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Instruction offered by members of the Schulich School of Engineering and Kinesiology.
Associate Dean (Academic, Planning & Research) – R. Brennan
Director, Centre for Bioengineering Research and Education – E. Vigmond
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Biomedical Engineering
103
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Biomedical Engineers and Technology in Health Care
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Factors in modern health care provision, economic and social constraints, methods for determining efficacy of treatment (outcome measures), health technology assessment and decision-making, considerations of quality of life, methods for determining local, national and global needs, roles for the Biomedical Engineer in healthcare.
Course Hours:
Q(20 hours)
Antirequisite(s):
Credit for both Biomedical Engineering 103 and 003 will not be allowed.
NOT INCLUDED IN GPA
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Biomedical Engineering
309
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Anatomy and Physiology for Engineers
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Physiological terminology and anatomical planes of reference; cell biology and physiology; includes structure and function of musculoskeletal, cardiac, nervous, gastrointestinal and respiratory tissues and systems; diseases and disorders of those systems; design constraints for bioengineering products.
Course Hours:
H(3-3/2)
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Biomedical Engineering
319
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Applied Statistics for the Experimental Sciences
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Presentation and description of data, introduction to probability theory, Bayes theorem, discrete and continuous probability distributions, estimation, sampling distributions, tests of hypotheses on means, variances and proportions, simple linear regression and correlation, multivariate analysis, power calculations and statistical significance for study design, analysis of variance, additional models of regression analysis. Applications are chosen from bioengineering examples.
Course Hours:
H(3-1.5T)
Prerequisite(s):
Applied Mathematics 219.
Antirequisite(s):
Credit for both Biomedical Engineering 319 and Engineering 319 will not be allowed.
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Biomedical Engineering
327
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Electrical Circuits for Biomedical Engineers
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Definition of linear elements, independent and dependent sources, sign conventions; basic circuit laws, simple resistive circuits; node and mesh analysis. Thevenin, Norton and other theorems; inductance and capacitance. AC circuit analysis, impedance, admittance, phasor diagrams; average and effective values of waveforms, real, reactive and complex power, power calculations; mutual inductance, ideal transformer, introduction to balanced three-phase circuits, power calculation in three-phase circuits. The tutorial and laboratory will introduce basic principles of sensors and measurement in a biomedical context. Includes signal amplification and filtering and analog-to-digital conversion.
Course Hours:
H(3-1T-3/2)
Prerequisite(s):
Physics 259.
Antirequisite(s):
Credit for both Biomedical Engineering 327 and any of Engineering 325, Engineering 225, Electrical Engineering 329 or 341 will not be allowed.
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Biomedical Engineering
405
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Biological Tissue and System Mechanics
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To understand the constitutive and structural behaviour of complex biological tissue: mechanical and electro-chemical properties of biological tissues, nonlinear and time-dependent behaviour, functional adaptation to load, multi-phasic materials, anisotropic and composite materials, structural and micro-structural behaviour, hierarchical modelling from system to tissue to cell, failure theories.
Course Hours:
H(3-1T-2)
Prerequisite(s):
Engineering 317 and Biomedical Engineering 309.
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Biomedical Engineering
407
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Cell Culture and Tissue Engineering
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Mammalian cell culture, including nutrient metabolism, growth kinetics and scale up to bioreactors. Cell adhesion, cell aggregation, cell motility. Forces on cells, stress and strain, fluid shear. Mass transfer in tissues, extra-cellular matrix and tissue microenvironments, biomaterials, artificial organs. Therapeutic molecule production from genetically engineered cells.
Course Hours:
H(3-1T-2)
Prerequisite(s):
Biomedical Engineering 309.
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Biomedical Engineering
409
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Bioelectricity
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The generation, transmission, and measurement of electrical events generated by the excitable cells which compose the heart, brain, and muscle. Starting with the behaviour of ions in solution, a description of biologically generated electricity is built up to ultimately relate cellular activity to body surface potentials as measured by the electrocardiogram and electroencephalogram. Equivalent electrical circuit representations of biological structures are derived. Physiology specific to the organ being studied will be given.
Course Hours:
H(3-1T -2)
Prerequisite(s):
Biomedical Engineering 309 and 327.
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Biomedical Engineering
500
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Biomedical Engineering Research Thesis
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A directed studies research project in an area of interest, directed by a project advisor/faculty member within the faculties of Engineering, Kinesiology, Science or Medicine. Includes a lecture component covering the scientific process, ethics, review of literature, and writing scientific proposals and manuscripts. The course culminates with a written thesis and presentation. Projects may involve experimental, analytic or computer modeling studies.
Course Hours:
M(1-8)
Prerequisite(s):
Final-year standing in the Engineering program of choice.
Notes:
Pre-term study is required.
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Biomedical Engineering
501
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Biomedical Engineering Project
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A directed studies project in an area of interest, supervised by a project advisor/faculty member within the faculties of Engineering, Kinesiology, Medicine, or Science. Includes a lecture component covering topics including the scientific process, ethics, review of literature, patent searches, market analysis, and technology evaluation. The project involves choosing a particular product, process or theory relevant to biomedical engineering, researching it and justifying its selection. A final report and presentation are required.
Course Hours:
H(1-2)
Prerequisite(s):
Final-year standing in the Engineering program of choice.
Notes:
Pre-term study is required.
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Biomedical Engineering
509
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Introduction to Biomedical Imaging and Applications
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Principles of various imaging modalities used in Biomedical engineering applications, including CT, MRI, ultrasound, PET, SPECT. Image processing operations: filtering, enhancement, feature extraction, pattern recognition and image reconstruction. Image registration and integration of different imaging modalities.
Course Hours:
H(3-2)
Prerequisite(s):
Applied Mathematics 307, Engineering 233, and one of Engineering 319, Biomedical Engineering 319, or Electrical Engineering 419.
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Biomedical Engineering
511
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Biomaterials and Biocompatibility
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Basic chemical and mechanical properties of biological and synthetic materials and their role in biological system health, dysfunction, and repair. Role of microstructure, material properties, and biocompatibility aspects in selection of biomaterials for medical or industrial applications. Incorporation of biomimetic concepts in material design. Topics may include artificial and tissue engineered products, implants, prostheses, biofilms, biosensors, and foreign body response.
Course Hours:
H(3-2)
Prerequisite(s):
Fourth-year standing in the Engineering program of choice.
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Biomedical Engineering
513
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Photogrammetric Techniques for Reconstruction and Manipulation of Biomedical Data
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Basic photogrammetric principles. Photogrammetric techniques for biomedical applications; image acquisition, camera calibration, bundle adjustment, conventional and x-ray imagery, accurate geometric measurements; multivariate least-squares estimation and object reconstruction from 2D and 3D imagery. Other photogrammetric techniques, including laser scanning, range cameras, and coded light projection. Applications in motion capture, implant measurement, facial measurement, and computer-assisted surgery.
Course Hours:
H(3-2)
Prerequisite(s):
Engineering 233, Mathematics 211, and one of Engineering 319, Biomedical Engineering 319, or Electrical Engineering 419.
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Biomedical Engineering
515
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Bioengineering Methods in Systems Biology and Physiology
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Concepts from systems theory, differential equations, and stochastic processes applied to physiological and biological systems. Experimental and computational approaches to the study of gene expression and gene networks. Use of quantitative model-based approaches for integrative analysis of physiological and biological functions. Case studies of applications to disease mechanisms and the drug discovery process.
Course Hours:
H(3-2)
Prerequisite(s):
Applied Mathematics 307.
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Biomedical Engineering
517
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Biomedical Device Development
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Medical device development and how it differs from other types of device development. Identification of market needs. Quality system requirements. Requirements for regulatory approval, including risk classifications, testing standards and human factors considerations. Importance and timing of intellectual property protection, especially patents. Commercialization considerations and pathways. Financing of new medical devices. Medical device industry-specific examples will be presented.
Course Hours:
H(3-2)
Prerequisite(s):
Final-year standing in the Engineering program of choice.
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Biomedical Engineering
519
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Special Topics in Biomedical Engineering
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Current topics in Biomedical engineering.
Course Hours:
H(3-2)
Prerequisite(s):
Consent of the BMES Director or designate.
MAY BE REPEATED FOR CREDIT
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Biomedical Engineering
605
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Research Seminars in Biomedical Engineering
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Reports of studies of the literature or of current research.
Course Hours:
Q(1.5S-0)
NOT INCLUDED IN GPA
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Biomedical Engineering
607
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Research Seminars in Biomedical Engineering
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Reports of studies of the literature or of current research.
Course Hours:
Q(1.5S-0)
NOT INCLUDED IN GPA
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Biomedical Engineering
609
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Anatomy and Physiology for Biomedical Engineers
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Advanced instruction on human skeletal structure, types of connective tissues, structure of joints, muscle and organ structure and function, cardiac physiology, blood properties and flow, introduction to autonomous nervous system, and disorders of the musculoskeletal system. Other topics will be covered dependent on the interests of the instructor and students.
Course Hours:
H(3-3/2)
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Biomedical Engineering
611
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Fundamentals of Biomedical Engineering - Core Areas
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An introduction to biology, biochemistry, anatomy, physiology and biomedical engineering fundamentals.
Course Hours:
Q(3-0)
Antirequisite(s):
(formerly Biomedical Engineering 601)
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Biomedical Engineering
612
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Fundamentals of Biomedical Engineering - Research Areas
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Detailed discussion on current biomedical engineering topics, including current local and international research and industry, with an emphasis on local strengths.
Course Hours:
Q(3-0)
Antirequisite(s):
(formerly Biomedical Engineering 601)
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Biomedical Engineering
613
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Frontiers of Biomedical Engineering - Scientific Communication
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An introduction to technical (oral and written) communication to diverse audiences.
Course Hours:
Q(3-0)
Antirequisite(s):
(formerly Biomedical Engineering 603)
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Biomedical Engineering
614
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Frontiers of Biomedical Engineering - Research Methods
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An introduction to research methodology in biomedical engineering, experimental design, research integrity, ethics, and preparation and review of research proposals. Satisfactory completion of this course within 1 year of registration will ensure that the Biomedical Engineering Graduate Program Research Proposal requirements are met.
Course Hours:
Q(3-0)
Antirequisite(s):
(formerly Biomedical Engineering 603)
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Biomedical Engineering
619
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Special Problems in Biomedical Engineering
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Designed to provide graduate students, especially at the PhD level, with the opportunity of pursuing advanced studies in particular areas under the direction of a faculty member.
Course Hours:
H(3-1)
MAY BE REPEATED FOR CREDIT
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