File list
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This special page shows all uploaded files.
Date | Name | Thumbnail | Size | User | Description |
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11:59, 17 May 2024 | Xu Lab Xiaoyu.png (file) | 133 KB | Peisheng Xu | ||
11:55, 17 May 2024 | Xu Lab Jia.png (file) | 152 KB | Peisheng Xu | ||
07:48, 15 May 2024 | Yu Lado Zhang Magnotti Beauchamp Frontiers in Neuroscience 2024.pdf (file) | 2.25 MB | Michael S Beauchamp | ||
06:53, 15 May 2024 | Careto CSL.png (file) | 173 KB | Raulemm | Raúl Montañez | |
16:54, 13 May 2024 | Hornbeck WUbites Spring 2024.pdf (file) | 113 KB | David Altman | ||
21:23, 12 May 2024 | Jeffe WUbites Spring 2024.pdf (file) | 234 KB | David Altman | ||
14:36, 10 May 2024 | Robbins WUbites Spring 2024.pdf (file) | 48 KB | David Altman | ||
18:23, 9 May 2024 | 097vwfNbs abstract.png (file) | 1.06 MB | Renhao Li | ||
15:24, 9 May 2024 | Martin WUbites Spring 2024.pdf (file) | 103 KB | David Altman | ||
14:48, 9 May 2024 | CampiTalk.jpg (file) | 1.3 MB | David Altman | ||
14:39, 9 May 2024 | JuniorPresentations.jpg (file) | 2.9 MB | David Altman | ||
14:39, 9 May 2024 | SeniorPresentations.jpg (file) | 2.78 MB | David Altman | ||
14:28, 9 May 2024 | SkypeaScientist January2024.jpeg (file) | 2.78 MB | David Altman | ||
14:18, 9 May 2024 | Isaacson WUbitres Spring 2024.pdf (file) | 193 KB | David Altman | ||
14:14, 9 May 2024 | Corado WUbites Spring 2024.pdf (file) | 73 KB | David Altman | ||
14:12, 9 May 2024 | DeBois WUbites Spring 2024.pdf (file) | 450 KB | David Altman | ||
14:05, 9 May 2024 | Tinat WUbites Spring 2024.pdf (file) | 374 KB | David Altman | ||
13:58, 9 May 2024 | Allen WUbites Spring 2024.pdf (file) | 68 KB | David Altman | ||
13:22, 8 May 2024 | Jernej-Turnšek-CV-May-2024.pdf (file) | 185 KB | Jernej Turnsek | ||
21:12, 5 May 2024 | Whatman® FTA® cards.png (file) | 642 KB | Xning098 | ||
21:03, 5 May 2024 | Diagram-Shows-the-Technique-of-FNAC.png (file) | 119 KB | Xning098 | ||
20:18, 5 May 2024 | Guthrie test .png (file) | 910 KB | Xning098 | ||
09:52, 3 May 2024 | R230pic.jpg (file) | 139 KB | Noelani Kamelamela | ||
08:42, 3 May 2024 | R230pic.jpeg (file) | 139 KB | Noelani Kamelamela | ||
08:32, 3 May 2024 | Syntax.jpg (file) | 300 KB | Noelani Kamelamela | ||
08:31, 3 May 2024 | Droligoprocess.jpg (file) | 639 KB | Noelani Kamelamela | ||
08:29, 3 May 2024 | Chamber.jpg (file) | 239 KB | Noelani Kamelamela | ||
08:28, 3 May 2024 | DrOligo.jpg (file) | 273 KB | Noelani Kamelamela | ||
18:42, 1 May 2024 | Endothelial Microvessel Device.png (file) | 310 KB | Ejmoore | ||
12:57, 30 April 2024 | NKBMC04082024.jpg (file) | 348 KB | Noelani Kamelamela | ||
12:01, 30 April 2024 | SynergyH1cart.jpg (file) | 75 KB | Noelani Kamelamela | ||
10:38, 30 April 2024 | BMC 10X data.png (file) | 33 KB | Noelani Kamelamela | ||
06:08, 30 April 2024 | Pulsatile blood sim.jpg (file) | 670 KB | Nkokkula | Numerically simulated formation of RBC rouleaux under pulsatile flow at 0.96s. The black and red particles represent aggregated and nonaggregated RBCs, respectively. The color gradient is the shear rate in the flow (1/s). (a)-(d) are RBC distributions at velocity amplitudes from 0.5 mm/s to 1.3 mm/s at a mean flow velocity of 4 mm/s. (e)-(h) are RBC distributions at the same velocity amplitudes at a mean flow velocity of 5 mm/s. Lee, C.-A.; Paeng, D.-G. Numerical Simulation of Spatiotemporal... | |
06:04, 30 April 2024 | Pulsatile blood sim.webp (file) | Error creating thumbnail: mkdir: cannot create directory '/sys/fs/cgroup/memory/mediawiki/job/10774': No such file or directory
limit.sh: failed to create the cgroup.
convert: delegate failed `"dwebp" -pam "%i" -o "%o"' @ error/delegate.c/InvokeDelegate/1310.
convert: unable to open image `/tmp/magick-10777l8CP11OGC1sM': No such file or directory @ error/blob.c/OpenBlob/2712.
convert: unable to open file `/tmp/magick-10777l8CP11OGC1sM': No such file or directory @ error/constitute.c/ReadImage/540.
convert: no images defined `/home/wiki/public_html/tmp/transform_9823403d5ec7.png' @ error/convert.c/ConvertImageCommand/3213.
Error code: 1 |
339 KB | Nkokkula | Numerically simulated formation of RBC rouleaux under pulsatile flow at 0.96s. The black and red particles represent aggregated and nonaggregated RBCs, respectively. The color gradient is the shear rate in the flow (1/s). (a)-(d) are RBC distributions at velocity amplitudes from 0.5 mm/s to 1.3 mm/s at a mean flow velocity of 4 mm/s. (e)-(h) are RBC distributions at the same velocity amplitudes at a mean flow velocity of 5 mm/s. Lee, C.-A.; Paeng, D.-G. Numerical Simulation of Spatiotemporal... |
05:54, 30 April 2024 | CFL in vitro.png (file) | 808 KB | Nkokkula | RBCs flow through a PDMS microfluidic channel and form an RBC-FL. The blue line tracks a single RBC across frames. The image was created by overlaying frames of a captured video. Pinto, E.; Faustino, V.; Rodrigues, R. O.; Pinho, D.; Garcia, V.; Miranda, J. M.; Lima, R. A Rapid and Low-Cost Nonlithographic Method to Fabricate Biomedical Microdevices for Blood Flow Analysis. Micromachines 2015, 6 (1), 121–135. https://doi.org/10.3390/mi6010121. is licensed under CC BY 4.0 | |
05:40, 30 April 2024 | Blood particle distribution.jpg (file) | 124 KB | Nkokkula | Representation of the distribution of WBCs, RBCs, and platelets in a blood vessel. The parabolic laminar velocity distribution is shown at the left end of the vessel. Wang, S.; Han, K.; Ma, S.; Qi, X.; Guo, L.; Li, X. Blood Cells as Supercarrier Systems for Advanced Drug Delivery. Med. Drug Discov. 2022, 13, 100119. https://doi.org/10.1016/j.medidd.2021.100119. is licensed under CC BY-NC-ND 4.04 | |
14:10, 29 April 2024 | Xu Lab Spring 2024-1.jpg (file) | 212 KB | Peisheng Xu | ||
11:24, 29 April 2024 | HighRisk.pdf (file) | 56 KB | Lacey Berry | ||
18:55, 28 April 2024 | Nonlineargradientmodel.jpeg (file) | 406 KB | Nmhatre | ||
18:24, 28 April 2024 | Nonlinear Gradient Tree with Varying Horizontal Channel Width.png (file) | 1.39 MB | Nmhatre | ||
18:18, 28 April 2024 | NIL2.png (file) | 244 KB | CarterPaul | ||
17:54, 28 April 2024 | Screenshot 2024-04-28 204106.png (file) | 89 KB | Mredder | Figure #1: Origami Folding | |
17:01, 28 April 2024 | Microfluidic DNA Sequencing - Source 7.png (file) | 71 KB | Khiemle | ||
16:51, 28 April 2024 | NIL.png (file) | 212 KB | CarterPaul | ||
16:35, 28 April 2024 | Microfluidic DNA Sequencing - Source 6.png (file) | 52 KB | Khiemle | ||
15:58, 28 April 2024 | NGS Technology Illustration.png (file) | 38 KB | Khiemle | ||
15:35, 28 April 2024 | CHAU Device 2.png (file) | 331 KB | Bfoss | Multiple levels on shear on 1 chip | |
15:09, 28 April 2024 | Sheet detatch.jpg (file) | 100 KB | CarterPaul | An illustration of standard cell detachment vs cell sheet detachment. (A) Cells harvested through enzymatic digestion. In this approach, cells lose their cell–cell junctions which cause them to float in a regular culture dish. (B) Cell sheet detachment through temperature control without any enzymatic digestion using temperature responsive culture dish. The temperature is lowered from 37 to 20 °C, which maintains the cell–cell junctions and ECM surface. | |
14:48, 28 April 2024 | Reactive coating.jpg (file) | 32 KB | CarterPaul | This image shows the steps to adding a reactive coating to a PDMS device | |
14:36, 28 April 2024 | Scaffold uses.jpg (file) | 95 KB | CarterPaul | This image shows the uses of 3D scaffold cell cultures and their current uses in cancer research |