Curvature-regulated lipid membrane softening of nano-vesicles
The physico-mechanical properties of nanoscale lipid vesicles (e.g., natural nano-vesicles and artificial nano-liposomes) dictate their interaction with biological systems. Understanding the interplay between vesicle size and stiffness is critical to both the understanding of the biological function...
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sg-ntu-dr.10356-1534522021-12-03T06:09:51Z Curvature-regulated lipid membrane softening of nano-vesicles Chng, Choon-Peng Sadovsky, Yoel Hsia, K. Jimmy Huang, Changjin School of Mechanical and Aerospace Engineering School of Chemical and Biomedical Engineering Magee-Womens Research Institute Science::Biological sciences::Biophysics Molecular Simulation Nanoscale Lipid Vesicle The physico-mechanical properties of nanoscale lipid vesicles (e.g., natural nano-vesicles and artificial nano-liposomes) dictate their interaction with biological systems. Understanding the interplay between vesicle size and stiffness is critical to both the understanding of the biological functions of natural nano-vesicles and the optimization of nano-vesicle-based diagnostics and therapeutics. It has been predicted that, when vesicle size is comparable to its membrane thickness, the effective bending stiffness of the vesicle increases dramatically due to both the entropic effect as a result of reduced thermal undulation and the nonlinear curvature elasticity effect. Through systematic molecular dynamics simulations, we show that the vesicle membrane thins and softens with the decrease in vesicle size, which effectively counteracts the stiffening effects as already mentioned. Our simulations indicate that the softening of nano-vesicles results from a change in the bilayer's interior structure - a decrease in lipid packing order - as the membrane curvature increases. Our work thus leads to a more complete physical framework to understand the physico-mechanical properties of nanoscale lipid vesicles, paving the way to further advances in the biophysics of nano-vesicles and their biomedical applications. Ministry of Education (MOE) Nanyang Technological University Accepted version Y.S., K.J.H. and C.H. acknowledge the financial support by the NIH Eunice Kennedy Shriver National Institute of Child Health and Human Development (grant R01HD086325). K.J.H. would like to acknowledge financial support from Nanyang Technological University (start-up grant M4082428.050). C.H. would also like to acknowledge financial support from Nanyang Technological University (start-up grant M4082352.050) and the Ministry of Education, Singapore, under its Academic Research Fund Tier 1 (M4012229.050). The computational work for this article was fully performed on resources of the National Supercomputing Centre, Singapore (https://www.nscc.sg). 2021-12-03T06:09:51Z 2021-12-03T06:09:51Z 2021 Journal Article Chng, C., Sadovsky, Y., Hsia, K. J. & Huang, C. (2021). Curvature-regulated lipid membrane softening of nano-vesicles. Extreme Mechanics Letters, 43, 101174-. https://dx.doi.org/10.1016/j.eml.2021.101174 2352-4316 https://hdl.handle.net/10356/153452 10.1016/j.eml.2021.101174 33542946 2-s2.0-85099382883 43 101174 en R01HD086325 M4082428 M4082352 M4012229 Extreme Mechanics Letters 10.21979/N9/L1GHBD © 2021 Elsevier Ltd. All rights reserved. This paper was published in Extreme Mechanics Letters and is made available with permission of Elsevier Ltd. application/pdf application/pdf |
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Science::Biological sciences::Biophysics Molecular Simulation Nanoscale Lipid Vesicle Chng, Choon-Peng Sadovsky, Yoel Hsia, K. Jimmy Huang, Changjin Curvature-regulated lipid membrane softening of nano-vesicles |
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The physico-mechanical properties of nanoscale lipid vesicles (e.g., natural nano-vesicles and artificial nano-liposomes) dictate their interaction with biological systems. Understanding the interplay between vesicle size and stiffness is critical to both the understanding of the biological functions of natural nano-vesicles and the optimization of nano-vesicle-based diagnostics and therapeutics. It has been predicted that, when vesicle size is comparable to its membrane thickness, the effective bending stiffness of the vesicle increases dramatically due to both the entropic effect as a result of reduced thermal undulation and the nonlinear curvature elasticity effect. Through systematic molecular dynamics simulations, we show that the vesicle membrane thins and softens with the decrease in vesicle size, which effectively counteracts the stiffening effects as already mentioned. Our simulations indicate that the softening of nano-vesicles results from a change in the bilayer's interior structure - a decrease in lipid packing order - as the membrane curvature increases. Our work thus leads to a more complete physical framework to understand the physico-mechanical properties of nanoscale lipid vesicles, paving the way to further advances in the biophysics of nano-vesicles and their biomedical applications. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Chng, Choon-Peng Sadovsky, Yoel Hsia, K. Jimmy Huang, Changjin |
| format |
Article |
| author |
Chng, Choon-Peng Sadovsky, Yoel Hsia, K. Jimmy Huang, Changjin |
| author_sort |
Chng, Choon-Peng |
| title |
Curvature-regulated lipid membrane softening of nano-vesicles |
| title_short |
Curvature-regulated lipid membrane softening of nano-vesicles |
| title_full |
Curvature-regulated lipid membrane softening of nano-vesicles |
| title_fullStr |
Curvature-regulated lipid membrane softening of nano-vesicles |
| title_full_unstemmed |
Curvature-regulated lipid membrane softening of nano-vesicles |
| title_sort |
curvature-regulated lipid membrane softening of nano-vesicles |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/153452 |
| _version_ |
1718368108851232768 |