Mesoscopic models of lipid bilayers and bilayers with embedded ...

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Page 1: Mesoscopic models of lipid bilayers

Page 4 and 5: Promotiecommissie: Promotor: • pr

Page 6 and 7: ii CONTENTS 5.3 Double-tail lipid b

Page 8 and 9: 2 Introduction 1.1 The cell membran

Page 10 and 11: 4 Introduction between the beads, a

Page 12 and 13: 6 Introduction whether the preferre

Page 14 and 15: 8 Simulation method for coarse-grai

Page 16 and 17: 10 Simulation method for coarse-gra





Page 27 and 28: III Surface tension in lipid bilaye

Page 29 and 30: 3.2 Method of calculation of surfac

Page 31 and 32: 3.2 Method of calculation of surfac

Page 33 and 34: 3.3 Constant surface tension ensemb

Page 35 and 36: 3.3 Constant surface tension ensemb

Page 37 and 38: 3.4 Surface tension in lipid bilaye



Page 43 and 44: IV Structural characterization of l

Page 45 and 46: 4.2 Structural quantities 39 been r

Page 47 and 48: 4.3 Computational details 41 lipid

Page 49 and 50: 4.4 Results and discussion 43 ρ(z)

Page 51 and 52: 4.4 Results and discussion 45 one l

Page 53 and 54: 4.4 Results and discussion 47 WH HT

Page 55 and 56: 4.4 Results and discussion 49 Shill

Page 57 and 58: 4.4 Results and discussion 51 chain

Page 59 and 60: 4.4 Results and discussion 53 4.4.4

Page 61: 4.4 Results and discussion 55 headg

Page 64 and 65: 58 Phase behavior of coarse-grained










Page 85 and 86: VI Interaction of small molecules w

Page 87 and 88: 6.2 Computational details 81 For re

Page 89 and 90: 6.3 Results and Discussion 83 withi

Page 91 and 92: 6.3 Results and Discussion 85 ρ(z)

Page 93 and 94: 6.3 Results and Discussion 87 ρ(z)

Page 95 and 96: 6.3 Results and Discussion 89 S m 0

Page 97 and 98: 6.3 Results and Discussion 91 π(z)

Page 99: 6.3 Results and Discussion 93 the l

Page 102 and 103: 96 Mesoscopic model for lipid bilay

Page 104 and 105: 98 Mesoscopic model for lipid bilay

Page 106 and 107: 100 Mesoscopic model for lipid bila









Page 125 and 126: References [1] Tanford, C. Science

Page 127: 7.4 Conclusion 121 [68] Ono, S.; Ko

Page 131 and 132: Summary Biological membranes, as th

Page 133 and 134: agreement we find gives us confiden

Page 135 and 136: Samenvatting Biologische membranen,

Page 137 and 138: de lage temperatuur gel fase of Lβ

Page 139: ied dat het dichtst bij het hydrofo

Page 143: This thesis is based on the followi

bilayer

lipid

lipids

hydrophobic

bilayers

protein

thickness

beads

length

simulations

mesoscopic

models

embedded

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