Category:Medical imaging

Subcategories

This category has the following 42 subcategories, out of 42 total.

Pages in category "Medical imaging"

This category contains only the following page.

Media in category "Medical imaging"

The following 200 files are in this category, out of 407 total.

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  113abcd Medical Imaging Techniques.jpg 1,041 × 939; 769 KB
  
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  1977 Version of Imaging System Prototype.jpg 1,411 × 999; 175 KB
  
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  2D Fourier Transform and Base Images.png 2,390 × 1,158; 1.2 MB
  
• 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
  
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  3DISCO imaging of mouse brain.jpg 480 × 525; 105 KB
  
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  4m msot.jpg 525 × 470; 122 KB
  
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  50pman medical imaging.svg 849 × 413; 51 KB
  
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  A video image of cardiac activity is achieved by injecting thallium into a patient's blood during testing in the clinical sciences division at the USAF School of Aerospace Medicine. - DPLA - c5dd0b088df5aacbe176bbc0adef2ebb.jpeg 3,000 × 2,028; 3.84 MB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s007.ogv 30 s, 512 × 512; 660 KB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s008.ogv 30 s, 504 × 354; 537 KB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s009.ogv 30 s, 512 × 512; 936 KB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s010.ogv 23 s, 512 × 512; 722 KB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s011.ogv 1 min 0 s, 512 × 512; 1.17 MB
  
• A-Bispecific-Antibody-Promotes-Aggregation-of-Ricin-Toxin-on-Cell-Surfaces-and-Alters-Dynamics-of-pone.0156893.s012.ogv 23 s, 512 × 512; 508 KB
  
• A-Development-of-Nucleic-Chromatin-Measurements-as-a-New-Prognostic-Marker-for-Severe-Chronic-Heart-pone.0148209.s003.ogv 3.2 s, 225 × 240; 42 KB
  
• A-Development-of-Nucleic-Chromatin-Measurements-as-a-New-Prognostic-Marker-for-Severe-Chronic-Heart-pone.0148209.s004.ogv 14 s, 225 × 240; 337 KB
  
• A-Development-of-Nucleic-Chromatin-Measurements-as-a-New-Prognostic-Marker-for-Severe-Chronic-Heart-pone.0148209.s005.ogv 6.1 s, 225 × 240; 282 KB
  
• A-Development-of-Nucleic-Chromatin-Measurements-as-a-New-Prognostic-Marker-for-Severe-Chronic-Heart-pone.0148209.s006.ogv 6.6 s, 226 × 240; 756 KB
  
• A-Microfluidic-Platform-for-Correlative-Live-Cell-and-Super-Resolution-Microscopy-pone.0115512.s002.ogv 19 s, 258 × 506; 3.28 MB
  
• A-Microfluidic-Platform-for-Correlative-Live-Cell-and-Super-Resolution-Microscopy-pone.0115512.s003.ogv 11 s, 1,039 × 300; 4.77 MB
  
• A-Microfluidic-Platform-for-Correlative-Live-Cell-and-Super-Resolution-Microscopy-pone.0115512.s004.ogv 6.6 s, 40 × 40; 218 KB
  
• A-Microfluidic-Platform-for-Correlative-Live-Cell-and-Super-Resolution-Microscopy-pone.0115512.s005.ogv 6.2 s, 35 × 25; 30 KB
  
• A-Microfluidic-Platform-for-Correlative-Live-Cell-and-Super-Resolution-Microscopy-pone.0115512.s006.ogv 6.2 s, 40 × 40; 67 KB
  
• A-Modular-and-Affordable-Time-Lapse-Imaging-and-Incubation-System-Based-on-3D-Printed-Parts-a-pone.0167583.s006.ogv 13 s, 496 × 480; 4.98 MB
  
• A-Modular-and-Affordable-Time-Lapse-Imaging-and-Incubation-System-Based-on-3D-Printed-Parts-a-pone.0167583.s007.ogv 12 s, 496 × 480; 5.03 MB
  
• A-Modular-and-Affordable-Time-Lapse-Imaging-and-Incubation-System-Based-on-3D-Printed-Parts-a-pone.0167583.s008.ogv 10 s, 508 × 480; 836 KB
  
• A-MRI-Compatible-Combined-Mechanical-Loading-and-MR-Elastography-Setup-to-Study-Deformation-Induced-pone.0169864.s003.ogv 2.0 s, 2,000 × 1,630; 1.4 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-Novel-μCT-Analysis-Reveals-Different-Responses-of-Bioerosion-and-Secondary-Accretion-to-pone.0153058.s001.ogv 22 s, 640 × 356; 4.45 MB
  
• A-Versatile-Optical-Clearing-Protocol-for-Deep-Tissue-Imaging-of-Fluorescent-Proteins-in-pone.0161107.s005.ogv 26 s, 512 × 512; 4.93 MB
  
• A-Wireless-EEG-Recording-Method-for-Rat-Use-inside-the-Water-Maze-pone.0147730.s001.ogv 51 s, 854 × 480; 4.08 MB
  
• A-Wireless-EEG-Recording-Method-for-Rat-Use-inside-the-Water-Maze-pone.0147730.s002.ogv 30 s, 854 × 480; 2.38 MB
  
• A-Wireless-EEG-Recording-Method-for-Rat-Use-inside-the-Water-Maze-pone.0147730.s003.ogv 23 s, 854 × 480; 1.71 MB
  
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  Advanced medical imaging during noninjury ED visits.png 960 × 518; 32 KB
  
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  AJUSTE DE BRILLO.png 129 × 292; 28 KB
  
• Allatostatin-A-Signalling-in-Drosophila-Regulates-Feeding-and-Sleep-and-Is-Modulated-by-PDF-pgen.1006346.s021.ogv 5.1 s, 530 × 480; 623 KB
  
• Allatostatin-A-Signalling-in-Drosophila-Regulates-Feeding-and-Sleep-and-Is-Modulated-by-PDF-pgen.1006346.s023.ogv 3 min 40 s, 854 × 480; 6.47 MB
  
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  Ambulatory Glucose Profile Sample Graphs.png 1,055 × 1,084; 303 KB
  
• An-Integrated-In-Vitro-Imaging-Platform-for-Characterizing-Filarial-Parasite-Behavior-within-a-pntd.0003305.s002.ogv 2.1 s, 640 × 480; 84 KB
  
• An-Integrated-In-Vitro-Imaging-Platform-for-Characterizing-Filarial-Parasite-Behavior-within-a-pntd.0003305.s003.ogv 2.1 s, 640 × 480; 62 KB
  
• An-Integrated-In-Vitro-Imaging-Platform-for-Characterizing-Filarial-Parasite-Behavior-within-a-pntd.0003305.s004.ogv 2.1 s, 640 × 480; 35 KB
  
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  Anatomisch 3D-model in Mimics.jpg 1,011 × 836; 90 KB
  
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  AngioCompareAneurysmsOS.jpg 930 × 715; 66 KB
  
• Aqueous-Angiography-Real-Time-and-Physiologic-Aqueous-Humor-Outflow-Imaging-pone.0147176.s001.ogv 37 s, 640 × 480; 772 KB
  
• Astroglia-in-Thick-Tissue-with-Super-Resolution-and-Cellular-Reconstruction-pone.0160391.s002.ogv 50 s, 852 × 455; 13.19 MB
  
• Astroglia-in-Thick-Tissue-with-Super-Resolution-and-Cellular-Reconstruction-pone.0160391.s003.ogv 50 s, 852 × 455; 3 MB
  
• Astroglia-in-Thick-Tissue-with-Super-Resolution-and-Cellular-Reconstruction-pone.0160391.s004.ogv 50 s, 852 × 455; 26.3 MB
  
• Astroglia-in-Thick-Tissue-with-Super-Resolution-and-Cellular-Reconstruction-pone.0160391.s005.ogv 13 s, 852 × 455; 8.7 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s025.ogv 50 s, 854 × 480; 13.06 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s026.ogv 50 s, 854 × 480; 13.28 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s027.ogv 50 s, 854 × 480; 12.73 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s028.ogv 50 s, 854 × 480; 11.82 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s029.ogv 25 s, 854 × 480; 5.04 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s030.ogv 50 s, 854 × 480; 13.84 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s031.ogv 50 s, 854 × 480; 13.89 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s032.ogv 50 s, 854 × 480; 12.17 MB
  
• Atrial-Heterogeneity-Generates-Re-entrant-Substrate-during-Atrial-Fibrillation-and-Anti-arrhythmic-pcbi.1005245.s033.ogv 50 s, 854 × 480; 10.81 MB
  
• Augmented-Endoscopic-Images-Overlaying-Shape-Changes-in-Bone-Cutting-Procedures-pone.0161815.s002.ogv 2 min 27 s, 480 × 424; 1.93 MB
  
• Augmented-Endoscopic-Images-Overlaying-Shape-Changes-in-Bone-Cutting-Procedures-pone.0161815.s003.ogv 47 s, 320 × 304; 337 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
  
• 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
  
• Calcium-Imaging-of-AM-Dyes-Following-Prolonged-Incubation-in-Acute-Neuronal-Tissue-pone.0155468.s001.ogv 13 s, 960 × 540; 16.74 MB
  
• Calcium-Imaging-of-AM-Dyes-Following-Prolonged-Incubation-in-Acute-Neuronal-Tissue-pone.0155468.s002.ogv 17 s, 960 × 540; 16.85 MB
  
• Calcium-Imaging-of-AM-Dyes-Following-Prolonged-Incubation-in-Acute-Neuronal-Tissue-pone.0155468.s003.ogv 19 s, 960 × 540; 30.27 MB
  
• Calcium-Imaging-of-AM-Dyes-Following-Prolonged-Incubation-in-Acute-Neuronal-Tissue-pone.0155468.s004.ogv 11 s, 960 × 540; 7.61 MB
  
• Caloric-Vestibular-Stimulation-Reduces-Pain-and-Somatoparaphrenia-in-a-Severe-Chronic-Central-Post-pone.0151213.s007.ogv 23 s, 480 × 272; 1.33 MB
  
• Caloric-Vestibular-Stimulation-Reduces-Pain-and-Somatoparaphrenia-in-a-Severe-Chronic-Central-Post-pone.0151213.s008.ogv 24 s, 480 × 272; 940 KB
  
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  Cardiac atlas pictures.png 618 × 276; 183 KB
  
• 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
  
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  CD curve nima.png 553 × 504; 23 KB
  
• Cell-Density-Dependent-Increase-in-Tyrosine-Monophosphorylated-ERK2-in-MDCK-Cells-Expressing-Active-pone.0167940.s001.ogv 6.0 s, 1,064 × 718; 4.14 MB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s010.ogv 8.0 s, 480 × 384; 2.71 MB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s011.ogv 8.3 s, 480 × 360; 2.06 MB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s012.ogv 8.3 s, 480 × 384; 3.43 MB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s013.ogv 5.0 s, 1,280 × 1,024; 816 KB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s014.ogv 5.0 s, 1,280 × 1,024; 425 KB
  
• Cellular-Architecture-Regulates-Collective-Calcium-Signaling-and-Cell-Contractility-pcbi.1004955.s015.ogv 5.0 s, 1,392 × 1,040; 1.56 MB
  
• Chemotaxis-and-Binding-of-Pseudomonas-aeruginosa-to-Scratch-Wounded-Human-Cystic-Fibrosis-Airway-pone.0150109.s001.ogv 30 s, 720 × 240; 1.7 MB
  
• Chemotaxis-and-Binding-of-Pseudomonas-aeruginosa-to-Scratch-Wounded-Human-Cystic-Fibrosis-Airway-pone.0150109.s002.ogv 30 s, 720 × 240; 827 KB
  
• Chronic-Posttraumatic-Epilepsy-following-Neocortical-Undercut-Lesion-in-Mice-pone.0158231.s002.ogv 15 s, 320 × 240; 262 KB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s001.ogv 30 s, 1,280 × 720; 4.31 MB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s002.ogv 24 s, 1,280 × 720; 7.06 MB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s003.ogv 31 s, 1,280 × 720; 5.87 MB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s004.ogv 34 s, 1,280 × 720; 12.88 MB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s005.ogv 25 s, 1,280 × 720; 8.35 MB
  
• Comparison-of-Cartesian-and-Non-Cartesian-Real-Time-MRI-Sequences-at-1.5T-to-Assess-Velar-Motion-pone.0153322.s006.ogv 27 s, 1,280 × 720; 15.34 MB
  
• Comparison-of-Confocal-and-Super-Resolution-Reflectance-Imaging-of-Metal-Oxide-Nanoparticles-pone.0159980.s011.ogv 0.4 s, 716 × 652; 818 KB
  
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  ComputationalAnatomy LandmarkGeodesic Single withLabel.gif 372 × 372; 580 KB
  
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  ComputationalAnatomy LandmarkGeodesic Single.gif 372 × 372; 576 KB
  
• Concentration-Sensing-by-the-Moving-Nucleus-in-Cell-Fate-Determination-A-Computational-Analysis-pone.0149213.s005.ogv 50 s, 1,127 × 334; 1.07 MB
  
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  Concept of FRET.png 1,421 × 1,543; 216 KB
  
• Correlating-Intravital-Multi-Photon-Microscopy-to-3D-Electron-Microscopy-of-Invading-Tumor-Cells-pone.0114448.s003.ogv 25 s, 854 × 480; 1.8 MB
  
• Correlating-Intravital-Multi-Photon-Microscopy-to-3D-Electron-Microscopy-of-Invading-Tumor-Cells-pone.0114448.s004.ogv 24 s, 854 × 480; 1.3 MB
  
• Correlating-Intravital-Multi-Photon-Microscopy-to-3D-Electron-Microscopy-of-Invading-Tumor-Cells-pone.0114448.s005.ogv 55 s, 854 × 480; 10.36 MB
  
• Correlating-Intravital-Multi-Photon-Microscopy-to-3D-Electron-Microscopy-of-Invading-Tumor-Cells-pone.0114448.s006.ogv 38 s, 854 × 480; 7.59 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
  
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  CRPS-RSD of the left foot.jpg 430 × 404; 82 KB
  
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  CTWristImage.png 798 × 636; 315 KB
  
• Cytological-Observations-of-the-Large-Symbiotic-Foraminifer-Amphisorus-kudakajimensis-Using-Calcein-pone.0165844.s003.ogv 4.9 s, 512 × 512; 1.98 MB
  
• Cytological-Observations-of-the-Large-Symbiotic-Foraminifer-Amphisorus-kudakajimensis-Using-Calcein-pone.0165844.s004.ogv 26 s, 512 × 512; 2.38 MB
  
• Cytological-Observations-of-the-Large-Symbiotic-Foraminifer-Amphisorus-kudakajimensis-Using-Calcein-pone.0165844.s005.ogv 3.5 s, 512 × 512; 299 KB
  
• Cytological-Observations-of-the-Large-Symbiotic-Foraminifer-Amphisorus-kudakajimensis-Using-Calcein-pone.0165844.s006.ogv 3.5 s, 512 × 512; 711 KB
  
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  Darmiyan Brain Map.png 1,186 × 1,127; 417 KB
  
• Data-Driven-Estimation-of-Imputation-Error—A-Strategy-for-Imputation-with-a-Reject-Option-pone.0164464.s003.ogv 20 s, 1,600 × 830; 885 KB
  
• Data-Driven-Estimation-of-Imputation-Error—A-Strategy-for-Imputation-with-a-Reject-Option-pone.0164464.s004.ogv 20 s, 1,600 × 830; 1.01 MB
  
• Data-Driven-Estimation-of-Imputation-Error—A-Strategy-for-Imputation-with-a-Reject-Option-pone.0164464.s005.ogv 20 s, 1,600 × 830; 601 KB
  
• Data-Driven-Estimation-of-Imputation-Error—A-Strategy-for-Imputation-with-a-Reject-Option-pone.0164464.s006.ogv 20 s, 1,600 × 830; 586 KB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s019.ogv 2.7 s, 880 × 880; 895 KB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s020.ogv 2.7 s, 900 × 900; 1.87 MB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s021.ogv 6.4 s, 1,220 × 1,020; 2.13 MB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s022.ogv 6.4 s, 1,280 × 1,080; 5.76 MB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s023.ogv 6.4 s, 1,220 × 1,020; 2.16 MB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s024.ogv 6.4 s, 1,220 × 1,020; 1.16 MB
  
• Deep-Learning-Automates-the-Quantitative-Analysis-of-Individual-Cells-in-Live-Cell-Imaging-pcbi.1005177.s025.ogv 6.4 s, 1,280 × 1,080; 11.76 MB
  
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  Demonstration of Method- Osmium-μCT with Advanced Image Processing.tif 4,683 × 1,996; 35.66 MB
  
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  Dental imaging UTHSCSA2.JPG 2,199 × 1,688; 1.62 MB
  
• Differential-Cargo-Mobilisation-within-Weibel-Palade-Bodies-after-Transient-Fusion-with-the-Plasma-pone.0108093.s001.ogv 50 s, 211 × 221; 1,006 KB
  
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  Dual Energy CT images with gout tophi shown in green.jpg 750 × 805; 136 KB
  
• Dual-Small-Molecule-Targeting-of-SMAD-Signaling-Stimulates-Human-Induced-Pluripotent-Stem-Cells-pone.0106952.s004.ogv 51 s, 320 × 240; 1.22 MB
  
• Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s001.ogv 3.1 s, 600 × 600; 349 KB
  
• Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s002.ogv 3.1 s, 600 × 600; 116 KB
  
• Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s003.ogv 5.6 s, 500 × 289; 234 KB
  
• Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s004.ogv 4.8 s, 407 × 249; 120 KB
  
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• Ellipsoid-Segmentation-Model-for-Analyzing-Light-Attenuated-3D-Confocal-Image-Stacks-of-Fluorescent-pone.0156942.s008.ogv 13 s, 4,224 × 5,024; 6.09 MB
  
• End-to-End-Digitisation-and-Analysis-of-Three-Dimensional-Coral-Models-from-Communities-to-pone.0149641.s003.ogv 50 s, 1,400 × 800; 31.83 MB
  
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• Enhanced-Vitreous-Imaging-in-Healthy-Eyes-Using-Swept-Source-Optical-Coherence-Tomography-pone.0102950.s001.ogv 22 s, 1,500 × 680; 34.09 MB
  
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• Enhanced-Vitreous-Imaging-in-Healthy-Eyes-Using-Swept-Source-Optical-Coherence-Tomography-pone.0102950.s006.ogv 14 s, 1,500 × 500; 29.51 MB
  
• Evidence-for-SH2-Domain-Containing-5-Inositol-Phosphatase-2-(SHIP2)-Contributing-to-a-Lymphatic-pone.0112548.s008.ogv 39 s, 514 × 514; 291 KB
  
• Evidence-for-SH2-Domain-Containing-5-Inositol-Phosphatase-2-(SHIP2)-Contributing-to-a-Lymphatic-pone.0112548.s009.ogv 38 s, 514 × 514; 600 KB
  
• Evidence-for-SH2-Domain-Containing-5-Inositol-Phosphatase-2-(SHIP2)-Contributing-to-a-Lymphatic-pone.0112548.s010.ogv 1 min 0 s, 514 × 514; 2.29 MB
  
• Evidence-for-SH2-Domain-Containing-5-Inositol-Phosphatase-2-(SHIP2)-Contributing-to-a-Lymphatic-pone.0112548.s011.ogv 37 s, 514 × 514; 3.44 MB
  
• Fast-online-deconvolution-of-calcium-imaging-data-pcbi.1005423.s002.ogv 22 s, 800 × 400; 314 KB
  
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• FISICO-Fast-Image-SegmentatIon-COrrection-pone.0156035.s001.ogv 1 min 47 s, 712 × 480; 12.91 MB
  
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• Global-Neuromagnetic-Cortical-Fields-Have-Non-Zero-Velocity-pone.0148413.s003.ogv 9.4 s, 640 × 400; 803 KB
  
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• High-Content-Screening-in-Zebrafish-Embryos-Identifies-Butafenacil-as-a-Potent-Inducer-of-Anemia-pone.0104190.s034.ogv 3.0 s, 1,392 × 1,040; 2.01 MB
  
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• High-Field-MRI-Reveals-a-Drastic-Increase-of-Hypoxia-Induced-Microhemorrhages-upon-Tissue-pone.0148441.s001.ogv 15 s, 1,436 × 762; 6.09 MB
  
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• Improved-Resection-and-Outcome-of-Colon-Cancer-Liver-Metastasis-with-Fluorescence-Guided-Surgery-pone.0148760.s002.ogv 34 s, 1,280 × 720; 7.45 MB
  
• In-Vivo-Detection-of-Macrophage-Recruitment-in-Hind-Limb-Ischemia-Using-a-Targeted-Near-Infrared-pone.0103721.s002.ogv 4.1 s, 320 × 240; 92 KB
  
• In-Vivo-Imaging-of-Hedgehog-Pathway-Activation-with-a-Nuclear-Fluorescent-Reporter-pone.0103661.s001.ogv 7.5 s, 426 × 426; 3.27 MB
  
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• In-Vivo-Imaging-Reveals-a-Pioneer-Wave-of-Monocyte-Recruitment-into-Mouse-Skin-Wounds-pone.0108212.s002.ogv 6.0 s, 773 × 774; 2.15 MB
  
• In-Vivo-Imaging-Reveals-a-Pioneer-Wave-of-Monocyte-Recruitment-into-Mouse-Skin-Wounds-pone.0108212.s003.ogv 16 s, 750 × 750; 7.38 MB