Protein and Drug Design Algorithms Using Improved Biophysical Modeling
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2016
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This thesis focuses on the development of algorithms that will allow protein design calculations to incorporate more realistic modeling assumptions. Protein design algorithms search large sequence spaces for protein sequences that are biologically and medically useful. Better modeling could improve the chance of success in designs and expand the range of problems to which these algorithms are applied. I have developed algorithms to improve modeling of backbone flexibility (DEEPer) and of more extensive continuous flexibility in general (EPIC and LUTE). I’ve also developed algorithms to perform multistate designs, which account for effects like specificity, with provable guarantees of accuracy (COMETS), and to accommodate a wider range of energy functions in design (EPIC and LUTE).
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Hallen, Mark Andrew (2016). Protein and Drug Design Algorithms Using Improved Biophysical Modeling. Dissertation, Duke University. Retrieved from https://hdl.handle.net/10161/12120.
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