不良研究所

不良研究所.CA / Biological & Biomedical Engineering / Programs

Program Offerings

Below is an overview of our programs.

(If you are visually impaired a text version follows.)

Overview of program offerings

Go to faculty page.

Get more information on the programs, including your funding options and how to apply.

Text Version of Program Offerings

Graduate Program Choices

  • Master's
    • Non-Thesis (M.Eng.) - Biomanufacturing Concentration
      • Course-based
      • RNA Technologies
      • Vaccine production (Biomanufacturing)
      • Cell and Gene Therapy
      • Bioengineering & Bioprocessing
      • Internship
    • Thesis (M.Sc.)
      • Funded
      • Possibility to fast-track to Doctoral program
  • Doctoral (Ph.D.)
    • Funded

In both the Master's (thesis) and Doctoral programs you may choose to advance research in numerous areas under the guidance of a supervisor. Consult our faculty page and filter by 'research area'.

Get more information on the programs, including your funding options and how to apply.

Showcasing research in our labs

Magnetic Resonance scan

MRI methods in cancer

The Levesque group develops quantitative imaging methods in the fight against cancer. The goal is to map tumour structure and metabolism to provide optimal treatment targeting information.

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Heart with a patch

Soft biomaterials

Dr. Li's lab takes multidisciplinary approaches of mechanics, chemistry and biomimetics to design and engineer novel soft biomaterials with unprecedented properties for cellular engineering, and tissue repair and regeneration.

Middle ear structure

Mechanics of the middle ear

Dr. Funnell's lab studies the mechanics of hearing. They use computational modelling, in close collaboration with state-of-the-art experimental and clinical measurements, to arrive at a quantitative understanding that will guide diagnostic and surgical practice.

Petri dishes holding blue dots

Viral vectors and vaccine bioprocessing

Dr. Kamen's lab is聽solving key scientific and engineering questions at different scales: molecular, cellular, and bioreactor; with a multi-dimensional bioengineering approach to achieve the development and implementation of fully integrated processes for viral vector and vaccine productions.

Brain with connective pathways

Network communications

Using anatomically realistic networks derived from diffusion weighted imaging (DWI), Dr. Misic's lab develops analytic and computational models of communication, diffusion and spreading. they use these models to characterize how communication processes unfold on structural brain networks and to individual differences in cognitive performance.聽

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3-D model of a protein

Computational biology

Dr. Xia鈥檚 lab uses multi-scale models of biomolecular machines and networks to probe their design principles in health and disease. They use聽3D structural models of proteins and protein-protein interactions to investigate their evolutionary design principles.

Bone with implant

Bone replacement implants with mechanical biocompatibility

Dr. Pasini's expertise lies in solid mechanics, structural optimization, and fabrication of architected materials. Some of these materials, often named mechanical metamaterials, exhibit extreme mechanical properties, at times beyond those of existing solids.

Images of cells

Bioactive materials

Dr. Ehrlicher's lab specializes in biological mechanics and how biological systems are able to convert chemical energy into controlled active forces; as these forces move cells and also change their mechanical properties.

Maze being solved

Biocomputation, biosimulation and biological algorithms

Dr. Nicolau鈥檚 lab uses microfluidic devices to study information storage and processing in biological systems, from the biomolecular to the cellular level.

Two students in a lab

Nanobioengineering and lab-on-a-chip

Dr. Juncker's lab specializes聽in the miniaturization and integration in biology and medicine, which includes
the engineering and utilization of novel micro and nanotechnologies for manipulating, stimulating and studying oligonucleotides, proteins, cells, and tissues.

Magnetic Resonance scan and resonance spectroscopy graph

Advanced magnetic resonance spectroscopy (MRS) data acquisition

Dr. Near uses聽functional MRI聽during optogenetic stimulation of GABAergic neurons in the medial septum of the mouse brain. Localized proton magnetic resonance spectroscopy for measurements of neurochemical concentrations in the human brain.

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