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Biotechnology Projects

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Click Here to View Biotechnology Project Program Structure

Exploring Dynamic Biotechnology Landscapes: Varied Topics and Titles Across Below Given Specialized Focussed Research Arenas / Areas

Research Areas focussed for project students under Biotechnology:

NTHRYS provides Biotechnology Projects for interested candidates at its Hyderabad facility, Telangana. Please refer below for more details including Fee strctures, Eligibility, Protocols and Modules etc.,. Please do call / message / whatsapp for more details on 9014935156 [India - +91]

Eligibility: BSc / BTech / MSc / MTech / MPhil / PhD in any Life Sciences studying or completed students

Academic Projects are those works which students belonging to various courses like BSc, BTech, MSc, MTech, MPhil & PhD for partial fullfillment of their respective degrees.

What do NTHRYS Provide under these Project Works?

  1. Training in Practicals to students who have not done those protocols earlier.
  2. Complete [Project Report] Thesis Assistance.
  3. Handson Practicals Experience
  4. Training in Content Writing with 9% Plagiarism
  5. Academic Reviews Assistance
  6. Project Presentation Assistance
  7. Project Publication Assistance in Scopus Indexed Journals with Impact Factor above 2.5 for required candidates
  8. Accommodation Assistance for Students coming from outstations to Hyderabad

Topics / Titles Covered

Note:Due to certain intellectual constrains complete titles of the topics are not mentioned

  1. Transformation of Umbilical cord blood stem cell to cardiomyocytes
  2. Isolation and Identification of Neural stem cells from human fetal brain samples
  3. Study on the effect of various food grade acidity regulators on the growth of various human stem cells
  4. Role of umbilical cord blood stem cells in repairing damaged hepatocytes
  5. Role of umbilical cord blood stem cells in repairing damaged pulomonary cells
  6. Study on the capabilities of various stem cells in repairing damaged or burnt skin cells
  7. Study on the enhancement of stem cell growth in the presence of various biomolecules procured from a variety of plant extracts
  8. Isolation and Identification human neural progenitor cells from various stages of human fetus
  9. Recombinant Human p53
  10. Recombinant Eryhropoietin
  11. Recombinant scFv Fragments
  12. Recombinant Granulocyte colony-stimulating factor
  13. Recombinant DNA based Vectors for Gene Tharapy
  14. Design & Development of Recombinant Viral Vectors
  15. Recombinant DNA based non viral Gene Delivery systems design
  16. Bacteriophage-plasmid hybrid vectors designing using recombinant DNA technology
  17. Translational Research in recombinant DNA Technology
  18. Genetic modification of rare herbs for the production of isoquinoline alkaloids
  19. Genetic alteration studies in plant salt stress genes
  20. Achieving enzyme over expressions using plant biotech strategies
  21. Plant biotechnology studies in hairy roots
  22. Study on the probabilities of fungal tolerance in selected plants
  23. Exploring various genes and pathways for plant biotech applications which are involved in insect pest defence mechanisms using genome wide transcriptomic and proteomic databases
  24. Cadmium phytoremediation studies using plant biotechnology approaches
  25. Isolation Screening & Production of Biopesticides from natural & commercial strains like BtK, BtI etc.,.
  26. Production of Industrially important Enzymes from comercial microorganiss [ Isolation & Screening can be done from natural resources]
  27. Production of Antibiotics from commercial fungal & bacterial sources [Natural isolation and screening can be done]
  28. Production of Secondary metabolites from selected microorganisms
  29. Production of therapeutically important molecules
  30. Research studies on Quorum sensing in Plant & Animal microbial pathogens
  31. Screening & identification of keratinase producing bacteria from various natural habitats
  32. Production of restriction endonucleases from commercial bacterial sources
  33. Production of L - Asparaginase
  34. Production of Biofungcides

     


Research Objectives that are focussed at NTHRYS BIOTECH LABS in the Field of Biotechnology:

1. Develop microbial engineering strategies to optimize the production of advanced biofuels (Peralta-Yahya et al., 2012).

2. Investigate metabolic engineering techniques to enhance the production of native metabolites in cells (Nielsen & Keasling, 2016).

3. Explore the use of synthetic biology and systems biology approaches to improve industrial microbial strains (Lee & Kim, 2015).

4. Develop strategies for scaling up metabolic engineering to the industrial level (Nielsen & Keasling, 2016).

5. Investigate the potential of metabolic engineering to produce chemicals, fuels, and materials from renewable resources (Keasling, 2010).

6. Study the application of molecular plant breeding in crop improvement programs (Moose & Mumm, 2008).

7. Investigate the factors influencing the adoption of molecular plant breeding in crop improvement (Moose & Mumm, 2008).

8. Explore the use of nanotechnology in the control, prevention, and treatment of malaria (Rahman et al., 2019).

9. Investigate the potential of nano-biotechnology to create, improve, and utilize nanoscale structures for advanced biotechnology (Rahman et al., 2019).

10. Develop strategies to overcome drug resistance and environmental concerns in the fight against malaria (Rahman et al., 2019).

11. Study the use of natural reagents and plant-based particles for the control of malaria (Rahman et al., 2019).

12. Investigate vector elimination and effective chemotherapy as tactics to combat malaria (Rahman et al., 2019).

13. Examine the challenges of scientific research in molecular biotechnology in specific regions, such as Yemen (Al-hajj & KEKİLLİOĞLU>, 2023).

14. Investigate the use of data-driven and synthetic biology approaches to optimize host and pathways for fuel production (Peralta-Yahya et al., 2012).

15. Study the rewiring of cellular metabolism to enhance the production of new products (Nielsen & Keasling, 2016).

16. Explore the use of state-of-the-art tools of systems biology, synthetic biology, and evolutionary engineering in industrial bioprocesses (Lee & Kim, 2015).

17. Investigate the potential of metabolic engineering to produce a large number of chemicals from simple, readily available starting materials (Keasling, 2010).

18. Study the combination of enzymes or pathways from different hosts to enable the production of specialty chemicals, bulk chemicals, and fuels (Keasling, 2010).

19. Investigate the use of designer cells tailor-made for desired chemicals and production processes (Keasling, 2010).

20. Explore the use of systems approaches in industrial strain development to optimize cellular metabolism (Lee & Kim, 2015).

21. Investigate the complex interactions among metabolic, gene regulatory, and signaling networks in strain development (Lee & Kim, 2015).

22. Study the limitations and challenges of systems metabolic engineering at advanced levels (Lee et al., 2012).

23. Investigate the inclusion of challenging modules on biotechnology in the curriculum to enhance student understanding (Steele & Aubusson, 2004).

24. Explore the use of practical activities and ethical discussions to make biotechnology interesting for students (Steele & Aubusson, 2004).

25. Investigate the historical developments and key principles influencing the practice of molecular plant breeding (Moose & Mumm, 2008).

26. Study the factors influencing the adoption of molecular plant breeding in crop improvement programs (Moose & Mumm, 2008).

27. Investigate the contribution of molecular plant breeding to discoveries of genes and their functions in basic plant biology research (Moose & Mumm, 2008).

28. Explore the potential of nanotechnology in analytical applications (Rahman et al., 2019).

29. Investigate the control, prevention, and treatment of malaria using nanotechnology (Rahman et al., 2019).

30. Study the challenges of drug resistance and environmental concerns in the fight against malaria (Rahman et al., 2019).

31. Investigate the use of lipids, proteins, nucleic acids, and metallic nanoparticles for malaria control (Rahman et al., 2019).

32. Explore the potential of plant-based particles for antagonistic responses against malaria (Rahman et al., 2019).

33. Investigate strategies for vector elimination and effective chemotherapy in the fight against malaria (Rahman et al., 2019).

34. Study the process of scientific research and its importance in biotechnology (Al-hajj & KEKİLLİOĞLU>, 2023).

35. Investigate the application of older biological knowledge and newer approaches in biotechnology (Al-hajj & KEKİLLİOĞLU>, 2023).

36. Explore the responsible use of biotechnology and its societal implications (Al-hajj & KEKİLLİOĞLU>, 2023).

Contact for any topic which is not present in the above lists.

References in String Format: Al-hajj, M. and KEKİLLİOĞLU>, A. (2023). Challenges Of Scientific Research In Molecular Biotechnology In Yemen. Turkish Journal of Agriculture - Food Science and Technology, 2(11), 338-342. https://doi.org/10.24925/turjaf.v11i2.338-342.5757 Keasling, J. (2010). Manufacturing Molecules Through Metabolic Engineering. Science, 6009(330), 1355-1358. https://doi.org/10.1126/science.1193990 Lee, J., Na, D., Park, J., Lee, J., Choi, S., Lee, S. (2012). Systems Metabolic Engineering Of Microorganisms For Natural and Non-natural Chemicals. Nature Chemical Biology, 6(8), 536-546. https://doi.org/10.1038/nchembio.970 Lee, S. and Kim, H. (2015). Systems Strategies For Developing Industrial Microbial Strains. Nature Biotechnology, 10(33), 1061-1072. https://doi.org/10.1038/nbt.3365 Moose, S. and Mumm, R. (2008). Molecular Plant Breeding As the Foundation For 21st Century Crop Improvement. Plant Physiology, 3(147), 969-977. https://doi.org/10.1104/pp.108.118232 Nielsen, J. and Keasling, J. (2016). Engineering Cellular Metabolism. Cell, 6(164), 1185-1197. https://doi.org/10.1016/j.cell.2016.02.004 Peralta-Yahya, P., Zhang, F., Cardayre, S., Keasling, J. (2012). Microbial Engineering For the Production Of Advanced Biofuels. Nature, 7411(488), 320-328. https://doi.org/10.1038/nature11478 Rahman, K., Khan, S., Fahad, S., Chang, M., Abbas, A., Khan, W., … & Khan, D. (2019). nano-biotechnology: a New Approach To Treat And Prevent Malaria. International Journal of Nanomedicine, (Volume 14), 1401-1410. https://doi.org/10.2147/ijn.s190692 Steele, F. and Aubusson, P. (2004). The Challenge In Teaching Biotechnology. Research in Science Education, 4(34), 365-387. https://doi.org/10.1007/s11165-004-0842-1


What do NTHRYS provide in Biotechnology Projects schedule / module?

  • Certification Issued to candidates doing Biotechnology Projects.
  • Live Practical exposure to all protocols in Biotechnology Projects methodologies.
  • Complete assistance in Thesis / project report making.
  • Complete guidance for reviews in the middle of project works.
  • [Optional] - Accommodation assistance [Lodging & Bording] for girls & Boys separately.
  • Following Plagiarism rule for report making if required by candidates belonging to certain Universities which has such rule.
  • Publication assistance for 5 months & above duration Biotechnology Projects.
  • A website profile to every candidate after completion of project work to facilitate direct project proof to placements / consultancies / feedback checking firms


Note: NTHRYS currently operates through three registered entities: NTHRYS BIOTECH LABS (NBL), NTHRYS OPC PVT LTD (NOPC), and NTHRYS Project Greenshield (NPGS).

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