Category:Interdisciplinary physics

Media in category "Interdisciplinary physics"

The following 193 files are in this category, out of 193 total.

• 3D-Multi-Cell-Simulation-of-Tumor-Growth-and-Angiogenesis-pone.0007190.s002.ogv 40 s, 300 × 300; 8.51 MB
  
• 3D-Multi-Cell-Simulation-of-Tumor-Growth-and-Angiogenesis-pone.0007190.s003.ogv 40 s, 270 × 270; 7.73 MB
  
• A-Microfluidic-Device-for-Temporally-Controlled-Gene-Expression-and-Long-Term-Fluorescent-Imaging-pone.0001468.s009.ogv 20 s, 1,350 × 450; 7.58 MB
  
• A-Microfluidic-Device-for-Temporally-Controlled-Gene-Expression-and-Long-Term-Fluorescent-Imaging-pone.0001468.s010.ogv 8.6 s, 1,400 × 639; 9.5 MB
  
• A-Microfluidic-Device-for-Temporally-Controlled-Gene-Expression-and-Long-Term-Fluorescent-Imaging-pone.0001468.s011.ogv 22 s, 800 × 909; 7.38 MB
  
• A-Microfluidic-Device-for-Temporally-Controlled-Gene-Expression-and-Long-Term-Fluorescent-Imaging-pone.0001468.s012.ogv 18 s, 800 × 828; 6.5 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s003.ogv 12 s, 128 × 128; 490 KB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s005.ogv 26 s, 128 × 128; 1.48 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s006.ogv 45 s, 256 × 256; 12.61 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s007.ogv 30 s, 256 × 248; 10.17 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s008.ogv 33 s, 256 × 256; 423 KB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s009.ogv 26 s, 128 × 128; 366 KB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s010.ogv 26 s, 128 × 128; 1.29 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s011.ogv 26 s, 128 × 128; 579 KB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s012.ogv 22 s, 180 × 180; 1.73 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s013.ogv 44 s, 128 × 128; 1.63 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s014.ogv 26 s, 128 × 128; 1.34 MB
  
• Accumulative-Difference-Image-Protocol-for-Particle-Tracking-in-Fluorescence-Microscopy-Tested-in-pone.0012216.s015.ogv 26 s, 128 × 128; 1.38 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s003.ogv 22 s, 512 × 384; 2.31 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s004.ogv 10 s, 715 × 536; 1.2 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s005.ogv 8.5 s, 512 × 384; 2.1 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s006.ogv 14 s, 512 × 349; 2.83 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s007.ogv 22 s, 312 × 234; 2.31 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s008.ogv 8.5 s, 715 × 536; 918 KB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s009.ogv 20 s, 512 × 384; 1.26 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s010.ogv 24 s, 512 × 384; 1.25 MB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s011.ogv 7.2 s, 580 × 512; 468 KB
  
• Assembling-Neurospheres-Dynamics-of-Neural-ProgenitorStem-Cell-Aggregation-Probed-Using-an-Optical-pone.0038613.s012.ogv 7.2 s, 622 × 512; 761 KB
  
• Barriers-to-Diffusion-in-Dendrites-and-Estimation-of-Calcium-Spread-Following-Synaptic-Inputs-pcbi.1002182.s001.ogv 12 s, 3,200 × 2,400; 20.35 MB
  
• Calcium-Signals-Driven-by-Single-Channel-Noise-pcbi.1000870.s002.ogv 6.4 s, 260 × 260; 882 KB
  
• Cascading-Failures-in-Spatially-Embedded-Random-Networks-pone.0084563.s003.ogv 11 s, 1,024 × 1,024; 306 KB
  
• Cascading-Failures-in-Spatially-Embedded-Random-Networks-pone.0084563.s004.ogv 12 s, 1,024 × 1,024; 341 KB
  
• Cascading-Failures-in-Spatially-Embedded-Random-Networks-pone.0084563.s005.ogv 12 s, 1,024 × 1,024; 323 KB
  
• Cascading-Failures-in-Spatially-Embedded-Random-Networks-pone.0084563.s006.ogv 10 s, 1,024 × 1,024; 307 KB
  
• Characterization-of-K-Complexes-and-Slow-Wave-Activity-in-a-Neural-Mass-Model-pcbi.1003923.s005.ogv 37 s, 1,920 × 1,080; 3.06 MB
  
• Chaste-An-Open-Source-C++-Library-for-Computational-Physiology-and-Biology-pcbi.1002970.s003.ogv 30 s, 1,348 × 772; 7.48 MB
  
• Chaste-An-Open-Source-C++-Library-for-Computational-Physiology-and-Biology-pcbi.1002970.s004.ogv 1 min 15 s, 1,036 × 852; 17.99 MB
  
• Chaste-An-Open-Source-C++-Library-for-Computational-Physiology-and-Biology-pcbi.1002970.s005.ogv 20 s, 455 × 455; 1.65 MB
  
• Chaste-An-Open-Source-C++-Library-for-Computational-Physiology-and-Biology-pcbi.1002970.s006.ogv 3.7 s, 1,412 × 952; 229 KB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s001.ogv 25 s, 1,024 × 768; 23.14 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s002.ogv 12 s, 1,024 × 768; 14.4 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s003.ogv 8.2 s, 680 × 512; 7.95 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s004.ogv 0.0 s, 512 × 340; 13.15 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s005.ogv 8.1 s, 1,024 × 768; 43.09 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s006.ogv 8.0 s, 1,384 × 1,040; 48.61 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s007.ogv 15 s, 1,024 × 768; 53.72 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s008.ogv 11 s, 1,024 × 768; 58.71 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s005.ogv 16 s, 480 × 480; 4.04 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s006.ogv 40 s, 480 × 480; 9.04 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s007.ogv 16 s, 480 × 480; 4.96 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s008.ogv 40 s, 480 × 480; 4.43 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s009.ogv 16 s, 480 × 480; 2.95 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s010.ogv 16 s, 480 × 480; 1.12 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s011.ogv 8.0 s, 200 × 200; 359 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s012.ogv 8.0 s, 200 × 200; 340 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s013.ogv 8.0 s, 200 × 200; 347 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s014.ogv 8.0 s, 200 × 200; 332 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s015.ogv 8.0 s, 200 × 200; 340 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s016.ogv 8.0 s, 200 × 200; 335 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s017.ogv 8.0 s, 200 × 200; 342 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s018.ogv 8.0 s, 200 × 200; 330 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s019.ogv 8.0 s, 200 × 200; 196 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s020.ogv 8.0 s, 200 × 200; 283 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s021.ogv 8.0 s, 200 × 200; 268 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s022.ogv 8.0 s, 200 × 200; 262 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s023.ogv 8.0 s, 200 × 200; 233 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s024.ogv 8.0 s, 200 × 200; 224 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s025.ogv 8.0 s, 200 × 200; 211 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s026.ogv 8.0 s, 200 × 200; 196 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s027.ogv 8.0 s, 200 × 200; 115 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s028.ogv 8.0 s, 200 × 200; 331 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s029.ogv 8.0 s, 200 × 200; 416 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s030.ogv 8.0 s, 200 × 200; 475 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s031.ogv 8.0 s, 200 × 200; 534 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s032.ogv 8.0 s, 200 × 200; 564 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s033.ogv 8.0 s, 200 × 200; 587 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s034.ogv 8.0 s, 200 × 200; 593 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s035.ogv 8.0 s, 200 × 200; 609 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s036.ogv 8.0 s, 200 × 200; 621 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s037.ogv 8.0 s, 200 × 200; 624 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s038.ogv 8.0 s, 200 × 200; 333 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s039.ogv 8.0 s, 200 × 200; 294 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s040.ogv 8.0 s, 200 × 200; 209 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s041.ogv 8.0 s, 200 × 200; 110 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s042.ogv 8.0 s, 200 × 200; 100 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s043.ogv 8.0 s, 200 × 200; 100 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s044.ogv 8.0 s, 200 × 200; 1.42 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s045.ogv 8.0 s, 200 × 200; 533 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s046.ogv 8.0 s, 200 × 200; 321 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s047.ogv 8.0 s, 200 × 200; 253 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s049.ogv 8.0 s, 200 × 200; 189 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s050.ogv 8.0 s, 200 × 200; 162 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s051.ogv 8.0 s, 400 × 400; 4.21 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s052.ogv 8.0 s, 400 × 400; 1.75 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s053.ogv 8.0 s, 400 × 400; 1.41 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s054.ogv 8.0 s, 400 × 400; 1.21 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s055.ogv 8.0 s, 400 × 400; 1.07 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s056.ogv 8.0 s, 400 × 400; 1.04 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s057.ogv 8.0 s, 400 × 400; 1,001 KB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s058.ogv 20 s, 480 × 480; 3.03 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s059.ogv 20 s, 480 × 480; 3.53 MB
  
• Contact-Inhibited-Chemotaxis-in-De-Novo-and-Sprouting-Blood-Vessel-Growth-pcbi.1000163.s060.ogv 20 s, 480 × 480; 3.26 MB
  
• Cooperation-Norms-and-Revolutions-A-Unified-Game-Theoretical-Approach-pone.0012530.s001.ogv 20 s, 560 × 500; 3.34 MB
  
• Cooperation-Norms-and-Revolutions-A-Unified-Game-Theoretical-Approach-pone.0012530.s002.ogv 18 s, 560 × 500; 2.05 MB
  
• Cooperation-Norms-and-Revolutions-A-Unified-Game-Theoretical-Approach-pone.0012530.s003.ogv 19 s, 560 × 500; 3.34 MB
  
• Correlative-Nanoscale-3D-Imaging-of-Structure-and-Composition-in-Extended-Objects-pone.0050124.s002.ogv 1 min 2 s, 464 × 384; 6.83 MB
  
• Detection-of-Atomic-Scale-Changes-in-the-Free-Volume-Void-Size-of-Three-Dimensional-Colorectal-pone.0083838.s002.ogv 6.0 s, 512 × 512; 18 KB
  
• Detection-of-Atomic-Scale-Changes-in-the-Free-Volume-Void-Size-of-Three-Dimensional-Colorectal-pone.0083838.s003.ogv 12 s, 512 × 512; 43 KB
  
• Detection-of-Atomic-Scale-Changes-in-the-Free-Volume-Void-Size-of-Three-Dimensional-Colorectal-pone.0083838.s004.ogv 9.0 s, 512 × 512; 39 KB
  
• Detection-of-Atomic-Scale-Changes-in-the-Free-Volume-Void-Size-of-Three-Dimensional-Colorectal-pone.0083838.s005.ogv 4.5 s, 512 × 512; 35 KB
  
• Electrical-Sintering-of-Silver-Nanoparticle-Ink-Studied-by-In-Situ-TEM-Probing-pone.0017209.s001.ogv 15 s, 768 × 752; 888 KB
  
• Exploring-the-Morphospace-of-Communication-Efficiency-in-Complex-Networks-pone.0058070.s007.ogv 41 s, 1,600 × 1,200; 6.15 MB
  
• Exploring-the-Morphospace-of-Communication-Efficiency-in-Complex-Networks-pone.0058070.s008.ogv 42 s, 1,600 × 1,200; 4.49 MB
  
• Flow-Based-Cytometric-Analysis-of-Cell-Cycle-via-Simulated-Cell-Populations-pcbi.1000741.s007.ogv 50 s, 768 × 576; 2.67 MB
  
• Functional-Analysis-of-Spontaneous-Cell-Movement-under-Different-Physiological-Conditions-pone.0002648.s002.ogv 1 min 20 s, 396 × 336; 3.08 MB
  
• Functional-Analysis-of-Spontaneous-Cell-Movement-under-Different-Physiological-Conditions-pone.0002648.s003.ogv 1 min 20 s, 472 × 420; 2.12 MB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s007.ogv 36 s, 688 × 516; 2.86 MB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s008.ogv 36 s, 688 × 516; 5.57 MB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s009.ogv 24 s, 688 × 516; 2.29 MB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s010.ogv 9.6 s, 512 × 512; 346 KB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s011.ogv 9.6 s, 512 × 512; 633 KB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s012.ogv 12 s, 452 × 142; 296 KB
  
• Geometry-Driven-Polarity-in-Motile-Amoeboid-Cells-pone.0113382.s013.ogv 9.9 s, 478 × 512; 1 MB
  
• High-Resolution-Intravital-Microscopy-pone.0050915.s005.ogv 3.8 s, 468 × 651; 266 KB
  
• High-Resolution-Intravital-Microscopy-pone.0050915.s006.ogv 7.4 s, 262 × 196; 88 KB
  
• High-Resolution-Intravital-Microscopy-pone.0050915.s007.ogv 4.5 s, 1,388 × 956; 448 KB
  
• High-Resolution-Intravital-Microscopy-pone.0050915.s008.ogv 4.0 s, 374 × 374; 179 KB
  
• High-Resolution-Intravital-Microscopy-pone.0050915.s009.ogv 2.2 s, 1,148 × 841; 214 KB
  
• High-Resolution-Measurements-of-Face-to-Face-Contact-Patterns-in-a-Primary-School-pone.0023176.s001.ogv 2 min 20 s, 800 × 802; 7.93 MB
  
• In-Situ-Observation-of-Modulated-Light-Emission-of-Fiber-Fuse-Synchronized-with-Void-Train-over-pone.0003276.s003.ogv 5.7 s, 720 × 480; 452 KB
  
• In-Situ-Observation-of-Modulated-Light-Emission-of-Fiber-Fuse-Synchronized-with-Void-Train-over-pone.0003276.s004.ogv 6.3 s, 720 × 480; 494 KB
  
• 
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• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s003.ogv 24 s, 800 × 800; 1.73 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s004.ogv 46 s, 800 × 800; 3.09 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s005.ogv 7.2 s, 800 × 800; 687 KB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s006.ogv 40 s, 800 × 800; 3.86 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s007.ogv 19 s, 800 × 800; 1.69 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s008.ogv 31 s, 800 × 800; 2.21 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s009.ogv 40 s, 800 × 800; 2.56 MB
  
• Mechanical-Properties-of-Growing-Melanocytic-Nevi-and-the-Progression-to-Melanoma-pone.0094229.s010.ogv 21 s, 800 × 800; 1.43 MB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s002.ogv 12 s, 500 × 442; 232 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s003.ogv 12 s, 500 × 442; 240 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s004.ogv 8.1 s, 500 × 620; 1.44 MB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s005.ogv 9.9 s, 500 × 442; 135 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s006.ogv 9.9 s, 500 × 442; 139 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s007.ogv 9.9 s, 500 × 442; 146 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s008.ogv 9.9 s, 500 × 442; 142 KB
  
• Modeling-Cell-Gradient-Sensing-and-Migration-in-Competing-Chemoattractant-Fields-pone.0018805.s009.ogv 9.9 s, 500 × 433; 148 KB
  
• Modeling-E.-coli-Tumbles-by-Rotational-Diffusion.-Implications-for-Chemotaxis-pone.0035412.s001.ogv 8.8 s, 272 × 236; 738 KB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s007.ogv 13 s, 160 × 140; 151 KB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s008.ogv 26 s, 266 × 199; 331 KB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s009.ogv 2 min 0 s, 58 × 54; 194 KB
  
• Neuronal-(Bi)Polarity-as-a-Self-Organized-Process-Enhanced-by-Growing-Membrane-pone.0024190.s008.ogv 2.7 s, 336 × 252; 32 KB
  
• Node-Vulnerability-under-Finite-Perturbations-in-Complex-Networks-pone.0020236.s002.ogv 25 s, 640 × 480; 5.72 MB
  
• Node-Vulnerability-under-Finite-Perturbations-in-Complex-Networks-pone.0020236.s003.ogv 25 s, 640 × 480; 5.22 MB
  
• Node-Vulnerability-under-Finite-Perturbations-in-Complex-Networks-pone.0020236.s004.ogv 25 s, 640 × 480; 3.04 MB
  
• Nonlinearity-of-Mechanochemical-Motions-in-Motor-Proteins-pcbi.1000814.s001.ogv 6.7 s, 240 × 320; 532 KB
  
• Nonlinearity-of-Mechanochemical-Motions-in-Motor-Proteins-pcbi.1000814.s002.ogv 8.4 s, 240 × 320; 314 KB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s022.ogv 32 s, 720 × 480; 8.82 MB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s023.ogv 32 s, 720 × 480; 8.98 MB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s024.ogv 32 s, 720 × 480; 10.55 MB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s025.ogv 32 s, 720 × 480; 9.88 MB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s026.ogv 32 s, 720 × 480; 9.96 MB
  
• Precursors-of-Dancing-and-Singing-to-Music-in-Three--to-Four-Months-Old-Infants-pone.0097680.s027.ogv 32 s, 720 × 480; 10.83 MB
  
• Protrusive-Push-versus-Enveloping-Embrace-Computational-Model-of-Phagocytosis-Predicts-Key-pcbi.1001068.s001.ogv 10 s, 540 × 360; 789 KB
  
• Protrusive-Push-versus-Enveloping-Embrace-Computational-Model-of-Phagocytosis-Predicts-Key-pcbi.1001068.s002.ogv 10 s, 540 × 360; 512 KB
  
• Quantifying-Morphological-Parameters-of-the-Terminal-Branching-Units-in-a-Mouse-Lung-by-Phase-pone.0063552.s001.ogv 13 s, 640 × 480; 10.89 MB
  
• Quantifying-Morphological-Parameters-of-the-Terminal-Branching-Units-in-a-Mouse-Lung-by-Phase-pone.0063552.s002.ogv 13 s, 640 × 480; 2.28 MB
  
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• Shape-Self-Regulation-in-Early-Lung-Morphogenesis-pone.0036925.s007.ogv 18 s, 834 × 1,668; 2.09 MB
  
• Shear-Forces-during-Blast-Not-Abrupt-Changes-in-Pressure-Alone-Generate-Calcium-Activity-in-Human-pone.0039421.s006.ogv 0.9 s, 512 × 512; 79 KB
  
• Shear-Forces-during-Blast-Not-Abrupt-Changes-in-Pressure-Alone-Generate-Calcium-Activity-in-Human-pone.0039421.s007.ogv 1.0 s, 512 × 512; 93 KB
  
• Shear-Forces-during-Blast-Not-Abrupt-Changes-in-Pressure-Alone-Generate-Calcium-Activity-in-Human-pone.0039421.s008.ogv 17 s, 325 × 325; 8.47 MB
  
• Shear-Forces-during-Blast-Not-Abrupt-Changes-in-Pressure-Alone-Generate-Calcium-Activity-in-Human-pone.0039421.s009.ogv 19 s, 325 × 325; 8.42 MB
  
• Spatial-and-Topological-Organization-of-DNA-Chains-Induced-by-Gene-Co-localization-pcbi.1000678.s007.ogv 7.5 s, 756 × 580; 6.15 MB
  
• Swimming-Using-Surface-Acoustic-Waves-pone.0042686.s002.ogv 33 s, 616 × 400; 4.24 MB
  
• Switching-Dynamics-in-an-Interpersonal-Competition-Brings-about-“Deadlock”-Synchronization-of-pone.0047911.s010.ogv 32 s, 160 × 120; 393 KB
  
• The-Emergence-of-Urban-Land-Use-Patterns-Driven-by-Dispersion-and-Aggregation-Mechanisms-pone.0080309.s002.ogv 28 s, 972 × 772; 8.06 MB
  
• Theoretical-Model-for-Cellular-Shapes-Driven-by-Protrusive-and-Adhesive-Forces-pcbi.1001127.s003.ogv 4.6 s, 508 × 364; 435 KB
  
• Theoretical-Model-for-Cellular-Shapes-Driven-by-Protrusive-and-Adhesive-Forces-pcbi.1001127.s004.ogv 5.3 s, 508 × 364; 228 KB
  
• Theoretical-Model-for-Cellular-Shapes-Driven-by-Protrusive-and-Adhesive-Forces-pcbi.1001127.s005.ogv 14 s, 508 × 364; 833 KB
  
• Three-Dimensional-Stochastic-Off-Lattice-Model-of-Binding-Chemistry-in-Crowded-Environments-pone.0030131.s001.ogv 20 s, 354 × 182; 5.77 MB
  
• Traffic-Experiment-Reveals-the-Nature-of-Car-Following-pone.0094351.s001.ogv 35 s, 640 × 360; 6.45 MB
  
• Traffic-Experiment-Reveals-the-Nature-of-Car-Following-pone.0094351.s002.ogv 31 s, 640 × 360; 1.41 MB
  
• Vibrot-a-Simple-Device-for-the-Conversion-of-Vibration-into-Rotation-Mediated-by-Friction-pone.0067838.s001.ogv 1 min 10 s, 375 × 288; 8.08 MB
  
• Vibrot-a-Simple-Device-for-the-Conversion-of-Vibration-into-Rotation-Mediated-by-Friction-pone.0067838.s002.ogv 25 s, 1,280 × 720; 2.55 MB
  
• Vibrot-a-Simple-Device-for-the-Conversion-of-Vibration-into-Rotation-Mediated-by-Friction-pone.0067838.s003.ogv 17 s, 640 × 480; 1.5 MB
  
• Vibrot-a-Simple-Device-for-the-Conversion-of-Vibration-into-Rotation-Mediated-by-Friction-pone.0067838.s004.ogv 47 s, 1,280 × 720; 6.93 MB
  
• Wet-Adhesion-and-Adhesive-Locomotion-of-Snails-on-Anti-Adhesive-Non-Wetting-Surfaces-pone.0036983.s001.ogv 1 min 0 s, 320 × 240; 3.18 MB