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Instructor: Charles A. Cain
Semesters Offered: Fall

Prerequisite: MATH 214 or MATH 216, and Physics 240 I (4 credits)
Students learn circuits and linear systems concepts necessary for analysis and design of biomedical systems. Theory is motivated by examples from biomedical engineering. Topics covered include electrical circuit fundamentals, operational amplifiers, frequency response, electrical transients, impulse response, transfer functions, and convolution, all motivated by circuit and biomedical examples. Elements of continuous time domain-frequency domain analytical techniques are developed.

Syllabus, ABET Course Profile

Instructor: Michael Mayer
Semesters Offered: Varies

Prerequisite: CHEM 210 and MATH 116. Recommend MCDB 310 or Biol Chem 415 or CHEM 351 to be taken concurrently. I (4 credits)
This course covers the physio-chemical concepts and processes relevant to life. The emphasis lies on the molecular level. Topics: Biomimetics; Energy and Driving Forces; Biochemical Equilibria; Aqueous Solutions; Molecular Self-Assembly; Bio-Electrochemistry; Biopolymers; Molecular Recognition and Binding Equilibria in Biology.

Syllabus, ABET Course Profile

Semesters Offered: Varies

Prerequisite: MATH 116 II (4 credits)
This course provides students with an introduction to topics in biomechanics, including statistics, dynamics, and deformable body mechanics, as they apply to biological tissues and systems.

Syllabus, ABET Course Profile

Semesters Offered: Varies

Prerequisite: BIOMEDE 211, 221, 231. I, II (4 credits)
This course provides an introduction to experimentation in circuits, systems, physical chemistry, thermodynamics, and mechanics with emphasis on biological applications. Lectures and laboratories on lab safety, measurement and analysis of physiological systems, operational amplifiers, rate of reaction, heat of reaction, whole body, tissue, and cellular mechanics, probability and statistical analysis.

Syllabus, ABET Course Profile

Semesters Offered: Varies

Prerequisite: permission of instructor. I, II, IIIa, IIIb (1-4 credits)
This course offers research experience to first- and second-year Engineering students in an area of mutual interest to the student and to a faculty member within the College of Engineering. For each hour of credit, it is expected that the student will work three hours per week. The grade for the course will be based on a final project/report evaluated by the faculty sponsor and participation in other required UROP activities, including bimonthly research group meetings and submission of a journal chronicling the research experience.

Semesters Offered: Varies

Prerequisite: none. II (1 credit)
This seminar is designed for students interested in the Sequential Graduate/ Undergraduate Study (SGUS) program in which students obtain a B.S.E. degree from a participating engineering department, now including the BIOMEDE Department, and a M.S. degree from BIOMEDE. We will explore various BIOMEDE subdisciplines with the goal of helping students choose an undergraduate major department and to gain an appreciation for the breadth of the field of biomedical engineering.

Semesters Offered: Varies

Prerequisite: BIOMEDE 211, EECS 215, or EECS 314 II (4 credits)
Theory and practice of signals and systems in both continuous and discrete time domains with examples from biomedical signal processing and control. Continuous-time linear systems convolution, steady-state responses, Fourier and Laplace transforms, transfer functions, poles and zeros, stability, sampling, feedback. Discrete-time linear systems: Z transform, filters, Fourier transform, signal processing.

Course Website

ABET Course Profile

Semesters Offered: Varies

Prerequisite: BIOMEDE 221, MCDB 310 or Biol Chem 415 (MCDB 310 or Biol Chem 415 may be concurrent). II (3 credits)
This course will introduce students to topics in enzyme kinetics, enzyme inhibition, mass and energy balance, cell growth and differentiation, cell engineering, bioreactor design, and analysis of the human body, organs, tissues, and cells as bioreactors. The application of bioreaction/bioreactor principles to tissue engineering will also be discussed.

Syllabus, ABET Course Profile

Instructor: Joseph L. Bull
Semesters Offered: Varies

Prerequisite: BIOMEDE 231 and MATH 216. I (4 credits)
This course introduces the fundamentals of biofluid dynamics and continuum mechanics, and covers the application of these principles to a variety of biological flows. Fluid flow in physiology and biotechnology is investigated at a variety of scales, ranging from subcellular to full body.

Syllabus, ABET Course Profile

Semesters Offered: Varies

Prerequisite: BIOMEDE 231 II (4 credits)
This course covers the fundamentals of continuum mechanics and constitutive modeling relevant for biological tissues. Constitutive models covered include linear elasticity, nonlinear elasticity, viscoelasticity and poroelasticity. Structure-function relationships which link tissue morphology and physiology to tissue constitutive models will be covered for skeletal, cardiovascular, pulmonary, abdominal, skin, eye, and nervous tissues.

Syllabus, ABET Course Profile

Instructor: Andrew Putnam
Semesters Offered: Varies

Prerequisite: advised BIOMEDE 211, 221, 231; co-requisite BIOMEDE 241. (3 credits)
This course uses problem-based learning to introduce students to biomedical engineering design concepts, tools, and methodologies. Students will work in small groups and use virtual design and computational tools to propose and validate feasible solutions to real-world biomedical engineering problems with industrial and/or clinical relevance.

Syllabus

Semesters Offered: Varies

I, II (5 credits)
This course offers the basic concepts of human anatomy. The gross anatomical features of the body systems are presented together with the relevant developmental, histological, functional and clinical facts. The course is offered Mondays, Wednesdays, and Fridays through 30 lectures and four lab sessions where pertinent plastinated specimens are displayed.

Syllabus

Instructor: Brian J. Love
Semesters Offered: Varies

Prerequisite: MATSCIE 220 or 250 or permission of instructor. I (3-4 credits)
Biomaterials and their physiological interactions. Materials used in medicine/dentistry: metals, ceramics, polymers, composites, resorbable, smart, natural materials. Material response/degradation: mechanical breakdown, corrosion, dissolution, leaching, chemical degradation, wear. Host responses: foreign body reactions, inflammation, wound healing, carcinogenicity, immunogenicity, cytotoxicity, infection, local/systemic effects.

Syllabus, ABET Course Profile

Instructor: Charles A. Cain
Semesters Offered: Varies

Prerequisite: BIOMEDE 211 and 311, or EECS 215 and 216 or graduate standing. II (4 credits)
Electrical biophysics of nerve and muscle; electrical conduction in excitable tissue; quantitative models for nerve and muscle including the Hodgkin Huxley equations; biopotential mapping, cardiac electrophysiology, and functional electrical stimulation; group projects. Lecture and recitation.

ABET Course Profile

Instructor: ajhunt
Semesters Offered: Varies

Prerequisite: MCDB 310, Biol Chem 415, 451, or 515, and Physics 240, Math 216, Chem 130. II (4 credits)
This course introduces the fundamentals of cell structure and functioning. The goal is to provide a general background in cell biology, with emphasis placed on physical aspects that are of particular interest to engineers.

Syllabus, ABET Course Profile

Instructor: Multiple
Semesters Offered: Varies

Prerequisite: MCBD 310 or Biol Chem 415, 451, 515 or CHEM 351. I (4 credits)
Quantitative Physiology provides learning opportunities for senior undergraduate and graduate students to understand and develop competencies in a quantitative, research oriented, systems approach to physiology. Systems examined include cellular; musculoskeletal; cardiovascular; respiratory; endocrine; gastrointestinal; and renal. Mathematical models and engineering analyses are used to describe system performance where applicable. Lectures and problem sessions are used for instruction, and performance is evaluated based on homework problem sets.

Syllabus, ABET Course Profile

Instructor: David R. Dowling
Semesters Offered: Varies

Prerequisite: MATH 216 and Physics 240. I (3 credits)
Vibrating systems; acoustic wave equation; plane and spherical waves in fluid media; reflection and transmission at interfaces; propagation in lossy media; radiation and reception of acoustic waves; pipes, cavities and waveguides; resonators and filters; noise; selected topics in physiological, environmental and architectural acoustics.

Syllabus

Semesters Offered: Varies

Prerequisite: Previous or simultaneous registration in IOE 333 or instructor approval. I (3 credits)
This is a lecture course which surveys the design and application of rehabilitation engineering and assistive technologies in a wide range of areas, including wheeled mobility, seating and positioning, environmental control, computer access, augmentative communication, sensory aids, as well as emerging technologies.

Instructor: Multiple
Semesters Offered: Varies

Prerequisite: BIOMEDE 458 and senior standing. II (4 credits)
Interdisciplinary design groups carry out biomedical instrumentation design projects. Projects are sponsored by Medical School and College of Engineering research labs and local industry. Students are exposed to the entire design process: design problem definition, generation of a design specification, documentation, design review process, prototype fabrication, testing and calibration.

Syllabus, ABET Course Profile

Instructor: Dr. R. Schmedlen
Semesters Offered: Fall

Prerequisite: BIOMEDE 458 and senior standing. (2 credits)
Two semester course - Interdisciplinary groups design-build-test biomedical instrumentation projects. Projects are sponsored by Medical School and Engineering research labs, and local industry. Students are exposed to the entire design process: design problem definition, generation of a design specification, documentation, design review process, prototype fabrication, testing, and calibration. Students may receive credit for either BME 450 or 451, not both.

Instructor: Dr. R. Schmedlen
Semesters Offered: Winter

Prerequisite: BIOMEDE 451, 458, and senior standing (3 credits)
Two semester course - interdisciplinary groups design-build-test biomedical instrumentation projects. Projects are sponsored by Medical School and Engineering research labs, and local industry. Students are exposed to the entire design process: design problem definition, generation of a design specification, documentation, design review process, prototype fabrication, testing, and calibration. Students may receive credit for either BME 450 or 452, not both.

Semesters Offered: Varies

Prerequisite: BIOMEDE 231 or MECHENG 211. I (3 credits)
Definition of biological tissue and orthopaedic device mechanics, including elastic, viscoelastic and non-linear elastic behavior. Emphasis on structure function relationships. Overview of tissue adaption and the interaction between tissue mechanics and physiology.

Syllabus

Instructor: Zhen Xu
Semesters Offered: Varies

Prerequisite: BIOMEDE 211 or EECS 215 or EECS 314, and BIOMEDE 241 or graduate standing. I, II (4 credits)
Measurement and analysis of biopotentials and biomedical transducer characteristics; electrical safety; applications of FET's, integrated circuits, operational amplifiers for signal processing and computer interfacing; signal analysis and display on the laboratory minicomputer. Lecture and laboratory.

Syllabus, ABET Course Profile

Semesters Offered: Varies

Prerequisite: MATH 217, MATH 417, or MATH 419; and MATH 216, MATH 256, MATH 286, or MATH 316. II (3 credits)
Mathematical concepts used in the solution of inverse problems and analysis of related forward operators is discussed. Topics include ill-posedness, singular-value decomposition, generalized inverses, and regularization. Inverse problems considered (e.g., tomography, inverse scattering, image restoration, inverse heat conduction) are problems in biomedical engineering with analogs throughout science and engineering.

Instructor: Prof. A. Putnam
Semesters Offered: Varies

Prerequisite: BME 410, senior standing or permission of instructor. (3 credits)
This course focuses on understanding the principles of tissue engineering and regenerative medicine. Emphasis is on the components and design criteria of tisse engineering constructs. The course will cover multiple examples of engineering soft and hard tissue, and application of new technologies in regenerative medicine.

Instructor: James B. Grotberg
Semesters Offered: Varies

Prerequisite: BIOMEDE 331 or MECHENG 320. II (4 credits)
This is an intermediate level fluid mechanics course which uses examples from biotechnology processes and physiologic applications, including the cardiovascular, respiratory, ocular, renal, musculo-skeletal, and gastrointestinal system.

Syllabus

Instructor: Cheri X. Deng
Semesters Offered: Varies

Prerequisite: MATH 216, BIOMEDE 331 or MECHENG 330, or permission of instructor. II (4 credits)
Fundamentals of mass and heat transport as they relate to living systems. Convection, diffusion, active transport, osmosis and conservation of momentum, mass and energy will be applied to cellular and organ level transport. Examples from circulatory, respiratory, renal and ocular physiology will be examined.

Syllabus

Instructor: Michael J. Flynn
Semesters Offered: Varies

Prerequisite: none. II (2 credits)
Analytic description of radiation production, transport and detection in radiation imaging systems. Measurements methods for image quality and statistical performance of observers. Systems for radiographic and radioisotope imaging, including film/screen, storage phosphor, and electronic radiography, fluoroscopy, computed tomography, Anger camera, and PET systems. Emphasis on impact of random process on observer detection.

Syllabus

Semesters Offered: Varies

Prerequisite: NERS 312 or equivalent or permission of instructor. I (4 credits)
Fundamental physics behind radiological health engineering and topics in quantitative radiation protection. Radiation quantities and measurement, regulations and enforcement, external and internal dose estimation, radiation biology, radioactive waste issues, radon gas, emergencies, and wide variety of radiation sources from health physics perspective.

Semesters Offered: Varies

I, II, IIIa, IIIb, III (1-4 credits)
Provides an opportunity for undergraduate students to perform directed research devoted to Biomedical Engineering.

Semesters Offered: Varies

Prerequisite: permission of instructor; mandatory pass/fail. I (1 credit)
Definition of scope, challenge, and requirements of the bioengineering field. Faculty members review engineering-life sciences interdisciplinary activities as currently pursued in the College of Engineering and Medical School.

Instructor: Multiple
Semesters Offered: Varies

I, II, IIIa, IIIb, III (1-4 credits)
Topics of special interest selected by faculty. Lecture, seminar or laboratory.

1st Semester Syllabus, 2nd Semester Syllabus, Section Syllabus

Semesters Offered: Varies

Mandatory, satisfactory/unsatisfactory. I, II (1 credit)
This seminar will feature various bioengineering-related speakers.

Syllabus

Instructor: Prof. D. Sept
Semesters Offered: Varies

Prerequisite: Graduate standing or permission of instructor (3 credits)
This course will cover descriptive statistics, probability theory, distributions for discrete and continuous variables, hypothesis testing, and analysis of variance, as well as more advanced topics. We will make connections with real problems from engineering, biology, and medicine, and computational tools, will be used for examples and assignments.

Semesters Offered: Varies

Prerequisite: none. (3 credits)
Biological tissues have multiple scales and can adapt to their physical environment. This course focuses on visualization and modeling of tissue physics and adaptation. Examples include electrical conductivity of heart muscle and mechanics of hard and soft tissues. Homogenization theory is used for multiple scale modeling.

Semesters Offered: Varies

Prerequisite: BIOMEDE 516 or permission of instructor. II (3 credits)
This course provides the student practical, hands-on experience with research grade, medical imaging systems including x-ray, magnetic resonance, nuclear medicine, and ultrasound. Participants rotate through each of the respective areas and learn about and perform experiments to support previous theoretical instruction.

Semesters Offered: Varies

Prerequisite: EECS 451. I (3 credits)
Principles of modern medical imaging systems. For each modality the basic physics is described, leading to a systems model of the imager. Fundamental similarities between the imaging equations of different modalities will be stressed. Modalities covered include radiography, x-ray computed tomography (CT), NMR imaging (MRI) and real-time ultrasound.

Syllabus

Semesters Offered: Varies

Prerequisite: MCDB 310 or Biol Chem 415, 451, 515 or CHEM 351 or permission of instructor. I (4 credits)
Quantitative description of the structure and function of mammalian systems, including the neuromuscular, cardiovascular, respiratory, renal and endocrine systems. Mathematical models are used to describe system performance where applicable. Lectures, laboratories, and problem sessions.

Semesters Offered: Varies

Prerequisite: MCDB 310 or Biol Chem 415, 451, 515, or CHEM 351 and BIOMEDE 221 and CHEM 210 or permission of instructor. II (3 credits)
This course focuses on the biochemistry and biophysics of transport and signaling processes through biomembranes and on the relevance of these processes for disease and therapy. The course discusses topics including composition of biomembranes; fluidity and self-assembly of lipids; membrane proteins; membrane potential; signal transduction.

Syllabus

Semesters Offered: Varies

Prerequisite: BIOL 105 or BIOL 112 and MATH 215. II (3 credits)
This course is designed to equip the student with appropriate concepts and techniques for the quantitative analysis of the integrated behavior of complex biochemical systems. A general approach is developed from the basic postulates of enzyme catalysis and is illustrated with numerous specific examples, primarily from the microbial cell.

Semesters Offered: Varies

Prerequisite: previous or simultaneous registration in BIOMEDE 430. I (1 credit)
This is a lab course which provides hands-on experience in the use of assistive technologies and in-depth consideration of rehabilitation engineering research and design of assistive technologies for a wide range of areas, including environmental control, computer access, augmentative communication, wheeled mobility, sensory aids, and seating and positioning.

Instructor: Daniel P. Ferris
Semesters Offered: Varies

Prerequisite: Graduate standing. I (3 credits)
Course focuses on interactions of the nervous and musculoskeletal system during human and animal movement with a focus on basic biological and engineering principles. Topics will include neurorehabilitation, and computer simulations of neuromechanical systems. No previous knowledge of neuroscience or mechanics is assumed.

Syllabus

Semesters Offered: Varies

Prerequisite: IOE 333 or IOE 334. II (3 credits)
Anatomical and physiological concepts are introduced to understand and predict human motor capabilities, with particular emphasis on the evaluation and design of manual activities in various occupations. Quantitative models are developed to explain: (1) muscle strength performance; (2) cumulative and acute musculoskeletal injury; (3) physical fatigue; and (4) human motion control.

Instructor: Aileen Y. Huang-Saad
Semesters Offered: Varies

Prerequisite: none. I (1 credit)
Ethics, technology transfer, and technology protection pertaining to biomedical engineering are studied. Ethics issues range from the proper research conduct to identifying and managing conflicts of interest. Technology transfer studies the process and its influences on relationships between academia and industry.

Syllabus

Semesters Offered: Varies

Prerequisite: Biological Chemistry and calculus. (3 credits)
Introduction to proteomics, from experimental procedures to data organization and analysis. Basic syllabus: sample preparation and separations, mass spectrometry, database search analysis, de novo sequence analysis, characterizing post translational modifications, medical applications. Further topics may include, e.g.: 2-D gels, protein-protein interactions, protein microarrays. Research literature seminars required.

Instructor: Mary-Ann Mycek
Semesters Offered: Varies

Prerequisite: MATH 216. I (3 credits)
This course provides students with an understanding of current research in biomedical optics. Topics include: fundamental theoretical principles of tissue optics; computational approaches to light transport in tissues; optical instrumentation; an overview of applications in clinical optical diagnostics and laser-based therapy; an introduction to biomedical microscopy and applications in biophotonic technology.

Syllabus

Instructor: ajhunt
Semesters Offered: Varies

Prerequisite: Senior standing. I (3 credits)
This course will focus on how biomechanical and biophysical properties of subcellular structures can be determined and interpreted to reveal the workings of biological nano-machines.

Syllabus

Semesters Offered: Varies

Prerequisite: Biol 172 or 174, Intro Physics and Chemistry, senior standing or permission of instructor. I (3 credits)
Many life processes occur at small size-scales. This course covers scaling laws, biological solutions to coping with or taking advantage of small size, micro- and nanofabrication techniques, biochemistry, and biomedical applications (genomics, proteomics, cell biology, diagnostics, etc.). There is an emphasis on micro fluidics, surface science, and non-traditional fabrication techniques.

Semesters Offered: Varies

Prerequisite: senior or graduate standing. (3 credits)
This class focuses on biomolecular engineering of surfaces and interfaces in contact with biological systems. Recent advances in the interfacial design of materials as well as methods that enable studying such systems will be highlighted.

Instructor: Prof. J. Stegemann
Semesters Offered: Varies

Prerequisite: graduate standing or permission of instructor. (3 credits)
This course focuses on how mammalian cells interact with the complex 3D environment that surrounds them in tissues. The goal is to provide students with a thorough understanding of how cell function is controlled and how this knowledge can be applied to the prevention and treatment of disease.

Instructor: Michael J. Flynn
Semesters Offered: Varies

Prerequisite: preceded or accompanied by NERS 481. II (1 credit)
Computational projects illustrate principles of radiation imaging from NERS 481 (BIOMEDE 481). Students will model the performance of radiation systems as a function of design variables. Results will be in the form of computer displayed images. Students will evaluate results using observer experiments. Series of weekly projects are integrated to describe the performance of imaging systems.

Syllabus

Semesters Offered: Varies

Prerequisite: NERS 484 (BIOMEDE 484) or graduate status. II (3 credits)
This course covers the fundamental approaches to radiation protection in radiology, nuclear medicine, radiotherapy, and research environments at medical facilities. Topics presented include health effects, radiation dosimetry and dose estimation, quality control of imaging equipment, regulations, licensing and health physics program design.

Semesters Offered: Varies

Prerequisite: MCDB 310 or Biol Chem 415, 451, 515 or CHEM 351, CHE 517, or equivalent biology course; senior standing. II (3 credits)
Fundamental engineering and biological principles underlying field of tissue engineering are studied, along with specific examples and strategies to engineer specific tissues for clinical use (e.g., skin). Student design teams propose new approaches to tissue engineering challenges.

Semesters Offered: Varies

Mandatory, satisfactory/unsatisfactory. (to be arranged)
Provides opportunity for bioengineering students to participate in the work of laboratories devoted to living systems studies.

Semesters Offered: Varies

Prerequisite: 2 hrs of BiomedE 590; mandatory satisfactory/ unsatisfactory. I, II, III (credit to be arranged)
To be elected by bioengineering students pursuing the master's thesis option. May be taken more than once up to a total of 6 credit hours. Graded on a satisfactory/unsatisfactory basis only.

Instructor: Prof. M. El-Sayed
Semesters Offered: Varies

Prerequisite: BIOMEDE 410, senior standing, or permission of instructor. (3 credits)
The course will review the basic principles of polymer science and controlled drug delivery. The course will discuss specific examples of biopolymer applications in protein, peptide, nucleic acids, vaccine delivery, and the formulation of nanostructured devices and their application in targeted delivery of therapeutic and imaging agents.

Semesters Offered: Varies

Prerequisite: graduate standing. I, II (1 credit)
This seminar will feature invited speakers from pharmaceutical, biomedical, and other life sciences-related industries, and academic institutions.

Semesters Offered: Varies

I, II (1-6 credits)
Topics of current interest selected by the faculty. Lecture, seminar, or laboratory.

Sample Syllabus I, Sample Syllabus II

Semesters Offered: Varies

Prerequisite: MATH 216, Biol Chem 415, 451, 515. II (3 credits)
Quantitative analysis of chemical signaling systems, including receptor/ligand binding and trafficking, signal transduction and second messenger production, and cellular responses such as adhesion and migration.

Semesters Offered: Varies

Prerequisite: IOE 534 (BIOMEDE 534). II (2 credits)
This laboratory is offered in conjunction with the Occupational Biomechanics lecture course (IOE 534) to enable students to examine experimentally: (1) musculoskeletal reactions to volitional acts; (2) the use of electromyography (EMG's) to evaluate muscle function and fatigue; (3) biomechanical models; (4) motion analysis systems; and (5) musculoskeletal reactions to vibrations.

Semesters Offered: Varies

Prerequisite: MECHENG 540 (AEROSP 540) or MECHENG 543 or equivalent. II alternate years (3 credits)
Dynamics of muscle and tendon, models of muscle contraction. Kinematics and dynamics of the human body, methods for generating equations of motion. Mechanics of proprioceptors and other sensors. Analysis of human movement, including gait, running, and balance. Computer simulations and discussion of experimental measurement techniques.

Semesters Offered: Varies

I, II, III (1-8 credits); IIIa, IIIb (1-4 credits)
Dissertation work by doctoral student not yet admitted to status as candidate. The defense of the dissertation, that is, the final oral examination, must be held under a full-term candidacy enrollment.

Semesters Offered: Varies

Prerequisite: Graduate School authorization for admission as a doctoral candidate. I, II, III (8 credits); IIIa, IIIb (4 credits)
Election for dissertation work by a doctoral student who has been admitted to candidate status. The defense of the dissertation, that is, the final oral examination, must be held under a full-term candidacy enrollment.