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2024

Conference Publication

Mending achy-breaky hearts: cyclic peptide TL01 is an enhancer of cardiac intracellular protein-protein interactions and promotes heart contractility

Rojas-Azofeifa, Daniela, Passioura, Toby, McMillen, Timothy, Cheesman, Elisabeth, Saez, Natalie, Chow, Jonathan, Eagles, David, Norman, Alexander, Perry, Matthew, Molenar, Peter, Regnier, Michael, King, Glenn and Palpant, Nathan (2024). Mending achy-breaky hearts: cyclic peptide TL01 is an enhancer of cardiac intracellular protein-protein interactions and promotes heart contractility. 37th European Peptide Symposium 14th International Peptide Symposium, Florence, Italy, 25-29 August 2024. Oxford, United Kingdom: John Wiley & Sons.

Mending achy-breaky hearts: cyclic peptide TL01 is an enhancer of cardiac intracellular protein-protein interactions and promotes heart contractility

2018

Conference Publication

The use of peptide-membrane interactions in the design of selective and potent sodium channel inhibitors

Schroeder, Christina, Agwa, Akello, Mueller, Alexander, Chow, Chun Yuen, Peigneur, Steve, Lawrence, Nicole, Deplazes, Evelyne, Mark, Alan, Craik, David, Tytgat, Jan, King, Glenn, Vetter, Irina and Henriques, Sonia Troeira (2018). The use of peptide-membrane interactions in the design of selective and potent sodium channel inhibitors. 35th European Peptide Symposium, Dublin City University, Ireland, 26-31 August 2018. Oxford, United Kingdom: John Wiley & Sons.

The use of peptide-membrane interactions in the design of selective and potent sodium channel inhibitors

2017

Conference Publication

Novel Human Eag Channel Antagonists from Spider Venoms

Ma, Linlin, Chin, Yanni K., Dekan, Zoltan, Ikonomopoulou, Maria, Herzig, Volker, Chow, Chun Yuen, Alewood, Paul and King, Glenn F. (2017). Novel Human Eag Channel Antagonists from Spider Venoms. 58th Annual Meeting of the Biophysical-Society, San Francisco, CA, United States, 15-19 February 2014. St. Louis, MO 63146 United States: Cell Press. doi: 10.1016/j.bpj.2016.11.1800

Novel Human Eag Channel Antagonists from Spider Venoms