Theoretical Predictions to be Scrutinized by Experiment
“The best way to predict the future is to invent it” Alan Kay
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Cis-dimerization of membrane proteins generates membrane tension in nanotubes of endoplasmic reticulum
(2023) .
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Stress asymmetry between bilayer leaflets controls adhesion
(Figure 43) and fusion
(Figure 44) of nanovesicles
(2023) .
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Positive and negative tension of contact line between condensate droplets and vesicles
(2023) .
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Different pathways for endocytosis of condensate droplets by nanovesicles
(2023).
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Collective Force Generation by Molecular Motors Is Determined by Strain-Induced Unbinding
(2020) .
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Force-Dependent Unbinding Rate of Molecular Motors from Stationary Optical Trap Data
(2019) .
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Adhesion-induced fission of membranes by ESCRT proteins
(2018).
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Nanoparticles in contact with vesicle membranes experience curvature-induced forces
(2017) .
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Tug-of-war between two elastically coupled molecular motors
(2017) .
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Adhesive substrates and constriction forces stabilize closed membrane necks
(2016) .
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Adhesive nanoparticles as local probes of membrane curvature
(2015) .
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Nanoparticles interacting with vesicles form
four engulfment regimes (2015)
and
ten engulfment patterns (2015)
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Binding constants of receptor/ligand bonds between membranes are governed
by nanoscale roughness (2013) .
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Phase behavior of multicomponent membranes exposed to different environments
(2013).
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Chemomechanics of two elastically coupled molecular motors
(2013) .
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Interference regimes for cooperative transport by molecular motors
(2012).
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Stability of double-membrane sheets and vesicles
(2012).
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Nonlinear law of mass action for membrane receptors
(2009) .
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Chemomechanical balance conditions for molecular motor cycles
(2008).
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Enhanced ordering of filaments by molecular motors
(2006).