Mitochondrial targeting by a new class of gadolinium agents. This research project will lead to the development of new molecular agents containing the element gadolinium which can selectively accumulate within cell mitochondria, with a long-term application in cutting-edge therapies involving X-rays or neutrons. The lanthanoid element gadolinium offers many unique opportunities for medicinal chemistry and this project will generate new knowledge in bioinorganic chemistry and synchrotron science. ....Mitochondrial targeting by a new class of gadolinium agents. This research project will lead to the development of new molecular agents containing the element gadolinium which can selectively accumulate within cell mitochondria, with a long-term application in cutting-edge therapies involving X-rays or neutrons. The lanthanoid element gadolinium offers many unique opportunities for medicinal chemistry and this project will generate new knowledge in bioinorganic chemistry and synchrotron science. The expected outcomes of this research will address many of the unresolved questions regarding mitochondrially-targeted gadolinium complexes, the first such agents specifically designed for potential long-term application in binary therapies and imaging.Read moreRead less
Charge-Controlled Materials for Separations of Important Resources. This project aims to develop new porous materials that are capable of greater molecular discrimination than current technologies. This project expects to advance understanding of fundamental structure-activity relationships in these materials, and synthetic targets will be geared towards materials for industrially or environmentally important chemical separations associated with metal extraction. Expected outcomes of this projec ....Charge-Controlled Materials for Separations of Important Resources. This project aims to develop new porous materials that are capable of greater molecular discrimination than current technologies. This project expects to advance understanding of fundamental structure-activity relationships in these materials, and synthetic targets will be geared towards materials for industrially or environmentally important chemical separations associated with metal extraction. Expected outcomes of this project include new insights on the underlying chemistry for tailoring crystalline microporous materials towards select applications. This should provide significant benefits, such as future low-energy and efficient technologies for industrially important separation processes with reduced financial and environmental costs.Read moreRead less