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45 Biomedical Research Topics for You

Biomedical Research Topics

Although choosing relevant biomedical research topics is often an arduous task for many, it shouldn’t be for you. You no longer have to worry as we have provided you with a list of topics in biomedical science in this write-up.

Biomedical research is a broad aspect of science, and it is still evolving. This aspect of science involves a variety of ways to prevent and treat diseases that lead to illness and death in people.

This article contains 45 biomedical topics. The topics were carefully selected to guide you in choosing the right topics. They can be used for presentations, seminars, or research purposes, as the case may be.

So, suppose you need topics in biomedical ethics for papers or biomedical thesis topics for various purposes. In that case, you absolutely have to keep reading! Are you ready to see our list of biomedical topics? Then, let’s roll.

Biomedical Engineering Research Topics

Biomedical engineering is the branch of engineering that deals with providing solutions to problems in medicine and biology. Biomedical engineering research is an advanced area of research. Are you considering taking up research in this direction?

Research topics in this area cannot just be coined while eating pizza. It takes a lot of hard work to think out something meaningful. However, we have made a list for you! Here is a list of biomedical engineering topics!

  • How to apply deep learning in biomedical engineering
  • Bionics: the latest discoveries and applications
  • The techniques of genetic engineering
  • The relevance of medical engineering today
  • How environmental engineering has affected the world

Biomedical Ethics Topics

There are ethical issues surrounding healthcare delivery, research, biotechnology, and medicine. Biomedical Ethics is fundamental to successful practice experience and is addressed by various disciplines. If you want to research this area, then you do not have to look for topics. Here’s a list of biomedical ethics for paper that you can choose from:

  • The fundamentals of a physician-patient relationship
  • How to handle disability issues as a health care sector
  • Resource allocation and distribution
  • All you need to know about coercion, consent, and or vulnerability
  • Ethical treatment of subjects or animals in clinical trials

Relevant Biomedical Topics

Topics in Biomedical science are numerous, but not all are relevant today. Since biomedical science is constantly evolving, newer topics are coming up. If you desire in your topic selection, read on. Here is a list of relevant biomedical topics just for you!

  • The replacement of gene therapy by gene editing
  • Revolution of vaccine development by synthetic biology
  • Introduction of artificial blood – the impact on the health sector
  • Ten things know about artificial womb
  • Transplanted reproductive organs and transgender birth

Biomedical Science Topics

Biomedical science is the aspect of scientific studies that focuses on applying biology and chemistry to health care. This field of science has a broad range of disciplines. If you intend to do research in this field, look at this list of research topics in biomedical science.

  • The role of biomechanics in health care delivery
  • Importance of biomaterials and regeneration engineering
  • The application of cell and molecular engineering to medicine
  • The evolution of medical instrumentation and devices
  • Neural engineering- the latest discoveries

Seminar Topics for Biomedical Instrumentation

Biomedical science is constantly making progress, especially in the aspect of biomedical instrumentation. This makes it worthy of a seminar presentation in schools where it is taught. However, choosing a biomedical research topic for a biomedical instrumentation seminar may not come easy. This is why we have collated five brilliant topics for biomedical instrumentation just for you. They include:

  • Microelectrode in neuro-transplants
  • Hyperbaric chamber for oxygen therapy
  • How concentric ring electrodes can be used to manage epilepsy
  • How electromagnetic interference makes cochlear implants work
  • Neuroprosthetics Management using Brain-computer interfaces (BCI)

Biomedical Engineering Topics for Presentation

One of the interesting aspects of biomedical science in biomedical engineering. It is the backbone that gives the biomedical science structure. Are you interested in making presentations about biomedical engineering topics? Or do you need biomedical engineering topics for paper? Get started here! We have compiled a list of biomedical engineering topics for you. Here they are:

  • In-the-ear device to control stuttering: the basis of its operation
  • How to implement the magnetic navigated catheterization
  • Semiconductor-cell interfaces: the rudiments of its application
  • The benefits of tissue engineering of muscle
  • The benefits of sensitive artificial skin for prosthetic arms

Hot Topics in Biomedical Research

Biomedical research is fun because it is often relatable. As interesting as it seems, choosing a topic for research doesn’t come easy at all. Yet, there are also a lot of trending events around biomedical topics. To simplify your selection process, we have written out a few of them here.

Here are some hot biomedical research topics below.

  • What is immunology, and what is the relevance today?
  • Regenerative medicine- definition, importance, and application
  • Myths about antibiotic resistance
  • Vaccine development for COVID-19
  • Infectious diseases now and before

Biomedical Research Topics

Biomedical research is an extensive process. It requires a lot of time, dedication, and resources. Getting a topic shouldn’t be added to that list. There are biomedical thesis topics and research topics in biomedical science for you here:

  • Air pollution- sources, impact, and prevention
  • Covid-19 vaccination- the effect on life expectancy
  • Hyper insomnia- what is responsible?
  • Alzheimer’s disease- newer treatment approaches
  • Introduction of MRI compatible infusion pump

Biomedical Nanotechnology Topics

Biomedical research topics and areas now include nanotechnology. Nanotechnology has extended its tentacles to medicine and has been used to treat cancer successfully. This makes it a good research area. It is good for seminar presentations. Here are some biomedical nanotechnology topics below.

  • The uses of functional particles and nanomaterials
  • Nanoparticles based drug delivery system
  • The incorporation of nanoporous membranes into biomedical devices
  • Nanostructured materials for biological sensing
  • Nanocrystals- imaging, transportation, and toxicity features

Seeking professional assistance to write your biomedical research or thesis? Look no further! At our reputable writing service, our experienced writers specialize in providing tailored support for the complexities of biomedical research. When you say, “ do my thesis for me ” we’re here to guide you through formulating research questions, conducting literature reviews, and analyzing data sets. Entrust the writing process to our experts while you focus on exploring the frontiers of biomedical research. Contact us today for a meticulously crafted thesis that enhances your chances of success.

We believe you have been thoroughly equipped with a list of biomedical topics. This way, you wouldn’t have to go through the stress of choosing a topic for research, seminars, or other educational purposes. Now that you have the topics at your fingertips make your choice and enjoy!

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UKnowledge > College of Engineering > Biomedical Engineering > Theses & Dissertations

Theses and Dissertations--Biomedical Engineering

Theses/dissertations from 2024 2024.

DEVELOPING AN IMMUNOMODULATORY STRATEGY USING BIOPHYSICAL CUES TO MODULATE MACROPHAGE PHENOTYPE FOR FRACTURE HEALING AND BONE REGENERATION , Harshini Suresh Kumar

Theses/Dissertations from 2023 2023

A Wearable Fiber-Free Optical Sensor for Continuous Measurements of Cerebral Blood Flow and Oxygenation , Xuhui Liu

3-DIMENSIONAL MUSCLE CONSTRUCTS: USING HYDROGELS IN ORDER TO MODEL THE EFFECTS OF EXERCISE IN DISEASE CONDITIONS , Mark McHargue

MULTISCALE AND MULTIMODALITY OPTICAL IMAGING OF BRAIN HEMODYNAMICS AND FUNCTION , Mehrana Mohtasebi

DEFINING SAGITTAL PLANE GAIT MECHANICS AND JOINT LOADING IN PEOPLE WITH MARFAN SYNDROME , Justin Melan Pol

Theses/Dissertations from 2022 2022

USE OF IMAGE PROCESSING TECHNIQUES AND MACHINE LEARNING FOR BETTER UNDERSTANDING OF T GONDII BIOLOGY , Amer Asiri

An Electrochemical, Fluidic, Chip-Based Biosensor for Biomarker Detection , Lauren Bell

VOLUNTARY CONTROL OF BREATHING ACCORDING TO THE BREATHING PATTERN DURING LISTENING TO MUSIC AND NON-CONTACT MEASUREMENT OF HEART RATE AND RESPIRATION , Dibyajyoti Biswal

Characterizing the Internal Porous Structure of Equine Proximal Sesamoid Bones Subjected to Race Training Using Fast Fourier Transforms , Joseph Erik Davis

Theses/Dissertations from 2021 2021

CHARACTERIZATION OF MODULATION AND COHERENCE IN SENSORIMOTOR RHYTHMS USING DIFFERENT ELECTROENCEPHALOGRAPHIC SIGNAL DERIVATIONS , Stephen Dundon

Analysis of Graded Sensorimotor Rhythms for Brain-Computer Interface Applications , Chase Allen Haddix

NOVEL TOOLS FOR ANALYSIS OF DISORDERED SLEEP AND MOTOR BEHAVIOR IN PRECLINICAL MODELS OF DISEASE , Dillon M. Huffman

CHANGES IN CARDIOVASCULAR, RESPIRATORY, AND NEURAL ACTIVITY BY MUSIC: EFFECTS OF BREATHING PATHWAY ON FEELING EMOTIONS , Mohammad Javad Mollakazemi

Facilitating Analysis of Toxoplasma gondii Bradyzoite Metabolic Activity via Image Processing and Multivariate Logistic Regression for High Throughput Classification of Mitochondrial Morphologies , Brooke Place

WORK-RELATED CHANGES IN THE TRUNK STIFFNESS OF NURSING PERSONNEL , Clare Tyler

Theses/Dissertations from 2020 2020

HIGH FREQUENCY OSCILLATIONS IN THE EPILEPTIC BRAIN: ACCURATE DETECTION, EFFECT OF VIGILANCE STATE, AND SAMPLE SIZE CONSIDERATIONS , Amir Fared Partu Al-Bakri

ATV Dynamics and Pediatric Rider Safety , James T. Auxier II

Assessment of White Matter Hyperintensity, Cerebral Blood Flow, and Cerebral Oxygenation in Older Subjects Stratified by Cerebrovascular Risk , Ahmed A. Bahrani

EFFECTS OF A HIP ORTHOSIS ON LUMBOPELVIC COORDINATION IN INDIVIDUALS WITH AND WITHOUT LOW BACK PAIN , Colin Drury

Noncontact Multiscale Diffuse Optical Imaging of Deep Tissue Hemodynamics in Animals and Humans , Siavash Mazdeyasna

Work Related Diurnal Changes in Trunk Mechanical Behavior , Maeve McDonald

Theses/Dissertations from 2019 2019

A POSSIBLE LINK BETWEEN R-WAVE AMPLITUDE ALTERNANS AND T-WAVE ALTERNANS IN ECGs , Sahar Alaei

BIOMECHANICAL EFFECTS OF A HIP ORTHOSIS ON LUMBO-PELVIC COORDINATION , Matthew Ballard

CALIBRATED SHORT TR RECOVERY MRI FOR RAPID MEASUREMENT OF BRAIN-BLOOD PARTITION COEFFICIENT AND CORRECTION OF QUANTITATIVE CEREBRAL BLOOD FLOW , Scott William Thalman

A BRAIN-COMPUTER INTERFACE FOR CLOSED-LOOP SENSORY STIMULATION DURING MOTOR TRAINING IN PATIENTS WITH TETRAPLEGIA , Sarah Helen Thomas

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Biomedical Engineering

Master's Thesis

BME 291 - MS Thesis/Project Preparation Seminar Syllabus [docx] BME 298 - MS Project Syllabus [docx] BME 299 - MS Thesis Syllabus [docx]

Required Report Writing Guidelines

BME Thesis/Project Report Style Guide [pdf]

Differences between MS Thesis and MS Project

There are few key differences between the Thesis and Project option. If you choose to do a Thesis, you will have to complete 6 units for that (BME 291, BME 298 and BME 299), compared to the 3 units required for the Project (BME 291, BME 298). Since the three courses (BME 291, BME 298 and BME 299) must be taken in a sequence, a Thesis usually requires at least three semester to complete, compared to the two or more semesters required for a Project.

The Thesis can only be pursued individually, so you won’t be able to share the workload with a team mate, unlike the Project.

Finally, the Thesis’ final deliverable is a dissertation, which needs to be approved by the College of Graduate Studies and published by Montezuma Publishing, a non-profit organization is SJSU's partner for review and publication of theses and dissertations. The review and approval process is based on high quality standards, and the time required for that usually takes the bulk of the BME 299 semester.

Reasons to choose the Thesis option over the Project include: (1) the student wants to pursue a PhD degree, and the Thesis provides the opportunity to prepare for higher-quality research work and earn one or more publications to support their application to PhD programs; (2) the student wants to improve their chance to land an R&D job in the private sector, and the experience and publications resulting from a Thesis can help with that; (3) personal accomplishment. 

Before you start your MS Thesis

Students should gear up for their MS Thesis at least one semester before they enroll in BME 291. In addition to clearing all the prerequisites for BME 291 (see MS-BME Degree Checklist [pdf] ), the student should:

  • Identify topic areas of interest and one or more prospective technical advisors (usually, BME faculty)
  • Inquire with prospective technical advisors for available projects in the areas they identified
  • Reach out to potential Reading Committee members (for MS Thesis, you need at least two members in addition to your technical advisor)
  • Explore funding opportunities to support their project expenses
  • Consider whether they want to pursue a Project or Thesis

Once the Thesis topic and advisor have been identified, the student should start working on getting familiar with the topic. In particular, it is recommended that, before the beginning of their BME 291 semester, the student:

  • Select and critically review some peer-reviewed papers from the relevant literature
  • Draft a list of (tentative) specific aims for their MS Thesis

The Thesis Proposal

The Thesis is generally articulated into three components: proposal (BME 291), execution (BME 298/299) and dissertation writeup and revisions (BME 299). In the proposal, the student identifies the overall objective and articulate specific aims that will allow them to address the technological or clinical gap they identified with their literature review. In addition to demonstrate the significance and innovation of the proposed work, the student needs to show that their thesis is feasible by discussing in detail the materials and methodologies they will use.

Here is the general template for the structure of a MS-BME Thesis proposal:

  • Introduction
  • Literature review
  • Objectives / Specific aims
  • Materials and Methods

By the end of the semester (BME 291), the student must defend their proposal with an oral presentation, followed by a Q&A session with the course instructor, technical advisor and Reading Committee member(s).

The Thesis 

Once the student has successfully defended their proposal and cleared BME 291, they are eligible to enroll in BME 298. During this semester, the student will execute the proposed work, which may include device or protocol design and validation, benchtop experiments, numerical simulation. The data collected from those activities will have to be appropriately processed, analyzed, interpreted, evaluated in light of the information available from literature review and established clinical practice.

The writeup of the Thesis usually takes most of the BME 299 semester. For detailed instructions about Thesis preparation, review, approval and publication, the student should review the following materials:

  • Thesis and Dissertation Guide  
  • Thesis and Dissertation Guidelines [pdf]  
  • Thesis and Dissertation Due Dates  

Completion of the Thesis may require one or more semesters, depending primarily on the time committed by the student and the number of draft resubmissions requested by the College of Graduate Studies before the dissertation is approved. Delays external to the student’s control (e.g. purchase of backordered items, equipment needing repair or maintenance, and the intrinsic uncertainties of research work) may further add to the time required to complete the Thesis. If the work extends beyond the BME 299 semester, the student may be required to register for BME 1290R to maintain continuous enrollment.

By the end of the BME 299 semester, the student must defend their results and conclusions with an oral presentation, followed by a Q&A session with the course instructor, technical advisor and Reading Committee members.

Thesis close-out and handover

After the final Thesis has been formally approved by the Reading Committee and the College of Graduate Studies, the student should work with the BME 299 course instructor, technical advisor and Graduate Advisor to finalize the following items:

  • Submit a digital copy of your approved dissertation to the Graduate Advisor, along with a copy of the thesis information form (a.k.a. dissertation packet), with signatures of every reading committee member (and yours)
  • Forward to the Graduate Advisor a formal communication (usually an email) with the CGS approval of your dissertation
  • Obtain a CR grade in BME 298 and BME 299
  • Confirm with the Graduate Advisor that all the coursework listed in the approved candidacy form has been completed satisfactorily. Any deviation from the courses listed in the approved candidacy form requires the submission of a Course Substitution Request.
  • Hand over all the materials produced for the Thesis to the technical advisor, including:

          - all the peer-reviewed papers referenced in the report           - all the deliverables generated (reports, slides, protocols,                     manuscripts, conference abstracts)           - all the experimental/numerical data generated and analyzed           - documentation and instructions for new equipment and software (not already documented), for the benefit of future students

  • Clear the lab space, refrigerator space, and return all the equipment borrowed for the Thesis.

After all the items above have been completed, the Graduate Advisor will submit a Verification of Culminating Experience form to GAPE, on behalf of the student. GAPE will award the MS degree shortly thereafter.

Home > FACULTIES > BIOMEDENG > BIOMEDENG-ETD

Biomedical Engineering Program

Biomedical Engineering Theses and Dissertations

This collection contains theses and dissertations from the Department of Biomedical Engineering, collected from the Scholarship@Western Electronic Thesis and Dissertation Repository

Theses/Dissertations from 2024 2024

Co-delivery of Adipose-derived Stromal Cells and Endothelial Colony Forming Cells in Novel Cell-assembled Scaffolds as a Pro-angiogenic Cell Therapy Platform , Sarah A. From

Theses/Dissertations from 2023 2023

Multiparametric Classification of Tumor Treatment Using Ultrasound Microvascular Imaging , mahsa bataghva

Towards Patient Specific Mitral Valve Modelling via Dynamic 3D Transesophageal Echocardiography , Patrick Carnahan

Developing a Finite Element Model for Evaluating the Posterior Tibial Slope in a Medial Opening Wedge High Tibial Osteotomy , VIctor Alexander Carranza

Analysis and Characterization of Embroidered Textile Strain Sensors for Use in Wearable Mechatronic Devices , Jose Guillermo Colli Alfaro

Developing Bioactive Hydrogels Containing Cell-derived Extracellular Matrix for Bone and Cartilage Repair , Ali Coyle

Modelling of a TCA-driven Wearable Tremor Suppression Device for People with Parkinson’s Disease , Parisa Daemi

Using Machine Learning Models to Address Challenges in Lung Cancer Care , Salma Dammak

Longitudinal dynamics of cerebrospinal fluid Aꞵ, pTau and sTREM2 reveal predictive preclinical trajectories of Alzheimer’s pathology , Bahaaldin Helal

MAGNETIC RESONANCE IMAGING BIOMARKERS FOR PARKINSON’S DISEASE: A MACHINE LEARNING APPROACH , Dimuthu Henadeerage Don

Detecting Treatment Failure in Rheumatoid Arthritis with Time-Domain Diffuse Optical Methods , Seva Ioussoufovitch

Novel Magnetic Resonance Imaging-Compatible Mechatronic Needle Guidance System for Prostate Focal Laser Ablation Therapy , Eric R. Knull

The Development of Stimuli-responsive Hydrogels from Self-Immolative Polymers , Jared David Pardy

Free-hand Photoacoustic Imaging of Breast Cancer Tissue , Elina Rascevska

Development of a Cell-based Regenerative Strategy to Modulate Angiogenesis and Inflammation in Ischemic Muscle , Fiona E. Serack

Investigation of Dynamic Culture on Matrix-derived Microcarriers as a Strategy to Modulate the Pro-Regenerative Phenotype of Human Adipose-derived Stromal Cells , McKenna R. Tosh

Evaluating EEG–EMG Fusion-Based Classification as a Method for Improving Control of Wearable Robotic Devices for Upper-Limb Rehabilitation , Jacob G. Tryon

Theses/Dissertations from 2022 2022

A two-layer continuous-capillary oxygen transport model: Development and application to blood flow regulation in resting skeletal muscle. , Keith C. Afas

Development of a Hybrid Stereotactic Guidance System For Percutaneous Liver Tumour Ablation , Joeana N. Cambranis Romero

Large-scale Analysis and Automated Detection of Trunnion Corrosion on Hip Arthroplasty Devices , Anastasia M. Codirenzi

The Role of Transient Vibration of the Skull on Concussion , Rodrigo Dalvit Carvalho da Silva

Biomechanical Investigation of Complete and Partial Medial Collateral Ligament Injuries , Callahan Doughty

Towards A Comprehensive Software Suite for Stereotactic Neurosurgery , Greydon Gilmore

The Bio-Mechanical Development and Kinematic Evaluation of Zone I and Zone II Injuries and their Corresponding Surgical Repair Techniques using an In-Vitro Active Finger Motion Simulator: A Cadaveric Study , Mohammad Haddara

Image-based Cochlear Implant Frequency-to-Place Mapping , Luke William Helpard

Mechanical Evaluation of Gyroid Structures to Combat Orthopaedic Implant Infections , Sydney Hitchon

The Development of a Motion Sensing Device for Use in a Home Setting , Jaspreet K. Kalsi

A Novel Ultrasound Elastography Technique for Evaluating Tumor Response to Neoadjuvant Chemotherapy in Patients with Locally Advanced Breast Cancer , Niusha Kheirkhah

Thermo-responsive Antibiotic-Eluting Coatings for Treating Infection near Orthopedic Implants , Jan Chung Kwan

Effects of Modulating the Culture Microenvironment on the Growth and Secretome of Human Adipose-Derived Stromal Cells , Zhiyu Liang

Conducting Polypyrrole Hydrogel Biomaterials For Drug Delivery And Cartilage Tissue Regeneration , Iryna Liubchak

Motion and Crosslinked Polyethylene Wear in Reverse Total Shoulder Arthroplasty , Christopher Millward

Intracardiac Ultrasound Guided Systems for Transcatheter Cardiac Interventions , Hareem Nisar

Investigation of Cell Derived Nanoparticles for Drug Delivery and Osteogenic Differentiation of Human Stem/Stromal Cells , Shruthi Polla Ravi

Quantitative Image Analysis of White Matter Dysregulation Using Brain Normalization for Diagnostic Analysis of Pediatric Hydrocephalus , Renee-Marie Ragguett

Automation through Deep-Learning to Quantify Ventilation Defects in Lungs from High-Resolution Isotropic Hyperpolarized 129Xe Magnetic Resonance Imaging , Tuneesh Kaur Ranota

Early Biological Response of Articular Cartilage to Hemiarthroplasty Wear , Debora Rossetti

Sol-Gel Derived Bioceramic Poly(Diethyl Fumarate – Co – Triethoxyvinylsilane) Composite , Aref Sleiman

The Application of Digital Volume Correlation Bone Strain Measurements in the Osteoarthritic Glenohumeral Joint , Jakub R. Targosinski

Development of Brain-Derived Bioscaffolds for Neural Progenitor Cell Culture and Delivery , Julia Terek

Modelling and Evaluation of Piezoelectric Actuators for Wearable Neck Rehabilitation Devices , Shaemus D. Tracey

Development of a Combined Experimental-Computational Framework to Study Human Knee Biomechanics , Samira Vakili

Investigation on the Performance of Dry Powder Inhalation System for Enhanced Delivery of Levosalbutamol Sulfate , Yuqing Ye

Theses/Dissertations from 2021 2021

Development of a Wireless Telemetry Load and Displacement Sensor for Orthopaedic Applications , William Anderson

Organic-Inorganic Hybrid Biomaterials for Bone Tissue Engineering and Drug Delivery , Neda Aslankoohi

Fabrication Of Inkjet-Printed Enzyme-Based Biosensors Towards Point-Of-Care Applications , Yang Bai

The Use of CT to Assess Shoulder Kinematics and Measure Glenohumeral Arthrokinematics , Baraa Daher

The Development of Region-Specific Decellularized Meniscus Bioinks for 3D Bioprinting Applications , Sheradan Doherty

In Vitro Analyses of the Contributions of the Hip Capsule to Joint Biomechanics , Emma Donnelly

Long-Circulating, Degradable Lanthanide-Based Contrast Agents for Pre-Clinical Microcomputed Tomography of the Vasculature , Eric Grolman

Mixed-reality visualization environments to facilitate ultrasound-guided vascular access , Leah Groves

Diffusion Kurtosis Imaging in Temporal Lobe Epilepsy , Loxlan W. Kasa

Extracellular Matrix-Derived Microcarriers as 3-D Cell Culture Platforms , Anna Kornmuller

3D Printed Polypyrrole Scaffolds for pH Dependent Drug Delivery with Applications in Bone Regeneration , Matthew T. Lawrence

Development of Multifunctional Drug Delivery Systems for Locoregional Therapy , Xinyi Li

Motion Intention Estimation using sEMG-ACC Sensor Fusion , Jose Alejandro Lopez

Biomaterial for Cervical Intervertebral Disc Prosthesis , Helium Mak

Biomechanical Analysis of Ligament Modelling Techniques and Femoral Component Malrotation Following TKA , Liam A. Montgomery

Snapshot Three-Dimensional Surface Imaging With Multispectral Fringe Projection Profilometry , Parsa Omidi

4DCT to Examine Carpal Motion , Sydney M. Robinson

Seizure Detection Using Deep Learning, Information Theoretic Measures and Factor Graphs , Bahareh Salafian

Modeling Fetal Brain Development: A semi-automated platform for localization, reconstruction, and segmentation of the fetal brain on MRI , Jianan Wang

Immobilized Jagged1 for Notch3-specific Differentiation and Phenotype Control of Vascular Smooth Muscle Cells , Kathleen E. Zohorsky

Theses/Dissertations from 2020 2020

Simulation Approaches to X-ray C-Arm-based Interventions , Daniel R. Allen

Implementing a multi-segment foot model in a clinical setting to measure inter-segmental joint motions , Tahereh Amiri

Cardiac Modelling Techniques to Predict Future Heart Function and New Biomarkers in Acute Myocardial Infarction , Sergio C. H. Dempsey

Feasibility of Twisted Coiled Polymer Actuators for Use in Upper Limb Wearable Rehabilitation Devices , Brandon P.R. Edmonds

Metal Additive Manufacturing for Fixed Dental Prostheses , Mai EL Najjar

Using an Internal Auditory Stimulus to Activate the Developing Primary Auditory Cortex: A Fetal fMRI Study , Estee Goldberg

Development of Water-Soluble Polyesters for Tissue Engineering Applications , Trent Gordon

Development Of Hybrid Coating Materials To Improve The Success Of Titanium Implants , Zach Gouveia

A 3D Printed Axon-Mimetic Diffusion MRI Phantom , Tristan K. Kuehn

Development of an Active Infection Monitoring Knee Spacer for Two-Stage Revision , Michael K. Lavdas

Computational Modeling of the Human Brain for mTBI Prediction and Diagnosis , Yanir Levy

Pulmonary Imaging of Chronic Obstructive Pulmonary Disease using Multi-Parametric Response Maps , Jonathan MacNeil

Optimization of Indentation for the Material Characterization of Soft PVA-Cryogels , Md. Mansur ul Mulk

Development and Validation of Augmented Reality Training Simulator for Ultrasound Guided Percutaneous Renal Access , Yanyu Mu

A Biomechanical Investigation into the Effect of Experimental Design on Wrist Biomechanics and Contact Mechanics , Clare E. Padmore

Structure-Function Relationships in the Brain: Applications in Neurosurgery , Daiana-Roxana Pur

The Effect of Joint Alignment After a Wrist Injury on Joint Mechanics and Osteoarthritis Development , Puneet Kaur Ranota

Development and Validation of Tools for Improving Intraoperative Implant Assessment with Ultrasound during Gynaecological Brachytherapy , Jessica Robin Rodgers

Studies on Carbon Quantum Dots with Special Luminescent Properties and Their Capability of Overcoming the Biological Barriers , Ji Su Song

Machine Learning towards General Medical Image Segmentation , Clara Tam

The Migration and Wear of Reverse Total Shoulder Arthroplasty , Madeleine L. Van de Kleut

Video Processing for the Evaluation of Vascular Dynamics in Neurovascular Interventions , Reid Vassallo

Preparation of Intra-articular Drug Delivery Systems for the Treatment of Osteoarthritis , Ian Villamagna

Deep Reinforcement Learning in Medical Object Detection and Segmentation , Dong Zhang

Theses/Dissertations from 2019 2019

Fabrication and Characterization of Collagen-Polypyrrole Constructs Using Direct-Ink Write Additive Manufacturing , Rooshan Arshad

Development of a Force-Based Ream Vector Measurement System For Glenoid Reaming Simulation , David Axford

Investigation of Visual Perceptions in Parkinson's Disease and the Development of Disease Monitoring Software , Matthew Bernardinis

Tissue Equivalent Gellan Gum Gel Materials for Clinical MRI and Radiation Dosimetry , Pawel Brzozowski

Implementation of User-Independent Hand Gesture Recognition Classification Models Using IMU and EMG-based Sensor Fusion Techniques , José Guillermo Collí Alfaro

Scaffold Design Considerations for Soft Tissue Regeneration , Madeleine M. Di Gregorio

Remote Navigation and Contact-Force Control of Radiofrequency Ablation Catheters , Daniel Gelman

High-throughput Fabrication of Drug-loaded Core-shell Tablets with Adjustable Release Profiles from Surface-erodible and Photocrosslinkable Polyanhydrides , Armin Geraili Nejadfomeshi

Apply dry powder on drug loading and enteric coating of esomeprazole magnesium trihydrate beads and capsules , Xiaojing Ge

Bioluminescence resonance energy transfer (BRET) - based nanostructured biosensor for detection of glucose , Eugene Hwang

A Heterogeneous Patient-Specific Biomechanical Model of the Lung for Tumor Motion Compensation and Effective Lung Radiation Therapy Planning , Parya Jafari

The Co-Delivery of Syngeneic Adipose-Derived Stromal Cells and Macrophages on Decellularized Adipose Tissue Bioscaffolds for In Vivo Soft Tissue Regeneration , Hisham A. Kamoun

Improving Material Mapping in Glenohumeral Finite Element Models: A Multi-Level Evaluation , Nikolas K. Knowles

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Thesis Master of Science Degree (M.S.) in Biomedical Engineering

Jump start your research career.

Our thesis master of science (M.S.) degree program provides a strong foundation in biomedical engineering, engineering science and a foundational research experience to positioning our graduates for a biomedical engineering research career.

The thesis M.S. is a 30-credit program with an in-depth research experience that culminates in the defense of a scientific or engineering thesis in the field of biomedical engineering. The course options are flexible and tailored to the career goals and research focus of the student. Students in the thesis program will work closely with a research advisor and a thesis committee to define a cutting-edge research question in biomedical engineering. The program is ideal for engineers and scientists with a B.S. degree who are seeking the tools and experience to start a professional research career.

Thesis M.S. Course Requirements

Timeline to complete the thesis m.s. in biomedical engineering.

The program is flexible to meet the research and career goals of our students. A typical thesis M.S. student will take two years to complete the program and defend their thesis.

Application Deadlines

The deadline to apply for the fall semester is July 15. The spring application deadline is December 15.

Application Criteria

Bachelor of science degree.

Prior to beginning the program, all applicants must have obtained a bachelor of science degree or equivalent from an accredited university or institution. Engineering, science, mathematics and life science degrees are strongly preferred.

Course Requirements

All applicants must have successfully completed at least one programming course (preferably Matlab) and one differential equations course.

GPA expectations for applicants are 3.0 or higher. Lower scores will be considered under special circumstances or if other aspects of the application are deemed considerably strong.

Letters of Recommendation

Two strong letters of recommendation are required in addition to the completed application. We recommend that these be submitted by a faculty member or mentor who knows you well and can attest to your work, research, or academic merit.

It is also recommended that all applicants have knowledge of differential equations and some computer programming experience.

Visit the Penn State Graduate School website and apply to the “BME MS” program.

Tuition fees for Pennsylvania residents and non-Pennsylvania residents or international students can be found here . Typical program is full time fall and spring semesters and 2 credits in the summer.

Contact Information

  • Dr. Leo Lei Professor of Biomedical Engineering and Graduate Programs Coordinator 814-865-2290 [email protected]
  • Virginia Simparosa Graduate Programs Assistant 814-865-8087 [email protected]
  • Graduate Handbook

one-year non-thesis M.S. program

The Department of Biomedical Engineering administers the undergraduate major in biomedical engineering, and is a part of the university-wide Intercollege Graduate Degree Program, offering both M.S. and Ph.D. degrees in Bioengineering. Our work combines traditional engineering principles with medicine and technology for the betterment of human health and society. 

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Home > College of Engineering > Dept. of Biomedical Engineering > Dissertations, Master’s Theses and Master’s Reports

Dept. of Biomedical Engineering Dissertations, Master’s Theses and Master’s Reports

Explore our collection of dissertations, master's theses and master's reports from the Department of Biomedical Engineering below.

Theses/Dissertations/Reports from 2023 2023

Collagen V Promotes Fibroblast Contractility, And Adhesion Formation, And Stability , Shaina P. Royer-Weeden

Theses/Dissertations/Reports from 2022 2022

AN ANTIMICROBIAL POLYDOPAMINE SURFACE COATING TO REDUCE BIOFOULING ON TELEMETRY TAGS USED IN MARINE CONSERVATION PRACTICES , Ariana Smies

ELECTROCHEMICAL APPROACHES TO CONTROL CATECHOL-BASED ADHESION , Md Saleh Akram Bhuiyan

Theses/Dissertations/Reports from 2021 2021

CHARACTERIZATION OF PROLIFERATION AND MIGRATION OF BREAST CANCER CELLS TARGETED BY A GLUT5-SPECIFIC FRUCTOSE MIMIC , Srinivas Kannan

IMPACT OF HEMODYNAMIC VORTEX SPATIAL AND TEMPORAL CHARACTERISTICS ON ANALYSIS OF INTRACRANIAL ANEURYSMS , Kevin W. Sunderland

Investigation into the Hemodynamics of Aortic Abnormalities Through Computational Fluid Dynamics , Tonie Johnson

MODEL POLYMER SYSTEMS CONTAINING CATECHOL MOIETIES TO TUNE HYDROGEN PEROXIDE GENERATION FOR ANTIPATHOGENIC AND WOUND HEALING APPLICATIONS , Pegah Kord Fooroshani

Theses/Dissertations/Reports from 2020 2020

ARTIFICIAL SYNTHETIC SCAFFOLDS FOR TISSUE ENGINEERING APPLICATION EMPHASIZING THE ROLE OF BIOPHYSICAL CUES , Samerender Nagam Hanumantharao

DEVELOPMENT AND VALIDATION OF THE FLOW CHAMBER FOR SHEAR FLOW MECHANOTRANSMISSION STUDIES , Mohanish Chandurkar

ELECTROSPUN NANOFIBER SCAFFOLDS AS A PLATFORM FOR BREAST CANCER RESEARCH , Carolynn Que

Nanofiber Scaffolds as 3D Culture Platforms , Stephanie Bule

STUDY OF SILICA NANOPARTICLE COMPOSITE ON SILICA-HYDROGEN PEROXIDE COMPLEXATIONS AND THEIR EFFECTS IN CATECHOL BASED ADHESIVES , Rattapol Pinnaratip

Theses/Dissertations/Reports from 2019 2019

AN INVESTIGATION OF UNCERTAINTY IN ULTRASONIC ELASTOGRAPHY: A CONTINUUM BIOMECHANICS PERSPECTIVE , David P. Rosen

A Smart Implantable Bone Fixation Plate Providing Actuation and Load Monitoring for Orthopedic Fracture Healing , Brad Nelson

DEGRADABLE ZINC MATERIAL CHARACTERISTICS AND ITS INFLUENCE ON BIOCOMPATIBILITY IN AN IN-VIVO MURINE MODEL , Roger J. Guillory II

MAGNETOSTRICTIVE BONE FIXATION DEVICE FOR CONTROLLING LOCAL MECHANICAL STIMULI TO BONE FRACTURE SITES , Salil Sidharthan Karipott

OPTICAL VORTEX AND POINCARÉ ANALYSIS FOR BIOPHYSICAL DYNAMICS , Anindya Majumdar

TOWARD AN UNDERSTANDING OF THE CLINICAL RELEVANCE OF NITRIC OXIDE (NO) MEASUREMENTS IN IN VITRO CELL CULTURE STUDIES , Maria Paula Kwesiga

Theses/Dissertations/Reports from 2018 2018

AN INJECTABLE THERMOSENSITIVE BIODEGRADABLE HYDROGEL EMBEDDED WITH SNAP CONTAINING PLLA MICROPARTICLES FOR SUSTAINED NITRIC OXIDE (NO) DELIVERY FOR WOUND HEALING , Nikhil Mittal

EFFECTS OF TOPOGRAPHICAL FEATURES ON MICROVASCULAR NETWORK FORMATION , Dhavan D. Sharma

REVERSIBLY SWITCHING ADHESION OF SMART ADHESIVES INSPIRED BY MUSSEL ADHESIVE CHEMISTRY , Ameya R. Narkar

Studying mass and mechanical property changes during the degradation of a bioadhesive with mass tracking, rheology and magnetoelastic (ME) sensors , Zhongtian Zhang

Theses/Dissertations/Reports from 2017 2017

A 3D Biomimetic Scaffold using Electrospinning for Tissue Engineering Applications , Samerender Nagam Hanumantharao

A WIRELESS, PASSIVE SENSOR FOR MEASURING TEMPERATURE AT ORTHOPEDIC IMPLANT SITES FOR EARLY DIAGNOSIS OF INFECTIONS , Salil Sidharthan Karipott

COMPUTATIONAL ULTRASOUND ELASTOGRAPHY: A FEASIBILITY STUDY , Yu Wang

DESIGN OF ROBUST HYDROGEL BASED ON MUSSEL-INSPIRED CHEMISTRY , Yuan Liu

EFFECT OF SILICA MICRO/NANO PARTICLES INCORPORATION OVER BIOINSPIRED POLY (ETHYLENE GLYCOL)-BASED ADHESIVE HYDROGEL , Rattapol Pinnaratip

FABRICATION OF PREVASCULARIZED CELL-DERIVED EXTRACELLULAR MATRIX BASED BIOMIMETIC TISSUE CONSTRUCTS FOR MULTIPLE TISSUE ENGINEERING , Zichen Qian

IDENTIFICATION OF NITRIC-OXIDE DEGRADATION PRODUCTS OF ASCORBIC ACID , Sushant Satyanarayan Kolipaka

Implantable Wireless Sensor Networks: Application to Measuring Temperature for In Vivo Detection of Infections , Praharsh Madappaly Veetil

SYSTEMATIC STUDY OF HYDROGEN PEROXIDE GENERATION, BIOCOMPATIBILITY AND ANTIMICROBIAL PROPERTY OF MUSSEL ADHESIVE MOIETY , Hao Meng

Theses/Dissertations/Reports from 2016 2016

A WIRELESS SENSOR SYSTEM WITH DIGITALLY CONTROLLED SIGNAL CONDITIONING CIRCUIT FOR FORCE MONITORING AT BONE FIXATION PLATES , Govindan Suresh

DESIGN AND DEVELOPMENT OF OPTICAL ELASTOGRAPHY SETUP , Abhinav Madhavachandran

EFFECTS OF SCATTERING AND ABSORPTION ON LASER SPECKLE CONTRAST IMAGING , Kosar Khaksari

INHIBITION OF BACTERIAL GROWTH AND PREVENTION OF BACTERIAL ADHESION WITH LOCALIZED NITRIC OXIDE DELIVERY , Julia Osborne

WIRELESS IMPLANTABLE MAGNETOELASTIC SENSORS AND ACTUATORS FOR BIOMEDICAL APPLICATIONS , Andrew DeRouin

Wireless Sensor System for Monitoring Strains and Forces On An External Bone Fixation Plate , Sterling Prince

Reports/Theses/Dissertations from 2015 2015

DEVELOPMENT OF A CELL MORPHOLOGICAL ANALYSIS TOOL TO EVALUATE THE ULTRASOUND VIBRATIONAL EFFECTS ON CELL ADHESION , Joseph M. Smith

DEVELOPMENT OF HIGH CAPACITY HYPERBRANCHED NITRIC OXIDE DONORS FOR CONTROLLING SUBCUTANEOUS INFLAMMATION , Sean Hopkins

ENGINEERING APPROACHES FOR SUPPRESSING DELETERIOUS HOST RESPONSES TO MEDICAL IMPLANTS , Connor McCarthy

GELATIN MICROGEL INCORPORATED POLY (ETHYLENE GLYCOL) BIOADHESIVE WITH ENHANCED ADHESIVE PROPERTY AND BIOACTIVITY , Yuting Li

METABOLOMIC AND PROTEOMIC APPROACHES TO UNDERSTAND LEAD STRESS IN VETIVER GRASS (Chrysopogon zizanioides L. NASH) , Venkataramana R. Pidatala

PH RESPONSIVE, ADHESIVE HYDROGELS BASED ON REVERSIBLE CATECHOL - BORONIC ACID COMPLEXATION , Ameya Ravindra Narkar

SYSTEMATIC STUDY OF THE BIOLOGICAL EFFECTS OF NITRIC OXIDE (NO) USING INNOVATIVE NO MEASUREMENT AND DELIVERY SYSTEMS , Weilue He

THE INFLUENCE OF PASSIVE ANKLE JOINT POWER ON BALANCE RECOVERY , Stephanie E. Hamilton

Three-dimensional Mesenchymal Stem Cell Spheroids and Zn-based Biomaterials as Potential Cardiovascular Treatments , Emily Shearier

Reports/Theses/Dissertations from 2014 2014

DESIGN AND APPLICATION OF WIRELESS PASSIVE MAGNETOELASTIC RESONANCE AND MAGNETOHARMONIC FORCE SENSORS , Brandon D. Pereles

Reports/Theses/Dissertations from 2013 2013

Development of Optically Based pH Sensing Hydrogel and Controlled Nitric Oxide Release Polymer , Matthew T. Nielsen

Development of Vapor Deposited Silica Sol-Gel Particles for a Bioactive Materials System to Direct Osteoblast Behavior , Katherine Lynn Snyder

Reports/Theses/Dissertations from 2011 2011

Wireless and passive pressure sensor system based on the magnetic higher-order harmonic field , Ee Lim Tan

Reports/Theses/Dissertations from 2010 2010

Exploration of the role of serum factors in maintaining bone mass during hibernation in black bears , Rachel Marie Bradford

Influence of traumatic impaction and pathological loading on knee menisci , Megan Leigh Killian

Use of a 3D perfusion bioreactor with osteoblasts and osteoblast/endothelial cell co-cultures to improve tissue-engineered bone , Matthew J. Barron

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Master in Biomedical Engineering

Master's thesis.

Research is moving at a fast pace. Students in the program will participate in challenging research activities, especially during the final phase of their studies. In accordance with their supervisors students select a topic for their master's thesis. Usually the student will conduct thesis research and prepare the thesis during a time frame of up to six months (30 ECTS credits).

Through the teaching faculty's and staff's home institutions (academic and industrial) we are proud to provide a large network of possible places, national and international, to conduct research on an individually suited topic.

Thesis topics on ILIAS

Enrolled students in the Biomedical Engineering program will find all current and former thesis projects, as well as all important information on the application process, on the university’s E-learning platform ILIAS. Follow the link to the folder " Master's Thesis " and log in with your campus account. Then join the course "Master's Thesis". Contact the BME study coordination for further information.

Master's Thesis Presentations

Before graduation, students have to give a talk on their thesis project. Interested persons are cordially invited to attend the thesis presentation which will take place online. For access contact [email protected]

Former Thesis Presentations

  • MyU : For Students, Faculty, and Staff

MS - Thesis

Students are expected to complete the Master's degree within two years. View a sample plan .

Course credits

MS-Plan A students are required to complete at least 20 credits of coursework as indicated below. All electives must be at the 5000 level or higher.

Courses that meet each requirement

Master’s thesis and defense

In addition to the 20 credits of coursework, MS-Plan A students must complete 10 thesis credits (BMEn 8777). The thesis must be based on research done by the student in collaboration with his or her advisor. Master's students may register for thesis credits during any semester, with the advisor's approval.

Upon completing the thesis and with approval of the committee reviewers, the student must complete a thesis defense, which is closed to the public. The final written thesis is submitted to the University of Minnesota electronically, after making all revisions required by the examination committee.

Graduate degrees are awarded on the last working day of the month that the candidate completes all requirements. In the spring of each year, eligible students may elect to participate in the Arts, Sciences and Engineering Graduate Commencement Ceremony.

Related links

  • How to apply
  • Sample five-year plan
  • Minor in Biomedical Engineering
  • Intranet (enrolled grad students only)

More About the Master’s Program

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  • Institute of Biomedical Engineering and Technology (IBiTech)

BioMMedA master thesis topics 2023-2024

Prof. an ghysels.

  • Drugs as cargo: development of advanced path sampling simulations to investigate how peptides can carry drugs through cell membranes
  • Intracellular drug delivery by laser-induced photoporation: molecular modeling of photothermally heated nanoparticles near biological membranes  
  • Kinetic profiling of protein-drug binding using non-equilibrium molecular dynamics simulations  
  • Modelling and development of low-uptake macromolecular photoinitiators for light-based 3D-printing  
  • Molecular dynamics study: conformational classifier of ABL  

Dr. ir. Annette Caenen

  • Understanding the biomechanics of the infarcted heart: analysis of biaxial mechanical tests of the pig heart

Prof. Charlotte Debbaut

  • Computational fluid dynamics (CFD)-based pre-treatment planning for liver cancer  
  • Development of a Method to Aerosolize Viscous Drug Carriers in the Peritoneal Cavity of Mice  
  • Development of a Method to Analyze the Physiological Environment during Intraperitoneal Aerosolized Chemotherapy Delivery in Cancer Patients  
  • Intraperitoneal drug delivery using a branched catheter  
  • Modelling locoregional drug delivery for liver cancer immunotherapy using computational fluid dynamics  
  • Using CFD for the design and evaluation of medical catheters for transarterial liver cancer treatments  
  • Virtual preoperative planning of lung segmentectomies: development of a segment-predicting algorithm  
  • Virtual preoperative planning of partial nephrectomies: automation of complexity scoring systems to increase insight in the surgery

Prof . Pascal Verdonck

  • Centralized activated carbon filters to reduce pollution from volatile anesthetics – a feasibility study

Prof. Patrick Segers

  • 1D arterial network models for the automated interpretation of cardiovascular signals from the cradle to the grave
  • A combined experimental/computational biomechanical study on the role of intratendinous pressure in the pathophysiology of tendinopathy
  • Biomechanics of aortic ageing: a tale of growth and remodelling
  • Increased coronary artery calification in the athlete heart: a CFD study
  • Microstructural Modelling of Elastin Lamellar Structures and their impact on Arterial Biomechanics
  • MR elastography of the brain - a way to measure intracranial pressure? A computational/experimental study
  • Neuro-biomechanics of Chiara malformation: a computational study on intracranial and -spinal pressure fluctuations during daily life activities
  • Sex and heart failure: different pathophysiology or inadequate diagnostic criteria? A biomechanical modelling study.
  • Shear wave elastography for assessing interstitial fluid pressure: a combined computational-experimental study
  • Ultrasound shear wave elastography: the cardiologists ultimate tool to directly measure the functional stiffness of the heart
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Masters in Biomedical Engineering

Master project.

The Master thesis project requires 6 months of full time study and is awarded 30 credit points upon completion. The project may only be started when all other requirements have been completed. This applies in particular to the semester project as well as to industry /research internships (see Download Art. 35 of the study regulations (PDF, 648 KB) vertical_align_bottom ). The project should demonstrate innovative, independent scientific work and culminates with a written thesis.

The Master project can be carried out in an industrial setting or laboratory outside of the ETH. The Master project cannot be done at the same place as the research project, or internship (Exceptions can be granted by the tutor, or in case the tutor is involved, the study coordinator).

Consult the individual websites under Research for available Master thesis topics . Alternatively, go through the external page SiROP website call_made to find a suitable project.

The Master project should not be performed in the same laboratory as the semester project or the group- and research projects.

Master projects can be supervised by ETH professors from the field of Biomedical Engineering ( Download see list (PDF, 166 KB) vertical_align_bottom ) . Find a professor, and discuss with him/her your project using the following form. This must be done BEFORE the start of the project. Semester/Master Download Project Plan (DOC, 64 KB) vertical_align_bottom (example)

Register for the Master project on mystudies

When submitting the written document for your Master project, include the plagiarism Form (in German) . All documents (Project Plan, Written Report and Plagiarism Plan) are not submitted to study administration - this remains between you the the host group.

ODU Digital Commons

Home > Engineering & Technology > Biomedical Engineering > ETDs

Biomedical Engineering Theses & Dissertations

Theses and dissertations published by graduate students in the Department of Biomedical Engineering, College of Engineering, Old Dominion University since Fall 2016 are available in this collection. Backfiles of all dissertations (and some theses) have also been added.

In late Fall 2023 or Spring 2024, all theses will be digitized and available here. In the meantime, consult the Library Catalog to find older items in print.

Theses/Dissertations from 2023 2023

Dissertation: Investigation of Nanosecond Pulsed Electric Fields (nsPEF) Induced Anti-Cancer Mechanism and Enhanced B16f10 Melanoma Cancer Treatment , Kamal Asadipour

Thesis: Validation of Meta Motion IMU Sensors Through Measurement of Knee Angles During Gait , Kerri Caruso

Dissertation: Pulsed Electric Field Ablation: Mechanisms of Differential Cell Sensitivity and Methods to Mitigate Neuromuscular Excitation , Emily Gudvangen

Dissertation: Nanosecond Pulsed Electric Field Modulates Electron Transport and Mitochondrial Structure and Function , Lucas Nelson Potter

Dissertation: Cardiac Ablation and Stimulation With Nanosecond Pulsed Electric Fields (nsPEFs) , Federica Serra

Thesis: Ultrasensitive Tapered Optical Fiber Refractive Index Glucose Sensor , Erem Ujah

Theses/Dissertations from 2022 2022

Thesis: Investigating Arrhythmia Potential in Cardiac Myocytes in Presence of Long QT Syndrome , Victoria Lin Lam

Dissertation: The Development and Application of Open-Source 3D Bioprinted Organoid and Tumoroid Models for Translational Sciences , Xavier-Lewis Palmer

Dissertation: Engineering of Ideal Systems for the Study and Direction of Stem Cell Asymmetrical Division and Fate Determination , Martina Zamponi

Theses/Dissertations from 2021 2021

Dissertation: Molecular Dynamics Simulations of Ion Transport Through Electrically Stressed Biological Membranes , Federica Castellani

Dissertation: Integrative Computational Analysis of Muscle Near-Infrared Spectroscopy Signals: Effects of Oxygen Delivery and Blood Volume , Bhabuk Koirala

Dissertation: Subtalar Joint Definition in Biomechanical Models , Julia Noginova

Thesis: Drive Leg and Stride Leg Ground Reaction Forces Relationship to Medial Elbow Stress and Velocity in Collegiate Baseball Pitchers , Brett Smith

Dissertation: Generation, Analysis, and Evaluation of Patient-Specific, Osteoligamentous, Spine Meshes , Austin R. Tapp

Theses/Dissertations from 2020 2020

Thesis: Biphasic Gene Electrotransfer Enhances Gene Delivery In Vitro , John Bui

Thesis: Flexible Electrochemical Lactate Sensor , Peyton Miesse

Dissertation: Nanosecond Stimulation and Defibrillation of Langendorff-Perfused Rabbit Hearts , Johanna Neuber

Thesis: Impedance Analysis of Tissues in nsPEF Treatment for Cancer Therapy , Edwin Ayobami Oshin

Thesis: Do Different Pathologies Affect the Relationship Between the Stiffness of the Plantar Fascia and the Function of the MTP Joint? , Madeline Ryan Pauley

Dissertation: Validation of Nanosecond Pulse Cancellation Using a Quadrupole Exposure System , Hollie A. Ryan

Theses/Dissertations from 2019 2019

Dissertation: Estimating Cognitive Workload in an Interactive Virtual Reality Environment Using Electrophysiological and Kinematic Activity , Christoph Tremmel

Theses/Dissertations from 2018 2018

Dissertation: Non-Invasive Picosecond Pulse System for Electrostimulation , Ross Aaron Petrella

Dissertation: 3D Bioprinting Systems for the Study of Mammary Development and Tumorigenesis , John Reid

Thesis: Developmental Steps for a Functional Three-Dimensional Cell Culture System for the Study of Asymmetrical Division of Neural Stem Cells , Martina Zamponi

Theses/Dissertations from 2017 2017

Thesis: Thermally Assisted Pulsed Electric Field Ablation for Cancer Therapy , James Michael Hornef

Theses/Dissertations from 2015 2015

Dissertation: Multichannel Characterization of Brain Activity in Neurological Impairments , Yalda Shahriari

Dissertation: New Engineering Approaches to Arrhythmias and Myocardial Infarction , Frency Varghese

Dissertation: Development of a Practical Visual-Evoked Potential-Based Brain-Computer Interface , Nicholas R. Waytowich

Dissertation: Ablation of Cardiac Tissue with Nanosecond Pulsed Electric Fields: Experiments and Numerical Simulations , Fei Xie

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UW Bioengineering logo

INVENTING THE FUTURE OF MEDICINE

UW Bioengineering

Master of Science (MS)

Students working in a lab

Apply basic sciences and engineering to solve biomedical problems. Gain comprehensive research experience.

UW Bioengineering’s thesis-based Master of Science students bring diverse experience from a variety of academic disciplines to solve biomedical problems using basic science and engineering principles while gaining comprehensive research experience.

GRE NOW OPTIONAL

Apply to uw bioengineering’s master of science program, application opens: october 1 st  2023 for uw bioengineering’s ph.d. program, the deadline for autumn 2024 is december 1st, 2023 11:59pm pst..

We welcome you to learn more about the Master of Science program application process, policies and requirements, and to review our admissions frequently asked questions.

Master of Science program at a glance

  • Interdisciplinary approach: Students gain interdisciplinary knowledge of mathematics, engineering principles, physics, chemistry, physiology and modern biology.
  • Research experience: Students undertake a significant research project, and prepare a thesis documenting their work, which they must defend in a final oral examination.
  • Skills-building curriculum: Students complete a core curriculum focused on developing skills essential to professional growth and success in independent research.

Master of Science program features

  • Prior to the first quarter identify which track to pursue (BPS: Bioengineering Professional Series or PTC: Program on Technology Commercialization).
  • By the end of the second quarter, find a research adviser to collaborate on a plan of study and research, and who will supervise the thesis.
  • By the end of Autumn Quarter of the second year in the program, form a Supervisory Committee (no less than 2 members).
  • Within one quarter of establishing the Committee, the Supervisory Committee must review and approve the student’s academic plan.
  • By the end of the second year, determine project status and prepare to write the thesis.
  • During the final quarter, submit a M.S. request with the Graduate School and defend the thesis.

Thesis and final examination

The thesis must demonstrate the author’s ability to solve a problem independently and to describe the solution clearly and succinctly. Students must orally defend the thesis via the Final Examination. The thesis must show the way that the problem was posed, the methods used for its solution and the solution of the problem. The thesis should suggest the importance of the results and their application to other problems of the same kind. The thesis is based on work performed while taking at least nine credits of BIOEN 700.

MS requirements (Minimum 36 credits)

Core courses (4 credits minimum from either track):

  • Bioengineering Professional Series (BPS) Track: BIOEN 530: Literature Analysis (2 credits, CR/NC), BIOEN 531: Grant Writing (2 credits) or BIOEN 532: Professional Development (1 credit, CR/NC)
  • Program on Technology Commercialization (PTC) track: BIOEN 504: PTC I (4 credits) or BIOEN 505: PTC II (4 credits)

Statistics (3 credits minimum):

  • BIOSTAT 517, 524; STAT 502, 504, 512, BIOEN 599* (Bioengineering statistics), or UCONJ 510 (2 cr, approved by petition when submitting the student plan) Note: BIOEN 599 is no longer offered; however, if you have taken it, it will fulfill the Statistics requirement.

Electives (19 credits minimum of bioengineering-related, PI-approved electives):

  • 6 credits must have a BIOEN prefix and be graded
  • 2 credits can be CR/NC

Additional MS requirements

  • Students will complete 1-2 laboratory rotations. The laboratory rotations occur during the first year of the MS degree.
  • 18 credits must be at the 500-level
  • 18 graded credits must be at the 400/500-level
  • 9 credits must have a BIOEN prefix
  • Students must complete 9 thesis research credits of BIOEN 700 prior to MS graduation
  • 36 total credits

MS in Biomedical Engineering

The Master's degrees require a minimum of 30 credits earned through the completion of ten approved courses with grades of S (satisfactory) or at least a B-. At least two of these courses must be chosen from the list of core courses below.

All MS students are admitted to the non-thesis Master's degree program. Students who wish to complete a master's thesis must first pass the original research proposal course (BME299-ORP), and only then may register for 9 credits of MS thesis.

Core Courses – Biomedical Engineering Graduate Program

Requirements include:, master of science.

  • 2 of the three core courses listed above (6 credits)
  • 1 Professional development (Engineering Management) course (3 credits)
  • One of the electives may be the BME 299-01 project course

Master of Science with thesis

  • 3 BME electives (9 credits)
  • 1 additional elective course approved by advisor (3 credits)
  • BME 299-ORP (Original Research Presentation) course (3 credits)
  • Master's Thesis - research committee meetings and thesis defense (9 credits)

Additional program details are provided in the  BME Graduate Handbook , which is revised at the beginning of each academic year.

Fifth-Year Master's Degree Program

The School of Engineering offers exceptional Tufts undergraduate students the option of pursuing a  combined Bachelor of Science and Master of Science degree (BS/MS)  as a thesis or non-thesis program.

Progress Forms

Current students should fill out the applicable form(s) per BME Handbook requirements, obtain necessary signatures, and submit the form(s) to the Biomedical Engineering Department Manager,  Lorin Polidora .

  • MS Degree Sheet
  • MS Degree with Thesis
  • ORP Completion Form
  • Foundation Waiver

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Biomedical Engineering graduate programs

Transforming healthcare.

The Department of Biomedical Engineering's  (BME) graduate program features an interdisciplinary research and training approach. Its world-class faculty deliver cutting-edge education and are often cross-appointed in multiple departments, enabling students to collaborate with experts and fellow students in various fields, including engineering, physics, biology, neuroscience, robotics, computer science, and machine learning. This collaborative effort ensures an unparalleled graduate education for BME students.

Application periods

  • Ph.D. - October 1st through December 1st
  • Master’s - October 1st through January 31st
  • Ph.D. and Master’s - July 1st through August 31st
  • Admission requirements
  • Graduate courses

students work in lab at CMU's Scott Hall

Doctor of philosophy degree programs

  • Ph.D. in Biomedical Engineering The Biomedical Engineering Ph.D. program is designed to nurture the next generation of leaders in biomedical engineering, preparing students for careers in academia and industry. Flexible degree requirements allow students to balance breadth and depth and develop a research plan best suited to their career goals.
  • Combined Ph.D. in Biomedical Engineering - Doctor of Medicine The Department of Biomedical Engineering participates in a combined M.D.-Ph.D. program, offering a Doctor of Medicine degree from the University of Pittsburgh School of Medicine and a Ph.D. in Biomedical Engineering from Carnegie Mellon University. The aim is to allow physician-engineers to blend research and clinical perspectives in treating patients.

student collaborate with professor working on computer

Master’s degree programs

  • Master of Science in Biomedical Engineering The Master of Science in Biomedical Engineering is designed to build both depth and breadth of knowledge in the field. The program appeals not only to students from standalone biomedical engineering programs but also to students of traditional engineering or basic science disciplines who wish to develop a career in biomedical engineering.
  • Master of Science in Biomedical Engineering - Applied Study The Master of Science in Biomedical Engineering - Applied Study program combines in-depth, course-based academic training with real-world experiences. Students elect to take part in an internship, practicum, or research as part of the degree requirements.
  • Master of Science in Biomedical Engineering - Research The Master of Science in Biomedical Engineering - Research is designed to equip students with a unique blend of advanced knowledge in biomedical engineering and independent research skills. The program offers comprehensive course-based academic training, along with an in-depth, hands-on research experience.
  • Master of Science in Computational Biomedical Engineering The Master of Science in Computational Biomedical Engineering offers in-depth, course-based academic training focused on computational methods applied in sub-fields of BME. It is meant for CMU College of Engineering students enrolled in the Integrated Master’s and Bachelor’s Degree Program who desire additional training in computational techniques.
  • Master of Science in Computational Biomedical Engineering - Applied Study The Master of Science in Computational Biomedical Engineering - Applied Study program supplements the in-depth, course-based computational training of the MS in Computational BME degree with an additional experience in which biomedical engineering is applied in a real-world setting.
  • Master of Science in Computational Biomedical Engineering - Research The Master of Science in Computational Biomedical Engineering - Research program supplements the in-depth, course-based computational training of the MS in Computational BME degree with an in-depth, original research experience leading to the submission of a thesis or the publication of a peer-reviewed journal paper.
  • Master of Science in Artificial Intelligence Engineering - Biomedical Engineering (MS in AIE-BME) The Master of Science in Artificial Intelligence Engineering -Biomedical Engineering offers students the opportunity to become experts in the AI and Biomedical Engineering domains. Students learn to integrate AI/machine learning approaches with engineering design and system analysis to develop effective solutions to challenging biomedical engineering problems.
  • Dual Master of Science in Biomedical Engineering and Engineering & Technology Innovation Management The Dual M.S. in Biomedical Engineering and Engineering and Technology Innovation Management educates future engineering leaders by providing frameworks to foster and manage technical innovation. The Master of Science in Biomedical Engineering program may be combined with the Engineering and Technology Innovation Management program to form a 21-month dual master of science program encompassing two highly interdisciplinary, complementary, and innovative fields.

Research areas

Biomaterials and nanotechnology

Biomechanics

Biomedical imaging

Cardiopulmonary engineering

Cell and tissue engineering

Computational biomedical engineering

Medical devices and robotics

Neural engineering

students work in a lab at CMU's Scott Hall

Student experience

Biomedical Engineering graduate students join a global community of scholars and researchers, fostering diversity and collaboration. Students are encouraged to enhance their professional and technical skills through active participation in Carnegie Mellon’s student organizations .

  • Graduate Biomedical Engineering Society
  • Society of Women Engineers
  • National Society of Black Engineers
  • Society of Hispanic Professional Engineers
  • Society of Asian Scientists and Engineers
  • Graduate Student Assembly

Energy & Environment

Dowd Fellowship encourages ambitious student research

Four Ph.D. students in the College of Engineering have received funding to pursue research on valuable, relatively unexplored topics.

A new platform aims to discover novel biomarkers to evaluate organ quality after donation, but before transplantation, and reveal new therapeutic targets to improve donor organ function.

Bringing donor organs back to life

Health & Biomedicine

Boosting oxygenation for transplanted cell-based therapies

To advance cell-based therapies, researchers have identified a novel device that makes on-site oxygen for biological cells transplanted inside the body.

  • Research paper

Curing cancer is not enough

Colette Bilynsky pursues both cancer research and health policy to ensure that potential cures are affordable and accessible to all.

Advanced Manufacturing

3D micro-ice printing for medical applications

Carnegie Mellon researchers receive funding from the Manufacturing Futures Institute to continue work on 3D micro-ice printing for medical applications.

Curating sustainable meat alternatives

Using cellular agriculture, the Abbott lab is working on a sustainable meat alternative that is safe and tastes good, without needing to sacrifice any animals.

ARPA-H fast tracks development of new cancer implant tech

ARPA-H has awarded $45 million to a multi-institutional team of researchers to rapidly develop sense-and-respond implant technology that could slash U.S. cancer-related deaths.

Zeynep Ozkaya’s work in Jana Kainerstorfer’s biophotonicslab has helped her to better understand the signal processing principles she is learning in her electrical engineering courses.

Relationships are key to the research and the researchers

Student works on tiny bio robots

Lameck Beni, an undergraduate student in mechanical engineering and biomedical engineering, conducted research on small biodegradable robots that have important medical applications.

Cybersecurity

2023 Dean’s Early Career Fellows announced

Xi (Charlie) Ren, Victoria Webster-Wood, and Ding Zhao have received the honor for their contributions to their respective fields.

News & Events

Engineering alumni double team innovation in sport

Two CMU materials science and biomedical engineering alumni are at the forefront of the development of an airless basketball made through additive manufacturing techniques.

Krause and Abbott receive NSF CAREER Awards

CMU College of Engineering’s Krause and Abbott receive NSF CAREER Awards for their research in materials science and biomedical engineering.

Carnegie Mellon’s entry into online education will provide working professionals flexible access to world class graduate-level training in emerging and evolving technologies.

New online graduate certificates to launch this fall

Improving patient care through ingestible sensing capsules

A team of CMU researchers is seeking an alternative to endoscopies for patients with gastrointestinal diseases with fewer risks and more convenience through digestible gelatin-based sensors.

Now printing: seaweed-based, biodegradable actuators

We are one step closer to naturally compostable robots now that researchers at Carnegie Mellon can print actuators using a bio-ink made from seaweed.

Forbes includes six CMU alumni in 30 Under 30 in Energy

Six alumni were listed in Forbes 30 Under 30 in Energy for their groundbreaking startup companies.

After-school bioprinting course activates imagination, new skills

A new course led by CMU biomedical engineers at the Citizen Science Lab is teaching middle- and high-school students from underserved communities the processes involved in soft-tissue biofabrication.

Dowd Fellowship supports “high-risk, high-reward” research

Each year, thanks to a generous gift from alumnus Philip Dowd (B.S. MSE ’63) and his wife Marsha, the Dowd Engineering Seed Fund for Graduate Student Fellowships supports a year of doctoral expenses for multiple Ph.D. students.

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Home > USC Columbia > Medicine, School of > Biomedical Science > Biomedical Science Theses and Dissertations

Biomedical Science Theses and Dissertations

Theses/dissertations from 2023 2023.

Gluten Free Diet Ameliorates SI Enteropathy in IGA Deficient Mice , Ryan Albert William Ball

Aortopathies: Mechanism of Pathogenesis and Therapy , Mengistu G. Gebere

Leptin, Serotonin, and the Control of Food Intake , Nicholas David Maxwell

Targeting Macrophages in Cancer Models Using Natural Compounds , Sierra Jordan McDonald

Neurodevelopmental and Transient Impacts of Brain Kynurenic Acid Elevation and Sleep-Wake Behavior , Katherine Rentschler

Exploration Into the Relationship Between Colitis and Depression: A Potential Role for the Aryl Hydrocarbon Receptor , Kasie Lynn Roark

B-Cell-Specific MHCII Promotes Host-Microbiome Symbiosis , Mary Melissa Roland

Cardiac Imaging in Mice With Micro-Computed Tomography: An Assessment , Kyle Porter Stegmann

Theses/Dissertations from 2022 2022

Role of Epigenome in Regulation of Inflammation By AHR Ligands 2,3,7,8-Tetrachlorodibenzo-P-Dioxin and 6-Formylindolo[3,2-B] Carbazole , Alkeiver Cannon

Neurochemical, Molecular, and Behavioral Effects of Intranasal Insulin , Jennifer Marie Erichsen

Sex Differences and Potential Non-invasive Treatments for Calcific Aortic Valve Disease , Henry Pascal Helms

Decellularization Strategies of Naturally Derived Biomaterials for Tissue Engineering Applications , Julia Elizabeth Hohn

Role of AhR in the Epigenetic Regulation of Immune Cells in Lungs During Acute Respiratory Distress Syndrome , Bryan Latrell Holloman

The Submission of a Section 513(g) Request For Information , Morgan Ashley Lano

Engineering and Optimization of an AAV Based Viral Vector to Limit the In-Vitro Expression of SARS-CoV-2 Spike-Protein , Ronald Anderson Smithwick

In Vitro and in Vivo Studies of Mediator Kinase , Lili Wang

Theses/Dissertations from 2021 2021

Role of AhR Ligands in Immune Modulation to Suppress Inflammation Through the Regulation of Microrna and Gut Microbiome , Osama Azeldeen Abdulla

Role of Estrogen in Regulating Diet-Induced Obesity in Females , Ahmed Aladhami

Impact of Acetylcholine on Internal Pathways To Basal Amygdala Pyramidal Neurons , Tyler Daniel Anderson-Sieg

Pseudomyxoma Peritonei Derived Cancers: A Novel Study on Growth and Growth Suppression Utilizing Common Colorectal Cancer Agents , Raymond Kennith Bogdon

Impact of Acetylcholine on Amygdala Network Oscillations , Joshua Xavier Bratsch-Prince

Real Time Neurochemical Analysis of the Brain For Pharmacological Treatments in Mood Disorders And Neurodegeneration , Anna Marie Buchanan

Regulation of Inflammatory Processes by Tryptamine, Cannabidiol and 2,3,7,8-Tetrachlorodibenzo-P-Dioxin , Nicholas Dopkins

Study of the Effect of B-Cell-Intrinsic Mhcii Antigen Presentation on Germinal Center B Cell Evolution Using The Brainbow Mouse Model , Nia Hall

Mechanism of Therapeutic Efficacy of New Drugs in Glioblastoma , Firas Hameed Khathayer

The Effect of Low Dose Penicillin on Tumor Development in Apc Min/+ Mice , Kinsey Ann Sierra Meggett

Defining the Pathophysiology of Gut Humoral Immunodeficiency , Ahmed Dawood Mohammed

The Role PDE11A4 Signaling and Compartmentalization in Social Behavior , Kaitlyn Pilarzyk

Anatomical Correlates of Age-Related Basal Forebrain Dysfunction , Brandy Lynn Somera

A Novel Model to Study Adipose-Derived Stem Cell Differentiation , Austin N. Worden

Theses/Dissertations from 2020 2020

Molecular Mechanisms of Loss of E7 Expression in HPV16 – Transformed Human Keratinocytes , Fadi Farooq Abboodi

17 β-Estradiol and Phytoestrogens Attenuate Apoptotic Cell Death in HIV-1 Tat Exposed Primary Cortical Cultures , Sheila Marie Adams

Helicobacter’s Effects on Colitis/Colon Cancer and the Response to Indole 3-Carbinol , Rasha Raheem Abdulhamza Alkarkoushi

A Comparative Study of Cannabinoids & CB1 Receptor GI Signaling , Haley Kristen Andersen

Expansion Microscopy: A New Approach to Microscopic Evaluation , Ashley Ferri

The Role of Acute and Chronic Neuroinflammation in Depression: Uncovering the Relationship Between Histamine and Serotonin Transmission , Melinda Hersey

The Use of Natural Anthraquinone Emodin as a Primary and Complementary Therapeutic in the Treatment of Colorectal Cancer , Alexander-Jacques Theodore Sougiannis

The Effects of Super-Resolution Microscopy on Colocalization Conclusions Previously Made With Diffraction-Limited Systems in the Biomedical Sciences , Madison Emily Yemc

Theses/Dissertations from 2019 2019

Role of Epigenome and Microbiome in Cannabinoid and Aryl Hydrocarbon Receptor-Mediated Regulation of Inflammatory and Autoimmune Diseases , Zinah Zamil Al-Ghezi

Tissue-Specific Roles of Transforming Growth Factor Beta Ligands in Cardiac Outflow Tract Malformations and Calcific Aortic Valve Disease , Nadia Al-Sammarraie

Role of Epigenetic, Molecular and Cellular Pathways in the Regulation of Inflammation , William James Becker

Neurochemical and Behavioral Outcomes of Intranasal Orexin Administration in Young and Aged Animals , Coleman Blaine Calva

Interdependent Mechanisms of Stress Susceptibility , Julie Elaine Finnell

Astrocyte Sensitivity to Dopamine in Culture and Ex Vivo , Ashley L. Galloway

Three-Dimensional Plasma Cell Survival Microniche in Multiple Myeloma , Katrina A. Harmon

Role of Epigenome and Microbiome in Endocannabinoid-Mediated Regulation of Inflammation During Diet-Induced Obesity , Kathryn Miranda

Epigenetic and Purinergic Regulation of Mast Cells Mediator Release , Zahraa Abdulmohsin Mohammed

Effect of TCDD, an Environmental Contaminant, on Activation of AHR Leading to Induction of Myeloid Derived Suppressor Cells (MDSCS) and the Ability of Resveratrol, a Botanical, to Neutralize this Effect , Wurood Hantoosh Neamah

An Anatomical Basis of the Differential Cholinergic Modulation of Valence-Specific Pyramidal Neurons in the Basolateral Amygdala , Nguyen Vu

Analysis of Cellular Interactions Within a Collagen Hydrogel , Austin N. Worden

Theses/Dissertations from 2018 2018

Role of Mammary Microenvironment in Promoting Left-Right Differences in Tumor Progression, Metastasis, and Therapeutic Response , Huda Issa Atiya

Enhancements in Alginate Microencapsulation Technology & Impacts on Cell Therapy Development , Marwa Belhaj

Effect Of Resveratrol On The Development Of Eczema , Christopher Carlucci

The Nervous System And Cancers Of The Head And Neck , Christian A. Graves

Turning Up Antitumor Immunity Against Breast Cancer , Johnie Hodge

Exploring Alternative Therapeutic Interventions For The Treatment Of Leigh Syndrome , Stephanie Martin

Regulation Of Prostaglandin D2 And Angiogenesis-Related Factors From Human Skin Mast Cells By Interleukin-6 And Resveratrol , Cody Cody McHale

Advanced Clearing Methods and Imaging Techniques for Optimized Three- Dimensional Reconstruction of Dense Tissues , Caleb A. Padgett

Role Of MIR-489 In HER2 Positive Breast Cancer , Yogin Patel

Operation Of The Leica SP8 Multiphoton Confocal System Using Single Or Multiple Fluorochromes , Amy E. Rowley

Theses/Dissertations from 2017 2017

Garlic Inhibits Inflammation during Dengue Infection , Alex R. Hall

Functional Role of the Homeobox Transcription Factor Six1 in Neoplastic Transformation of Human Keratinocytes , Maria Hosseinipour

Individual Differences in Markers of Cholinergic Signaling Correlating to Fear and Extinction Learning , Grace C. Jones

The Role Of Cyclin-Dependent Kinase 8 In Vascular Disease , Desiree Leach

Succination Impairs Protein Folding and Promotes Chop Stability in the Adipocyte during Diabetes , Allison Manuel

Muscarinic Acetylcholine Receptor M1’s Impact on Fear Extinction Learning , Joshua R. McElroy

Hemodynamic Regulation Of Cardiac Valve Development , Vinal Menon

The Role Of Inflammation In Atherosclerosis , Fatma Saaoud

Synergism of Quercetin and Sodium Butyrate for Controlling Growth of Glioblastoma , Matthew Alan Taylor

Mast Cells and Lipid Cross-Talk in Skin Inflammation , Piper Alexandra Wedman

Theses/Dissertations from 2016 2016

Tumor Suppressor p53 Response To UV Light In Normal Human Keratinocyte Strains From Different Individuals , Fadi Farooq Abboodi

Vitamin D and Stress Fractures in Collegiate and Professional Athletes , Christian Michael Askew

Linking Obesity & Breast Cancer: Role Of Monocyte Chemoattractant Protein-1 And High Fat Diet-Induced Inflammation On Mammary Tumorigenesis , Taryn L. Cranford

The Identification Of The Direct And Indirect Pathways Through Which Leptin Facilitates Synaptic Plasticity In The Hippocampus , Catherine Van Doorn

Morphogenic Effects Of Dopamine In Cultured Rat Hippocampal Astrocytes , Ashley L. Galloway

Emodin Regulates Macrophage Polarization: Application In Breast Cancer Treatment , Stephen Iwanowycz

Differences In Resting-State Functional Connectivity Of Chronic Migraine, With And Without Medication Overuse Headache, And The Effectiveness Of Sphenopalatine Ganglion Block As A Treatment For Repairing Dysfunctional Connectivity. , Kaitlin Krebs

Prospective Assessment Of Health Disparities And Injury Risk Factors At Basic Combat Training At Ft. Jackson , Kristin Lescalleet

Transcriptional And Post-Transcriptional Regulation Of NRF2 In The Heart By The Deubiquitinase CYLD , Bryan J. Mathis

Regulation of Chronic and Acute Inflammatory Disease by microRNA and Microbiota , Pegah Mehrpouya-Bahrami

The Effect of Arsenic on Type 2 Diabetes and Inflammation , Kayla Penta

Factors Influencing The Collagen Fiber Angle Distribution in The Mouse Aorta , Shana Roach Watson

The Role of Epidermal Stem/Progenitor-Like Cells In HPV-Mediated Pre-Neoplastic Transformation , Yvon L. Woappi

Theses/Dissertations from 2015 2015

Extensive Genome Rearrangements of Caulobacter K31 and Genomic Diversity of type B3 Bacteriophages of Caulobacter Crescentus , Kurt Taylor Ash

Evaluating Muscle Fiber Architecture , Morgan Ashley Flahive

Characterization of STARD4 and STARD6 Proteins in Human Ovarian Tissue and Human Granulosa Cells and Cloning of Human STARD4 Transcripts , Aisha Shaaban

Cannabinoid-mediated Epigenetic Regulation of Immune Functions , Jessica Margaret Sido

The Effect of 3D Collagen Scaffolds on Regulating Cellular Responses , Chad Simmons

Theses/Dissertations from 2014 2014

Metformin Arrests Growth and Induces Apoptosis of Neuroblastoma Cells , Nadia Al-Sammarraie

Cellular and Biochemical Effects of Sparstolonin B on Endothelial Cells to Inhibit Angiogenesis , Marwa Belhaj

An Evolutionary Perspective on Infectious and Chronic Disease , John Eberth

Status Epilepticus Induced Alterations in Hippocampal Anatomy and Neurotransmission , Denise K. Grosenbaugh

The Cardio-Protective Effects of Substance P in Both Ischemia/Reperfusion and and Short-Term Hypoxia Rat Models , Shaiban Jubair

MUSCARINIC MODULATION OF BASOLATERAL AMYGDALA , Lei Liu

MCP-1 In Colorectal Cancer: Benefits of Exercise , Jamie Lee McClellan

Diethylstilbestrol (DES) mediates immune suppression via modulation of microRNA expression in mice , Martine Menard

Effects of cPLA-2 on the Migration and Proliferation of Human Vascular Smooth Muscle Cells and the 2-D Migratory Patterns of Tropomyosin in Femoral and Abdominal Aorta Tissue , Jaimeson Thomas Powell

The Role of MicroRNA in Staphylococcal Enterotoxin B-Induced Inflammation and Acute Lung Injury , Roshni Rao

ENHANCING PERIPHERAL OPIOID ANALGESIA: DEVELOPMENT OF VIRAL VECTOR AND SMALL PEPTIDE THERAPIES , Sherika Smith

ROLE OF APELIN AND ENDOTHELIN SYSTEMS IN THE PAIN ASSOCIATED WITH SICKLE CELL DISEASE , Terika Smith

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Biomedical Engineering Graduate Group

Ms plan i - thesis, ms plan i degree requirements.

The requirements for a Master of Science Plan I degree in Biomedical Engineering are completion of 30 units of approved coursework, including four core courses (below), and an MS thesis approved by a three-member faculty committee. 28 units of these courses must be taken for a letter grade; the minimum acceptable grade is B- and the minimum overall GPA is 3.00. S/U-graded courses (e.g., research 290C and 299 and seminar 290 courses) do not count toward the 28-unit graded coursework requirement.Each MS student must pass the 4 core courses and all additional elective courses completed to satisfy degree requirements. Each student’s program of study must be approved by their major professor and signed by the corresponding Biomedical Engineering graduate advisor. Students are asked to file a preliminary program of study with the graduate group within the first two weeks of the first quarter of enrollment. The study plan is to be updated annually.

MS Degree Requirements

MS Plan I Checklist

Core Courses

Bim 202: cell and molecular biology for engineers.

Preparation for research and critical review in the field of cell and molecular biology for biomedical or applied science engineers. Emphasis on biophysical and engineering concepts intrinsic to specific topics including protein traffic, the cytoskeleton, cell motility, cell division, and cell adhesion. Modern topics in mechano-biology of cancer cells and stem cells.

  • Quarter:  F
  • Units:  4
  • Requirements:  Biol

BIM 204: Physiology for Bioengineers

Basic human physiology of the nervous, muscular, cardiovascular, respiratory, endocrine, lymphatic, renal and gastrointestinal systems and their interactions. Emphasis is placed on the physical and engineering principles governing these systems, including control and transport processes, fluid dynamics, and electrochemistry.

  • Units:  5

BIM 281: Acquisition and Analysis of Biomedical Signals

This lecture/laboratory course introduces basic concepts associated with digital signal recording and analysis. Lectures introduce concepts of sampling; standard probability distributions; statistical error analysis related to experimental design; Fourier, and spectral analysis applied to signal and image processing. Labs are designed to provide hands-on experience with digital oscilloscopes, waveform generators, optical microscopy, Matlab- and Labview-based software applications.

  • Quarter:  S
  • Requirements:  Engr

BIM 283: Experimental Design for Biomedical Engineers

Provides biomedical engineering graduate students with the tools to properly design experiments, collect and analyze data, and extract, communicate and act on information generated. 

  • Quarter:  W

BIM 284: Mathematical Methods for Biomedical Engineers

Theoretical and numerical analyses of linear and nonlinear systems, ordinary and partial differential equations that describe biological systems and instruments that measure them. Students will be introduced to numerical solution techniques. 

Course Selection

At least 18 units of the 28 unit total graded coursework must be graduate-level engineering courses (those numbered 200 – 289). The remaining units must be either advanced undergraduate (courses numbered 100 – 189) or graduate courses (200 – 289).  Students must enroll in BIM 290 seminar course (1 unit) during each quarter it is offered.  Students select courses in consultation with their major professor and graduate advisor. For an up to date listing of classes, please see the  courses  page.

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  • Engineering
  • Biomedical Engineering

Research Papers/Topics in Biomedical Engineering

Sweat sensors in the smart wearables era - a review.

In recent years, there has been significant interest in developing wearable devices to mimic the integrated sensing of life forms, which enhances their performance and survival capabilities. Progress in the development of physical sensors and wearable electronics has been promising, leading to numerous consumer products that measure activity, posture, heart rate, respiration rate, and blood oxygen level. Despite the challenges in retrieving and processing bodily fluids, wearable chemical sens...

Effect of Magnetic field on Micro-organisms

  This study uses the model organism, C. elegans, to investigate its sensitivity and response to static magnetic fields. Wild-type C. elegans are put into microfluidic channels and exposed to permanent magnets for five cycles of thirty-second time intervals at field strengths ranging from 5 milli Tesla to 120 milli Tesla. Recorded and analyzed with custom software, the results of the worm's movement - the average velocity, turning and curling percentage - were compared to control experiments...

Worm Egg Counting using Machine learning

To evaluate the level of infestation of the soybean cyst nematode (SCN), Heterodera glycines, in the field, egg population densities are determined from soil samples. Sucrose centrifugation is a common technique for separating debris from the extracted SCN eggs. We have developed a procedure, however, that employs OptiPrep as a density gradient medium, with improved extraction and recovery of the eggs compared to the sucrose centrifugation technique. Also, we have built computerized methods t...

Paralysis modes of worms in drugs

The emergence of new drugs is often driven by the escalating resistance of parasites to existing drugs and the accessibility of more advanced technology platforms. Microfluidic devices have allowed for quicker testing of compounds, regulated sampling/sorting of entire animals, and automated behavioral pattern detection. In the majority of microfluidic devices, the effects of drugs on small animals (e.g. Caenorhabditis elegans)elegant are quantified by an endpoint, dose response curve that sho...

Modes of paralysis of worms in anthelmintic drugs

Microfluidic chip for culturing gene-edited bacteria.

By utilizing a low-cost engineering tool, we have created a microfluidic platform to study bacteria at the single cell level, allowing us to unlock insights into microbial physiology and genetics that would otherwise not be possible. The platform is composed of 3D devices made of adhesive tapes, an agarose membrane as the resting substrate, a temperature-controlled environmental chamber, and an autofocusing module. With this technology, we have been able to observe Escherichia coli morphologi...

Wearable devices at Work

The effects of the workplace on the safety, health, and productivity of personnel can be seen at various levels. To protect and boost general worker health, innovative hardware and software tools have been developed for the detection, elimination, substitution, and regulation of occupational hazards. Wearable technologies make it possible for constant tracking of workers and their environment, whereas connected worker solutions provide contextual information and support for decision-making. H...

Video Capsule Endoscopy : A Review of Technologies

In this review, we focus on the hardware and software technologies used for the purpose of gastrointestinal tract monitoring in a safe and comfortable manner. We review the FDA guidelines for ingestible wireless telemetric medical devices, and the features incorporated in capsule systems such as microrobotics, closed-loop feedback, physiological sensing, nerve stimulation, sampling and delivery, panoramic imaging and rapid reading software. Both experimental and commercialized capsule systems...

Animal Behavior Sensing Electronics

We propose a remote monitoring device for measuring behavioral indicators like posture, gait, vocalization, and external temperature which can help in evaluating the health and welfare of pigs. The multiparameter electronic sensor board was tested in a laboratory and on animals. Machine learning algorithms and decision support tools can be used to detect lameness, lethargy, pain, injury, and distress. The roadmap for technology adoption, potential benefits, and further challenges are discusse...

Electrical field effects on micro-organisms

We present the NERV, a nonmechanical, unidirectional valve, to control the locomotion of Caenorhabditis elegant (C. elegans) in microfluidic devices. This valve is created by establishing a region of lateral electric field which can be toggled between on and off states. We observed that C. elegans do not prefer to advance into this region when the field lines are facing their movement, so when they reach the boundary of the NERV, they partway enter the field, retreat, and switch direction. We...

Anthelmintic resistance in nematodes

It is becoming more essential to identify and recognize the phenotypes of anti-parasitic drug-resistant isolates. Current molecular methods of doing so are restricted. In this paper, we showcase a microfluidic bioassay to measure phenotype using parameters of nematode locomotion, using larvae of the animal parasite Oesophagostomum dentatum. Parameters of sinusoidal movement, including propagation speed, wavelength, wave amplitude, and oscillation frequency, were dependent on the levamisole-se...

Robotic Manipulator using an Inductive Sensor

This project involves the use of an inductive sensor to control a robotic arm system. The signals generated in the induction coil will help in controlling the manipulator to perform certain gripping and grabbing actions. Also, the report describes the method used to acquire and process these induced signals before they are sent (induced signals) to the manipulator through the help of two programmed microcontrollers.

A Hybrid Technique for Speckle Noise Reduction in ultrasound images

Abstract In the field of biomedical imaging, Ultrasound is an incontestable vital tool for diagnosis, it provides in non-invasive manner the internal structure of the body to detect eventually diseases or abnormalities tissues. These images are obtained with a simple linear or sector scan US probe, which show a granular appearance called speckle. . Unfortunately, the presence of speckle noise affects edges and fine details which limit the contrast resolution and make diagnostic more difficult...

Comparative Studies of Needle Free Injection Systems and Hypodermic Needle Injection: A Global Perspective

Needle-free injection (NFI) is a novel transdermal either intramuscularly or subcutaneously drug delivery system, where innovative ways to introduce a variety of medicines like as antibiotics, iron, or vaccines comfortably, accurately, easily and rapidly without, piercing the skin compared to traditional needle. While hypodermic needle is inject substances into body by intradermal, intramuscular, subcutaneous, intravenous, etc or extract fluids from the body body, for example taking blood fro...

Design and Implementation of a Mechanical Ventilator

Africa’s healthcare system is challenged by inadequate medical equipment, stemming from the fact that it does not manufacture its own medical devices but depends mostly on used medical equipment donations, many of which do not function and require extensive repairs. The World Health Organization estimates that 50 to 80 percent of medical equipment in developing countries are not working, therefore creating a barrier in the health system delivery of health services.  Mechanical ventilators ...

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Consortium identifies 5 grand challenges in biomedical engineering

A consortium of 50 renowned researchers from universities around the world, including Cornell Engineering, has published a paper establishing five grand challenges in biomedical engineering, which it said will lay the foundation for a concerted worldwide effort to achieve technological and medical breakthroughs.

The paper titled, “ Grand Challenges at the Interface of Engineering and Medicine ” published Feb. 21 in the IEEE Open Journal of Engineering in Medicine and Biology, and was the result of a two-day workshop organized by the IEEE Engineering in Medicine and Biology Society, the Department of Biomedical Engineering at Johns Hopkins University and the Department of Bioengineering at the University of California San Diego. Among the co-authors is Marjolein van der Meulen, the James M. and Marsha McCormick Director of the Meinig School of Biomedical Engineering at Cornell.

“The interface of engineering and medicine is important and growing, extending beyond biomedical engineering,” said van der Meulen, who is also a senior scientist in the Research Division of the Hospital for Special Surgery. “This workshop brought together leaders in the field to focus on critical areas for future progress, leading to the identification of five grand challenges. These challenges are an opportunity for engineering approaches and interdisciplinary teams to transform human health and disease.”

"What we’ve accomplished here will serve as a roadmap for groundbreaking research to transform the landscape of medicine in the coming decade,” said Dr. Michael Miller, senior author of the paper and professor and director of the Department of Biomedical Engineering at Johns Hopkins University. “The outcomes of the task force, featuring significant research and training opportunities, are poised to resonate in engineering and medicine for decades to come.”

Through the course of the workshop, the researchers identified five primary medical challenges that have yet to be addressed, but, by solving them with advanced biomedical engineering approaches, can greatly improve human health. By focusing on these five areas, the consortium has laid out a roadmap for future research and funding.

The five grand challenges facing biomedical engineering:

1. Bridging precision engineering and precision medicine for personalized physiology avatars In an increasingly digital age, we have technologies that gather immense amounts of data on patients, which clinicians can add to or pull from. Making use of this data to develop accurate models of physiology, called “avatars” – which take into account multimodal measurements and comorbidities, concomitant medications, potential risks and costs – can bridge individual patient data to hyper-personalized care, diagnosis, risk prediction, and treatment. Advanced technologies, such as wearable sensors and digital twins, can provide the basis of a solution to this challenge.

2. The pursuit of on-demand tissue and organ engineering for human health Tissue engineering is entering a pivotal period in which developing tissues and organs on demand, either as permanent or temporary implants, is becoming a reality. To shepherd the growth of this modality, key advancements in stem cell engineering and manufacturing – along with ancillary technologies such as gene editing – are required. Other forms of stem cell tools, such as organ-on-a-chip technology, can soon be built using a patient’s own cells and can make personalized predictions and serve as “avatars.”

3. Revolutionizing neuroscience using artificial intelligence (AI) to engineer advanced brain-interface systems Using AI, we have the opportunity to analyze the various states of the brain through everyday situations and real-world functioning to noninvasively pinpoint pathological brain function. Creating technology that does this is a monumental task, but one that is increasingly possible. Brain prosthetics, which supplement, replace or augment functions, can relieve the disease burden caused neurological conditions. Additionally, AI modeling of brain anatomy, physiology, and behavior, along with the synthesis of neural organoids, can unravel the complexities of the brain and bring us closer to understanding and treating these diseases.

4. Engineering the immune system for health and wellness With a heightened understanding of the fundamental science governing the immune system, we can strategically make use of the immune system to redesign human cells as therapeutic and medically invaluable technologies. The application of immunotherapy in cancer treatment provides evidence of the integration of engineering principles with innovations in vaccines, genome, epigenome and protein engineering, along with advancements in nanomedicine technology, functional genomics and synthetic transcriptional control.

5. Designing and engineering genomes for organism repurposing and genomic perturbations Despite the rapid advances in genomics in the past few decades, there are obstacles remaining in our ability to engineer genomic DNA. Understanding the design principles of the human genome and its activity can help us create solutions to many different diseases that involve engineering new functionality into human cells, effectively leveraging the epigenome and transcriptome, and building new cell-based therapeutics. Beyond that, there are still major hurdles in gene delivery methods for in vivo gene engineering, in which we see biomedical engineering being a component to the solution to this problem.

“These grand challenges offer unique opportunities that can transform the practice of engineering and medicine,” remarked Dr. Shankar Subramaniam, lead author of the taskforce, distinguished professor, Shu Chien-Gene Lay Department of Bioengineering at the University of California San Diego and past President of IEEE EMBS. “Innovations in the form of multi-scale sensors and devices, creation of humanoid avatars and the development of exceptionally realistic predictive models driven by AI can radically change our lifestyles and response to pathologies. Institutions can revolutionize education in biomedical and engineering, training the greatest minds to engage in the most important problem of all times – human health.”

This article was adapted with permission from an original version published by the IEEE Engineering in Medicine and Biology Society.

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Exploring Biomedical Engineering Careers: From Research to Medical Devices

Team of Bioengineers Working On Computer, Analyzing Genetic Material Samples with Special Machines in the Modern Laboratory.

The future of engineering careers is promising, from traditional spheres of engineering such as mechanical and electrical to emerging ones such as systems and software. Among the various fields, however, biomedical engineering stands out as uniquely interdisciplinary.

As one of the fastest-growing engineering sectors, there's a reason why biomedical engineering has become the third best engineering job in the country. 1 The profession is poised for even more growth, with employment rates projected to increase by five percent from 2022 to 2032. 2

Preparing for a career in biomedical engineering is nuanced, requiring a proper understanding of the different branches and career opportunities within the field. This article will explore the different career paths you can take as a biomedical engineer, from research and development to designing innovative medical devices.

Introduction to Biomedical Engineering Careers

Biomedical engineering is one of the most diverse and interdisciplinary professions, incorporating the fields of engineering science, medicine, biology, physics, chemistry and mathematics under its umbrella. 3 That doesn't mean every biomedical engineer studies all of these disciplines. Most specialize in one area and collaborate with experts in others. At the intersection of science, medicine and mathematics, the field incorporates teams of physicians, scientists, engineers, patent attorneys, physical therapists, business professionals, teachers and technical writers, all working together to achieve common goals. 4

Biomedical engineers are problem-solvers at the core, using medical knowledge, engineering principles and technology to improve the ways in which we approach healthcare.

The Role of Biomedical Engineers in Healthcare

The overarching role of biomedical engineers is to bridge the gap between technology and patient care by researching, designing and developing medical devices, diagnostic equipment and therapeutic strategies. Within that context, the individual roles and responsibilities of biomedical engineers may include any of the following: 5

  • Designing medical devices, machines and computer simulation software
  • Training others in the proper use of medical devices and equipment
  • Installing, testing and maintaining medical equipment
  • Studying human biology to inform engineering design
  • Researching and writing reports and technical manuals
  • Teaching and presenting research findings to students and colleagues
  • Creating business models for incorporating new medical devices

We can divide biomedical engineering careers into two broad categories: performing research and designing medical devices.

Biomedical Research and Development

Those involved in the R&D side of biomedical engineering contribute to cutting-edge medical research by designing experiments, collecting data and analyzing the results. Biomedical researchers, prosthetists and manufacturing engineers are typical jobs for those interested in the problem-solving work that goes into the design and development of medical devices.

Biomedical engineering research and development is currently focused in two main areas:

Tissue Engineering and Regenerative Medicine

This area of biomedical science helps refine the development of artificial organs, tissues and biomaterials. People who conduct research in this field operate in diverse environments, ranging from university laboratories and biotech companies to specialized research institutes.

Going beyond traditional methodologies, tissue engineering merges innovative fabrication with biological sciences to address critical gaps in organ transplantation and tissue repair. Recent advancements, such as the development of so-called 'organ-on-a-chip' technologies, have seen remarkable progress, holding promise for personalized medicine. 6

Biomechanics and Bioinstrumentation

Integral to biomedical engineering, biomechanics and bioinstrumentation focus on analyzing human movement and physiological processes, such as breathing, to inform the design and innovation of healthcare technology.

Examples include researching prosthetics that mimic natural limb movements and wearable technology for real-time monitoring of vital signs. Currently, a focus of biomechanics is enhancing sports performance and injury prevention, while examples of ongoing bioinstrumentation projects include refining imaging technology and developing miniaturized health-monitoring devices. 7

Medical Device Design and Innovation

The research arm of biomedical engineering lays the groundwork for those motivated to design and develop medical devices or improve the equipment already in use. People in these roles also ensure equipment safety, efficacy and regulatory compliance. 8

Most biomedical engineers work in one of two branches of device innovation and design :

Imaging and Diagnostic Equipment

Innovative imaging and diagnostic equipment help with accurate disease detection, allowing physicians to intervene early and effectively. This may include:

  • Conventional X-ray
  • Computed tomography scanner (CT)
  • Magnetic resonance imaging (MRI)

The design and development of these devices offer diverse professional opportunities. Possible career paths for biomedical engineers in this field can include jobs in hospitals, clinics and diagnostic laboratories. GE Healthcare, Carestream Health, Inc. and Hologic, Inc. are all companies that specialize in this type of equipment. 9

Rehabilitation and Assistive Technology

This branch of devices is designed to enhance the quality of life for people with disabilities. It’s specifically focused on customized mobility, communication and independence solutions. Implantable devices and other equipment in this category may include:

  • Dental implants
  • Cochlear implants
  • Drug infusion pumps
  • Artificial limbs, knees, hips and heart valves

Biomedical engineers working in this realm have career prospects with prosthetics manufacturers, biomedical companies and healthcare facilities. The U.S. Veterans Health Administration, the country’s largest health network, is also an excellent place to look for biomedical engineering careers in rehabilitation and assistive technology. 10

Education and Skill Requirements

Biomedical engineers are creative, diligent and detail-oriented. Due to the many overlapping fields involved and the constant need for collaboration, biomedical engineering also requires excellent communication skills.

It’s a highly specialized field that spans multiple disciplines, so anyone preparing for a career in the world of biomedical engineering can begin as early as high school. Advanced math, physics, anatomy and microbiology are foundational courses for this career path. 11

Beyond high school, a bachelor's degree in biomedical or general engineering and an internship or work experience are typical for those looking to gain a better understanding of, and to enter, the field. At the undergraduate level, students begin to focus on skills in specialty areas of engineering, biology or medical sciences, further refining their educational focus.

A master of science (MS) in biomedical engineering is the next step for those looking to improve their job prospects, further refine their skills and develop new ones. The many benefits of a graduate engineering degree range from advanced research, technical, communication and problem-solving skills to an expanded network and collaboration with other engineers. As a result, skilled professionals with this level of education are indispensable to the future of biomedical science.

Entrepreneurship and Startups in Biomedical Engineering

The biomedical engineering workforce also has a robust entrepreneurial sector. Whether launching new ventures or joining a startup, new biomedical engineers are actively helping address pressing healthcare challenges . These startups aren’t just businesses. They’re hubs of innovation from which solutions and cutting-edge technologies emerge. 11

Advance Your Biomedical Engineering Career

Case Western Reserve University's online MS in Biomedical Engineering program is specifically designed to teach interdisciplinary skills that are immediately relevant and applicable, helping you stand out in the job market and expand your earning potential.

Our fully online program allows you to tailor your education to fit your schedule while learning from experienced faculty who are engaged in cutting-edge biomedical research. By supporting students in job placement, sponsored research and industrial training, we help our graduates decide how best to use their biomedical engineering education.

To explore how CWRU can advance your technical skills, strengthen your critical thinking and redefine your career journey , schedule a call with one of our admissions outreach advisors today.

  • Retrieved on January 14, 2024, from money.usnews.com/careers/best-jobs/rankings/best-engineering-jobs
  • Retrieved on January 14, 2024, from bls.gov/ooh/architecture-and-engineering/biomedical-engineers.htm
  • Retrieved on January 14, 2024, from linkedin.com/pulse/exploring-world-biomedical-engineering-path-innovation-edlighten-ai/
  • Retrieved on January 14, 2024, from embs.org/wp-content/uploads/2016/01/EMB-CareerGuide.pdf
  • Retrieved on January 14, 2024, from indeed.com/career-advice/finding-a-job/what-is-biomedical-engineering
  • Retrieved on January 14, 2024, from nature.com/articles/s43586-022-00118-6
  • Retrieved on January 14, 2024, from nature.com/articles/s41528-022-00146-y
  • Retrieved on January 14, 2024, from linkedin.com/pulse/diagnostic-imaging-equipment-market-size-mrdmf/
  • Retrieved on January 14, 2024, from vacareers.va.gov/careers/technology-jobs/
  • Retrieved on January 14, 2024, from indeed.com/career-advice/finding-a-job/job-for-biomedical-engineer
  • Retrieved on January 14, 2024, from admitad.pro/en/blog/44-startups-in-biomedical-engineering

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UC Davis Graduate Studies

2023 Grad Slam competition

Top 10 Finalists of 2024 UC Davis Grad Slam Announced

Graduate students will compete at the april 12 semi-final round.

  • by Grad News
  • March 26, 2024

 Graduate Studies is proud to announce the 2024 Top 10 finalists of UC Davis Grad Slam.

This year’s top 10 finalists will be competing at the semi-final round of UC Grad Slam on April 12. The event will be held at the Graduate Center in Walker Hall at UC Davis. The graduate students will be vying for the chance to win $5,000, among other awards, as well as the opportunity to compete in the final round of UC Grad Slam where they could win the UC-wide title and additional prize money.

UC Grad Slam is an annual competition where master’s and doctoral students are invited to share their research in a compelling presentation that is three minutes or less. UC Davis has been participating in UC Grad Slam since 2016.

A panel of internal and external volunteer judges selected this year’s Top 10 UC Davis graduate students from a highly competitive pool of videos submissions. Those who made it to the semi-final round were reviewed and scored based on their presentation skills and compliance with the competition criteria. 

“This year’s finalists are a great example of the breadth of high-level, impactful research and scholarship that our graduate students engage in at UC Davis,” said Jean-Pierre Delplanque, vice provost and dean of Graduate Studies. “I'm so excited to watch their pitches at our April 12 Grad Slam event. I know it's going to be a very tough competition."

The champion of the UC Davis Grad Slam competition will go on to compete with winners from other campuses at the University of California Grad Slam annual competition, which will be held in person at the LinkedIn headquarters in San Francisco on May 3, 2024.

Congratulations to the 2024 Top 10 Finalists!

(listed in alphabetical order by last name)

Rajul Bains smiles at the camera.

Rajul Bains Master's student, Biomedical Engineering Graduate Group "Microfluidic Tumor-on-a-Chip Model for Cancer Research" My research uses microfluidic technology to create mini "organ-on-chips," which simulate human body conditions to study how our immune system fights cancer. I'm enthusiastic about my work and love sharing it with friends and family who might not be familiar with my research! Participating in Grad Slam is a fantastic chance for me to bring this exciting work to a broader audience!

Meredith Carlson sitting for the camera.

Meredith Carlson Ph.D. candidate, Anthropology "Using Videos and Stone Tools to Understand Tool Use in Capuchin Monkeys" My research is in primate archaeology – a new area that combines the methods of archaeology with questions about our living primate relatives. I'm so excited to share my enthusiasm for the clever tool-using capuchin monkeys that I study.

Sam Dudley smiles for the camera.

Sam Dudley Ph.D. student, Horticulture and Agronomy Graduate Group "Using Biology to Create More Drought Resistant Grapevines" I research the drought tolerance of grapevine roots. I chose to enter grad slam because I know how hard it can be to learn about scientific research in other fields, and I want to present my research in a way that it’s accessible to everyone!

Anjelica Guerrier smiling for the camera.

Anjelica Guerrier Ph.D. student, Earth and Planetary Sciences "Volcanoes? Who Cares?" I'm a passionate researcher delving into the depths of Yellowstone's volcanic mysteries! 🌋 With a keen interest in deciphering the secrets of Earth's most enigmatic forces, I focus on unraveling the history preserved within ancient crystals from past eruptions. Through meticulous isotopic analysis, I seek to understand the interconnectedness and activity of the magma chamber beneath the Yellowstone supervolcano. This research journey isn't just about uncovering geological insights; it's about paving the way for better hazard prevention and mitigation strategies. Join me on this captivating journey into the heart of Yellowstone's fiery narrative and the quest for predictability in the face of nature's awe-inspiring power.

Erin Hisey smiling for the camera.

Erin Hisey Ph.D. student, Integrative Pathobiology Graduate Group "Stare Like a Rabbit" In my project, I am studying a new fat based treatment for evaporative dry eye disease, a condition that affects both humans and animals around the world. I am studying how this treatment works by looking at how it interacts with the fat molecules of tears in the laboratory and in animals with dry eye disease to see if it would be an effective treatment . I am passionate about sharing my clinical research and information about clinical diseases with animal owners, so I am excited to participate in Grad Slam to practice those skills and to share my research with the UC Davis community.

Caleb Huntington doing research in the field.

Caleb Huntington Ph.D. student, Integrative Pathobiology Graduate Group "Cloudy with a Chance of Global Pandemics" The world is not through with pandemics. In fact, they are only expected to become more common. My work aims to improve our methods for studying viruses in bats before they have the chance to spillover into humans. Come learn about bats, caves, and the jungles of Puerto Rico

Tim Linke smiling at the camera.

Tim Linke Ph.D. candidate, Mechanical and Aerospace Engineering "From Big to Small: We Need It All" If you want to find out what we’re doing today to usher in the new era of clean energy, you should come check out my talk at the 2024 UC Davis Grad Slam competition. I initially got interested in this research because making fusion energy happen is one of the most pressing and challenging problems we have today. So if you want to learn more, I’ll see you on April 12!

Sasha Neil Pimento smiling at the camera.

Sasha Neil Pimento M.S. student, Computer Science Graduate Group "Opening Doors for Alzheimer's Disease Care" My research tackles an important healthcare challenge – enabling those with Alzheimer's disease to live independently for longer periods. Under the guidance of my advisor, Dr. Alyssa Weakley, I am developing innovative applications that leverage modern technology to aid memory for intentions, facilitate long-distance caregiving and analyze disease progression. I am thrilled to share our work at Grad Slam and raise awareness about these interactive platforms, which have the potential to improve the quality of life for the millions affected by this debilitating condition.

Prabhash Ragbir smiling at the camera.

Prabhash Ragbir Ph.D., Mechanical and Aerospace Engineering "Firefight with Flight: How Drones Can Help Us Detect Wild Fires" My research focuses on using drones to detect wildfires as early as possible. I was inspired to pursue this area of research because I think it can have a significant impact on minimizing the destruction caused by wildfires. I’m really excited to participate in Grad Slam because I think it provides a great opportunity for students to share their research with each another in a very fun and engaging manner. I look forward to learning about the research of other students and sharing my work with you all!

Roshni Shetty smiling for the camera.

Roshni Shetty

Ph.D. student, Biomedical Engineering Graduate Group "Male and Female Hearts Are Different! Can We Predict Drug Responses Across Sexes?" I am passionate about understanding the intricacies of the human heart's electrical activity and molecular orchestration of rhythm. My research delves into sex-specific differences in cardiac electrophysiology, aiming to uncover the mechanistic basis for divergent arrhythmia susceptibility between sexes. Females are at increased risk of drug-related side effects and sudden cardiac death. However, female sex is underrepresented in basic research and clinical studies, and cardiac safety assessments often overlook these sex differences, leading to uniform medication prescriptions across sexes. To address this gap, we are developing a tool to predict female electrical activity responses to drugs based on male data, with the aim of enhancing cardiac safety assessments for females. But I'm not just crunching numbers in the lab – I am deeply committed to science communication, and I see Grad Slam as an excellent opportunity to shed light on the significance of my research and advocate for sex-inclusive fundamental and clinical studies and healthcare practices.

Additional Awards and Designations 

In addition to competing for the chance to participate in the UC competition in May, finalists at the April 12 event could earn the following awards:

  • First Place
  • Second Place
  • Third Place

People’s Choice Award

  • Public Impact Prize

The People’s Choice Award is granted to the contestant who receives the most votes from members of the public who are either in attendance at the event or are watching via a livestream. The voting link will be shared following the presentations at the event in Walker Hall. 

Public Impact Prize UC Davis Public Scholarship and Engagement will be awarding an additional prize to the student who best demonstrates how their research has or will have significant impact by addressing a public concern or topic.

Join us for the UC Davis semi-final round on Friday, April 12 from 1 - 4 p.m. at the Graduate Center at Walker Hall. Seating is limited, so RSVP soon .

To learn more about the UC Grad Slam happening on May 3, visit https://gradslam.universityofcalifornia.edu .

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An illustration of a double-stranded DNA molecule with mutation in a gene.

Photo: Shutterstock

Tufts Researcher Takes on Epilepsy After Daughter’s Diagnosis

A biomedical engineer and a neuroscientist have teamed up to advance epilepsy research and push for more effective treatments for patients

In 2021, Madeleine Oudin , associate professor of biomedical engineering at the School of Engineering , noticed that her three-month-old daughter’s eyes were moving strangely. She took a video and sent it to her pediatrician, who told her to take Margot to the emergency department at Boston Children’s Hospital. 

The eye movements, it turned out, were the result of seizures and Margot was diagnosed with epilepsy.

Less than three years later, Oudin has added a focus on epilepsy to her research lab, where she was already studying cancer.

“I felt like if I couldn’t really do anything to stop my daughter from seizing or help her develop, I could try to do something in the lab to contribute to the field,” she said. 

Finding Genetic Mutations

Seizures in infants can be caused by many factors, including temporary conditions like fever. In Margot’s case, genetic testing showed that her seizures were caused by mutations in a part of a gene called SCN8A that contains instructions for building ion channels, which are portals in cell membranes. Ion channels have many functions in the body; in the brain, they help transmit electrical signals. 

Margot’s case of SCN8A epilepsy is severe: she’s unable to see, hold her head up, or eat using her mouth. In her three years of life, she’s had more than 20,000 seizures, has been in the hospital 17 times, and has tried 11 anti-seizure medications. 

Despite Margot’s challenges, Oudin said, “She’s a happy girl. She loves to swim and go outside and listen to music. We’ve learned to take advantage of life in a different way with her.”

A Scientific Pivot

Madeleine Oudin, associate professor of biomedical engineering at the School of Engineering

Madeleine Oudin, associate professor of biomedical engineering at the School of Engineering. Photo: Alonso Nichols

Even though Oudin was making waves with her research on cancer metastasis (and continues to do so), she was well positioned to take on epilepsy. She had a Ph.D. in neuroscience and was surrounded by colleagues with relevant expertise, including Chris Dulla , professor and interim chair of the neuroscience department at Tufts University School of Medicine , and her husband, Christopher Burge , professor of biology at the Massachusetts Institute of Technology.

On top of all that, Oudin’s cancer research related to ion channels , the same cellular structures that are affected by Margot’s mutations.

“It’s weird,” she said, “I do feel like all my training up to now has prepared me for this: to be Margot’s mom and take this on, to help her and her community. I do feel like this happened for a reason.” 

Gathering Expertise and Resources

Soon after Margot’s diagnosis, Oudin reached out to Dulla, who has a long history of epilepsy research . “I could never have done this without Chris,” Oudin said.

Dulla brought Oudin up to speed on epilepsy research and connected her with other experts. And Oudin taught Dulla everything she knew about ion channels, which hadn’t been part of his research before. “Madeleine is a dynamo,” Dulla said. “She has so much energy to push the understanding of this ion channel that we’re working on.”

They have already raised $50,000 on Oudin’s lab website , won a small seed grant from the American Epilepsy Society and were recently awarded a $700,000 grant from the Mathers Foundation. 

Both of them marvel at the speed with which this productive partnership is lifting off. “The set of coincidences of a group of people who each have the right expertise to move this forward very quickly is amazing,” Dulla said.

Investigating a New Therapeutic Option

During childhood, SCN8A makes a different version of the ion channel protein than in adulthood. Margot’s mutations affect the childhood version.

Would it be possible to stop Margot’s seizures by persuading SCN8A to switch over to making the adult version? And if the seizures stopped, would she be able to achieve some of the developmental milestones she’s missed? These are the questions Oudin and her colleagues are aiming to answer.

The childhood and adult versions are created using the same genetic material in different combinations, as you might use the same building blocks to assemble two different structures. This is called alternative splicing and it’s a basic function that occurs naturally in many genes.

Chris Burge, Oudin’s husband, has studied alternative splicing for 20 years; he was the one who figured out that Margot’s mutations were in the region of SCN8A that switches from a childhood version to an adult one.

That realization pointed to a new treatment shown to change alternative splicing. Molecules called antisense oligonucleotides, or ASOs, can be engineered to bind to certain parts of genetic material to influence alternative splicing.

“We think the therapeutic option for this is to use an ASO to switch the splicing to include the correct adult version and prevent the mutated childhood version from being a part of the protein,” Oudin said.

Rare Solution, Big Impact

Oudin and Burge applied to n-Lorem , a nonprofit foundation that develops ASOs for patients with rare mutations, and Margot was accepted. “We hope within a couple of years Margot will be injected with a treatment,” Oudin said.

Margot is the only known person with her exact mutations. However, many children with epilepsy have mutations in other parts of SCN8A or mutations in other genes related to other ion channels. So, if the ASO treatment works for Margot, the technique could help other children as well.

Chris Dulla, professor and interim chair of the neuroscience department at Tufts University School of Medicine

Chris Dulla, professor and interim chair of the neuroscience department at Tufts University School of Medicine. Photo: Alonso Nichols

“Most drug discovery for epilepsy is made possible thanks to rare disease,” Dulla said. “If we find something that works for SCN8A, it could be applied to lots of other sodium channel mutations that would benefit from the splice-switching approach.”

Meanwhile, Oudin and Dulla are hard at work to advance the science related to SCN8A, ion channels, and epilepsy.

Haley Dame , a graduate student in the Genetics, Molecular, and Cellular Biology program at the Graduate School for Biomedical Sciences , is working on the epilepsy project for her doctoral thesis, advised by Oudin, Dulla, and Burge. The goals of the project are to illuminate more about how, why, and when SCN8A’s alternative splicing occurs in healthy development and to investigate the impact of switching from the childhood version to the adult version earlier in life than usual in both healthy mice and those with Margot’s mutations.

“No one is really studying this region of SCN8A and the alternative splicing,” Oudin said, “so we felt like we could bring in a lot of new and exciting science.”

Motivation from Margot 

There are thousands of scientific steps between here and the answer to the ultimate question, which is, in Oudin’s words, “Can we correct and treat this disorder?” 

But none of the team members are daunted. They are fueled by a happy little girl who loves life, Margot.

“Margot is amazing,” Dulla said. “It’s such a wonderful experience for me to get to take my scientific training and use it in such an immediately useful way.”

Dame agreed: “I don’t think a lot of researchers get to see what they are working for,” she said. “It’s really rewarding.”

As for Oudin, her daughter has motivated her not only to become an epilepsy researcher, but also to become a patient advocate and an active member of the SCN8A community.

“Having the perspective of being both a scientist and a caregiver and patient advocate is really unique,” she said. “You just don’t know until you live through it. I can understand the needs of patients and the community as well as the research and biology behind it.” 

Oudin now serves on the board of the International SCN8A Alliance , where she shares both her scientific expertise and her personal experience.

“It’s been a crazy couple of years, but I’m excited that I can contribute in a meaningful way,” Oudin said, “and I could not have done it without the community at Tufts.” 

Philip Haydon in a video explaining epilepsy

What is Epilepsy?

A blue-tinted illustration of a DNA double helix with a portion illuminated in red

Tufts Scientist Teams Up with Families to Find a Treatment for Rare Disease

Illustration by Siena Fried of a starfish-like creature against a dark blue background

Tufts Researchers Discover New Function Performed by Nearly Half of Brain Cells

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  1. Research thesis topics and objectives formulation 8613

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  1. 45 Biomedical Research Topics for You

    We have compiled a list of biomedical engineering topics for you. Here they are: In-the-ear device to control stuttering: the basis of its operation. How to implement the magnetic navigated catheterization. Semiconductor-cell interfaces: the rudiments of its application. The benefits of tissue engineering of muscle.

  2. Projects and Master Thesis in Biomedical Engineering

    What are typical master thesis topics? Students report intermediate results during our yearly Biomedical Industry Day. An overview of this years displayed posters is found here. Some examples of finalized master theses in biomedical engineering. Biomechanics and Biomaterials

  3. Theses and Dissertations--Biomedical Engineering, University of

    Master's theses and doctoral dissertations from the University of Kentucky Department of Biomedical Engineering are available here.

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  5. Master's Thesis

    Differences between MS Thesis and MS Project. There are few key differences between the Thesis and Project option. If you choose to do a Thesis, you will have to complete 6 units for that (BME 291, BME 298 and BME 299), compared to the 3 units required for the Project (BME 291, BME 298). Since the three courses (BME 291, BME 298 and BME 299 ...

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    Organic-Inorganic Hybrid Biomaterials for Bone Tissue Engineering and Drug Delivery, Neda Aslankoohi. PDF. Fabrication Of Inkjet-Printed Enzyme-Based Biosensors Towards Point-Of-Care Applications, Yang Bai. PDF. The Use of CT to Assess Shoulder Kinematics and Measure Glenohumeral Arthrokinematics, Baraa Daher. PDF

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  8. Biomedical Engineering

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  9. Department of Biomedical Engineering Dissertations, Master's Theses and

    Dissertations, master's theses and master's reports from the Department of Biomedical Engineering of the College of Engineering at Michigan Technological University

  10. Master's Thesis

    Thesis topics on ILIAS. Enrolled students in the Biomedical Engineering program will find all current and former thesis projects, as well as all important information on the application process, on the university's E-learning platform ILIAS. Follow the link to the folder "Master's Thesis" and log in with your campus account. Then join the ...

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    The Master's-Plan A (thesis) in Biomedical Engineering requires completing at least 20 credits of coursework, plus 10 thesis credits and a final defense. Apply Timeline Students are expected to complete the Master's degree within two years. View a sample plan. Course credits MS-Plan A students are required to complete at least 20 credits of coursework as indicated below. All electives must be ...

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    Consult the individual websites under Research for available Master thesis topics. Alternatively, ... Master projects can be supervised by ETH professors from the field of Biomedical Engineering (Download see list (PDF, 166 KB) vertical_align_bottom). Find a professor, and discuss with him/her your project using the following form.

  14. Biomedical Engineering Theses & Dissertations

    Theses and dissertations published by graduate students in the Department of Biomedical Engineering, College of Engineering, Old Dominion University since Fall 2016 are available in this collection. Backfiles of all dissertations (and some theses) have also been added. In late Fall 2023 or Spring 2024, all theses will be digitized and available ...

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    The Master's thesis is guided and supervised by a pro-gramme-affiliated faculty member. ... 8 Master of Science - Biomedical Engineering Individual Learning Agreement Master of Science ... ly available Master's and semester project topics can be found under the individual websites as well as at:

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  19. Graduate Study in Biomedical Engineering at Yale:

    thesis advisers, a thesis committee consisting of at least two (preferably three) other professors, and the Director of Graduate Studies. Working with the student, the PhD adviser proposes the topic of study, usually arranges for funding of the project (including student salary, benefits, and tuition), and commits to

  20. Master's Thesis Biomedical Engineering

    The Master's Thesis is an important part of the BME programme. You will face solving a concrete technical-scientific problem. To find a solution you will have to perform independent research, literature search and analysis, simulations, experiments, etc. Technical-scientific research is not only essential for the progress of society, it also ...

  21. Biomedical Engineering graduate programs

    The Biomedical Engineering Department's graduate program features an interdisciplinary research and training approach. Its world-class faculty deliver cutting-edge education and are often cross-appointed in multiple departments, enabling students to collaborate with experts and fellow students in various fields, including engineering, physics, biology, psychology, robotics, computer science ...

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    Decellularization Strategies of Naturally Derived Biomaterials for Tissue Engineering Applications, Julia Elizabeth Hohn. PDF. Role of AhR in the Epigenetic Regulation of Immune Cells in Lungs During Acute Respiratory Distress Syndrome, Bryan Latrell Holloman. PDF. The Submission of a Section 513(g) Request For Information, Morgan Ashley Lano. PDF

  23. MS Plan I

    MS Plan I Degree Requirements The requirements for a Master of Science Plan I degree in Biomedical Engineering are completion of 30 units of approved coursework, including four core courses (below), and an MS thesis approved by a three-member faculty committee. 28 units of these courses must be taken for a letter grade; the minimum acceptable grade is B- and the minimum overall GPA is 3.00.

  24. Biomedical Engineering Project Topics and Papers

    2. 3. ». 1 - 15 Of 44 Results. Browse through academic research topics in Biomedical Engineering. Access and download complete Biomedical Engineering papers, Biomedical Engineering project topics, seminar topics, thesis, assignments, dissertations etc. Project topics in Biomedical Engineering - Page 1.

  25. Consortium identifies 5 grand challenges in biomedical engineering

    The paper titled, "Grand Challenges at the Interface of Engineering and Medicine" published Feb. 21 in the IEEE Open Journal of Engineering in Medicine and Biology, and was the result of a two-day workshop organized by the IEEE Engineering in Medicine and Biology Society, the Department of Biomedical Engineering at Johns Hopkins University ...

  26. Biomedical Engineering Careers: Research to Medical Devices

    The future of engineering careers is promising, from traditional spheres of engineering such as mechanical and electrical to emerging ones such as systems and software. Among the various fields, however, biomedical engineering stands out as uniquely interdisciplinary. As one of the fastest-growing engineering sectors, there's a reason why biomedical engineering has become the third best ...

  27. Top 10 Finalists of 2024 UC Davis Grad Slam Announced

    Graduate Studies is proud to announce the 2024 Top 10 finalists of UC Davis Grad Slam. This year's top 10 finalists will be competing at the semi-final round of UC Grad Slam on April 12. The event will be held at the Graduate Center in Walker Hall at UC Davis. The graduate students will be vying for the chance to win $5,000, among other awards, as well as the opportunity to compete in the ...

  28. Tufts Researcher Takes on Epilepsy After Daughter's Diagnosis

    Haley Dame, a graduate student in the Genetics, Molecular, and Cellular Biology program at the Graduate School for Biomedical Sciences, is working on the epilepsy project for her doctoral thesis, advised by Oudin, Dulla, and Burge. The goals of the project are to illuminate more about how, why, and when SCN8A's alternative splicing occurs in ...