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Biological and Biomedical Engineering
Location
Location
- Duff Medical Building
- 3775 University Street, Room 316
- Montreal QC H3A 2B4
- Canada
- Website: www.mcgill.ca/bbme
About Biological and Biomedical Engineering
About Biological and Biomedical Engineering
The Biological and Biomedical Engineering (BBME) graduate program is an interfaculty program involving the Department of Bioengineering in the Faculty of Engineering and the Department of Biomedical Engineering in the Faculty of Medicine. The BBME interfaculty program builds on the excellence and high standard of its predecessor graduate program in Biomedical Engineering. This broader interfaculty restructuring supports the growing trend in research universities toward formalized interdisciplinary studies and multifaculty collaboration.
BBME students come from a wide range of backgrounds including engineering, physics, chemistry, biology, and dentistry, among others. The multicultural diversity of our student body is a strength of the program, as networking and collaborative opportunities are vast. Students in BBME have supervisors associated with the program whose home departments will be spread primarily across the Faculties of Engineering and Medicine.
As researchers in this field unravel the molecular and physiological mechanisms of biology, develop increasingly advanced technologies to transform healthcare, or attempt to reverse-engineer naturally occurring biological solutions, devices, and procedures, alumni of the BBME program are poised to play a critical role in shaping our global future.
Please consult our website for additional information.
Research Domains
Our faculty members are particularly active in research related to the development of quantitative analysis tools and instruments for biological and biomedical research. The ultimate goal is the pursuit of answers to biological and medical questions. Ongoing biological and biomedical engineering research at McGill includes:
- signal analysis, including brain (EEG), muscles (EMG), eyes (EOG), respiration, and mass spectrometry;
- systems analysis, including neuromuscular control, and oculomotor and vestibular control;
- experimental and computational biomechanics, including orthopedic and auditory mechanics;
- biomaterials, including artificial cells;
- medical imaging and image processing;
- micro and nanotechnology and biosensors;
- nanoparticles and cell imaging;
- bioinformatics and computational biology;
- computers in medical education, including interactive 3D models and haptics;
- biological materials and mechanics;
- biomolecular and cellular engineering, and regenerative medicine;
- biomedical, diagnostics, and high throughput screening engineering;
- mechanics of disease;
- tissue engineering, especially concerning 3D and nano-related biological microfluidics devices, such as fungi and cellular traffic;
- biological dynamic devices, from whole-organisms (e.g., bacteria) to nanodevices;
- information processing and storage in biological systems;
- systems and synthetic biology;
- cell mechanisms and the cytoskeleton;
- soft matter physics.
| Master of Engineering (M.Eng.) Biological and Biomedical Engineering (Thesis) (45 credits) |
|---|
| The Biological and Biomedical Engineering Master's program focuses on the interdisciplinary application of methods, paradigms, technologies, and devices from engineering and the natural sciences to problems in biology, medicine, and the life sciences. With its unique multidisciplinary environment and taking advantage of research collaborations between staff in the Faculties of Medicine, Science, and Engineering, BBME offers thesis-based graduate degrees (M.Eng.) that span broad themes, including: biomodelling, biosignal processing, medical imaging, nanotechnology, artificial cells and organs, probiotics, bioinformatics, orthopedics, biological materials and mechanobiology, motor proteins and the cytoskeleton, biosensors and biological therapeutics, biological networks, and computational biology. BBME's internationally-renowned staff provide frequent and stimulating interactions with physicians, scientists, and the biomedical industry. Through courses and thesis research, this program will prepare students for careers in industry, academia, hospitals, and government and provide a solid basis for Ph.D. studies. Candidates should hold a Bachelor's degree in engineering, science, or medicine with a strong emphasis on mathematics, physics, chemistry, and basic biology (physiology, cell biology, or molecular biology). For more information please consult www.mcgill.ca/bbme/prospective-students/masters-program. |
| Doctor of Philosophy (Ph.D.) Biological and Biomedical Engineering |
|
The Biological and Biomedical Engineering doctoral program provides students with advanced training in the interdisciplinary application of methods, paradigms, technologies, and devices from engineering and the natural sciences to problems in biology, medicine, and the life sciences. The program will focus on an area of choice while integrating quantitative concepts and engineering tools for the study of natural and life sciences and/or for patient care. As part of the Ph.D. requirement, the student will integrate the scientific method, develop critical and deep thinking, and acquire advanced writing and presentation skills that will form the foundation for his/her future career. Under the guidance of his/her supervisor, the student will tackle a research challenge and make original contributions to the advancement of science and engineering in an area of Biological and Biomedical Engineering. Through independent research and thesis writing, the program will prepare students for careers in academia, industry, hospitals, and government. Students who complete the program will obtain a doctor of philosophy in Biological and Biomedical Engineering. The best preparation for this program is a master's degree in BBME or a related discipline. For more information please consult www.mcgill.ca/bbme/prospective-students/doctoral-program. |
Programs, Courses and University Regulations—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
Biological and Biomedical Engineering Admission Requirements and Application Procedures
Biological and Biomedical Engineering Admission Requirements and Application Procedures
Admission Requirements
For up-to-date admission requirements, please consult www.mcgill.ca/bbme/prospective-students/how-apply and University Regulations & Resources > Graduate > Graduate Ï㽶ÊÓƵ and Application Procedures > Admission Requirements (Minimum Requirements to be Considered for Admission).
Application Procedures
McGill’s online application form for graduate program candidates is available at www.mcgill.ca/gradapplicants/apply.
See University Regulations & Resources > Graduate > Graduate Ï㽶ÊÓƵ and Application Procedures > Application Procedures for detailed application procedures.
Please address enquiries directly to info.bbme [at] mcgill.ca.
Application Dates and Deadlines
Application Dates and Deadlines
Application opening dates are set by Enrolment Services in consultation with Graduate and Postdoctoral Studies (GPS), while application deadlines are set by the Biological and Biomedical Engineering Graduate Program and may be revised at any time. Applicants must verify all deadlines and documentation requirements well in advance on the appropriate McGill departmental website; please consult the list at www.mcgill.ca/gps/contact/graduate-program. For additional information, please consult www.mcgill.ca/bbme/prospective-students/how-apply.
| Ìý | Application Opening Dates | Application Deadlines | ||
|---|---|---|---|---|
| Ìý | All Applicants | Non-Canadian citizens (incl. Special, Visiting & Exchange) | Canadian citizens/Perm. residents of Canada (incl. Special, Visiting & Exchange) | Current McGill Students (any citizenship) |
| Fall Term: | Sept. 15 | Feb. 1 | Feb. 1 | Feb. 1 |
| Winter Term: | Feb. 15 | Sept. 1 | Nov. 1 | Nov. 1 |
| Summer Term: | N/A | N/A | N/A | N/A |
Admission to graduate studies is competitive; accordingly, late and/or incomplete applications are considered only as time and space permit.
Note: Applications for Summer term admission will not be considered.
Programs, Courses and University Regulations—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
Biological and Biomedical Engineering Faculty
Biological and Biomedical Engineering Faculty
Biological and Biomedical Engineering is an interfaculty program offered jointly by the Department of Bioengineering in the Faculty of Engineering and the Department of Biomedical Engineering in the Faculty of Medicine.
Please refer to Bioengineering Faculty and Biomedical Engineering Faculty for their respective faculty listings.
Programs, Courses and University Regulations—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
Master of Engineering (M.Eng.) Biological and Biomedical Engineering (Thesis) (45 credits)
The Biological and Biomedical Engineering (BBME) Master’s program focuses on the interdisciplinary application of methods, paradigms, technologies, and devices from engineering and the natural sciences to problems in biology, medicine, and the life sciences. With its unique multidisciplinary environment, and taking advantage of research collaborations between staff in the Faculties of Medicine, Science, and Engineering. BBME offers thesis-based graduate degrees (M.Eng.) that span broad themes in biomodelling, biosignal processing, medical imaging, nanotechnology, artificial cells and organs, probiotics, bioinformatics, bioengineering, biomaterials, and orthopaedics. BBME’s internationally renowned staff provide frequent and stimulating interactions with physicians, scientists, and the biomedical industry. Through courses and thesis research, this program will prepare students for careers in industry, academia, hospitals and government and provide a solid basis for Ph.D. studies. Candidates should hold a bachelor’s degree in engineering, science, or medicine with a strong emphasis on mathematics, physics, chemistry, and basic physiology or cell biology.
Required Courses (3 credits)
| BBME 600D1 | (1.5) | Seminars in Biological and Biomedical Engineering |
| BBME 600D2 | (1.5) | Seminars in Biological and Biomedical Engineering |
OR
| BBME 600N1 | (1.5) | Seminars in Biological and Biomedical Engineering |
| BBME 600N2 | (1.5) | Seminars in Biological and Biomedical Engineering |
Complementary Courses (18 credits)
12 credits from BMDE or BIEN courses at the 500-level or higher core courses which may also include MDPH 607, of which the following must be included:
3 credits from the following quantitative courses, or other quantitative courses (at the 500-level or higher) approved by the Graduate Program Director.
| BIEN 510 | (3) | Engineered Nanomaterials for Biomedical Applications |
| BIEN 520 | (3) | High Throughput Bioanalytical Devices |
| BIEN 530 | (3) | Imaging and Bioanalytical Instrumentation |
| BIEN 550 | (3) | Biomolecular Devices |
| BIEN 560 | (3) | Biosensors |
| BIEN 570 | (3) | Active Mechanics in Biology |
| BIEN 590 | (3) | Cell Culture Engineering |
| BMDE 502 | (3) | BME Modelling and Identification |
| BMDE 503 | (3) | Biomedical Instrumentation |
| BMDE 509 | (3) | Quantitative Analysis and Modelling of Cellular Processes |
| BMDE 512 | (3) | Finite-Element Modelling in Biomedical Engineering |
| BMDE 519 | (3) | Biomedical Signals and Systems |
| BMDE 610 | (3) | Functional Neuroimaging Fusion |
Revision, May 2018. Start of revision.
6 credits from the list below or from other courses (at the 500-level or higher) which have both biomedical content and content from the physical sciences, engineering, or computer science, with the approval of the supervisor and Graduate Program Director.
| BIEN 510 | (3) | Engineered Nanomaterials for Biomedical Applications |
| BIEN 520 | (3) | High Throughput Bioanalytical Devices |
| BIEN 530 | (3) | Imaging and Bioanalytical Instrumentation |
| BIEN 550 | (3) | Biomolecular Devices |
| BIEN 560 | (3) | Biosensors |
| BIEN 570 | (3) | Active Mechanics in Biology |
| BIEN 590 | (3) | Cell Culture Engineering |
| BIEN 680 | (4) | Bioprocessing of Vaccines |
| BINF 511 | (3) | Bioinformatics for Genomics |
| BIOL 598 | (3) | Advanced Design and Statistics |
| BIOT 505 | (3) | Selected Topics in Biotechnology |
| BMDE 501 | (3) | Selected Topics in Biomedical Engineering |
| BMDE 502 | (3) | BME Modelling and Identification |
| BMDE 503 | (3) | Biomedical Instrumentation |
| BMDE 504 | (3) | Biomaterials and Bioperformance |
| BMDE 505 | (3) | Cell and Tissue Engineering |
| BMDE 506 | (3) | Molecular Biology Techniques |
| BMDE 508 | (3) | Introduction to Micro and Nano-Bioengineering |
| BMDE 509 | (3) | Quantitative Analysis and Modelling of Cellular Processes |
| BMDE 510 | (3) | Topics in Astrobiology |
| BMDE 512 | (3) | Finite-Element Modelling in Biomedical Engineering |
| BMDE 519 | (3) | Biomedical Signals and Systems |
| BMDE 610 | (3) | Functional Neuroimaging Fusion |
| BMDE 625D1 | (3) | Design of Assistive Technologies: Principles and Praxis |
| BMDE 625D2 | (3) | Design of Assistive Technologies: Principles and Praxis |
| BMDE 650 | (3) | Advanced Medical Imaging |
| BMDE 651 | (3) | Orthopaedic Engineering |
| BMDE 652 | (3) | Bioinformatics: Proteomics |
| BMDE 653 | (3) | Patents in Biomedical Engineering |
| BMDE 654 | (3) | Biomedical Regulatory Affairs - Medical Devices |
| BMDE 655 | (3) | Biomedical Clinical Trials - Medical Devices |
| CHEE 561 | (3) | Introduction to Soft Tissue Biophysics |
| CHEE 563 | (3) | Biofluids and Cardiovascular Mechanics |
| CHEE 651 | (4) | Advanced Biochemical Engineering |
| CHEM 571 | (3) | Polymer Synthesis |
| COMP 526 | (3) | Probabilistic Reasoning and AI |
| COMP 546 | (4) | Computational Perception |
| COMP 551 | (4) | Applied Machine Learning |
| COMP 558 | (3) | Fundamentals of Computer Vision |
| COMP 561 | (4) | Computational Biology Methods and Research |
| COMP 652 | (4) | Machine Learning |
| COMP 761 | (4) | Advanced Topics Theory 2 |
| DENT 669 | (3) | Extracellular Matrix Biology |
| ECSE 523 | (3) | Speech Communications |
| ECSE 526 | (3) | Artificial Intelligence |
| ECSE 529 | (3) | Computer and Biological Vision |
| ECSE 618 | (4) | Haptics |
| ECSE 626 | (4) | Statistical Computer Vision |
| ECSE 681* | (4) | Colloquium in Electrical Engineering |
| EPIB 521 | (3) | Regression Analysis for Health Sciences |
| EXMD 609 | (3) | Cellular Methods in Medical Research |
| EXMD 610 | (3) | Molecular Methods in Medical Research |
| FACC 510 | (3) | Selected Topics in the Faculty of Engineering 1 |
| MATH 525 | (4) | Sampling Theory and Applications |
| MDPH 607 | (3) | Medical Imaging |
| MDPH 612 | (3) | Instrumentation and Computation in Medical Physics |
| MECH 500* | (3) | Selected Topics in Mechanical Engineering |
| MECH 548 | (3) | Cellular Materials in Natural and Engineering Structures |
| MECH 553 | (3) | Design and Manufacture of Microdevices |
| MECH 561 | (3) | Biomechanics of Musculoskeletal Systems |
| MECH 562 | (3) | Advanced Fluid Mechanics |
| MECH 563 | (3) | Biofluids and Cardiovascular Mechanics |
| MECH 605 | (4) | Applied Mathematics 1 |
| MECH 610 | (4) | Fundamentals of Fluid Dynamics |
| MECH 632 | (4) | Advanced Mechanics of Materials |
| NEUR 603 | (3) | Computational Neuroscience |
| NEUR 630 | (3) | Principles of Neuroscience 1 |
| NEUR 631 | (3) | Principles of Neuroscience 2 |
| PHGY 502 | (3) | Exercise Physiology |
| PHGY 517 | (3) | Artificial Internal Organs |
| PHGY 518 | (3) | Artificial Cells |
| PHGY 556 | (3) | Topics in Systems Neuroscience |
| PHYS 519 | (3) | Advanced Biophysics |
| PSYT 630 | (3) | Statistics for Neurosciences |
* When topic is appropriate.
Revision, May 2018. End of revision.
Programs, Courses and University Regulations—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
Doctor of Philosophy (Ph.D.) Biological and Biomedical Engineering
The goal of the Biological and Biomedical Engineering Ph.D. program is for students to gain advanced training in the interdisciplinary application of methods, paradigms, technologies, and devices from engineering and the natural sciences to problems in biology, medicine, and the life sciences. The program will focus in an area of choice while integrating quantitative concepts and engineering tools for the study of life sciences and/or for patient care. As part of the Ph.D. requirement, the student will integrate the scientific method, develop critical and deep thinking, and acquire advanced writing and presentation skills that will form the foundation for his/her career. Under the guidance of his/her supervisor, the student will tackle a research challenge and make original contributions to the advancement of science and engineering in an area of Biological and Biomedical Engineering. The program will prepare students for careers in academia, industry, hospitals and government. Students who complete the program will obtain a Doctor of Philosophy in Biological and Biomedical Engineering. The best preparation for this program is a Master’s degree in BBME or a related discipline.
Thesis
Thesis
A thesis for the doctoral degree must constitute original scholarship and must be a distinct contribution to knowledge. It must show familiarity with previous work in the field and must demonstrate ability to plan and carry out research, organize results, and defend the approach and conclusions in a scholarly manner. The research presented must meet current standards of the discipline; as well, the thesis must clearly demonstrate how the research advances knowledge in the field. Finally, the thesis must be written in compliance with norms for academic and scholarly expression and for publication in the public domain.
Required Course
| BBME 701 | (0) | Ph.D. Comprehensive Examination |
Students must be registered in this course at the time of the Thesis Proposal and Comprehensive Exam Meeting.
Programs, Courses and University Regulations—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
Faculty of Medicine—2018-2019 (last updated Aug. 16, 2018) (disclaimer)
