It’s that time of the year again – Join BioZone for an afternoon of exciting student research presentations, 3MTs and poster sessions.
Get to know what labs in BioZone are doing. Pizza will be provided after the event for people who register on Eventbrite.
RON WEISS
Massachusetts Institute of Technology
Mammalian Synthetic Biology: Foundation and Therapeutic Applications
Synthetic biology is revolutionizing how we conceptualize and approach the engineering of biological systems. Recent advances in the field are allowing us to expand beyond the construction and analysis of small gene networks towards the implementation of complex multicellular systems with a variety of applications. In this talk I will describe our integrated computational / experimental approach to engineering complex behavior in a variety of cells, with a focus on mammalian cells. In our research, we appropriate design principles from electrical engineering and other established fields. These principles include abstraction, standardization, modularity, and computer aided design. But we also spend considerable effort towards understanding what makes synthetic biology different from all other existing engineering disciplines and discovering new design and construction rules that are effective for this unique discipline. We will briefly describe the implementation of genetic circuits and modules with finely-tuned digital and analog behavior and the use of artificial cell-cell communication to coordinate the behavior of cell populations. The first system to be presented is a multi-input genetic circuit that can detect and destroy specific cancer cells based on the presence or absence of specific biomarkers in the cell. We will also discuss preliminary experimental results for obtaining precise spatiotemporal control over stem cell differentiation for tissue engineering applications. We present a novel approach for generating and then co-differentiating hiPSC-derived progenitors with a genetically engineered pulse of GATA-binding protein 6 (GATA6) expression. We initiate rapid emergence of all three germ layers as a combined function of GATA6 expression levels and tissue context. We ultimately obtain a complex tissue that recapitulates early developmental processes and exhibits a liver bud-like phenotype that includes haematopoietic and stromal cells, as well as a neuronal niche. This complex organoid can be used for drug development and potentially for tissue transplantation.
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RON WEISS is Professor in the Departments of Biological Engineering and of Electrical Engineering and Computer Science at MIT, and is the Director of the Synthetic Biology Center. Professor Weiss is one of the pioneers of synthetic biology, and has been engaged in synthetic biology research since 1996 when he was a graduate student at MIT. After completion of his PhD, Weiss joined the faculty at Princeton University, and then returned to MIT in 2009 to take on a faculty position. The research pursued by Weiss since those early days has placed him in a position of leadership in the field, as evidenced both by publications from his lab as well as a variety of awards and other forms of recognition. He pursued several aspects of synthetic biology, including synthesis of gene networks engineered to perform in vivo analog and digital logic computation. The Weiss lab also published seminal papers in synthetic biology focused on programming cell aggregates to perform coordinated tasks using engineered cell-cell communication with chemical diffusion mechanisms such as quorum sensing. Several of these manuscripts were featured in a recent Nature special collection of a select number of synthetic biology papers reflecting on the first 10 years of synthetic biology. While work in the Weiss lab began mostly with prokaryotes, during the last 5 years a majority of the research in the lab shifted to mammalian synthetic biology. The lab focuses both on foundational research, e.g. creating general methods to improve our ability to engineering biological systems, as well as pursuing specific health related applications where synthetic biology provides unique capabilities.
Download the lecture poster HERE
For more information on Lectures at the Leading Edge 2018-19 click HERE
MANOS MAVRIKAKIS
University of Wisconsin – Madison
Reaction Mechanisms and Structure Sensitivity for Heterogeneous Catalyst Discovery from First-Principles
First-principles calculations have emerged as a key contributor towards the fundamental understanding of heterogeneous catalysis and the educated discovery of improved catalytic materials. By choosing the example of formic acid (HCOOH) decomposition on transition metals and alloys, we demonstrate how a deep mechanistic understanding of selective versus unselective routes can help with designing more selective catalysts. HCOOH is a simple molecule that is an abundant product of biomass processing and can serve as an internal source of hydrogen for oxygen removal and upgrading of biomass to chemicals and fuels. In addition, HCOOH can be used as a fuel for low temperature direct fuel cells. We start by presenting a systematic study of the HCOOH decomposition reaction mechanism starting from first-principles and including reactivity experiments and microkinetic modeling. In particular, periodic self-consistent Density Functional Theory (DFT) calculations are performed to determine the stability of reactive intermediates and activation energy barriers of elementary steps. Mean-field microkinetic models are developed and calculated reaction rates, orders, etc are then compared with experimentally measured ones. These comparisons provide useful insights on the nature of the active site, most-abundant surface intermediates as a function of reaction conditions and feed composition. Trends across metals on the fundamental atomic-scale level up to selectivity trends will be discussed. Finally, we identify from first-principles alloy surfaces, which may possess better catalytic properties for selective dehydrogenation of HCOOH than monometallic surfaces, thereby guiding synthesis towards promising novel catalytic materials. Time-permitting, we may discuss novel catalyst design for the efficient electrocatalytic oxidation of HCOOH.
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MANOS MAVRIKAKIS is the Paul A. Elfers Professor and the Vilas Distinguished Achievement Professor of Chemical Engineering at UW-Madison. He received a Diploma in Chemical Engineering from NTUA in Greece, and a MS in Applied Math, and a PhD in Chemical Engineering & Scientific Computing from the University of Michigan, Ann Arbor. Following a postdoc at U of Delaware and another one at the Technical University of Denmark, he joined the Chemical Engineering faculty at UW-Madison in 1999. His main research interests include the elucidation of detailed reaction mechanisms for heterogeneously catalyzed reactions and the identification of improved catalytic materials from first-principles-based microkinetic modeling. Manos was elected to APS Fellow in 2013, AAAS Fellow in 2014, and AVS Fellow in 2016. He received the 2009 Paul H. Emmett award in Fundamental Catalysis from the North American Catalysis Society, and the 2014 R. H. Wilhelm Award in Chemical Reaction Engineering from AIChE. In 2017, he received the G. Parravano Memorial Award for Excellence in Catalysis Research by the Michigan Catalysis Society. His work has been cited >18,500 times (WoS). Manos served as his Department Chair between 2015-2018. He currently serves on the editorial board of: ACS Catalysis, AIChE Journal, ChemPhysChem, Journal of Molecular Catalysis A: Chemical, Catalysis Today, and he is the editor-in-chief of Surface Science.
Download the lecture poster HERE
For more information on Lectures at the Leading Edge 2018-19 click HERE
Co-hosted with the Institute for Water Innovation (IWI)
JOHN LIENHARD
Massachusetts Institute of Technology
THERMODYNAMICS AND TRANSPORT IN DESALINATIONSYSTEMS ENGINEERING
The world’s renewable fresh water supply may be considered to be the difference between precipitation over land and evaporation; and this supply is essentially fixed while world population has risen sharply and the water demands of growing economies continue to rise. As a result, water scarcity is an increasing problem throughout the world, with water shortages impacting both rural and urban populations and with substantial environmental damage as a result of water diversions for human use.
Desalination has been deployed worldwide to expand the supply of freshwater, especially for coastal populations, and its use has increased rapidly, with roughly 90 million m3/day of capacity now installed. The cost and lifetime of plants has also improved steadily. But concerns remain about the energy consumption and costs of desalination. In this talk, we will discuss research directed at understanding the causes of energy inefficiency in various desalination processes and efforts to adapt concepts from thermal systems engineering to improve the design of both thermal and membrane desalination systems. Topics to be discussed include thermodynamic and heat and mass transfer phenomena in various desalination technologies, with examples drawn from reverse osmosis, humidification-dehumidification, forward osmosis, membrane distillation, and the remediation wastewater from oil and gas production. Prospects for renewable energy integration will also be considered.
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JOHN LIENHARD is the Abdul Latif Jameel Professor of Water at MIT. During three decades on the MIT faculty,Lienhard’s research and educational efforts have focused on heat and mass transfer, water purification and desalination, and thermodynamics. Lienhard received his bachelors and masters degrees in thermal engineering at UCLA from the Chemical, Nuclear, and Thermal Engineering Department. He joined MIT immediately after completing his PhD in the Applied Mechanics and Engineering Science Department at UC SanDiego. Lienhard’s research on desalination has included humidification-dehumidification, membrane distillation, forward and reverse osmosis, nanofiltration, electrodialysis, management of high salinity brines, fouling, energy efficiency, and remediation of wastewater from oil/gas operations. Lienhard has directly supervised more than 85 graduate theses and postdoctoral associates, and he is the author of 200 peer-reviewed publications and three textbooks. In addition, he holds more than 40 US Patents and pending applications, many of which have been commercialized in the water industry. Lienhard is a recipient of the 2012 ASME Globalization Medal and the 2015 ASME Heat Transfer Memorial Award. Lienhard and his students have received thirteen best paper and poster awards for their desalination research over the past seven years.
Download the lecture poster HERE
For more information on Lectures at the Leading Edge 2018-19 click HERE
Wednesday, January 30th is Bell Let’s Talk Day; a charitable program dedicated to the promotion, support, and destigmatization of mental health across Canada. The Department of Chemical Engineering & Applied Chemistry will be participating in this event by hosting drop-in mental health and de-stress activities in WB116 from 12pm-2pm, including:
- Photo station – Bell will donate 5 cents per photo we post with their filter or hashtag
- Mindful cookie eating
- Conflict corner – chat about grad student problems facilitated by a rep from the Conflict Resolution Centre
- Mental health mural and colouring station
- Free pizza upon participating in 1 of the activities
Other ways to participate:
- Post from your facebook/twitter/instagram/snapchat with the Bell Let’s Talk filter or #BellLetsTalk (we will have reps around the building to take pictures too)
- If Bell is your phone service provider, send a text or make a call
- Watch videos on their website
- Talk about it! This is the best way to promote awareness and destigmatize mental health issues
Any questions or concerns can be directed to: cegsa.chemeng@gmail.com
Emily Moore
Director, Troost Institute for Leadership Education in Engineering (ILead)
Mine water treatment is a complex challenge which requires a combination of specialist chemical engineering knowledge with an integrated, multi-disciplinary approach. Tightening legislative requirements and emerging contaminants present new challenges which are driving more sites to tertiary water treatment systems. While new technologies show promise, there are considerable challenges to implementation resulting in significant operating and capital costs. Integrated water management (IWM) is a holistic approach to minimizing water use and contamination across the entire site, and when implemented well can reduce treatment requirements and costs. IWM presents a wonderful teaching opportunity for context-based decision making and introducing environmental considerations.
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Emily Moore is the new Director of the Troost Institute for Leadership Education in Engineering (ILead), joining UofT after over 20 years in industry. Emily spent the first half of her career at the Xerox Research Center of Canada (XRCC) in scale-up engineering, then in 2008 joined Hatch Limited as director of technology development, later serving as managing director for water and for innovation. In 2011 Emily was elected president of the Canadian Society for Chemical Engineering and has served on numerous committees of the Natural Sciences and Engineering Research Council of Canada. Her leadership in industry has been recognized by the Society for Chemical Industry Canada, and by Women in Mining, who named her one of 100 Global Inspirational Women in Mining 2016.
Emily earned a bachelor’s degree in engineering chemistry from Queen’s University and is a licensed professional engineer. She was named a Rhodes Scholar and completed her doctorate in physical chemistry at Oxford University.
The Association for Leadership in Chemical Engineering (AlChemE) will be holding its annual Ace the Interview Night on Wednesday, March 6, 2019 at 6 pm in WB 238.
The annual “Ace the Interview Event” which provides undergraduate students with the confidence and interview experience to help them succeed in their search for PEY, summer and post-graduate job opportunities.
As in previous years, we will present 5 mock jobs to students who will then choose to apply to one of them. They will create a resume and cover letter for this job and we will send it to you for review before the interview date. We will also provide you with the mock job descriptions of the students you will be interviewing so you can prepare interview questions beforehand.
Please respond as soon as possible to the google form posted below to participate in this alumni outreach/mentorship event.
https://docs.google.com/forms/d/e/1FAIpQLSfTRSgNjlpxNdyrJWpKd8ibSwcxdxVeh9SCjpPT44pHzYdsKQ/viewform
If you have any questions about the event, feel free to email us at z.gao@mail.utoronto.ca or purushoth.thavendran@mail.utoronto.ca.
Emission of CO2, a byproduct from many industrial processes and power plants, has increased with increasing energy demand and growing population. Most of the efforts to chemically reduce CO2 requires the use of H2. This is not desirable because at present ~95% of H2 is generated from hydrocarbon-based feedstock, producing CO2 as a byproduct. In this talk we will first give a brief summary on CO2 conversion by H2, followed by discussing our recent efforts in converting CO2 by light alkanes, such as ethane, via the dry reforming pathway to produce synthesis gas (C2H6 + 2CO2 → 4CO + 3H2) or the oxidative dehydrogenation route to generate ethylene (C2H6 + CO2 → C2H4 + CO + H2O). Using a combination of kinetic studies, in situ characterization and DFT calculations, we have identified several classes of catalysts that can activate both CO2 and light alkanes (C2-C4) to achieve selective dry reforming or oxidative dehydrogenation. Finally, we will discuss potentially reducing CO2 emission by alternative pathways for N2 transformations, which are currently the most CO2-emitting chemical processes.
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Jingguang Chen is the Thayer Lindsley Professor of chemical engineering at Columbia University, with a joint appointment as a senior chemist at Brookhaven National Laboratory. He received his BS degree from Nanjing University and PhD degree from the University of Pittsburgh. He then carried out his Alexander von Humboldt postdoctoral research in KFA-Julich in Germany. After spending several years as a staff scientist at Exxon Corporate Research Laboratories, he started his academic career at the University of Delaware in 1998 and rose to the rank of the Claire LeClaire Professor of
chemical engineering and the Director of the Center for Catalytic Science and Technology. He moved to Columbia University in 2012. He is the co-author of 23 United States patents and over 380 journal
publications that have been cited over 25,000 times. He is currently the President of the North American Catalysis Society and an Associate Editor of ACS Catalysis. He received many catalysis awards, including the 2015 George Olah award from the American Chemical Society and the 2017 Robert Burwell Lectureship from the North American Catalysis Society.
Co-hosted with the Ontario Centre for the Characterisation of Advanced Materials (OCCAM)
IAN GILMORE
National Physical Laboratory, UK
Metabolic Imaging at the Single-Cell Scale: Recent Advances and Future Challenges in Mass Spectrometry Imaging
Super-resolution optical microscopy using fluorescent labels has been transformational in allowing the machinery of life, e.g. proteins, to be seen at the nanoscale. There is a great desire in the life-sciences to achieve this level of insight for metabolites. This will allow unprecedented ability to understand rewiring of metabolic networks involved in disease, understanding of the uptake of drugs in cells and construct mechanistic understanding in fundamental biology. However, this is a monumental challenge since fluorescent labelling strategies cannot be used because of the dynamic processes in the creation of metabolites and because the fluorescent labels themselves radically alter the chemistry of the metabolite.
Mass spectrometry allows label-free (or with stable isotope labelling) identification of endogenous and exogenous (e.g drugs) metabolites and when combined with high-resolution ion beams in secondary ion mass spectrometry (SIMS) allows sub-cellular resolution imaging. Substantial barriers need to be overcome to achieve a super-resolution goal (< 250 nm) including increasing sensitivity, increasing specificity (accurate identification of molecules), sample preparation methodologies (e.g. cryo-SIMS) and improvements in ion beam resolution. This lecture will review our research at NiCE-MSI using three SIMS instrument types; ToF-SIMS, 3D OrbiSIMS and a CAMECA NanoSIMS 50L and place this in context with complementary methods such as AP-SMALDI.
Many metabolites are of low mass (e.g. dopamine) and are in a highly congested region of the mass spectrum. Here, ToF-SIMS is inadequate to resolve the peaks especially at high-spatial resolution. We have led the development of a powerful new hybrid instrument, the 3D OrbiSIMS, combining an OrbitrapTM-based Thermo ScientificTM Q ExactiveTM HF instrument and a dedicated ToF-SIMS 5. The instrument is equipped with high-resolution ion beams including a new micron resolution argon cluster ion beam for biomolecular imaging and 3D analysis of organics and an ultra-high resolution Bi cluster focussed ion beam with < 100 nm resolution. We demonstrate the unparalleled ability for 2D and 3D metabolite imaging with sub-cellular resolution.
For imaging at the organelle scale, e.g. mitochondria and lysosomes, then a resolution of 50 nm or better is needed. This is achieved with the CAMECA NanoSIMS 50L. Normally, the solvent based sample preparation procedures used wash out drug molecules. We have developed a method that traps molecules within the organelles and use this to demonstrate the first direct evidence of drug induced phospholipidosis caused by amiodarone uptake in rat alveolar macrophages.
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IAN GILMORE is a Senior NPL Fellow in Surface & Nanoanalysis and a Visiting Professor in the School of Pharmacy at the University of Nottingham.
His research focus is on the analysis of molecules at surfaces and interfaces in a wide range of sciences, including the intracellular distribution of pharmaceuticals, drug delivery systems, medical devices, organic electronics and devices using 2D materials.
Ian has recently launched a UK National Centre of Excellence in Mass Spectrometry Imaging (NiCE-MSI). This world-class centre has over 15 staff scientists who are experts in the three principal techniques: secondary ion mass spectrometry (SIMS); ambient mass spectrometries (AMS); and matrix assisted laser desorption ionisation (MALDI MS).
The aims of NiCE-MSI are to advance the fundamentals of the techniques and innovate measurement capabilities; establish metrology for reliability and standardisation; and support the uptake of the techniques in industry and academia. For example, Ian is leading a major new project, 3D nanoSIMS, in collaboration with GlaxoSmithKline, to create the next generation SIMS instrument for label-free imaging of drugs in cells with a spatial resolution at the organelle scale.
He has authored and co-authored over 100 papers on surface analysis and co-edited the popular teaching book ‘Surface Analysis – The Principal Techniques’.
Ian is a Fellow of the Institute of Physics (UK) and was awarded the Institute’s Paterson Medal (2004) for his innovation of G-SIMS. He is a Fellow of the American Vacuum Society, a major science and technology society in the USA, and served on the Board of Directors in 2013-14 where he led the development of the Society’s strategy.
Ian has made a major contribution to international leadership in surface analysis, recognised by the Rivière Prize in 2013 from the UK Surface Analysis Forum. He is chair of the International SIMS conference series and is chairing a Royal Society Scientific Meeting on Mass Spectrometry Imaging in 2015. He has previously successfully co-chaired the SIMS XV international conference (Manchester, 2005) and chaired the IUVSTA workshop on sputtering and ion emission by cluster ion beams (Scotland, 2007).
Ian provides leadership in international standardisation through chairing the committee for SIMS in ISO TC 201 and he is chair of VAMAS for surface chemical analysis, which conducts interlaboratory studies in electron spectroscopies, scanning probe microscopies and mass spectrometries to advance the techniques, support uptake into industry and standardisation.
Download the lecture poster HERE
For more information on Lectures at the Leading Edge 2018-19 click HERE
Topics for discussion:
1. Courses
2. financial literacy
3. general feedback
Is there a need for financial literacy seminars? What’s missing from ChemE’s curriculum? What are the main obstacles standing in the way of completing your research? What other issues should we be focusing on?
HAVE YOUR SAY AND EAT FOR FREE!