Innovative Projects Realized

Explore thousands of successful projects resulting from collaboration between organizations and post-secondary talent.

29670 Completed Projects

2811
AB
4990
BC
801
MB
663
NL
825
SK
8841
ON
9197
QC
95
PE
568
NB
1088
NS

Projects by Category

The experiences of Indigenous school psychology trainees working with Indigenous communities

To date, there is little understanding of how to adapt school psychology practice to fit the needs of Indigenous populations. This project seeks to understand the current challenges that exist for school psychology practice with Indigenous peoples and what changes are needed to advance the practice. By completing autobiographical studies, Indigenous master’s students-in-training who will be working with First Nations communities and Indigenous students are uniquely positioned to consider how school psychology can better serve the interests of their people. Their reflections on the interests, needs, barriers, and processes they encounter can help to inform most effective-practice for the profession.

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Faculty Supervisor:

Meadow Schroeder;Elisa Lacerda-Vandenborn

Student:

Partner:

Manitoba First Nations Education Resource Centre

Discipline:

Sociology

Sector:

Education

University:

University of Calgary

Program:

Accelerate

Optimization of Bacteriophage Production for use in Treatment and Prevention of Bacterial Diseases in Swine

This project will involve research into the optimal production and purification methods for bacteriophages that are effective against bacterial infections in pigs. Cytophage’s bacteriophages will provide a highly effective, environmentally safe, and a cost competitive alternative to antibiotics in the pork industry. This project will benefit Cytophage by helping to advance our technology and product development.

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Faculty Supervisor:

Deborah Court

Student:

Partner:

Cytophage Technologies

Discipline:

Life Sciences

Sector:

Professional, scientific and technical services

University:

University of Manitoba

Program:

Accelerate

Quantifying the financial benefits of technological solutions for improved water and tailings management

Of the many sustainability issues facing the mining sector, water has emerged as one of the most business critical. This project quantifies the benefits of investing in water and tailings technologies in financial terms in order to identify contextual environments wherein water-related savings make the most economic sense. The outputs of this project will be of direct benefit to the mining sector and the industry partner through providing information needed to justify investments in water-saving technologies and thereby enhance more effective organizational decision-making. The project also provides participating interns with an opportunity to gain direct exposure and experience with one of the world’s largest equipment service and process knowledge suppliers for the mining sector. Furthermore, research outputs will be published in blog pieces, conference presentations and journal publications that will be made publicly available to other companies operating in Canada and beyond.

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Faculty Supervisor:

Nadja Kunz;John Steen

Student:

Partner:

FLSmidth Ltd

Discipline:

Engineering

Sector:

Manufacturing; Mining

University:

The University of British Columbia

Program:

Accelerate

Développement de substituts de terre végétale à partir de matériaux locaux pour la végétalisation de la mine Canadian Malartic

L’exploitation des mines à ciel ouvert entraine souvent un changement du paysage, des horizons et de la structure du sol. L’utilisation de matériaux peu coûteux disponibles sur les sites miniers et dans les environs constitue une alternative pour remédier à la problématique du manque de terre végétale nécessaire végétaliser les parcs à rejets miniers. Les rejets miniers générés sur ces sites sont peu propices à l’installation de la végétation à cause de leur faible teneur en nutriments et de leur structure physique inappropriée. Ce projet a donc pour objectif d’évaluer la capacité de matériaux alternatifs au sol végétal à répondre aux différentes fonctions du sol pour assurer le succès de végétalisation sur diverses zones d’un site minier. Tous matériaux disponibles sur site et dans les environs de la mine susceptibles d’être utilisés pour la végétalisation seront inventoriés et des essais de caractérisation au laboratoire ainsi que des tests de culture seront réalisés. Les résultats attendus de ce projet permettront d’identifier les recettes prometteuses pour végétaliser les parcs à résidus selon différentes zones topographiques.

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Faculty Supervisor:

Marie Guittonny-Larchevêque

Student:

Partner:

Mine Canadian Malartic

Discipline:

Life Sciences

Sector:

Mining

University:

Université du Québec en Abitibi-Témiscamingue

Program:

Accelerate

Concrete Slab-On-Grade Analysis for Slab-Mounted Jib Cranes

Various industries and warehouse operations often need free-standing jib cranes to be installed on the floor. Industrial floors typically consist of unreinforced or very lightly reinforced concrete slabs poured directly on the ground which may not have sufficient strength to support the crane. Improper design may result in severe cracking which raises concrete durability issues or catastrophic collapse which could endanger lives. The project will develop a design software to assist engineers design slab-mounted jib cranes based on an in depth theoretical and numerical study of concrete slab behaviour. This project will help broaden the portfolio and profitability of crane and material handling system manufacturers as well as help a large number of industries that require the use of slab-mounted jib cranes.

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Faculty Supervisor:

Eugene Kim

Student:

Partner:

Engineered Lifting Systems

Discipline:

Engineering

Sector:

Manufacturing

University:

University of Waterloo

Program:

Accelerate

Prevention of noise- and cisplatin-inducedhearing loss by oral administration of theflavonoid-enriched fraction AF4 in mice

Flavonoids are polyphenolic compounds which give fruits and vegetables their bright colours. Habitual
consumption of dietary flavonoids reduces the risk for neurodegenerative disorders such as Parkinson’s
disease, stroke and Alzheimer’s disease. Pre-clinical studies performed using animal models for these
disorders have convincingly demonstrated that flavonoids not only halt the pathological processes
which cause neurodegeneration but also promote recovery after brain damage. These findings and the
fact that flavonoids can be consumed safely even in large amounts suggest they be useful treatments
for neurodegenerative disorders. With this in mind, we have isolated a flavonoid-enriched fraction
from the peel of Nova Scotia apple called AF4. Oral administration of AF4 reduces inflammation,
brain damage and motor deficits in mouse models for stroke and multiple sclerosis. The purpose of the
present application is to determine whether AF4 also reduces the inflammatory and degenerative
events responsible for noise- and cisplatin-induced hearing loss in mice. Hearing loss is a frequent
complication of cisplatin…TOBECONT’D…

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Faculty Supervisor:

George Robertson

Student:

Partner:

Scotia Biosciences

Discipline:

Life Sciences

Sector:

University:

Dalhousie University

Program:

Accelerate

Genes to affordable medicines – Stream 1-B1

The Structural Genomics Consortium (SGC) is a not-for-profit public-private partnership research organization that aims to accelerate the discovery of new medicines through open science. This Mitacs cluster will bring together SGC’s industry and academic collaborators to work together towards new and affordable medicines for challenging diseases. Sixty-three post-doctoral fellows will spend 2-3 years developing open source tools and knowledge for previously understudied proteins, thereby unlocking new areas of biology and identifying new opportunities for drug discovery. SGC’s spin-offs, the M4 companies, will be the vehicles to translate this knowledge into new medicines for rare and challenging diseases that have been excluded from traditional pharma company programs. The M4 companies are committed to open science and sharing, and to affordable pricing to ensure patients can access the new drugs.

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Faculty Supervisor:

Cheryl Arrowsmith;Mahmoud Pouladi

Student:

Partner:

Structural Genomics Consortium

Discipline:

Life Sciences

Sector:

Professional, scientific and technical services

University:

The University of British Columbia; University of Toronto

Program:

Accelerate

Genes to affordable medicines – Stream 1-A2

The Structural Genomics Consortium (SGC) is a not-for-profit public-private partnership research organization that aims to accelerate the discovery of new medicines through open science. This Mitacs cluster will bring together SGC’s industry and academic collaborators to work together towards new and affordable medicines for challenging diseases. Sixty-three post-doctoral fellows will spend 2-3 years developing open source tools and knowledge for previously understudied proteins, thereby unlocking new areas of biology and identifying new opportunities for drug discovery. SGC’s spin-offs, the M4 companies, will be the vehicles to translate this knowledge into new medicines for rare and challenging diseases that have been excluded from traditional pharma company programs. The M4 companies are committed to open science and sharing, and to affordable pricing to ensure patients can access the new drugs.

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Faculty Supervisor:

Jinrong Min;Mark Lautens;Masoud Vedadi;Matthieu Schapira;Cheryl Arrowsmith;Dalia Barsyte-Lovejoy;Robert A. Batey;Brian Raught

Student:

Partner:

Structural Genomics Consortium

Discipline:

Life Sciences

Sector:

Professional, scientific and technical services

University:

University of Toronto

Program:

Accelerate

Random bin picking with industrial robot

Materials with different sizes, shapes, or materials come into the process every day, they need to be sorted, placed, and usually fed into a machine for processing. Traditionally, this task is very hard to be automated because of the non-fixed position of the part and frequent part changes. For this random bin picking project, we are targeting to build a solution that can pick and place the part from a box with the aid of the latest computer vision technologies. We will be looking into find ways to create a model for any random part, match the part in the clustered point cloud, and retrieve the part’s precise location in the 3D spaces.

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Faculty Supervisor:

Jiannan Wang

Student:

Partner:

DaoAI Robotics Inc

Discipline:

Computer science

Sector:

Professional, scientific and technical services

University:

Simon Fraser University

Program:

Accelerate

Efficacy and feasibility of online cognitive training platforms for older adults with subjective cognitive complaints: A randomized controlled trial

With an aging population on the rise, the prevalence of cognitive decline is expected to increase substantially. Goal Management Training® (GMT) and the Memory and Aging Program® (MAP) are cognitive interventions that have been studied extensively and applied clinically to address these needs. Although previous research has demonstrated efficacy of the in-person versions of both MAP and GMT, significant barriers exist in the utilization of these programs. In light of these challenges, online versions of MAP and GMT have recently been developed. The current project aims to evaluate if online versions of MAP and GMT are successful at improving cognitive functioning, cognitive complaints, and the impact of cognitive concerns on daily functioning. Findings will be used for knowledge dissemination and will aid in the commercialization of these evidence-based online cognitive interventions.

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Faculty Supervisor:

Alexandra J Fiocco

Student:

Partner:

Cogniciti

Discipline:

Life Sciences

Sector:

Health and Related Sciences & Technology; Professional, scientific and technical services

University:

Toronto Metropolitan University

Program:

Accelerate

Point-of-Need Microfluidic Biosensor for Detecting Airborne Viruses using Molecularly Imprinted Polymers: Towards COVID 19 Virus Monitoring

This project is a partnership between York University and Sixth Wave Innovation Inc. (SIXW). The goal of this partnership is to develop components of a portable and low-cost technology for rapid and on-site air sampling and detection of aerosol viruses in indoor and outdoor environments. Virus capturing will be done by Molecularly Imprinted Polymers (MIPs) under the extensive expertise of the partner company. MIPs are robust materials with pre-made nano-cavities that can capture target objects such as viruses in this project. For this, MIP-based nanoparticles for microwire coating and surface immobilization of viruses will be designed and optimized. MIP-virus conjugation will be investigated in microfluidic devices. Finally, on-chip virus capturing, tagging with detection labels, and quantitative detection will be performed electrically. This project will result in innovative scientific research, mobilization of research from conception to proof of concept stage, and lab-scale development and integration of sample preparation and virus detection devices. These integrated sample preparation and detection systems will be portable, easy to operate, and sensitive for future use by inspectors, businesses, hospitals, special care centers, and police force involved in decision-making to address various challenges associated with airborne pathogen outbreaks and pandemics.

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Faculty Supervisor:

Pouya Rezai;Satinder Kaur Brar

Student:

Partner:

Sixth Wave

Discipline:

Engineering

Sector:

Manufacturing

University:

York University

Program:

Accelerate

Passive Airborne Sensor Platform

In disaster scenarios involving airborne contaminants, where the dispersal of toxic agents can impact human lives, first responders require fast and accurate dispersal trajectory information. Existing methods that detect the local presence of an agent do not provide insight towards dispersal trajectory, and long range spread is either simulated with sparse reference data or measured long after the dispersion is complete. The lightweight and porous form of the milkweed seed offers natural inspiration for a novel sensor platform. In addition to investigating the market potential for the passive airborne sensor platform, the objective of the project is to quantify the effect of porosity on the response of the sensor platform to rapid changes in wind speed. Understanding how porosity affects the capability of the sensor platform to passively track the flow will assist in scaling the sensor platform design to meet the needs of potential customers.

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Faculty Supervisor:

David Rival

Student:

Partner:

Springboard Atlantic Inc.

Discipline:

Engineering

Sector:

Technology; Aerospace; Public Service, Policy, and Governance

University:

Queen's University

Program:

Accelerate

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