Dr. Brian Amsden

Department of Chemical Engineering, Queen’s University

Aliphatic polycarbonates feature low cytotoxicity, a low glass transition temperature, and elasticity. These polymers are readily synthesized through ring-opening polymerization of cyclic carbonates, such as trimethylene carbonate, using a variety of biologically benign catalysts. They are also hydrolysis resistant and degrade in a molecular weight dependent manner through the action of reactive oxygen species and enzymes secreted by activated macrophages. This combination of properties makes them potentially useful for creating a variety of polymer biomaterials, ranging from elastic and resilient hydrogels to viscous liquids. In this presentation, a demonstration of the utility of these materials will be provided, focusing on copolymers designed as scaffolding materials for soft connective tissue regeneration and as vehicles of the delivery of acid-sensitive drugs.
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Brian Amsden is the Donald and Joan McGeachy Chair in Biomedical Engineering at Queen’s University. His current research interests include the development of biodegradable elastomers, hydrogels, and low viscosity hydrophobic polymers for the local delivery of small molecules, peptides and proteins, and stem cells, and as scaffolds for soft and connective tissue regeneration. He is the Director of the CONNECT! NSERC CREATE Program in Soft Connective Tissue Regeneration Network and a Co-Director of the Human Mobility Research Centre at Queen’s..

Hosted by Dr. Molly Shoichet
Snacks and Refreshments will be served

Microwave Applications in Mineral Processing: Opportunities for Energy Savings and Smart Beneficiation

Join us this month as Professor Erin Bobicki discusses new innovations in sustainability. The depletion of high-grade ores, rising production costs, climate change, the increasing scarcity of fresh water, and the need for a social license to operate all necessitate the development of efficient and sustainable mineral processing technologies. The application of microwaves in mineral processing presents an opportunity for energy savings and improved mineral separation efficiency. This presentation briefly describes the fundamentals of microwave heating, discusses emerging applications of microwave technology in mineral processing, reviews results from our lab on the microwave processing of ultramafic nickel ores, and addresses common concerns regarding energy savings and scale-up.

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Dr. Erin R. Bobicki is a professor of mineral processing in the departments of Materials Science and Engineering and Chemical Engineering and Applied Science at the University of Toronto. She has a PhD in Chemical Engineering from the University of Alberta and has worked as a researcher and plant metallurgist for Vale, and as a Process Technology Development Engineer for Intel. Professor Bobicki’s research interests include microwave applications in mineral processing, bioreagent development, bioseparation, the rheology of complex mineral slurries, and value recovery from waste materials.

Dr. Inbo Han, MD, PhD
Department of Neurosurgery, Spine Center
CHA University, School of Medicine, South Korea

“Matrilin-3 pretreatment improves the function of mesenchymal stem cells in the intervertebral disc repair”

Dr. UnYong Choi, MD
Department of Neurosurgery, Spine Center
CHA University, School of Medicine, South Korea

“Disc regenerative therapy of intervertebral disc degeneration in stem cell with scaffold”

Ji-hye Lee, PhD
Medical & scientific affairs, CGBio, Co., Ltd., South Korea

“Introduction of CGBio”

Chanwoo Ryan Hong
Director, illuminaid inc., South Korea
R&D team3 manager, CGBio, Co., Ltd., South Korea

“Introduction of custom 3d printing system for bioprint”

PDF: IBBME Visiting Researcher Joint Seminar

Kara L. Spiller, PhD
Biomaterials and Regenerative Medicine Laboratory
School of Biomedical Engineering, Science, and Health Systems
Drexel University, Philadelphia

Diabetes and peripheral arterial disease affect hundreds of millions of people worldwide. Patients with these conditions frequently develop chronic wounds on the lower limbs that lead to amputation, with a 5-year mortality rate as high as 77%. Macrophages, the primary cell of the innate immune system, are critical regulators of angiogenesis and wound healing. Their dysfunction is strongly implicated in arterial dysfunction, limb ischemia, and poorly healing chronic wounds. The goal of the Biomaterials and Regenerative Medicine Laboratory at Drexel University is to understand the mechanisms by which macrophages orchestrate successful angiogenesis and tissue regeneration and to develop novel biomaterial strategies that apply these principles to pathological situations, in order to ultimately prevent limb amputation. This talk will focus on the effects of temporal changes in macrophage phenotype on angiogenesis, the design of biomaterials and drug delivery systems to modulate macrophage phenotype for enhanced angiogenesis, and the development of macrophage phenotype-related biomarkers to assist in clinical decision making for a personalized medicine approach to wound care.

Dr. Kara Spiller is an Associate Professor in Drexel University’s School of Biomedical Engineering, Science, and Health Systems. Her research interests include the role of immune cells in tissue regeneration, the design of immunomodulatory biomaterials, and international engineering education. Her research is funded by the NIH, the NSF, and private foundations. Her awards include a Fulbright fellowship, the NSF CAREER award, and the United States nomination for the ASPIRE prize.

Professor. Matthias Heinemann
University of Groningen,
Netherlands

The principles governing cellular metabolic operation are poorly understood. Because diverse organisms show similar metabolic flux patterns, we hypothesized that a fundamental thermodynamic constraint might shape cellular metabolism. Here, we develop a constraint-based model for Saccharomyces cerevisiae with a comprehensive description of biochemical thermodynamics including a Gibbs energy balance. Non-linear regression analyses of quantitative metabolome and physiology data reveal the existence of an upper rate limit for cellular Gibbs energy dissipation. By applying this limit in flux balance analyses with growth maximization as the objective function, our model correctly predicts the physiology and intracellular metabolic fluxes for different glucose uptake rates as well as the maximal growth rate. We find that cells arrange their intracellular metabolic fluxes in such a way that, with increasing glucose uptake rates, they can accomplish optimal growth rates but stay below the critical rate limit on Gibbs energy dissipation. Once all possibilities for intracellular flux redistribution are exhausted, cells reach their maximal growth rate. This principle also holds for Escherichia coli and different carbon sources. Our work proposes that metabolic reaction stoichiometry, a limit on the cellular Gibbs energy dissipation rate, and the objective of growth maximization shape metabolism across organisms and conditions.

Download the event poster HERE

Associate Professor Vikramaditya Yadav
The Biofoundry, Department of Chemical and Biological Engineering
University of British Columbia 

Hosted by Prof. Krishna Mahadevan

The principal theme of Prof. Yadav’s research is the utilization of metabolic & enzyme engineering to investigate and customize novel biosynthetic enzymes that can convert biomass-derived feedstocks into value-added chemicals. His group also extends the principles of metabolic engineering to the design and development of unique bioremediation strategies to rehabilitate the water quality in and around industrial zones and develop new mining biotechnologies. In addition to green engineering, his research group also pursues medical biotechnology research, and focuses on bioengineering for assay development, lead generation and product development.

The seminar will provide a broad overview of the research and commercialization efforts that are afoot in his laboratory at UBC. In particular, the talk will cover some of his group’s recent successes in elucidating and using a novel plant metabolic pathway for the synthesis of value-added chemicals, the development of a biosensor for screening insect repellants, bioremediation of oil sands tailings ponds and the fabrication of biohybrid materials for harvesting solar energy.

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Vikramaditya G. Yadav is an Associate Professor in the Department of Chemical & Biological Engineering and the School of Biomedical Engineering at the University of British Columbia (UBC). He is a leading voice on synthetic biology research, education and translation in Canada, and his research program is distinguished by its impact and strong emphasis on technology translation, and his group collaborates with several companies. He is also the Chief Technology Officer of Metabolik Technologies Inc., an environmental biotechnology company, and serves on the boards of InMed Pharmaceuticals and Phytonix Corporation. He is a highly respected educator and currently serves as the Director of the Master of Engineering Leadership program in Sustainable Process Engineering at UBC. He currently serves as an Associate Scientific Advisor for Science Translational Medicine and an Associate Editor of Catalysis in Green Chemistry & Engineering. He was recognized by the CSChE with its Emerging Leader in Chemical Engineering Award in 2017

Mining biotechnology provides sustainable alternatives to traditional mining methods for extracting value from low grade ores and wastes. Moreover, biotechnology can be harnessed to treat (bio)hydrometallurgical and mine waters and decrease the environmental footprint of mining operations. This presentation will give an overview of CSIRO activities in bioleaching and bio-oxidation of low-grade ores, mine wastes and post-consumer wastes such as batteries and electronic wastes. Moreover, studies on removing inorganic and organic contaminants and recovering value from metallurgical effluents will be discussed.

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Anna Kaksonen has about 20 years’ experience in various aspects of biomining, from bio-oxidising and bioleaching low-grade ores to treating waste streams and recovering resources. During her Doctor of Technology degree, she developed fluidized bed reactor processes for biotechnical mine water treatment at Tampere University of Technology (TUT) in Finland. As a Senior Researcher at TUT, she also contributed to the development of heap bioleaching for complex low-grade black schist ores, bioprocesses for excess iron and sulfate removal from barren leach liquors and metal recovery from various metallurgical wastes. In 2009 Anna joined Commonwealth Scientific and Industrial Research Organisation (CSIRO), Australia as a Team Leader of Environmental and Industrial Biotechnology. In 2017 she was appointed as Group Leader for Biotechnology and Synthetic Biology. Anna has delivered projects to a number of companies on base metal and precious metal biomining, as well as biotechnical removal of organic and inorganic impurities from hydrometallurgical process waters. She has also been active in urban mining, developing bioprocesses for the extraction of metals from electronic wastes.

Join CEGSA for their annual Wine and Cheese event. This is a great time for staff, students, and faculty to meet each other at the start of the new academic year while dining on some delicious cheeses, wine, and beer.

Co-hosted with the Institute for Studies in Transdisciplinary Engineering Education and Practice (ISTEP)

Host: Greg Evans

There has been a race to build active learning spaces, and particularly spaces that are heavily technology enabled.  At the University of Toronto there are several major projects of this nature underway or recently completed, including the new Myhal building and the Transforming the Instructional Landscape (TIL) project. There is a general sense that classroom environments of this nature support active learning pedagogies, but to what degree is this supported by the literature and what aspects of the design are important?  In this talk Prof. McCahan will explore the literature that exists on active learning spaces and the design concepts that underpin this trend in classroom construction.  She will also discuss her current research in this area and the gaps in our understanding that need to be investigated to ensure that classrooms enable, rather than hinder, faculty who are implementing high impact teaching practices.

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Susan McCahan is currently the Vice Provost, Innovations in Undergraduate Education and Vice Provost, Academic Programs at the University of Toronto.  She is formerly the Vice Dean, Undergraduate in the Faculty of Applied Science and Engineering.  Her research area is in engineering education and, in particular, in considering engineering education as a designed environment.  Most recently her work has focused on Universal Instructional Design and assessment. She is the past President of the Canadian Engineering Education Association, a Fellow of the American Association for the Advancement of Science and has been the recipient of several major teaching awards including the 3M National Teaching Fellowship and the Medal of Distinction in Engineering Education from Engineers Canada.

Click here for more information on Lectures of the Leading Edge 2019-2020