Those who study biomedical engineering learn to utilize engineering techniques to address medical needs. Biomedical engineering makes possible such advancements as artificial limbs that better integrate with the body or cutting edge cell therapies.
This major is designed so that its graduates can enter industry/government as practicing engineers or pursue research and teaching careers with government and/or academic
This major is designed so that its graduates can enter industry/government as practicing engineers or pursue research and teaching careers with government and/or academic institutions. The major also provides advanced study in biomedical engineering, with an emphasis in biomedical instrumentation, biomechanics, and medical imaging, for students who intend to pursue a Ph.D. degree in Biomedical Engineering or related fields.
For more information regarding the MSc in Engineering Physics, please click here.
The student may select either the non-thesis option or the thesis option. The thesis option requires the submission and public defense of an acceptable thesis based on independent research activities....
Grigore T. Popa University Of Medicine and Pharmacy IASI
The Master of Science in Biomedical Engineering was created to respond to increased needs for healthcare in our society. A biomedical engineer acts as an integrator betwe
Master of Science in Biomedical Engineering
Biomedical Engineering = Clinical education across diverse areas of practice
Number of years: 2 years graduate degree, 120 credits
Number of students: 45 students/year
TUITION FEE: 2,500 euro/year
Reasons to pursue Biomedical Engineering Master’s Degree?
The Master of Science in Biomedical Engineering was created to respond to increased needs for healthcare in our society. A biomedical engineer acts as an integrator between medical specialists and technology specialists.
The broad technological background that is essential in biomedical engineering also makes biomedical engineers attractive to conventional industrial sectors.
Integrated approaches to enable prevention of injury and disease and support healthy aging and engineered novel therapeutics.
How do biomedical engineers differ from other engineers?
Biomedical engineers must integrate biology and medicine with engineering to solve problems related to living systems.
Biomedical engineers are expected to integrate their engineering skills with their understanding of the complexity of biological systems in order to improve medical practice.
Where is a biomedical engineer working?
Pharmaceutical and biotechnology industries ;
Engage themselves in advance study in biomedical engineering or a related field.
Learning outcomes of the study program
George Washington University - School of Medicine and Health Sciences Online
The online Master of Science in Health Sciences (MSHS) in Biomedical Informatics is designed for professionals who want to lead at the intersection of data science, stati
The online Master of Science in Health Sciences (MSHS) in Biomedical Informatics is designed for professionals who want to lead at the intersection of data science, statistics, and health care. The program prepares you to solve complex clinical and public health issues by harnessing the power of data analysis and information systems.
Upon completion, you'll be able to effectively apply data science principles and design solutions to support clinical decision-making, research and patient engagement in a variety of health care settings.
Why GW's MSHS in Biomedical Informatics?
Innovative Curriculum: Learn cutting-edge methods for leveraging informatics tools and put them to use...
Biomedical engineering is a relatively new discipline that is up-and-coming. Modern technology has become an inextricable part of medicine and healthcare. That means ther
Biomedical engineering is a relatively new discipline that is up-and-coming. Modern technology has become an inextricable part of medicine and healthcare. That means there is a growing need on both the technological and the healthcare side for people with a grasp of increasingly complex biomedical problems.
Profile of the biomedical engineer
Biomedical engineers specialize in solving technological problems that require an understanding of how the human body functions. They combine a knowledge of the synthetic and analytic methods of physics and chemistry, computational methods of mathematics, and measurement and control systems of electrical engineering with a thorough medical and biological foundation....
The George Washington University - School of Engineering & Applied Science
Offered through the Department of Biomedical Engineering, the M.S. program in Biomedical Engineering is designed to prepare students to apply engineering principles to pr
Offered through the Department of Biomedical Engineering, the M.S. program in Biomedical Engineering is designed to prepare students to apply engineering principles to problems in medicine and biology; to understand and model attributes of living systems; and to synthesize biomedical systems and devices.
The program is strongly interdisciplinary, as students choose from a large array of areas of study across the university. The core faculty expertise includes cancer therapy, cardiac electrophysiology, biosensors, microfluidics, medical imaging and image analysis, optogenetics, robotics, and ultrasound applications in medicine.
Both the M.S. and Ph.D. programs are based on the main campus in Foggy Bottom, taking full advantage of the close proximity to the School of Medicine, the Milken Institute School of Public Health, and the GW Hospital. These interactions are supplemented by collaborations with nearby clinical and research facilities, including Children’s National Health System and federal agencies such as the Food and Drug Administration (FDA) and the National Institutes of Health (NIH)....
Our interdisciplinary Master of Bioscience Engineering: Human Health Engineering program (HHE) is dedicated to training the next generation of experts in human health eng
Our interdisciplinary Master of Bioscience Engineering: Human Health Engineering programme (HHE) is dedicated to training the next generation of experts in human health engineering. As a student, you will develop a unique profile that transcends traditional disciplinary boundaries and combines knowledge of the biology of the healthy human body and mind with engineering skills. Upon graduation, you will have the knowledge and skills to develop novel creative technologies aimed at improving our quality of life.
What is the Master of Bioscience Engineering: Human Health Engineering all about?
HHE offers a unique program and educational vision focusing on technology for healthy humans. While many programs in biomedical technology are offered in Belgium and abroad, HHE is the first and only programme offered in English that applies the unique combination of human physiology and engineering in a broad range of areas for healthy humans....
The Biomedical Engineering Department offers programs leading to the Master of Science (M.S.) and Doctor of Philosophy (Ph.D.) degrees, as well as a certificate program f
Leading education and research in biomedical engineering to improve human health
Biomedical engineering is a discipline of growing importance in society and is a vital and growing part not only of the Boston area but also of the whole US territory infrastructure – industry, academics, and hospitals. The field of biomedical engineering has been growing rapidly in the past few years. This expansion is due to many factors, including:
scientific and technological advances in molecular and cell biology, materials science and the engineering disciplines;
the increasing recognition of the role of interdisciplinary strategies to solve complex biomedical problems;
the aging of the population leading to increased healthcare needs and the associated demands and costs.
The role of technology in contemporary medicine has evolved considerably over the past decades. Computers and other high-tech devices are essential in hospitals, rehabili
The role of technology in contemporary medicine has evolved considerably over the past decades. Computers and other high-tech devices are essential in hospitals, rehabilitation centers, and private medical practices. Moreover, engineering breakthroughs have increased our fundamental insight into the functioning of the human body, tissue generation, and regeneration, physiological processes, and locomotion.
What's the Master of Biomedical Engineering about?
The Master of Science in Biomedical Engineering provides students with a state-of-the-art overview of all areas in biomedical engineering:
Medical sensors and signal processing
The Department of Biomedical Engineering at the University of North Texas is committed to educating and creating well-rounded, knowledgeable biomedical engineers who are
MScs in Biomedical Engineering.
The Department of Biomedical Engineering at the University of North Texas is committed to educating and creating well-rounded, knowledgeable biomedical engineers who are passionate about improving the quality of life for people in Texas, the United States, and the world.
To earn this degree, students will earn 30 credits for the thesis option and 33 credits for the non-thesis option. Students also have the option to earn a Certificate in Health Services Management through the University of North Texas Health Science Center.
A Biomedical Engineering concentration is available in the Electrical Engineering, Mechanical, and Energy Engineering, and Materials Science and Engineering Ph.D. programs....
Ghent University - Faculty of Engineering and Architecture
The International Master course prepares students from Europe and beyond for a profession in Biomedical Engineering. The biomedical engineer generates knowledge from the
The International Master course prepares students from Europe and beyond for a profession in Biomedical Engineering. The biomedical engineer generates knowledge from the molecular to the organ and system level. You will develop new materials, devices, tools, systems and methods for the early diagnosis, prevention and treatment of disease in order to improve and guarantee the health care and quality of life of the society.
Biomedical Engineering (BME) is a broad multidisciplinary area, involving many sub-specialisations, varying from regenerative medicine to implant design and from PET-scan imaging to biosensors. It is, for a single university, difficult to have in-depth knowledge of all sub-specialisations in Biomedical Engineering to teach their students on an adequate level. In addition, the required European and international scope is difficult to gain when students stick to a single university. Therefore a consortium of six universities has joined their knowledge and specific expertise into a two-year European Master in Biomedical Engineering. The student follows the first and second master at two different universities but any combination is possible. In this way, the student has maximum freedom to create a master’s programme tailored to his/her interests and to choose the preferred specialisation....
The master’s program in Biomedical Engineering at NJIT stresses the application of the principles and practices of engineering, science, and mathematics in solving clinic
The master’s program in Biomedical Engineering at NJIT stresses the application of the principles and practices of engineering, science, and mathematics in solving clinical problems in medicine. NJIT gives students the opportunity to customize their program to meet their career needs; they can select classes in Medical Imaging, Tissue Engineering, Design of Orthopedic Implants and Medical Instrumentation.
Master’s students in NJIT’s Biomedical Engineering program are expected to make significant contributions to research in their area of study, while also preparing to become leaders in academia, industry or the government. Graduates of our program are successfully engaged in the practice of biomedical engineering within the industry, academia, and government....
Biochemical Engineering utilizes the governing principles of living systems, properties of biological materials and engineering methodology in the processing of biologica
Biochemical Engineering utilizes the governing principles of living systems, properties of biological materials and engineering methodology in the processing of biological materials and in the processes using biological agents such as cells, enzymes, and antibodies. The School of Chemical, Materials, and Biomedical (CMB) Engineering offers several graduate programs for students to gain expertise at the frontiers of science and engineering knowledge. The faculty conduct research supported by the USDA, DOE, NIH, NSF, EPA and by industry partners, and have collaborative efforts with numerous centers of excellence at the University of Georgia, including the New Materials Institute, the Regenerative Bioscience Center and the Biomedical & Health Sciences Institute. These collaborations provide students with opportunities to engage with scientists across many science disciplines to tailor their education....
Biofabrication is an emerging technology in the field of medical engineering. In particular, additive production processes (such as 3D printing) are expected to make impo
Biofabrication is an emerging technology in the field of medical engineering. In particular, additive production processes (such as 3D printing) are expected to make important contributions to technological progress in the near term – and so is biofabrication. The internationally oriented master’s programme Biofabrication is interdisciplinary in nature, representing an engineering curriculum at the intersection of technology, chemistry, materials science, biology, and medicine. We offer you the opportunity to work in a research area at the cutting edge of medical innovation. Students profit from our conveniently located key labs, including those at Bayreuth’s Centre for Materials Science & Engineering (ZMW, TAO) and at the new Bavarian Polymer Institute....
Located within a European Centre of Excellence for Tissue engineering, and based on Keele University’s local hospital campus at the Guy Hilton Research Centre, the MSc in
The research centre is also an EPSRC Doctoral Training Centre for Regenerative Medicine, an Arthritis UK Centre and a UK Regenerative Medicine Platform Research Hub. This multidisciplinary environment enables close interaction with leading academics and clinicians involved in cutting-edge, and clinically transformative research.
The course provides support from the basics of human anatomy and physiology, through to the development of novel nanotechnologies for healthcare. Due to the teaching and research involvement of clinical academic staff within the department, there are exciting opportunities to be exposed to current clinical challenges and state-of-the-art developments. Clinical visits and specialist seminars are offered and students will be able to select dissertation projects that span fundamental research to clinical translation of technologies – a truly ‘bench to bedside’ approach....
This programme provides you with a solid understanding of the challenges related to biomedical and health sciences. You will become familiar with advanced technologies at
Biomedical Sciences and Engineering combines engineering with life sciences
People's need for more tailored and cost-efficient implants, devices and health informatics solutions is growing.
The biomedical engineering industry is an increasingly important, global high-tech sector. In Finland, the HealthTech industry is especially strong. With the emergence of numerous small enterprises, the fields of biomedical sciences and engineering are rapidly expanding and offer diverse career options. This programme provides you with a solid understanding of the challenges related to biomedical and health sciences. You will become familiar with advanced technologies at the interface between engineering and health sciences and have the ability to develop innovative solutions to solve these challenges. You will be able to demonstrate critical thinking and professionalism and pursue a career in industry, a hospital or continue your studies towards a doctoral degree. You may also be a natural-born entrepreneur and launch your own start-up....