Grants and Contributions:

Grant or Award spanning more than one fiscal year. (2017-2018 to 2022-2023)

Global production of petroleum-derived plastics is in excess of 310 million metric tonnes. Significant amounts (22% to 43%) of these non-biodegradable plastic materials are disposed of in municipal land-fill sites and million tonnes per year of plastic materials are accumulating in the oceans and pose a significant threat to ocean ecosystems. There is a growing market pull for renewable and biodegradable polymeric products, both in Canada and internationally, to reduce our dependence on non-biodegradable, petroleum-based polymers. Bio-based, biodegradable plastics offer great potential to displace non-degradable polymers for many commercial applications. The overall objective of my research program is to create and characterize novel medium chain-length poly-3-hydroxyalkanoate (mcl-PHA) polymers synthesized by bacteria that are tailored to specific novel applications. The sub-unit composition of these polymers determines their physical and thermal properties, which in-turn determines the specific uses. Microbially synthesized PHA polymers are both biodegradable and biocompatible, and have great potential as alternative source of polyester polymers for a wide variety of industrial applications, such as bioresins in biocomposite materials, as biodegradable packaging films, 3-D printing of biodegradable plastic components as scaffolds for tissue engineering, and/or as capsules for slow release of pharmaceuticals. The proposed research will combine the use of genetic engineering and bioprocess engineering approaches to induce the microbial synthesis of PHA polymers with novel subunit composition from low cost, renewable sources. We will characterize the physical and thermal properties of these polymers, modifying the polymers to create novel physical and/or thermal properties suitable for high-value applications. The proposed research will support four PhD students and eight undergraduate students who will acquire advanced skills in molecular biology, bioprocess engineering, and material sciences. This research will open new fields of study and drive innovation that will focus on the development of new products and applications (i.e. renewable food packaging, tissue engineering scaffolds, biodegradable wound dressings, biocompatible implants, etc.). Both the European Union and the United States of America have developed bio-economy strategies with a clear focus on innovation for environmental sustainability. To remain competitive in the global bioeconomy, Canada must remain at the leading edge of innovation, using biotechnology and bioprocess engineering to develop novel polymers for industrial applications.