
Accessible Products and Technologies
(3)
18. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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• Setting-up of Technology Advancement/ Translational Centers in Academia/ Industry
under Joint Partnership.
• Setting-up of Bio-manufacturing hubs and National Biotech Resource Indigenous
Consortium (NBRIC) to provide thrust to indigenous manufacturing.
• Cataloguing indigenous manufacturing capacities along with analytical specifications
and regulatory approvals for adding credibility to Made In India biotech products.
• Expansion of innovators and entrepreneurs query resolution forums like FIRST HUB in
multiple regions.
• Partnership with state universities for establishing microenterprises in Tier-II &
Tier-III cities.
• Technology Transfer Offices (TTO) to be set up in research institutes and universities.
• Biotech AcE fund to be expanded and a special Manufacturing Fund to be launched.
• 50 technology management centres, 25 Bioconnect offices and 10 regional centres of
BIRAC to be set up.
• Private sector participation and involvement of state government departments for new
biotech parks.
• Launching specific Mission programs for indigenous product development to ensure
import substitution in priority sectors.
Instruments of
Implementation
19. || NATIONAL BIOTECHNOLOGY DEVELOPMENT STRATEGY
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B) Scaling the Innovation Ecosystem
In 2012, the DBT had established a public sector undertaking Biotechnology Industry Research
Assistance Council (BIRAC) to catalyse innovative research, development, and Entrepreneurship
in the biotechnology sector. In a short span of eight years, BIRAC has nurtured over 1,102
entrepreneurs, start-ups and SMEs, 10,000 manpower for high-end skills, created 150 industry
partnerships, invested Rs. 3,529.87 Crores in R&D (BIRAC contribution of Rs. 2,149.45 Crores
plus industry contribution of Rs. 1,380.42 Crores) and created 5,68,719 sq. ft of incubation space
through support to 52 bio-incubators and 4 Regional Entrepreneurship Development Centres.
These activities resulted in the filing of 268 patent applications and development of more than
150 products/ technologies.
Connecting Start-up India with Make In India:
Access to facilities for designing, fabrication and validation of proof of concept, and further
scaling is the missing link between Start-up India and Make in India. Technology clusters
harbouring Technology Propellers (T-Propellers) and Manufacturing Zones (M-Zones) need to
be set up to facilitate single product start-up to move to integrated enterprises. Such initiatives
would benefit the growing number of biotech start-ups (10,000+ by 2024) especially engaged
in projects aimed towards import substitution, cutting edge, mass impact, market deployment,
export-oriented and disruptive technologies to integrate and add value to the national priorities
of Make In India.
• T-Propellers to serve several incubators and pool of start-ups to take their research leads
from proof of concept stage to pilot facility. This will address the large gap in the ecosystem
by providing design improvisation, material selection, process standardisation, validation
for manufacturing, regulatory compliances, licenses etc. to facilitate market deployment.
• M-Zones for the successful scaling of technology-based start-ups to “Manufacturing Stage”
by providing affordable access to new and existing manufacturing facilities which include
raw material clustering, hardware & software vendors, distribution network, marketing and
design labs, advertisement industry, industry associations, professional societies,
investors, centre, state agencies, investments pooling from VCs advanced
modelling & simulation tools for design and process improvement.
• Develop a central mechanism for the intake of exciting new lead candidates from research
institutes and facilitate the development of products in mission mode as part of a national
effort and not just as a PI/ institution-driven activity.
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• Establish 'Innovation Accelerators' and 'Translational Accelerators' accessible to
public institutions and SMEs to successfully incubate discoveries.
• Work through BIRAC for nurturing entrepreneurship, technology acquisition and
commercialisation.
• 10 Strategically located Technology Clusters to be established.
• 5 Bio-manufacturing Zones to be established in the vicinity of SEZs.
• 10 Biotech URJIT Clusters to be setup for connecting universities, research institutes,
industries and start-ups and to undertake industry-inspired projects.
• Biodesign Centers in NITs/ IITs/ IIITs etc. to be explored for developing products for
identified clinical needs/ agri-field requirements.
• Biotech Angel Network for catalysing early-stage Investments in 150 start-ups in next
three years through Angels, Family offices, HNIs, early-stage VCs.
• Setting up of 250 e-YUVA centre networks in the country for undergraduates to create a
culture of Biotech entrepreneurship.
Instruments of
Implementation
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Joining hands and pursuing complementary targeted research with the best talent available
nationally and internationally will leapfrog the Indian research community to the next level
of innovation. Strength of leveraging partnerships also lies in the fact that multidisciplinary
networks of biologists, chemists, physicists, computational biologists and others can address
most pressing scientific challenges in a comprehensive manner and in a much shorter
time. This is also when India is transitioning from technology receivers to co-developers of
technology. In light of these recent developments, it becomes imperative that partnerships
are strategically driven where India has a greater say in deciding areas of co-operation and
creating market access for indigenous products/ technologies has to be kept central in future
discussions. India’s contribution to LMICS, Africa, PACT clinical trial framework for neighbouring
countries should also form the backdrop for deciding future partnerships as also triangular
cooperation strategies Areas such as agriculture biotechnology, which have traditionally been
our strength but have not been adequately represented in international partnerships, should
find greater representation in the future.
• Collaborations with multilateral forums like SAARC, BRICS, ASEAN, BIMSTEC,G-20, G-6 and
professional organizations e.g. National Center for Biotechnology Information (NCBI),
European Molecular Biology Laboratory (EMBL), DNA Data Bank of Japan (DDBJ) to highlight
strengths of the Indian biotech sector on global platforms.
• Build upon existing global partnerships with Government/ Non-Govt/ Philanthropic
organisations and develop new models of multilateral alliances.
• Global public-private partnerships to be forged by connecting Indian start-ups to the global
ecosystem and setting-up of test bed facilities for start-ups.
• Strategic partnerships for building quality human resource and a strong technology and
knowledge base – Ind-CEPI, VAP, Mission Innovation, HFSPO, EMBO, EMBL, ICDA, ICGC, Global
AMR, HCA.
• Expand the scope of R&D and entrepreneurship development with the collaborating partners
and initiate mission mode projects in bioinformatics, functional genomics/ Encyclopedia of
DNA Elements (ENCODE), AI and Big Data, Bio-resources to put India on the world map.
• Strengthening partnership with States for strengthening the biotech sector in India.
• Collaboration with other government ministries & departments.
Leveraging the Strength of Strategic
Partnerships - National and International
(4)
22. • Partnerships with EMBL, Max-Planck and similar professional organisations.
• Launch major international projects in bioinformatics/ Genomics/ AI etc. wherein
India can become a leader through strategically identified Bilateral and Multilateral
cooperation.
• Set up international incubators in areas such as Agriculture, AMR, Clean Energy.
• Establish cooperation with Low and Middle-Income Countries (LMICs) and emerging
economies of Asia, Africa and Latin America.
• New biotech parks with the active participation of the state governments.
• Attract and retain the highly qualified scientists in the country through ongoing
Ramalingaswami Re-entry Fellowship and other such specialized schemes.
• Working and engaging with the Global Indian Diaspora to take advantage their potential
for building strength and collaboration.
Instruments of
Implementation
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To stay ahead of the curve, it is crucial to build HR capacity, set up necessary infrastructure and
put in the adequate investment to prepare for future technologies. These new and emerging
technologies have an immense potential for transformative change in Healthcare, Agriculture
and Environment. Also, since most of these technologies are nascent, it provides a unique
opportunity to position India as a global leader in these technologies.
• Greater and focused funding towards new and emerging areas of biology and cutting edge
blue-sky basic research in the prioritized areas - Precision Medicine, CAR-T technology,
Gene editing and therapy, CRISPR- CAS biology, Synthetic Biology, Lipid biology, Glycobiology,
Epigenetics, Secondary plant metabolites, Marine biology, Natural products and medicinal
chemistry, quantum biology, 3D- bioprinting etc.
• Artificial Intelligence and machine learning in Precision Health.
• Snake envenomation & novel monoclonal antibodies which are cost effective & globally
accessible.
• Integrating stem cell technology and embryo manipulation technologies with genome editing
to develop xeno transplantation models and chimeric animals for tissue/organ transplant
models.
• Application of nanotechnology for regenerative medicine and enhancement of new generation
of technologies like photonic/ thermal/ cryo interventions in medical practice.
• To initiate a major network programme on CRISPR/ Cas mutagenesis with identified traits in
some of the selected crops.
• To promote research on aerobic cultivation of rice, low till cultivation of wheat, rice and
resistance to terminal heat stress in wheat aswell as disease resistance in rice and wheat.
• Development of technologies for cattle semen sexing and sorting.
• Development of integrated technologies for ‘Bioeconomy’ through the bio-refinery concept.
• Sequestration of effluent gases into various platform chemicals.
Preparing for the Future – Building the
Knowledge Base
(5)
24. • Establishment of Centres of Excellence centred on New Emerging technologies
(CONEs) like Gene Editing, Gene Therapy, Regenerative Medicine, CAR-T Cell Therapy,
Big-data Analysis, Data Analysis, Adjuvants, Data Science and Artificial Intelligence
(AI), Speed breeding platforms & Precision Agriculture, Bioastronautics research,
Astrobiology etc.
• Develop Network proposals with well-defined goals in priority areas.
• Initiate programs on Bio-IT and Code Biology, Medical Analytics, Digital Health.
• Commission foresight studies in life sciences and biotechnology.
Instruments of
Implementation
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Under the overarching umbrella of Scientific Social Responsibility, scientific solutions need
to percolate down to the grass-root level to have a wider societal impact and ensure Ease
of Living of the citizens. This will bring biotechnology closer to fulfilling societal needs and
in the same vein society will also be brought closer to fruits of biotechnology which in the
long run will contribute to building the public confidence in scientific solutions. Creating
employment opportunities through biotech led micro-enterprises, wealth creation, and
ensuring local resources’ sustainability are some of the myriad ways biotechnology can
interface with society.
• Establish biotech innovation hubs for societal development, including in the Aspirational
Districts.
• Promote rural bio-entrepreneurship and upscaling of grass-root innovations through the
demonstration of viable and ecologically compatible technologies to the target group for
adoption in a holistic and sustainable manner.
• Promote scientist-farmer partnership for agriculture innovation through participatory
research to connect science laboratories with the farmers to find innovative solutions and
technologies to be developed and applied at the farm level.
• Promote frugal innovation and awareness of natural resources.
Taking Science to Society – Empowering the
Rural Sector
(6)
26. • Establish Biotech-Krishi Innovation Science Application Network (Biotech-KISAN)
Hubs in all aspirational districts and 15 agro-climatic regions across India.
• Setting up Rural Bioresource Complexes/ Rural Technology Clusters in Aspirational
districts for social enterprises.
• DNA Clubs (DBT’s Natural Resource Awareness clubs) at school level for 6th
-10th
standard in all Aspirational districts.
• Wider outreach of hands-on training in frugal science programmes for teacher and
student training.
Instruments of
Implementation
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With data becoming central to the decision-making process, there is a need to move
towards data-driven communication to build public confidence in biotechnology solutions.
Communication needs to be effective and should reach end users/ beneficiaries of
biotechnology interventions/ solutions at the grass-root level. This can significantly
increase acceptance and also create channels to assess ground level requirements. Effective
communication strategies are also crucial from the standpoint of projecting the growth and
success of the Indian biotechnology sector to a global audience. This, in turn, could attract
investment in the Indian biotechnology sector from various quarters. Moving ahead the
following need to be prioritised:
• Emphasis on data-driven communication and advocacy.
• Deeper engagement with stakeholders through multiple channels.
• Focus on a bottom-up approach to feel the pulse of society.
• Combining data and evidence from various quarters for decision making.
Effective Outreach and Communication –
Building the Public Trust
(7)
28. • Setting up a Communication unit as an interface of DBT and stakeholders.
• Socio- economic research-based societal inputs in prioritisation and strategic
planning.
• Promotion of public communication through print, digital and social media.
• Global Bio-India events for projecting strength of Indian biotechnology sector to a
global audience.
• India International Science Festival for the scientific community and other
stakeholders.
• Organisation of outreach programmes such as Nobel Prize Series.
• Centres for analysing and enabling the interaction of Biotechnology with social and
economic thought and developmental studies.
• Building Public confidence in new technologies.
• Establish Science Policy Coordination, Collaboration, and Reporting section.
Instruments of
Implementation
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An exercise to measure biotechnology and benchmark activities through an internationally
acceptable statistical framework needs to be initiated. This is important from the perspective
of measuring the impact of activities of DBT and its autonomous institutions and how it fares in
comparison to global efforts.
• Global Benchmarking to be done in the context of the size of the sector, available resources,
societal impact and other discernible indicators.
• Develop a portal to provide information on scientific achievements and authentic knowledge
about biotechnology in technology licensing, IPR and regulatory issues. This should also be a
source of information for policymakers.
• Setting up a Data Monitoring unit.
• Develop strong impact assessment capabilities, including data-based and objective
assessment of social and economic impact, for both basic and applied research.
Global Benchmarking and Performance
Measurement – A Measurement
Matrix to Build Quality
(8)
30. • Internationally acceptable statistical framework to be set up for measuring the
bioeconomy.
• Engaging with professionals/ third parties for periodic assessment of performance
metrics.
• Periodic socio-economic impact assessment of schemes/ programs of DBT.
Instruments of
Implementation
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With the motto of minimum government maximum governance, science-based, predictable
and time-bound policies and regulations will be streamlined in response to stakeholder
requirements and evolving policy environment. Significant efforts have gone into creating
a facilitative regulatory environment, establishing a vibrant research and entrepreneurship
ecosystem and professionalization of research funding mechanisms. During the current
COVID-19 pandemic, Rapid Response Regulatory Framework for expedited regulatory approvals
for all diagnostics drugs and vaccines was put into place. Guidelines for sharing bio-specimens
and data for research related to COVID-19 were also developed to ensure that there were no
impediments to scientific research. Future efforts in this direction will be as follows:
• Develop an ‘Ease of Doing Science Index’ to ensure effective use of both disbursed funds
(including flexibility of fund utilisation) and the researcher's time.
• Develop regulatory guidelines for implementation of new and emerging technologies such a
gene editing and other cutting edge technologies.
• Define policy on sharing biological data specifically pertaining to modern high-throughput,
high-volume data, such as data generated by nucleic acid sequencing and microarrays, bio-
molecular structures and flow cytometry and set up the first indigenous biological data centre.
• Developing a “Network of infrastructure under Biosecurity and Biosafety” across the country to
strengthen the nation for preparing the country for future epidemic/ pandemic.
• To have a molecular surveillance system with advanced diagnostic facilities and customary
network facilities to tackle pathogens affecting humans, livestocks, animals and plants.
• Continuously improve the Indian biotechnology industry’s ability to compete globally, by
interventions at the level of policy and support.
• Develop policies and frameworks for the utilisation of Biotechnology-based products that have
a social but not necessarily market-based value in key areas.
• Technology Transfer and Innovation Policy to serve as a central resource on matters involving
technology transfer and innovation.
• Policy to promote and strengthen Biomanufacturing ecosystem.
• Policy on the ethics and usage of Synthetic Biology and Emerging Technologies.
• Frugal Innovation policy through engagement with state governments & state science &
technology councils.
Policy Enablers
(9)
32. • Formulation of Biological Data Storage, Access and Sharing Policy of India and setting
up the Indian Biological Data Centre- PRIDE policy.
• Formulation of Regulatory Guidelines for Gene Editing.
• Indian Bio-safety Knowledge Portal (IBKP): For ease of doing business.
• Harmonisation of Regulatory guidelines such as Updation of Risk Group, Formulation
of stacked event guidelines, Environmental Risk Assessment (ERA) of Genetically
Engineered Microorganism, Updation of recombinant DNA guidelines.
• Setting up a Policy Unit/ Think Tank, for forecasting and developing policy white paper
on new and emerging areas and strategic priority areas.
• A well-structured National Biosafety and Biosecurity Network to be developed for
epidemic/ pandemic.
Instruments of
Implementation
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33. • $ 150 billion Biotech Industry
• $ 100 billion Biomanufacturing Global Hub
• Import substitution for medical devices, reagents, components
• 125 Bioincubators
• 10 Technology Clusters
• 10 Biotech Parks and Manufacturing Hubs
• 10 URJIT Clusters
• 10 CONEs
• 10 PACERs
• 100 PG Courses
• Skill Vigyan Centre in all States
• 100 Rural Bioresource Technology Clusters
• 115 KISAN Hubs in Aspirational Districts
2021 – 2025 OUR TARGETS
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34. 1,000+
Startups,
Entrepreneurs
& SMEs supported
52
Bio-incubators
5,69,219 sq. ft.
incubation space
check
150+ Cr
Partnered funding
raised by 75
Startups
200
Marketed products/
Technologies
2,057 Cr
Funding
4
Regional
Entrepreneurship
Development Centres
3,500+ cr
Valuation 750
Startups
250
IPs filed 10,000+
Manpower supported
for high end skills
300 cr
Equity funding
AcE-fund of fund
DEPARTMENT OF BIOTECHNOLOGY
Ministry Of Science And Technology
Government of India
Building the innovation ecosystem:
startup India - Make in india