Use of this web site signifies your agreement to the terms and conditions. What makes a biomedical engineer?
Abstract: This article focuses on undergraduate biomedical engineering BME curriculum, particularly on how to address industrial needs and to what extent a common curriculum can and should exist.
The editorial offers a snapshot of the continually evolving effort to integrate ideas from many sources for the improvement of curriculum in BME. The term "biomedical engineering" denotes a type of engineering with a strongly medical focus. Now that you know how to become a biomedical engineer, you can upload your resume for free on Monster and soon find yourself at the forefront of engineering and medicine—a powerful intersection of sciences that can help so many people in both the short and long terms.
Thank you! You are now a Monster member—and you'll receive more content in your inbox soon. By continuing, you agree to Monster's privacy policy , terms of use and use of cookies. Search Career Advice. How to Become a Biomedical Engineer This career path puts you at the forefront of exciting developments in practical science.
Omar Sommereyns, Monster contributor. Jump-start your biomedical engineering career. Related Articles. Browse articles by Find The Right Career Path. Professional Development. Latest Jobs. See More Jobs. Close Looking for the right fit? Sign up to get job alerts relevant to your skills and experience. 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.
In industry, they may create products where an in-depth understanding of living systems and technology is essential. Some biomedical engineers design electrical circuits, software to run medical equipment, or computer simulations to test new drug therapies. Some also design and build artificial body parts to replace injured limbs. In some cases, they develop the materials needed to make the replacement body parts.
They also design rehabilitative exercise equipment. 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, in order to understand the signals transmitted by the brain or heart.
Some biomedical engineers prefer to stay in academia and become professors. Biomedical engineers have distinct personalities. They are curious, methodical, rational, analytical, and logical. Does this sound like you?
Take our free career test to find out if biomedical engineer is one of your top career matches. A biomedical engineer can 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. Additionally, these engineers also work in commercial offices where they make or support business decisions.
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, the engineer might have to then return to the manufacturer to help alter the manufacturing process to improve the design.
Bioinstrumentation Bioinstrumentation is an application of biomedical engineering and is a new and upcoming field electrical engineering and computer science are also related to bioinstrumentation. The majority of innovations within bioinstrumentation have taken place within the past two decades. This specialty focuses on treating diseases and bringing together the engineering and medical worlds.
It uses electronics, computer science, and measurement principles to develop devices, instruments, and mechanics used in the diagnosis and treatment of medical problems and biological systems.
This specialty is also focused on using multiple sensors to keep a close eye on physiological characteristics of a human or an animal bioinstrumentation was first developed by NASA during early space missions to understand how humans were affected by space travel.
The sensors convert signals found within the body into electrical signals.
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