best research topics for biotechnology

200+ Biotechnology Research Topics: Let’s Shape the Future

In the dynamic landscape of scientific exploration, biotechnology stands at the forefront, revolutionizing the way we approach healthcare, agriculture, and environmental sustainability. This interdisciplinary field encompasses a vast array of research topics that hold the potential to reshape our world. 

In this blog post, we will delve into the realm of biotechnology research topics, understanding their significance and exploring the diverse avenues that researchers are actively investigating.

Overview of Biotechnology Research

Table of Contents

Biotechnology, at its core, involves the application of biological systems, organisms, or derivatives to develop technologies and products for the benefit of humanity. 

The scope of biotechnology research is broad, covering areas such as genetic engineering, biomedical engineering, environmental biotechnology, and industrial biotechnology. Its interdisciplinary nature makes it a melting pot of ideas and innovations, pushing the boundaries of what is possible.

How to Select The Best Biotechnology Research Topics?

• Identify Your Interests

Start by reflecting on your own interests within the broad field of biotechnology. What aspects of biotechnology excite you the most? Identifying your passion will make the research process more engaging.

• Stay Informed About Current Trends

Keep up with the latest developments and trends in biotechnology. Subscribe to scientific journals, attend conferences, and follow reputable websites to stay informed about cutting-edge research. This will help you identify gaps in knowledge or areas where advancements are needed.

• Consider Societal Impact

Evaluate the potential societal impact of your chosen research topic. How does it contribute to solving real-world problems? Biotechnology has applications in healthcare, agriculture, environmental conservation, and more. Choose a topic that aligns with the broader goal of improving quality of life or addressing global challenges.

• Assess Feasibility and Resources

Evaluate the feasibility of your research topic. Consider the availability of resources, including laboratory equipment, funding, and expertise. A well-defined and achievable research plan will increase the likelihood of successful outcomes.

• Explore Innovation Opportunities

Look for opportunities to contribute to innovation within the field. Consider topics that push the boundaries of current knowledge, introduce novel methodologies, or explore interdisciplinary approaches. Innovation often leads to groundbreaking discoveries.

• Consult with Mentors and Peers

Seek guidance from mentors, professors, or colleagues who have expertise in biotechnology. Discuss your research interests with them and gather insights. They can provide valuable advice on the feasibility and significance of your chosen topic.

• Balance Specificity and Breadth

Strike a balance between biotechnology research topics that are specific enough to address a particular aspect of biotechnology and broad enough to allow for meaningful research. A topic that is too narrow may limit your research scope, while one that is too broad may lack focus.

• Consider Ethical Implications

Be mindful of the ethical implications of your research. Biotechnology, especially areas like genetic engineering, can raise ethical concerns. Ensure that your chosen topic aligns with ethical standards and consider how your research may impact society.

• Evaluate Industry Relevance

Consider the relevance of your research topic to the biotechnology industry. Industry-relevant research has the potential for practical applications and may attract funding and collaboration opportunities.

• Stay Flexible and Open-Minded

Be open to refining or adjusting your research topic as you delve deeper into the literature and gather more information. Flexibility is key to adapting to new insights and developments in the field.

200+ Biotechnology Research Topics: Category-Wise

Genetic engineering.

• CRISPR-Cas9: Recent Advances and Applications
• Gene Editing for Therapeutic Purposes: Opportunities and Challenges
• Precision Medicine and Personalized Genomic Therapies
• Genome Sequencing Technologies: Current State and Future Prospects
• Synthetic Biology: Engineering New Life Forms
• Genetic Modification of Crops for Improved Yield and Resistance
• Ethical Considerations in Human Genetic Engineering
• Gene Therapy for Neurological Disorders
• Epigenetics: Understanding the Role of Gene Regulation
• CRISPR in Agriculture: Enhancing Crop Traits

Biomedical Engineering

• Tissue Engineering: Creating Organs in the Lab
• 3D Printing in Biomedical Applications
• Advances in Drug Delivery Systems
• Nanotechnology in Medicine: Theranostic Approaches
• Bioinformatics and Computational Biology in Biomedicine
• Wearable Biomedical Devices for Health Monitoring
• Stem Cell Research and Regenerative Medicine
• Precision Oncology: Tailoring Cancer Treatments
• Biomaterials for Biomedical Applications
• Biomechanics in Biomedical Engineering

Environmental Biotechnology

• Bioremediation of Polluted Environments
• Waste-to-Energy Technologies: Turning Trash into Power
• Sustainable Agriculture Practices Using Biotechnology
• Bioaugmentation in Wastewater Treatment
• Microbial Fuel Cells: Harnessing Microorganisms for Energy
• Biotechnology in Conservation Biology
• Phytoremediation: Plants as Environmental Cleanup Agents
• Aquaponics: Integration of Aquaculture and Hydroponics
• Biodiversity Monitoring Using DNA Barcoding
• Algal Biofuels: A Sustainable Energy Source

Industrial Biotechnology

• Enzyme Engineering for Industrial Applications
• Bioprocessing and Bio-manufacturing Innovations
• Industrial Applications of Microbial Biotechnology
• Bio-based Materials: Eco-friendly Alternatives
• Synthetic Biology for Industrial Processes
• Metabolic Engineering for Chemical Production
• Industrial Fermentation: Optimization and Scale-up
• Biocatalysis in Pharmaceutical Industry
• Advanced Bioprocess Monitoring and Control
• Green Chemistry: Sustainable Practices in Industry

Emerging Trends in Biotechnology

• CRISPR-Based Diagnostics: A New Era in Disease Detection
• Neurobiotechnology: Advancements in Brain-Computer Interfaces
• Advances in Nanotechnology for Healthcare
• Computational Biology: Modeling Biological Systems
• Organoids: Miniature Organs for Drug Testing
• Genome Editing in Non-Human Organisms
• Biotechnology and the Internet of Things (IoT)
• Exosome-based Therapeutics: Potential Applications
• Biohybrid Systems: Integrating Living and Artificial Components
• Metagenomics: Exploring Microbial Communities

Ethical and Social Implications

• Ethical Considerations in CRISPR-Based Gene Editing
• Privacy Concerns in Personal Genomic Data Sharing
• Biotechnology and Social Equity: Bridging the Gap
• Dual-Use Dilemmas in Biotechnological Research
• Informed Consent in Genetic Testing and Research
• Accessibility of Biotechnological Therapies: Global Perspectives
• Human Enhancement Technologies: Ethical Perspectives
• Biotechnology and Cultural Perspectives on Genetic Modification
• Social Impact Assessment of Biotechnological Interventions
• Intellectual Property Rights in Biotechnology

Computational Biology and Bioinformatics

• Machine Learning in Biomedical Data Analysis
• Network Biology: Understanding Biological Systems
• Structural Bioinformatics: Predicting Protein Structures
• Data Mining in Genomics and Proteomics
• Systems Biology Approaches in Biotechnology
• Comparative Genomics: Evolutionary Insights
• Bioinformatics Tools for Drug Discovery
• Cloud Computing in Biomedical Research
• Artificial Intelligence in Diagnostics and Treatment
• Computational Approaches to Vaccine Design

Health and Medicine

• Vaccines and Immunotherapy: Advancements in Disease Prevention
• CRISPR-Based Therapies for Genetic Disorders
• Infectious Disease Diagnostics Using Biotechnology
• Telemedicine and Biotechnology Integration
• Biotechnology in Rare Disease Research
• Gut Microbiome and Human Health
• Precision Nutrition: Personalized Diets Using Biotechnology
• Biotechnology Approaches to Combat Antibiotic Resistance
• Point-of-Care Diagnostics for Global Health
• Biotechnology in Aging Research and Longevity

Agricultural Biotechnology

• CRISPR and Gene Editing in Crop Improvement
• Precision Agriculture: Integrating Technology for Crop Management
• Biotechnology Solutions for Food Security
• RNA Interference in Pest Control
• Vertical Farming and Biotechnology
• Plant-Microbe Interactions for Sustainable Agriculture
• Biofortification: Enhancing Nutritional Content in Crops
• Smart Farming Technologies and Biotechnology
• Precision Livestock Farming Using Biotechnological Tools
• Drought-Tolerant Crops: Biotechnological Approaches

Biotechnology and Education

• Integrating Biotechnology into STEM Education
• Virtual Labs in Biotechnology Teaching
• Biotechnology Outreach Programs for Schools
• Online Courses in Biotechnology: Accessibility and Quality
• Hands-on Biotechnology Experiments for Students
• Bioethics Education in Biotechnology Programs
• Role of Internships in Biotechnology Education
• Collaborative Learning in Biotechnology Classrooms
• Biotechnology Education for Non-Science Majors
• Addressing Gender Disparities in Biotechnology Education

Funding and Policy

• Government Funding Initiatives for Biotechnology Research
• Private Sector Investment in Biotechnology Ventures
• Impact of Intellectual Property Policies on Biotechnology
• Ethical Guidelines for Biotechnological Research
• Public-Private Partnerships in Biotechnology
• Regulatory Frameworks for Gene Editing Technologies
• Biotechnology and Global Health Policy
• Biotechnology Diplomacy: International Collaboration
• Funding Challenges in Biotechnology Startups
• Role of Nonprofit Organizations in Biotechnological Research

Biotechnology and the Environment

• Biotechnology for Air Pollution Control
• Microbial Sensors for Environmental Monitoring
• Remote Sensing in Environmental Biotechnology
• Climate Change Mitigation Using Biotechnology
• Circular Economy and Biotechnological Innovations
• Marine Biotechnology for Ocean Conservation
• Bio-inspired Design for Environmental Solutions
• Ecological Restoration Using Biotechnological Approaches
• Impact of Biotechnology on Biodiversity
• Biotechnology and Sustainable Urban Development

Biosecurity and Biosafety

• Biosecurity Measures in Biotechnology Laboratories
• Dual-Use Research and Ethical Considerations
• Global Collaboration for Biosafety in Biotechnology
• Security Risks in Gene Editing Technologies
• Surveillance Technologies in Biotechnological Research
• Biosecurity Education for Biotechnology Professionals
• Risk Assessment in Biotechnology Research
• Bioethics in Biodefense Research
• Biotechnology and National Security
• Public Awareness and Biosecurity in Biotechnology

Industry Applications

• Biotechnology in the Pharmaceutical Industry
• Bioprocessing Innovations for Drug Production
• Industrial Enzymes and Their Applications
• Biotechnology in Food and Beverage Production
• Applications of Synthetic Biology in Industry
• Biotechnology in Textile Manufacturing
• Cosmetic and Personal Care Biotechnology
• Biotechnological Approaches in Renewable Energy
• Advanced Materials Production Using Biotechnology
• Biotechnology in the Automotive Industry

Miscellaneous Topics

• DNA Barcoding in Species Identification
• Bioart: The Intersection of Biology and Art
• Biotechnology in Forensic Science
• Using Biotechnology to Preserve Cultural Heritage
• Biohacking: DIY Biology and Citizen Science
• Microbiome Engineering for Human Health
• Environmental DNA (eDNA) for Biodiversity Monitoring
• Biotechnology and Astrobiology: Searching for Life Beyond Earth
• Biotechnology and Sports Science
• Biotechnology and the Future of Space Exploration

Challenges and Ethical Considerations in Biotechnology Research

As biotechnology continues to advance, it brings forth a set of challenges and ethical considerations. Biosecurity concerns, especially in the context of gene editing technologies, raise questions about the responsible use of powerful tools like CRISPR. 

Ethical implications of genetic manipulation, such as the creation of designer babies, demand careful consideration and international collaboration to establish guidelines and regulations. 

Moreover, the environmental and social impact of biotechnological interventions must be thoroughly assessed to ensure responsible and sustainable practices.

Funding and Resources for Biotechnology Research

The pursuit of biotechnology research topics requires substantial funding and resources. Government grants and funding agencies play a pivotal role in supporting research initiatives. 

Simultaneously, the private sector, including biotechnology companies and venture capitalists, invest in promising projects. Collaboration and partnerships between academia, industry, and nonprofit organizations further amplify the impact of biotechnological research.

Future Prospects of Biotechnology Research

As we look to the future, the integration of biotechnology with other scientific disciplines holds immense potential. Collaborations with fields like artificial intelligence, materials science, and robotics may lead to unprecedented breakthroughs. 

The development of innovative technologies and their application to global health and sustainability challenges will likely shape the future of biotechnology.

In conclusion, biotechnology research is a dynamic and transformative force with the potential to revolutionize multiple facets of our lives. The exploration of diverse biotechnology research topics, from genetic engineering to emerging trends like synthetic biology and nanobiotechnology, highlights the breadth of possibilities within this field. 

However, researchers must navigate challenges and ethical considerations to ensure that biotechnological advancements are used responsibly for the betterment of society. 

With continued funding, collaboration, and a commitment to ethical practices, the future of biotechnology research holds exciting promise, propelling us towards a more sustainable and technologically advanced world.

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Top 50 Research Topics in Biotechnology

Table of Contents

Biotechnology

Research in biotechnology can helps in bringing massive changes in humankind and lead to a better life. In the last few years, there have been so many leaps, and paces of innovations as scientists worldwide worked to develop and produce novel mRNA vaccinations and brought some significant developments in biotechnology. During this period, they also faced many challenges. Disturbances in the supply chain and the pandemic significantly impacted biotech labs and researchers, forcing lab managers to become ingenious in buying lab supplies, planning experiments, and using technology for maintaining research schedules.

At the beginning of 2022, existing biotech research projects are discovering progress in medicines, vaccines, disease treatment and the human body, immunology, and some viruses such as coronavirus that had such a destructive impact that we could never have expected.

The Biotech Research Technique is changing

How research is being done is changing, as also how scientists are conducting it. Affected by both B2C eCommerce and growing independence in remote and cloud-dependent working, most of the biotechnology labs are going through some digital transformations. This implies more software, automation, and AI in the biotech lab, along with some latest digital procurement plans and integrated systems for various lab operations.

In this article, we’ll discuss research topics in biotechnology for students, biotechnology project topics, biotechnology research topics for undergraduates, biotechnology thesis topics, biotechnology research topics for college students, biotechnology research paper topics, biotechnology dissertation topics, biotechnology project ideas for high school, medical biotechnology topics for presentation, research topics for life science , research topics on biotechnology , medical biotechnology topics, recent research topics in biotechnology, mini project ideas for biotechnology, pharmaceutical biotechnology topics, plant biotechnology research topics, research topics in genetics and biotechnology, final year project topics for biotechnology, biotech research project ideas, health biotechnology topics, industrial biotechnology topics, agricultural biotechnology project topics and biology thesis topics.

Look at some of the top trends in biotech research and recent Biotechnology Topics that are bringing massive changes in this vast world of science, resulting in some innovation in life sciences and biotechnology ideas .

• Development of vaccine: Development of mRNA has been done since 1989 but has accelerated to combat the pandemic. As per many researchers, mRNA vaccines can change infectious disease control as it is a prophylactic means of disease prevention for various diseases such as flu, HIV, etc.
• Respiratory viruses: More and more research is being done because understanding those viruses will assist in getting better protection, prohibition, and promising treatments for respiratory viruses.
• Microvesicles and extracellular vesicles are now being focused on because of their involvement in the transportation of mRNA, miRNA, and proteins. But in what other ways can they give support to the human body? So many unknown roles of microvesicles and extracellular vesicles should be discovered.
• RNA-based Therapeutics: Researchers focus on RNA-based therapeutics such as CAR T cells, other gene/cell therapeutics, small molecular drugs to treat more diseases and other prophylactic purposes.
• Metabolism in cancers and other diseases: Metabolism helps convert energy and represent the chemical reactions that will sustain life. Nowadays, research is being done to study metabolism in cancers and immune cells to uncover novel ways to approach treatment and prohibition of a specific illness.

All of the ongoing research keeps the potential to bring changes in the quality of life of millions of people, prohibit and do treatment of illnesses that at present have a very high rate of mortality, and change healthcare across the world.

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Top 50 Emerging Research Topics in Biotechnology

Trending Research Topics in Biotechnology

Table of contents

A. crispr and gene editing, b. synthetic biology, a. precision medicine, b. pharmacogenomics, a. nanoparticles in medicine, b. nanosensors and diagnostics, a. cancer immunotherapy, b. vaccine technology, a. bioremediation and bioenergy, b. agricultural biotechnology.

Biotechnology is a dynamic field that continuously shapes our world, enabling innovation, breakthroughs, and solutions to various challenges. As we move into the future, numerous emerging research areas promise to revolutionize healthcare, agriculture, environmental sustainability, and more. The top 50 emerging research topics in biotechnology are presented in this article.

1. Gene Editing and Genomic Engineering

Precision Medicine : Developing targeted therapies for various diseases using CRISPR/Cas9 and other gene-editing tools.

Ethical Implications : Exploring and addressing ethical concerns surrounding CRISPR use in human embryos and germline editing.

Agricultural Advancements : Enhancing crop resistance and nutritional content through gene editing of improved farm outcomes.

Gene Drive Technology : Investigating the potential of gene drive technology to control vector-borne diseases like malaria and dengue fever.

Regulatory Frameworks : Establishing global regulations for responsible gene editing applications in different fields.

Bioengineering Microbes : Creating engineered microorganisms for sustainable production of fuels, pharmaceuticals, and materials.

Designer Organisms : Designing novel organisms with specific functionalities for environmental remediation or industrial processes.

Cell-Free Systems : Developing cell-free systems for various applications, including drug production and biosensors.

Biosecurity Measures : Addressing concerns regarding the potential misuse of synthetic biology for bioterrorism.

Standardization and Automation : Standardizing synthetic biology methodologies and automating processes to streamline production.

2. Personalized Medicine and Pharmacogenomics

Individualized Treatment : Tailoring medical treatment based on a person’s genetic makeup and environmental factors.

Cancer Therapy : Advancing targeted cancer therapies based on the genetic profile of tumors and patients.

Data Analytics : Implementing big data and AI for comprehensive analysis of genomic and clinical data to improve treatment outcomes.

Clinical Implementation : Integrating genetic testing into routine clinical practice for personalized healthcare.

Public Health and Policy : Addressing the challenges of integrating personalized medicine into public health policies and practices.

Drug Development : Optimizing drug development based on individual genetic variations to improve efficacy and reduce side effects.

Adverse Drug Reactions : Understanding genetic predispositions to adverse drug reactions and minimizing risks.

Dosing Optimization : Tailoring drug dosage based on an individual’s genetic profile for better treatment outcomes.

Economic Implications : Assessing the economic impact of pharmacogenomics on healthcare systems.

Education and Training : Educating healthcare professionals on integrating pharmacogenomic data into clinical practice.

3. Nanobiotechnology and Nanomedicine

Drug Delivery Systems : Developing targeted drug delivery systems using nanoparticles for enhanced efficacy and reduced side effects.

Theranostics : Integrating diagnostics and therapeutics through nanomaterials for personalized medicine.

Imaging Techniques : Advancing imaging technologies using nanoparticles for better resolution and early disease detection.

Biocompatibility and Safety : Ensuring the safety and biocompatibility of nanoparticles used in medicine.

Regulatory Frameworks : Establishing regulations for the use of nanomaterials in medical applications.

Point-of-Care Diagnostics : Developing portable and rapid diagnostic tools for various diseases using nanotechnology.

Biosensors : Creating highly sensitive biosensors for detecting biomarkers and pathogens in healthcare and environmental monitoring.

Wearable Health Monitors : Integrating nanosensors into wearable devices for continuous health monitoring.

Challenges and Limitations : Addressing challenges in scalability, reproducibility, and cost-effectiveness of nanosensor technologies.

Future Applications : Exploring potential applications of nanosensors beyond healthcare, such as environmental monitoring and food safety.

4. Immunotherapy and Vaccine Development

Immune Checkpoint Inhibitors : Enhancing the efficacy of immune checkpoint inhibitors and understanding resistance mechanisms.

CAR-T Cell Therapy : Improving CAR-T cell therapy for a wider range of cancers and reducing associated side effects.

Combination Therapies : Investigating combination therapies for better outcomes in cancer treatment.

Biomarkers and Predictive Models : Identifying predictive biomarkers for immunotherapy response.

Long-Term Effects : Studying the long-term effects and immune-related adverse events of immunotherapies.

mRNA Vaccines : Advancing mRNA vaccine technology for various infectious diseases and cancers.

Universal Vaccines : Developing universal vaccines targeting multiple strains of viruses and bacteria.

Vaccine Delivery Systems : Innovating vaccine delivery methods for improved stability and efficacy.

Vaccine Hesitancy : Addressing vaccine hesitancy through education, communication, and community engagement.

Pandemic Preparedness : Developing strategies for rapid vaccine development and deployment during global health crises.

5. Environmental Biotechnology and Sustainability

Biodegradation Techniques : Using biotechnology to enhance the degradation of pollutants and contaminants in the environment.

Biofuels : Developing sustainable biofuel production methods from renewable resources.

Microbial Fuel Cells : Harnessing microbial fuel cells for energy generation from organic waste.

Circular Economy : Integrating biotechnological solutions for a circular economy and waste management.

Ecosystem Restoration : Using biotechnology for the restoration of ecosystems affected by pollution and climate change.

Genetically Modified Crops : Advancing genetically modified crops for improved yields, pest resistance, and nutritional content.

Precision Agriculture : Implementing biotechnological tools for precise and sustainable farming practices.

Climate-Resilient Crops : Developing crops resilient to climate change-induced stresses.

Micro-biome Applications : Leveraging the plant micro-biome for enhanced crop health and productivity.

Consumer Acceptance and Regulation : Addressing consumer concerns and regulatory challenges related to genetically modified crops.

The field of biotechnology is a beacon of hope for addressing the challenges of our time, offering promising solutions for healthcare, sustainability, and more. As researchers explore these emerging topics, the potential for ground-breaking discoveries and transformative applications is immense.

I hope this article will help you to find the top research topics in biotechnology that promise to revolutionize healthcare, agriculture, environmental sustainability, and more.

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Research Topics & Ideas

Biotechnology and Genetic Engineering

If you’re just starting out exploring biotechnology-related topics for your dissertation, thesis or research project, you’ve come to the right place. In this post, we’ll help kickstart your research topic ideation process by providing a hearty list of research topics and ideas , including examples from recent studies.

PS – This is just the start…

We know it’s exciting to run through a list of research topics, but please keep in mind that this list is just a starting point . To develop a suitable research topic, you’ll need to identify a clear and convincing research gap , and a viable plan  to fill that gap.

If this sounds foreign to you, check out our free research topic webinar that explores how to find and refine a high-quality research topic, from scratch. Alternatively, if you’d like hands-on help, consider our 1-on-1 coaching service .

Biotechnology Research Topic Ideas

Below you’ll find a list of biotech and genetic engineering-related research topics ideas. These are intentionally broad and generic , so keep in mind that you will need to refine them a little. Nevertheless, they should inspire some ideas for your project.

• Developing CRISPR-Cas9 gene editing techniques for treating inherited blood disorders.
• The use of biotechnology in developing drought-resistant crop varieties.
• The role of genetic engineering in enhancing biofuel production efficiency.
• Investigating the potential of stem cell therapy in regenerative medicine for spinal cord injuries.
• Developing gene therapy approaches for the treatment of rare genetic diseases.
• The application of biotechnology in creating biodegradable plastics from plant materials.
• The use of gene editing to enhance nutritional content in staple crops.
• Investigating the potential of microbiome engineering in treating gastrointestinal diseases.
• The role of genetic engineering in vaccine development, with a focus on mRNA vaccines.
• Biotechnological approaches to combat antibiotic-resistant bacteria.
• Developing genetically engineered organisms for bioremediation of polluted environments.
• The use of gene editing to create hypoallergenic food products.
• Investigating the role of epigenetics in cancer development and therapy.
• The application of biotechnology in developing rapid diagnostic tools for infectious diseases.
• Genetic engineering for the production of synthetic spider silk for industrial use.
• Biotechnological strategies for improving animal health and productivity in agriculture.
• The use of gene editing in creating organ donor animals compatible with human transplantation.
• Developing algae-based bioreactors for carbon capture and biofuel production.
• The role of biotechnology in enhancing the shelf life and quality of fresh produce.
• Investigating the ethics and social implications of human gene editing technologies.
• The use of CRISPR technology in creating models for neurodegenerative diseases.
• Biotechnological approaches for the production of high-value pharmaceutical compounds.
• The application of genetic engineering in developing pest-resistant crops.
• Investigating the potential of gene therapy in treating autoimmune diseases.
• Developing biotechnological methods for producing environmentally friendly dyes.

Biotech & GE Research Topic Ideas (Continued)

• The use of genetic engineering in enhancing the efficiency of photosynthesis in plants.
• Biotechnological innovations in creating sustainable aquaculture practices.
• The role of biotechnology in developing non-invasive prenatal genetic testing methods.
• Genetic engineering for the development of novel enzymes for industrial applications.
• Investigating the potential of xenotransplantation in addressing organ donor shortages.
• The use of biotechnology in creating personalised cancer vaccines.
• Developing gene editing tools for combating invasive species in ecosystems.
• Biotechnological strategies for improving the nutritional quality of plant-based proteins.
• The application of genetic engineering in enhancing the production of renewable energy sources.
• Investigating the role of biotechnology in creating advanced wound care materials.
• The use of CRISPR for targeted gene activation in regenerative medicine.
• Biotechnological approaches to enhancing the sensory qualities of plant-based meat alternatives.
• Genetic engineering for improving the efficiency of water use in agriculture.
• The role of biotechnology in developing treatments for rare metabolic disorders.
• Investigating the use of gene therapy in age-related macular degeneration.
• The application of genetic engineering in developing allergen-free nuts.
• Biotechnological innovations in the production of sustainable and eco-friendly textiles.
• The use of gene editing in studying and treating sleep disorders.
• Developing biotechnological solutions for the management of plastic waste.
• The role of genetic engineering in enhancing the production of essential vitamins in crops.
• Biotechnological approaches to the treatment of chronic pain conditions.
• The use of gene therapy in treating muscular dystrophy.
• Investigating the potential of biotechnology in reversing environmental degradation.
• The application of genetic engineering in improving the shelf life of vaccines.
• Biotechnological strategies for enhancing the efficiency of mineral extraction in mining.

Recent Biotech & GE-Related Studies

While the ideas we’ve presented above are a decent starting point for finding a research topic in biotech, they are fairly generic and non-specific. So, it helps to look at actual studies in the biotech space to see how this all comes together in practice.

Below, we’ve included a selection of recent studies to help refine your thinking. These are actual studies,  so they can provide some useful insight as to what a research topic looks like in practice.

• Genetic modifications associated with sustainability aspects for sustainable developments (Sharma et al., 2022)
• Review On: Impact of Genetic Engineering in Biotic Stresses Resistance Crop Breeding (Abebe & Tafa, 2022)
• Biorisk assessment of genetic engineering — lessons learned from teaching interdisciplinary courses on responsible conduct in the life sciences (Himmel et al., 2022)
• Genetic Engineering Technologies for Improving Crop Yield and Quality (Ye et al., 2022)
• Legal Aspects of Genetically Modified Food Product Safety for Health in Indonesia (Khamdi, 2022)
• Innovative Teaching Practice and Exploration of Genetic Engineering Experiment (Jebur, 2022)
• Efficient Bacterial Genome Engineering throughout the Central Dogma Using the Dual-Selection Marker tetAOPT (Bayer et al., 2022)
• Gene engineering: its positive and negative effects (Makrushina & Klitsenko, 2022)
• Advances of genetic engineering in streptococci and enterococci (Kurushima & Tomita, 2022)
• Genetic Engineering of Immune Evasive Stem Cell-Derived Islets (Sackett et al., 2022)
• Establishment of High-Efficiency Screening System for Gene Deletion in Fusarium venenatum TB01 (Tong et al., 2022)
• Prospects of chloroplast metabolic engineering for developing nutrient-dense food crops (Tanwar et al., 2022)
• Genetic research: legal and ethical aspects (Rustambekov et al., 2023). Non-transgenic Gene Modulation via Spray Delivery of Nucleic Acid/Peptide Complexes into Plant Nuclei and Chloroplasts (Thagun et al., 2022)
• The role of genetic breeding in food security: A review (Sam et al., 2022). Biotechnology: use of available carbon sources on the planet to generate alternatives energy (Junior et al., 2022)
• Biotechnology and biodiversity for the sustainable development of our society (Jaime, 2023) Role Of Biotechnology in Agriculture (Shringarpure, 2022)
• Plants That Can be Used as Plant-Based Edible Vaccines; Current Situation and Recent Developments (İsmail, 2022)

As you can see, these research topics are a lot more focused than the generic topic ideas we presented earlier. So, in order for you to develop a high-quality research topic, you’ll need to get specific and laser-focused on a specific context with specific variables of interest.  In the video below, we explore some other important things you’ll need to consider when crafting your research topic.

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If you’re still unsure about how to find a quality research topic, check out our Research Topic Kickstarter service, which is the perfect starting point for developing a unique, well-justified research topic.

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Open Access

The future is bright, the future is biotechnology

* E-mail: [email protected]

Affiliation Public Library of Science, San Francisco, California, United States of America and Cambridge, United Kingdom

• Richard Hodge, 
• on behalf of the PLOS Biology staff editors

Published: April 28, 2023

• https://doi.org/10.1371/journal.pbio.3002135
• Reader Comments

As PLOS Biology celebrates its 20 th anniversary, our April issue focuses on biotechnology with articles covering different aspects of the field, from genome editing to synthetic biology. With them, we emphasize our interest in expanding our presence in biotechnology research.

Citation: Hodge R, on behalf of the PLOS Biology staff editors (2023) The future is bright, the future is biotechnology. PLoS Biol 21(4): e3002135. https://doi.org/10.1371/journal.pbio.3002135

Copyright: © 2023 Hodge, on behalf of the PLOS Biology staff editors. This is an open access article distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: The authors received no specific funding for this work.

Competing interests: The authors have declared that no competing interests exist.

The PLOS Biology Staff Editors are Ines Alvarez-Garcia, Joanna Clarke, RichardHodge, Paula Jauregui, Nonia Pariente, Roland Roberts, and Lucas Smith.

This article is part of the PLOS Biology 20th Anniversary Collection.

Biotechnology is a revolutionary branch of science at the forefront of research and innovation that has advanced rapidly in recent years. It is a broad discipline, in which organisms or biological processes are exploited to develop new technologies that have the potential to transform the way we live and work, as well as to boost sustainability and industrial productivity. The new tools and products being generated have a wide range of applications across various sectors, including medicine, agriculture, energy, manufacturing and food.

PLOS Biology has traditionally published research reporting significant advances across a wide range of biological disciplines. However, our scope must continue to evolve as biology increasingly becomes more and more applied, generating technologies with potentially game-changing therapeutic and environmental impact. To that end, we recently published a collection of magazine articles focused on ideas for green biotechnologies that could have an important role in a sustainable future [ 1 ], including how to harness microbial photosynthesis to directly generate electricity [ 2 ] and using microbes to develop carbon “sinks” in the mining industry [ 3 ]. Moreover, throughout this anniversary year we are publishing Perspective articles that take stock of the past 20 years of biological research in a specific field and look forward to what is to come in the next 20 years [ 4 ]; in this issue, these Perspectives focus on different aspects of the broad biotechnology field—synthetic biology [ 5 ] and the use of lipid nanoparticles (LNPs) for the delivery of therapeutics [ 6 ].

One fast moving area within biotechnology is gene editing therapy, which involves the alteration of DNA to treat or prevent disease using techniques such as CRISPR-Cas9 and base editors that enable precise genetic modifications to be made. This approach shows great promise for treating a variety of genetic diseases. Excitingly, promising phase I results of the first in vivo genome editing clinical trial to treat several liver-related diseases were reported at the recent Keystone Symposium on Precision Genome Engineering. This issue of PLOS Biology includes an Essay from Porto and Komor that focuses on the clinical applications of base editor technology [ 7 ], which could enable chronic diseases to be treated with a ‘one-and-done’ therapy, and a Perspective from Hamilton and colleagues that outlines the advances in the development of LNPs for the delivery of nucleic acid-based therapeutics [ 6 ]. LNPs are commonly used as vehicles for the delivery of such therapeutics because they have a low immunogenicity and can be manufactured at scale. However, expanding the toolbox of delivery platforms for these novel therapeutics will be critical to realise their full clinical potential.

Synthetic biology is also a rapidly growing area, whereby artificial or existing biological systems are designed to produce products or enhance cellular function. By using CRISPR to edit genes involved in metabolic pathways, researchers can create organisms that produce valuable compounds such as biofuels, drugs, and industrial chemicals. In their Perspective, Kitano and colleagues take stock of the technological advances that have propelled the “design-build-test-learn” cycle methodology forward in synthetic biology, as well as focusing on how machine-learning approaches can remove the bottlenecks in these pipelines [ 5 ].

While the potential of these technologies is vast, there are also concerns about their safety and ethical implications. Gene editing, in particular, raises ethical concerns, as it could be used to create so-called “designer babies” with specific traits or to enhance physical or mental capabilities. There are also concerns about the unintended consequences of gene editing, such as off-target effects that could cause unintended harm. These technologies can be improved by better understanding the interplay between editing tools and DNA repair pathways, and it will be essential for scientists and policymakers to be cautious and work together to establish guidelines and regulations for their use, as outlined at the recent International Summit on Human Genome Editing .

Basic research has also benefitted from biotechnological developments. For instance, methodological developments in super-resolution microscopy offer researchers the ability to image cells at exquisite detail and answer previously inaccessible research questions. Sequencing technologies such as Nanopore sequencers are revolutionising the ability to sequence long DNA/RNA reads in real time and in the field. Great strides have also been made in the development of analysis software for structural biology purposes, such as sub-tomogram averaging for cryo-EM [ 8 ]. The rate of scientific discovery is now at an unprecedented level in this age of big data as a result of these huge technological leaps.

The past few years has also seen the launch of AI tools such as ChatGPT. While these tools are increasingly being used to help write students homework or to improve the text of scientific papers, generative AI tools hold the potential to transform research and development in the biotechnology industry. The recently developed language model ProGen can generate and then predict function in protein sequences [ 9 ], and these models can also be used to find therapeutically relevant compounds for drug discovery. Protein structure prediction programs, such as AlphaFold [ 10 ] and RosettaFold, have revolutionized structural biology and can be used for a myriad of purposes. We have recently published several papers that have utilized AlphaFold models to develop methods that determine the structural context of post-translational modifications [ 11 ] and predict autophagy-related motifs in proteins [ 12 ].

The future of biotechnology is clearly very promising and we look forward to being part of the dissemination of these important new developments. Open access science sits at the core of our mission and the publication of these novel technologies in PLOS Biology can help their widespread adoption and ensure global access. As we look forward during this year of celebration, we are excited that biotechnology research will continue to grow and become a central part of the journal. The future is bright and the future is very much biotechnology.

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Biotechnology Research Paper Topics

This collection of biotechnology research paper topics provides the list of 10 potential topics for research papers and overviews the history of biotechnology.

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Get 10% off with 24start discount code, 1. animal breeding: genetic methods.

Modern animal breeding relies on scientific methods to control production of domesticated animals, both livestock and pets, which exhibit desired physical and behavioral traits. Genetic technology aids animal breeders to attain nutritional, medical, recreational, and fashion standards demanded by consumers for animal products including meat, milk, eggs, leather, wool, and pharmaceuticals. Animals are also genetically designed to meet labor and sporting requirements for speed and endurance, conformation and beauty ideals to win show competitions, and intelligence levels to perform obediently at tasks such as herding, hunting, and tracking. By the late twentieth century, genetics and mathematical models were appropriated to identify the potential of immature animals. DNA markers indicate how young animals will mature, saving breeders money by not investing in animals lacking genetic promise. Scientists also successfully transplanted sperm-producing stem cells with the goal of restoring fertility to barren breeding animals. At the National Animal Disease Center in Ames, Iowa, researchers created a gene-based test, which uses a cloned gene of the organism that causes Johne’s disease in cattle in order to detect that disease to avert epidemics. Researchers also began mapping the dog genome and developing molecular techniques to evaluate canine chromosomes in the Quantitative Trait Loci (QTL). Bioinformatics incorporates computers to analyze genetic material. Some tests were developed to diagnose many of several hundred genetic canine diseases including hip dysplasia and progressive retinal atrophy (PRA). A few breed organizations modified standards to discourage breeding of genetically flawed animals and promote heterozygosity.

2. Antibacterial Chemotherapy

In the early years of the twentieth century, the search for agents that would be effective against internal infections proceeded along two main routes. The first was a search for naturally occurring substances that were effective against microorganisms (antibiosis). The second was a search for chemicals that would have the same effect (chemotherapy). Despite the success of penicillin in the 1940s, the major early advances in the treatment of infection occurred not through antibiosis but through chemotherapy. The principle behind chemotherapy was that there was a relationship between chemical structure and pharmacological action. The founder of this concept was Paul Erhlich (1854–1915). An early success came in 1905 when atoxyl (an organic arsenic compound) was shown to destroy trypanosomes, the microbes that caused sleeping sickness. Unfortunately, atoxyl also damaged the optic nerve. Subsequently, Erhlich and his co-workers synthesized and tested hundreds of related arsenic compounds. Ehrlich was a co-recipient (with Ilya Ilyich Mechnikov) of the Nobel Prize in medicine in 1908 for his work on immunity. Success in discovering a range of effective antibacterial drugs had three important consequences: it brought a range of important diseases under control for the first time; it provided a tremendous stimulus to research workers and opened up new avenues of research; and in the resulting commercial optimism, it led to heavy postwar investment in the pharmaceutical industry. The therapeutic revolution had begun.

3. Artificial Insemination and in Vitro Fertilization

Artificial insemination (AI) involves the extraction and collection of semen together with techniques for depositing semen in the uterus in order to achieve successful fertilization and pregnancy. Throughout the twentieth century, the approach has offered animal breeders the advantage of being able to utilize the best available breeding stock and at the correct time within the female reproductive cycle, but without the limitations of having the animals in the same location. AI has been applied most intensively within the dairy and beef cattle industries and to a lesser extent horse breeding and numerous other domesticated species.

Many of the techniques involved in artificial insemination would lay the foundation for in vitro fertilization (IVF) in the latter half of the twentieth century. IVF refers to the group of technologies that allow fertilization to take place outside the body involving the retrieval of ova or eggs from the female and sperm from the male, which are then combined in artificial, or ‘‘test tube,’’ conditions leading to fertilization. The fertilized eggs then continue to develop for several days ‘‘in culture’’ until being transferred to the female recipient to continue developing within the uterus.

4. Biopolymers

Biopolymers are natural polymers, long-chained molecules (macromolecules) consisting mostly of a repeated composition of building blocks or monomers that are formed and utilized by living organisms. Each group of biopolymers is composed of different building blocks, for example chains of sugar molecules form starch (a polysaccharide), chains of amino acids form proteins and peptides, and chains of nucleic acid form DNA and RNA (polynucleotides). Biopolymers can form gels, fibers, coatings, and films depending on the specific polymer, and serve a variety of critical functions for cells and organisms. Proteins including collagens, keratins, silks, tubulins, and actin usually form structural composites or scaffolding, or protective materials in biological systems (e.g., spider silk). Polysaccharides function in molecular recognition at cell membrane surfaces, form capsular barrier layers around cells, act as emulsifiers and adhesives, and serve as skeletal or architectural materials in plants. In many cases these polymers occur in combination with proteins to form novel composite structures such as invertebrate exoskeletons or microbial cell walls, or with lignin in the case of plant cell walls.

The use of the word ‘‘cloning’’ is fraught with confusion and inconsistency, and it is important at the outset of this discussion to offer definitional clarification. For instance, in the 1997 article by Ian Wilmut and colleagues announcing the birth of the first cloned adult vertebrate (a ewe, Dolly the sheep) from somatic cell nuclear transfer, the word clone or cloning was never used, and yet the announcement raised considerable disquiet about the prospect of cloned human beings. In a desire to avoid potentially negative forms of language, many prefer to substitute ‘‘cell expansion techniques’’ or ‘‘therapeutic cloning’’ for cloning. Cloning has been known for centuries as a horticultural propagation method: for example, plants multiplied by grafting, budding, or cuttings do not differ genetically from the original plant. The term clone entered more common usage as a result of a speech in 1963 by J.B.S. Haldane based on his paper, ‘‘Biological possibilities for the human species of the next ten-thousand years.’’ Notwithstanding these notes of caution, we can refer to a number of processes as cloning. At the close of the twentieth century, such techniques had not yet progressed to the ability to bring a cloned human to full development; however, the ability to clone cells from an adult human has potential to treat diseases. International policymaking in the late 1990s sought to distinguish between the different end uses for somatic cell nuclear transfer resulting in the widespread adoption of the distinction between ‘‘reproductive’’ and ‘‘therapeutic’’ cloning. The function of the distinction has been to permit the use (in some countries) of the technique to generate potentially beneficial therapeutic applications from embryonic stem cell technology whilst prohibiting its use in human reproduction. In therapeutic applications, nuclear transfer from a patient’s cells into an enucleated ovum is used to create genetically identical embryos that would be grown in vitro but not be allowed to continue developing to become a human being. The resulting cloned embryos could be used as a source from which to produce stem cells that can then be induced to specialize into the specific type of tissue required by the patient (such as skin for burns victims, brain neuron cells for Parkinson’s disease sufferers, or pancreatic cells for diabetics). The rationale is that because the original nuclear material is derived from a patient’s adult tissue, the risks of rejection of such cells by the immune system are reduced.

6. Gene Therapy

In 1971, Australian Nobel laureate Sir F. MacFarlane Burnet thought that gene therapy (introducing genes into body tissue, usually to treat an inherited genetic disorder) looked more and more like a case of the emperor’s new clothes. Ethical issues aside, he believed that practical considerations forestalled possibilities for any beneficial gene strategy, then or probably ever. Bluntly, he wrote: ‘‘little further advance can be expected from laboratory science in the handling of ‘intrinsic’ types of disability and disease.’’ Joshua Lederberg and Edward Tatum, 1958 Nobel laureates, theorized in the 1960s that genes might be altered or replaced using viral vectors to treat human diseases. Stanfield Rogers, working from the Oak Ridge National Laboratory in 1970, had tried but failed to cure argininemia (a genetic disorder of the urea cycle that causes neurological damage in the form of mental retardation, seizures, and eventually death) in two German girls using Swope papilloma virus. Martin Cline at the University of California in Los Angeles, made the second failed attempt a decade later. He tried to correct the bone marrow cells of two beta-thalassemia patients, one in Israel and the other in Italy. What Cline’s failure revealed, however, was that many researchers who condemned his trial as unethical were by then working toward similar goals and targeting different diseases with various delivery methods. While Burnet’s pessimism finally proved to be wrong, progress in gene therapy was much slower than antibiotic or anticancer chemotherapy developments over the same period of time. While gene therapy had limited success, it nevertheless remained an active area for research, particularly because the Human Genome Project, begun in 1990, had resulted in a ‘‘rough draft’’ of all human genes by 2001, and was completed in 2003. Gene mapping created the means for analyzing the expression patterns of hundreds of genes involved in biological pathways and for identifying single nucleotide polymorphisms (SNPs) that have diagnostic and therapeutic potential for treating specific diseases in individuals. In the future, gene therapies may prove effective at protecting patients from adverse drug reactions or changing the biochemical nature of a person’s disease. They may also target blood vessel formation in order to prevent heart disease or blindness due to macular degeneration or diabetic retinopathy. One of the oldest ideas for use of gene therapy is to produce anticancer vaccines. One method involves inserting a granulocyte-macrophage colony-stimulating factor gene into prostate tumor cells removed in surgery. The cells then are irradiated to prevent any further cancer and injected back into the same patient to initiate an immune response against any remaining metastases. Whether or not such developments become a major treatment modality, no one now believes, as MacFarland Burnet did in 1970, that gene therapy science has reached an end in its potential to advance health.

7. Genetic Engineering

The term ‘‘genetic engineering’’ describes molecular biology techniques that allow geneticists to analyze and manipulate deoxyribonucleic acid (DNA). At the close of the twentieth century, genetic engineering promised to revolutionize many industries, including microbial biotechnology, agriculture, and medicine. It also sparked controversy over potential health and ecological hazards due to the unprecedented ability to bypass traditional biological reproduction.

For centuries, if not millennia, techniques have been employed to alter the genetic characteristics of animals and plants to enhance specifically desired traits. In a great many cases, breeds with which we are most familiar bear little resemblance to the wild varieties from which they are derived. Canine breeds, for instance, have been selectively tailored to changing esthetic tastes over many years, altering their appearance, behavior and temperament. Many of the species used in farming reflect long-term alterations to enhance meat, milk, and fleece yields. Likewise, in the case of agricultural varieties, hybridization and selective breeding have resulted in crops that are adapted to specific production conditions and regional demands. Genetic engineering differs from these traditional methods of plant and animal breeding in some very important respects. First, genes from one organism can be extracted and recombined with those of another (using recombinant DNA, or rDNA, technology) without either organism having to be of the same species. Second, removing the requirement for species reproductive compatibility, new genetic combinations can be produced in a much more highly accelerated way than before. Since the development of the first rDNA organism by Stanley Cohen and Herbert Boyer in 1973, a number of techniques have been found to produce highly novel products derived from transgenic plants and animals.

At the same time, there has been an ongoing and ferocious political debate over the environmental and health risks to humans of genetically altered species. The rise of genetic engineering may be characterized by developments during the last three decades of the twentieth century.

8. Genetic Screening and Testing

The menu of genetic screening and testing technologies now available in most developed countries increased rapidly in the closing years of the twentieth century. These technologies emerged within the context of rapidly changing social and legal contexts with regard to the medicalization of pregnancy and birth and the legalization of abortion. The earliest genetic screening tests detected inborn errors of metabolism and sex-linked disorders. Technological innovations in genomic mapping and DNA sequencing, together with an explosion in research on the genetic basis of disease which culminated in the Human Genome Project (HGP), led to a range of genetic screening and testing for diseases traditionally recognized as genetic in origin and for susceptibility to more common diseases such as certain types of familial cancer, cardiac conditions, and neurological disorders among others. Tests were also useful for forensic, or nonmedical, purposes. Genetic screening techniques are now available in conjunction with in vitro fertilization and other types of reproductive technologies, allowing the screening of fertilized embryos for certain genetic mutations before selection for implantation. At present selection is purely on disease grounds and selection for other traits (e.g., for eye or hair color, intelligence, height) cannot yet be done, though there are concerns for eugenics and ‘‘designer babies.’’ Screening is available for an increasing number of metabolic diseases through tandem mass spectrometry, which uses less blood per test, allows testing for many conditions simultaneously, and has a very low false-positive rate as compared to conventional Guthrie testing. Finally, genetic technologies are being used in the judicial domain for determination of paternity, often associated with child support claims, and for forensic purposes in cases where DNA material is available for testing.

9. Plant Breeding: Genetic Methods

The cultivation of plants is the world’s oldest biotechnology. We have continually tried to produce improved varieties while increasing yield, features to aid cultivation and harvesting, disease, and pest resistance, or crop qualities such as longer postharvest storage life and improved taste or nutritional value. Early changes resulted from random crosspollination, rudimentary grafting, or spontaneous genetic change. For centuries, man kept the seed from the plants with improved characteristics to plant the following season’s crop. The pioneering work of Gregor Mendel and his development of the basic laws of heredity showed for other first time that some of the processes of heredity could be altered by experimental means. The genetic analysis of bacterial (prokaryote) genes and techniques for analysis of the higher (eukaryotic) organisms such as plants developed in parallel streams, but the rediscovery of Mendel’s work in 1900 fueled a burst of activity on understanding the role of genes in inheritance. The knowledge that genes are linked along the chromosome thereby allowed mapping of genes (transduction analysis, conjugation analysis, and transformation analysis). The power of genetics to produce a desirable plant was established, and it was appreciated that controlled breeding (test crosses and back crosses) and careful analysis of the progeny could distinguish traits that were dominant or recessive, and establish pure breeding lines. Traditional horticultural techniques of artificial self-pollination and cross-pollination were also used to produce hybrids. In the 1930s the Russian Nikolai Vavilov recognized the value of genetic diversity in domesticated crop plants and their wild relatives to crop improvement, and collected seeds from the wild to study total genetic diversity and use these in breeding programs. The impact of scientific crop breeding was established by the ‘‘Green revolution’’ of the 1960s, when new wheat varieties with higher yields were developed by careful crop breeding. ‘‘Mutation breeding’’— inducing mutations by exposing seeds to x-rays or chemicals such as sodium azide, accelerated after World War II. It was also discovered that plant cells and tissues grown in tissue culture would mutate rapidly. In the 1970s, haploid breeding, which involves producing plants from two identical sets of chromosomes, was extensively used to create new cultivars. In the twenty-first century, haploid breeding could speed up plant breeding by shortening the breeding cycle.

10. Tissue Culturing

The technique of tissue or cell culture, which relates to the growth of tissue or cells within a laboratory setting, underlies a phenomenal proportion of biomedical research. Though it has roots in the late nineteenth century, when numerous scientists tried to grow samples in alien environments, cell culture is credited as truly beginning with the first concrete evidence of successful growth in vitro, demonstrated by Johns Hopkins University embryologist Ross Harrison in 1907. Harrison took sections of spinal cord from a frog embryo, placed them on a glass cover slip and bathed the tissue in a nutrient media. The results of the experiment were startling—for the first time scientists visualized actual nerve growth as it would happen in a living organism—and many other scientists across the U.S. and Europe took up culture techniques. Rather unwittingly, for he was merely trying to settle a professional dispute regarding the origin of nerve fibers, Harrison fashioned a research tool that has since been designated by many as the greatest advance in medical science since the invention of the microscope.

From the 1980s, cell culture has once again been brought to the forefront of cancer research in the isolation and identification of numerous cancer causing oncogenes. In addition, cell culturing continues to play a crucial role in fields such as cytology, embryology, radiology, and molecular genetics. In the future, its relevance to direct clinical treatment might be further increased by the growth in culture of stem cells and tissue replacement therapies that can be tailored for a particular individual. Indeed, as cell culture approaches its centenary, it appears that its importance to scientific, medical, and commercial research the world over will only increase in the twenty-first century.

History of Biotechnology

Biotechnology grew out of the technology of fermentation, which was called zymotechnology. This was different from the ancient craft of brewing because of its thought-out relationships to science. These were most famously conceptualized by the Prussian chemist Georg Ernst Stahl (1659–1734) in his 1697 treatise Zymotechnia Fundamentalis, in which he introduced the term zymotechnology. Carl Balling, long-serving professor in Prague, the world center of brewing, drew on the work of Stahl when he published his Bericht uber die Fortschritte der zymotechnische Wissenschaften und Gewerbe (Account of the Progress of the Zymotechnic Sciences and Arts) in the mid-nineteenth century. He used the idea of zymotechnics to compete with his German contemporary Justus Liebig for whom chemistry was the underpinning of all processes.

By the end of the nineteenth century, there were attempts to develop a new scientific study of fermentation. It was an aspect of the ‘‘second’’ Industrial Revolution during the period from 1870 to 1914. The emergence of the chemical industry is widely taken as emblematic of the formal research and development taking place at the time. The development of microbiological industries is another example. For the first time, Louis Pasteur’s germ theory made it possible to provide convincing explanations of brewing and other fermentation processes.

Pasteur had published on brewing in the wake of France’s humiliation in the Franco–Prussian war (1870–1871) to assert his country’s superiority in an industry traditionally associated with Germany. Yet the science and technology of fermentation had a wide range of applications including the manufacture of foods (cheese, yogurt, wine, vinegar, and tea), of commodities (tobacco and leather), and of chemicals (lactic acid, citric acid, and the enzyme takaminase). The concept of zymotechnology associated principally with the brewing of beer began to appear too limited to its principal exponents. At the time, Denmark was the world leader in creating high-value agricultural produce. Cooperative farms pioneered intensive pig fattening as well as the mass production of bacon, butter, and beer. It was here that the systems of science and technology were integrated and reintegrated, conceptualized and reconceptualized.

The Dane Emil Christian Hansen discovered that infection from wild yeasts was responsible for numerous failed brews. His contemporary Alfred Jørgensen, a Copenhagen consultant closely associated with the Tuborg brewery, published a widely used textbook on zymotechnology. Microorganisms and Fermentation first appeared in Danish 1889 and would be translated, reedited, and reissued for the next 60 years.

The scarcity of resources on both sides during World War I brought together science and technology, further development of zymotechnology, and formulation of the concept of biotechnology. Impending and then actual war accelerated the use of fermentation technologies to make strategic materials. In Britain a variant of a process to ferment starch to make butadiene for synthetic rubber production was adapted to make acetone needed in the manufacture of explosives. The process was technically important as the first industrial sterile fermentation and was strategically important for munitions supplies. The developer, chemist Chaim Weizmann, later became well known as the first president of Israel in 1949.

In Germany scarce oil-based lubricants were replaced by glycerol made by fermentation. Animal feed was derived from yeast grown with the aid of the new synthetic ammonia in another wartime development that inspired the coining of the word biotechnology. Hungary was the agricultural base of the Austro–Hungarian empire and aspired to Danish levels of efficiency. The economist Karl Ereky (1878–1952) planned to go further and build the largest industrial pig-processing factory. He envisioned a site that would fatten 50,000 swine at a time while railroad cars of sugar beet arrived and fat, hides, and meat departed. In this forerunner of the Soviet collective farm, peasants (in any case now falling prey to the temptations of urban society) would be completely superseded by the industrialization of the biological process in large factory-like animal processing units. Ereky went further in his ruminations over the meaning of his innovation. He suggested that it presaged an industrial revolution that would follow the transformation of chemical technology. In his book entitled Biotechnologie, he linked specific technical injunctions to wide-ranging philosophy. Ereky was neither isolated nor obscure. He had been trained in the mainstream of reflection on the meaning of the applied sciences in Hungary, which would be remarkably productive across the sciences. After World War I, Ereky served as Hungary’s minister of food in the short-lived right wing regime that succeeded the fall of the communist government of Bela Kun.

Nonetheless it was not through Ereky’s direct action that his ideas seem to have spread. Rather, his book was reviewed by the influential Paul Lindner, head of botany at the Institut fu¨ r Ga¨ rungsgewerbe in Berlin, who suggested that microorganisms could also be seen as biotechnological machines. This concept was already found in the production of yeast and in Weizmann’s work with strategic materials, which was widely publicized at that very time. It was with this meaning that the word ‘‘Biotechnologie’’ entered German dictionaries in the 1920s.

Biotechnology represented more than the manipulation of existing organisms. From the beginning it was concerned with their improvement as well, and this meant the enhancement of all living creatures. Most dramatically this would include humanity itself; more mundanely it would include plants and animals of agricultural importance. The enhancement of people was called eugenics by the Victorian polymath and cousin of Charles Darwin, Francis Galton. Two strains of eugenics emerged: negative eugenics associated with weeding out the weak and positive eugenics associated with enhancing strength. In the early twentieth century, many eugenics proponents believed that the weak could be made strong. People had after all progressed beyond their biological limits by means of technology.

Jean-Jacques Virey, a follower of the French naturalist Jean-Baptiste de Monet de Lamarck, had coined the term ‘‘biotechnie’’ in 1828 to describe man’s ability to make technology do the work of biology, but it was not till a century later that the term entered widespread use. The Scottish biologist and town planner Patrick Geddes made biotechnics popular in the English-speaking world. Geddes, too, sought to link life and technology. Before World War I he had characterized the technological evolution of mankind as a move from the paleotechnic era of coal and iron to the neotechnic era of chemicals, electricity, and steel. After the war, he detected a new era based on biology—the biotechnic era. Through his friend, writer Lewis Mumford, Geddes would have great influence. Mumford’s book Technics and Civilization, itself a founding volume of the modern historiography of technology, promoted his vision of the Geddesian evolution.

A younger generation of English experimental biologists with a special interest in genetics, including J. B. S. Haldane, Julian Huxley, and Lancelot Hogben, also promoted a concept of biotechnology in the period between the world wars. Because they wrote popular works, they were among Britain’s best-known scientists. Haldane wrote about biological invention in his far-seeing work Daedalus. Huxley looked forward to a blend of social and eugenics-based biological engineering. Hogben, following Geddes, was more interested in engineering plants through breeding. He tied the progressivism of biology to the advance of socialism.

The improvement of the human race, genetic manipulation of bacteria, and the development of fermentation technology were brought together by the development of penicillin during World War II. This drug was successfully extracted from the juice exuded by a strain of the Penicillium fungus. Although discovered by accident and then developed further for purely scientific reasons, the scarce and unstable ‘‘antibiotic’’ called penicillin was transformed during World War II into a powerful and widely used drug. Large networks of academic and government laboratories and pharmaceutical manufacturers in Britain and the U.S. were coordinated by agencies of the two governments. An unanticipated combination of genetics, biochemistry, chemistry, and chemical engineering skills had been required. When the natural mold was bombarded with high-frequency radiation, far more productive mutants were produced, and subsequently all the medicine was made using the product of these man-made cells. By the 1950s penicillin was cheap to produce and globally available.

The new technology of cultivating and processing large quantities of microorganisms led to calls for a new scientific discipline. Biochemical engineering was one term, and applied microbiology another. The Swedish biologist, Carl-Goran Heden, possibly influenced by German precedents, favored the term ‘‘Biotechnologi’’ and persuaded his friend Elmer Gaden to relabel his new journal Biotechnology and Biochemical Engineering. From 1962 major international conferences were held under the banner of the Global Impact of Applied Microbiology. During the 1960s food based on single-cell protein grown in fermenters on oil or glucose seemed, to visionary engineers and microbiologists and to major companies, to offer an immediate solution to world hunger. Tropical countries rich in biomass that could be used as raw material for fermentation were also the world’s poorest. Alcohol could be manufactured by fermenting such starch or sugar rich crops as sugar cane and corn. Brazil introduced a national program of replacing oil-based petrol with alcohol in the 1970s.

It was not, however, just the developing countries that hoped to benefit. The Soviet Union developed fermentation-based protein as a major source of animal feed through the 1980s. In the U.S. it seemed that oil from surplus corn would solve the problem of low farm prices aggravated by the country’s boycott of the USSR in1979, and the term ‘‘gasohol‘‘ came into currency. Above all, the decline of established industries made the discovery of a new wealth maker an urgent priority for Western governments. Policy makers in both Germany and Japan during the 1970s were driven by a sense of the inadequacy of the last generation of technologies. These were apparently maturing, and the succession was far from clear. Even if electronics or space travel offered routes to the bright industrial future, these fields seemed to be dominated by the U.S. Seeing incipient crisis, the Green, or environmental, movement promoted a technology that would depend on renewable resources and on low-energy processes that would produce biodegradable products, recycle waste, and address problems of the health and nutrition of the world.

In 1973 the German government, seeking a new and ‘‘greener’’ industrial policy, commissioned a report entitled Biotechnologie that identified ways in which biological processing was key to modern developments in technology. Even though the report was published at the time that recombinant DNA (deoxyribonucleic acid) was becoming possible, it did not refer to this new technique and instead focused on the use and combination of existing technologies to make novel products.

Nonetheless the hitherto esoteric science of molecular biology was making considerable progress, although its practice in the early 1970s was rather distant from the world of industrial production. The phrase ‘‘genetic engineering’’ entered common parlance in the 1960s to describe human genetic modification. Medicine, however, put a premium on the use of proteins that were difficult to extract from people: insulin for diabetics and interferon for cancer sufferers. During the early 1970s what had been science fiction became fact as the use of DNA synthesis, restriction enzymes, and plasmids were integrated. In 1973 Stanley Cohen and Herbert Boyer successfully transferred a section of DNA from one E. coli bacterium to another. A few prophets such as Joshua Lederberg and Walter Gilbert argued that the new biological techniques of recombinant DNA might be ideal for making synthetic versions of expensive proteins such as insulin and interferon through their expression in bacterial cells. Small companies, such as Cetus and Genentech in California and Biogen in Cambridge, Massachusetts, were established to develop the techniques. In many cases discoveries made by small ‘‘boutique’’ companies were developed for the market by large, more established, pharmaceutical organizations.

Many governments were impressed by these advances in molecular genetics, which seemed to make biotechnology a potential counterpart to information technology in a third industrial revolution. These inspired hopes of industrial production of proteins identical to those produced in the human body that could be used to treat genetic diseases. There was also hope that industrially useful materials such as alcohol, plastics (biopolymers), or ready-colored fibers might be made in plants, and thus the attractions of a potentially new agricultural era might be as great as the implications for medicine. At a time of concern over low agricultural prices, such hopes were doubly welcome. Indeed, the agricultural benefits sometimes overshadowed the medical implications.

The mechanism for the transfer of enthusiasm from engineering fermenters to engineering genes was the New York Stock Exchange. At the end of the 1970s, new tax laws encouraged already adventurous U.S. investors to put money into small companies whose stock value might grow faster than their profits. The brokerage firm E. F. Hutton saw the potential for the new molecular biology companies such as Biogen and Cetus. Stock market interest in companies promising to make new biological entities was spurred by the 1980 decision of the U.S. Supreme Court to permit the patenting of a new organism. The patent was awarded to the Exxon researcher Ananda Chakrabarty for an organism that metabolized hydrocarbon waste. This event signaled the commercial potential of biotechnology to business and governments around the world. By the early 1980s there were widespread hopes that the protein interferon, made with some novel organism, would provide a cure for cancer. The development of monoclonal antibody technology that grew out of the work of Georges J. F. Kohler and Cesar Milstein in Cambridge (co-recipients with Niels K. Jerne of the Nobel Prize in medicine in 1986) seemed to offer new prospects for precise attacks on particular cells.

The fear of excessive regulatory controls encouraged business and scientific leaders to express optimistic projections about the potential of biotechnology. The early days of biotechnology were fired by hopes of medical products and high-value pharmaceuticals. Human insulin and interferon were early products, and a second generation included the anti-blood clotting agent tPA and the antianemia drug erythropoietin. Biotechnology was also used to help identify potential new drugs that might be made chemically, or synthetically.

At the same time agricultural products were also being developed. Three early products that each raised substantial problems were bacteria which inhibited the formation of frost on the leaves of strawberry plants (ice-minus bacteria), genetically modified plants including tomatoes and rapeseed, and the hormone bovine somatrotropin (BST) produced in genetically modified bacteria and administered to cattle in the U.S. to increase milk yields. By 1999 half the soy beans and one third of the corn grown in the U.S. were modified. Although the global spread of such products would arouse the best known concern at the end of the century, the use of the ice-minus bacteria— the first authorized release of a genetically engineered organism into the environment—had previously raised anxiety in the U.S. in the 1980s.

In 1997 Dolly the sheep was cloned from an adult mother in the Roslin agricultural research institute outside Edinburgh, Scotland. This work was inspired by the need to find a way of reproducing sheep engineered to express human proteins in their milk. However, the public interest was not so much in the cloning of sheep that had just been achieved as in the cloning of people, which had not. As in the Middle Ages when deformed creatures had been seen as monsters and portents of natural disasters, Dolly was similarly seen as monster and as a portent of human cloning.

The name Frankenstein, recalled from the story written by Mary Shelley at the beginning of the nineteenth century and from the movies of the 1930s, was once again familiar at the end of the twentieth century. Shelley had written in the shadow of Stahl’s theories. The continued appeal of this book embodies the continuity of the fears of artificial life and the anxiety over hubris. To this has been linked a more mundane suspicion of the blending of commerce and the exploitation of life. Discussion of biotechnology at the end of the twentieth century was therefore colored by questions of whose assurances of good intent and reassurance of safety could be trusted.

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Hot Research Topics in Biotech in 2022

The past few years years have seen leaps and strides of innovation as scientists have worked to develop and produce new mRNA vaccinations and made major developments in biotech research. During this time, they’ve also faced challenges. Ongoing supply chain disruptions , the Great Resignation, and the pandemic have impacted biotech labs and researchers greatly, forcing lab managers and PIs to get creative with lab supply purchasing, experiment planning, and the use of technology in order to maintain their research schedules.

“The pace of innovation specific to COVID to be able to develop both medicines related to antibodies as well as vaccines is just staggering. Those of us in the industry are in awe of the innovation we’re witnessing on a daily basis. We’ve been behind in the use of automation, software, and AI that can make our industry more efficient — that’s where we’re headed,” says Michelle Dipp, Cofounder and Managing Partner, Biospring Partners on the This is ZAGENO podcast .

At the start of 2022, current biotech research projects are exploring advancements in medicine, vaccines, the human body and treatment of disease, bacteria and immunology, and viruses like the Coronavirus that affected the globe in ways we couldn’t have anticipated.

Biotech Research Processes are Changing

As Michelle explained, the research that’s happening is changing, and so is the way that scientists conduct it. Influenced by both B2C ecommerce and the growing dependence on remote and cloud-based working, biotech labs are undergoing digital transformations . This means more software, AI, and automation in the lab, along with modern digital procurement strategies and integrated systems for lab operations.

Here are some of the top biotech research trends and recent biotech research papers that are changing the world of science and leading to innovation in life sciences.

Top 6 Biotech Research Topics for 2022

Science journals have never been more popular as they’ve been in the past several years. Resonating with the general public, biotech research papers have found their way into the hands and social media streams of interested citizens and scientists alike.

As we look to the most credible, peer-reviewed sources for recent innovations like PubMed , the Journal of Biotechnology , BioTech , and Biotechnology Journal , the trending themes in biotech research are in direct response to COVID-19, like vaccine development, respiratory virus research, and RNA-based pharmaceuticals. Additionally, there have been major advances in metabolism and the human microbiome, as well as further exploration in microvesicles.

All of the research happening has the potential to change millions of people’s quality of life, prevent and treat illnesses that currently have high mortality rates, and change healthcare around the world.

Here's what's happening in biotech research.

1. Vaccine Development mRNA vaccine development has been in the works since 1989 and was accelerated in recent years to combat the global COVID-19 pandemic. Researchers like Maruggi, Zhang, Li, Ulmer, Yu and their team believe that mRNA vaccines could change infectious disease control as we know it as a prophylactic means of disease prevention for diseases like HIV, Zika, and the flu.

Recent developments in mRNA research from Pardi, Hogan, and Weissman in 2020 explored the ways that mRNA vaccines can combat certain cancers and infectious pathogens that were previously resistant to existing vaccine options.

With new access to data from the 3.4 billion+ COVID-19 mRNA vaccines that have been administered worldwide, researchers have been able to determine the risks associated with mRNA vaccines , which brings forward new topics for research in the medical and pharmaceutical sides of the biotech industry. mRNA vaccines are faster to develop and can help prevent more diseases than traditional vaccine methods.

2. Respiratory Viruses Acute respiratory diseases (ARDs) like those caused by the SARS-CoV pathogen or the influenza virus lead to morbidity and mortality, and can lead to pneumonia, which can be fatal for immunocompromised or elderly patients — they represent a huge impact to human society.

Identifying the cause of ARDs and identifying viral infections from COVID-19 has become an issue of public health and safety, leading research groups like Zhang, Wang, and team to seek out more accurate and faster ways to detect respiratory viruses .

Understanding these respiratory virus mechanisms can help lead to better protection, prevention, and treatments for respiratory viruses, which have a mortality rate of up to 78% .

3. RNA-based Therapeutics RNA-based treatments like modified non-coding RNAs (ncRNAs), microRNAs (miRNAs), and others have been developed and studied by teams like Feng, Patil, et al (2021) to treat various diseases and conditions, including pancreatic cancer, acute renal failure, acute kidney injuries, diabetic macular edema, and advanced solid tumors.

In 2022, we expect to see further development of RNA-based therapeutics, like CAR T cells and other gene/cell therapeutics, therapeutic antibodies, and small molecular drugs to treat even more diseases and for prophylactic purposes as well.

4. Microvesicles + Extracellular Vesicles Microvesicles are coming to light due to their involvement in transporting mRNA, miRNA, and proteins — but how else might they support the human body? There are unknown functions of microvesicles and other extracellular vesicles that have yet to be discovered.

In 2020, Ratajczak and Ratajczak found that understanding microvesicles (or exosomes, microparticles) could mean understanding cell-to-cell communication , and their research showed that extracellular vesicles could transfer mRNA and proteins and modify stem cells ex vivo. This year, we look forward to seeing more research on what these tiny cell parts can do.

5. Metabolism in Cancers + Other Diseases Metabolism is the process of energy conversion in organisms and it represents the chemical reactions that sustain life. Recent research on metabolism in cancers and in immune cells has uncovered new ways to approach treatment and prevention of certain illnesses.

Take a look at Matsushita, Nakagawa, and Koike’s (2021) research on lipid metabolism in oncology and how recent advances in lipidomics technology and mass spectrometry have opened the door for new analysis of lipid profiles of certain cancers.

6. The Human Microbiome The human microbiome hosts bacteria, microorganisms, and other naturally-occurring flora that can help us and harm us. Diet, stress, drugs, and other factors shape the microbiome, leading to inflammation and an immune response of cytokines. Recent machine learning and statistical analyses of microbiome data , like that of Indias, Lahti, Nedyalkova, and team (2021) are getting smarter and smarter by removing variables and providing ways to test new hypotheses using statistical modeling.

With a deeper understanding of the microbiome, researchers like David Sinclair have shown that lifestyle changes can actually help people live healthier lives for longer . Sinclair’s lab is at the forefront of aging research and its impact on healthcare — and it’s all rooted in biotechnology and life science experiments.

Recent updates to ICD-11 and its classification of aging as a disease have led to debate, with Sinclair and colleagues advocating for the ongoing paradigm shift that biological age and chronological age are not synonymous. The implications for longevity and aging research from a funding perspective will be impacted by WHO and NIH decisions, and we anticipate seeing more biotech research on topics like epigenetics, metabolism, mitochondrial dysfunction, reproduction, and stem cell developments in the coming years.

Biotech research can change humankind, and lead to a better quality of life for generations to come. Subscribe to the ZAGENO blog to keep up with the latest topics in biotech and life sciences research and find the tech that supports biotech lab managers and PIs in their ongoing work.

To learn more about how ZAGENO can eliminate the lab management challenges, gain access.

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Research Proposal Topics In Biotechnology

Biotechnology is a fascinating subject that blends biology and technology and provides a huge chance to develop new ideas. However, before pursuing a career in this field, a person needs to complete a number of studies and have a thorough knowledge of the matter. When we begin our career must we conduct study to discover some innovative innovations that could benefit people around the world. Biotechnology is one of a variety of sciences of life, including pharmacy. Students who are pursuing graduation, post-graduation or PhD must complete the research work and compose their thesis to earn the satisfaction in their education. When choosing a subject for biotechnology-related research it is important to choose one that is likely to inspire us. Based on our passion and personal preferences, the subject to study may differ.

What is Biotechnology?

In its most basic sense, biotechnology is the science of biology that enables technology Biotechnology harnesses the power of the biomolecular and cellular processes to create products and technologies that enhance our lives and the wellbeing of the planet. Biotechnology has been utilizing microorganisms' biological processes for over six thousand years to create useful food items like cheese and bread as well as to keep dairy products in good condition.

Modern biotechnology has created breakthrough products and technology to treat rare and debilitating illnesses help reduce our footprint on the environment and feed hungry people, consume less energy and use less and provide safer, more clean and productive industrial production processes.

Introduction

Biotechnology is credited with groundbreaking advancements in technological development and development of products to create sustainable and cleaner world. This is in large part due to biotechnology that we've made progress toward the creation of more efficient industrial manufacturing bases. Additionally, it assists in the creation of greener energy, feeding more hungry people and not leaving a large environmental footprint, and helping humanity fight rare and fatal diseases.

Our writing services for assignments within the field of biotechnology covers all kinds of subjects that are designed to test and validate the skills of students prior to awarding their certificates. We assist students to successfully complete their course in all kinds of biotechnology-related courses. This includes biological sciences for medical use (red) and eco-biotechnology (green) marine biotechnology (blue) and industrial biotechnology (white).

What do we hope to gain from all these Initiatives?

Our primary goal in preparing this list of the top 100 biotechnology assignment subjects is to aid students in deciding on effective time management techniques. We've witnessed a large amount of cases where when looking for online help with assignments with the topic, examining sources of information, and citing the correct order of reference students find themselves stuck at various points. In the majority of cases, students have difficulty even to get through their dilemma of choosing a topic. This is why we contribute in our effort to help make the process easier for students in biotech quickly and efficiently. Our students are able to save time and energy in order to help them make use of the time they are given to write the assignment with the most appropriate topics.

Let's look at some of the newest areas of biotechnology research and the related areas.

• Renewable Energy Technology Management Promoting Village
• Molasses is a molasses-based ingredient that can be used to produce and the treatment of its effluent
• Different ways to evapotranspirate
• Scattering Parameters of Circulator Bio-Technology
• Renewable Energy Technology Management Promoting Village.

Structural Biology of Infectious Diseases

A variety of studies are being conducted into the techniques used by pathogens in order to infect humans and other species and for designing strategies for countering the disease. The main areas that are available to study by biotech researchers include:

• inlA from Listeria monocytogenes when combined with E-cadherin from humans.
• InlC in Listeria monocytogenes that are multipart with human Tuba.
• Phospholipase PatA of Legionella pnemophila.
• The inactivation process of mammalian TLR2 by inhibiting antibody.
• There are many proteins that come originate from Mycobacterium tuberculosis.

Plant Biotechnology

Another significant area for research in biotechnology for plants is to study the genetic causes of the plant's responses to scarcity and salinity, which have a significant impact on yields of the crop and food.

• Recognition and classification of genes that influence the responses of plants to drought and salinity.
• A component of small-signing molecules in plants' responses to salinity and drought.
• Genetic enhancement of plant sensitivity salinity and drought.

Pharmacogenetics

It's also a significant area for conducting research in biotechnology. One of the most important reasons for doing so could be the identification of various genetic factors that cause differences in drug effectiveness and susceptibility for adverse reactions. Some of the subjects which can be studied are,

• Pharmacogenomics of Drug Transporters
• Pharmacogenomics of Metformin's response to type II mellitus
• The pharmacogenomics behind anti-hypertensive medicines
• The Pharmacogenomics of anti-cancer drugs

Forensic DNA

A further area of research in biotechnology research is the study of the genetic diversity of humans for its applications in criminal justice. Some of the topics that could be studied include,

• Y-chromosome Forensic Kit, Development of commercial prototype.
• Genetic testing of Indels in African populations.
• The Y-chromosome genotyping process is used for African populations.
• Study of paternal and maternal ancestry of mixed communities in South Africa.
• The study of the local diversity in genetics using highly mutating Y-STRs and Indels.
• South African Innocence Project: The study of DNA extracted from historical crime scene.
• Nanotechnology is a new technology that can be applied to DNA genotyping.
• Nanotechnology methods to isolate DNA.

Food Biotechnology

It is possible to conduct research in order to create innovative methods and processes in the fields of food processing and water. The most fascinating topics include:

• A molecular-based technology that allows for the rapid identification and detection of foodborne pathogens in intricate food chains.
• The effects of conventional and modern processing techniques on the bacteria that are associated with Aspalathus lineriasis.
• DNA-based identification of species of animals that are present in meat products that are sold raw.
• The phage assay and PCR are used to detect and limit the spread of foodborne pathogens.
• Retention and elimination of pathogenic, heat-resistant and other microorganisms that are treated by UV-C.
• Analysis of an F1 generation of the cross Bon Rouge x Packham's Triumph by Simple Sequence Repeat (SSR/microsatellite).
• The identification of heavy metal tolerant and sensitive genotypes
• Identification of genes that are involved in tolerance to heavy metals
• The isolation of novel growth-promoting bacteria that can help crops cope with heavy metal stress . Identification of proteins that signal lipids to increase the tolerance of plants to stress from heavy metals

This topic includes high-resolution protein expression profiling for the investigation of proteome profiles. The following are a few of the most fascinating topics:

• The identification and profile of stress-responsive proteins that respond to abiotic stress in Arabidopsis Thalian and Sorghum bicolor.
• Analyzing sugar biosynthesis-related proteins in Sorghum bicolor, and study of their roles in drought stress tolerance
• Evaluation of the viability and long-term sustainability of Sweet Sorghum for bioethanol (and other by-products) production in South Africa
• In the direction of developing an environmentally sustainable, low-tech hypoallergenic latex Agroprocessing System designed specifically especially for South African small-holder farmers.

Bioinformatics

This is an additional aspect of biotechnology research. The current trend is to discover new methods to combat cancer. Bioinformatics may help identify proteins and genes as well as their role in the fight against cancer. Check out some of the areas that are suitable to study.

• Prediction of anticancer peptides with HIMMER and the the support vector machine.
• The identification and verification of innovative therapeutic antimicrobial peptides for Human Immunodeficiency Virus In the lab and molecular method.
• The identification of biomarkers that are associated with cancer of the ovary using an molecular and in-silico method.
• Biomarkers identified in breast cancer, as possible therapeutic and diagnostic agents with a combination of molecular and in-silico approaches.
• The identification of MiRNA's as biomarkers for screening of cancerous prostates in the early stages an in-silico and molecular method
• Identification of putatively identified the genes present in breast cancer tissues as biomarkers for early detection of lobular and ductal breast cancers.
• Examining the significance of Retinoblastoma Binding Protein 6 (RBBP6) in the regulation of the cancer-related protein Y-Box Binding Protein 1 (YB-1).
• Examining the role played by Retinoblastoma Binding Protein 6 (RBBP6) in the regulation of the cancer suppressor p53 through Mouse Double Minute 2 (MDM2).
• Structural analysis of the anti-oxidant properties of the 1-Cys peroxiredoxin Prx2 found in the plant that resurrects itself Xerophyta viscosa.

Nanotechnology

This is a fascinating aspect of biotechnology, which can be used to identify effective tools to address the most serious health issues.

• Evaluation of cancer-specific peptides to determine their applications for the detection of cancer.
• The development of a quantum dot-based detection systems for breast cancer.
• The creation of targeted Nano-constructs for in vivo imaging as well as the treatment of tumors.
• Novel quinone compounds are being tested as anti-cancer medicines.
• Embedelin is delivered to malignant cells in a specific manner.
• The anti-cancer activities of Tulbaghia Violacea extracts were studied biochemically .
• Novel organic compounds are screened for their anti-cancer potential.
• To treat HIV, nanotechnology-based therapeutic techniques are being developed.

Top 100 Biotechnology Research Proposal Topics to Consider in 2022

We've prepared a list of the top 100 most suggested dissertation topics, which were compiled by our experts in research. They've made sure to offer a an extensive list of topics that cover all aspects of the topic. We hope that this list will meet all of the requirements for assistance with your dissertation . Let us start with our list of subjects, one at a time each one

• Achieving effective control of renewable power technologies to help the village
• The production of ethanol through the aid of molasses and the treatment of its effluent
• Different approaches and aspects of Evapotranspiration
• Its scattering parameter is biotechnology circulator
• The inactivation of mammalian TLR2 via an inhibiting antibody
• The number of proteins produced by Mycobacterium tuberculosis
• Recognition and classification of genes that shape the responses of plants to drought and salinity.
• The small sign molecules that are involved in the response that plants have to the effects of salinity as well as drought
• Genetic improvement of the plant's sensitivity to drought and saltiness
• The pharmacogenomics of drug transporters
• The anti-cancer drugs' pharmacogenomics are based on pharmac
• The pharmacogenomics of antihypertensive medications
• Indels genotyping of African populations
• Genomics of the Y-chromosomes of African populations
• The profiling of DNA extracted from historical crime scenes Consider the implications of South African Innocence Project
• Nanotechnology-related methods for DNA isolation
• Nanotechnology applications in the context of DNA genotyping
• Recognizing the heavy metals that are tolerant with genotypes that are sensitive.
• Genetic characteristics that play a role within the procedure of gaining tolerance to metals
• The animal's DNA is authenticated by the species by the commercial production of raw meat products
• The use of molecular-based technology is in the sense of detection and identification of foodborne pathogens in complicated food systems
• Assessing the effectiveness of cancer-specific peptides that are suitable for efficient implementations in the area of diagnosis and treatment for cancer
• Quantum Dot-based detection system is being developed in relation to a positive breast cancer diagnosis
• It is targeted delivery of the embelin to cancerous cells
• Exploring the potential of novel quinone compounds as anti-cancer agents
• Treatment strategies for treating HIV in addition to the significance of nanotechnology the treatment of HIV.
• A review of the medicinal value the antioxidants found in nature.
• An in-depth examination of the structure of COVID spike proteins
• A review of the immune response to the stem therapy using cells
• CRISPR-Cas9 technology to aid in the process of editing the genome
• Tissue engineering and delivery of drugs through the application of Chitosan
• Evaluation of beneficial effects of cancer vaccines
• Use of PacBio sequencing in relation to genome assembly of model organisms
• Examining the connection between mRNA suppression and its effect on the growth of stem cells
• Biomimicry is a method of identifying of cancer cells
• The sub-classification and characterisation of the Yellow enzymes
• The process of producing food products that are hypoallergenic and fermented.
• The production of hypoallergenic milk
• The purification process for the thermostable phytase
• Bioconversion of the cellulose produce products that are significant for industry
• The investigation of the gut microbiota of the model organisms
• The use of fungal enzymes for the manufacture of chemical glue
• A look at those inhibitors to exocellulase as well as endocellulase
• Examine the value of microorganisms to aid in the recovery of gas from shale.
• Examine the thorough analysis of the method of natural decomposition
• Examine ways to recycle bio-wastes
• Improved bio-remediation in the case of oil spills
• The process of gold biosorption is accomplished with the aid of the cyanobacterium
• A healthy equilibrium between the biotic and the abiotic elements by using biotechnological devices
• The measurement of the mercury level in fish by means of markers
• Exploring the biotechnological capabilities from Jellyfish related microbiomes Jellyfish related microbiome
• What is the role of marine fungi to aid in attempts to break down plastics and polymers?
• Examine the biotechnological possibilities that can be extracted of dinoflagellates
• Removing endosulfan residues using the use of biotechnology the agriculture sector
• The creation of the ELISA method for the detection of crop virus
• Enhancing the quality of drinking water by the aid of the E.coli consortium
• The characterisation of E.coli is its isolation from the feces of Zoo animals
• Enhancing the resistance of crops to the attack of insects
• The reduction of the expenditure on agriculture by using efficient bio-tools
• Are there the most efficient ways to stop erosion of soils using the help of biotechnology-based tools?
• What can biotechnology do to assist in increasing the levels of vitamin content in GM food items?
• Enhancing the distribution of pesticides by using biotechnology
• Comparing the biofortification of folate in various types of corpses
• Examine the photovoltaic-based generation of ocean-based crop
• What is the best way to use nanotechnology will improve the efficiency of the agriculture sector?
• Analyzing the mechanisms that govern resistance to water stresses in models of plants
• Production and testing of human immune boosters within the test organisms
• Comparing genomic analysis to the usefulness of tools intended for bioinformatics
• The Arabinogalactan protein sequence and its value in the field of computational methods
• Analyzing and interpreting gut microbiota from model organisms
• Different methods of purification of proteins A comparative analysis
• The diagnosis of microbes and their function in micro-arrays of oligonucleotide oligonu
• The use of diverse techniques within the biomedical research field that includes micro-arrays technology
• The use of microbial community to produce the greenhouse effect
• Evaluation of the computational properties of various proteins that are derived from the marine microbiota
• E.coli gene mapping through the help of different tools for microbial research
• Intensifying the strains of Cyanobacterium the aid of gene sequencing
• Assessment and description by computation of crystallized proteins that are found in the natural world.
• MTERF protein and the use of it to end the process of transcription that occurs in mitochondrial DNA inside algae
• Reverse column chromatography in phase and its use in the separation of proteins
• The study of the various proteins that are found within Mycobacterium leprae.
• A review of the methods that are ideal to ensure the success of cloning RNA
• Examine the most common mistakes of biotechnology in conserving the ecology and natural environment.
• Is there a method to ensure that the medicinal plants are free of insects? Discuss
• What are the dangers caused by pest resistant animals on birds and human beings?
• What are the many areas of biotechnology that remain unexplored in terms research?
• What's the future of biotechnology in the medical field?
• Recombinant DNA technology to develop of new medical treatments
• What is the reason for the type of bacteria that is used to make vaccines with the aid of biotechnology?
• How can biotechnology aid in the development of new medicines that are resistant to the mutations of viruses and bacteria?
• Is there a long-term treatment for cancer that is available in the near term? Biotechnology could play an essential role in this?
• What is the reason it is so important that students remember the DNA codes in biotechnology?
• How can we create hybrid seeds with assistance of biotechnology?
• How can one create resistant plants to pests and what are the benefits of these seeds in final yields in agriculture?
• Examine bio-magnification and its effects on the ecology
• What are the causes to the reasons ecologists do not approve the use of pest-resistant seed, even though they are in application in agriculture?
• How has biotechnology influenced the lives of farmers in developing countries?
• Biotechnology can be used to boost the yield of plant species?
• Examine the role played by biotechnology to increase the production of the seasonal crops
• Are there any adverse side effects associated with pharmaceutical drugs when they are manufactured with biotechnological techniques? Let the issue with real-world examples

We attempted to cover the essential topics needed for research work. Other topics are available that could be picked based on our interests, the facilities available and resources available for the research, as well as resources and time limits.

We have reached the end of this list. We feel it was beneficial in satisfying the selection criteria. Furthermore, the inclusion of biotechnology-related assignment themes was done in such a manner that they may help us with the requirements of assignment writing kinds and forms. The themes listed above can meet our demands for topic selection linked to aid with case studies and essay assistance, research paper writing help , or thesis writing help .

Frequently asked questions

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Insights in Plant Biotechnology: 2021

Loading... Editorial 30 January 2023 Editorial: Insights in plant biotechnology: 2021 James R. Lloyd , Ralf Wilhelm , Manoj K. Sharma , Jens Kossmann  and  Peng Zhang 690 views 0 citations

Original Research 25 July 2022 Pan-genome analysis of three main Chinese chestnut varieties Guanglong Hu ,  4 more  and  Yanping Lan 3,857 views 6 citations

Original Research 14 June 2022 Differential Gene Expression and Withanolides Biosynthesis During in vitro and ex vitro Growth of Withania somnifera (L.) Dunal Sachin Ashok Thorat ,  8 more  and  Annamalai Muthusamy 2,461 views 3 citations

Original Research 06 June 2022 Identification of Reference Genes for Reverse Transcription-Quantitative PCR Analysis of Ginger Under Abiotic Stress and for Postharvest Biology Studies Gang Li ,  9 more  and  Yongxing Zhu 2,401 views 13 citations

Original Research 02 June 2022 Nested miRNA Secondary Structure Is a Unique Determinant of miR159 Efficacy in Arabidopsis Muhammad Imran ,  8 more  and  Min Zhang 1,362 views 2 citations

Original Research 31 May 2022 Production of Recombinant Active Human TGFβ1 in Nicotiana benthamiana Aditya Prakash Soni ,  3 more  and  Inhwan Hwang 3,089 views 1 citations

Perspective 27 May 2022 Gene Editing to Accelerate Crop Breeding Kanwarpal S. Dhugga 3,375 views 7 citations

Mini Review 26 May 2022 Clustered Regularly Interspaced Short Palindromic Repeats-Associated Protein System for Resistance Against Plant Viruses: Applications and Perspectives Fredy D. A. Silva  and  Elizabeth P. B. Fontes 2,173 views 4 citations

Original Research 20 May 2022 Genomics-Assisted Improvement of Super High-Yield Hybrid Rice Variety “Super 1000” for Resistance to Bacterial Blight and Blast Diseases Zhizhou He ,  15 more  and  Junhua Peng 1,685 views 5 citations

Loading... Original Research 19 May 2022 Eradication of Potato Virus S, Potato Virus A, and Potato Virus M From Infected in vitro-Grown Potato Shoots Using in vitro Therapies Jean Carlos Bettoni ,  7 more  and  Jayanthi Nadarajan 5,696 views 21 citations

Original Research 13 May 2022 Successful Production and Ligninolytic Activity of a Bacterial Laccase, Lac51, Made in Nicotiana benthamiana via Transient Expression André van Eerde ,  8 more  and  Jihong Liu Clarke 1,843 views 2 citations

Loading... Review 09 May 2022 Molecular Determinants of in vitro Plant Regeneration: Prospects for Enhanced Manipulation of Lettuce (Lactuca sativa L.) Tawni Bull  and  Richard Michelmore 7,938 views 7 citations

Review 29 April 2022 A Walk Through the Maze of Secondary Metabolism in Orchids: A Transcriptomic Approach Devina Ghai ,  3 more  and  Jaspreet K. Sembi 2,353 views 3 citations

Review 29 April 2022 Glyco-Engineering Plants to Produce Helminth Glycoproteins as Prospective Biopharmaceuticals: Recent Advances, Challenges and Future Prospects Alex van der Kaaij ,  3 more  and  Arjen Schots 3,563 views 2 citations

Loading... Review 29 April 2022 Heat Stress-Mediated Constraints in Maize (Zea mays) Production: Challenges and Solutions Ahmed H. El-Sappah ,  13 more  and  Manzar Abbas 8,575 views 35 citations

Review 25 April 2022 Biotechnological Road Map for Innovative Weed Management Albert Chern Sun Wong ,  3 more  and  Bhagirath Singh Chauhan 4,850 views 4 citations

Original Research 13 April 2022 A Multi-Omics Approach for Rapid Identification of Large Genomic Lesions at the Wheat Dense Spike (wds) Locus Zhenyu Wang ,  14 more  and  Aili Li 1,975 views 2 citations

Loading... Review 08 April 2022 CRISPR/Cas9 and Nanotechnology Pertinence in Agricultural Crop Refinement Banavath Jayanna Naik ,  7 more  and  Soo-Hong Lee 7,146 views 13 citations

Original Research 22 March 2022 Physiological and Molecular Changes in Cherry Red Tobacco in Response to Iron Deficiency Stress Fei Liu ,  6 more  and  Zhongbang Song 1,411 views 2 citations

Original Research 10 March 2022 Salt Stress Alleviation in Triticum aestivum Through Primary and Secondary Metabolites Modulation by Aspergillus terreus BTK-1 Muhammad Ikram Khan ,  6 more  and  In-Jung Lee 1,810 views 13 citations

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Biotechnology Research Topics

What is biotechnology.

What first pops up in your mind when you hear the term Biotechnology? Maybe you started thinking of GMOs ( Genetically Modified Organisms ), transgenic cloning, and other gene therapies. Of course, you got it right, but the horizon of biotechnology is not so tiny. It has a wide range of applications in the industry that can improve our living standards. Let us first understand the term Biotechnology. In simple words, it is the utilization of living organisms or their components in the industrial sector to generate various products that are beneficial for the human race. We have been utilizing microorganisms for more than thousands of years to develop useful commodities such as cheese, bread, and various other dairy-related products. Even its implementation in the medical sector has led to the manufacturing of different vaccines, biofuel, chitosan-coated dressing for wounds, brewing, and even age-defying products. As the biotechnology scope is expanding day by day, researchers felt an urge to classify main areas and types of biotechnology depending on some commonalities and their ultimate objectives:

Red Biotechnology- involves the utilization of organisms for upgrading the quality of health care departments and aiding the body’s immune system to fight against various diseases. Examples include; the development of different vaccines, antibiotics, medicinal drugs, and various molecular techniques.

White Biotechnology- mainly comprises industrial biotechnology and involves the utilization of microorganisms and their by-products for manufacturing more eco-friendly and energy-efficient products. White biotechnology examples include the production of biofuel, Lactic acid, and 3- hydroxy propionic acid.

Yellow Biotechnology- it is related to the use of Biotech in the food production area, i.e., making bread, cheese, beer, and wine by the fermentation process.

Grey Biotechnology – mainly deals with the removal of pollutants from the environment by using various microorganisms and plants. For example., different strains of bacteria can be used for the degradation of kitchen waste into compost.

  Green Biotechnology- concentrates on the agriculture sector and focuses on generating new varieties of plants and producing good quality bio-pesticides & bio-fertilizers.

  Blue Biotechnology – it mainly refers to the utilization of aquatic or marine organisms to create goods that can aid various industrial processes, such as using Chitosan (sugar derived from the shells of crabs and shrimps) for the dressing of wounds.

Biotechnology Topics for Research Paper

In the modern world, students are apprehending the benefits of Biotech and want to study it with more enthusiasm and interest. They are actively opting for this subject and compiling their research work to contribute their efforts in the field of Biotechnology. They are indulged in exhaustive research to find the best topic for the research purpose. So, here are a few potential research topics in the domain of Biotechnology:

Red Biotechnology Research Topics:

• Studying the relationship between the intake of iron-folic acid during pregnancy and its impact on the overall health of the fetus.
• Pharmacogenomics of antimicrobial drugs.
• Identifying the biomarkers linked with breast cancer.
• Study the medicinal value of natural antioxidants.
• Study the structure of coronavirus spike proteins.
• Studying the immune response of stem cell therapy.
• Utilization of CRISPR-Cas9 technology for genome editing.
• Application of Chitosan in tissue engineering and drug delivery.
• Study the therapeutic effects of cancer vaccines.
• Utilizing PacBio sequencing for the genome assembly of model organisms.
• Study the relationship between the suppression of mRNA and its effect on stem cell expansion.
• Study the application of nanoprobes in molecular imaging.
• Incorporating biomimicry for the detection of tumor cells.
• Study of immune-based therapies in treating COVID-19.
• Regulation of immune response using the cellular and molecular mechanism
• Microchip implantation – a vaccine for coronavirus.
• The Use of CRISPR for Human Genome Editing

Yellow Biotechnology Research Topics:

• Production of hypoallergenic milk.
• Production of hypoallergenic fermented foods.
• Yellow enzymes subclassification and their characterization.

White Biotechnology Research Topics:

• Bioconversion of cellulose to yield industrially important products.
• Studying the inhibitors of endocellulase and exocellulase.
• Fungal enzymes used in the production of chemical glue.
• Mechanism of fungal enzymes in the biodegradation of lignin.
• Studying gut microbiota in model organisms.
• Study the lactic acid bacteria for probiotic potential.
• Purification of thermostable phytase.
• Mesophilic and Thermophilic aerobic and anaerobic bacteria from compost.
• Study the dietary strategies for the prophylaxis of Alzheimer’s and dementia.
• Examine the positive effects of probiotics and prebiotics on the nervous system.

Examples of Grey Biotechnology Research Topics:

• Production of sustainable, low-cost, and environmentally friendly microbial biocement and biogrouts.
• Use of microorganisms for the recovery of shale gas.
• Studying the procedure of natural decomposition.
• Treatment of grey water in a multilayer reactor with passive aeration.
• Excavation of various anaerobic microbes using grey biotechnology.
• Improving the biodegradation of micro-plastics using GMOs.
• Removal of pollutants from the land.
• Use of microbes to excavate the hidden metals from earth.
• Managing the processes of environmental biotechnology using microbial ecology.
• In situ product removal techniques using the process of biocatalysis.
• Production of biodegradable, disposable plastic for the storage of food.
• Plastic waste decomposition management.  
• Maintaining a healthy equilibrium between biotic and abiotic factors using biotechnological tools.
• Recycling of biowastes.
• Restoration of biodiversity using tools.
• Improved Recombinant DNA technology for bioremediation.
• Gold biosorption using cyanobacterium.
• Improved bioremediation of oil spills.
• Biodegradation of oil and natural gas.

Blue Biotechnology Research Ideas:

• Various bioactive compounds derived from marine sponges.
• Controlling the emerged biological contaminant using the sustainable future.
• Protecting the environment using grey, blue, and green biotechnology.  
• Exploring marine biota which survives the extreme conditions.
• Studying the patterns of Arctic and Antarctic microbiota for the benefits of humans.
• Excavation of bioactive molecules from extreme environmental conditions.
• Studying the potential of sponge-associated microbes.
• Mercury labeling in the fish using markers.
• Sea urchin repelling ocean macroalgal afforestation.
• Microbial detection techniques to find sea animals.
• Studying the mechanisms in deep-sea hydrothermal vent bacteria.
• Production of antibiotics using marine fungi.
• Exploring the biotechnological potential of Jellyfish associated microbiome.  
• Exploring the potential of marine fungi in degrading plastics and polymers.
• Expl oring the biotechnological potential of dinoflagellates.

Green Biotechnology Research Paper Topics:

• Detection of endosulfan residues using biotechnology in agricultural products.
• Development of ELISA technique for the detection of crops’ viruses.
• Use of Green Fluorescent Protein (GFP) as a cytoplasmic folding reporter.
• E.coli as an all-rounder in biotechnological studies.
• Improving the water quality for drinking using E.coli consortium.
• E.coli characterization isolated from the zoo animals’ feces.  
• Biocatalysis and agricultural biotechnology in situ studies.
• Improving the insect resistance of the crops.
• Improving the nutritional value and longer shelf life of GM crops.
• Improving the qualities of hydroponic GM plants.
• Reducing the cost of agriculture using bio-tools.
• Production of heavy cotton balls in agricultural biotechnology using in situ technique.
• Steps to minimize soil erosion using the tools of biotechnology.
• Enhancement of vitamin levels in GM Foods .
• Improving pesticide delivery using biotechnology.
• Comparison of folate biofortification of different crops.
• Photovoltaic-based production of crops in the ocean.
• Application of nanotechnology in the agricultural sector.
• Study the water stress tolerance mechanisms in model plants.

Combination and Analytical Topics:

• Sequencing of infectious microbes using molecular probes.
• Production and testing of human immune boosters in experimental organisms.
• Comparative genomic analysis using the tools of bioinformatics.
• Arabinogalactan protein sequencing using computational methods.
• Comparative analysis of different protein purification techniques.
• Oligonucleotide microarrays used in the diagnosis of the microbes.
• Uses of different techniques in biomedical research including microarray technology.
• Microbial consortium used to produce the greenhouse effect.
• Computational analysis of different proteins obtained from marine microbiota.
• Gene mapping of E.coli using different microbial tools.
• Computational analysis and characterization of the crystallized proteins in nature.
• Improving the strains of cyanobacterium using gene sequencing.
• mTERF protein used to terminate the mitochondrial DNA transcription in algae.  
• Reverse phase column chromatography used to separate proteins.
• Study of different proteins present in Mycobacterium leprae.
• Study the strategies best suitable for cloning RNA
• Study the application of nanocarriers for the gene expression in model plants.
• Exploring thermotolerant microorganisms for their biotechnological potential.

Biotechnology is full of research prospects. Various research and development companies are working day and night to achieve the required outcomes for different branches of biotechnology. If you find these list of Biotechnology research topics helpful, you may visit our blog for further assistance.

Also look for Biology Research Topics

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The research projects listed on our alumni webpages are meant to illustrate the diversity and number of research possibilities that the MBP has to offer. Research projects naturally evolve over time: some continue, while others get terminated based on research advisors' interests and funding opportunities. However, the MBP ensures that each of the 12 areas of research listed on our website continue to be adequately represented by research projects.

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Plant biotechnology articles from across Nature Portfolio

Plant biotechnology can be defined as the introduction of desirable traits into plants through genetic modification.

Haploids fast-track hybrid plant breeding

Two studies report the use of paternal haploids to enable one-step transfer of cytoplasmic male sterility in maize and broccoli, which resolves a key technical bottleneck in hybrid crop breeding.

• Ravi Maruthachalam

Related Subjects

• Agricultural genetics
• Field trials
• Molecular engineering in plants

Latest Research and Reviews

Comparative studies of four cumin landraces grown in Egypt

• Abeer A. Ahmed
• Marwa Ghoneim
• Mohamed A. A. Ahmed

Transient expression of anti-HrpE scFv antibody reduces the hypersensitive response in non-host plant against bacterial phytopathogen Xanthomonas citri subsp. citri

• Hamideh Raeisi
• Mohammad Reza Safarnejad
• Seyed Ali Elahinia

Identification of a sugarcane bacilliform virus promoter that is activated by drought stress in plants

The promoter PSCBV-YZ2060 cloned from the sugarcane bacilliform virus is shown to be induced by drought in sugarcane and Arabidopsis plants and is a potential alternative promoter for genetic engineering of drought-resistant transgenic crops.

• Sheng-Ren Sun
• Xiao-Bin Wu

Lipids productivity of cyanobacterium Anabaena vaginicola in an internally illuminated photobioreactor using LED bar lights

• Hootan Goldoost
• Farzaneh Vahabzadeh
• Narges Fallah

Dynamics of starch formation and gene expression during grain filling and its possible influence on grain quality

• Sanjeeva Rao Durbha
• N. Siromani
• R. M. Sundaram

Cyto-swapping in maize by haploid induction with a cenh3 mutant

An efficient method of cyto-swapping by haploid induction using a CENH3 mutation is reported in maize, to convert commercial germplasm to cytoplasmic male sterility for hybrid seed production.

• Esteban Bortiri
• Rebecca Selby
• Tim Kelliher

News and Comment

Feeding the future global population.

Climate change is exacerbating challenges both for global food production and from its environmental impacts. Sustainable and socially responsible solutions for future world-wide food security are urgently needed.

Novel gene for herbicide resistance

Blueprint for non-transgenic edited plants

A robust strategy to obtain edited crops without integration of a transgene is developed based on co-editing the ALS gene and a gene of interest.

• Jean-Luc Gallois
• Fabien Nogué

A new chance for genome editing in Europe

• Hervé Vanderschuren
• Patience Chatukuta
• Devang Mehta

Callose integration into secondary cell walls modifies woody biomass ultrastructure and accessibility

Previous genetic engineering of plant secondary cell walls targeted its core polymers to facilitate their extractability. The ectopic introduction of the polymer callose into poplar wood secondary cell walls modifies the ultrastructure of cellulose microfibril aggregates and suggests new avenues when considering biomass genetic engineering.

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