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Dr. Audrey Moores
McGill University
Mechanochemistry and aging-based methods as novel tools to transform biopolymers into high value materials
Wednesday, September 25, 2024
SSB 7172 @ 3:30 p.m.
Host: Dr. Byron Gates
Abstract
Chitin, the second most abundant biopolymer after cellulose, is present in the shell of crustaceans, in the cuticle of insect and even in some fungi.1 It can be converted into chitosan, a highly praised material with application as a fertilizer, water treatment flocculant, biomedical fibers and food additive. Yet today's technologies for chitin extraction and chitosan production rely on the use of corrosive treatments, high energy input and large quantities of by product effluents. Herein I am presenting my group's effort to tackle this question, through the use of solvent-free methods, and the road map we have established to access several exciting added-value polymers and nanomaterials. Mechanochemistry is becoming an established method for the sustainable, solid-phase synthesis of scores of nanomaterials and molecules, ranging from active pharmaceutical ingredients to materials for cleantech.2 Beyond its ability to trigger reactivity through energy delivery to chemical systems, mechanochemistry is also a way to activate precursors and mix reagents that may react further in a subsequent aging phase.3 We showed that mechanochemistry and aging could be used effectively for the deacetylation of chitin using solid NaOH as reagent.4 This process yielded high molecular weight chitosan with minimal use of energy and solvent. We have also explored the possibility to reduce the molecular weight of chitosan via mechanochemical and aging-based acid treatment.6 Moving upstream, we have explored the extraction of chitin from crustacean shells, and demonstrated effective extraction of high quality chitin using milling with various solid acids.5 Chitin, like cellulose, is a crystalline material, granting access to nanocrystals via acid or oxidative partial hydrolysis.1 Classic methods being water and chemical intensive, we have developed a mechanochemical version, in which aging done under high humidity in a shaker was needed to afford high yields of excellent quality chitin nanocrystals.7 This method can be extended to cellulose nanocrystals synthesis. Finally, we have also extended the use of mechanochemistry to the fabrication of chitosan nanocrystals from chitin nanocrystals.8 We developed hydrogels from chitosan and chitin nanocrystals, with exceptional gelling properties and demonstrated their applicability for slow drug release.
- T. Jin, T. Liu, E. Lam, A. Moores, Nanoscale Horiz. 2021, 6, 505-542
- J.-L. Do, T. Fri禳i, ACS Cent. Sci. 2017, 3, 1, 1319
- M. J. Cliffe, C. Mottillo, R.S. Stein, D.-K. Buar, T. Fri禳i, Chem. Sci., 2012, 3, 2495-2500
- T. Di Nardo, C. Hadad, A. Nguyen Van Nhien, A. Moores, Green Chem. 2019, 21, 3276-3285
- F. Hajiali, J. L. Vidal, T. Jin, L. de la Garza, M. Santos, G. Yang, A. Moores, ACS Sustainable Chem. Eng. 2022, 10, 34, 1134811357.
- G. Yang, E. Lam, A. Moores, ACS Sustainable Chem. Eng. 2023 11 (20), 7765-7774
- T. Jin, T. Liu, F. Hajiali, M. Santos, Y. Liu, D. Kurdyla. S. Regnier, S. Hrapovich, E. Lam, A. Moores, Angew. Chem. Int. Ed. 2022, 61 (42), e202207206
- T. Jin, T. Liu, S. Jiang, V. Michaelis, D. Kurdyla, B.A. Klein, E. Lam, J. Li, A. Moores, Green Chem. 2021, 23, 6527-6537
Biography
Audrey Moores is a Full Professor of Chemistry and associate director of the Facility for Electron Microscopy Research (FEMR) at McGill University.
She completed her PhD from the Ecole Polytechnique, France in 2005, under the supervision of Prof. Pascal Le Floch and received the Best Thesis award of the Ecole Polytechnique that year. She was a post-doctoral fellow at Yale University in 2006 under the guidance of Prof. Robert H. Crabtree, funded by a Lavoisier fellowship from the European Union.
She serves as an executive editor for ACS Sustainable Chemistry & Engineering. In 2020, she became a member of the College of New Scholars, Artists and Scientists of the Royal Society of Canada, which is the junior body of the equivalent to a Canadian Academy of Science, and was elected President-Elect in 2023. Between 2007 and 2017, she held a Canada Research Chair in Green Chemistry. In 2019 she received a Fessenden Professorship awarded by the faculty of science at McGill University towards the commercial development of the clean transformation of crustacean shells into chitosan. In 2021 she received the Canadian Chemistry and Chemical Engineering Award for Green Chemistry. She was also a university-funded visiting professor at the University of Tokyo from January to June 2024. With her group, she focuses on sustainable solutions for nanoparticles and biopolymer synthesis as well as catalyzed reactions, with an interest in waste biomass valorization, earth abundant starting materials and high atom economy. In 2024, she chaired the Gordon Research Conference in Green Chemistry.