Category:Biological models

Subcategories

This category has the following 11 subcategories, out of 11 total.

Media in category "Biological models"

The following 200 files are in this category, out of 1,189 total.

• 
  2. Создание 3D-модели дикинсонии из Агар-агара в чашке Петри. Исследования проведены при финансовой поддержке гранта РНФ № 20-67-46028.jpg 4,272 × 2,848; 3.81 MB
  
• 3-D-Modelling-of-Megaloolithid-Clutches-Insights-about-Nest-Construction-and-Dinosaur-Behaviour-pone.0010362.s001.ogv 7.9 s, 720 × 576; 353 KB
  
• 
  3d cell collective.gif 750 × 364; 7.28 MB
  
• 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 Shortcut to Modeling Sickle Cell Disease - 28129665329.jpg 2,228 × 1,411; 333 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s009.ogv 40 s, 640 × 480; 5.54 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s010.ogv 20 s, 640 × 480; 368 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s011.ogv 20 s, 640 × 480; 1.16 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s012.ogv 20 s, 640 × 480; 1.01 MB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s013.ogv 20 s, 640 × 480; 918 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s014.ogv 20 s, 640 × 480; 783 KB
  
• A-Cell-Based-Model-for-Quorum-Sensing-in-Heterogeneous-Bacterial-Colonies-pcbi.1000819.s015.ogv 20 s, 640 × 480; 1.28 MB
  
• A-Cellular-Automata-Based-Mathematical-Model-for-Thymocyte-Development-pone.0008233.s001.ogv 1 min 52 s, 316 × 392; 8.8 MB
  
• A-Cellular-Automata-Based-Mathematical-Model-for-Thymocyte-Development-pone.0008233.s002.ogv 1 min 52 s, 316 × 392; 6.04 MB
  
• A-Cellular-Automata-Based-Mathematical-Model-for-Thymocyte-Development-pone.0008233.s003.ogv 1 min 52 s, 316 × 392; 10.33 MB
  
• A-chalcone-related-small-molecule-that-induces-methuosis-a-novel-form-of-non-apoptotic-cell-death-1476-4598-10-69-S1.ogv 1 min 0 s, 320 × 240; 1 MB
  
• A-Comprehensive-Model-of-the-Spatio-Temporal-Stem-Cell-and-Tissue-Organisation-in-the-Intestinal-pcbi.1001045.s004.ogv 54 s, 300 × 400; 12.68 MB
  
• A-Comprehensive-Model-of-the-Spatio-Temporal-Stem-Cell-and-Tissue-Organisation-in-the-Intestinal-pcbi.1001045.s005.ogv 58 s, 300 × 400; 10.89 MB
  
• A-Comprehensive-Panel-of-Three-Dimensional-Models-for-Studies-of-Prostate-Cancer-Growth-Invasion-pone.0010431.s013.ogv 1 min 6 s, 524 × 384; 8.71 MB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s004.ogv 51 s, 320 × 240; 358 KB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s005.ogv 51 s, 320 × 240; 515 KB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s006.ogv 51 s, 320 × 240; 706 KB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s007.ogv 55 s, 320 × 240; 2.33 MB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s008.ogv 55 s, 320 × 240; 4.84 MB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s009.ogv 55 s, 320 × 240; 3.85 MB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s010.ogv 51 s, 320 × 240; 333 KB
  
• A-Computational-Approach-to-Understand-In-Vitro-Alveolar-Morphogenesis-pone.0004819.s011.ogv 51 s, 320 × 240; 285 KB
  
• A-Computational-Clonal-Analysis-of-the-Developing-Mouse-Limb-Bud-pcbi.1001071.s009.ogv 18 s, 854 × 722; 16.25 MB
  
• A-Computational-Clonal-Analysis-of-the-Developing-Mouse-Limb-Bud-pcbi.1001071.s010.ogv 18 s, 917 × 719; 8.64 MB
  
• A-Computational-Clonal-Analysis-of-the-Developing-Mouse-Limb-Bud-pcbi.1001071.s011.ogv 25 s, 925 × 720; 1.48 MB
  
• A-Cryptic-Frizzled-Module-in-Cell-Surface-Collagen-18-Inhibits-Wntβ−Catenin-Signaling-pone.0001878.s005.ogv 2.3 s, 1,024 × 1,024; 130 KB
  
• A-Cryptic-Frizzled-Module-in-Cell-Surface-Collagen-18-Inhibits-Wntβ−Catenin-Signaling-pone.0001878.s006.ogv 2.0 s, 450 × 338; 77 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s002.ogv 6.0 s, 640 × 512; 369 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s003.ogv 15 s, 640 × 512; 91 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s004.ogv 5.2 s, 640 × 512; 362 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s005.ogv 8.0 s, 640 × 512; 397 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s006.ogv 15 s, 640 × 512; 340 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s007.ogv 15 s, 640 × 512; 198 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s008.ogv 15 s, 640 × 512; 203 KB
  
• A-Differential-Role-for-Neuropeptides-in-Acute-and-Chronic-Adaptive-Responses-to-Alcohol-pone.0010422.s009.ogv 6.0 s, 640 × 512; 166 KB
  
• A-local-glucose-and-oxygen-concentration-based-insulin-secretion-model-for-pancreatic-islets-1742-4682-8-20-S2.ogv 30 s, 640 × 480; 1.17 MB
  
• A-local-glucose-and-oxygen-concentration-based-insulin-secretion-model-for-pancreatic-islets-1742-4682-8-20-S3.ogv 30 s, 640 × 480; 1.27 MB
  
• A-Mathematical-Model-for-Neutrophil-Gradient-Sensing-and-Polarization-pcbi.0030036.sv001.ogv 0.0 s, 432 × 336; 2.28 MB
  
• A-Mathematical-Model-for-Neutrophil-Gradient-Sensing-and-Polarization-pcbi.0030036.sv002.ogv 5.6 s, 432 × 336; 1.09 MB
  
• A-Mathematical-Model-of-Muscle-Containing-Heterogeneous-Half-Sarcomeres-Exhibits-Residual-Force-pcbi.1002156.s001.ogv 34 s, 528 × 768; 570 KB
  
• A-Mathematical-Model-of-Muscle-Containing-Heterogeneous-Half-Sarcomeres-Exhibits-Residual-Force-pcbi.1002156.s002.ogv 27 s, 528 × 768; 512 KB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s001.ogv 8.0 s, 640 × 480; 485 KB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s002.ogv 18 s, 640 × 480; 1.19 MB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s008.ogv 25 s, 640 × 480; 2.91 MB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s009.ogv 28 s, 640 × 480; 1.51 MB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s010.ogv 32 s, 640 × 480; 2.79 MB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s011.ogv 18 s, 512 × 512; 382 KB
  
• A-Modular-Library-of-Small-Molecule-Signals-Regulates-Social-Behaviors-in-Caenorhabditis-elegans-pbio.1001237.s012.ogv 24 s, 640 × 480; 5.19 MB
  
• A-Multi-cell-Multi-scale-Model-of-Vertebrate-Segmentation-and-Somite-Formation-pcbi.1002155.s016.ogv 1 min 3 s, 640 × 480; 6.71 MB
  
• A-Multi-cell-Multi-scale-Model-of-Vertebrate-Segmentation-and-Somite-Formation-pcbi.1002155.s017.ogv 1 min 2 s, 640 × 480; 6.06 MB
  
• A-Multi-cell-Multi-scale-Model-of-Vertebrate-Segmentation-and-Somite-Formation-pcbi.1002155.s018.ogv 1 min 2 s, 640 × 480; 6.04 MB
  
• A-Multi-cell-Multi-scale-Model-of-Vertebrate-Segmentation-and-Somite-Formation-pcbi.1002155.s019.ogv 29 s, 640 × 480; 630 KB
  
• A-Multi-cell-Multi-scale-Model-of-Vertebrate-Segmentation-and-Somite-Formation-pcbi.1002155.s020.ogv 2 min 5 s, 640 × 480; 5.94 MB
  
• A-Near-Infrared-Cell-Tracker-Reagent-for-Multiscopic-In-Vivo-Imaging-and-Quantification-of-pone.0001075.s001.ogv 4.0 s, 320 × 240; 305 KB
  
• A-Near-Infrared-Cell-Tracker-Reagent-for-Multiscopic-In-Vivo-Imaging-and-Quantification-of-pone.0001075.s002.ogv 14 s, 320 × 240; 328 KB
  
• A-Near-Infrared-Cell-Tracker-Reagent-for-Multiscopic-In-Vivo-Imaging-and-Quantification-of-pone.0001075.s003.ogv 1.2 s, 320 × 240; 21 KB
  
• A-plausible-mechanism-for-auxin-patterning-along-the-developing-root-1752-0509-4-98-S9.ogv 23 s, 548 × 330; 227 KB
  
• A-Putative-Cation-Channel-NCA-1-and-a-Novel-Protein-UNC-80-Transmit-Neuronal-Activity-in-C.-elegans-pbio.0060055.sv004.ogv 33 s, 320 × 240; 502 KB
  
• A-Putative-Cation-Channel-NCA-1-and-a-Novel-Protein-UNC-80-Transmit-Neuronal-Activity-in-C.-elegans-pbio.0060055.sv005.ogv 2 min 30 s, 136 × 118; 314 KB
  
• A-Quorum-Sensing-Factor-in-Vegetative-Dictyostelium-Discoideum-Cells-Revealed-by-Quantitative-pone.0026901.s009.ogv 4.8 s, 294 × 67; 106 KB
  
• A-Quorum-Sensing-Factor-in-Vegetative-Dictyostelium-Discoideum-Cells-Revealed-by-Quantitative-pone.0026901.s010.ogv 7.5 s, 1,168 × 354; 4.44 MB
  
• A-Reaction-Diffusion-Model-of-ROS-Induced-ROS-Release-in-a-Mitochondrial-Network-pcbi.1000657.s004.ogv 1.9 s, 324 × 120; 1.32 MB
  
• A-Reaction-Diffusion-Model-of-ROS-Induced-ROS-Release-in-a-Mitochondrial-Network-pcbi.1000657.s005.ogv 1.6 s, 316 × 134; 1.11 MB
  
• A-Reaction-Diffusion-Model-of-ROS-Induced-ROS-Release-in-a-Mitochondrial-Network-pcbi.1000657.s006.ogv 1 min 38 s, 472 × 136; 13.17 MB
  
• A-Reaction-Diffusion-Model-of-ROS-Induced-ROS-Release-in-a-Mitochondrial-Network-pcbi.1000657.s007.ogv 29 s, 472 × 136; 3.67 MB
  
• A-Second-Generation-Device-for-Automated-Training-and-Quantitative-Behavior-Analyses-of-Molecularly-pone.0014370.s005.ogv 1 min 4 s, 1,200 × 600; 3.68 MB
  
• A-simple-rule-for-quadrupedal-gait-generation-determined-by-leg-loading-feedback-a-modeling-study-srep08169-s1.ogv 1 min 10 s, 854 × 480; 10.43 MB
  
• A-simple-rule-for-quadrupedal-gait-generation-determined-by-leg-loading-feedback-a-modeling-study-srep08169-s2.ogv 2 min 21 s, 854 × 480; 18.33 MB
  
• A-Spatio-Temporal-Model-of-Notch-Signalling-in-the-Zebrafish-Segmentation-Clock-Conditions-for-pone.0016980.s002.ogv 1 min 0 s, 640 × 480; 673 KB
  
• A-Spatio-Temporal-Model-of-Notch-Signalling-in-the-Zebrafish-Segmentation-Clock-Conditions-for-pone.0016980.s003.ogv 1 min 0 s, 640 × 480; 1.59 MB
  
• A-Spatio-Temporal-Model-of-Notch-Signalling-in-the-Zebrafish-Segmentation-Clock-Conditions-for-pone.0016980.s004.ogv 1 min 0 s, 640 × 480; 983 KB
  
• A-Spatio-Temporal-Model-of-Notch-Signalling-in-the-Zebrafish-Segmentation-Clock-Conditions-for-pone.0016980.s005.ogv 1 min 0 s, 640 × 480; 2.48 MB
  
• A-synthetic-modular-approach-for-modeling-the-role-of-the-3D-microenvironment-in-tumor-progression-srep17814-s2.ogv 6.5 s, 479 × 495; 631 KB
  
• A-synthetic-modular-approach-for-modeling-the-role-of-the-3D-microenvironment-in-tumor-progression-srep17814-s3.ogv 5.0 s, 100 × 178; 74 KB
  
• A-synthetic-modular-approach-for-modeling-the-role-of-the-3D-microenvironment-in-tumor-progression-srep17814-s4.ogv 10 s, 389 × 466; 453 KB
  
• A-synthetic-modular-approach-for-modeling-the-role-of-the-3D-microenvironment-in-tumor-progression-srep17814-s5.ogv 9.1 s, 385 × 405; 228 KB
  
• A-synthetic-modular-approach-for-modeling-the-role-of-the-3D-microenvironment-in-tumor-progression-srep17814-s6.ogv 6.1 s, 400 × 400; 213 KB
  
• A-theoretical-model-of-the-application-of-RF-energy-to-the-airway-wall-and-its-experimental-1475-925X-9-81-S1.ogv 54 s, 320 × 240; 1.13 MB
  
• A-Theory-of-Cheap-Control-in-Embodied-Systems-pcbi.1004427.s007.ogv 30 s, 1,280 × 720; 11.61 MB
  
• A-Theory-of-Cheap-Control-in-Embodied-Systems-pcbi.1004427.s008.ogv 30 s, 1,280 × 720; 8.81 MB
  
• A-Theory-of-Cheap-Control-in-Embodied-Systems-pcbi.1004427.s009.ogv 30 s, 1,280 × 720; 8.85 MB
  
• A-Theory-of-Cheap-Control-in-Embodied-Systems-pcbi.1004427.s010.ogv 30 s, 1,280 × 720; 9.56 MB
  
• A-Two-Dimensional-Model-of-the-Colonic-Crypt-Accounting-for-the-Role-of-the-Basement-Membrane-and-pcbi.1002515.s001.ogv 18 s, 450 × 250; 3.96 MB
  
• A-Two-Dimensional-Model-of-the-Colonic-Crypt-Accounting-for-the-Role-of-the-Basement-Membrane-and-pcbi.1002515.s002.ogv 18 s, 500 × 410; 6.71 MB
  
• A-Two-Dimensional-Model-of-the-Colonic-Crypt-Accounting-for-the-Role-of-the-Basement-Membrane-and-pcbi.1002515.s003.ogv 22 s, 250 × 390; 4.07 MB
  
• Activated-Membrane-Patches-Guide-Chemotactic-Cell-Motility-pcbi.1002044.s007.ogv 7.1 s, 435 × 343; 162 KB
  
• Activated-Membrane-Patches-Guide-Chemotactic-Cell-Motility-pcbi.1002044.s008.ogv 7.1 s, 435 × 343; 142 KB
  
• Activated-Membrane-Patches-Guide-Chemotactic-Cell-Motility-pcbi.1002044.s009.ogv 22 s, 389 × 734; 492 KB
  
• Activated-Membrane-Patches-Guide-Chemotactic-Cell-Motility-pcbi.1002044.s010.ogv 22 s, 389 × 734; 521 KB
  
• Activated-Membrane-Patches-Guide-Chemotactic-Cell-Motility-pcbi.1002044.s011.ogv 27 s, 389 × 734; 507 KB
  
• Adaptation-of-the-Spore-Discharge-Mechanism-in-the-Basidiomycota-pone.0004163.s003.ogv 5.4 s, 256 × 128; 10 KB
  
• Adaptation-of-the-Spore-Discharge-Mechanism-in-the-Basidiomycota-pone.0004163.s004.ogv 0.7 s, 128 × 128; 7 KB
  
• Adherent-Primary-Cultures-of-Mouse-Intercostal-Muscle-Fibers-for-Isolated-Fiber-Studies-393740.f2.ogv 10 s, 519 × 512; 6.78 MB
  
• Adherent-Primary-Cultures-of-Mouse-Intercostal-Muscle-Fibers-for-Isolated-Fiber-Studies-393740.f3.ogv 10 s, 519 × 512; 1.97 MB
  
• Adherent-Primary-Cultures-of-Mouse-Intercostal-Muscle-Fibers-for-Isolated-Fiber-Studies-393740.f4.ogv 10 s, 519 × 512; 3.56 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s017.ogv 1 min 1 s, 637 × 616; 7.11 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s018.ogv 1 min 1 s, 588 × 568; 6.38 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s019.ogv 59 s, 637 × 616; 6.8 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s020.ogv 1 min 1 s, 588 × 568; 6.55 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s021.ogv 1 min 1 s, 637 × 616; 7.29 MB
  
• Adhesion-Failures-Determine-the-Pattern-of-Choroidal-Neovascularization-in-the-Eye-A-Computer-pcbi.1002440.s022.ogv 1 min 1 s, 637 × 616; 7.16 MB
  
• Advances-in-establishment-and-analysis-of-three-dimensional-tumor-spheroid-based-functional-assays-1741-7007-10-29-S4.ogv 29 s, 853 × 480; 3.22 MB
  
• Advances-in-establishment-and-analysis-of-three-dimensional-tumor-spheroid-based-functional-assays-1741-7007-10-29-S5.ogv 13 s, 853 × 480; 795 KB
  
• Advances-in-establishment-and-analysis-of-three-dimensional-tumor-spheroid-based-functional-assays-1741-7007-10-29-S6.ogv 12 s, 853 × 480; 270 KB
  
• Aging-and-Death-in-an-Organism-That-Reproduces-by-Morphologically-Symmetric-Division-pbio.0030045.sv001.ogv 7.0 s, 232 × 240; 142 KB
  
• Akt1-Intramitochondrial-Cycling-Is-a-Crucial-Step-in-the-Redox-Modulation-of-Cell-Cycle-Progression-pone.0007523.s013.ogv 16 s, 640 × 640; 445 KB
  
• Akt1-Intramitochondrial-Cycling-Is-a-Crucial-Step-in-the-Redox-Modulation-of-Cell-Cycle-Progression-pone.0007523.s014.ogv 16 s, 256 × 256; 161 KB
  
• Akt1-Intramitochondrial-Cycling-Is-a-Crucial-Step-in-the-Redox-Modulation-of-Cell-Cycle-Progression-pone.0007523.s015.ogv 16 s, 640 × 640; 345 KB
  
• Akt1-Intramitochondrial-Cycling-Is-a-Crucial-Step-in-the-Redox-Modulation-of-Cell-Cycle-Progression-pone.0007523.s016.ogv 16 s, 256 × 253; 101 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s010.ogv 7.0 s, 256 × 256; 276 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s011.ogv 7.0 s, 256 × 256; 233 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s012.ogv 10 s, 256 × 256; 453 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s013.ogv 15 s, 256 × 256; 164 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s014.ogv 25 s, 256 × 256; 806 KB
  
• An-Adhesion-Dependent-Switch-between-Mechanisms-That-Determine-Motile-Cell-Shape-pbio.1001059.s015.ogv 18 s, 720 × 496; 9.83 MB
  
• An-ALS-Linked-Mutant-SOD1-Produces-a-Locomotor-Defect-Associated-with-Aggregation-and-Synaptic-pgen.1000350.s013.ogv 29 s, 640 × 480; 1.04 MB
  
• An-ALS-Linked-Mutant-SOD1-Produces-a-Locomotor-Defect-Associated-with-Aggregation-and-Synaptic-pgen.1000350.s015.ogv 30 s, 480 × 360; 366 KB
  
• An-Emerging-Allee-Effect-Is-Critical-for-Tumor-Initiation-and-Persistence-pcbi.1004366.s003.ogv 36 s, 180 × 180; 591 KB
  
• An-Emerging-Allee-Effect-Is-Critical-for-Tumor-Initiation-and-Persistence-pcbi.1004366.s004.ogv 36 s, 180 × 180; 1.38 MB
  
• An-Excitable-Cortex-and-Memory-Model-Successfully-Predicts-New-Pseudopod-Dynamics-pone.0033528.s003.ogv 18 s, 386 × 442; 530 KB
  
• An-Experimental-and-Computational-Study-of-the-Effect-of-ActA-Polarity-on-the-Speed-of-Listeria-pcbi.1000434.s011.ogv 6.1 s, 640 × 640; 1.46 MB
  
• An-Integrin-Dependent-Role-of-Pouch-Endoderm-in-Hyoid-Cartilage-Development-pbio.0020244.sv001.ogv 20 s, 519 × 512; 1.72 MB
  
• An-Integrin-Dependent-Role-of-Pouch-Endoderm-in-Hyoid-Cartilage-Development-pbio.0020244.sv002.ogv 20 s, 519 × 512; 2.33 MB
  
• An-Integrin-Dependent-Role-of-Pouch-Endoderm-in-Hyoid-Cartilage-Development-pbio.0020244.sv003.ogv 20 s, 519 × 512; 1.77 MB
  
• Arginylation-Dependent-Neural-Crest-Cell-Migration-Is-Essential-for-Mouse-Development-pgen.1000878.s016.ogv 19 s, 736 × 608; 9.69 MB
  
• Arginylation-Dependent-Neural-Crest-Cell-Migration-Is-Essential-for-Mouse-Development-pgen.1000878.s017.ogv 33 s, 592 × 496; 2.42 MB
  
• Arginylation-Dependent-Neural-Crest-Cell-Migration-Is-Essential-for-Mouse-Development-pgen.1000878.s018.ogv 12 s, 277 × 224; 2.06 MB
  
• Arginylation-Dependent-Neural-Crest-Cell-Migration-Is-Essential-for-Mouse-Development-pgen.1000878.s019.ogv 12 s, 304 × 304; 1.96 MB
  
• Arginylation-Dependent-Neural-Crest-Cell-Migration-Is-Essential-for-Mouse-Development-pgen.1000878.s020.ogv 9.0 s, 749 × 706; 2.83 MB
  
• 
  Aristotle's heart temperature model.png 960 × 720; 60 KB
  
• 
  Aristotle's metabolism.png 960 × 720; 68 KB
  
• 
  Aristotle's metabolism.sr.png 900 × 675; 58 KB
  
• 
  Aristotle's model of information processing.png 960 × 720; 76 KB
  
• 
  Aristotle's model of Inheritance.png 960 × 720; 109 KB
  
• 
  Aristotle's model of Inheritance.svg 960 × 720; 13 KB
  
• Automated-characterization-of-cell-shape-changes-during-amoeboid-motility-by-skeletonization-1752-0509-4-33-S1.ogv 20 s, 996 × 484; 475 KB
  
• Automated-characterization-of-cell-shape-changes-during-amoeboid-motility-by-skeletonization-1752-0509-4-33-S4.ogv 13 s, 328 × 92; 76 KB
  
• Bare-Bones-Pattern-Formation-A-Core-Regulatory-Network-in-Varying-Geometries-Reproduces-Major-pone.0010892.s006.ogv 30 s, 881 × 383; 140 KB
  
• Bare-Bones-Pattern-Formation-A-Core-Regulatory-Network-in-Varying-Geometries-Reproduces-Major-pone.0010892.s007.ogv 10 s, 881 × 383; 61 KB
  
• Bare-Bones-Pattern-Formation-A-Core-Regulatory-Network-in-Varying-Geometries-Reproduces-Major-pone.0010892.s008.ogv 20 s, 881 × 383; 99 KB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s005.ogv 1 min 2 s, 976 × 720; 4.96 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s006.ogv 3 min 39 s, 976 × 720; 13.5 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s007.ogv 1 min 37 s, 964 × 720; 6 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s008.ogv 2 min 12 s, 964 × 720; 10.87 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s009.ogv 2 min 19 s, 964 × 720; 11.7 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s010.ogv 3 min 19 s, 1,106 × 720; 21.04 MB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s011.ogv 6.0 s, 318 × 333; 58 KB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s012.ogv 6.2 s, 293 × 333; 51 KB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s013.ogv 8.6 s, 320 × 333; 199 KB
  
• BioSig3D-High-Content-Screening-of-Three-Dimensional-Cell-Culture-Models-pone.0148379.s014.ogv 8.0 s, 382 × 333; 354 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s001.ogv 12 s, 134 × 137; 104 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s002.ogv 1.8 s, 818 × 716; 829 KB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s003.ogv 5.6 s, 1,000 × 484; 1.09 MB
  
• Bistable-Forespore-Engulfment-in-Bacillus-subtilis-by-a-Zipper-Mechanism-in-Absence-of-the-Cell-Wall-pcbi.1003912.s004.ogv 12 s, 218 × 116; 55 KB
  
• BMP2-induced-chemotaxis-requires-PI3K-p55γp110α-dependent-phosphatidylinositol-(345)-triphosphate-1741-7007-12-43-S6.ogv 18 s, 1,392 × 1,040; 4.93 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv001.ogv 13 s, 512 × 512; 10.42 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv002.ogv 12 s, 512 × 512; 13.91 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv003.ogv 10 s, 512 × 512; 10.81 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv004.ogv 13 s, 512 × 512; 15.82 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv005.ogv 14 s, 1,000 × 500; 2 MB
  
• Calcium-Dynamics-of-Cortical-Astrocytic-Networks-In-Vivo-pbio.0020096.sv006.ogv 36 s, 284 × 164; 19.01 MB
  
• Calcium-Signals-Driven-by-Single-Channel-Noise-pcbi.1000870.s002.ogv 6.4 s, 260 × 260; 882 KB
  
• Cancer-Cell-Invasion-Is-Enhanced-by-Applied-Mechanical-Stimulation-pone.0017277.s001.ogv 0.9 s, 640 × 480; 31 KB
  
• Cancer-Cell-Invasion-Is-Enhanced-by-Applied-Mechanical-Stimulation-pone.0017277.s002.ogv 1.2 s, 640 × 480; 34 KB
  
• Cancer-Cell-Invasion-Is-Enhanced-by-Applied-Mechanical-Stimulation-pone.0017277.s003.ogv 3.8 s, 320 × 240; 35 KB
  
• Caspase-dependent-cell-death-associated-release-of-nucleosome-and-damage-associated-molecular-cddis2014450x2.ogv 58 s, 528 × 528; 5.8 MB
  
• Causes-of-Abnormal-Ca2+-Transients-in-Guinea-Pig-Pathophysiological-Ventricular-Muscle-Revealed-by-pone.0007069.s003.ogv 9.0 s, 116 × 254; 8.29 MB
  
• Causes-of-Abnormal-Ca2+-Transients-in-Guinea-Pig-Pathophysiological-Ventricular-Muscle-Revealed-by-pone.0007069.s004.ogv 9.0 s, 116 × 254; 7.8 MB
  
• Ccdc80-l1-Is-Involved-in-Axon-Pathfinding-of-Zebrafish-Motoneurons-pone.0031851.s007.ogv 2.7 s, 720 × 576; 106 KB
  
• Ccdc80-l1-Is-Involved-in-Axon-Pathfinding-of-Zebrafish-Motoneurons-pone.0031851.s008.ogv 5.0 s, 720 × 576; 242 KB
  
• Cell-Cycle-Dependent-Microtubule-Based-Dynamic-Transport-of-Cytoplasmic-Dynein-in-Mammalian-Cells-pone.0007827.s006.ogv 3.8 s, 210 × 210; 167 KB
  
• Cell-Cycle-Dependent-Microtubule-Based-Dynamic-Transport-of-Cytoplasmic-Dynein-in-Mammalian-Cells-pone.0007827.s007.ogv 3.2 s, 204 × 182; 623 KB
  
• Cell-Cycle-Dependent-Microtubule-Based-Dynamic-Transport-of-Cytoplasmic-Dynein-in-Mammalian-Cells-pone.0007827.s009.ogv 2.1 s, 744 × 242; 2.76 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s007.ogv 22 s, 183 × 184; 1.2 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s008.ogv 22 s, 184 × 184; 802 KB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s009.ogv 40 s, 179 × 180; 1.69 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s010.ogv 13 s, 347 × 346; 2.72 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s011.ogv 15 s, 512 × 512; 4.44 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s012.ogv 9.5 s, 323 × 325; 371 KB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s013.ogv 43 s, 131 × 131; 3.82 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s014.ogv 45 s, 132 × 133; 1.45 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s015.ogv 22 s, 349 × 349; 2.36 MB
  
• Cell-Shape-Dynamics-From-Waves-to-Migration-pcbi.1002392.s016.ogv 22 s, 336 × 341; 2.06 MB
  
• Cell-Sorting-at-the-AP-Boundary-in-the-Drosophila-Wing-Primordium-A-Computational-Model-to-pcbi.1002025.s005.ogv 38 s, 576 × 432; 23.73 MB
  
• Cell-Sorting-at-the-AP-Boundary-in-the-Drosophila-Wing-Primordium-A-Computational-Model-to-pcbi.1002025.s006.ogv 55 s, 640 × 480; 21.85 MB
  
• Cell-Sorting-at-the-AP-Boundary-in-the-Drosophila-Wing-Primordium-A-Computational-Model-to-pcbi.1002025.s007.ogv 35 s, 600 × 452; 8.3 MB
  
• Cell-to-Cell-Heterogeneity-in-Cortical-Tension-Specifies-Curvature-of-Contact-Surfaces-in-pone.0030224.s002.ogv 5.0 s, 510 × 306; 1.87 MB
  
• Cell-to-Cell-Heterogeneity-in-Cortical-Tension-Specifies-Curvature-of-Contact-Surfaces-in-pone.0030224.s003.ogv 5.0 s, 488 × 308; 1.28 MB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s001.ogv 16 s, 300 × 224; 2.7 MB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s002.ogv 58 s, 544 × 240; 3.35 MB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s003.ogv 8.9 s, 1,392 × 934; 7.51 MB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s004.ogv 14 s, 139 × 139; 146 KB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s005.ogv 14 s, 348 × 234; 666 KB
  
• Cells-Assemble-Invadopodia-Like-Structures-and-Invade-into-Matrigel-in-a-Matrix-Metalloprotease-pone.0030605.s006.ogv 19 s, 348 × 234; 1.39 MB