DEPARTMENT OF ENGINEERING SCIENCES
BIOENGINEERING MINOR PROGRAM PROPOSAL
Bioengineering is the integration
of physical, chemical, or mathematical sciences and engineering principles in
an engineering approach to problems in the life sciences. Bioengineering is a
broad interdisciplinary field that brings together engineering, sciences
(biology and chemistry, especially) and medicine to create new techniques,
devices, and understanding of living systems to improve the quality of life.
Bioengineering has major fields specialization tracks
such as biomechanics, biomedical science and engineering, biomaterials
(including cell and tissue engineering).
The roots of bioengineering goes
back as early as 1950’s with groundbreaking developments in contact lenses, plasma
expanders, pacemakers, ultrasound, artificial hip joints, etc. Bioengineering
was approved as a graduate program in the
Student interest, industrial,
scientific and medical advances point to highlight a growing need for trained
bioengineers all over the world. Employment opportunities for people trained in
multidisciplinary areas such as bioengineering are increasing. People with special
expertise in bioengineering will be one of the determinants for guiding the
nations to achieve scientific excellence and improve their quality of life in
the upcoming decades.
The primary goals of the minor
program in Bioengineering are to provide the fundamentals of engineering and
life sciences, teach the students to apply engineering approaches to biological
problems and enable them to further specialize in special tracks of
bioengineering, and broaden their perspectives. Today, many universities in the
world have already established or are in the process of establishing
undergraduate and graduate level bioengineering programs. This list includes
four universities in
The METU Experience: The
potential interest among students from different disciplines towards
Bioengineering has been tested by means of two courses offered by the
Department of Engineering Sciences; ES 494 Introduction to Bioengineering and
ES 704 Tissue Engineering within the last two semesters. Many graduate and
undergraduate students have shown tremendous interest in these courses, in
spite of very short notices. There were 34 registered students in ES 704, 16 of
which are from Engineering majors, 18 from Sciences in
Spring 2002. In Fall 2002, there are 21 registered
students in ES 494, 17 of which are from Engineering majors, 4 from Sciences
and 4 unregistered PhD students from Engineering. In 704, there are 17 registered students,
8 from Engineering, 9 from Sciences this semester.
The Objectives of Minor Program in bioengineering are:
MINOR PROGRAM IN BIOENGINEERING
The main objective is to teach
student bioengineering principles and their applications in the life and
medical sciences. Engineering students will receive necessary background to
pursue education in related graduated programs: Biomechanics, Biotechnology,
Bioinformatics, and Biomedical Engineering. The curriculum will provide the
fundamentals and specific applications of bioengineering.
Compulsory Courses (minimum 12 credits)
BIO 252 Physiology (3-0)3
ES 223 Statics and Strength of Materials (4-0)4
ES 441 Introduction
to Biomechanics (3-0)3
ES 443 Introduction
to Bioengineering (ES 494) (3-0)3
Elective Courses (minimum 6 credits)
(At least 1 course must be from ES department)
EE 209 Fundamentals
of Electrical and Electronic Engineering (3-0)3
EE 415 Introduction
to Medical Imaging (3-2)4
EE 416 Fundamentals
of Biomedical Engineering (3-0)3
CHE 220 Principles
of Transport Phenomena (3-0)3
METE 222 Material
Science and Engineering (3-0)3
METE 229 Materials Science and Engineering (3-0)3
BIO 414 Biomedical
Materials and Instrumentation (3-0)3
BIO 461 Biophysics (3-0)3
ES 442 Advanced
Biomechanics (3-0)3
ES 444 Advanced Bioengineering (New) (3-0)3
ES 445 Tissue
Engineering (ES 704) (3-0)3
ES 446 Surface Engineering for Medical Applications (New) (3-0)3
ES 450 Human
Factors in Engineering Design (3-0)3
BIO 514 Biomaterials (3-0)3
CHEM 568 Biomedical Materials (3-0)3
EE 209 Fundamentals of
Electrical and Electronics Engineering (3-0)3
Fundamental circuit laws. Resistive circuit analysis. Sinusoidal steady-state response of circuits. Three-phase circuits. Magnetic circuits
and transformers. Electromechanical energy conversion.
Semiconductor elements, transistor biasing and amplifiers.
Operational amplifiers. (Offered to
non-EE students only).
Prerequisite: PHYS 106 or consent
of the department.
EE 415 Introduction to
Medical Imaging (3-0)3
Fundamentals of X-ray, generation and detection of X-rays, X-ray diagnostic
methods, X-ray image characteristics, biological effects of ionizing radiation.
Fundamentals of acoustic propagation, generation and
detection of ultrasound, ultrasonic diagnostic methods, biological effects of
ultrasound. Fundamentals of radionuclide imaging,
generation and detection of nuclear emission, radionuclide imaging methods,
radiation dosimetry and biological effects.
Fundamentals of magnetic resonance imaging, generation and detection of NMR
signal, imaging methods, biological effects of magnetic fields.
Prerequisite: EE 301 or consent
of the department.
EE 416 Fundamentals of Biomedical Engineering (3-2)4
Introduction to cell physiology: The neuron, synapses and the neural models. Sources of bioelectrical potentials and theory of ECG, EEG, EMG.
Electrodes for bioelectric and related instrumentation.
Physiology and measurement of the neural, circulatory,
respiratory and metabolic systems. Phonocardiography.
Patient care and monitoring. Introduction
to the principles and instrumentation of medical imaging systems and
computerized tomography.
Prerequisite: EE 311 or consent of the department.
CHE 220 Principles of Transport Phenomena (3-0)3
Introduction to basic concepts of momentum, heat and mass transfer.
Transport by molecular motion and in laminar flow in one dimension. Transport
between two phases and in large flow systems. (For non-CHE
students only).
METE 222 Materials
Science and Engineering (3-0)3
Classification of materials. Atomic bonding in solids.
Amorphous and crystalline structure of solids. Imperfections in crystals. Mechanical
properties of materials. Deformation and fracture behavior. Phase
diagrams and phase transformations. Metal alloys. Thermal
processing of metals. Nonmetallic materials. Corrosion and degradation of materials. (Oriented for
Chemical and Food Engineering)
METE 229 Materials
Science and Engineering (3-0)3
Classification of materials. Atomic structure and interatomic bonding. The structure
of crystalline solids. Crystalline and noncrystalline materials. Imperfections
in solids. Mechanical properties of materials.
Phase diagrams and phase transformations. Metal alloys. Structure
and properties of ceramics, polymers and composites. Electrical,
magnetic, thermal and optical properties of materials. Performance of materials in service. (Oriented for
Electrical and Electronic Engineering and Computer Engineering)
BIO 252 Physiology (3-0)3
This is a compact physiology course which covers a general survey of operation
and functions of the nervous system, special senses and skeletal muscle system,
digestive system and liver, the heart and circulatory endocrine system with
particular emphasis on homeostatic control mechanisms.
BIO 414 Biomedical
Materials and Instrumentation (3-0)3
This course is designed to
familiarize the students with two important aspects of the biological field at
an introductory level. The first part deals with biomedical applications of materials
obtained from natural and synthetic sources and covers interactions between the
body and the material, guidelines for biocompatibility and selection of
appropriate electronic apparatus, etc., used in biomedical instrumentation
systems.
BIO 461 Biophysics
I (3-0)3
An introduction to some selected topics in biophysics,
with emphasis on molecular background of structure and function is aimed. The
course content includes; introduction to molecular biophysics, radiation
biophysics, medical imaging techniques, microscopic and sub-microscopic methods
in biological structure and function analysis.
ES 223 Statics and
Strength of Materials (4-0)4
Principles of mechanics. Elements of statics in two dimensions. Centroids and moments of inertia.
Analysis of simple plane structures. Internal force
diagrams. Concepts of stress and strain. Axially loaded members. Torsion. Laterally loaded members.
Prerequisite: MATH 156 or MATH 158.
ES 441 Introduction
to Biomechanics (3-0)3
Structural and physical properties of bone, muscle, tendon and cartilage.
Mechanics of joint and muscle action. Body equilibrium.
Mechanics of the spinal column, of the pelvis and of the hip
joint. Panhomechanics.
Prerequisite: Consent of the
department.
ES 442 Advanced
Biomechanics (3-0)3
The knee joint, foot and ankle, shoulder-arm complex,
the elbow joint. Pathomechanics. Gait analysis.
Prerequisite: Consent of the
department.
ES 443 Introduction
to Bioengineering (ES 494) (3-0)3
Introduction of
the concept of bioengineering. Application of fluid
mechanics, mass transfer, bioheat transfer, control
theory to physiological systems and artificial organs. Structure-property relationships of biomedical materials.
Problems associated with the selection and function of biomedical materials. Design
principles for biomaterials. Basis for the molecular
therapeutics and drug delivery systems. Engineering of
biomaterial structures and surfaces. Biomechanics of
human musculoskeletal system.
ES 444 Advanced
Bioengineering (NEW) (3-0)3
Biomimetics. Material
Selection, Design and Processing for Bioengineering (films, foams, coatings,
nanotechnology, etc). Biosensors. Neuroengineering:
Neuro modeling and simulation system. Nerve guides
and nerve regeneration. Biomechanics of soft and hard tissues (hip
replacement). New areas of medical treatment (cell and gene
therapy, etc.) Separation methods; chromatography.
Diagnostic materials.
ES 445 Tissue
Engineering (ES 704) (3-0)3
Fundamentals of
Tissue Engineering, Challenges in tissue engineering. Principles of adhesion. Mechanics and Tissue Engineering. Mechanics
of tissues/ mass transfer. Biomaterials in Tissue
Engineering (Scaffold processing). Load Bearing Tissues: Cartilage and
Bone Engineering (design and evaluation of mechano-active
scaffolds). Engineering of vascular grafts.
ES 446
Surface Engineering for Medical Applications (NEW) (3-0)3
Surface
Chemistry. Molecular adsorption.
ES 450 Human
Factors in Engineering Design (3-0)3
Perceptual,
central and motor processes in man-machine systems. Human
capabilities and limitations. Use of anthropometric
data. Body mechanics and posture. Man-machine interface design. Physical
work capacity. Thermal stress and comfort. Vision and illumination. Noise,
vibrations. Fatigue, vigilance and accidents. Technological skills and training.
Prerequisite: Consent of the department.
BIO 514 Biomaterials (3-0)3
The multidisciplinary subject of
biomedical application of materials obtained from natural and synthetic
sources. Various applications and developments in the field
with special emphasis on biopolymers.
CHEM 568 Biomedical
Materials (3-0)3
Classification,
and characterization of materials which are used in biomedical area. Metals,
metal alloys, ceramics, polymers and their structure-property relationships. Tissue and blood response to implants and their tests.
Facility Needs of Minor Program in Bioengineering:
Classroom Need: Classrooms in the Department of Engineering
Sciences and in general use will be sufficient for the program.
Laboratory Need: Additional laboratory facilities will not
be needed.
Personnel Need: The department has to recruit one instructor
whose degree is from medical school but is also equipped with necessary
knowledge in mathematics and mechanics in order to maintain the present
graduate program in biomechanics. This instructor can also serve for the Minor
Program in Bioengineering. No additional recruitment is necessary.
Typical Examples of Undergraduate and Graduate
Bioengineering Programs
|
University |
Bioengineering Dept. |
Subunits |
Research Areas (Strong Areas) |
|
MIT |
Division of Bioengineering and Environmental Health (Undergraduate major) |
-Toxicology and Environmental Health -Biomedical Engineering |
-Cell, Tissue Engineering -Therapeutics Development and Delivery -Environmental and Endogenous Chemicals -Molecular Engineering -Environmental and Molecular Pathogens -Genetic Diseases and Diagnosis - Physiological modeling - Biological Imaging and Measurement |
|
UC, Berkeley |
Bioengineering Department (Undergraduate major) |
|
-Biomaterials and Molecular Eng. -Biomechanics and Physiological Fluid Mech. -Biomedical Imaging and Medical Physiology -Biomedical Inst. And Signal Process. -Biomedical Sensors -Medical Computing and Expert Systems -Molecular and Cellular Biology -Neuroscience -Vision Science -Pharmacology |
|
Cornell U. |
Field of Biomedical Engineering (Undergraduate and Graduate) |
10 Engineering Fields |
-Biomaterials -Drug delivery, design, production -Biomechanics -Biomedical Instrumentation and Diagnosis |
|
U. Utah |
Bioengineering (Undergraduate and Graduate) |
-Bioelectrical Eng. Tr. -Biomaterials Science and Eng. Tr. -Biomechanical Eng. Tr. -Biomolecular Eng. Tr. -Computational Bioeng. Tr |
-Bioinstrumentation and Imaging -Biomaterials -Biomechanics -Neural Interfaces |
|
U. Pittsburgh |
Bioengineering (Undergraduate Minor) |
|
|
|
Penn State U. |
Bioengineering (Undergraduate Major and Minor) |
-Chemical Eng Opt. -Materials Sci.and Eng. Opt. -Mechanical Eng. Opt. |
-Transport -Drug Delivery -Engineered Tissues -Mechanics of Human Body -Biomaterials |
|
Clemson U. |
Bioengineering Dept. (Undergraduate Major and Minor,
Graduate) |
|
-Biomaterials -Biomechanics -Biomedical Eng. -Cellular Biology -Orthopaedics -Cardiovascular Applications and Tissue Eng. -Development of New Implants -CAD/CAM based Prosthesis Design |
|
UC, San Diego |
Bioengineering (Graduate) |
|
-Vascular Molecular Bioengineering -Tissue Remodeling Mechanics -Biosensors -Cellular Simulation and Modeling -Microhemodynamics -Cardiac Mechanics -Genetic Circuits -Cartilage Tissue Engineering -Microcirculation -Bioinformatics -Molecular Bioengineering |
|
SUNY, Stony Brook |
Bioengineering (Undergraduate Major and Minor) |
|
|
|
U. Michigan Med. School |
Bioengineering (Graduate) |
|
-Biomechanics, -Biotechnology, -Bioelectric Sciences, -Medical Imaging, -Biomaterials |
|
U. Washington |
Bioengineering (Undergraduate, Graduate) |
-Cellular Bioengineering, -Molecular Bioengineering, -Bioinstrumentation/sensors, -Imaging, -Biomaterials, -Biosystems, -Biomechanics |
-Distributed Diagnosis and Home Healthcare -Engineered Biomaterials -Molecular Bioengineering and Nanotechnology -Medical Imaging and Image-Guided Therapy -Computational Bioengineering |
|
Rice U. |
Dept. Bioengineering (Graduate) |
|
|
|
Georgia Inst. Tech., Emory U. |
Bioengineering (Undergraduate and Graduate) |
|
-Biomechanics and Tissue Engineering -Bioinstrumentation and Medical Imaging -Medical Informatics and Telemedicine -Biomaterials and Drug Delivery -Biomechanics -Cellular Engineering -Interactive Biomedical Technologies -Medical Imaging -Quantitative Analysis and Modeling -Tissue Engineering -Neuroengineering |
|
U. Illinois, Urbana Champaign |
Bioengineering (Undergraduate Minor, Graduate), |
-Biomedical Eng. Specialization -Bioprocess Eng. Specialization -Cell and Tissue Eng. Specialization. |
|
|
U. Illinois, Chicago |
Bioengineering (Undergraduate and Graduate) |
|
-Cell and Tissue Engineering -Bioinformatics and Genomics -Neural Engineering -Biomechanics |
|
U. Syracuse |
Dept of Bioengineering and Neuroscience (Undergraduate,
Graduate) |
-Bioengineering -Neuroscience |
|
|
U. Toledo |
Dept. of Bioengineering |
|
-Bioinformatics Laboratory -Orthopaedic Bioengineering -Biomedical Optics -Transport Biological System -Spine Biomechanics Nanotechnology Center -Bioinstrumentation Lab -Total Hip Replacement -Cellular Engineering Response -Neuro Physiology |
|
Ege Üni. |
Bioengineering Dept. (Undergraduate and Graduate) |
|
-Genetic Eng. (Tissue Eng.) -Bioprocess Eng. -Biomedical Eng. |
|
Sabancı Üni. |
Biosciences and Bioengineering (Undergraduate) |
|
|
|
Hacettepe Üni. |
Bioengineering (Graduate) |
|
|
|
21. Başkent Üni. |
Biomedical Eng. (Undergraduate) |
|
|