Category:Videos of cardiovascular anatomy

Subcategories

This category has only the following subcategory.

Media in category "Videos of cardiovascular anatomy"

The following 197 files are in this category, out of 197 total.

• 31P-NMR-2D-Mapping-of-Creatine-Kinase-Forward-Flux-Rate-in-Hearts-with-Postinfarction-Left-pone.0162149.s001.ogv 9.2 s, 648 × 364; 3.54 MB
  
• 31P-NMR-2D-Mapping-of-Creatine-Kinase-Forward-Flux-Rate-in-Hearts-with-Postinfarction-Left-pone.0162149.s002.ogv 5.7 s, 864 × 576; 3.57 MB
  
• A-Novel-Model-of-Intravital-Platelet-Imaging-Using-CD41-ZsGreen1-Transgenic-Rats-pone.0154661.s001.ogv 12 s, 400 × 400; 2.89 MB
  
• A-Novel-Model-of-Intravital-Platelet-Imaging-Using-CD41-ZsGreen1-Transgenic-Rats-pone.0154661.s002.ogv 25 s, 1,024 × 348; 3.32 MB
  
• A-Novel-Model-of-Intravital-Platelet-Imaging-Using-CD41-ZsGreen1-Transgenic-Rats-pone.0154661.s003.ogv 25 s, 1,024 × 348; 359 KB
  
• A-Novel-Mouse-Segmentation-Method-Based-on-Dynamic-Contrast-Enhanced-Micro-CT-Images-pone.0169424.s001.ogv 6.5 s, 987 × 736; 1.9 MB
  
• A-Novel-Mouse-Segmentation-Method-Based-on-Dynamic-Contrast-Enhanced-Micro-CT-Images-pone.0169424.s002.ogv 6.5 s, 987 × 736; 1.92 MB
  
• A-Novel-Mouse-Segmentation-Method-Based-on-Dynamic-Contrast-Enhanced-Micro-CT-Images-pone.0169424.s003.ogv 6.5 s, 987 × 736; 2.18 MB
  
• A-Three-Dimensional-Human-Atrial-Model-with-Fiber-Orientation.-Electrograms-and-Arrhythmic-pone.0050883.s001.ogv 33 s, 404 × 280; 5.14 MB
  
• A-Three-Dimensional-Human-Atrial-Model-with-Fiber-Orientation.-Electrograms-and-Arrhythmic-pone.0050883.s002.ogv 33 s, 404 × 280; 3.92 MB
  
• A-Three-Dimensional-Human-Atrial-Model-with-Fiber-Orientation.-Electrograms-and-Arrhythmic-pone.0050883.s003.ogv 33 s, 404 × 280; 4.14 MB
  
• A-Three-Dimensional-Human-Atrial-Model-with-Fiber-Orientation.-Electrograms-and-Arrhythmic-pone.0050883.s004.ogv 33 s, 404 × 280; 4.64 MB
  
• A-Tubular-Biomaterial-Construct-Exhibiting-a-Negative-Poissons-Ratio-pone.0155681.s001.ogv 30 s, 640 × 480; 1.53 MB
  
• A-Tubular-Biomaterial-Construct-Exhibiting-a-Negative-Poissons-Ratio-pone.0155681.s002.ogv 22 s, 640 × 480; 1.63 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s008.ogv 12 s, 1,488 × 832; 8.15 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s009.ogv 12 s, 1,488 × 832; 6.9 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s010.ogv 12 s, 1,488 × 832; 7.95 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s011.ogv 12 s, 1,488 × 832; 8.69 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s012.ogv 12 s, 1,488 × 832; 7.05 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s013.ogv 12 s, 1,488 × 832; 10.69 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s014.ogv 12 s, 1,488 × 832; 11.64 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s015.ogv 12 s, 1,488 × 832; 8.89 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s016.ogv 12 s, 1,488 × 832; 8.84 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s017.ogv 12 s, 1,920 × 1,004; 9.7 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s018.ogv 12 s, 1,920 × 1,004; 9.71 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s019.ogv 12 s, 1,920 × 1,004; 9.17 MB
  
• A-Validated-Multiscale-In-Silico-Model-for-Mechano-sensitive-Tumour-Angiogenesis-and-Growth-pcbi.1005259.s020.ogv 12 s, 1,920 × 1,004; 9.2 MB
  
• Adherence-of-Staphylococcus-aureus-to-Dyneema-Purity®-Patches-and-to-Clinically-Used-Cardiovascular-pone.0162216.s001.ogv 13 s, 1,392 × 1,040; 6.26 MB
  
• Adherence-of-Staphylococcus-aureus-to-Dyneema-Purity®-Patches-and-to-Clinically-Used-Cardiovascular-pone.0162216.s002.ogv 13 s, 1,392 × 1,040; 1.09 MB
  
• Adherence-of-Staphylococcus-aureus-to-Dyneema-Purity®-Patches-and-to-Clinically-Used-Cardiovascular-pone.0162216.s003.ogv 13 s, 1,392 × 1,040; 386 KB
  
• Calcific-Aortic-Valve-Disease-Is-Associated-with-Layer-Specific-Alterations-in-Collagen-Architecture-pone.0163858.s004.ogv 26 s, 512 × 512; 944 KB
  
• Calcific-Aortic-Valve-Disease-Is-Associated-with-Layer-Specific-Alterations-in-Collagen-Architecture-pone.0163858.s005.ogv 26 s, 512 × 512; 542 KB
  
• Calcific-Aortic-Valve-Disease-Is-Associated-with-Layer-Specific-Alterations-in-Collagen-Architecture-pone.0163858.s006.ogv 26 s, 512 × 512; 957 KB
  
• Cardiac-Myocyte-Diversity-and-a-Fibroblast-Network-in-the-Junctional-Region-of-the-Zebrafish-Heart-pone.0072388.s003.ogv 2.5 s, 1,312 × 1,040; 2.17 MB
  
• Cathepsin-Activity-Based-Probes-and-Inhibitor-for-Preclinical-Atherosclerosis-Imaging-and-pone.0160522.s002.ogv 10 s, 640 × 480; 443 KB
  
• Cathepsin-Activity-Based-Probes-and-Inhibitor-for-Preclinical-Atherosclerosis-Imaging-and-pone.0160522.s003.ogv 10 s, 640 × 480; 443 KB
  
• Cellular-Basis-of-Pineal-Gland-Development-Emerging-Role-of-Microglia-as-Phenotype-Regulator-pone.0167063.s003.ogv 59 s, 1,280 × 720; 3.27 MB
  
• Cellular-Basis-of-Pineal-Gland-Development-Emerging-Role-of-Microglia-as-Phenotype-Regulator-pone.0167063.s004.ogv 41 s, 1,920 × 1,080; 2.76 MB
  
• Cellular-Basis-of-Pineal-Gland-Development-Emerging-Role-of-Microglia-as-Phenotype-Regulator-pone.0167063.s005.ogv 1 min 5 s, 1,280 × 720; 4.06 MB
  
• Cellular-Basis-of-Pineal-Gland-Development-Emerging-Role-of-Microglia-as-Phenotype-Regulator-pone.0167063.s006.ogv 32 s, 1,920 × 1,080; 4.55 MB
  
• Chronic-High-Fat-Diet-Impairs-Collecting-Lymphatic-Vessel-Function-in-Mice-pone.0094713.s003.ogv 18 s, 512 × 512; 230 KB
  
• Chronic-High-Fat-Diet-Impairs-Collecting-Lymphatic-Vessel-Function-in-Mice-pone.0094713.s004.ogv 18 s, 512 × 512; 291 KB
  
• Chronic-High-Fat-Diet-Impairs-Collecting-Lymphatic-Vessel-Function-in-Mice-pone.0094713.s005.ogv 14 s, 512 × 512; 110 KB
  
• Chronic-High-Fat-Diet-Impairs-Collecting-Lymphatic-Vessel-Function-in-Mice-pone.0094713.s006.ogv 14 s, 512 × 512; 117 KB
  
• Computational-Investigation-of-Cerebrospinal-Fluid-Dynamics-in-the-Posterior-Cranial-Fossa-and-pone.0162938.s002.ogv 5.1 s, 588 × 688; 603 KB
  
• Contribution-of-the-Arterial-System-and-the-Heart-to-Blood-Pressure-during-Normal-Aging-–-A-pone.0157493.s001.ogv 3 min 25 s, 1,920 × 1,080; 79.42 MB
  
• Creating-High-Resolution-Multiscale-Maps-of-Human-Tissue-Using-Multi-beam-SEM-pcbi.1005217.s004.ogv 5.0 s, 1,000 × 1,149; 5.71 MB
  
• Creating-High-Resolution-Multiscale-Maps-of-Human-Tissue-Using-Multi-beam-SEM-pcbi.1005217.s005.ogv 4.2 s, 742 × 980; 12.66 MB
  
• Creating-High-Resolution-Multiscale-Maps-of-Human-Tissue-Using-Multi-beam-SEM-pcbi.1005217.s006.ogv 5.0 s, 750 × 652; 24.87 MB
  
• Critical-Transitions-in-Early-Embryonic-Aortic-Arch-Patterning-and-Hemodynamics-pone.0060271.s009.ogv 9.7 s, 757 × 756; 5.21 MB
  
• Cyp26-Enzymes-Facilitate-Second-Heart-Field-Progenitor-Addition-and-Maintenance-of-Ventricular-pbio.2000504.s013.ogv 5.2 s, 640 × 360; 303 KB
  
• Cyp26-Enzymes-Facilitate-Second-Heart-Field-Progenitor-Addition-and-Maintenance-of-Ventricular-pbio.2000504.s014.ogv 5.2 s, 640 × 360; 293 KB
  
• Deeper-Penetration-of-Erythrocytes-into-the-Endothelial-Glycocalyx-Is-Associated-with-Impaired-pone.0096477.s001.ogv 2.0 s, 740 × 554; 759 KB
  
• Deeper-Penetration-of-Erythrocytes-into-the-Endothelial-Glycocalyx-Is-Associated-with-Impaired-pone.0096477.s002.ogv 2.0 s, 744 × 562; 676 KB
  
• Development-and-Fibronectin-Signaling-Requirements-of-the-Zebrafish-Interrenal-Vessel-pone.0043040.s006.ogv 6.4 s, 640 × 480; 1.04 MB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s010.ogv 15 s, 854 × 480; 1.05 MB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s011.ogv 15 s, 854 × 480; 1.05 MB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s012.ogv 15 s, 854 × 480; 906 KB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s013.ogv 15 s, 854 × 480; 1.21 MB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s014.ogv 15 s, 854 × 480; 1,013 KB
  
• Development-of-the-Hearts-of-Lizards-and-Snakes-and-Perspectives-to-Cardiac-Evolution-pone.0063651.s015.ogv 15 s, 854 × 480; 1 MB
  
• Distinct-Contributions-of-Astrocytes-and-Pericytes-to-Neuroinflammation-Identified-in-a-3D-Human-pone.0150360.s006.ogv 5.1 s, 1,920 × 1,080; 3.53 MB
  
• Distinct-Contributions-of-Astrocytes-and-Pericytes-to-Neuroinflammation-Identified-in-a-3D-Human-pone.0150360.s007.ogv 5.1 s, 1,920 × 1,080; 2.36 MB
  
• Distinctive-Left-Sided-Distribution-of-Adrenergic-Derived-Cells-in-the-Adult-Mouse-Heart-pone.0022811.s001.ogv 49 s, 348 × 312; 1.7 MB
  
• Distinctive-Left-Sided-Distribution-of-Adrenergic-Derived-Cells-in-the-Adult-Mouse-Heart-pone.0022811.s002.ogv 55 s, 348 × 312; 3.63 MB
  
• Embryonic-Ethanol-Exposure-Dysregulates-BMP-and-Notch-Signaling-Leading-to-Persistent-Atrio-pone.0161205.s004.ogv 1 min 7 s, 356 × 376; 1.9 MB
  
• Embryonic-Ethanol-Exposure-Dysregulates-BMP-and-Notch-Signaling-Leading-to-Persistent-Atrio-pone.0161205.s005.ogv 1 min 7 s, 352 × 356; 1.59 MB
  
• Embryonic-Ethanol-Exposure-Dysregulates-BMP-and-Notch-Signaling-Leading-to-Persistent-Atrio-pone.0161205.s006.ogv 1 min 7 s, 404 × 400; 1.32 MB
  
• Endocannabinoids-Control-Platelet-Activation-and-Limit-Aggregate-Formation-under-Flow-pone.0108282.s002.ogv 26 s, 1,384 × 1,036; 13.6 MB
  
• Endocannabinoids-Control-Platelet-Activation-and-Limit-Aggregate-Formation-under-Flow-pone.0108282.s003.ogv 40 s, 1,384 × 1,036; 32.14 MB
  
• Evidence-of-Flicker-Induced-Functional-Hyperaemia-in-the-Smallest-Vessels-of-the-Human-Retinal-pone.0162621.s001.ogv 17 s, 1,488 × 785; 1.04 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s002.ogv 41 s, 640 × 360; 3.41 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s003.ogv 1 min 5 s, 640 × 360; 6.42 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s004.ogv 32 s, 640 × 360; 1.6 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s005.ogv 1 min 17 s, 640 × 360; 7.64 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s006.ogv 1 min 0 s, 640 × 360; 5.17 MB
  
• Ex-Vivo-Lung-Perfusion-in-the-Rat-Detailed-Procedure-and-Videos-pone.0167898.s007.ogv 32 s, 640 × 360; 1.29 MB
  
• Fetuin-A-and-Albumin-Alter-Cytotoxic-Effects-of-Calcium-Phosphate-Nanoparticles-on-Human-Vascular-pone.0097565.s007.ogv 9.7 s, 672 × 512; 6.71 MB
  
• Hemodynamic-Forces-Regulate-Developmental-Patterning-of-Atrial-Conduction-pone.0115207.s004.ogv 6.8 s, 406 × 426; 45 KB
  
• Hemodynamic-Forces-Regulate-Developmental-Patterning-of-Atrial-Conduction-pone.0115207.s005.ogv 6.8 s, 404 × 424; 132 KB
  
• Hemodynamic-Forces-Regulate-Developmental-Patterning-of-Atrial-Conduction-pone.0115207.s006.ogv 6.8 s, 404 × 426; 109 KB
  
• Identification-of-Inter-Organ-Vascular-Network-Vessels-Bridging-between-Organs-pone.0065720.s002.ogv 19 s, 1,512 × 788; 234 KB
  
• Identification-of-Inter-Organ-Vascular-Network-Vessels-Bridging-between-Organs-pone.0065720.s003.ogv 40 s, 1,512 × 872; 4 MB
  
• Identification-of-Inter-Organ-Vascular-Network-Vessels-Bridging-between-Organs-pone.0065720.s004.ogv 18 s, 1,512 × 872; 6.78 MB
  
• Identification-of-Inter-Organ-Vascular-Network-Vessels-Bridging-between-Organs-pone.0065720.s005.ogv 9.6 s, 1,512 × 872; 1.3 MB
  
• In-Vitro-Shear-Stress-Measurements-Using-Particle-Image-Velocimetry-in-a-Family-of-Carotid-Artery-pone.0098209.s005.ogv 8.7 s, 1,200 × 1,570; 3.35 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s002.ogv 12 s, 1,024 × 1,024; 6.66 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s003.ogv 12 s, 1,024 × 1,024; 7.49 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s004.ogv 20 s, 480 × 480; 24.22 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s005.ogv 20 s, 480 × 480; 21.77 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s006.ogv 20 s, 480 × 480; 9.36 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s007.ogv 15 s, 512 × 512; 7.32 MB
  
• In-Vivo-Quantitative-Microcomputed-Tomographic-Analysis-of-Vasculature-and-Organs-in-a-Normal-and-pone.0150085.s008.ogv 10 s, 480 × 480; 6.8 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s002.ogv 6.6 s, 640 × 472; 2.77 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s003.ogv 6.0 s, 640 × 472; 2.41 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s004.ogv 6.0 s, 640 × 472; 2.5 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s005.ogv 6.0 s, 640 × 472; 2.98 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s006.ogv 24 s, 444 × 480; 250 KB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s007.ogv 24 s, 444 × 480; 179 KB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s008.ogv 24 s, 492 × 480; 2.7 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s009.ogv 24 s, 444 × 480; 844 KB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s010.ogv 34 s, 640 × 300; 3.84 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s011.ogv 35 s, 640 × 340; 3.38 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s012.ogv 1 min 7 s, 340 × 480; 7.1 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s013.ogv 30 s, 640 × 268; 1.33 MB
  
• Increased-Echogenicity-and-Radiodense-Foci-on-Echocardiogram-and-MicroCT-in-Murine-Myocarditis-pone.0159971.s014.ogv 30 s, 640 × 268; 709 KB
  
• Indian-Ink-Perfusion-Based-Method-for-Reconstructing-Continuous-Vascular-Networks-in-Whole-Mouse-pone.0088067.s005.ogv 41 s, 640 × 480; 5.92 MB
  
• Indian-Ink-Perfusion-Based-Method-for-Reconstructing-Continuous-Vascular-Networks-in-Whole-Mouse-pone.0088067.s006.ogv 26 s, 1,280 × 720; 25.26 MB
  
• Indian-Ink-Perfusion-Based-Method-for-Reconstructing-Continuous-Vascular-Networks-in-Whole-Mouse-pone.0088067.s007.ogv 18 s, 1,280 × 720; 17.68 MB
  
• Inhibition-of-the-Unfolded-Protein-Response-Mechanism-Prevents-Cardiac-Fibrosis-pone.0159682.s006.ogv 1 min 14 s, 640 × 368; 39.48 MB
  
• Modeling-Electrophysiological-Coupling-and-Fusion-between-Human-Mesenchymal-Stem-Cells-and-pcbi.1005014.s015.ogv 22 s, 1,120 × 840; 9.38 MB
  
• Modeling-Electrophysiological-Coupling-and-Fusion-between-Human-Mesenchymal-Stem-Cells-and-pcbi.1005014.s016.ogv 22 s, 1,120 × 840; 9.43 MB
  
• Modeling-Electrophysiological-Coupling-and-Fusion-between-Human-Mesenchymal-Stem-Cells-and-pcbi.1005014.s017.ogv 31 s, 1,120 × 840; 8.88 MB
  
• Modeling-Electrophysiological-Coupling-and-Fusion-between-Human-Mesenchymal-Stem-Cells-and-pcbi.1005014.s018.ogv 22 s, 1,120 × 840; 9.25 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s005.ogv 7.5 s, 656 × 752; 2.46 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s006.ogv 8.0 s, 656 × 752; 2.28 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s007.ogv 5.3 s, 656 × 752; 3.01 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s008.ogv 5.6 s, 656 × 752; 3.02 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s009.ogv 7.7 s, 656 × 752; 2.41 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s010.ogv 8.5 s, 656 × 752; 2.54 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s011.ogv 5.7 s, 656 × 752; 2.61 MB
  
• New-Strategies-for-Echocardiographic-Evaluation-of-Left-Ventricular-Function-in-a-Mouse-Model-of-pone.0041691.s012.ogv 5.5 s, 656 × 752; 3 MB
  
• Optimisation-of-Embryonic-and-Larval-ECG-Measurement-in-Zebrafish-for-Quantifying-the-Effect-of-QT-pone.0060552.s021.ogv 34 s, 320 × 240; 660 KB
  
• Optimisation-of-Embryonic-and-Larval-ECG-Measurement-in-Zebrafish-for-Quantifying-the-Effect-of-QT-pone.0060552.s022.ogv 44 s, 320 × 240; 699 KB
  
• Optimisation-of-Embryonic-and-Larval-ECG-Measurement-in-Zebrafish-for-Quantifying-the-Effect-of-QT-pone.0060552.s023.ogv 44 s, 320 × 240; 694 KB
  
• Optimisation-of-Embryonic-and-Larval-ECG-Measurement-in-Zebrafish-for-Quantifying-the-Effect-of-QT-pone.0060552.s024.ogv 44 s, 320 × 240; 769 KB
  
• Optimization-of-Liver-Decellularization-Maintains-Extracellular-Matrix-Micro-Architecture-and-pone.0155324.s002.ogv 28 s, 1,180 × 1,080; 1.52 MB
  
• Optimization-of-Liver-Decellularization-Maintains-Extracellular-Matrix-Micro-Architecture-and-pone.0155324.s003.ogv 28 s, 1,168 × 1,024; 2.37 MB
  
• Optimization-of-Liver-Decellularization-Maintains-Extracellular-Matrix-Micro-Architecture-and-pone.0155324.s004.ogv 47 s, 960 × 540; 4.79 MB
  
• Optimization-of-Liver-Decellularization-Maintains-Extracellular-Matrix-Micro-Architecture-and-pone.0155324.s005.ogv 1 min 16 s, 640 × 480; 2.11 MB
  
• PKC-Regulates-Force-Signaling-during-VEGFCXCL4-Induced-Dissociation-of-Endothelial-Tubes-pone.0093968.s001.ogv 0.5 s, 1,392 × 1,040; 2.08 MB
  
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• Scroll-Wave-Dynamics-in-Human-Cardiac-Tissue-Lessons-from-a-Mathematical-Model-with-Inhomogeneities-pone.0018052.s008.ogv 33 s, 860 × 802; 3.73 MB
  
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• Scroll-Wave-Dynamics-in-Human-Cardiac-Tissue-Lessons-from-a-Mathematical-Model-with-Inhomogeneities-pone.0018052.s012.ogv 33 s, 822 × 762; 3.67 MB
  
• Scroll-Wave-Dynamics-in-Human-Cardiac-Tissue-Lessons-from-a-Mathematical-Model-with-Inhomogeneities-pone.0018052.s013.ogv 33 s, 860 × 802; 4.31 MB
  
• Scroll-Wave-Dynamics-in-Human-Cardiac-Tissue-Lessons-from-a-Mathematical-Model-with-Inhomogeneities-pone.0018052.s014.ogv 33 s, 822 × 762; 3.26 MB
  
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• The-LIM-Only-Protein-FHL2-Reduces-Vascular-Lesion-Formation-Involving-Inhibition-of-Proliferation-pone.0094931.s007.ogv 25 s, 480 × 320; 3.45 MB
  
• The-LIM-Only-Protein-FHL2-Reduces-Vascular-Lesion-Formation-Involving-Inhibition-of-Proliferation-pone.0094931.s008.ogv 13 s, 480 × 320; 2.39 MB
  
• The-Natural-History-of-Kidney-Graft-Cortical-Microcirculation-Determined-by-Real-Time-Contrast-pone.0150384.s001.ogv 1 min 18 s, 787 × 576; 8.94 MB
  
• The-UNC-45-Chaperone-Is-Critical-for-Establishing-Myosin-Based-Myofibrillar-Organization-and-pone.0022579.s008.ogv 20 s, 640 × 480; 3.1 MB
  
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