Biomedical Physics is an interdisciplinary frontier of science in which the principles and techniques of physics are applied to study living things and how they work. Biophysicists are also involved in applying their knowledge of fundamental physics to develop and implement new techniques for analyzing organisms. Biophysicists may even facilitate the application of biological knowledge to problems in physics.
Interest in biomedical physics is exploding as a result of a realization that biological phenomena cannot be understood fully without physical insight. Students undertaking studies in biomedical physics can have the satisfaction of becoming players in a real frontier of modern science with a vast potential for breakthroughs. Headlines reveal a breathtaking range of scientific endeavours. At a macroscopic level, biophysicists are exploring how organisms develop and how they see, hear, taste, feel, and think. Also, they are examining activities such as movement, breathing, muscle contractions, and the operation of bones. Research along these avenues can have significant technological spinoffs, such as the development of better robots. At a microscopic level, biophysicists are studying how cells move and divide, how they harness and process energy, and how they react to external stimuli. Particularly interesting subjects include how a muscle cell converts the chemical energy of ATP into movement, how DNA can exactly replicate itself during cell division, and whether the folding of DNA defines a “second genetic code”. Spinoffs include the development of nanotechnology founded upon the unique mechanical and electrical properties of biomolecules. To facilitate their explorations, biophysicists are at the cutting edge of research aimed at developing new or improved techniques of imaging, diagnosis, and analysis.
York University offers a comprehensive four-year undergraduate degree program in biomedical physics. The program is special because it is strong in both physics and biology, focused by courses dedicated to biomedical physics, and sufficiently broad in scope to expose students to knowledge and techniques applicable not only to humans but to all of the kingdoms of life. Students acquire a theoretical and practical understanding of biology, physics and biomedical physics through both lecture-based and lab-based courses. The program offers experiences with lasers that are unique in Canada. Practical skills in mathematics and computing are developed by promoting applications to physical and biophysical problems. Powers of lateral thinking are enhanced through the mixing of physics and biology courses and the unification of material through biomedical physics courses. In the end, students learn to recognize biological problems that could benefit from physical insights as well as physical principles that might productively confront biological challenges. Most important, students gain the ability to think critically and to analyze and solve complex problems, talents that are in high demand in both the private and public sectors.
Because of the breadth of their training, students who graduate from the Biomedical Physics Program at York University have a wide range of career options. Jobs for which training in Biomedical Physics would be an asset exist in both the private and public sectors, including aerospace, agriculture, biotechnology, computing, environmental science, fashion, forensics, health, medicine, neuroscience, pharmaceuticals, and robotics. For example, there is demand for biophysicists in many large and small biomedical companies and in public institutions such as government laboratories, research units in hospitals, and public policy agencies. Companies and organizations engaging in activities with biomedical roots are highlighted under Careers.
Biomedical Physics is a highly-regarded path towards a career in medicine. In fact, undergraduate majors in physics recently ranked number 2 in performance on the MCAT (after economics majors; see MCAT, LSAT, and Physics Bachelor’s, American Institute of Physics, December 2013). Biomedical Physics is also a good starting point for a career in optometry or in dentistry. Students who graduate from the Biomedical Physics Program at York University are well-prepared for diploma programs in radiation therapy, ultrasound, and other applied health sciences, such as offered by the Michener Institute.
Biomedical Physics graduates are among the most valuable contributors to the teaching profession because they are so versatile. Students who graduate from the Biomedical Physics Program at York University achieve strong backgrounds in biology, biochemistry, physics, mathematics, and computer science, so they are capable of teaching a wide range of courses in school curricula. In Ontario, Biomedical Physics majors who wish to become teachers would normally apply for admission into a teacher education program following completion of their degree.
Students who wish to embark upon a research career must go on to graduate studies. Those who wish to lead research require a Ph.D. York’s Undergraduate Biomedical Physics Program is a logical starting point, especially for students who want the widest possible choice of options for study. The Program offers excellent preparation for graduate studies in biomedical physics or biological physics. With judicious selection of courses, the Program facilitates graduate studies in physics or biology, too.
To be eligible to major in Biomedical Physics at York University starting in first year, it is necessary to have passed Grade 12 courses or their equivalents in English, Physics, and Mathematics. Grade 12 Chemistry is recommended but not required for entry into the Biomedical Physics Program, but students lacking it must make it up prior to second year (York University offers an equivalent course). Specifically, applicants from high schools in Ontario must have passed
12U English (a Faculty requirement)
12U Physics
MHF4U Advanced Functions
MCV4U Calculus and Vectors
Applicants admitted to York University who lack any of these requirements cannot become Biomedical Physics majors until such time as the deficiencies are corrected. Those who wish to become Biomedical Physics majors can initially enroll as “undeclared majors”. York University offers bridging courses (high school equivalents) to help such students meet the entry requirements of the Program.
For applicants from Ontario high schools, admission and scholarships are based upon the best six 12U/M courses, which must include all pre-requisite courses for the declared major. Presently, the minimum per cent average required for admission to the Biomedical Physics Program is around the high seventies.
Students start by taking survey courses in biology, chemistry, and physics, along with supporting courses in mathematics and computer science. Specialized courses in biology, physics, and biomedical physics follow. Students are grounded in foundational physics disciplines such as electromagnetism, thermodynamics, and quantum mechanics as well as foundational biology disciplines such as genetics, biochemistry, and cell biology. Biomedical Physics courses confront the physics behind problems in the life sciences. Students have a wide range of choices starting in third year, ranging from photosynthesis to biomechanics on the biology side and electronics to fluid dynamics on the physics side. Rich laboratory experiences accompany lecture-based courses in all four years. Required courses and the suggested rate of progress are given in the Biomedical Physics Undergraduate Handbook.
York University professors in all science and engineering disciplines engage undergraduate students in their research. Engagement can take place through a paid “work/study” position or through a one-semester research course in the third or fourth year of study, any of which are possible throughout the year. Biomedical physics students also have the opportunity to participate in the University’s Technology Internship Program, which enables them to gain a paid internship outside of the University for up to 16 months.
Biomedical Physics is an Honours Program, and as such students are required to achieve an average grade of C+ or higher (York University Grade Point Average of 5.0 or higher) over all courses in order to graduate.
At York University, degrees (namely, the fancy pieces of paper) do not specify departments, programs, or streams. All students graduating from the Biomedical Physics Program would receive a degree stating “B.Sc., Honours”. On the transcript, however, the full details of a student’s educational path are given. So, a biophysicist’s transcript would show: Faculty of Science, B.Sc. Hnrs., Biomedical Physics.
Information about careers can be found on this website under Careers.
Images, videos, and articles pertaining to biomedical physics can be found on this website under Explore and on the Careers page for Teaching.
A database of graduate programs in biomedical physics is maintained by the Biophysical Society of America.
- Undergraduate Studies (B.Sc.)
Full details concerning the Undergraduate Biomedical Physics Program are summarized in the biomedical Physics Undergraduate Handbook. The Undergraduate Biomedical Physics Program is managed by the Department of Physics and Astronomy, whose website is here. - Graduate Studies (M.Sc. and Ph.D.)
At the graduate level, biomedical physics can be studied under the rubric “Biological Physics”, which is a field managed by the Graduate Program in Physics and Astronomy. Program details are provided in the Graduate Handbook. The website of the Graduate Program in Physics and Astronomy is here. - Research
Research in biomedical physics is undertaken in many different Departments at York University. Researchers are unified under the field “Biological Physics” in the Graduate Program in Physics and Astronomy. A summary of researchers and their interests is given here.
York University is located in Toronto, Ontario. With a culturally diverse population of 53,000 students and 7,000 faculty and staff, it is the second largest university in Canada. Worldwide, it has a community of 250,000 alumni. York is internationally recognized for research by faculty and students, which is led by 11 faculties and 27 research centres. The University is also on the forefronts of educational innovation. It’s Scott Library houses over 2.5 million books, and its newly built stadium recently hosted the track and field portion of the Toronto 2015 PanAm/ParaPanAm games. The academic community benefits from a wide range of restaurants, shops, and services situated on campus. York will be directly linked to the Metro Toronto subway system once the construction of subway stations on the north and south sides is completed in 2017.