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Cellular Biophysics

Prof. Andreas Bausch

Research Field

Understanding complex biomaterials on a fundamental physical basis is an integral challenge of future biophysical research. This challenge can be addressed by the concerted application of new experimental tools of soft condensed matter physics to living cells and bio-mimetic model systems. In our group we concentrate on the one hand on developing new physical tools to address the underlying complexity and mechanisms and on the other hand on developing new biomaterials for applications ranging from biomedicine to functional food.


James-Franck-Str. 1/I
85748 Garching b. München
+49 89 289 12408
Fax: +49 89 289 14469

Members of the Research Group





Other Staff


Course with Participations of Group Members

Titel und Modulzuordnung
Experimentalphysik 2 für Studierende der Chemie
Zuordnung zu Modulen:
VO 2 Bausch, A. Di, 10:00–12:00, MI HS1
Bachelorseminar zur Biophysik
Zuordnung zu Modulen:
PS 2 Bausch, A. Zacharias, M.
Übung zu Experimentalphysik 2 für Studierende der Chemie
Zuordnung zu Modulen:
UE 1 Pirzer, T.
Leitung/Koordination: Bausch, A.
Termine in Gruppen
Aktuelle Themen der Mikrofluidik
Zuordnung zu Modulen:
SE 2 Bausch, A.
Anleitung zu wissenschaftlichem Publizieren
Diese Lehrveranstaltung ist keinem Modul zugeordnet.
SE 2 Bausch, A.
E27-Statusbericht – aktuelle Themen der zellulären Biophysik
Zuordnung zu Modulen:
SE 2 Bausch, A.
FOPRA-Versuch 07: Molekulare Motoren
Zuordnung zu Modulen:
PR 1 Bausch, A.
Mitwirkende: Bleicher, W.Dehne, H.
FOPRA-Versuch 72: Laser-Fallen-Mikroskopie (Bakterienflagellen)
Zuordnung zu Modulen:
PR 1 Bausch, A.
Mitwirkende: Englbrecht, F.Ritzer, D.Tych, K.
Mentoren informieren zur Schwerpunktwahl im Bachelorstudiengang Physik (Biophysik [BIO])
Zuordnung zu Modulen:
OV 0.1 Bausch, A. Zacharias, M.
Repetitorium zu Bachelorseminar zur Biophysik
Zuordnung zu Modulen:
RE 2
Leitung/Koordination: Bausch, A.
Zuordnung zu Modulen:
SE 2 Abstreiter, G. Bausch, A. Rief, M. Fr, 13:00–14:30, PH II 127

Offers for Theses in the Group

Cell-size-dependent regulation of the budding yeast contractile ring

The ability to robustly assemble and maintain complex intracellular structures is fundamental for cell function. The budding yeast septin ring, which sets the basis for bud formation and downstream assembly of the contractile actomyosin ring, is one of the best-studied biological self-assembly processes and serves as an important model system to understand cell polarization and non-linear feedback dynamics. However, what determines the the diameter of the emerging ring structure is so far unclear.

Recently, our lab was able to demonstrate that cell size sets the septin ring diameter in an actin-dependent manner. Aim of this thesis is to use a combination of molecular biology, genetic manipulations, live-cell imaging and image analysis to reveal the molecular processes that underlie the observed scaling of ring diameter with cell volume. Ultimately, theoretical modelling will be used to obtain a quantitative understanding.

This project will be carried out together with the Schmoller lab, Helmholtz Zentrum Neuherberg

suitable as
  • Master’s Thesis Biophysics
  • Master’s Thesis Matter to Life
Supervisor: Andreas Bausch

Current and Finished Theses in the Group

Mapping forces that shape complex organs
Abschlussarbeit im Masterstudiengang Physik (Biophysik)
Themensteller(in): Andreas Bausch
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