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Research Fellow skills for your resume and career

Updated January 8, 2025
6 min read
Quoted Experts
Katina Lillios,
Alexandra (Sasha) Ormond Ph.D.
Research Fellow Example Skills
Below we've compiled a list of the most critical research fellow skills. We ranked the top skills for research fellows based on the percentage of resumes they appeared on. For example, 9.9% of research fellow resumes contained patients as a skill. Continue reading to find out what skills a research fellow needs to be successful in the workplace.

15 research fellow skills for your resume and career

1. Patients

Here's how research fellows use patients:
  • Developed psychological screening process for breast clinic patients to identify patients in distress and provide subsequent consultation and ongoing treatment.
  • Conducted behavioral medicine hypnotherapy protocols for patients with GI disorders to reduce visceral hypersensitivity and improve disease management.

2. Research Projects

Here's how research fellows use research projects:
  • Supported time-sensitive scholarly research by authoring research projects, conducting literature reviews, collecting and analyzing data, and preparing manuscripts.
  • Performed scientific and administrative reviews of journal articles and other scientific materials related to conducting and implementing two research projects.

3. Data Analysis

Here's how research fellows use data analysis:
  • Developed automated data analysis routines, based on anti-correlative measurement strategies to differentiate instrument systematic error from physical mirror surface attributes.
  • Research Fellow Designed, documented, and presented efficient atmospheric models and satellite data analysis programs for the detection of pollutants.

4. Cell Culture

Here's how research fellows use cell culture:
  • Managed laboratory cell culture operations, including training lab personnel, writing protocols, and performing necessary troubleshooting and maintenance tasks.
  • Provided cell culture support and advised laboratory members on the cellular and physiological aspects of their dissertation projects.

5. Immunology

Immunology is a branch of medical service that deals with studying the immune system of a person. This particular specialization focuses on the function of the immune system and how it affects the entire body. It is usually an activity where it develops a mechanism that helps prevent and susceptibility of bacteria, infection, and other viruses that can enter the body.

Here's how research fellows use immunology:
  • Coordinated interdisciplinary research between the Department of Microbiology and Immunology and the College of Science and Technology.
  • Conducted research on islet biology and diabetes, immune-isolation and transplantation, and transplant immunology.

6. CRISPR

Here's how research fellows use crispr:
  • Utilized CRISPR technology to generate MED12 exon 2 deletion mutations in colon cancer cells.
  • Established the CRISPR genome editing technique for C. elegans in the laboratory.

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7. Cell Biology

Here's how research fellows use cell biology:
  • Conducted experiments to characterize the biological diversity of breast tumors using molecular and cell biology techniques.
  • Performed independent research project studying cell biology and protein dynamics under the supervision of Ruth Johnson

8. Python

Python is a widely-known programming language. It is an object-oriented and all-purpose, coding language that can be used for software development as well as web development.

Here's how research fellows use python:
  • Used PYTHON and BASH scripts to manage the submission approximately 500 event generation jobs to a grid-computing cluster.
  • Produced numerous data processing, analysis, and visualization pipelines using Python, R, and BASH.

9. RNA

A Ribonucleic acid (RNA) has a vital role in determining the biological macromolecule commonly found in all bodily cells. It is the synthesis of protein, carriers message instruction from the Deoxyribonucleic acid or DNA. RNA is a kind of single-stranded cell that has different forms. It allows the molecule to go back and forth to its original condition.

Here's how research fellows use rna:
  • Designed and investigated novel dumbbell-shaped vectors for non-coding and coding RNA expression.
  • Assisted with training collaborators in RNA amplification techniques and lab management.

10. Chemistry

Chemistry is the branch of science that tells us about the composition, properties, and structure of elements and compounds. The processes these elements undergo and how they undergo change all come under the branch of chemistry.

Here's how research fellows use chemistry:
  • Oversee daily management of organic/medicinal chemistry aspects while serving on a multidisciplinary team comprised of physical chemists and pharmacologists.
  • Research resulted in a high-impact publication in the Journal of Biological Chemistry and two additional publications currently under preparation.

11. NIH

NIH stands for the National Institutes of Health. This organization oversees a series of research institutions, each focused on a different area of study involving anatomical systems or diseases. As the organization is affiliated with the government, a great deal of the funding institutions receive come from Congress.

Here's how research fellows use nih:
  • Participated in numerous professional development workshops, attended NIH Clinical Center Grand Rounds and special lecture series featuring distinguished NIH investigators.
  • Delivered research presentations, seminars on disease state/therapeutic area to clinicians at NIH.

12. Data Collection

Data collection means to analyze and collect all the necessary information. It helps in carrying out research and in storing important and necessary information. The most important goal of data collection is to gather the information that is rich and accurate for statistical analysis.

Here's how research fellows use data collection:
  • Manage evaluation budget, research staff, quantitative and qualitative data collection, analysis, dissemination, report writing and dissemination.
  • Designed and conducted a study concerning manual dexterity in object manipulation in captive chimpanzees; managed data collection and analyses.

13. C++

C++ is a general-purpose programming language that is used to create high-performing applications. It was invented as an extension to the C language. C++ lets the programmer have a high level of domination over memory and system resources. C++ is an object-oriented language that helps you implement real-time issues based on different data functions

Here's how research fellows use c++:
  • Developed time-series analysis software in C++ for use in the data mining and statistical analysis of astronomical data.
  • Coded in C++ within the ROOT programming environment in order to analyze and plot data from the LHC.

14. Public Health

Here's how research fellows use public health:
  • Collaborated with clinical microbiologists and state epidemiologists to identify priority MRSA public health needs.
  • Planned state-wide public health caucuses, attended by government representatives and community members.

15. Flow Cytometry

Flow cytometry (FC) is a procedure used to recognize and gauge the physical and compound attributes of a populace of cells or particles. In this cycle, an example containing cells or particles is suspended in a liquid and infused into the stream cytometer instrument. Stream cytometry is a research center technique used to recognize, distinguish, and check explicit cells. This technique can likewise distinguish specific parts inside cells. This data depends on actual attributes and additionally markers called antigens on the phone surface or inside cells that are special to that phone type.

Here's how research fellows use flow cytometry:
  • Assessed CTL stimulation, recognition of endogenously processed antigens and efficacy of vaccine formulations using chromium release assays and flow cytometry.
  • Developed new techniques to identify antigen specific B cell using flow cytometry.
top-skills

What skills help Research Fellows find jobs?

Tell us what job you are looking for, we’ll show you what skills employers want.

What skills stand out on Research Fellow resumes?

Katina LilliosKatina Lillios LinkedIn Profile

Professor, Department Chair, The University of Iowa

While the precise skills that are desired depend on the job, there are some that all graduates from an Anthropology program should work on developing. These include experience contributing to group projects, collaborating with diverse communities, strong communication and writing skills, versatility, and mastery of a specialized skill, such as GIS, a foreign language, statistics, and other digital technologies.

What soft skills should all Research Fellows possess?

Alexandra (Sasha) Ormond Ph.D.

Associate Professor of Chemistry, Director of Dual Degree Engineering, Meredith College

From what I've heard (from employers), companies look for employees that they can work with. I know that sounds silly, but companies want employees that are team players and work well with other individuals and in groups. These employees also need to work independently when asked to work on a project. They need to be organized, reliable, and trustworthy. Employees also need to be able to communicate well by writing and speaking. They must be able to follow directions.

What hard/technical skills are most important for Research Fellows?

Alexandra (Sasha) Ormond Ph.D.

Associate Professor of Chemistry, Director of Dual Degree Engineering, Meredith College

This one is tough because it depends on the position! I think what is valuable for a chemist is being knowledgeable of working with instrumentation such as chromatography and mass spectrometry. Employees that are likely more attractive for a job position than another person have had the independent experience of working with instruments and can troubleshoot problems. Employees need to be able to explain the data that they obtained from an experiment and describe what the data mean. (Data is a plural term!) Problem-solving and critical thinking is very important for scientists.

What Research Fellow skills would you recommend for someone trying to advance their career?

Dr. Neal Palmer Ph.D.Dr. Neal Palmer Ph.D. LinkedIn Profile

Chair, Associate Professor, Christian Brothers University

The answer to that question likely won't change from pre- to post-pandemic. Southern cities such as Nashville and Memphis were booming before the pandemic, and that will likely continue. These are good places to find jobs because the cost of living is relatively low, there are vibrant culture and entertainment, and there is not as much college-educated competition for jobs as in larger cities.

What type of skills will young Research Fellows need?

David Cool Ph.D.David Cool Ph.D. LinkedIn Profile

Professor, Pharmacology & Toxicology; Professor, Obstetrics & Gynecology, Wright State University

The skill sets that young graduates will need when they graduate and enter the workforce are similar to and vastly different from just 15-30 years ago. If they are working in a laboratory setting, then the standards are the same; accurate pipetting, the ability to make complex buffers, and understanding how all the necessary equipment in a lab works. However, that is not nearly enough nowadays. The equipment and instrumentation have been expanding exponentially to the point that you will be working with both expensive and complicated instruments to generate a more considerable amount of data than anyone ever thought possible. Standards for labs today will be using digital imaging devices to capture everything from microscopic images, to western blots, to automated living cell analysis using multi-well plates. Multiplexed assays for 27 to 50 to 1050 cytokines and proteins have replaced single marker ELISA. But knowing ELISA will allow you to be trained to do the multiplexed assays. Most pharmaceutical companies have a great need still for 'old-fashioned' HPLC techniques. Every student I have had in my research techniques class, that graduates and goes for a Pharma position, comes back and tells me they asked them if they could run an HPLC.
Some were even given a test to see if they understood the concept. This then leads to mass spectrometry, LCMS, MALDI-TOF, and even GCMS, and everything that has been developed around those basic techniques is now commonplace in most core facilities and Pharma. New methods for flow cytometry, FACS, are necessary for the higher throughput drug discovery types of labs. Molecular biology has evolved from simple PCR machines that could run 24 samples, just 25 years ago, to digital PCR machines that can run 384 pieces today and email the final data to you at home, while you sleep. Knowing how to calculate the PCR data is extremely critical, as it isn't intuitive, and people tend to take short cuts. Knowing how to do that will be vital. Cell culture and working with animals are still common ways to generate data in any lab, and people who have those skills will always have a job. What do all these techniques have in common? They all have evolved to the point that no one is an expert in every one of them. Labs focus and concentrate on the ones they need the most and make use of them over a long period. What a student should develop is what I call a big toolbox. Learn as many of these techniques as you can, and then use them. Understanding that these are all cyclic and that you may get rusty, or the technology will change. It doesn't matter. By being trained in any of these, it will mean that you can be prepared for other things, that you can catch up and learn and update your techniques in your toolbox. This is what any PI running a lab will be looking for, someone who can be trained, and can evolve and adapt to different technologies, know how they work and how they can be used, what the data looks like when it is working well, and what it looks like when it isn't. The people who have these skills will always be employable.

There is a greater need than ever for workers to analyze data and synthesize a reasonable idea about what it means. This means that they must understand their experiments at a deeper level than just pipetting buffers and timing reactions. They must know what is happening, and if there is a problem, first, they have a problem and then how to solve it. Bioinformatics has become one of the fastest-growing fields. The increased amount of data, whether from standard assays run in an ordinary lab or high throughput data, needs more crunching. The future researcher will not be able to get by just knowing how to use a computer stats program but will be required to understand how to run data in R or Python or whatever new data analysis package is coming next. This becomes even more critical as the data becomes more complex, i.e., 27 cytokines analyzed in 3 different tissues over three other times, from 14 different groups, 6 of which are controls, with the rest being toxin and then treatment groups and authorities. A simple two way ANOVA just doesn't cut it. For this, machine learning tools, pattern recognition, neural networks, topological data analysis (TDA), Deep Learning, etc., are becoming the norm and are being advanced and changed to give more and more substance to what the data means. Students who can operate instruments to generate data and run more complex types of analysis on this 'big data' are in great demand. Likewise, learning the computer-generated design of drugs 'in silico' is a growing field that is now required to screen tens of thousands of compounds before generating them in the lab. This will need someone who can think three-dimensionally; even though the software and advanced computers can do that, it helps if your brain is wired that way, at least a little.

Aside from instruments and complex data analysis, consider where the clinical research is headed. With COVID19, the need to quickly advance drugs from potential use to clinical application has undergone an exponential increase. Lives are being lost daily to the lack of a vaccine or medication that can attenuate to any level the impact the virus has on the human body. The future clinical researcher will need to understand how the instruments work and how tests are run, how a vaccine works, how the virus or disease manifests itself, and how to get it under control. This will only be possible if the researcher is familiar with much of what I wrote above. You won't need to be an expert on virtually everything, but you'll need to understand it so you can use it to synthesize new ideas that may be applicable in the clinical environment. COVID19 is a perfect example. One of the early struggles with this virus was how to test for it. Antibodies weren't developed for it in the very beginning, so an ELISA was out.

In contrast, PCR is one of the most sensitive methods to identify genetic material, such as viruses. So, early on, PCR primers were created that could be used to run a PCR to determine if a person had a live virus. However, the first such PCRs had high false negatives and positives. Further refinement led to the creation of PCR primer sets and protocols that allowed for a more accurate and faster test. An advantage that anyone who has been trained in biotechnology will know the basics of developing a test. If it is a PCR, then what goes into that. Suppose it is an ELISA, how it works, and what you need to set it up. Imagine a test strip similar to the one used for at-home pregnancy tests. This came about in much the same way, through experimentation and developing a way to lower the false negatives and positives, to allow a quick, 5-minute test that could determine if a particular hormone was in your urine at a stage of pregnancy when many women may not have realized there was a possibility they could be pregnant. The person entering the workforce that can think in these ways will be employable and will be able to move between jobs and continue with a very successful and enriching career.

What technical skills for a Research Fellow stand out to employers?

Sya Kedzior Ph.D.

Associate Professor, Towson University

The ability to understand technical or complex scientific processes and communicate that information with the public is one of the most attractive skills for an entry-level worker to possess. Many employers may not have staff skilled in the latest GIS technologies or social media trends. While the ability to use last year's software or network via Instagram might not seem particularly novel to recent graduates, these are skills less likely to be found in the workforce of even 10 years ago. Geographers are particularly well prepared for today's workforce because they've often had coursework across the "hard" and social sciences, along with training in technical skills (usually GIS or quantitative analysis) and written and oral communication skills. Another skill in high demand today is data collection and analysis. I often talk with potential employers who want to hire people who can develop and administer a public survey, and then analyze and write up the results. That requires understanding human behavior, public communication, and different forms of data analysis. But, these are skills that can be developed in perhaps only a few classes as part of a major or minor in Geography and other cognate fields.

List of research fellow skills to add to your resume

Research Fellow Skills

The most important skills for a research fellow resume and required skills for a research fellow to have include:

  • Patients
  • Research Projects
  • Data Analysis
  • Cell Culture
  • Immunology
  • CRISPR
  • Cell Biology
  • Python
  • RNA
  • Chemistry
  • NIH
  • Data Collection
  • C++
  • Public Health
  • Flow Cytometry
  • PI
  • Independent Research
  • Immunotherapy
  • Next-Generation Sequencing
  • Animal Models
  • Statistical Analysis
  • DNA
  • Rna Sequencing
  • Molecular Biology Techniques
  • Stem Cells
  • Experimental Design
  • Research Findings
  • Excellent Interpersonal
  • Clinical Trials
  • Biomarkers
  • Cancer Research
  • Gene Expression
  • Protein Expression
  • Western Blotting
  • Synthesis
  • MRI
  • Molecular Mechanisms
  • R
  • Scientific Journals
  • Animal Handling
  • Mass Spectrometry
  • Elisa
  • Journal Articles
  • Pathogens
  • Research Results
  • SAS
  • RT-PCR
  • Stata
  • PowerPoint

Updated January 8, 2025

Zippia Research Team
Zippia Team

Editorial Staff

The Zippia Research Team has spent countless hours reviewing resumes, job postings, and government data to determine what goes into getting a job in each phase of life. Professional writers and data scientists comprise the Zippia Research Team.

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