Homepage of Martin Michael Müller

Publications

Articles in scientific journals
Books
Theses

See also profiles on Publons, Orcid or Google Scholar.

1. Articles in scientific journals

Conformational Space of the Translocation Domain of Botulinum Toxin: Atomistic Modeling and Mesoscopic Description of the Coiled-Coil Helix Bundle

Alexandre Delort, Grazia Cottone, Thérèse E. Malliavin, Martin Michael Müller

Abstract

Int. J. Mol. Sci., 25: 2481, 2024.

Flexoelectric fluid membrane vesicles in spherical confinement

Niloufar Abtahi, Lila Bouzar, Nadia Saidi-Amroun, Martin Michael Müller
EPL, 131(1): 18001, 2020. See also arXiv:2006.04475.

Isometric bending requires local constraints on free edges

Jemal Guven, Martin Michael Müller, Pablo Vázquez-Montejo

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Math. Mech. Solids, 24: 4051, 2019. See also arXiv:1904.05855.

Helical Superstructure of Intermediate Filaments

Lila Bouzar, Martin Michael Müller, René Messina, Bernd Nöding, Sarah Köster, Hervé Mohrbach, Igor M. Kulić

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Phys. Rev. Lett., 122: 098101, 2019. See also arXiv:1803.04691.

Vesicle dynamics in confined steady and harmonically modulated Poiseuille flows

Zakaria Boujja, Chaouqi Misbah, Hamid Ez-Zahraouy, Abdelilah Benyoussef, Thomas John, Christian Wagner, Martin Michael Müller

Abstract

Phys. Rev. E, 98: 043111, 2018. See also arXiv:1810.04500.

Confining a fluid membrane vesicle of toroidal topology in an adhesive hard sphere

Lila Bouzar, Ferhat Menas, Martin Michael Müller

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IOP Conf. Series: MSE, 186: 012021, 2017.

Squeezed helical elastica

Lila Bouzar, Martin Michael Müller, Pierre Gosselin, Igor M. Kulić, Hervé Mohrbach

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Eur. Phys. J. E, 39: 114, 2016. See also arXiv:1606.03611.

How bio-filaments twist membranes

Julien Fierling, Albert Johner, Igor M. Kulić, Hervé Mohrbach, Martin Michael Müller

Abstract

Soft Matter, 12: 5747, 2016.

Toroidal membrane vesicles in spherical confinement

Lila Bouzar, Ferhat Menas, Martin Michael Müller
We investigate the morphology of a toroidal fluid membrane vesicle confined inside a spherical container. The equilibrium shapes are assembled in a geometrical phase diagram as a function of scaled area and reduced volume of the membrane. For small area the vesicle can adopt its free form. When increasing the area, the membrane cannot avoid contact and touches the confining sphere along a circular contact line, which extends to a zone of contact for higher area. The elastic energies of the equilibrium shapes are compared to those of their confined counterparts of spherical topology to predict under which conditions a topology change is favored energetically.

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Phys. Rev. E, 92: 032721, 2015. See also arXiv:1509.00765.

Non-linear buckling and symmetry breaking of a soft elastic sheet sliding on a cylindrical substrate

Norbert Stoop, Martin Michael Müller

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Int. J. Non-Linear Mech., 75: 115, 2015. See also arXiv:1503.05030.

Crunching Biofilament Rings

Julien Fierling, Martin Michael Müller, Hervé Mohrbach, Albert Johner, Igor M. Kulić

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Europhys. Lett., 107(6): 68002, 2014. See also arXiv:1408.6787.

Confotronic dynamics of tubular filaments

Osman Kahraman, Hervé Mohrbach, Martin Michael Müller, Igor M. Kulić

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Soft Matter, 10(16): pp. 2836-2847, 2014. See also arXiv:1312.3106.

Whirling skirts and rotating cones

Jemal Guven, J. A. Hanna, Martin Michael Müller

Abstract

New J. Phys., 15: 113055, 2013. See also arXiv:1306.2619.

Myotubularin and PtdIns3P remodel the sarcoplasmic reticulum in muscle in vivo

Leonela Amoasii, Karim Hnia, Gaëtan Chicanne, Andreas Brech, Belinda Simone Cowling, Martin Michael Müller, Yannick Schwab, Pascale Koebel, Arnaud Ferry, Bernard Payrastre, Jocelyn Laporte

Abstract

J. Cell Sci., 126(8): 1806, 2013.

Dipoles in thin sheets

Jemal Guven, J. A. Hanna, Osman Kahraman, Martin Michael Müller

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Eur. Phys. J. E, 36: 106, 2013. See also arXiv:1212.3262.

Fluid membrane vesicles in confinement

Osman Kahraman, Norbert Stoop, Martin Michael Müller
We numerically study the morphology of fluid membrane vesicles with prescribed volume and surface area in confinement. For spherical confinement we observe axisymmetric invaginations that transform into ellipsoidal invaginations a the area of the vesicle is increased, followed by a transition into stomatocyte-like shapes. We provide a detailed analysis of the axisymmetric shapes and investigate the effect of the spontaneous curvature of the membrane as a possible mechanism for shape regulation. We show that the observed morphologies are stable under small geometric deformations of the confinement. The results could help to understand the role of mechanics in the complex folding patterns of biological membranes.

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New J. Phys., 14: 095021, 2012.

Petal shapes of sympetaleous flowers: the interplay between growth, geometry and elasticity

Martine Ben Amar, Martin Michael Müller, Miguel Trejo

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New J. Phys., 14: 085014, 2012. Also featured in the Highlights of 2012.

Morphogenesis of membrane invaginations in spherical confinement

Osman Kahraman, Norbert Stoop, Martin Michael Müller
We study the morphology of a fluid membrane in spherical confinement. When the area of the membrane is slightly larger than the area of the outer container, a single axisymmetric invagination is observed. For higher area, self-contact occurs: the invagination breaks symmetry and deforms into an ellipsoid-like shape connected to its outer part via a small slit. For even higher areas, a second invagination forms inside the original invagination. The folding patterns observed could constitute basic building blocks in the morphogenesis of biological tissues and organelles.

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Europhys. Lett., 97(6): 68008, 2012. See also arXiv:1201.2518.

Conical instabilities on paper

Jemal Guven, Martin Michael Müller, Pablo Vázquez-Montejo

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J. Phys. A: Math. Theor., 45(1): 015203, 2012. See also arXiv:1107.5008.

Interface-mediated interactions: Entropic forces of curved membranes

Pierre Gosselin, Hervé Mohrbach, Martin Michael Müller

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Phys. Rev. E, 83(5): 051921, 2011. See also arXiv:1011.1221.

Self-Contact and Instabilities in the Anisotropic Growth of Elastic Membranes

Norbert Stoop, Falk K. Wittel, Martine Ben Amar, Martin Michael Müller, Hans J. Herrmann

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Phys. Rev. Lett., 105(6): 068101, 2010. See also arXiv:1007.1871.

Cell Model Approach to Membrane Mediated Protein Interactions

Martin Michael Müller, Markus Deserno

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Prog. Theor. Phys. Suppl., 184: pp. 351-363, 2010.

Hamiltonian formulation of surfaces with constant Gaussian curvature

Miguel Trejo, Martine Ben Amar, Martin Michael Müller

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J. Phys. A: Math. Theor., 42(42): 425204, 2009.

Local Membrane Mechanics of Pore-Spanning Bilayers

Ingo Mey, Milena Stephan, Eva K. Schmitt, Martin Michael Müller, Martine Ben Amar, Claudia Steinem, Andreas Janshoff

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J. Am. Chem. Soc., 131(20): pp. 7031-7039, 2009.

Elasticity Mapping of Pore-Suspending Native Cell Membranes

Bärbel Lorenz, Ingo Mey, Siegfried Steltenkamp, Tamir Fine, Christina Rommel, Martin Michael Müller, Alexander Maiwald, Joachim Wegener, Claudia Steinem, Andreas Janshoff

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Small, 5(7): pp. 832-838, 2009.

Conical Defects in Growing Sheets

Martin Michael Müller, Martine Ben Amar, Jemal Guven

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Phys. Rev. Lett., 101(15): 156104, 2008. See also arXiv:0807.1814.

How paper folds: bending with local constraints

Jemal Guven, Martin Michael Müller

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J. Phys. A: Math. Theor., 41(5): 055203, 2008. See also arXiv:0712.0978.

Contact lines for fluid surface adhesion

Markus Deserno, Martin Michael Müller, Jemal Guven

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Phys. Rev. E, 76(1): 011605, 2007. See also cond-mat/0703019.
Also featured in the Virtual Journal of Biological Physics Research.

Balancing torques in membrane-mediated interactions: Exact results and numerical illustrations

Martin Michael Müller, Markus Deserno, Jemal Guven

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Phys. Rev. E, 76(1): 011921, 2007. See also cond-mat/0702340.
Also featured in the Virtual Journal of Biological Physics Research.

Aggregation and vesiculation of membrane proteins by curvature-mediated interactions

Benedict J. Reynwar, Gregoria Illya, Vagelis A. Harmandaris, Martin Michael Müller, Kurt Kremer, Markus Deserno

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Nature 447(7143): pp. 461-464, 2007.

How to determine local elastic properties of lipid bilayer membranes from atomic-force-microscope measurements: A theoretical analysis

Davood Norouzi, Martin Michael Müller, Markus Deserno

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Phys. Rev. E, 74(6): 061914, 2006. See also cond-mat/0602662.
Also featured in the Virtual Journal of Biological Physics Research.

Mechanical Properties of Pore-Spanning Lipid Bilayers Probed by Atomic Force Microscopy

Siegfried Steltenkamp, Martin Michael Müller, Markus Deserno, Christian Hennesthal, Claudia Steinem, Andreas Janshoff

Interface mediated interactions between particles -- a geometrical approach

Martin Michael Müller, Markus Deserno, Jemal Guven

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Phys. Rev. E, 72(6): 061407, 2005. See also cond-mat/0506019.
Also featured in the Virtual Journal of Biological Physics Research.

Geometry of surface-mediated interactions

Martin Michael Müller, Markus Deserno, Jemal Guven
Soft interfaces can mediate interactions between particles bound to them. The force transmitted through the surface geometry on a particle may be expressed as a closed line integral of the surface stress tensor around that particle. This contour may be deformed to exploit the symmetries present; for two identical particles, one obtains an exact expression for the force between them in terms of the local surface geometry of their mid-plane; in the case of a fluid membrane the sign of the interaction is often evident. The approach, by construction, is adapted directly to the surface and is independent of its parameterization. Furthermore, it is applicable for arbitrarily large deformations; in particular, it remains valid beyond the linear small-gradient regime.

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Europhys. Lett., 69(3): pp. 482-488, 2005. See also cond-mat/0409043.

2. Books

New Trends in the Physics and Mechanics of Biological Systems
Lecture Notes of the Les Houches Summer School, vol. 92 (Oxford University Press, 2011),
edited by Martine Ben Amar, Alain Goriely, Martin Michael Müller and Leticia Cugliandolo.

Chapter 9:
The physics of the cell membrane
Martin Michael Müller and Martine Ben Amar.

3. Theses

Theoretical examinations of interface mediated interactions between colloidal particles, diploma thesis (2004).

Theoretical studies of fluid membrane mechanics, dissertation (2007).

Symmetry breaking in bioelasticity, habilitation thesis (2015).