Atomistic study of zwitterionic peptoid antifouling brushes
Cheung, David L. Lau, King Hang Aaron
Cheung, David L.
Lau, King Hang Aaron
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Publication Date
2018-08-24
Type
Article
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Citation
Cheung, David L., & Lau, King Hang Aaron. (2018). Atomistic Study of Zwitterionic Peptoid Antifouling Brushes. Langmuir. doi: 10.1021/acs.langmuir.8b01939
Abstract
Using molecular dynamics (MD) simulations, we study the molecular behavior and hydration properties of a set of zwitterionic peptoid brushes, grafted on a rutile surface, that has been previously reported to exhibit excellent resistance against protein adsorption and cell attachment. Peptoids are novel poly(N-substituted glycine) peptide mimics with sidechains attached to amide nitrogens. They constitute a unique model polymer system because hundreds of sidechains have been demonstrated, and the exact chain length and sequence order of the residues/monomers may be specified in experiments. In this report, we vary the brush grafting density as well as the sidechain/polymer molecular volume. We include in our study polysarcosine as an uncharged comparison with a small polymer chain cross-section. Sarcosine is the simplest peptoid residue with only a nominally hydrophobic methyl group as sidechain but is also reported to exhibit high antifouling performance. Overall, we show in detail how molecular volume and hydration effects are intertwined in a zwitterionic polymer brush. For example, the zwitterionic design significantly promotes extended chain conformations and could actually lower the overall electrostatic potential. Some properties promoted by the balanced charges, such as chain flexibility and hydration, increase more prominently at low to intermediate chain densities. These and other observations should provide insight on the molecular behavior of peptoids and inform the design of zwitterionic antifouling polymer brushes.
Publisher
American Chemical Society
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Attribution-NonCommercial-NoDerivs 3.0 Ireland