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Experience with polymer synthesis and purification techniques as well as a firm understanding of analytical methods for polymer characterization is
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Biomedical engineers combine engineering principles with medical and biological sciences to design and create equipment, devices, computer systems, and software used in healthcare.
Biomedical engineers typically do the following:
Biomedical engineers design instruments, devices, and software used in healthcare; bring together knowledge from many technical sources to develop new procedures; or conduct research needed to solve clinical problems.
They often serve a coordinating function, using their background in both engineering and medicine. For example, they may create products for which an indepth understanding of living systems and technology is essential. They frequently work in research and development or in quality assurance.
Biomedical engineers design electrical circuits, software to run medical equipment, or computer simulations to test new drug therapies. In addition, they design and build artificial body parts, such as hip and knee joints. In some cases, they develop the materials needed to make the replacement body parts. They also design rehabilitative exercise equipment.
The work of these engineers spans many professional fields. For example, although their expertise is based in engineering and biology, they often design computer software to run complicated instruments, such as three-dimensional x-ray machines. Alternatively, many of these engineers use their knowledge of chemistry and biology to develop new drug therapies. Others draw heavily on mathematics and statistics to build models to understand the signals transmitted by the brain or heart.
The following are examples of specialty areas within the field of biomedical engineering:
Bioinstrumentation uses electronics, computer science, and measurement principles to develop devices used in the diagnosis and treatment of disease.
Biomaterials is the study of naturally occurring or laboratory-designed materials that are used in medical devices or as implantation materials.
Biomechanics involves the study of mechanics, such as thermodynamics, to solve biological or medical problems.
Clinical engineering applies medical technology to optimize healthcare delivery.
Rehabilitation engineering is the study of engineering and computer science to develop devices that assist individuals with physical and cognitive impairments.
Systems physiology uses engineering tools to understand how systems within living organisms, from bacteria to humans, function and respond to changes in their environment.
Some people with training in biomedical engineering become professors. For more information, see the profile on postsecondary teachers.
Biomedical engineers held about 22,100 jobs in 2014. The industries that employed the most biomedical engineers were as follows:
|Medical equipment and supplies manufacturing||23%|
|Research and development in the physical, engineering, and life sciences||16|
|Pharmaceutical and medicine manufacturing||12|
|Navigational, measuring, electromedical, and control instruments manufacturing||8|
|Hospitals; state, local, and private||8|
Biomedical engineers work in a variety of settings. Some work in hospitals, where therapy occurs, and others work in laboratories, doing research. Still others work in manufacturing settings, where they design biomedical engineering products. Yet other biomedical engineers work in commercial offices, where they make or support business decisions.
Biomedical engineers work in teams with scientists, healthcare workers, or other engineers. Where and how they work depends on the project. For example, a biomedical engineer who has developed a new device designed to help a person with a disability to walk again might have to spend hours in a hospital to determine whether the device works as planned. If the engineer finds a way to improve the device, he or she might have to return to the manufacturer to help alter the manufacturing process in order to improve the design.
Biomedical engineers usually work full time on a normal schedule. However, as with employees in almost any engineering occupation, biomedical engineers occasionally may have to work additional hours to meet the needs of patients, managers, colleagues, and clients.
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Biomedical engineers typically need a bachelor’s degree in biomedical engineering or bioengineering from an accredited program in order to enter the occupation. Alternatively, they can get a bachelor’s degree in a different field of engineering and then either choose biological science electives or get a graduate degree in biomedical engineering.
Prospective biomedical engineering or bioengineering students should take high school science courses, such as chemistry, physics, and biology. They should also take math courses, including algebra, geometry, trigonometry, and calculus. Courses in drafting or mechanical drawing and in computer programming are also useful.
Bachelor’s degree programs in biomedical engineering and bioengineering focus on engineering and biological sciences. Programs include laboratory-based courses, in addition to classroom-based courses, in subjects such as fluid and solid mechanics, computer programming, circuit design, and biomaterials. Other required courses may include biological sciences, such as physiology.
Accredited programs also include substantial training in engineering design. Many programs include co-ops or internships, often with hospitals and medical device and pharmaceutical manufacturing companies, to provide students with practical applications as part of their study. Biomedical engineering and bioengineering programs are accredited by ABET.
Analytical skills. Biomedical engineers must be able to analyze the needs of patients and customers to design appropriate solutions.
Communication skills. Because biomedical engineers sometimes work with patients and frequently work on teams, they must be able to express themselves clearly. They must seek others’ ideas and incorporate those ideas into the problem-solving process.
Creativity. Biomedical engineers must be creative to come up with innovative and integrative advances in healthcare equipment and devices.
Math skills. Biomedical engineers use the principles of calculus and other advanced topics in mathematics, as well as statistics, for analysis, design, and troubleshooting in their work.
Problem-solving skills. Biomedical engineers typically deal with and solve problems in complex biological systems.
Biomedical engineers typically receive greater responsibility through experience and more education. To lead a research team, a biomedical engineer generally needs a graduate degree. Some biomedical engineers attend medical or dental school to specialize in applications at the forefront of patient care, such as using electric impulses in new ways to get muscles moving again. Some earn law degrees and work as patent attorneys. Others pursue a master’s degree in business administration (MBA) and move into managerial positions. For more information, see the profiles on lawyers and architectural and engineering managers.
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The median annual wage for biomedical engineers was $86,950 in May 2014. The median wage is the wage at which half the workers in an occupation earned more than that amount and half earned less. The lowest 10 percent earned less than $52,680, and the highest 10 percent earned more than $139,350.
In May 2014, the median annual wages for biomedical engineers in the top industries in which they worked were as follows:
|Research and development in the physical, engineering, and life sciences||$97,160|
|Navigational, measuring, electromedical, and control instruments manufacturing||91,480|
|Medical equipment and supplies manufacturing||91,010|
|Pharmaceutical and medicine manufacturing||79,670|
|Hospitals; state, local, and private||72,060|
Biomedical engineers usually work full time on a normal schedule. However, as with employees in almost any engineering occupation, biomedical engineers occasionally may have to work additional hours to meet project deadlines.
Employment of biomedical engineers is projected to grow 23 percent from 2014 to 2024, much faster than the average for all occupations.
Biomedical engineers likely will see more demand because of growing technology and its application to medical equipment and devices. Smartphone technology and three-dimensional printing are examples of technology being applied to biomedical advances.
As the aging baby-boom generation lives longer and stays active, the demand for biomedical devices and procedures, such as hip and knee replacements is expected to increase. In addition, as the public has become more aware of medical advances, increasing numbers of people are seeking biomedical solutions to their health problems from their physicians.
Biomedical engineers work with scientists, other medical researchers, and manufacturers to address a wide range of injuries and physical disabilities. Their ability to work in different activities with workers from other fields is enlarging the range of applications for biomedical engineering products and services.
Rapid advances in technology will continue to change what biomedical engineers do and continue to create new areas for them to work in. Thus, the expanding range of activities in which biomedical engineers are engaged should translate into very favorable job prospects. In addition, the aging of the population and retirement of a substantial percentage of biomedical engineers is likely to help create job openings between 2014 and 2024.
|Occupational Title||Employment, 2014||Projected Employment, 2024||Change, 2014-24|