Undergraduate courses offer a great deal of exposure to the field. Working in a hospital where biomedical engineers are employed can also provide you with insight into the field, as can interviews with practicing or retired biomedical engineers. Visit the IEEE EMBS Students Web site (http://students.embs.org/) to view videos and access other information about career paths in biomedical engineering. You should also consider joining the Technology Student Association (https://www.tsaweb.org), a membership organization for middle and high school students who want to become engineers, scientists, and technologists.
Using engineering principles to solve medical and health-related problems, the biomedical engineer works closely with life scientists, members of the medical profession, and chemists. Most of the work revolves around the laboratory. There are three interrelated work areas: research, design, and teaching.
Biomedical research is multifaceted and broad in scope. It calls upon engineers to apply their knowledge of mechanical, chemical, and electrical engineering as well as anatomy and physiology in the study of living systems. Using computers, biomedical engineers use their knowledge of graphic and related technologies to develop mathematical models that simulate physiological systems.
In biomedical engineering design, medical instruments and devices are developed. Engineers work on artificial organs, ultrasonic imagery devices, cardiac pacemakers, and surgical lasers, for example. They design and build systems that will update hospital, laboratory, and clinical procedures. They also train health care personnel in the proper use of this new equipment.
Biomedical engineering is taught on the university level. Teachers conduct classes, advise students, serve on academic committees, and supervise or conduct research.
Within biomedical engineering, an individual may concentrate on a particular specialty area. Some of the well-established specialties are biomechanics, biomaterials, bioinstrumentation, systems physiology, orthopedic engineering, and rehabilitation engineering. These specialty areas frequently depend on one another. Biomechanics is mechanics applied to biological or medical problems. Examples include the artificial heart, the artificial kidney, and the artificial hip. Biomaterials is the study of the optimal materials with which to construct such devices. Bioinstrumentation is the science of measuring physiological functions. Systems physiology uses engineering strategies, techniques, and tools to gain a comprehensive and integrated understanding of living organisms ranging from bacteria to humans. Biomedical engineers in this specialty examine such things as the biochemistry of metabolism and the control of limb movements. Orthopedic engineering is the application of biomedical engineering to diseases and conditions of the musculoskeletal system. Rehabilitation engineering is a new and growing specialty area of biomedical engineering. Its goal is to expand the capabilities and improve the quality of life for individuals with physical impairments. Rehabilitation engineers often work directly with the disabled person and modify equipment for individual use.