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Uci Bioengineering
Biomedical engineering combines engineering expertise with medical needs for the enhancement of health care. It is a branch of engineering in which knowledge and skills are developed and applied to define and solve problems in biology and medicine. Students choose the biomedical engineering field to be of service to people, for the excitement of working with living systems, and to apply advanced technology to the complex problems of medical care. Biomedical engineers may be called upon to design instruments and devices, to bring together knowledge from many sources to develop new procedures, or to carry out research to acquire knowledge needed to solve new problems.
During the last 20 years, we have witnessed unprecedented advances in engineering, medical care, and the life sciences. The combination of exploding knowledge and technology in biology, medicine, the physical sciences, and engineering, coupled with the changes in the way health care will be delivered in the next century, provide a fertile ground for biomedical engineering. Biomedical engineering, at the confluence of these fields, has played a vital role in this progress. Traditionally, engineers have been concerned with inanimate materials, devices, and systems, while life scientists have investigated biological structure and function. Biomedical engineers integrate these disciplines in a unique way, combining the methodologies of the physical sciences and engineering with the study of biological and medical problems. The collaboration between engineers, physicians, biologists, and physical scientists is an integral part of this endeavor and has produced many important discoveries in the areas of artificial organs, artificial implants, and diagnostic equipment.
The Department offers a B.S. in Biomedical Engineering (BME), a four-year engineering curriculum accredited by the Engineering Accreditation Commission of ABET, http://www.abet.org. This program prepares students for a wide variety of careers in Biomedical Engineering in industry, hospitals, and research laboratories or for further education in graduate school.
The Department also offers a B.S. in Biomedical Engineering: Premedical (BMEP), a four-year engineering curriculum taken with required premedical courses. It is one of many majors that can serve as preparation for further training in medical, veterinary, or allied health professions. It is also suitable for students interested in pursuing graduate work in Biomedical Engineering and other biomedical areas such as physiology, neurosciences, and bioinformatics. The curriculum has less engineering content but more biological sciences and chemistry course work than the Biomedical Engineering major. The undergraduate major in Biomedical Engineering: Premedical is not designed to be accredited, therefore is not accredited by ABET.
Areas of graduate study and research include biophotonics, biomedical nanoscale systems, biomedical computational technologies, and tissue engineering.
uci biomedical engineering course plan
Biomedical Engineering, B.S.- Biomedical Engineering, M.S.
- Biomedical Engineering, Minor
- Biomedical Engineering, Ph.D.
- Biomedical Engineering: Premedical, B.S.
Courses
BME 1. Introduction to Biomedical Engineering. 3 Units.
Introduction to the central topics of biomedical engineering. Offers a perspective on bioengineering as a discipline in a seminar format. Principles of problem solving, design, engineering inventiveness, entrepreneurship, information access, communication, ethics, teamwork, and social responsibility are emphasized.
(Design units: 1)
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment.
BME 3. Engineering Innovations in Treating Diabetes. 4 Units.
Innovations in diabetes treatment from the 1800s until the present: purification of insulin, measuring and control of blood glucose, recombinant DNA, clinical trials, and ethics. Solving optimization problems in engineering with Excel.
(II and VA ).
BME 50A. Cell and Molecular Engineering. 4 Units.
Molecular, structural, genetic, biophysical, and cellular principles of life and bioengineering. Introduction to molecular bioengineering, genetic engineering, synthetic biology, and cell biology. Applications to genetic and biomolecular design.
(Design units: 1)
Corequisite: BME 1
Prerequisite: CHEM 1C or CHEM H2C
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Chemical Engineering Majors have first consideration for enrollment. Materials Science and Engr Majors have first consideration for enrollment.
BME 50B. Cell and Molecular Engineering. 4 Units.
Physiological function from a cellular, molecular, and biophysical perspective. Introduction to genetics, neuronal signaling, and cell cycle control.
(Design units: 1)
Prerequisite: BME 50A
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Chemical Engineering Majors have first consideration for enrollment.
BME 60A. Engineering Analysis/Design: Data Acquisition. 4 Units.
Fundamentals of LabVIEW programming, basics of computer-based experimentation, establishing interface between computer and data acquisition instrumentation, signal conditioning basics. Materials fee.
(Design units: 2)
Prerequisite: PHYS 7D
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment.
BME 60B. Engineering Analysis/Design: Data Analysis. 4 Units.
Overview of MATLAB; numeric, cell, and structure arrays; file management; plotting and model building; solving linear algebraic equations; signal and image processing. Materials fee.
(Design units: 1)
Prerequisite: MATH 3A
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment.
BME 60C. Engineering Analysis/Design: Computer-Aided Design. 4 Units.
Introduction to SolidWorks and Computer-Aided Design software; design; analysis; rapid prototyping; visualization and presentation; manufacturing planning. Materials fee.
(Design units: 2)
Prerequisite or corequisite: BME 1
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment.
BME 60D. Engineering Analysis/Design: Finite-Element Simulation. 4 Units.
Introduction to finite-element simulation; fundamentals of Multiphysics simulation;.
(Design units: 2)
Prerequisite: BME 60B and BME 60C
BME 110A. Biomechanics I. 4 Units.
Introduction to statics and dynamics. Topics include rigid bodies, analysis of structures, forces in beams, moments of inertia, friction, kinetics, work, and energy.
(Design units: 1)
Prerequisite: PHYS 7C and MATH 3A and MATH 3D and BME 60B and BME 60C
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment. Materials Science and Engr Majors have first consideration for enrollment.
BME 110B. Biomechanics II. 4 Units.
Introduction to biomechanics from subcellular to tissue levels. Introduction to stress, strain, and constitutive laws of cells and tissues. Emphasis is placed on biosolids. Introduction to elastic and viscoelastic behaviors with emphasis on the standard linear model of viscoelasticity.
(Design units: 1)
Prerequisite: BME 110A
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment. Materials Science and Engr Majors have first consideration for enrollment.
BME 110C. Biomechanics III. 4 Units.
Introduction to human biomechanics with emphasis on cardiovascular biomechanics and biofluid mechanics.
(Design units: 0)
Prerequisite: BME 110B
Restriction: Biomedical Engineering Majors have first consideration for enrollment.
BME 111. Design of Biomaterials. 4 Units.
Natural and synthetic polymeric materials. Metal and ceramics implant materials. Mechanical properties, degradation, surface characterization, and design of materials. Wound repair, blood clotting, foreign body response, biocompatibility of material. Artificial organs and medical devices. Government regulations.
(Design units: 3)
Corequisite: BME 50B or BIO SCI 99.
Prerequisite: CHEM 1C
Restriction: Biomedical Engineering Majors have first consideration for enrollment. Biomedical Engr: Premedical Majors have first consideration for enrollment. Materials Science and Engr Majors have first consideration for enrollment.
BME 114. Genetic Engineering and Synthetic Biology. 4 Units.
Exploring how biological function can be engineered and “synthesized” from the DNA level up.
(Design units: 0)
Prerequisite: (CHEM 1C or CHEM H2C) and MATH 3D and BME 50A and BME 50B
Restriction: Biomedical Engineering Majors have first consideration for enrollment.
uci biomedical engineering ranking
The bachelor’s program at UC Irvine was ranked #56 on College Factual’s Best Schools for bio engineering list. It is also ranked #10 in California.
Popularity of Bio Engineering at UC Irvine
During the 2019-2020 academic year, University of California – Irvine handed out 120 bachelor’s degrees in biomedical engineering. Due to this, the school was ranked #13 in popularity out of all colleges and universities that offer this degree. This is an increase of 33% over the previous year when 90 degrees were handed out.
In 2020, 44 students received their master’s degree in bio engineering from UC Irvine. This makes it the #17 most popular school for bio engineering master’s degree candidates in the country.
In addition, 22 students received their doctoral degrees in bio engineering in 2020, making the school the #11 most popular school in the United States for this category of students.
uci biomedical engineering major requirements
Mathematics and Basic Science Courses: | |
Students must complete a minimum of 48 units of mathematics and basic sciences including: | |
Core Courses: | |
CHEM 1A– 1B– 1C | General Chemistry and General Chemistry and General Chemistry |
CHEM 1LC | General Chemistry Laboratory |
MATH 2A– 2B | Single-Variable Calculus and Single-Variable Calculus |
MATH 2D | Multivariable Calculus |
MATH 2E | Multivariable Calculus |
MATH 3A | Introduction to Linear Algebra |
MATH 3D | Elementary Differential Equations |
PHYSICS 7C | Classical Physics |
PHYSICS 7LC | Classical Physics Laboratory |
PHYSICS 7D– 7E | Classical Physics and Classical Physics |
PHYSICS 7LD | Classical Physics Laboratory |
STATS 8 | Introduction to Biological Statistics |
Engineering Topics Courses: | |
Students must complete a minimum of 28 units of engineering design including: | |
Core Courses: | |
BME 1 | Introduction to Biomedical Engineering |
BME 50A– 50B | Cell and Molecular Engineering and Cell and Molecular Engineering |
BME 60A– 60B– 60C | Engineering Analysis/Design: Data Acquisition and Engineering Analysis/Design: Data Analysis and Engineering Analysis/Design: Computer-Aided Design |
BME 110A– 110B– 110C | Biomechanics I and Biomechanics II and Biomechanics III |
BME 111 | Design of Biomaterials |
BME 120 | Sensory Motor Systems |
BME 121 | Quantitative Physiology: Organ Transport Systems |
BME 130 | Biomedical Signals and Systems |
BME 140 | Design of Biomedical Electronics |
BME 150 | Biotransport Phenomena |
BME 170 | Biomedical Engineering Laboratory |
BME 180A– 180B– 180C | Biomedical Engineering Design and Biomedical Engineering Design and Biomedical Engineering Design |
Engineering Electives: | |
Students select, with the approval of a faculty advisor a minimum of 12 units of engineering topics needed to satisfy school and major requirements. | |
(The nominal Biomedical Engineering program will require 181 units of courses to satisfy all university and major requirements. Because each student comes to UCI with a different level of preparation, the actual number of units will vary.) | |
Engineering Professional Topics Course: | |
ENGR 190W | Communications in the Professional World |
Optional Specialization in Biophotonics
Select three of the following: | |
BME 135 | Photomedicine |
BME 136 | Engineering Medical Optics |
BME 137 | Introduction to Biomedical Imaging |
BME 138 | Spectroscopy and Imaging of Biological Systems |
EECS 180A | Engineering Electromagnetics I |
These courses will also satisfy the Engineering Electives requirement.
Optional Specialization in Micro and Nano Biomedical Engineering
Select three of the following: | |
BME 142 | Microfabrication |
BME 147 | Microfluidics and Lab-on-a-Chip |
BME 148 | Microimplants |
MSE 141 | Nano-Scale Materials and Applications |
ENGRMAE 153 | Advanced BIOMEMS Manufacturing Techniques |
These courses will also satisfy the Engineering Electives requirement.