The MS in Bioengineering prepares students for research and professional practice in bioengineering and related fields. The program includes both fundamentals and advanced work to apply engineering techniques to solve problems in biology and medicine. A major distinguishing feature of the curriculum is that it is designed to educate leaders who understand and appreciate how biomedical technology is translated from bench to bedside. Graduates from this program will eventually work in universities, industry or government in a variety of roles due to the breadth of this program and its content specific clinical translation of new technologies.

Admissions

Applicants must have completed a baccalaureate degree in engineering or the sciences from an accredited program and an earned GPA of 3.0 or better in their 60 highest-level credits.

In addition to fulfilling Mason's admission requirements for graduate study, applicants seeking to be admitted must demonstrate or provide the following:

  • Demonstrate strong knowledge in ordinary differential equations cell biology and general chemistry as demonstrated by the BS degree, course selection, or project work.
  • Additional knowledge in molecular biology, physiology, organic chemistry, linear algebra, and/or statistics is recommended.
  • Provide two letters of recommendation, from references who are familiar with the applicant's professional accomplishments.
  • Provide a resume and detailed statement of career goals and professional aspirations.
  • If their native language is not English, students must take the English Proficiency exam. Test score minimum requirements are available at https://www2.gmu.edu/admissions-aid/how-apply/graduate/standardized-test-information

Banner Code: EC-MS-BIOE

Degree Requirements

Total credits: 30-33

Students complete the Core Bioengineering requirements, and requirements within one selected option: thesis, practicum or coursework. 

Core Bioengineering

BENG 520Biomedical Data Analytics3
BENG 521Cell and Tissue Engineering3
or BENG 540 Advanced Biomaterials and Biomimetic Devices for Nanomedicine
BENG 526Neural Engineering3
BENG 537Medical Image Processing3
or BENG 538 Medical Imaging
Choose two courses from the following:6
BENG 501
Bioengineering Research Methods
BENG 514
Pathophysiology and the Role of New Technologies in Human Diseases
BENG 575
Intellectual Property, Regulatory Concepts and Product Development
BENG 601
Collaborative Bioengineering Basic Science Research
BENG 602
Collaborative Bioengineering Clinical Science Research
STAT 535
Analysis of Experimental Data
STAT 560
Biostatistical Methods
Total Credits18

Thesis Option

Research Thesis6
BENG 799
Master's Thesis 1
Total Credits6
1

Students are expected to complete 6 credits of BENG 799 Master's Thesis towards their degree. Students cannot enroll in BENG 799 Master's Thesis until the completion of 15 credits of coursework. Once enrolled students must maintain continuous registration in thesis research until graduation, excluding summers. Students who defend in the summer must be registered for at least 1 credit of thesis research during that summer term.

Students choose from a restricted list of technical specialization courses below and/or from the list of core courses that are not already being taken as part of their core requirement to increase technical depth in an area of their interest, under the guidance and with the approval of the student's advisor. Students must choose six credits from these courses. At least half of the selected classes must be at the 600 or 700 level.

Technical Specialization6
Bioengineering
BENG 530
Continuum Biomechanics and Biotransport II
BENG 535
Multi-Scale Modeling and Simulation in Biomedicine
BENG 615
Biomanufacturing
BENG 699
Advanced Topics in Bioengineering
BENG 725
Computational Motor Control
BENG 738
Advanced Medical Image Processing
BENG 798
Independent Reading and Research in Bioengineering
Electrical, Computer & Mechanical Engineering
ECE 511
Computer Architecture
ECE 528
Introduction to Random Processes in Electrical and Computer Engineering
ECE 530
Sensor Engineering
ECE 550
System Engineering Design
ECE 635
Adaptive Signal Processing
ME 621
Foundations of Fluid Mechanics
Bioinformatics
BINF 631
Molecular Cell Biology for Bioinformatics
BINF 641
Biomolecular Modeling
BINF 690
Numerical Methods for Bioinformatics
BINF 701
Systems Biology
BINF 731
Protein Structure Analysis
BINF 740
Introduction to Biophysics
BINF 741
Introduction to Computer Simulations of Biomolecules
BINF 751
Biochemical and Cellular Systems Modeling
BINF 760
Machine Learning for Bioinformatics
Biology and Chemistry
BIOL 562
Personalized Medicine
BIOL 563
Virology
BIOL 566
Cancer Genomics
BIOL 572
Human Genetics
BIOL 583
General Biochemistry
BIOL 682
Advanced Eukaryotic Cell Biology
CHEM 563
General Biochemistry I
CHEM 568
Bioorganic Chemistry
CHEM 613
Modern Polymer Chemistry
CHEM 660
Protein Biochemistry
Physics
PHYS 510
Computational Physics I
PHYS 612
Physics of Modern Imaging
PHYS 640
Finite Element Analysis of Solids and Fluids
PHYS 694
Applied Mechanics of Solids
PHYS 695
Applied Fluid Mechanics
Mathematics and Statistics
MATH 685
Numerical Analysis
STAT 517
Experimental Design
STAT 522
Applied Multivariate Statistics
STAT 526
Applied Regression Analysis
STAT 560
Biostatistical Methods
STAT 662
Multivariate Analysis and Statistical Learning
STAT 672
Statistical Learning and Data Analytics
Neurotechnology and Neuroscience
NEUR 601
Developmental Neuroscience
NEUR 602
Cellular Neuroscience
NEUR 651
Molecular Neuropharmacology
NEUR 734
Computational Neurobiology

Committee Selection

Each student must form a master's committee comprising three individuals. A minimum of two members of the committee must be tenured or tenure-track faculty in the Department of Bioengineering. The other member must be from outside the department.

Thesis Research Proposal

Each student must prepare a written thesis proposal, and it must be presented before the completion of the second semester. The proposal must be made available to the committee at least two weeks in advance of the presentation. The proposal must be presented to and approved by the committee. The committee determines whether the proposal has merit and can lead to significant contributions to the area and whether the student has the knowledge and skills to complete the proposed work successfully and in a timely manner. If the student fails to defend the proposal, the student may present a proposal a second time, no later than 60 days from the first attempt. Failure in the second attempt results in dismissal from the program.

Thesis Preparation and Defense

While preparing the thesis, the candidate enrolls in thesis research. The candidate can proceed to a public defense of the thesis once it has been approved by the committee.

The defense must be announced at least two weeks in advance. The thesis draft must be submitted to the library and made publicly available at least two weeks in advance of the defense. The entire committee must be present at the defense. If the candidate fails to defend the thesis, the candidate may request a second defense, following the same procedures as for the initial defense. A candidate who fails a second attempt to defend the thesis is terminated from the program.

Practicum Option

Internship/Co-Op6
BENG 797
Graduate Practicum 1
Total Credits6
1

Students are expected to complete 6 credits of BENG 797 Graduate Practicum towards their degree. Students cannot enroll in BENG 797 Graduate Practicum until the completion of 15 credits of coursework. BENG 797 Graduate Practicum credits must be taken along with an internship/co-op opportunity. Therefore, a letter from the specific employer must be provided on behalf of the student.

Students choose from a restricted list of technical specialization courses below and/or from the list of core courses that are not already being taken as part of their core requirement to increase technical depth in an area of their interest, under the guidance and with the approval of the student's advisor. Students must choose six credits from these courses. At least half of the selected classes must be at the 600 or 700 level.

Technical Specialization6
Bioengineering
BENG 530
Continuum Biomechanics and Biotransport II
BENG 535
Multi-Scale Modeling and Simulation in Biomedicine
BENG 615
Biomanufacturing
BENG 699
Advanced Topics in Bioengineering
BENG 725
Computational Motor Control
BENG 738
Advanced Medical Image Processing
BENG 798
Independent Reading and Research in Bioengineering
Electrical, Computer & Mechanical Engineering
ECE 511
Computer Architecture
ECE 528
Introduction to Random Processes in Electrical and Computer Engineering
ECE 530
Sensor Engineering
ECE 550
System Engineering Design
ECE 635
Adaptive Signal Processing
ME 621
Foundations of Fluid Mechanics
Bioinformatics
BINF 631
Molecular Cell Biology for Bioinformatics
BINF 641
Biomolecular Modeling
BINF 690
Numerical Methods for Bioinformatics
BINF 701
Systems Biology
BINF 731
Protein Structure Analysis
BINF 740
Introduction to Biophysics
BINF 741
Introduction to Computer Simulations of Biomolecules
BINF 751
Biochemical and Cellular Systems Modeling
BINF 760
Machine Learning for Bioinformatics
Biology and Chemistry
BIOL 562
Personalized Medicine
BIOL 563
Virology
BIOL 566
Cancer Genomics
BIOL 572
Human Genetics
BIOL 583
General Biochemistry
BIOL 682
Advanced Eukaryotic Cell Biology
CHEM 563
General Biochemistry I
CHEM 568
Bioorganic Chemistry
CHEM 613
Modern Polymer Chemistry
CHEM 660
Protein Biochemistry
Physics
PHYS 510
Computational Physics I
PHYS 612
Physics of Modern Imaging
PHYS 640
Finite Element Analysis of Solids and Fluids
PHYS 694
Applied Mechanics of Solids
PHYS 695
Applied Fluid Mechanics
Mathematics and Statistics
MATH 685
Numerical Analysis
STAT 517
Experimental Design
STAT 522
Applied Multivariate Statistics
STAT 526
Applied Regression Analysis
STAT 560
Biostatistical Methods
STAT 662
Multivariate Analysis and Statistical Learning
STAT 672
Statistical Learning and Data Analytics
Neurotechnology and Neuroscience
NEUR 601
Developmental Neuroscience
NEUR 602
Cellular Neuroscience
NEUR 651
Molecular Neuropharmacology
NEUR 734
Computational Neurobiology

Committee Selection

Each student must form a master's committee, comprising two or three individuals. In this case, the committee will help identify the goals of the internship and make sure that they are in line with the MS program's objectives. The committee will also be responsible to evaluate a final report and presentation to assess the successful completion of the internship. A minimum of one member of the committee must be a full-time faculty member in the Department of Bioengineering. The other two members must be representatives from the internship program.

Project Preparation and Presentation

During the internship, the candidate enrolls in BENG 797 Graduate Practicum (Internship/Co-op) and prepares the project report and presentation. The candidate can proceed to the final presentation of the project once it has been approved by the committee.

The presentation must be announced at least two weeks in advance. The report draft must be submitted to the library and made publicly available at least two weeks in advance of the defense. The entire committee must be present at the presentation. If the candidate fails to defend the project, the candidate may request a second attempt, following the same procedures as for the initial one. A candidate who fails a second attempt is terminated from the program.

Coursework Option

Students choose from a restricted list of technical specialization courses below and/or from the list of core courses that are not already being taken as part of their core requirement to increase technical depth in an area of their interest, under the guidance and with the approval of the student's advisor. Students must choose 15 credits from these courses. At least half of the selected classes must be at the 600 or 700 level.

Technical Specialization15
Bioengineering
BENG 530
Continuum Biomechanics and Biotransport II
BENG 535
Multi-Scale Modeling and Simulation in Biomedicine
BENG 615
Biomanufacturing
BENG 699
Advanced Topics in Bioengineering
BENG 725
Computational Motor Control
BENG 738
Advanced Medical Image Processing
BENG 798
Independent Reading and Research in Bioengineering
Electrical, Computer & Mechanical Engineering
ECE 511
Computer Architecture
ECE 528
Introduction to Random Processes in Electrical and Computer Engineering
ECE 530
Sensor Engineering
ECE 550
System Engineering Design
ECE 635
Adaptive Signal Processing
ME 621
Foundations of Fluid Mechanics
Bioinformatics
BINF 631
Molecular Cell Biology for Bioinformatics
BINF 641
Biomolecular Modeling
BINF 690
Numerical Methods for Bioinformatics
BINF 701
Systems Biology
BINF 731
Protein Structure Analysis
BINF 740
Introduction to Biophysics
BINF 741
Introduction to Computer Simulations of Biomolecules
BINF 751
Biochemical and Cellular Systems Modeling
BINF 760
Machine Learning for Bioinformatics
Biology and Chemistry
BIOL 562
Personalized Medicine
BIOL 563
Virology
BIOL 566
Cancer Genomics
BIOL 572
Human Genetics
BIOL 583
General Biochemistry
BIOL 682
Advanced Eukaryotic Cell Biology
CHEM 563
General Biochemistry I
CHEM 568
Bioorganic Chemistry
CHEM 613
Modern Polymer Chemistry
CHEM 660
Protein Biochemistry
Physics
PHYS 510
Computational Physics I
PHYS 612
Physics of Modern Imaging
PHYS 640
Finite Element Analysis of Solids and Fluids
PHYS 694
Applied Mechanics of Solids
PHYS 695
Applied Fluid Mechanics
Mathematics and Statistics
MATH 685
Numerical Analysis
STAT 517
Experimental Design
STAT 522
Applied Multivariate Statistics
STAT 526
Applied Regression Analysis
STAT 560
Biostatistical Methods
STAT 662
Multivariate Analysis and Statistical Learning
STAT 672
Statistical Learning and Data Analytics
Neurotechnology and Neuroscience
NEUR 601
Developmental Neuroscience
NEUR 602
Cellular Neuroscience
NEUR 651
Molecular Neuropharmacology
NEUR 734
Computational Neurobiology

Note: Students who elect to the coursework option will complete a minimum of 33 credit hours.

Additional Training Requirement

Bioengineering Seminar

All MS students are required to attend a minimum of two departmental seminars per semester. Students will sign an attendance sheet available at the end of each seminar.

On This Page

Bioengineering, BS/Bioengineering, Accelerated MS

Overview

Highly-qualified undergraduates may be admitted to the bachelor's/accelerated master's program and obtain a BS in Bioengineering and a MS in Bioengineering in an accelerated time-frame after satisfactory completion of a minimum of 140 credits.   

See AP.6.7 Bachelor's/Accelerated Master's Degrees for policies related to this program.

Students in an accelerated degree program must fulfill all university requirements for the master's degree.  For policies governing all graduate degrees, see AP.6 Graduate Policies.

BAM Pathway Admission Requirements

Applicants to all graduate programs at George Mason University must meet the admission standards and application requirements for graduate study as specified in the Graduate Admissions Policies and Bachelor's/Accelerated Master's Degree policies. 

Students majoring in Bioengineering, BS will be considered for admission into the BAM Pathway after completion of a minimum of 60 undergraduate credits with an overall GPA of at least 3.0 and have completed all MATH and PHYS requirements. Criteria for admission are identical to criteria for admission to the Bioengineering, MS program.

Students who are accepted into the BAM Pathway will be allowed to register for graduate level courses after successful completion of a minimum of 75 undergraduate credits and course-specific pre-requisites.

Accelerated Master's Admission Requirements

Students already admitted in the BAM Pathway will be admitted to the Bioengineering, MS program, if they have met the following criteria, as verified on the Bachelor’s/Accelerated Master’s Transition form:

  • A GPA of 3.0 or better in their 60 highest-level credits
  • Successfully meeting Mason’s requirements for undergraduate degree conferral (graduation) and completing the application for graduation.

Accelerated Pathway Requirements

To maintain the integrity and quality of both the undergraduate and graduate degree programs, undergraduate students must complete all credits that satisfy requirements for both the BS and MS programs, with up to four classes (twelve credits) overlap chosen from the following graduate courses:

BENG 520Biomedical Data Analytics3
BENG 521Cell and Tissue Engineering3
or BENG 540 Advanced Biomaterials and Biomimetic Devices for Nanomedicine
BENG 526Neural Engineering3
BENG 537Medical Image Processing3
or BENG 538 Medical Imaging
BENG 501Bioengineering Research Methods3
BENG 514Pathophysiology and the Role of New Technologies in Human Diseases3
BENG 575Intellectual Property, Regulatory Concepts and Product Development3

All graduate course prerequisites must be completed prior to enrollment.  Each graduate course must be completed with a grade of B or better to apply toward the MS program. The graduate courses may be counted as Technical Electives or Concentration Core courses towards the Bioengineering, BS program requirements with approval by the academic advisor of the BS program and the program director of the MS program (or the bioengineering department chair).

While still in undergraduate status, a maximum of six additional graduate credits may be taken as reserve graduate credit and applied to the master's program. Reserve graduate credits do not apply to the undergraduate degree.  These reserve credits can be chosen from the list of graduate level courses given above with approval by the academic advisor of the BS program and the program director of the MS program (or the bioengineering department chair).

For more detailed information on coursework and timeline requirements, see AP.6.7 Bachelor's/Accelerated Master's Degrees policies. 

Degree Conferral

Students are recommended to meet with the Bioengineering academic advisor one year before and must apply to the program one semester before they expect to complete the BS requirements to have the BS degree conferred. In addition, at the beginning of the student's final undergraduate semester, students must complete a Bachelor's/Accelerated Master's Transition form. At the completion of MS requirements, a MS degree is conferred.

Mechanical Engineering, BS / Bioengineering, Accelerated MS

Overview

Highly-qualified students in the Mechanical Engineering, BS have the option of obtaining an accelerated Bioengineering, MS.

For more detailed information, see AP.6.7 Bachelor's/Accelerated Master's Degrees.  For policies governing all graduate degrees, see AP.6 Graduate Policies.

Admission Requirements

Mason undergraduate students majoring in Mechanical Engineering, BS may apply to this option if they have earned 60 undergraduate credits with an overall GPA of at least 3.20, completed all MATH and PHYS requirements, and passed BENG 320 Bioengineering Signals and Systems and BIOL 213 Cell Structure and Function with the grade of C or better. It is also recommended that students take BENG 214 Physiology for Engineers and are proficient in MATLAB. Criteria for admission are identical to criteria for admission to the Bioengineering, MS program.

Students who are accepted into the BAM Pathway will be allowed to register for graduate level courses after successful completion of a minimum of 75 undergraduate credits and course-specific pre-requisites.

Accelerated Options Requirement

Students must complete all credits that satisfy requirements for both the BS and MS programs. Students take up to 9 credits of approved MS level BENG courses as part of their undergraduate degree that will also be applied to the graduate degree. The courses selected for this purpose must be approved by the academic advisor of both the BS and MS programs and by the Bioengineering department chair. 

Specifically, students are encouraged to take up to three of the following courses to apply towards both their undergraduate and graduate degree.

BENG 520Biomedical Data Analytics3
BENG 521Cell and Tissue Engineering3
or BENG 541 Biomaterials
BENG 526Neural Engineering3
BENG 537Medical Image Processing3
or BENG 538 Medical Imaging
BENG 501Bioengineering Research Methods3
BENG 514Pathophysiology and the Role of New Technologies in Human Diseases3
BENG 575Intellectual Property, Regulatory Concepts and Product Development3

Degree Conferral

Students must apply the semester before they expect to complete the BS requirements to have the BS degree conferred. In addition, at the beginning of the student's final undergraduate semester, students must complete a Bachelor's/Accelerated Master's Transition form. At the completion of MS requirements, a master's degree is conferred.