%0 Journal Article %A Xia, Yan %A Charubin, Kamil %A Marquardt, Drew %A Heberle, Frederick A. %A Katsaras, John %A Tian, Jianhui %A Cheng, Xiaolin %A Liu, Ying %A Nieh, Mu-Ping %D 2016 %T Morphology-Induced Defects Enhance Lipid Transfer Rates %U https://acs.figshare.com/articles/journal_contribution/Morphology-Induced_Defects_Enhance_Lipid_Transfer_Rates/3822894 %R 10.1021/acs.langmuir.6b02099.s001 %2 https://acs.figshare.com/ndownloader/files/5959554 %K lipid transfer %K lipid transfer rate %K nanoparticle stability %K bicelle %K short-chain lipid species %K lipid dissociation energy cost %K Morphology-Induced Defects Enhance Lipid Transfer Rates Molecular transfer %K ULV %K defect %K short-chain lipid molar ratio %X Molecular transfer between nanoparticles has been considered to have important implications regarding nanoparticle stability. Recently, the interparticle spontaneous lipid transfer rate constant for discoidal bicelles was found to be very different from spherical, unilamellar vesicles (ULVs). Here, we investigate the mechanism responsible for this discrepancy. Analysis of the data indicates that lipid transfer is entropically favorable, but enthalpically unfavorable with an activation energy that is independent of bicelle size and long- to short-chain lipid molar ratio. Moreover, molecular dynamics simulations reveal a lower lipid dissociation energy cost in the vicinity of interfaces (“defects”) induced by the segregation of the long- and short-chain lipids in bicelles; these defects are not present in ULVs. Taken together, these results suggest that the enhanced lipid transfer observed in bicelles arises from interfacial defects as a result of the hydrophobic mismatch between the long- and short-chain lipid species. Finally, the observed lipid transfer rate is found to be independent of nanoparticle stability. %I ACS Publications