1 to 7 of 7 Results
Dec 15, 2023 - PN 2-3B
Santana Chacon, Pablo Filipe; Hammer, Maria; Wochner, Isabell; Walter, Johannes R.; Schmitt, Syn, 2023, "Replication Data for: A physiologically enhanced muscle spindle model: using a Hill-type model for extrafusal fibers as template for intrafusal fibers", https://doi.org/10.18419/darus-3796, DaRUS, V1
This code/data allows you reproduce the results of the paper: "A physiologically enhanced muscle spindle model: using a Hill-type model for extrafusal fibers as template for intrafusal fibers" by P. F. S. Chacon, M. Hammer, I. Wochner, J. R. Walter and S. Schmitt. Always cite the... |
Nov 9, 2023PN 2
Open-Source structurally physiological Hill-type model of the muscle spindle for forward-dynamic simulations in biophysics and biomechanics. |
Aug 4, 2023 - Walking Model
Bunz, Elsa; Häufle, Daniel F. B.; Remy, C. David; Schmitt, Syn, 2023, "Experimental results for Bioinspired Preactivation Reflex Increases Robustness of Walking on Rough Terrain", https://doi.org/10.18419/darus-3492, DaRUS, V1
This dataset contains the experimental results and postprocessing script (Matlab, Mathworks, Natick, MA) to obtain the plots and results described in the paper "Bioinspired Preactivation Reflex Increases Robustness of Walking on Rough Terrain" by Elsa K. Bunz, Daniel F.B. Haeufle... |
Jun 30, 2023 - PN 3-11
Wachlmayr, Johann; Fläschner, Gotthold; Pluhackova, Kristyna; Sandtner, Walter; Siligan, Christine; Horner, Andreas, 2023, "Supplementary Material for 'Entropic barrier of water permeation through single-file channels'", https://doi.org/10.18419/darus-3390, DaRUS, V1
Facilitated water permeation through narrow biological channels is fundamental for all forms of life. This process involves dehydration of bulk water entering the single-file region and hydrogen bond formation with channel lining amino acid residues. Despite its significance in h... |
Jun 21, 2023 - Biophysics Group
Wang, Shuo; Nussberger, Stephan, 2023, "Data for: Tracking the activity and position of mitochondrial beta-barrel proteins", https://doi.org/10.18419/darus-3573, DaRUS, V1
Total interference reflection fluorescence microscopy (TIRF) of lipid bilayers is an effective technique for studying the lateral motion and ion channel activity of individual integral membrane proteins by optical means. This dataset contains a demo video for tracking the activit... |