The possibilities of modern medicine are continually growing. Biomedical engineering opened doors to many advancements in the diagnosis and treatment of disease. Today, we have imaging methods that show living tissue in microscopic resolution. Around 400,000 medical devices are now available in medical technology.

The prerequisite for this is the use of high biomedical technology. The combination of precision mechanics, electronics, and optics creates innovative medical devices. These devices improve our quality of life, help heal diseases, and save lives. At the intersection between medicine and technology, we need specialists who can think in an interdisciplinary manner.

Biomedical engineers can transform medical questions into technical solutions. They can develop, optimize, design, and in this way, ensure innovations. As a biomedical engineer, you control, analyze, certify, and ensure quality and safety. They explain, inform, train, and bring designs to the market.

The professional opportunities for biomedical engineers are proliferating. These engineers work mostly in the following types of companies:
⦁ Agencies and companies for the evaluation and transfer of health technology
⦁ Biomedical technology companies
⦁ Biotechnology companies; clinical engineering departments of hospitals
⦁ Companies of diagnostic equipment
⦁ Hospital clinical services
⦁ Monitoring and medical therapy
⦁ Pharmaceutical companies
⦁ Technology-based healthcare service providers
⦁ Universities and research institutes
Many products they create may turn into business embryos capable of becoming business initiatives.

Is biomedical engineering a degree with a future?

Yes. It is a degree with a great future – probably the degree with the most future of all. How do we make this statement? Every day we live in this world, we see the impressive progress that is taking place. Different degrees may offer other prospects – it’s best to check the online rankings when choosing. The acceleration rate of this department is startling. If our subjective opinion doesn’t convince you, here are some objective facts:

⦁ The US Bureau of Labor Statistics forecasts a 23% growth in Biomedical Engineering (“Much faster than average”) in 2014-2024. By far, it is the branch of engineering that grows the most, with the average growth in jobs being 7%.
⦁ On the New York Times Top 10 Jobs list, Biomedical Engineering ranks # 1
⦁ On CNN’s Top 10 Jobs list, Biomedical Engineering ranks # 1
⦁ On the 2013 Career Cast Best Jobs list, Biomedical Engineering ranked second; the median pay for the position is $81,540

What is the typical career path for a Biomedical Engineer?

The profile of the Biomedical Engineer is diverse. A highly qualified engineer works in the R&D sector either in a company, a research center, or a hospital. These environments have a significant international component. There is a frequent movement of researchers between different countries. The engineer’s high qualification usually implies completing a postgraduate master’s degree and possibly a doctorate.

Job opportunities for biomedical engineers

The positions of biomedical managers are increasing. In large establishments, the biomedical engineering department may have several specialized engineers. In small structures, the biomedical manager has a versatile role. The role is also developing in companies in the industrial health sector. Therefore, the outlets are good. Moreover, 90% of graduates find their job in less than six months.

Professional evolution

A biomedical engineer can, with experience, take charge of a biomedical department in a hospital. He can also turn to industry and occupy positions in research and development, management, or trade.

Career Prospects

The program will prepare professionals and provide radiology protection equipment for the future with lifelong learning abilities. Students who complete the Master’s program in Biomedical Sciences and Engineering will gain various career opportunities with multidisciplinary challenges.

Graduates will find employment opportunities in global healthcare technology companies. Overall, the medical technology industry is one of the most export-oriented industries. Therefore, there is a need for graduates from abroad. Alternatively, graduates can also start a career in academia and pursue a Ph.D. Doctoral degree. Opportunities are available all over the world. The healthcare sector, from university hospitals to private clinics, is a significant employer. There is also a growing need for new talented engineers and researchers to work in the public sector or government agencies (e.g., Patent Office, Medical Device Regulations). Finally, over the past decade, a growing number of small businesses and subsidiaries have emerged, offering excellent opportunities for those interested in becoming entrepreneurs.

Specializing in Biomedical Micro- and Nano-devices provides competitive skills to work both in academia and industry in biomedicine and life sciences. There are excellent prospects in areas focused on micro-manufacturing. This specialty offers a good foundation for postgraduate study towards the doctoral degree, highly regarded in today’s technology industries.

Professional opportunities are also available in the industrial field. These engineers work on equipment acquisition, process efficiency, medical care, telemedicine, and remote monitoring in the healthcare sector.

In medicine, biomedical engineers work on the design and construction of health products and health technologies. These include medical equipment, prosthetics, medical devices, diagnostic devices (medical imaging), and therapy. This career combines engineering expertise with medical needs for healthcare benefits. Many specialists even consider tissue culture technology and the production of certain drugs as a part of bioengineering.


A biomedical engineering degree offers outstanding career opportunities around the world in almost every sector. An aging population and emerging diseases will lead to an increased demand for better devices and medical equipment that biomedical engineers create. On the other hand, rehabilitation and orthopedic engineering specialties are proliferating, increasing biomedical engineers’ demand.