DEPARTMENT OF FLUID PHYSICS, PATTERN FORMATION AND BIOCOMPLEXITY

Isabella Guido

Publications

Guido, I.
Spontaneously Beating Biomimetic Structures
Book chapter in: Inaba H. (eds) Microtubules. Methods in Molecular Biology, vol 2430. Humana, New York, NY, (2022)
DOI
Collesano, L., Guido, I., Golestanian, R. and Vilfan, A.
Active beating modes of two clamped filaments driven by molecular motors
J. R. Soc. Interface, Vol. 19(186), 20210693 (2022)
DOI
Guido I., Vilfan A., Ishibashi K., Sakakibara H., Shigara M., Bodenschatz E., Golestanian R. and Oiwa K.
Active beating of a reconstituted synthetic minimal axoneme
(Submitted)
Source
Herzog S., Schiepel D., Guido, I. and Wagner C.
A Probabilistic Particle Tracking Framework for Guided and Brownian Motion Systems with High Particle Densities
SN COMPUT. SCI. 2, 485 (2021)
Source
DOI
Ahmad R., Kleineberg C., Nasirimarekani V., Su Y., Goli Pozveh S., Bae A., Sundmacher K., Bodenschatz E., Guido I., Vidaković-koch T. and Gholami A.
Light-powered reactivation of flagella and contraction of microtubule networks: Toward building an artificial cell
ACS Synth. Biol. 2021, 10, 1490–1504
DOI
Nasirimarekani V., Strübing T., Vilfan A. and Guido, I.
Tuning the Properties of Active Microtubule Networks by Depletion Forces
Langmuir 2021, 37, 26, 7919–7927
DOI
Stricker, L., Guido, I., Breithaupt, T., Mazza, M. G. and Vollmer, J.
Hybrid sideways/longitudinal swimming in monoflagellate bacteria: from aerotactic band to biofilm
JRS Interface 17, 20200559 (2020)
DOI
Guido, I., Diehl, D., Olszok, N.A. and Bodenschatz, E.
Cellular velocity, electrical persistence and sensing in developed and vegetative cells during electrotaxis
PLoS ONE, 15: e0239379 (2020)
DOI
Strübing, T., Khosravanizadeh, A., Vilfan, A., Bodenschatz, E., Golestanian, R. and Guido, I.
Wrinkling Instability in 3D Active Nematics
Nano Lett., 2020, 20, 6281-6288
DOI
Ahmad, R., Kleineberg, C., Nasirimarekani, V., Su, Y., Goli Pozveh, S., Bae, AJ., Bodenschatz, E., K. Sundmacher, K., Guido, I., Vidaković-Koch, T. and Gholami, A.
Light-powered reactivation of flagella and contraction of microtubules network: towards building an artificial cell
Biorxiv:https://doi.org/10.1101/2020.07.20.212191 (2020)
Vilfan, A., Subramani, S., Bodenschatz, E., Golestanian, R. and Guido, I.
Flagella-like Beating of a Single Microtubule
Nano Lett., 19, 3359-3363  (2019)
DOI
Westendorf, C., Gholami, A., Faubel, R., Guido, I., Wang, Y., Bae, A., Eichele, G. and Bodenschatz, E.
Koordinierter Flüssigkeitstransport durch zilienbesetzte Oberflächen
Part of the annually published yearbook of the Max-Planck Society. (in German)
DOI
SS. Li, SS., Liu, XQ., Chao, A., Peng, XL., Guido, I., Wang, LL., Ge, ZG., Xiong, CY.
A simple magnetic force-based cell patterning method using soft lithography
Sci. China Life Sci. 58, 400–402 (2015)
DOI
Guido, I., Xiong, CY. and Fang, J.
Low-voltage electroporation with fluidic microelectrodes
Microelectronic Engineering 98, 707-710 (2012)
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Guido, I., Xiong, CY., Jaeger, MS. and Duschl, C.
Microfluidic system for cell mechanics analysis through dielectrophoresis
Microelectronic Engineering 97, 379-382 (2012)
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Guido, I., Jaeger, MS. and Duschl C.
Dielectrophoretic stretching of cells allows for characterization of their mechanical properties
Eur Biophys J, 40, 281-288 (2011)
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Guido, I., Jaeger, MS. and Duschl C.
Influence of medium consumption on cell elasticity
Cytotechnology, 62, 257-263 (2010)
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Guido, I., Jaeger, MS. and Duschl C.
Cell Deformation by Dielectrophoretic Fields
IFMBE Proceedings, 25, 21-24 (2009)
DOI
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