phd topics in biotech

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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1. Gene Editing and Genomic Engineering

an artist s illustration of artificial intelligence ai this image depicts how ai could assist in genomic studies and its applications it was created by artist nidia dias as part of the

a. CRISPR and Gene Editing

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.

b. Synthetic Biology

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

a. Precision Medicine

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.

b. Pharmacogenomics

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

a. Nanoparticles in Medicine

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.

b. Nanosensors and Diagnostics

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

person holding syringe and vaccine bottle

a. Cancer Immunotherapy

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.

b. Vaccine Technology

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

a. Bioremediation and Bioenergy

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.

b. Agricultural Biotechnology

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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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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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.

Get 1-On-1 Help

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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About the PhD in Biochemistry and Molecular Biology Program

In the Biochemistry and Molecular Biology PhD program, faculty, and students work together to increase knowledge of the biochemical and molecular bases of normal and abnormal cellular processes. Our program trains students to be successful independent scientists and gives them the knowledge, research training, and leadership skills to continue to provide new insights into the biomedical issues that have a profound impact on public health.

Students engage in a rigorous course curriculum and a range of structured and informal activities outside the classroom and lab to build their skills. They will pursue their thesis research in the lab of one of our over forty training faculty across the Johns Hopkins Bloomberg School of Public Health and the Johns Hopkins School of Medicine.

Visit our dedicated PhD program website to learn more about the diverse research training opportunities of the program.

PhD in Biochemistry and Molecular Biology Program Highlights

Our position within the School of Public Health provides a unique setting in which students learn how biochemistry, molecular biology, physical chemistry, cell biology, and genetics can be used to solve significant problems in public health and medicine. Our program offers:

Training faculty from across the School of Public Health and the School of Medicine
A strong grounding in the science of biomedical and public health research through a core curriculum that includes courses taught by leading experts from the Schools of Public Health and Medicine
Training outside the lab and classroom in key skills such as communications and leadership
Opportunities to build strong communications skills through a range of speaking venues including journal club, research colloquium, department retreats, and national meetings
Access to the Johns Hopkins School of Medicine Professional Development and Career Office , offering excellent career services and professional development, including the BMB-required OPTIONS program, a guided process of career exploration for paths from medicine to biotech to academia and beyond for careers paths from medicine to biotech to academia and beyond
Opportunities to participate in community service and outreach, with a focus on our East Baltimore neighborhoods, through the Johns Hopkins University community engagement and service-learning center, SOURCE

Training faculty across the School of Public Health and the School of Medicine

Schools that students can take courses in: Public Health, Arts & Sciences, Medicine, and Engineering

Two-month rotations in the first year prior to selecting thesis lab

Average number of incoming students in the BMB PhD degree program each year

What Can You Do With a PhD In Biochemistry And Molecular Biology?

The Biochemistry and Molecular Biology PhD program prepares students for a range of biomedical and health sciences careers, including in academia, industry, policy, and beyond. Visit the Graduate Employment Outcomes Dashboard to learn about Bloomberg School graduates' employment status, sector, and salaries.

Sample Careers

Research Scientist
Science Policy Adviser
Biotech Executive
Senior Scientist
Patent Lawyer
Science Policy Analyst/Advocate
Science Writer/Journalist
Biological Sciences Teacher

Topic Areas

The BMB PhD program faculty conduct research to gain new insights into the cellular and molecular mechanisms underlying normal and abnormal cellular processes, and their relevance as targets for improving health and treating disease. Our training program places particular emphasis on mechanistic approaches to research problems.

Common topic areas within our faculty's diverse research interests include:

Biophysics and Structural Biology
Cancer Biology
Chemical Biology and Proteomics
Cell Biology
Cellular Stress and Cell Signaling
Genetics, Genomics, and Gene Regulation
Immunology and Infectious Diseases
Translational Research

Curriculum for the PhD in Biochemistry and Molecular Biology

The BMB PhD offers students a rigorous course curriculum, including a set of common core classes from the Schools of Public Health and Medicine. A rich array of seminar programs and journal clubs are also available to all students.

Browse an overview of the requirements for this PhD program in the JHU Academic Catalogue and explore all course offerings in the Bloomberg School Course Directory .

Courses in core curriculum

Minimum elective credits

Seminars on current research presented by experts from across Johns Hopkins and other biomedical research institutions

Courses available across Johns Hopkins Schools of Public Health, Medicine, and Arts and Sciences

Admissions Requirements

For the general admissions requirements see our How to Apply page. The specific program also requires:

Prior Work Experience

Laboratory research experience (from academia, industry, etc.) is required

Prior Coursework

Strong background in the sciences, particularly in chemistry, biochemistry, or biology

Standardized Test Scores

Standardized test scores (GRE) are optional for this program. The admissions committee will make no assumptions if a standardized test score is omitted from an application, but will require evidence of quantitative/analytical ability through other application components such as academic transcripts and/or supplemental questions. Applications will be reviewed holistically based on all application components.

Program Faculty Spotlight

Ashani T. Weeraratna

Ashi Weeraratna, PhD, studies how cancer cells move to distant sites and how changes in the normal cells around a tumor contribute to their movement, especially as we age.

Michael J. Matunis

Michael Matunis, PhD, studies how protein modification by SUMO—the small ubiquitin-related modifier—drives changes in key cellular pathways from stress response to DNA repair.

Jennifer M. Kavran

Jennifer Kavran, PhD, MS, MPhil, is a biophysicist who investigates how cells communicate with each other and their environment.

Danfeng Cai

Danfeng Cai, PhD, combines advanced microscopy, genomics, and proteomics to tease out the functions of protein condensates in cells, with a focus on cancer.

Vivien Thomas PhD Scholars

The Vivien Thomas Scholars Initiative (VTSI) is an endowed fellowship program at Johns Hopkins for PhD students in STEM fields. It provides full tuition, stipend, and benefits while also providing targeted mentoring, networking, community, and professional development opportunities. Students who have attended a historically Black college and university (HBCU) or other minority serving institution (MSI) for undergraduate study are eligible to apply. To be considered for the VTSI, you will need to submit a SOPHAS application, VTSI supplementary materials, and all supporting documents (letters, transcripts, and test scores) by December 1 , 202 3 . VTSI applicants are eligible for an application fee waiver , but the fee waiver must be requested by November 15, 202 3 and prior to submission of the SOPHAS application.

All full-time PhD students receive the following support for all years of the program: full tuition and fees, individual health insurance, University Health Services fee, vision insurance, dental insurance, and a stipend for living expenses for students who remain in good academic standing. PhD students are required to serve as a teaching assistant for at least one term, in either their 2nd or 3rd year.

Need-Based Relocation Grants Students who are admitted to PhD programs at JHU starting in Fall 2023 or beyond can apply to receive a $1500 need-based grant to offset the costs of relocating to be able to attend JHU. These grants provide funding to a portion of incoming students who, without this money, may otherwise not be able to afford to relocate to JHU for their PhD program. This is not a merit-based grant. Applications will be evaluated solely based on financial need. View more information about the need-based relocation grants for PhD students .

Questions about the program? We're happy to help.

Mike Matunis, PhD PhD Program Director

Roza Selimyan , PhD BMB Executive Director for Academic Affairs and Education Programs

Erika Vaitekunas Administrative Specialist

[email protected]

Compare Programs

Check out similar programs at the Bloomberg School to find the best fit.
Master of Science (ScM), Offered by BMB
Master of Health Science (MHS), Offered by BMB
Master of Health Science (MHS), Offered by MMI
Doctor of Philosophy (PhD), Offered by MMI
Master of Health Science (MHS) in Environmental Health
Doctor of Philosophy (PhD) in Environmental Health

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Best Doctorates in Biotechnology: Top PhD Programs, Career Paths, and Salaries

Biotechnology companies are among the most profitable businesses in the modern era, contributing to the development of several widely used products. The best PhDs in Biotechnology allow graduate students to take part in this global biotech revolution.

Biotechnology is a very in-demand field. However, several people doubt whether a doctorate in this broad field is the best choice. This article clearly explains everything you need to know about a Biotechnology PhD. It also shares important information on the best biotechnology jobs and the average PhD in Biotechnology salary.

Find your bootcamp match

What is a phd in biotechnology.

A PhD in Biotechnology is an advanced degree that helps students further understand how to take advantage of biological processes to create products for various industries. Biotechnology PhD degrees are usually research-intensive and include a lot of lab work.

How to Get Into a Biotechnology PhD Program: Admission Requirements

The requirements to get into a biotechnology PhD program are dependent on the specific institution you are applying to. However, most universities have similar admission requirements for their biotechnology doctorate degree programs.

Usually, before you are accepted into a biotechnology PhD program, you must have at least a Bachelor’s Degree in Biology, Chemistry, or any related life science major. In addition, you will be required to submit your transcripts, personal statement, letters of recommendation, and resume. Finally, if you are an international student, you will need to take an English proficiency test.

PhD in Biotechnology Admission Requirements

Official transcripts
Letters of recommendation
Personal statement
Proof of English proficiency (for international students)

Biotechnology PhD Acceptance Rates: How Hard Is It to Get Into a PhD Program in Biotechnology?

It is very hard to get into a PhD program in Biotechnology. Biotechnology is a competitive field and most schools only accept a handful of students who apply to these in-demand PhD programs. For example, in the 2020-2021 session, Stanford University only accepted 4.6 percent of the total number of applicants into its Bioengineering PhD program.

How to Get Into the Best Universities

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Best PhDs in Biotechnology: In Brief

Best universities for biotechnology phds: where to get a phd in biotechnology.

The best universities in biotechnology are well-equipped with modern equipment. They also have experienced faculty members to guide you through your academic journey. If you are wondering where to get a PhD in Biotechnology, check out the top schools listed below.

Arizona State University , founded in 1885, is one of the best-rated universities in the United States for PhD programs. This public university currently has 139 doctoral programs available in various areas such as life sciences, arts, and business.

PhD in Molecular/Cellular Biology

Arizona State University's PhD in Molecular/Cellular Biology program is an 84-credit degree that teaches students how to understand biological activity from a cellular level. This program also covers topics in genetics and provides several electives for students to choose from, including a course on bionanotechnology.

PhD in Molecular/Cellular Biology Overview

Program Length: 4 - 5 years
Acceptance Rate: N/A
Tuition and Fees: $837/credit hour (in state); $1,308/credit hour (out of state)
PhD Funding Opportunities: Research fellowships, teaching assistantships

PhD in Molecular/Cellular Biology Admission Requirements

Bachelor’s or Master’s Degree in Biochemistry, Biological Sciences, or related field
Completed online application
Undergraduate applicants must have a minimum cumulative GPA of 3.0 on a 4-point scale in the last 60 hours of their degree program
Graduate applicants must have a minimum cumulative GPA of 3.0 on a 4-point scale
Transcripts
Three letters of recommendation
Proof of English language proficiency
Non-refundable $70 application fee; $115 for international students

Brown University is a research-focused university that trains students to create innovative solutions to complex global problems. It was founded in 1764 and offers 51 PhD programs in fields such as art and history, life science, and social science disciplines.

PhD in Biotechnology

The PhD in Biotechnology is offered by the Department of Molecular Pharmacology, Physiology, and Pharmacology at Brown University. This degree is a 24-tuition unit course and covers several concepts applied in industry jobs such as drug delivery and diagnostics. Graduates of this program will be able to work in diverse roles in the biomedical industry and academia.

PhD in Biotechnology Overview

Program Length: 3 years
Acceptance Rate: 10.5%
Tuition and Fees: $7,835/course per year
PhD Funding Opportunities: Teaching assistantship, research assistantship, fellowship, proctorship
Bachelor's Degree in Biology, Physics, Biochemistry, Engineering, or Chemistry
Online application form
$75 application fee
Proof of English proficiency (international non-native English-speaking applicants)

Founded in 1636, Harvard University is one of the oldest and most reputable learning colleges in the US. This private university has 14 schools and provides graduate education in several topics, including bioinformatics, applied physics, and architecture.

PhD in Molecular and Cellular Biology

Students enrolled in Harvard University's Molecular and Cellular Biology course will attend lectures spanning various biomedical science topics such as biochemistry, genetics, cellular biology, and microbiology. Upon graduation from this doctorate program, you will also be equipped with practical skills to enable you to work in diverse roles.

PhD in Molecular and Cellular Biology Overview

Program Length: 5 years
Tuition and Fees: $50,928 for first 2 years
PhD Funding Opportunities: Grants, stipends, teaching fellowships, research assistantships

PhD in Molecular and Cellular Biology Admission Requirements

Prior educational knowledge of chemistry, physics, biology, and mathematics
Graduate School of Arts and Sciences online application form
$105 application fee
Statement of purpose with a maximum length of 1000 words
Three letters of recommendation with at least one from a faculty member at previous university
TOEFL Internet-based test score of 80 or more for international students

Pennsylvania State University was established in 1855. It is a public university with over 20 campuses located in different areas of Pennsylvania. Pennsylvania State University delivers top-notch graduate programs in biomedical engineering and other life science-based disciplines. It also provides courses in the arts and social sciences.

PhD in Biomedical Engineering

This 29-credit doctorate degree program helps to prepare students to work in research institutions, academia, and industry roles. Students enrolled in the PhD in Biomedical Engineering program will study topics like bioimaging, drug delivery, and computational techniques for understanding biological systems.

PhD in Biomedical Engineering Overview

Tuition and Fees: $11,541/semester (in state); $19,624/semester (out of state)
PhD Funding Opportunities: Graduate assistantships, fellowships

PhD in Biomedical Engineering Admission Requirements

Bachelor's Degree in Engineering, Physics, or any life science discipline
Online application form via Pennsylvania State University's graduate school online application portal
$65 application fee
Score of at least 80 (TOEFL) or 6.5 (IELTS) for international students as proof of English proficiency
Statement of purpose
Resume (optional)

Stanford University was established in 1885 and has consistently ranked among the top colleges in the US for graduate students. Stanford University provides PhD programs in cancer biology, biochemistry, genetics, and several in-demand medical science fields. It also delivers top-quality education in engineering, business, and law-based topics.

PhD in Bioengineering

This five to six-year doctorate program is designed to provide students with a well-rounded educational experience in bioengineering. Participants will be allowed to rotate between three labs in their first year before deciding on their dissertation advisor. This program also includes in-demand courses such as systems biology and computational protein modeling.

PhD in Bioengineering Overview

Program Length: 5 - 6 years
Acceptance Rate: 4.6%
Tuition and Fees: $11,770/quarter consisting of 8 - 10 units
PhD Funding Opportunities: Fellowships, research assistantships, teaching assistantships, graduate student loans

PhD in Bioengineering Admission Requirements

Bachelor's degree from a related field
Scanned copy of academic transcripts via the application portal
Two-three page statement of purpose
TOEFL scores (international applicants from non-native English speaking countries)
Non-refundable $125 application fee

Syracuse University is a multidisciplinary private school founded in 1870. This university has 13 colleges and schools, including Visual and Performing Arts, Architecture, Engineering, and Computer Science, which offer reputable graduate programs.

The PhD in Bioengineering is a rigorous 42-credit hour program that usually takes about five years to complete. Students enrolled in this doctorate degree program will be allowed to choose from one of 10 currently available research areas, including molecular biotechnology, catalysis and reaction engineering, and metabolic engineering.

Tuition and Fees: $32,436/academic year
PhD Funding Opportunities: Fellowship, research assistantships, graduate assistantships, scholarships
Online application form on Syracuse University's graduate application portal
500-word personal statement
Proof of English language proficiency (for international applicants)
Financial documents, including proof of financial support (international students)
$75 application fee

Tufts University was established in 1852 to solve complex global problems through research. This private college has over 370,699 square feet of lab space spread across its four campuses. It offers graduate programs covering public policy, public health, business, and technology.

PhD in Biotechnology Engineering

Tufts University's PhD in Biotechnology Engineering program is provided by the Department of Chemical and Biological Engineering. This doctorate program is structured to allow individuals from different academic backgrounds to participate. It includes courses on protein purification, microbe cultivation, and cellular engineering.

PhD in Biotechnology Engineering Overview

Program Length: 4 years
Tuition and Fees: Covered by tuition scholarship
PhD Funding Opportunities: Teaching assistantships, research assistantships

PhD in Biotechnology Engineering Admission Requirements

Bachelor's degree in Biology, Biotechnology, Biochemistry, or Chemical Engineering
Online application
Non-refundable $85 application fee
Minimum TOEFL score of 90, an IELTS score of 6.5, or a Duolingo score of 110 (international applicants from non-native English speaking countries)

University of California, Berkeley has 14 schools and colleges and offers over 100 graduate programs for prospective students. Since its inception in 1868, the University of California has become a leading destination for graduate students due to its hands-on approach to learning and research.

PhD in Molecular and Cell Biology

The University of California, Berkeley's PhD in Molecular and Cellular Biology provides a deep dive into the structure and function of cells. It covers several essential aspects of medical and life sciences, including structural biology, genetics, computational biology, and immunology.

PhD in Molecular and Cell Biology Overview

Program Length: 3 - 5 years
Tuition and Fees: $5,721/semester
PhD Funding Opportunities: Fellowships, stipend

PhD in Molecular and Cell Biology Admission Requirements

Completed at least one year of chemistry, calculus, physics, and general biology in your undergraduate program
Completed advanced coursework in microbiology, cell biology, biochemistry, or other similar subjects
Graduated with a minimum GPA of 3.0 on a 4-point scale
Laboratory research experience
Submit TOEFL scores of 570+ (written test), 233 (computer-based test), or 90 (Internet-based test) for international applicants
Unofficial transcripts
GRE scores (optional)

The University of Pennsylvania , founded in 1740, delivers many top-rated graduate degree programs via its 12 graduate and professional schools. The University of Pennsylvania is one of the most popular public schools for graduate students, with over 16,000 students currently pursuing post-graduate education on its campus.

The Penn Bioengineering PhD was the first-ever doctorate bioengineering program in the US. This graduate degree program has a comprehensive curriculum to equip students with the technical skills to land the best jobs at biotech companies .

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Acceptance Rate: 15%
Tuition and Fees: $39,838/year
PhD Funding Opportunities: Fellowships, grants
Online graduate application form
Bachelor's degree in Engineering or a physical science, natural science, or math major
Submit TOEFL scores of 600+ (written test), 250 (computer-based test), or 100 (Internet-based test) for international applicants

Founded in 1969, the University of Texas, San Antonio has been recognized by Times Higher Education as one of the best young universities in the US . This public college has seven colleges and offers several highly-rated graduate degree programs.

PhD in Cell and Molecular Biology

Cellular and molecular medicine is one of the top new trends in pharmacological sciences for the future . This graduate degree program helps prepare students to play a significant role in this burgeoning industry. The PhD in Cell and Molecular Biology program also offers specialized tracks in Stem Cell, Molecular Microbiology, and Immunology.

PhD in Cell and Molecular Biology Overview

Tuition and Fees: $247.53/credit-hour (in state); $428.63/credit-hour (out of state)
PhD Funding Opportunities: Fully funded through internal grants

PhD in Cell and Molecular Biology Admission Requirements

Bachelor's degree in Biology or any similar field
Non-refundable $50 application fee; $90 international applicants
Students from non-native English speaking countries must score a minimum of 6.5 on the IELTS test, 79 on the internet-based TOEFL test, or 60 on the paper-based TOEFL test
International applicants must submit English proficiency scores of 6.5 (IELTS), 79 (Internet-based TOEFL) test, 60 (paper-based TOEFL)

Can You Get a PhD in Biotechnology Online?

No, you cannot get a PhD in Biotechnology online. Biotechnology PhDs usually involve hours of lab work and other technical aspects that can only be taught via an on-campus program. At the moment, if you are considering getting a biotechnology doctorate degree, you can only do so via an in-person program.

How Long Does It Take to Get a PhD in Biotechnology?

It takes three to five years to get a PhD in Biotechnology. Before you are considered eligible for a biotechnology PhD degree, you must have completed at least two years of coursework in various core topics. You will also need to carry out original research and present your findings in a dissertation.

Is a PhD in Biotechnology Hard?

Yes, earning a PhD in Biotechnology is hard. Biotechnology PhD students are required to carry out a lot of research and spend hours on lab work. However, you can earn your degree in the stipulated amount of time with commitment and effort.

How Much Does It Cost to Get a PhD in Biotechnology?

It costs $19,314 per year to get a PhD in Biotechnology , according to the most recent data released by the National Center for Education Statistics. However, your tuition costs can vary depending on the reputation of the school and the nature of your program.

For example, a PhD in Biotechnology costs about $25,929 per year for private institutions. Public universities, however, are much cheaper. The average yearly tuition cost for a PhD program at a public university in the US is $12,171.

How to Pay for a PhD in Biotechnology: PhD Funding Options

The PhD funding options that students can use to pay for a biotechnology doctorate program include teaching assistantships, research assistantships, and fellowships. Most universities provide incoming biotechnology PhD students with one or more of these options to reduce the cost of their tuition.

Best Online Master’s Degrees

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What Is the Difference Between a Biotechnology Master’s Degree and PhD?

The difference between a biotechnology master’s degree and a PhD is that a PhD program usually involves more intensive research and takes at least three years to complete. PhD degrees are typically pursued by individuals with a strong desire to contribute to existing knowledge in the biotechnology space. Master’s programs typically take two years to complete.

Master’s degree students spend a year or two on coursework and finish their program with a capstone project or thesis. Biotechnology PhD students spend at least two years on coursework and possibly longer on research before working on and submitting their dissertations.

Master’s vs PhD in Biotechnology Job Outlook

For job roles such as food scientist that are available to master’s degree graduates, the job outlook is 9 percent between 2020 and 2030, according to the Bureau of Labor Statistics. In comparison, biotechnology PhD jobs such as medical scientist roles are expected to grow by 17 percent in this same period.

Difference in Salary for Biotechnology Master’s vs PhD

According to PayScale, the average salary for professionals with a PhD in Biotechnology is $112,000 annually. However, in comparison, the average salary for master’s degree holders is $75,000 per year.

Graduates with a PhD degree have more experience and can command a higher salary and function in senior industry roles. Although a master’s degree is excellent for improving your career options, a PhD is better for landing the highest-paying job roles.

Related Biotechnology Degrees

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Why You Should Get a PhD in Biotechnology

You should get a PhD in Biotechnology because it can help you achieve your maximum potential in academia and propel the field further through your research. Biotechnology is a competitive field which means obtaining a PhD allows you to distinguish yourself from other candidates and increase your career options within the field of biotechnology.

Reasons for Getting a PhD in Biotechnology

Higher salaries. A PhD in Biotechnology will help you gather rare and specialized skills which usually translates to higher-paying jobs. You will become qualified for many senior industry positions and significantly increase your earning potential by obtaining an advanced degree.
Research opportunities. PhDs are research-focused degrees. So, if you are passionate about contributing to pre-existing scientific knowledge in the biological science space, a PhD in Biotechnology is an excellent way to add to your quota.
Networking opportunities. A PhD program is an easy way to connect with other specialists in biotechnology and build potentially beneficial academic or business relationships. You will also be meeting faculty members who have years of experience and can provide you with mentorship.
Boost your reputation. Getting a PhD is very useful for individuals seeking to establish themselves as an authority within the biotechnology space. PhD programs provide you with the necessary knowledge and research experience to become a leading voice in your industry.

Getting a PhD in Biotechnology: Biotechnology PhD Coursework

A biotechnologist working with test tubes in a lab environment

Getting a PhD in Biotechnology demands that you complete your course requirements as specified by your academic institution. The majority of PhD programs in biotechnology cover similar courses. Biotechnology PhD coursework usually spans cell biology, chemical engineering, and other scientific areas listed below.

Molecular Biology

In this course, PhD students in biotechnology will examine the mechanisms of biological activity from a molecular perspective. Graduate students taking a molecular biology course will be taught the structure and function of biological molecules. They will also learn the underlying scientific principles behind molecular interactions.

Introduction to Proteomics

Most advanced degree programs in biotechnology usually include an in-depth study of protein structure and function. Proteins are an essential component of cells and a pillar of several biological processes. Introduction to Proteomics teaches students about protein-protein interactions and relevant techniques for modifying proteins.

Bioengineering Fundamentals

Biological engineering is one of the most essential subjects for students pursuing an advanced degree in biotechnology. As a PhD candidate enrolled in a biotechnology program, you will learn scientific techniques for creating valuable products from biological systems. This course is helpful, especially for individuals seeking the best tech jobs at pharmaceutical tech companies .

Cell and Microbial Cultivation

Biotechnology specialists routinely carry out experiments with microbes. A cell and microbial cultivation course teaches students modern and relevant principles for culturing microorganisms in biotechnology labs. The technical skills obtained in this course will enable students to land a job with any of the leading biotechnology companies.

Introduction to Genomics

Genomics is a field of study in biological sciences that examines gene structure, function, and expression. In this course, students will be taught about concepts such as gene mapping, editing, and mutations. This course aims to provide students with the needed academic background to improve the quality of life in society through scientific interventions.

Best Master’s Degrees

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How to Get a PhD in Biotechnology: Doctoral Program Requirements

Unlike a Bachelor of Science in Biotechnology degree, doctoral program requirements are slightly more stringent. If you are interested in getting a PhD in Biotechnology, the requirements are outlined below.

Regardless of your university, each PhD program in biotechnology has a specified number of credit hours that graduate students must complete to be deemed qualified to receive a PhD certificate in biotechnology.

For most biotechnology PhD programs, you will be required to maintain a minimum passing grade of B, which is equivalent to a 3.0 GPA on a 4-point scale. Each school usually states its GPA requirements on its program page or catalog.

Seminars allow graduate students to demonstrate their knowledge of specific biotechnology topics. Attendance and participation in seminars organized by your university's biotechnology department is a vital requirement for obtaining a PhD in Biotechnology.

After carrying out a research project and gathering your findings, you will need to present your work to your faculty and other department members. A strong performance in your oral defense is mandatory for you to be eligible to receive your doctoral degree.

A thesis is one of the most essential requirements for students carrying out their doctoral studies in biotechnology. Your thesis is a write-up containing your findings from an original research project. For the duration of your thesis, you will be working closely with a supervisor who will provide guidance and instruction for your research efforts.

Potential Careers With a Biotechnology Degree

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PhD in Biotechnology Salary and Job Outlook

Biotechnology is an interdisciplinary field whose relevance cuts across several sectors. As a result, biotechnology jobs will continue to be in high demand. For example, according to the Bureau of Labor Statistics, the job outlook for principal medical scientists is expected to increase by 17 percent through to 2030.

What Can You Do With a PhD in Biotechnology?

With a PhD in Biotechnology, you can work in academia, research institutes, and biopharmaceutical companies. There are several high-paying career options for biotechnology PhD graduates. Some of these jobs are listed below.

Best Jobs with a PhD in Biotechnology

Industrial production manager
Senior biochemical engineer
Principal medical scientist
Biotechnology lecturer

What Is the Average Salary for a PhD in Biotechnology?

The average salary for a PhD in Biotechnology is $112,000 per year, according to PayScale. Obtaining a PhD in Biotechnology also significantly increases your earning potential. Compared to bachelor’s and master’s degree graduates, PhD holders earn considerably higher salaries and are eligible to work in the most challenging biotechnology roles.

Highest-Paying Biotechnology Jobs for PhD Grads

Best biotechnology jobs with a doctorate.

The best biotechnology jobs with a doctorate enable graduates to make notable contributions to fields such as healthcare, agriculture, and education. They also provide attractive salaries and require the application of biotechnology principles to solve complex problems.

Biochemists can typically be found in universities, research firms, or pharmaceutical companies. They must study biological processes and apply bioengineering principles to produce beneficial products. Most biochemists work as part of a team in a laboratory environment.

Salary with a Biotechnology PhD: $102,270
Job Outlook: 5% job growth from 2020 to 2030
Number of Jobs: 34,800
Highest-Paying States: Massachusetts, Virginia, Colorado, New Jersey, Oregon

Senior biomedical engineers work with scientists and other healthcare professionals in the clinical setting. Their responsibility is to carry out comprehensive biological systems research and create medical inventions based on their studies. They also gather data and write technical reports.

Salary with a Biotechnology PhD: $97,410
Job Outlook: 6% job growth from 2020 to 2030
Number of Jobs: 19,300
Highest-Paying States: New Mexico, Arizona, Minnesota, Connecticut, Massachusetts

A principal medical scientist conducts thorough studies on various biological phenomena. As a principal medical scientist, you will be required to design your research methods, gather data, and propose a hypothesis.

Salary with a Biotechnology PhD: $95,310
Job Outlook: 17% job growth from 2020 to 2030
Number of Jobs: 133,900
Highest-Paying States: Connecticut, Maine, Delaware, New Jersey, Tennessee

Biotechnology lecturers can be found in universities. They work as part of their academic institution's biotechnology department to carry out research and train students in modern biotechnology applications.

Salary with a Biotechnology PhD: $79,640
Job Outlook: 12% job growth from 2020 to 2030
Number of Jobs: 47,690
Highest-Paying States: Arkansas, California, New Hampshire, California, New York

Food scientists are research-oriented professionals. They use their knowledge of biology and chemistry to improve the quality of food products and devise safe and effective food processing methods. As a food scientist, you will be working predominantly in the laboratory as part of a research team.

Salary with a Biotechnology PhD: $74,160
Job Outlook: 9% job growth from 2020 to 2030
Number of Jobs: 37,400
Highest-Paying States: Colorado, Kansas, Connecticut, Ohio, Minnesota

Is a PhD in Biotechnology Worth It?

Yes, a PhD in Biotechnology is worth it. Biotechnology is a vast field with several highly profitable industry jobs. Therefore, individuals with expert knowledge of biological processes and how to create valuable products using bioengineering techniques are in high demand.

With a PhD in Biotechnology, you can work in pharmaceutical, cosmetic, agricultural, food processing, and medical diagnostic companies. Although graduates with a bachelor’s or master’s degree can still get a very high-paying job within these fields, a PhD will increase your pool of choices and enable you to land senior roles which attract the best salaries.

Additional Reading About Biotechnology

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PhD in Biotechnology FAQ

The academic background needed for a biotechnology PhD includes a Bachelor’s or Master’s Degree in Biology, Chemistry, Microbiology, or any other life science discipline. Individuals with art or social science backgrounds will not be eligible for admission into a biotechnology PhD program.

Yes, a biotechnology graduate can work in the agricultural sector. Several companies that manufacture agricultural products have research teams that investigate potential methods to improve the quality of their produce. PhD holders in biotechnology can easily find jobs in any of these organizations.

Yes, biotechnology is a very interesting field. If you are intrigued by biology or chemistry and want to know how you can translate your knowledge of life science concepts into innovative solutions to complex problems, then you will enjoy participating in a biotechnology doctorate program.

Yes, there are many good jobs for biotechnology PhD graduates. Biotechnology offers an abundance of career opportunities in academia and the biotechnology industry. Through a PhD program, you can acquire rare and in-demand skills, which will help you land a fantastic job.

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What does a PhD in Biotech Involve?

The aim of a university PhD programme in Biotechnology is to prepare you to start and complete theoretical, methodological and research training in the multidisciplinary field of biotechnology, which takes the form of the preparation and defence of an innovative doctoral thesis.

Examples of topics you could investigate as part of your PhD research project include:

Biomedicine: a field of study that focuses on understanding the cellular and molecular biology processes and their applications. It focuses on finding cures for diseases such as Alzheimer’s, cancer, etc.
Plant biotechnology : area of study oriented towards fundamental and applied research in plant physiology and cell biology, functional genomics and plant-pathogen interaction.
Bioinformatics: related to programming and data analysis in health issues and nanotechnology and computational modelling of biological systems. Research in nanoparticle biogenesis, microscopy, bioprocess engineering, systems biology and molecular modelling.
Aquaculture biotechnology: a combination of science and practical skill in fish farming. The primary objective is to generate knowledge that can increase the productivity of aquaculture.
Microbial biotechnology: focuses on both fundamental and applied research into the functioning of biological systems such as bacteria, viruses and yeasts for the generation of value-added products such as nanoparticles, proteins, biopolymers and probiotics.

A doctorate training programme in biotechnology aims to train PhD students to:

Independently, with capacities, knowledge and skills to identify opportunities, develop and direct relevant research projects to develop biotechnological.
Recognised for their ability to create knowledge and provide technological solutions in biotechnology for research centres, productive, educational and social sectors.
Capable of linking up with the private sector so that the research is translated into improved technologies, processes and products that drive a country’s development.
Ability to create, disseminate and ethically impart knowledge with a strong sense of responsibility and social duty.

Browse PhDs in Biotechnology

A next-generation genetic technology to identify biotechnologically-valuable enzymes and transporters, ubiquitin-dependent signalling pathways in ageing, exploring the impact of microplastic-bacterial complexes on animal health and the gut microbiome, energy dissipation in human soft tissue during impacts, micro-manufacturing of surface textures for enhanced electrosurgery, how long does it take to get a phd in biotechnology.

A Biotechnology PhD in the UK commonly takes between three and four years to complete if studying full-time, including a year for writing up your thesis , and between five and seven years if studying part-time or as distance learning.

What are the typical application requirements for a Biotech PhD?

The entry profile of a PhD candidate for a Biotechnology degree is a prospective student with an undergraduate degree, typically a 2:1 Master’s degree, in a field related to Biotechnology, Microbiology, Biochemistry, Food Science and Technology, Veterinary Medicine, Chemistry and Engineering. A background in biology is particularly favourable.

In addition to this, candidates will be expected to have:

Excellent academic background and have a vocation for a graduate research area in one of the fields of knowledge promoted by the doctoral programme.
Good written and oral communication skills in English.
If you’re an international student, you must meet the university’s minimum English language requirement. This will typically be through an IELTS (Academic) or TOEFL examination.

How much does a PhD in Biotechnology cost?

Annual fees will depend on whether you’re a home or international student and the specific university you study within. However, annual tuition fees typically range between £4,407 – £15,607 for full-time study, and £2,203 – £7,803 for part-time study.

Career in Biotechnology for PhD Holders

Not everyone knows there are many career options available with an advanced degree in biotechnology , especially at a doctorate level. As such, biotechnology graduates do not strictly need to pursue a career as a scientist at a medical company.

Those who possess a higher education doctorate in biotechnology will be capable of working in the academic, scientific and industrial fields, both in the application and generation of knowledge. Research degree holders will have excellent communication skills and the capacity for critical analysis and scientific reasoning, which allows them to formulate complex problems and propose innovative solutions to them, leading groups of applied research in laboratories of public and/or private institutions.

Because of this, biotech PhD postgraduates can take up an opportunity from a range of industries, including:

Quality Assurance and Control
Manufacturing industry
Clinical research
Government policymaking
Research & Development
Software engineering
Chemistry, biological science, and agriculture
Business and Project management
Biomedical science and Engineering

As well as undertaking a range of positions, biotech PhD holders can also work in a range of environments such as for government agencies, private companies, regulatory bodies, or clinical laboratories. People in biotech jobs range from small start-ups to big pharma companies to national departments such as UKRI.

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Bioengineering PhD Model Program

Bioengineering is a diverse and growing field encompassing many topics including biomaterials, biomechanics including robotics, biophysics and neuromotor control.

The guidelines given here form a starting point for a discussion with the faculty about areas of interest. Students should become familiar with both these bioengineering course guidelines as well as the school's overall PhD course requirements , and work in close consultation with their advisors to develop an individualized program plan that is consistent with those requirements. Courses provide the background knowledge that is needed to successfully complete research and allow students to learn more broadly about a field or related fields in a structured fashion.

Students can consider structuring their coursework in the following framework:

Applied math and computation, 2-3 courses. The goal is to acquire analytical and computational tools for modeling and data analysis. Typical courses include AM 121, AM 201, AM 205, AM 216, AM 232, AC 209a.
Cells, Tissues, and Biomaterials: ES 222, ES 230, ES 221, ES 228, ES 220, ES 293, ES 240, AP 225, AP 235
Applied Mechanics: ES 240, ES 241, ES 246, ES 228, ES 220, AP 235
Signal, Image and Data Processing: ES 201, ES 226r, ES 250, ES 255, AM 254, CS 283
Controls and Robotics: ES 201, ES 202, ES 226r, ES 249, ES 259, ES 252r, CS 289
Medical Imaging & Image Processing: CS 283, ES 250, ES 258, ES 293
Design and Instrumentation: ES 227, ES 228, ES 259, ES 276, ES 277, ES 291, PHY 223
Physiology and biology, 1-2 courses. Background in biological function that informs thesis research and prepares students for future research in bioengineering. Subject areas may range from molecular to cellular to organs to system-level anatomy and function. Typical courses include: ES 222, CELLBIO 304qc.

It is also worth noting that Harvard and MIT students may cross register for courses at either institution.

The Model Program provided above is intended to provide guidance and should not be construed as a requirement; students, in consultation with their advisor(s) , have the flexibility to construct any Ph.D. Program Plan that meets the overall PhD Program course requirements.

In Bioengineering

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PhD in Biotechnology

Biotechnology, phd: 1st year.

Other requirements for the PhD program include:

Additional electives that emphasize individual research themes
3.25 GPA in core classes (listed above)
Oral critique of a current research article
Research progress report with oral presentation
1-3 teaching assistant assignments
Attendance and participation in the Departmental Seminar Series
Research committee meetings and thesis defense

** Additional program details are provided in the Graduate Handbook

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Phd programme in biotechnology, biotechnology.

PhD programme (doctoral education)

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PhD Full time, 3 years
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The objective of the PhD programme in Biotechnology is to prepare the PhD candidates for work that requires advanced scientific expertise and analytical skills and for a career in academia.

The PhD programme in Biotechnology is closely linked with our research groups and departments, and is a key component in the overall research strategy at the Faculty of Natural Sciences.

About the programme

The Department of Biotechnology and Food Science is responsible for the major research area biotechnology. Research is performed in cooperation between departmental and external research groups. Both basic and applied research topics are addressed.

The Department of Biotechnology and Food Science offers 13 courses on the PhD level.

Research areas

Biopolymer chemistry and bio-nanotechnology
Determination of polysaccharide primary structure
Enzymatic, chemical and physical modification of polysaccharides
Determination of conformation in solution and gel phase
Interactions between polysaccharides and ions, enzymes, antigens, DNA and RNA
Non-viral gene delivery using chitosans
Nanostructure, phase behaviour and rheology in biopolymer gels, films, emulsions and suspensions
Alginate based capsule technology for treatment of diabetes
New experimental methods for characterization of polysaccharides
New biomedical and pharmaceutical applications of alginates, chitosans, gelatine, sphagnan, beta glucans, glycoproteins and proteoglycans
Capsule- and gel technology applied in food

Marine biochemistry/mariculture

Production of fatty acids (DHA) in marine microorganisms
Marine biopolymers – from raw material to biological applications
Fish gelatins: Properties and modifications
New antibiotics from marine bacteria
Capsule- and gel technology in feed technology

Molecular genetics/Microbiology

Studies of the mechanism for plasmid replication, construction of cloning vectors and analysis of recombinant protein expression
Genetic analysis of the production of antibiotics in bacteria
Studies of molecular mechanisms for cellular osmoregulation
The genetics of alginate biosynthesis and function studies of the enzyme structures
Oil microbiology
Development of new plasmid tools for use in bioprospecting
Microbial producers of bioactive agents from the marine environment

Biochemical engineering

Production of secondary metabolites in bacteria
Microbiological aspects in food science
Microbial production of lysine from methanol

Food chemistry

Superchilling
Utilization of Calanus
Using NMR to study water and salt during salting of fish and meat
Application of NMR for determination of food authenticity
Lipid oxidation
Ethical slaughtering of white fish
Production of stable marine oils

Environmental biotechnology/Microbial ecology

Biofilm formation and biofouling
Gel-immobilized microbial ecosystems
Anaerobic fermentation of organic material
Directing microbial environment in marine aquaculture
Mechanisms for bacterial colonization and directing microbial environment in marine aquaculture
Structure and stability in natural pelagic ecosystems

Programme structure

The PhD education is a structured degree with a nominal duration of three-year full-time study . Some PhD positions may include a fourth year of required duties, usually in the form of teaching, this will be detailed in your employee contract if applicable.

Career opportunities

A PhD degree is the highest level of formalised education in Norway.

A doctoral degree from NTNU qualifies you to a range of positions both in the private and public sector. Academia has traditionally been the main career path for doctors, but now an increasing number of doctors are going into leading positions in the private sector.

How to apply and admission

To be accepted to a PhD programme at NTNU, you must have:

a funding plan
completed at least five years of higher education that includes a master's degree or other equivalent degree.
a strong academic record and a weighted average for the last two years of your master's degree equivalent to a B or higher in NTNU's grading scale.

Applications for admission to the PhD programme must to be submitted through the Department of your subject area

Read more about how to apply and admission

Administrative contact

Maja Caroline Haaker Senior Executive Officer

Academic contact

Ingrid Bakke Professor and Deputy of Research at the Department of Biotechnology and Food Science

PhD in Biology and Biotechnology

As a student in WPI’s PhD in Biology and Biotechnology program, you will benefit from close mentorship by dynamic faculty who encourage creativity and inquisitiveness.

Value Proposition Description

Enabled by a world-class research infrastructure, students in our competitive program explore their passion for discovery while driving cutting-edge, hypothesis-driven research. You will work alongside interdisciplinary teams of WPI faculty, peers, and industry partners to make an impact in your field and explore topics that matter to you, from cancer biology and immunology research to studies of brain plasticity and pollinator decline.

Through our well-rounded PhD in Biology and Biotechnology, you will delve into immersive research in biology and biotechnology while also sharpening your professional and pedagogical knowledge and skills. You will take core courses covering professional ethics, grant writing, and experimental design, and hone your communication skills by participating in department-wide research presentations. You may also take part in supervised teaching experiences and discuss interdisciplinary research initiatives in our Journal Clubs.

Students complete a qualifying exam by the end of the second year of study and round out required coursework with electives. Completion of PhD studies concludes with the preparation of a written thesis and successful oral defense.

To treat many infectious diseases, including the global scourge of tuberculosis, doctors must do battle with a wily adversary, bacteria. Unfortunately for afflicted patients, bacteria have also acquired strategies for thwarting attacks from the immune system and the onslaught of antibiotic drugs. We need to know more about the strategies bacteria use to survive stresses. Biology and biotechnology professor, Scarlet Shell, is seeking to do just that by probing the molecular changes that underlie these mechanisms.

WPI's Department of Biology and Biotechnology is home to a diverse and dynamic faculty body that employs cutting-edge research to explore and understand research topics at the intersection of biology and technology. You will work alongside them as you make your own discoveries in these research areas:

cancer cell biology
cognition and behavior
cytoskeletal dynamics
drug resistance
epigenetics and gene regulation
infectious diseases
neuronal migration and degeneration
regenerative medicine
signal transduction mechanisms

Grad students work closely with faculty and with each other. The opportunity for potential brings new ideas to the forefront and enhances the work everyone does here.

Students in WPI’s BBT program have access to the state-of-the-art labs and multidisciplinary collaborations in the Life Sciences & Bioengineering Center at Gateway Park.

Well-equipped BBT facilities mean you’ll be supported in your research endeavors whether that involves an AAALAC-accredited vivarium with surgical suites, NMR, or a greenhouse.

WPI’s biology and biotechnology graduate degree programs are rigorous yet flexible to provide students with the appropriate backgrounds in both the theory of biology and the practice of biotechnology.

Work in WPI’s biology and biotechnology labs has real-world applications that impacts problems on a human scale.

The BBT program is rigorous, flexible, and comprehensive, so students are prepared for whatever the next step in their career path brings.

PhD candidates are encouraged to review the department's faculty pages to identify potential advisors.

You will have access to state-of-the-art equipment in WPI’s Life Sciences and Bioengineering Center, a research complex where an open-plan lab and presence of biotech companies encourage interdisciplinary collaborations. Facilities include an analytical instrumentation core equipped for NMR, Mass Spec, X-Ray Crystal, and qPCR analysis; imaging core with advanced microscopes for point-scanning confocal, spinning disk confocal, and TIRF microscopy; and AAALAC-accredited vivarium.

Faculty Profiles

Work in my lab is focused on defining the cellular mechanisms that maintain genome stability in normal cells and understanding how these pathways are corrupted in cancer cells.

Defining signaling pathways that program cellular diversity is one of the foremost problems in biology and is central to my research interests. In the lab we use molecular, genetic, and biochemical approaches to characterize the function of these pathways and to gain insight into their role in disease. To date, the lab has focused on the Epidermal Growth Factor Receptor network, a principal therapeutic target for a variety of human cancers.

I deeply enjoy teaching, in particular conveying the important roles played by plants. It is a great reward when my students realize that plants are more complex and interesting than they anticipated, and they want to learn more. I enjoy that students at WPI are open about thinking in new ways; this critical thinking is the result of intense project-based learning.

Prof. Weathers is an internationally recognized expert on Artemisia annua and artemisinin, having worked with the plant and its phytochemicals including the antimalarial drug, artemisinin, for >25 years. She is a Fellow of AAAS and SIVB, won many awards, given many national and international presentations, reviews manuscripts for many journals and proposals for many national and international funding agencies. She is an Associate Editor for multiple journals. Her lab was the first to genetically transform A. annua.

Our lab investigates the molecular basis of phenotype switching in human fibroblasts that can be modulated using defined extracellular stimuli. We evaluate the role of oxygen and growth factor FGF2 isoforms independently and in combination in order to identify key molecular mechanisms and pathways, some of which closely mimic mechanisms described in human embryonic stem cells. Extended lifespan of these cells in culture also offers us a model for investigation of molecular mechanism that are regulating cell cycle in the context of both aging and cancer.

My lab works broadly in the emerging field of synthetic biology. Synthetic biology seeks to apply engineering design principles to the understanding and creation of biological systems. I use synthetic biology to design biosensors and bioremediation strategies for various environmental contaminants that impact human health, including lead, arsenic, and other toxic substances. We apply the tools of synthetic biology to address global challenges related to water, soil, and human health.

Research in my laboratory addresses questions in the field of evolutionary ecology and environmental biology, and typically combines field work and laboratory studies. Current projects focus on two disciplines.

A member of the WPI faculty since 2004 and chair of the Department of Biology and Biotechnology since 2022, Reeta Rao is a leader in the field of molecular genetics and genomics. Her primary research activities are focused on emerging infectious diseases, specifically understanding and managing fungal diseases. Students and research associates in her laboratory are trained to use a variety of biochemical, molecular-genetic, and genomic tools to study host-microbe interactions to explore fungal virulence strategies and identify novel therapeutics in a high through

I have a passion for understanding how living systems work, as well as for sharing my love of biology and research with the next generation of scientists and informed citizens.

The central goal of my lab is to understand the regulatory mechanisms that underlie mycobacterial stress tolerance. We combine genetics, genomics, transcriptomics and biochemistry to understand how mycobacteria respond to, and ultimately survive, stressful conditions.

It has been my lifelong dream to become a professor in the field of Biology. Being a faculty member provides a great opportunity to teach and interact with students. Students by nature are highly inquisitive and motivated, and as teachers, we have the responsibility to guide our students to explore and think in new ways. I believe that teaching is a two-way interaction between teachers and students. I come from India and my parents, both of whom were teachers, taught me to strive for excellence in my scholarly pursuits.

PhD Student

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Earn a Master’s Degree in Biology & Biotechnology First

Are you interested in making advanced discoveries about living organisms in a robust community of like-minded researchers, but need your master’s to get there? Consider earning a master’s in biology and biotechnology where you’ll participate in cutting-edge laboratory training and gain professional training in areas like experimental design, ethics, and more. Do you prefer advancing a career in the biotech industry from making cross-functional decisions to gaining expertise in bio-production? Our online master’s in biotechnology is a skills-focused program perfect for students who are working professionals looking to study part-time. Maybe you have a strong foundation in computer science and statistics? Consider earning a master’s in bioinformatics and computational biology which dives into leveraging biological data to improve health care.

Get Started with a BS in Biology & Biotechnology or a Minor in a Related Field

If you’re interested in the field but need your initial degree, a bachelor’s in biology & biotechnology is the first step. This degree introduces you to how the theory of biology is put into practice with biotechnology. If your interest lies in gaining enough information to use in a different discipline or practice, WPI has minors that will deliver the skills and knowledge you seek. A minor in biology is an excellent addition to your academic program and will be relevant in many industries including biomechanics, big data, or personalized medicine. Or maybe you’re seeking a global perspective. WPI’s interdisciplinary minor in global public health examines biological, social, political, environmental, and economic influences on the health of diverse and varied populations.

WPI is proud to be the recipient of not one, but two National Science Foundation Research Traineeship programs. The programs provide exceptionally talented graduate students with specialized training and funding assistance to join careers at the forefront of technology and innovation. The programs are for graduate students in research-based master's and doctoral degree programs in STEM. Learn more .

The BioPoint Program for Graduate Students has been designed to complement traditional training in bioscience, digital and engineering fields. Students accepted into one of the home BioPoint programs will have the flexibility to select research advisors and take electives in other departments to broaden their skills. BioPoint curriculum is designed to be individual, interactive, project-focused and diverse, and includes innovative courses, seminars, journal clubs and industrial-based projects. Learn more .

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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 2,520 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 1,461 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 3,486 views 3 citations

Perspective 27 May 2022 Gene Editing to Accelerate Crop Breeding Kanwarpal S. Dhugga 3,525 views 8 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 2,222 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 1,744 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 5,904 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 1,898 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 8,283 views 8 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 2,434 views 4 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 3,627 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 9,128 views 35 citations

Review 25 April 2022 Biotechnological Road Map for Innovative Weed Management Albert Chern Sun Wong , 3 more and Bhagirath Singh Chauhan 5,002 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 2,018 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 7,391 views 15 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 1,449 views 3 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 1,860 views 13 citations

Ph.D. in Biotechnology

The Department of Biosciences and Technology offers research-intensive PhD programmes designed to help postgraduate students develop research skills and prepare for careers in academia or research.

The scholars, researchers and guides at the Department are engaged in research in diverse research areas of fundamental & applied biology like molecular microbiology, genomics, Bioinformatics, Cell biology, Plant biotechnology, Proteomics, Nanobiotechnology, Biosensors, Biomimetics, Complexity Biology, Applied Microbiology and Biotechnology, Metabolomics, Biofertilizers, Biocontrol and Integrated Nutrient Management.

The Department also focuses on advanced interdisciplinary translational research in the areas of Point-of-Care biosensors, diagnostic tools, multiplexed detection methodology, Lab-on-Chip devices, nutraceuticals and bio-actives production.

Microbial Culture laboratory
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The Department of Biosciences and Technology, MIT-WPU welcomes dedicated and motivated students passionate about science and technology to pursue promising research prospects.

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Ph.D Programme Fees

The following candidates are eligible to seek admission to the Ph.D. programme

Candidates who have completed:

i) A 1-year/2-semester master’s degree programme after a 4-year/8-semester bachelor’s degree programme or a 2-year/4-semester master’s degree programme after a 3-year bachelor’s degree programme or qualifications declared equivalent to the master’s degree by the corresponding statutory regulatory body, with at least 55% marks in aggregate or its equivalent grade in a point scale wherever grading system is followed or equivalent qualification from a foreign educational institutions accredited by an assessment and accreditation agency which is approved, recognized or authorized by an authority, established or incorporated under a law in its home country or any other statutory authority in that country to assess, accredit or assure quality and standards of the educational institutions.

A relaxation of 5% marks or its equivalent grade may be allowed for those belonging to SC/ST/OBC (non-creamy layer)/differently-abled, Economically Weaker Section (EWS) and other categories of candidates as per the decision of the commission from time to time.

Provided that a candidate seeking admission after a 4-year/8-semester bachelor’s degree programme should have a minimum of 75% marks in aggregate or its equivalent grade on a point scale wherever the grading system is followed. A relaxation of 5% marks or its equivalent grade may be allowed for those belonging to SC/ST/OBC (non-creamy layer)/Differently-abled, Economically Weaker Section (EWS) and other categories of candidates as per the decision of commission from time to time.

ii) Candidates who have completed the M. Phil programme with at least 55% marks in aggregate or its equivalent grade in a point scale. A relaxation of 5% marks or its equivalent grade may be allowed for those belonging to SC/ST/OBC (non-creamy layer)/Differently abled, Economically Weaker Section (EWS) and other categories of candidates as per the decision of commission from time to time.

Reservation is applicable only to Maharashtra domicile candidates provided they submit the necessary documents for reservation before interview. Outside Maharashtra candidates will be considered in open category.

1. Candidates satisfying eligibility criterion shall be called to appear for the Ph.D. entrance test conducted by MITWPU. The exemption will be given from Ph.D. entrance test for those students who qualify UGC-NET /UGC-CSIR NET /GATE (valid score)/CEED/GPAT (valid score)and similar national tests.

2. PhD entrance test shall be qualifying with qualifying marks as 50% provided that relaxation from 50% to 45% shall be allowed for the candidates belongs to SC/ST/OBC (Non creamy layer)/Differently abled category, Economically Weaker section (EWS) and other category of candidates. The syllabus of entrance test shall consist of 50% of research methodology and 50% shall be subject specific.

3. The interview/viva-voce will be conducted by the university for test qualifying candidates. For selection of candidates a weightage of 70% to the entrance test and 30% to the performance in the interview/Viva-voce shall be given. For GATE/NET/JRF /SET/GPAT/CEED qualified students, the selection will be based on Interview/Viva Voce

4. The recommended candidates will be intimated through email about their selection and the candidates will be offered Ph.D. provisional admission.

5. The eligibility of a candidate is provisional as per information provided by the candidate in his/her application form and is subject to verification of minimum eligibility conditions for admission to the program, educational documents and reservation documents (if any).

6. University keep rights to cancel admission of the Ph.D. scholars in the case of misconduct by the scholar, unsatisfactory progress/absent for consecutive two progress seminars, failure in any examination related to Ph.D., fabrication found in educational and reservation documents, candidate is found ineligible, involved in plagiarism in paper publications and thesis.

7. Provisional eligibility to appear in the selection process is no guarantee for admission to the program.

8. Candidates who will join PhD program full time, they will be provided with the stipend as per MITWPU norms.

9. PhD admission will be confirmed after successful completion of the course work with 55% or more as per UGC norms. Ph.D. programme should be minimum of three years including course work and maximum of six years from the date of admission to the Ph.D. programme.

10. A maximum of an additional two years (2) years can be given through the process of re-registration provided, however, that the total period for completion of a Ph.D. programme should not exceed eight (8) years from the date of admission in the Ph.D. programme.

11. Provided further that, female Ph.D. scholars and persons with Disabilities (having more than 40% disability) may be allowed an additional relaxation of two years(2) ; however the total period for completion of a Ph.D. program in such cases should not exceed ten (10) years from the date of admission of the programme.

12. Female candidates may be provided Maternity Leave/Child Care Leave for up to 240 days in the entire duration of Ph.D. programme.

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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.

Frequently asked questions

What are some biotechnology research proposal topics .

Some of biotechnology topics are:

What are the research areas in biotechnology ?

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Should You Get a Master’s or a PhD in Biotechnology?

Industry Advice Science & Mathematics

The job outlook for biotechnology professionals is very positive, with 2020 salaries averaging between $80,000 and $90,00 per year. As a result, many individuals are pursuing advanced degrees in biotechnology in hopes of acquiring the training and experience needed to land a role in this lucrative field.

Luckily, those with an undergraduate degree have the benefit of tailoring their graduate education by choosing to enroll in either a biotech master’s or a PhD program. Read on to explore how these two programs differ and what the five key aspects you should consider when deciding which is the right fit for you.

Choosing a Master’s vs. a PhD in Biotechnology: What to Consider

1. your career goals.

Perhaps the most significant question you can ask yourself when picking between a master’s and a PhD is, “What do I intend to do with my degree?”

For example, because PhDs require an extensive time commitment and provide students the chance to explore the academic side of the field, individuals who want to pursue research are best suited for this degree.

“If you want to be an academic, you absolutely have to get a PhD,” says Jared Auclair, director of the biotechnology and bioinformatics programs at Northeastern. Conversely, he explains, “if you want to go work the industry, a master’s is the way to go.”

A master’s degree is designed to transition students seamlessly from the classroom into the workforce. These programs tend to be shorter, and they provide chances for hands-on learning within real-world organizations. In short, they are developed in a way that allows students to begin shaping their careers in biotech before they even graduate.

“Because a master’s degree takes less time schooling-wise, you can go out and work in the industry sooner, get hands-on experience, and then move up in the chain of command,” Auclair says.

Learn More: Industry vs. Academia: Which is Right for You?

PhD candidates considering work in industry (versus academia) are not as easily set up for success. This is because, while a PhD candidate is spending years in a classroom, professionals with master’s degrees are already out in the field collecting valuable real-world experiences that will help prepare them to advance within an organization.

And while there are still some companies that might value a PhD applicant’s extensive study over a master’s degree applicant’s time in the workforce, Auclair explains that, in most cases, a master’s is really all a hiring manager is looking for among applicants.

“In most of the job postings I see…companies are looking for those with master’s [degrees], not PhDs,” he says, noting that there are only a few situations where, in C-level leadership roles specifically, a PhD candidate might have an edge.

2. Curriculum

“A master’s program and a PhD program in biotechnology will have similar coursework,” Auclair says. Both are designed to provide students with an expansive understanding of the field, including the tools, practices, and trends that define it today.

In a PhD program, however, students will have the opportunity to specialize in a specific area of practice within the larger biotechnology field. “A master’s offers a broader depth of training…[whereas] PhDs are trained to do something very specific,” he continues.

As a result, master’s students may end up taking more classes and leaving with a much broader and holistic understanding of the field than their PhD counterparts.

3. Program Length

A master’s program is designed to be completed quickly so that students can explore opportunities within the industry earlier in their careers. At Northeastern, for example, the master’s in biotechnology program can take anywhere from two to three years to complete, depending on whether a student pursues it in a full-time or part-time capacity.

A PhD, on the other hand, requires a much longer time commitment. After completing core classes, PhD students complete a three- to five-year research project with the faculty of their program, effectively delaying their release into the workforce.

4. Experiential Learning Opportunities

The experiential component of a student’s education is perhaps the biggest differentiator in the structures of PhD and master’s programs.

Students who pursue their master’s at Northeastern, for example, have unparalleled opportunities to practice their skills hands-on at organizations in the industry before ever entering the workforce.

“Our master program has a mandatory co-op , which is 12 weeks to six months of experience in the industry,” Auclair says. This paid and credited work provides students with the chance to explore the trends of the industry first-hand, network with leaders in the field, and begin to develop working relationships with organizations they may hope to be employed by after they graduate.

Just as industry experience prepares master’s students to thrive in the field, many PhD programs provide experiential learning opportunities for their students that expose them to the types of research and academia they can expect to pursue post-graduation.

“After you do your mandatory coursework for your PhD, you’re going to do a research project with a faculty,” Auclair says. “And that’s not industry experience, it’s academic research experience, which is completely different.”

This academic research gives students a chance to become comfortable in a lab or research setting, gain exposure to some of the technology and tools they will use in practice, and begin developing working relationships with professors and other university faculty.

5. Demands of the Industry

Some professionals considering an advanced degree do so knowing exactly what they want to do with their careers. For these individuals, the process of deciding between a master’s and a PhD may stop after consideration of their career goals.

However, some individuals embark on advanced education not to fulfill a specific career objective, but to simply pursue their passion for biotechnology. These individuals should think about not only what career opportunities each program might lead to, but which degree will best set them up to meet the current demands of the industry.

For example, the COVID-19 pandemic has created a plethora of lucrative possibilities for those in the biotechnology sector. Between a need for expedited vaccine development, a rethinking of telemedicine, and much more, Auclair notes there will be many new and exciting opportunities for those hoping to get involved.

“With COVID…sciences and new technologies are going to evolve rapidly,” he says. “The master’s degree sets you up to be more nimble and flexible [in order] to adapt to those [changes] and to really have a broader impact.”

Though there are opportunities for PhD holders to carve out a place for themselves in the industry, Auclair explains that the depth and type of training required at their level don’t as easily translate.

“Traditionally a person with a PhD is very specialized in one specific technique or aspect of the sciences, whereas somebody with a master’s is [better] able to adapt to the evolution of where the science is going to go. I’m not saying that PhDs can’t do that, but it’s typically not as easy for them.”

Weighing Your Options

If you’re considering a career in biotechnology, an advanced degree provides a perfect opportunity to gain the training and hands-on experience necessary to thrive within this ever-evolving field.

The Master of Science in Biotechnology at Northeastern, for example, has been designed with the input of industry experts and is constantly evolving to best prepare its students to meet the changing needs of the field.

“Part of my mission is to develop all of our programs in collaboration with industry,” Auclair says. “[We] monitor the trends and evolve and adapt as the trends evolve and adapt so that we’re producing people who are ready to work in the business of today or tomorrow, and not of yesterday.”

Northeastern has also taken steps to create opportunities for students who want both the industry exposure of a master’s degree with the cumulative title of a PhD.

The Experiential PhD is a unique program that allows students to work toward their PhD while simultaneously holding a full-time position within the industry. While this degree can be applied to any field, it’s particularly relevant to master’s degree holders who later realize they want to specialize their knowledge or to pivot their career toward research.

Northeastern’s master’s in biotechnology is designed to effectively complement this degree, as well. The Experiential PhD allows students to build off the holistic understanding of the industry obtained at the master’s level, preventing them from repeating much of the same coursework over again as they would in pursuit of a different science-based PhD.

The way it works, Auclair explains, is that “when you have your master’s…and you’re working at a company, you find a mentor in that company and a mentor at the university, and you [choose and then] work on a project that’s interesting to all three of you.”

This type of industry-applicable PhD is ideal for those who have already spent time working within organizations in the field. It allows you to advance your education while still continuing to function as an employee at your company. “You get all the benefits and the money and the salary and everything, but you’re still getting your PhD and it [only takes] three years,” Auclair says.

Take the Next Step

No matter which program you choose, pursuing an advanced degree in biotechnology is sure to be a positive step toward success in this field. If you’re still struggling to determine which path is right for you, consult with an expert in the field. Whether that person is someone in your network that works in biotech or an enrollment coach at Northeastern, (who are well-versed in Northeastern’s variety of programs), gaining some outside perspective can help you make this important career choice.

Explore the master’s in biotechnology at Northeastern on our program page then download our free e-Book to learn more about how you can advance your career in biotechnology.

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The average U.S. bioscience worker earned nearly $99,000 in 2016, 85% greater than the average for the overall private sector. (BIO, 2018)

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Digital Commons @ USF > College of Arts and Sciences > Molecular Biosciences > Theses and Dissertations

Molecular Biosciences Theses and Dissertations

Theses/dissertations from 2023 2023.

Exploring strain variation and bacteriophage predation in the gut microbiome of Ciona robusta , Celine Grace F. Atkinson

Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression , Janine M. DeBlasi

Thermodynamic frustration of TAD2 and PRR contribute to autoinhibition of p53 , Emily Gregory

Utilization of Detonation Nanodiamonds: Nanocarrier for Gene Therapy in Non-Small Cell Lung Cancer , Allan E. Gutierrez

Role of HLA-DRB1 Fucosylation in Anti-Melanoma Immunity , Daniel K. Lester

Targeting BET Proteins Downregulates miR-33a To Promote Synergy with PIM Inhibitors in CMML , Christopher T. Letson

Regulated Intramembrane Proteolysis by M82 Peptidases: The Role of PrsS in the Staphylococcus aureus Stress Response , Baylie M. Schott

Histone Deacetylase 8 is a Novel Therapeutic Target for Mantle Cell Lymphoma and Preserves Natural Killer Cell Cytotoxic Function , January M. Watters

Theses/Dissertations from 2022 2022

Regulation of the Heat Shock Response via Lysine Acetyltransferase CBP-1 and in Neurodegenerative Disease in Caenorhabditis elegans , Lindsey N. Barrett

Determining the Role of Dendritic Cells During Response to Treatment with Paclitaxel/Anti-TIM-3 , Alycia Gardner

Cell-free DNA Methylation Signatures in Cancer Detection and Classification , Jinyong Huang

The Role Of Eicosanoid Metabolism in Mammalian Wound Healing and Inflammation , Kenneth D. Maus

A Holistic Investigation of Acidosis in Breast Cancer , Bryce Ordway

Characterizing the Impact of Postharvest Temperature Stress on Polyphenol Profiles of Red and White-Fruited Strawberry Cultivars , Alyssa N. Smith

Theses/Dissertations from 2021 2021

Multifaceted Approach to Understanding Acinetobacter baumannii Biofilm Formation and Drug Resistance , Jessie L. Allen

Cellular And Molecular Alterations Associated with Ovarian and Renal Cancer Pathophysiology , Ravneet Kaur Chhabra

Ecology and diversity of boletes of the southeastern United States , Arian Farid

CircREV1 Expression in Triple-Negative Breast Cancer , Meagan P. Horton

Microbial Dark Matter: Culturing the Uncultured in Search of Novel Chemotaxonomy , Sarah J. Kennedy

The Multifaceted Role of CCAR-1 in the Alternative Splicing and Germline Regulation in Caenorhabditis elegans , Doreen Ikhuva Lugano

Unraveling the Role of Novel G5 Peptidase Family Proteins in Virulence and Cell Envelope Biogenesis of Staphylococcus aureus , Stephanie M. Marroquin

Cytoplasmic Polyadenylation Element Binding Protein 2 Alternative Splicing Regulates HIF1α During Chronic Hypoxia , Emily M. Mayo

Transcriptomic and Functional Investigation of Bacterial Biofilm Formation , Brooke R. Nemec

A Functional Characterization of the Omega (ω) subunit of RNA Polymerase in Staphylococcus aureus , Shrushti B. Patil

The Role Of Cpeb2 Alternative Splicing In TNBC Metastasis , Shaun C. Stevens

Screening Next-generation Fluorine-19 Probe and Preparation of Yeast-derived G Proteins for GPCR Conformation and Dynamics Study , Wenjie Zhao

Theses/Dissertations from 2020 2020

Understanding the Role of Cereblon in Hematopoiesis Through Structural and Functional Analyses , Afua Adutwumwa Akuffo

To Mid-cell and Beyond: Characterizing the Roles of GpsB and YpsA in Cell Division Regulation in Gram-positive Bacteria , Robert S. Brzozowski

Spatiotemporal Changes of Microbial Community Assemblages and Functions in the Subsurface , Madison C. Davis

New Mechanisms That Regulate DNA Double-Strand Break-Induced Gene Silencing and Genome Integrity , Dante Francis DeAscanis

Regulation of the Heat Shock Response and HSF-1 Nuclear Stress Bodies in C. elegans , Andrew Deonarine

New Mechanisms that Control FACT Histone Chaperone and Transcription-mediated Genome Stability , Angelo Vincenzo de Vivo Diaz

Targeting the ESKAPE Pathogens by Botanical and Microbial Approaches , Emily Dilandro

Succession in native groundwater microbial communities in response to effluent wastewater , Chelsea M. Dinon

Role of ceramide-1 phosphate in regulation of sphingolipid and eicosanoid metabolism in lung epithelial cells , Brittany A. Dudley

Allosteric Control of Proteins: New Methods and Mechanisms , Nalvi Duro

Microbial Community Structures in Three Bahamian Blue Holes , Meghan J. Gordon

A Novel Intramolecular Interaction in P53 , Fan He

The Impact of Myeloid-Mediated Co-Stimulation and Immunosuppression on the Anti-Tumor Efficacy of Adoptive T cell Therapy , Pasquale Patrick Innamarato

Investigating Mechanisms of Immune Suppression Secondary to an Inflammatory Microenvironment , Wendy Michelle Kandell

Posttranslational Modification and Protein Disorder Regulate Protein-Protein Interactions and DNA Binding Specificity of p53 , Robin Levy

Mechanistic and Translational Studies on Skeletal Malignancies , Jeremy McGuire

Novel Long Non-Coding RNA CDLINC Promotes NSCLC Progression , Christina J. Moss

Genome Maintenance Roles of Polycomb Transcriptional Repressors BMI1 and RNF2 , Anthony Richard Sanchez IV

The Ecology and Conservation of an Urban Karst Subterranean Estuary , Robert J. Scharping

Biological and Proteomic Characterization of Cornus officinalis on Human 1.1B4 Pancreatic β Cells: Exploring Use for T1D Interventional Application , Arielle E. Tawfik

Evaluation of Aging and Genetic Mutation Variants on Tauopathy , Amber M. Tetlow

Theses/Dissertations from 2019 2019

Investigating the Proteinaceous Regulome of the Acinetobacter baumannii , Leila G. Casella

Functional Characterization of the Ovarian Tumor Domain Deubiquitinating Enzyme 6B , Jasmin M. D'Andrea

Integrated Molecular Characterization of Lung Adenocarcinoma with Implications for Immunotherapy , Nicholas T. Gimbrone

The Role of Secreted Proteases in Regulating Disease Progression in Staphylococcus aureus , Brittney D. Gimza

Advanced Proteomic and Epigenetic Characterization of Ethanol-Induced Microglial Activation , Jennifer Guergues Guergues

Understanding immunometabolic and suppressive factors that impact cancer development , Rebecca Swearingen Hesterberg

Biochemical and Proteomic Approaches to Determine the Impact Level of Each Step of the Supply Chain on Tomato Fruit Quality , Robert T. Madden

Enhancing Immunotherapeutic Interventions for Treatment of Chronic Lymphocytic Leukemia , Kamira K. Maharaj

Characterization of the Autophagic-Iron Axis in the Pathophysiology of Endometriosis and Epithelial Ovarian Cancers , Stephanie Rockfield

Understanding the Influence of the Cancer Microenvironment on Metabolism and Metastasis , Shonagh Russell

Modeling of Interaction of Ions with Ether- and Ester-linked Phospholipids , Matthew W. Saunders

Novel Insights into the Multifaceted Roles of BLM in the Maintenance of Genome Stability , Vivek M. Shastri

Conserved glycine residues control transient helicity and disorder in the cold regulated protein, Cor15a , Oluwakemi Sowemimo

A Novel Cytokine Response Modulatory Function of MEK Inhibitors Mediates Therapeutic Efficacy , Mengyu Xie

Novel Strategies on Characterizing Biologically Specific Protein-protein Interaction Networks , Bi Zhao

Theses/Dissertations from 2018 2018

Characterization of the Transcriptional Elongation Factor ELL3 in B cells and Its Role in B-cell Lymphoma Proliferation and Survival , Lou-Ella M.m. Alexander

Identification of Regulatory miRNAs Associated with Ethanol-Induced Microglial Activation Using Integrated Proteomic and Transcriptomic Approaches , Brandi Jo Cook

Molecular Phylogenetics of Floridian Boletes , Arian Farid

MYC Distant Enhancers Underlie Ovarian Cancer Susceptibility at the 8q24.21 Locus , Anxhela Gjyshi Gustafson

Quantitative Proteomics to Support Translational Cancer Research , Melissa Hoffman

A Systems Chemical Biology Approach for Dissecting Differential Molecular Mechanisms of Action of Clinical Kinase Inhibitors in Lung Cancer , Natalia Junqueira Sumi

Investigating the Roles of Fucosylation and Calcium Signaling in Melanoma Invasion , Tyler S. Keeley

Synthesis, Oxidation, and Distribution of Polyphenols in Strawberry Fruit During Cold Storage , Katrina E. Kelly

Investigation of Alcohol-Induced Changes in Hepatic Histone Modifications Using Mass Spectrometry Based Proteomics , Crystina Leah Kriss

Off-Target Based Drug Repurposing Using Systems Pharmacology , Brent M. Kuenzi

Investigation of Anemarrhena asphodeloides and its Constituent Timosaponin-AIII as Novel, Naturally Derived Adjunctive Therapeutics for the Treatment of Advanced Pancreatic Cancer , Catherine B. MarElia

The Role of Phosphohistidine Phosphatase 1 in Ethanol-induced Liver Injury , Daniel Richard Martin

Theses/Dissertations from 2017 2017

Changing the Pathobiological Paradigm in Myelodysplastic Syndromes: The NLRP3 Inflammasome Drives the MDS Phenotype , Ashley Basiorka

Modeling of Dynamic Allostery in Proteins Enabled by Machine Learning , Mohsen Botlani-Esfahani

Uncovering Transcriptional Activators and Targets of HSF-1 in Caenorhabditis elegans , Jessica Brunquell

The Role of Sgs1 and Exo1 in the Maintenance of Genome Stability. , Lillian Campos-Doerfler

Mechanisms of IKBKE Activation in Cancer , Sridevi Challa

Discovering Antibacterial and Anti-Resistance Agents Targeting Multi-Drug Resistant ESKAPE Pathogens , Renee Fleeman

Functional Roles of Matrix Metalloproteinases in Bone Metastatic Prostate Cancer , Jeremy S. Frieling

Disorder Levels of c-Myb Transactivation Domain Regulate its Binding Affinity to the KIX Domain of CREB Binding Protein , Anusha Poosapati

Role of Heat Shock Transcription Factor 1 in Ovarian Cancer Epithelial-Mesenchymal Transition and Drug Sensitivity , Chase David Powell

Cell Division Regulation in Staphylococcus aureus , Catherine M. Spanoudis

A Novel Approach to the Discovery of Natural Products From Actinobacteria , Rahmy Tawfik

Non-classical regulators in Staphylococcus aureus , Andy Weiss

Theses/Dissertations from 2016 2016

In Vitro and In Vivo Antioxidant Capacity of Synthetic and Natural Polyphenolic Compounds Identified from Strawberry and Fruit Juices , Marvin Abountiolas

Quantitative Proteomic Investigation of Disease Models of Type 2 Diabetes , Mark Gabriel Athanason

CMG Helicase Assembly and Activation: Regulation by c-Myc through Chromatin Decondensation and Novel Therapeutic Avenues for Cancer Treatment , Victoria Bryant

Computational Modeling of Allosteric Stimulation of Nipah Virus Host Binding Protein , Priyanka Dutta

Cell Cycle Arrest by TGFß1 is Dependent on the Inhibition of CMG Helicase Assembly and Activation , Brook Samuel Nepon-Sixt

Gene Expression Profiling and the Role of HSF1 in Ovarian Cancer in 3D Spheroid Models , Trillitye Paullin

VDR-RIPK1 Interaction and its Implications in Cell Death and Cancer Intervention , Waise Quarni

Regulation of nAChRs and Stemness by Nicotine and E-cigarettes in NSCLC , Courtney Schaal

Targeting Histone Deacetylases in Melanoma and T-cells to Improve Cancer Immunotherapy , Andressa Sodre De Castro Laino

Nonreplicative DNA Helicases Involved in Maintaining Genome Stability , Salahuddin Syed

Theses/Dissertations from 2015 2015

Functional Analysis of the Ovarian Cancer Susceptibility Locus at 9p22.2 Reveals a Transcription Regulatory Network Mediated by BNC2 in Ovarian Cells , Melissa Buckley

Exploring the Pathogenic and Drug Resistance Mechanisms of Staphylococcus aureus , Whittney Burda

Regulation and Targeting of the FANCD2 Activation in DNA Repair , Valentina Celeste Caceres

Mass Spectrometry-Based Investigation of APP-Dependent Mechanisms in Neurodegeneration , Dale Chaput

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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.

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Molecular Biology and Biotechnology

Explore this course:.

Applications for 2024 entry are now open. Apply now or register your interest to hear about postgraduate study and events at the University of Sheffield.

School of Biosciences, Faculty of Science

Image of Bethaney Green, postgraduate student in the Department of Molecular Biology and Biotechnology

Course description

This course is designed to develop your technical skills, confidence, and autonomy to enable you to lead innovation across the fast-moving biotechnology industry.

Throughout your studies you'll be exposed to the diverse areas of biology and engineering, with your module choices allowing you to integrate molecular science with chemical and biological engineering modules. Lectures and seminars delivered by academic experts will provide you with a unique perspective on the cutting edge techniques and the collaborative research being performed in these areas.

Through research-focused training, you’ll develop skills in planning and carrying out your own experiments, solving scientific problems in a research environment and receive extensive training in modern laboratory techniques, including CRISPR genome editing, molecular cloning, organism handling, DNA sequence analysis, PCR, SDS-PAGE and western blotting.

Once you’ve mastered these fundamental molecular bioscience techniques, you’ll apply these skills to your Research Project. Here you’ll spend up to six months researching an area of molecular biology or biotechnology that matches your future career aspirations under the supervision of an expert in the field.

Example research projects themes include:

Protein and enzyme engineering
Plant genetic engineering Structural biology (eg X-Ray crystallography)
Synthetic biology/industrial biotechnology (production of useful products from microorganisms)
Plastic degradation using manufactured enzymes Intelligent protein optimisation / bioinformatics
Molecular biology (biomedical/disease related projects)

An open day gives you the best opportunity to hear first-hand from our current students and staff about our courses.

You may also be able to pre-book a department visit as part of a campus tour. Open days and campus tours

1 year full-time

This masters course will provide you with high-level skills in practical experimental science, through personal supervision and training by experienced academic scientists, in modern, well-equipped laboratories, leading to a project where you’ll design and conduct your own research.

Teaching will also be delivered using lectures, seminars and small grouping teaching to develop your academic understanding and become skilled in critically analysing scientific literature and producing your own scientific writing.

Assessment is based on a combination of coursework, practical laboratory work, oral presentations, formal examinations and a dissertation.

Your career

Biotechnology is a rapidly developing area that is heavily dependent upon molecular approaches, creating significant demand for graduates with strong experimental skills and knowledge of molecular bioscience and biochemical engineering.

The specialist training students receive on our Molecular Biology and Biotechnology MSc means our graduates are highly employable, with many working in biotechnology in roles including:

Device Development Scientist, Pfizer
Research Associate, Ortho Bio Therapeutics
Research and Development Manager, EDX Medical
Analytical Scientist, Oxford Biomedica
Research Scientist, Entropix Ltd

Students have also gone on to PhD training in:

Plant Biotechnology
Enzyme Engineering
Human Health and Disease
Membrane Protein Biogenesis
Chemical Engineering

School of Biosciences

The School of Biosciences brings together more than 100 years of teaching and research expertise across the breadth of biology.

It's home to over 120 lecturers who are actively involved in research at the cutting edge of their field, sharing their knowledge with more than 1,500 undergraduate and 300 postgraduate students.

We carry out world-leading research to address the most important global challenges such as food security, disease, health and medicine, ageing, energy, and the biodiversity and climate crises.

Our expertise spans the breadth and depth of bioscience, including molecular and cell biology, genetics, development, human physiology and pharmacology through to evolution, ecology, biodiversity conservation and sustainability. This makes us one of the broadest and largest groupings of the discipline and allows us to train the next generation of biologists in the latest research techniques and discoveries.

Student profiles

Chris standing in the courtyard at Firth Court, smiling and holding a certificate

After my MSc I secured a fully-funded PhD at the University of Melbourne, Australia

Chris Buckley Degree: MSc Molecular Biology and Biotechnology, Graduate role: PhD in Plant Molecular Biology, University of Melbourne, Australia

During his undergraduate Biology degree at Sheffield, Chris discovered that his passion lay in the field of molecular biology and biotechnology. Chris quickly made the transition to this new area thanks to a module dedicated to developing laboratory techniques during his MSc and following supervision from Professor Julie Gray, Chris will begin a PhD in molecular plant biology.

The course director helped me to get to where I am today

Khushboo is now a Microbiology Laboratory Technician at Isopharm here in Sheffield, using the lab techniques she learnt on her course every day, and teaching her colleagues how to use them too!

My year studying Molecular Biology and Biotechnology MSc

Linshu was looking for a hands-on masters course to build on her undergraduate studies in biotechnology. This course gave Linshu technical skills training including how to use industry-standard lab equipment, ready to pursue a PhD.

Entry requirements

Minimum 2:1 undergraduate honours degree in molecular biology or a related subject (e.g. biochemistry, genetics, biotechnology, microbiology).

We also accept medical students who wish to intercalate their studies.

We may also consider your application if you do not meet the standard academic requirements but you have relevant professional experience. An interview will be required in this case.

We accept medical students who wish to intercalate their studies. Find out more on the School of Medicine and Population Health website.

If you have any questions about entry requirements, please contact the department .

Fees and funding

You can apply now using our Postgraduate Online Application Form. It's a quick and easy process.

More information

[email protected] +44 114 222 2341

Suggestions or feedback?

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“Pathways to Invention” documentary debuts on PBS, streaming

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The Lemelson-MIT Program has announced the national debut of an award-winning documentary that celebrates invention: American Public Television (APT) presents “Pathways to Invention,” a film that follows modern inventors of diverse backgrounds as they develop life-changing innovations.

Produced by Maaia Mark Productions in association with the Lemelson-MIT Program with funding from The Lemelson Foundation, MIT's School of Engineering, and the University of California at Berkeley, the 60-minute special explores whether inventors are born or made through a series of engaging, up-close profiles while examining the tangible impact they’re making across a variety of disciplines including biotech, medical diagnostics and prosthetics, sustainable agriculture, food production, software development, and materials science. The inventors featured in the documentary are all recipients of the Lemelson-MIT Student Prize. The program premieres this month on PBS stations nationwide, available for streaming in the PBS app and on PBS.org as well as on WORLD. The film will also air on WGBH 44 Boston on July 7 and 19. A companion website with related learning resources for all ages launched May 1.

“Pathways to Invention” explores the lives of 12 inventors overcoming obstacles to achieve success in cities across the country. Each shares an insightful perspective inspiring audiences to discover their own pathways to realizing their goals.

Journeying through the workshops, garages, laboratories, and offices of these entrepreneurs, the film considers what it really means to take “leaps of faith” as the accomplished innovators present a realistic approach of persevering through overwhelming odds and obstacles, taking risks, and inevitably experiencing failures before achieving success and discovering that the essence of invention is collaboration and lifelong learning.

“We all have the power in our minds and hands to shape the world,” says Levi C. Maaia, the film’s director, a former high school educator, and co-founder of Maaia Mark Productions with Noah Mark, a veteran showrunner and executive producer who has produced numerous series for a who’s who of major broadcast/cable networks and video streaming platforms. “The goal of 'Pathways to Invention' is to inspire others to think about new ways they can create solutions to benefit their own lives and humanity at large.”

Together, Maaia and Mark have collected more than a dozen awards for the film. At the Los Angeles Independent Film Festival Awards in summer 2022, it was recognized as the season's best documentary feature, Mark and Maaia as best producers, Maaia as best director of a documentary feature, and composers Michael Mark and Jon Cobert for best original musical score.

The film seamlessly weaves together the distinctive paths of each inventor working to achieve similarly meaningful results. They include:

David Moinina Sengeh SM '12, PhD '16, chief innovation officer and minister of basic and senior secondary education for the government of Sierra Leone, who witnessed those around him struggle with ill-fitting prosthetics that were too uncomfortable to wear, and designed next-generation wearable mechanical interfaces that improve comfort for amputees.
Nicole Black, a materials scientist whose experience growing up as a little girl grappling with hearing loss due to a perforated eardrum led to the groundbreaking formulation of a 3D-printed material — a near-perfect scaffold for the regrowth of human eardrum tissue.
Paige Balcom, a Fulbright Scholar visiting Uganda who was inspired to develop a small-scale community recycling process in Gulu employing street-connected, at-risk youth. This supposedly “impossible” initiative was the genesis of Takataka Plastics, where Paige now serves as co-founder and is currently working to expand to five towns across Uganda, and eventually scale to other developing countries.
Geoff von Maltzahn '03, PhD '10, who, after becoming hyper-focused during college with the programmability of living things at a microscopic level, has raised hundreds of millions of dollars to fund groundbreaking biotech and life sciences research. Through the management of microbes and the DNA programming of organisms big and small, von Maltzahn and his colleagues are focused on eliminating plant pesticides, creating drought-tolerant crops, sequestering carbon, and eliminating disease.

Championing the idea that most inventors do not emulate the storied life of Thomas Edison or follow the financial trajectory of Elon Musk, “Pathways to Invention” brings a relatable aspect to the journeys of each inventor.

Stephanie Couch, executive director of The Lemelson-MIT Program, states that “the key takeaway we’d like for viewers to keep in mind is that it’s never too late — or too early — to get on the pathway to invention. We are all aware of problems in our daily lives and we have what it takes to become collaborative problem-solvers and invent solutions that can make the world a better place.”

“We all are born curious; we all like to study the world. We like to understand it. That’s the innate curiosity that we all have, and sometimes it’s the environmental factors that drive it out of us,” says Josh Siegel, an assistant professor at Michigan State University and inventor whose work focuses on designing platforms for collecting and analyzing vehicle data. “Inventing has taught me to be persistent; inventing has taught me to be creative; inventing has taught me to trust myself as I have never trusted myself before. It’s OK to be imperfect, so long as you’re better than you were. We can invent things, we can invent products, we can invent services. We can create new capabilities; we can create new knowledge. But at the end of the day, what we’re really doing is reinventing ourselves.”

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Georgia Tech to Offer Ph.D. in Neuroscience and Neurotechnology, New Minor

The University System of Georgia Board of Regents has approved a new Neuroscience and Neurotechnology Ph.D. Program at Georgia Tech.

The interdisciplinary degree is a joint effort across the Colleges of Sciences , Computing , and Engineering . The program expects to enroll its first graduate students in Fall 2025, pending approval by the Southern Association of Colleges and Schools Commission on Colleges.

The Institute Curriculum Committee has also approved a new Minor in Neuroscience , set to become available in the Georgia Tech 2024-2025 Catalog .

B.S. in Neuroscience

The Ph.D. and Minor offerings build on the recently launched Neuro Next Initiative in Research , and the established Undergraduate Program in Neuroscience , respectively.

Approved by the Board of Regents in 2017, the interdisciplinary B.S. in Neuroscience degree in the College of Sciences enrolled more than 400 undergraduate students in 2022, and has been the fastest growing undergraduate major at Georgia Tech.

The B.S. in Neuroscience is also key to a strong ecosystem of undergraduate neuroscience education across the state, which includes peer programs at Mercer University, Augusta University, Georgia State University, Agnes Scott College, and Emory University.

Ph.D. in Neuroscience and Neurotechnology

The new doctoral degree will provide a path for the rapidly growing pipeline of in-state neuroscience undergraduate students and young alumni — while also welcoming a wider slate of graduate researchers to campus.

The Ph.D. Program’s mission is focused on educating students to advance the field of neuroscience through an interdisciplinary approach, with scientists and engineers of diverse backgrounds — ultimately integrating neuroscience research and technological development to study all levels of nervous system function.

Biological Sciences Professor Lewis A. Wheaton , who chaired the Ph.D. Program Planning Committee, shares that a cohort model will fuse “experimental and quantitative skill development, creating opportunities for students to work in science and engineering labs to promote collaborations, while also fostering a program and community that’s unique to the state and against national peer offerings.”

Expanding innovation — and impact

Wheaton explains that the new Ph.D. aims to equip graduates for a wide range of employment opportunities and growing specializations, including computational neuroscience, neurorehabilitation, cultural and social neuroscience, neuroimaging, cognitive and behavioral neuroscience, developmental neuroscience, and neurolinguistics.

The new degree will also help meet the country’s growing demand for a neuro-centric workforce. According to the U.S. Bureau of Labor Statistics, job growth for medical scientists (including neuroscientists) tracked around 13% between 2012 and 2022, faster than the average for all tracked occupations.

Wheaton, who also serves as director of the Cognitive Motor Control Lab and director of the Center for Promoting Inclusion and Equity in the Sciences (C-PIES) at Georgia Tech, adds that the program will equip neuroscientists to conduct research that can significantly improve lives.

Seeking students

The Planning Committee anticipates a tentative February 1, 2025 application deadline for Fall 2025 enrollments — and encourages students with the following interests to learn more and apply in the coming school year:

Developing deeper quantitative, computing and/or engineering skills to make scientific discoveries that support innovations in neuroscience
A clear, comprehensive understanding of the nervous system at all scales from molecular to systems
Understanding how to use and innovate new tools and approaches to investigate the nervous system at all levels
Becoming uniquely qualified to translate knowledge across neuroscience and related disciplines to create new knowledge in their professional pursuits

Director search

The participating Colleges will soon conduct a search for a program director , engaging a tenured member of the Georgia Tech faculty to serve as the new program’s administrator. A graduate program committee composed of five faculty members and mentors across the Colleges of Sciences, Computing, and Engineering, will also be created.

During their April 2024 meeting, Regents also announced budget approvals and tuition changes for Georgia's 26 member institutions.

The Ph.D. Program Planning Committee included the following faculty:

Lewis Wheaton (Committee Chair, Biological Sciences)
Constantine Dovrolis (Computer Science)
Christopher Rozell (Electrical and Computer Engineering)
Eric Schumacher (Psychology)
Garrett Stanley (Biomedical Engineering)
David Collard (College of Sciences Office of the Dean)

Ph.D. in Neuroscience and Neurotechnology Contact Professor Lewis Wheaton , Planning Committee Chair
Undergraduate Program in Neuroscience
Minor in Neuroscience
Georgia Tech Neuro and Neuro Next

Press Contact: Jess Hunt-Ralston Director of Communications College of Sciences at Georgia Tech

Neuro Next Initiative:

Sarah Peterson Program Manager GT Neuro

Audra Davidson Research Communications Program Manager Neuro Next Initiative at Georgia Tech