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Subcategories

This category has the following 13 subcategories, out of 13 total.

A

Arp2/3-mediated F-actin formation controls regulated exocytosis in vivo (26 F)

C

Chronic Toxoplasma Infection Modifies the Structure and the Risk of Host Behavior (5 F)

R

S

T

U

Uploaded with Open Access Media Importer and needing category review (134 C, 34988 F)
Uploaded with Open Access Media Importer and needing license review (2 F)
Uploaded with reCitation Bot (1430 F)

V

Videos of immune system uploaded with Open Access Media Importer (1 C, 191 F)

Media in category "Uploaded with Open Access Media Importer"

The following 200 files are in this category, out of 35,755 total.

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-Adrenergic-Inhibition-of-Contractility-in-L6-Skeletal-Muscle-Cells-pone.0022304.s001.ogv 17 s, 320 × 240; 931 KB
-Adrenergic-Inhibition-of-Contractility-in-L6-Skeletal-Muscle-Cells-pone.0022304.s002.ogv 17 s, 320 × 240; 877 KB
-Arrestin2-Regulates-Lysophosphatidic-Acid-Induced-Human-Breast-Tumor-Cell-Migration-and-Invasion-pone.0056174.s003.ogv 10 s, 322 × 480; 1.96 MB
-Catenin-Is-Critical-for-Cerebellar-Foliation-and-Lamination-pone.0064451.s001.ogv 14 s, 200 × 150; 919 KB
-Globin-Sleeping-Beauty-Transposon-Reduces-Red-Blood-Cell-Sickling-in-a-Patient-Derived-CD34+-Based-pone.0080403.s002.ogv 45 s, 640 × 480; 11.15 MB
-Globin-Sleeping-Beauty-Transposon-Reduces-Red-Blood-Cell-Sickling-in-a-Patient-Derived-CD34+-Based-pone.0080403.s003.ogv 45 s, 640 × 480; 17.69 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s002.ogv 40 s, 426 × 240; 1.54 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s003.ogv 40 s, 426 × 240; 2.19 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s004.ogv 40 s, 426 × 240; 1.8 MB
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-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s006.ogv 40 s, 426 × 240; 1.16 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s007.ogv 40 s, 426 × 240; 2.07 MB
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-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s019.ogv 40 s, 426 × 240; 2.36 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s020.ogv 40 s, 426 × 240; 2.34 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s021.ogv 40 s, 426 × 240; 2.34 MB
-Hairpin-Mediated-Formation-of-Structurally-Distinct-Multimers-of-Neurotoxic-Prion-Peptides-pone.0087354.s022.ogv 2 min 0 s, 426 × 240; 10.41 MB
1.0-T-open-configuration-magnetic-resonance-guided-microwave-ablation-of-pig-livers-in-real-time-srep13551-s1.ogv 1 min 3 s, 1,280 × 720; 40.26 MB
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14-3-3ζ-Interacts-with-Stat3-and-Regulates-Its-Constitutive-Activation-in-Multiple-Myeloma-Cells-pone.0029554.s002.ogv 17 s, 640 × 576; 7.78 MB
14000-year-old-seeds-indicate-the-Levantine-origin-of-the-lost-progenitor-of-faba-bean-srep37399-s2.ogv 26 s, 640 × 360; 2.67 MB
14000-year-old-seeds-indicate-the-Levantine-origin-of-the-lost-progenitor-of-faba-bean-srep37399-s3.ogv 26 s, 640 × 360; 3.63 MB
14000-year-old-seeds-indicate-the-Levantine-origin-of-the-lost-progenitor-of-faba-bean-srep37399-s4.ogv 26 s, 640 × 360; 5.17 MB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s001.ogv 7.0 s, 1,072 × 452; 357 KB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s002.ogv 7.0 s, 1,072 × 452; 467 KB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s003.ogv 14 s, 1,072 × 904; 676 KB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s004.ogv 14 s, 1,076 × 904; 675 KB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s005.ogv 14 s, 1,072 × 904; 942 KB
19F-Magnetic-Resonance-Imaging-of-Perfluorocarbons-for-the-Evaluation-of-Response-to-Antibiotic-pone.0064440.s006.ogv 14 s, 1,076 × 904; 859 KB
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1D-3D-hybrid-modeling--from-multi-compartment-models-to-full-resolution-models-in-space-and-time-Movie2.ogv 13 s, 1,360 × 784; 499 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s006.ogv 2.8 s, 900 × 900; 344 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s007.ogv 2.5 s, 684 × 684; 240 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s008.ogv 2.5 s, 900 × 900; 128 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s009.ogv 2.5 s, 512 × 512; 56 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s010.ogv 2.5 s, 512 × 512; 43 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s011.ogv 2.5 s, 512 × 512; 37 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s012.ogv 2.5 s, 360 × 360; 22 KB
2-Adrenergic-Receptor-Fluorescent-Protein-Fusions-Traffic-to-the-Plasma-Membrane-and-Retain-pone.0074941.s013.ogv 2.5 s, 512 × 512; 29 KB
2-Bromopalmitate-Reduces-Protein-Deacylation-by-Inhibition-of-Acyl-Protein-Thioesterase-Enzymatic-pone.0075232.s001.ogv 6.0 s, 4,096 × 1,512; 7.65 MB
225γ-habit-planes-in-martensitic-steels-from-the-PTMC-to-a-continuous-model-srep40938-s1.ogv 5.0 s, 1,075 × 668; 703 KB
2D-and-3D-Organized-Cardiac-Cells-Shows-Differences-in-Cellular-Morphology-Adhesion-Junctions-pone.0038147.s001.ogv 7.9 s, 375 × 348; 1,000 KB
2D-and-3D-Organized-Cardiac-Cells-Shows-Differences-in-Cellular-Morphology-Adhesion-Junctions-pone.0038147.s002.ogv 1.5 s, 512 × 533; 1.66 MB
2D-and-3D-Self-Assembling-Nanofiber-Hydrogels-for-Cardiomyocyte-Culture-285678.f1.ogv 38 s, 800 × 610; 9.87 MB
2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s2.ogv 10 s, 720 × 1,000; 763 KB
2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s3.ogv 5.3 s, 720 × 1,000; 250 KB
2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s4.ogv 27 s, 1,074 × 512; 1.73 MB
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2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s6.ogv 9.6 s, 810 × 270; 2 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
3-D-neurohistology-of-transparent-tongue-in-health-and-injury-with-optical-clearing-Movie1.ogv 6.6 s, 768 × 768; 7.15 MB
3-D-neurohistology-of-transparent-tongue-in-health-and-injury-with-optical-clearing-Movie2.ogv 26 s, 768 × 768; 26.03 MB
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3-D-neurohistology-of-transparent-tongue-in-health-and-injury-with-optical-clearing-Movie5.ogv 27 s, 768 × 768; 18.61 MB
3-D-neurohistology-of-transparent-tongue-in-health-and-injury-with-optical-clearing-Movie6.ogv 13 s, 1,024 × 1,024; 11.59 MB
3-D-neurohistology-of-transparent-tongue-in-health-and-injury-with-optical-clearing-Movie7.ogv 13 s, 1,024 × 1,024; 12.77 MB
3-D-Ultrastructure-of-O.-tauri-Electron-Cryotomography-of-an-Entire-Eukaryotic-Cell-pone.0000749.s001.ogv 1 min 54 s, 262 × 240; 2.52 MB
3-D-Visualization-and-Quantitation-of-Microvessels-in-Transparent-Human-Colorectal-Carcinoma-pone.0081857.s003.ogv 10 s, 1,024 × 512; 4 MB
3-D-Visualization-and-Quantitation-of-Microvessels-in-Transparent-Human-Colorectal-Carcinoma-pone.0081857.s004.ogv 30 s, 768 × 768; 17.64 MB
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3-D-Visualization-and-Quantitation-of-Microvessels-in-Transparent-Human-Colorectal-Carcinoma-pone.0081857.s006.ogv 24 s, 768 × 768; 17.91 MB
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3-D-Worm-Tracker-for-Freely-Moving-C.-elegans-pone.0057484.s004.ogv 33 s, 800 × 600; 558 KB
3-D-Worm-Tracker-for-Freely-Moving-C.-elegans-pone.0057484.s005.ogv 12 s, 436 × 188; 36 KB
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3-D-Worm-Tracker-for-Freely-Moving-C.-elegans-pone.0057484.s008.ogv 1 min 5 s, 390 × 402; 1.87 MB
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3-OST-7-Regulates-BMP-Dependent-Cardiac-Contraction-pbio.1001727.s014.ogv 6.7 s, 720 × 486; 558 KB
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3-OST-7-Regulates-BMP-Dependent-Cardiac-Contraction-pbio.1001727.s020.ogv 18 s, 128 × 128; 237 KB
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
3D animation of reconstructed skull and atlas of Niassodon mfumukasi - pone.0080974.s002.ogv 24 s, 1,024 × 768; 21.53 MB
3D rendering of micro-CT scan of Eupolybothrus cavernicolus Komerički & Stoev - biodiversity data journal-1-e1013-g021.ogv 1 min 39 s, 1,224 × 720; 25.56 MB
3D-Bite-Modeling-and-Feeding-Mechanics-of-the-Largest-Living-Amphibian-the-Chinese-Giant-Salamander-pone.0121885.s003.ogv 19 s, 1,024 × 768; 3.95 MB
3D-Bite-Modeling-and-Feeding-Mechanics-of-the-Largest-Living-Amphibian-the-Chinese-Giant-Salamander-pone.0121885.s004.ogv 19 s, 1,024 × 768; 3.96 MB
3D-Bite-Modeling-and-Feeding-Mechanics-of-the-Largest-Living-Amphibian-the-Chinese-Giant-Salamander-pone.0121885.s005.ogv 18 s, 1,024 × 768; 3.65 MB
3D-Bite-Modeling-and-Feeding-Mechanics-of-the-Largest-Living-Amphibian-the-Chinese-Giant-Salamander-pone.0121885.s006.ogv 19 s, 1,024 × 768; 4.14 MB
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3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S10.ogv 2.8 s, 490 × 399; 63 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S2.ogv 13 s, 424 × 337; 75 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S3.ogv 2.8 s, 487 × 316; 105 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S4.ogv 2.8 s, 452 × 333; 140 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S5.ogv 2.8 s, 467 × 433; 75 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S6.ogv 2.8 s, 477 × 411; 33 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S7.ogv 2.8 s, 459 × 263; 113 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S8.ogv 2.8 s, 456 × 305; 127 KB
3D-collagen-type-I-matrix-inhibits-the-antimigratory-effect-of-doxorubicin-1475-2867-10-26-S9.ogv 2.8 s, 465 × 399; 61 KB
3D-Echo-systematically-underestimates-right-ventricular-volumes-compared-to-cardiovascular-magnetic-1532-429X-13-78-S1.ogv 0.8 s, 972 × 954; 80 KB
3D-Holographic-Observatory-for-Long-term-Monitoring-of-Complex-Behaviors-in-Drosophila-srep33001-s1.ogv 14 s, 2,048 × 1,024; 2.66 MB
3D-Holographic-Observatory-for-Long-term-Monitoring-of-Complex-Behaviors-in-Drosophila-srep33001-s2.ogv 12 s, 2,048 × 1,024; 2.19 MB
3D-Holographic-Observatory-for-Long-term-Monitoring-of-Complex-Behaviors-in-Drosophila-srep33001-s3.ogv 25 s, 1,024 × 908; 821 KB
3D-Holographic-Observatory-for-Long-term-Monitoring-of-Complex-Behaviors-in-Drosophila-srep33001-s4.ogv 18 s, 300 × 150; 3.32 MB
3D-Image-Guided-Automatic-Pipette-Positioning-for-Single-Cell-Experiments-in-vivo-srep18426-s2.ogv 2 min 29 s, 1,920 × 1,080; 33.88 MB
3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s2.ogv 33 s, 479 × 320; 819 KB
3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s3.ogv 33 s, 478 × 480; 2.11 MB
3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s4.ogv 2.4 s, 478 × 320; 440 KB
3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s5.ogv 0.9 s, 480 × 480; 1.4 MB
3D-interactive-tractography-informed-resting-state-fMRI-connectivity-Video1.ogv 3 min 41 s, 1,088 × 720; 35.01 MB
3D-map-of-the-human-corneal-endothelial-cell-srep29047-s2.ogv 5.0 s, 1,000 × 1,000; 3.32 MB
3D-mapping-of-elastic-modulus-using-shear-wave-optical-micro-elastography-srep35499-s2.ogv 15 s, 864 × 512; 3.73 MB
3D-mapping-of-elastic-modulus-using-shear-wave-optical-micro-elastography-srep35499-s3.ogv 15 s, 864 × 512; 3.31 MB
3D-mapping-of-elastic-modulus-using-shear-wave-optical-micro-elastography-srep35499-s4.ogv 15 s, 560 × 420; 2.93 MB
3D-mapping-of-elastic-modulus-using-shear-wave-optical-micro-elastography-srep35499-s5.ogv 10 s, 512 × 512; 281 KB
3D-Mass-Spectrometry-Imaging-Reveals-a-Very-Heterogeneous-Drug-Distribution-in-Tumors-srep37027-s1.ogv 39 s, 852 × 579; 17.37 MB
3D-Mass-Spectrometry-Imaging-Reveals-a-Very-Heterogeneous-Drug-Distribution-in-Tumors-srep37027-s2.ogv 39 s, 852 × 579; 13.85 MB
3D-Mass-Spectrometry-Imaging-Reveals-a-Very-Heterogeneous-Drug-Distribution-in-Tumors-srep37027-s3.ogv 39 s, 852 × 579; 22.9 MB
3D-Microfluidic-model-for-evaluating-immunotherapy-efficacy-by-tracking-dendritic-cell-behaviour-41598 2017 1013 MOESM2 ESM.ogv 1 min 17 s, 720 × 576; 53.78 MB
3D-Microfluidic-model-for-evaluating-immunotherapy-efficacy-by-tracking-dendritic-cell-behaviour-41598 2017 1013 MOESM3 ESM.ogv 1 min 17 s, 720 × 576; 56.02 MB
3D-Microstructural-Architecture-of-Muscle-Attachments-in-Extant-and-Fossil-Vertebrates-Revealed-by-pone.0056992.s013.ogv 5.9 s, 1,110 × 775; 6.27 MB
3D-microtumors-in-vitro-supported-by-perfused-vascular-networks-srep31589-s2.ogv 2 min 8 s, 1,360 × 1,024; 27.53 MB
3D-microtumors-in-vitro-supported-by-perfused-vascular-networks-srep31589-s3.ogv 13 s, 852 × 488; 1.18 MB
3D-Morphology-Ultrastructure-and-Development-of-Ceratomyxa-puntazzi-Stages-First-Insights-into-the-pone.0032679.s001.ogv 1 min 27 s, 768 × 576; 4.35 MB
3D-Morphology-Ultrastructure-and-Development-of-Ceratomyxa-puntazzi-Stages-First-Insights-into-the-pone.0032679.s002.ogv 16 s, 768 × 576; 3.11 MB
3D-Morphology-Ultrastructure-and-Development-of-Ceratomyxa-puntazzi-Stages-First-Insights-into-the-pone.0032679.s003.ogv 10 s, 768 × 576; 2.36 MB
3D-Morphology-Ultrastructure-and-Development-of-Ceratomyxa-puntazzi-Stages-First-Insights-into-the-pone.0032679.s004.ogv 33 s, 768 × 576; 11.18 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
3D-Multi-isotope-Imaging-Mass-Spectrometry-Reveals-Penetration-of-18O-Trehalose-in-Mouse-Sperm-pone.0042267.s001.ogv 19 s, 1,100 × 550; 8.29 MB
3D-Printable-Graphene-Composite-srep11181-s2.ogv 56 s, 320 × 240; 2.45 MB
3D-Printed-Microwell-Arrays-for-Ciona-Microinjection-and-Timelapse-Imaging-pone.0082307.s002.ogv 23 s, 360 × 240; 8.73 MB
3D-Printed-Microwell-Arrays-for-Ciona-Microinjection-and-Timelapse-Imaging-pone.0082307.s003.ogv 1 min 56 s, 480 × 270; 3.45 MB
3D-Printed-Microwell-Arrays-for-Ciona-Microinjection-and-Timelapse-Imaging-pone.0082307.s004.ogv 51 s, 490 × 446; 854 KB
3D-Printed-Multimaterial-Microfluidic-Valve-pone.0160624.s007.ogv 17 s, 1,920 × 1,080; 2.27 MB
3D-printed-self-driven-thumb-sized-motors-for-in-situ-underwater-pollutant-remediation-srep41169-s1.ogv 2 min 16 s, 320 × 240; 866 KB
3D-printed-self-driven-thumb-sized-motors-for-in-situ-underwater-pollutant-remediation-srep41169-s2.ogv 6.8 s, 640 × 480; 490 KB
3D-printed-self-driven-thumb-sized-motors-for-in-situ-underwater-pollutant-remediation-srep41169-s3.ogv 1 min 14 s, 640 × 480; 3.14 MB
3D-printed-self-driven-thumb-sized-motors-for-in-situ-underwater-pollutant-remediation-srep41169-s4.ogv 38 s, 640 × 480; 2.36 MB
3D-printed-self-driven-thumb-sized-motors-for-in-situ-underwater-pollutant-remediation-srep41169-s5.ogv 44 s, 640 × 480; 2.75 MB
3D-Printing-of-Meso-structurally-Ordered-Carbon-FiberPolymer-Composites-with-Unprecedented-srep43401-s1.ogv 45 s, 852 × 480; 10.46 MB
3D-Printing-of-Meso-structurally-Ordered-Carbon-FiberPolymer-Composites-with-Unprecedented-srep43401-s2.ogv 25 s, 704 × 480; 1.41 MB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s001.ogv 34 s, 512 × 492; 983 KB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s002.ogv 27 s, 512 × 492; 1.69 MB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s003.ogv 48 s, 512 × 492; 2.28 MB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s004.ogv 26 s, 512 × 492; 240 KB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s005.ogv 3.8 s, 184 × 179; 164 KB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s006.ogv 22 s, 480 × 400; 2.08 MB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s007.ogv 12 s, 512 × 492; 509 KB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s008.ogv 12 s, 512 × 492; 429 KB
3D-Quantitative-Imaging-of-Unprocessed-Live-Tissue-Reveals-Epithelial-Defense-against-Bacterial-pone.0024008.s009.ogv 12 s, 512 × 492; 658 KB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s001.ogv 7.1 s, 638 × 628; 6.72 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s002.ogv 21 s, 496 × 449; 4 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s003.ogv 17 s, 504 × 457; 3.62 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s004.ogv 2.6 s, 1,058 × 1,070; 4.58 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s005.ogv 30 s, 504 × 457; 4.31 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s006.ogv 12 s, 512 × 490; 9.15 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s007.ogv 24 s, 504 × 457; 5.19 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s008.ogv 13 s, 504 × 457; 4.15 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s009.ogv 19 s, 422 × 422; 5.47 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s010.ogv 6.7 s, 801 × 1,116; 2.51 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s011.ogv 20 s, 634 × 511; 5.5 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s012.ogv 27 s, 512 × 512; 3.68 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s013.ogv 15 s, 519 × 519; 3.82 MB
3D-Reconstruction-of-VZV-Infected-Cell-Nuclei-and-PML-Nuclear-Cages-by-Serial-Section-Array-ppat.1002740.s014.ogv 11 s, 512 × 512; 2.08 MB
3D-replicon-distributions-arise-from-stochastic-initiation-and-domino-like-DNA-replication-ncomms11207-s2.ogv 32 s, 1,000 × 750; 40.24 MB
3D-replicon-distributions-arise-from-stochastic-initiation-and-domino-like-DNA-replication-ncomms11207-s3.ogv 31 s, 600 × 450; 3.93 MB
3D-replicon-distributions-arise-from-stochastic-initiation-and-domino-like-DNA-replication-ncomms11207-s4.ogv 32 s, 1,000 × 750; 49.31 MB
3D-SIM-Super-Resolution-Microscopy-Reveals-a-Bead-Like-Arrangement-for-FtsZ-and-the-Division-pbio.1001389.s004.ogv 9.9 s, 1,540 × 905; 2.62 MB
3D-SIM-Super-Resolution-Microscopy-Reveals-a-Bead-Like-Arrangement-for-FtsZ-and-the-Division-pbio.1001389.s005.ogv 10 s, 1,540 × 906; 5.28 MB
3D-SIM-Super-Resolution-Microscopy-Reveals-a-Bead-Like-Arrangement-for-FtsZ-and-the-Division-pbio.1001389.s006.ogv 12 s, 1,920 × 1,080; 307 KB
3D-Structural-Fluctuation-of-IgG1-Antibody-Revealed-by-Individual-Particle-Electron-Tomography-srep09803-s2.ogv 2 min 59 s, 512 × 490; 55.34 MB
3D-Time-lapse-Imaging-and-Quantification-of-Mitochondrial-Dynamics-srep43275-s1.ogv 17 s, 430 × 430; 4.32 MB
3D-Time-lapse-Imaging-and-Quantification-of-Mitochondrial-Dynamics-srep43275-s2.ogv 17 s, 430 × 175; 2.26 MB
3D-Time-lapse-Imaging-and-Quantification-of-Mitochondrial-Dynamics-srep43275-s3.ogv 17 s, 430 × 175; 2.36 MB
3D-tracking-of-single-nanoparticles-and-quantum-dots-in-living-cells-by-out-of-focus-imaging-with-srep16088-s2.ogv 22 s, 121 × 111; 52 KB
3D-tracking-of-single-nanoparticles-and-quantum-dots-in-living-cells-by-out-of-focus-imaging-with-srep16088-s3.ogv 27 s, 117 × 108; 633 KB
3D-tracking-of-single-nanoparticles-and-quantum-dots-in-living-cells-by-out-of-focus-imaging-with-srep16088-s4.ogv 13 s, 111 × 138; 641 KB
3D-Traction-Forces-in-Cancer-Cell-Invasion-pone.0033476.s018.ogv 19 s, 640 × 480; 9.02 MB
3D-Traction-Forces-in-Cancer-Cell-Invasion-pone.0033476.s019.ogv 2.0 s, 1,344 × 1,024; 268 KB
3D-Traction-Forces-in-Cancer-Cell-Invasion-pone.0033476.s020.ogv 17 s, 640 × 480; 971 KB
3D-Traction-Forces-in-Cancer-Cell-Invasion-pone.0033476.s021.ogv 25 s, 640 × 480; 1.17 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s003.ogv 47 s, 1,072 × 940; 25.78 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s004.ogv 24 s, 422 × 504; 11.1 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s005.ogv 55 s, 1,024 × 1,024; 34.82 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s006.ogv 1 min 27 s, 1,104 × 1,168; 24.76 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s007.ogv 20 s, 1,920 × 997; 5.68 MB
3D-Ultrastructural-Organization-of-Whole-Chlamydomonas-reinhardtii-Cells-Studied-by-Nanoscale-Soft-pone.0053293.s008.ogv 20 s, 930 × 720; 2.71 MB
3D-Visualization-of-the-Initial-Yersinia-ruckeri-Infection-Route-in-Rainbow-Trout-(Oncorhynchus-pone.0089672.s004.ogv 41 s, 512 × 512; 2.01 MB
3D-Visualization-of-the-Initial-Yersinia-ruckeri-Infection-Route-in-Rainbow-Trout-(Oncorhynchus-pone.0089672.s005.ogv 36 s, 1,024 × 918; 6.58 MB
3D-Visualization-of-the-Initial-Yersinia-ruckeri-Infection-Route-in-Rainbow-Trout-(Oncorhynchus-pone.0089672.s006.ogv 23 s, 1,024 × 918; 5.51 MB
3D-Visualization-of-the-Temporal-and-Spatial-Spread-of-Tau-Pathology-Reveals-Extensive-Sites-of-Tau-pone.0159463.s004.ogv 58 s, 1,920 × 1,080; 6.68 MB

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