Category:Videos of materials science

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Subcategories

This category has the following 20 subcategories, out of 20 total.

B

Videos of materials science (biology) (1 C, 7 F)

C

Videos of materials characterization (2 C)
Videos of condensed matter physics (6 C, 93 F)
Videos of continuum mechanics (3 C, 2 F)
Videos of crystal structures (8 F)

E

Videos of electromagnetism (10 C, 14 F)

J

Media from Journal of Magnetism and Magnetic Materials (1 F)

L

Videos of liquids (3 C, 9 F)

M

N

Videos of nanotechnology (2 C, 17 F)

P

Videos of materials physics (25 F)
Videos of polymer chemistry (2 C, 70 F)
Videos of material properties (2 C, 62 F)

S

Videos of solid state chemistry (1 C, 1 F)

T

Videos of materials testing (1 C, 9 F)
Videos of thermodynamics (7 C, 14 F)

V

Videos of Von Kármán vortex street (5 F)

Media in category "Videos of materials science"

The following 200 files are in this category, out of 409 total.

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A-Handheld-Point-of-Care-Genomic-Diagnostic-System-pone.0070266.s002.ogv 20 s, 426 × 240; 484 KB
A-Microfluidic-System-for-Studying-Ageing-and-Dynamic-Single-Cell-Responses-in-Budding-Yeast-pone.0100042.s007.ogv 12 s, 422 × 483; 825 KB
A-Microfluidic-System-for-Studying-Ageing-and-Dynamic-Single-Cell-Responses-in-Budding-Yeast-pone.0100042.s008.ogv 4.9 s, 106 × 92; 13 KB
A-Microfluidic-System-for-Studying-Ageing-and-Dynamic-Single-Cell-Responses-in-Budding-Yeast-pone.0100042.s009.ogv 4.9 s, 104 × 92; 14 KB
A-Microfluidic-System-for-Studying-Ageing-and-Dynamic-Single-Cell-Responses-in-Budding-Yeast-pone.0100042.s010.ogv 58 s, 512 × 1,127; 19.81 MB
A-Microfluidic-System-for-Studying-Ageing-and-Dynamic-Single-Cell-Responses-in-Budding-Yeast-pone.0100042.s011.ogv 58 s, 512 × 1,127; 17.4 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-Novel-μCT-Analysis-Reveals-Different-Responses-of-Bioerosion-and-Secondary-Accretion-to-pone.0153058.s002.ogv 20 s, 640 × 356; 2.6 MB
A-Photoactivatable-Nanopatterned-Substrate-for-Analyzing-Collective-Cell-Migration-with-Precisely-pone.0091875.s001.ogv 12 s, 334 × 334; 794 KB
A-Photoactivatable-Nanopatterned-Substrate-for-Analyzing-Collective-Cell-Migration-with-Precisely-pone.0091875.s002.ogv 12 s, 334 × 334; 658 KB
A-Quantitative-Comparison-of-Single-Dye-Tracking-Analysis-Tools-Using-Monte-Carlo-Simulations-pone.0064287.s002.ogv 4.3 s, 320 × 320; 1.73 MB
A-Quantitative-Comparison-of-Single-Dye-Tracking-Analysis-Tools-Using-Monte-Carlo-Simulations-pone.0064287.s003.ogv 4.3 s, 321 × 321; 917 KB
A-Quantitative-Comparison-of-Single-Dye-Tracking-Analysis-Tools-Using-Monte-Carlo-Simulations-pone.0064287.s004.ogv 22 s, 214 × 205; 2.51 MB
A-Quantitative-Comparison-of-Single-Dye-Tracking-Analysis-Tools-Using-Monte-Carlo-Simulations-pone.0064287.s005.ogv 22 s, 216 × 206; 753 KB
A-Simple-and-Versatile-2-Dimensional-Platform-to-Study-Plant-Germination-and-Growth-under-pone.0096730.s003.ogv 1 min 59 s, 640 × 360; 18.55 MB
A-Single-Molecule-Investigation-of-the-Photostability-of-Quantum-Dots-pone.0044355.s004.ogv 8.0 s, 252 × 188; 2.25 MB
A-Single-Molecule-Investigation-of-the-Photostability-of-Quantum-Dots-pone.0044355.s005.ogv 12 s, 512 × 512; 1.48 MB
A-Single-Molecule-Investigation-of-the-Photostability-of-Quantum-Dots-pone.0044355.s006.ogv 12 s, 512 × 512; 6.71 MB
A-Test-of-Canine-Olfactory-Capacity-Comparing-Various-Dog-Breeds-and-Wolves-in-a-Natural-Detection-pone.0154087.s003.ogv 46 s, 854 × 480; 16.5 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
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
Antibodies-Covalently-Immobilized-on-Actin-Filaments-for-Fast-Myosin-Driven-Analyte-Transport-pone.0046298.s005.ogv 9.2 s, 512 × 512; 56 KB
Antibodies-Covalently-Immobilized-on-Actin-Filaments-for-Fast-Myosin-Driven-Analyte-Transport-pone.0046298.s006.ogv 17 s, 512 × 512; 382 KB
Antibodies-Covalently-Immobilized-on-Actin-Filaments-for-Fast-Myosin-Driven-Analyte-Transport-pone.0046298.s007.ogv 5.2 s, 512 × 512; 99 KB
Ateneo EINA 266 - La ingeniería al servicio de la salud, estudio del envejecimiento del corazón.webm 1 h 8 min 27 s, 1,280 × 720; 432.65 MB
ATP-Dependent-Rotational-Motion-of-Group-II-Chaperonin-Observed-by-X-ray-Single-Molecule-Tracking-pone.0064176.s011.ogv 7.5 s, 640 × 480; 327 KB
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
Automated-Cell-Identification-and-Tracking-Using-Nanoparticle-Moving-Light-Displays-pone.0040835.s002.ogv 35 s, 1,280 × 720; 945 KB
Automated-Cell-Identification-and-Tracking-Using-Nanoparticle-Moving-Light-Displays-pone.0040835.s003.ogv 48 s, 1,280 × 720; 10.38 MB
Automated-Cell-Identification-and-Tracking-Using-Nanoparticle-Moving-Light-Displays-pone.0040835.s004.ogv 45 s, 1,280 × 720; 1.73 MB
Automated-Cell-Identification-and-Tracking-Using-Nanoparticle-Moving-Light-Displays-pone.0040835.s005.ogv 49 s, 960 × 720; 4.6 MB
Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s001.ogv 6.0 s, 458 × 422; 828 KB
Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s002.ogv 6.0 s, 462 × 422; 1.14 MB
Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s003.ogv 6.0 s, 404 × 370; 1.14 MB
Automated-Design-of-Complex-Dynamic-Systems-pone.0086696.s004.ogv 6.7 s, 404 × 370; 1.17 MB
Biochemical-and-Structural-Characterization-of-Neocartilage-Formed-by-Mesenchymal-Stem-Cells-in-pone.0091662.s012.ogv 17 s, 1,321 × 1,330; 69.79 MB
Brazil nut effect demonstration.webm 14 s, 1,620 × 2,160; 11.02 MB
Caenorhabditis-elegans-Maintains-Highly-Compartmentalized-Cellular-Distribution-of-Metals-and-Steep-pone.0032685.s002.ogv 32 s, 1,280 × 1,024; 2.1 MB
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-Signaling-in-Live-Cells-on-Elastic-Gels-under-Mechanical-Vibration-at-Subcellular-Levels-pone.0026181.s003.ogv 29 s, 496 × 760; 532 KB
Calcium-Signaling-in-Live-Cells-on-Elastic-Gels-under-Mechanical-Vibration-at-Subcellular-Levels-pone.0026181.s004.ogv 29 s, 524 × 766; 333 KB
Calcium-Signaling-in-Live-Cells-on-Elastic-Gels-under-Mechanical-Vibration-at-Subcellular-Levels-pone.0026181.s005.ogv 8.3 s, 1,024 × 512; 846 KB
Calcium-Signaling-in-Live-Cells-on-Elastic-Gels-under-Mechanical-Vibration-at-Subcellular-Levels-pone.0026181.s006.ogv 18 s, 1,024 × 512; 429 KB
Calcium-Wave-Propagation-in-Networks-of-Endothelial-Cells-Model-based-Theoretical-and-Experimental-pcbi.1002847.s003.ogv 6.9 s, 245 × 288; 133 KB
Calcium-Wave-Propagation-in-Networks-of-Endothelial-Cells-Model-based-Theoretical-and-Experimental-pcbi.1002847.s004.ogv 6.0 s, 218 × 257; 229 KB
Calcium-Wave-Propagation-in-Networks-of-Endothelial-Cells-Model-based-Theoretical-and-Experimental-pcbi.1002847.s005.ogv 4.4 s, 321 × 384; 91 KB
Calcium-Wave-Propagation-in-Networks-of-Endothelial-Cells-Model-based-Theoretical-and-Experimental-pcbi.1002847.s006.ogv 5.0 s, 422 × 403; 210 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s001.ogv 8.3 s, 320 × 240; 161 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s002.ogv 8.1 s, 320 × 240; 131 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s003.ogv 8.5 s, 320 × 240; 204 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s004.ogv 13 s, 320 × 240; 202 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s005.ogv 9.3 s, 320 × 240; 126 KB
Cell-Origami-Self-Folding-of-Three-Dimensional-Cell-Laden-Microstructures-Driven-by-Cell-Traction-pone.0051085.s006.ogv 9.4 s, 640 × 480; 4.82 MB
Characterization-of-Cross-Linked-Porous-Gelatin-Carriers-and-Their-Interaction-with-Corneal-pone.0054058.s002.ogv 26 s, 640 × 480; 2.67 MB
Characterization-of-the-Drosophila-BEAF-32A-and-BEAF-32B-Insulator-Proteins-pone.0162906.s004.ogv 20 s, 512 × 512; 4.51 MB
Characterization-of-the-Drosophila-BEAF-32A-and-BEAF-32B-Insulator-Proteins-pone.0162906.s006.ogv 1 min 2 s, 854 × 480; 31.61 MB
Colloids-as-Mobile-Substrates-for-the-Implantation-and-Integration-of-Differentiated-Neurons-into-pone.0030293.s007.ogv 1 min 11 s, 42 × 42; 216 KB
Conformational-Dynamics-of-Dry-Lamellar-Crystals-of-Sugar-Based-Lipids-An-Atomistic-Simulation-Study-pone.0101110.s009.ogv 2 min 13 s, 320 × 240; 57.99 MB
Conformational-Dynamics-of-Dry-Lamellar-Crystals-of-Sugar-Based-Lipids-An-Atomistic-Simulation-Study-pone.0101110.s010.ogv 1 min 3 s, 640 × 480; 31.99 MB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s007.ogv 1 min 13 s, 336 × 256; 484 KB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s008.ogv 1 min 13 s, 336 × 256; 436 KB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s009.ogv 13 s, 256 × 256; 4.26 MB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s010.ogv 1 min 13 s, 336 × 256; 436 KB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s011.ogv 14 s, 256 × 256; 6.01 MB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s012.ogv 9.5 s, 336 × 256; 178 KB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s013.ogv 14 s, 256 × 256; 2.88 MB
Contraction-Mechanisms-in-Composite-Active-Actin-Networks-pone.0039869.s014.ogv 7.8 s, 336 × 256; 379 KB
Contrasting-MicroNano-Architecture-on-Termite-Wings-Two-Divergent-Strategies-for-Optimising-Success-pone.0024368.s003.ogv 17 s, 640 × 480; 226 KB
Contrasting-MicroNano-Architecture-on-Termite-Wings-Two-Divergent-Strategies-for-Optimising-Success-pone.0024368.s004.ogv 4.4 s, 853 × 480; 2.42 MB
Contrasting-MicroNano-Architecture-on-Termite-Wings-Two-Divergent-Strategies-for-Optimising-Success-pone.0024368.s005.ogv 5.1 s, 853 × 480; 1.49 MB
Controlled-Delivery-of-Sonic-Hedgehog-Morphogen-and-Its-Potential-for-Cardiac-Repair-pone.0063075.s002.ogv 2.0 s, 1,280 × 720; 562 KB
Controlled-Delivery-of-Sonic-Hedgehog-Morphogen-and-Its-Potential-for-Cardiac-Repair-pone.0063075.s003.ogv 2.0 s, 1,280 × 720; 324 KB
Controlled-Delivery-of-Sonic-Hedgehog-Morphogen-and-Its-Potential-for-Cardiac-Repair-pone.0063075.s004.ogv 2.0 s, 1,280 × 720; 422 KB
Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s009.ogv 45 s, 960 × 720; 7.02 MB
Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s010.ogv 50 s, 1,006 × 968; 12.7 MB
Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s011.ogv 27 s, 1,354 × 540; 10.08 MB
Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s012.ogv 20 s, 1,024 × 1,024; 2.78 MB
Coordination-of-Cellular-Dynamics-Contributes-to-Tooth-Epithelium-Deformations-pone.0161336.s013.ogv 30 s, 715 × 720; 12.23 MB
Correlative-Nanoscale-3D-Imaging-of-Structure-and-Composition-in-Extended-Objects-pone.0050124.s002.ogv 1 min 2 s, 464 × 384; 6.83 MB
Cyanine-5.5-Conjugated-Nanobubbles-as-a-Tumor-Selective-Contrast-Agent-for-Dual-Ultrasound-pone.0061224.s002.ogv 25 s, 960 × 720; 6.11 MB
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
D-Alanine-Controlled-Transient-Intestinal-Mono-Colonization-with-Non-Laboratory-Adapted-Commensal-pone.0151872.s006.ogv 24 s, 846 × 558; 575 KB
Deep-and-Clear-Optical-Imaging-of-Thick-Inhomogeneous-Samples-pone.0035795.s001.ogv 7.2 s, 1,094 × 748; 224 KB
Deep-and-Clear-Optical-Imaging-of-Thick-Inhomogeneous-Samples-pone.0035795.s002.ogv 7.2 s, 1,094 × 748; 204 KB
Deep-and-Clear-Optical-Imaging-of-Thick-Inhomogeneous-Samples-pone.0035795.s003.ogv 7.2 s, 1,150 × 748; 757 KB
Deep-and-Clear-Optical-Imaging-of-Thick-Inhomogeneous-Samples-pone.0035795.s004.ogv 7.2 s, 1,150 × 748; 907 KB
Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s001.ogv 15 s, 758 × 479; 10.3 MB
Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s002.ogv 15 s, 758 × 479; 10.27 MB
Dendrimers-Bind-Antioxidant-Polyphenols-and-cisPlatin-Drug-pone.0033102.s003.ogv 3.2 s, 758 × 479; 1.36 MB
Density-Gradient-Mediated-Band-Extraction-of-Leukocytes-from-Whole-Blood-Using-Centrifugo-Pneumatic-pone.0155545.s001.ogv 2 min 43 s, 1,280 × 720; 17.39 MB
Depending-on-Its-Nano-Spacing-ALCAM-Promotes-Cell-Attachment-and-Axon-Growth-pone.0040493.s006.ogv 1 min 12 s, 366 × 656; 828 KB
Depending-on-Its-Nano-Spacing-ALCAM-Promotes-Cell-Attachment-and-Axon-Growth-pone.0040493.s007.ogv 1 min 12 s, 670 × 722; 2.58 MB
Depending-on-Its-Nano-Spacing-ALCAM-Promotes-Cell-Attachment-and-Axon-Growth-pone.0040493.s008.ogv 1 min 12 s, 425 × 647; 1.72 MB
Depending-on-Its-Nano-Spacing-ALCAM-Promotes-Cell-Attachment-and-Axon-Growth-pone.0040493.s009.ogv 1 min 12 s, 300 × 360; 273 KB
Depending-on-Its-Nano-Spacing-ALCAM-Promotes-Cell-Attachment-and-Axon-Growth-pone.0040493.s010.ogv 1 min 12 s, 231 × 245; 192 KB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s006.ogv 39 s, 1,388 × 1,040; 6.65 MB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s007.ogv 39 s, 1,388 × 1,040; 11.03 MB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s008.ogv 39 s, 1,388 × 1,040; 6.86 MB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s009.ogv 39 s, 1,388 × 1,040; 6.86 MB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s010.ogv 39 s, 426 × 240; 2.35 MB
Differential-Effects-of-Tissue-Culture-Coating-Substrates-on-Prostate-Cancer-Cell-Adherence-pone.0112122.s011.ogv 39 s, 1,388 × 1,040; 5.96 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
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s013.ogv 5.3 s, 452 × 198; 397 KB
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s014.ogv 6.4 s, 452 × 588; 493 KB
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s015.ogv 10 s, 316 × 466; 868 KB
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s016.ogv 8.2 s, 546 × 482; 4.24 MB
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s017.ogv 5.8 s, 780 × 416; 499 KB
DNAH6-and-Its-Interactions-with-PCD-Genes-in-Heterotaxy-and-Primary-Ciliary-Dyskinesia-pgen.1005821.s018.ogv 4.6 s, 392 × 220; 145 KB
Drosophila-Embryos-as-Model-to-Assess-Cellular-and-Developmental-Toxicity-of-Multi-Walled-Carbon-pone.0088681.s002.ogv 10 s, 798 × 714; 3.8 MB
Drosophila-Embryos-as-Model-to-Assess-Cellular-and-Developmental-Toxicity-of-Multi-Walled-Carbon-pone.0088681.s004.ogv 9.0 s, 818 × 726; 5.02 MB
Drug-Eluting-Fibers-for-HIV-1-Inhibition-and-Contraception-pone.0049792.s013.ogv 12 s, 696 × 520; 1.1 MB
Drug-Eluting-Fibers-for-HIV-1-Inhibition-and-Contraception-pone.0049792.s014.ogv 13 s, 696 × 520; 2.12 MB
Drug-Eluting-Fibers-for-HIV-1-Inhibition-and-Contraception-pone.0049792.s015.ogv 10 s, 696 × 520; 1.29 MB
Drug-Eluting-Fibers-for-HIV-1-Inhibition-and-Contraception-pone.0049792.s016.ogv 10 s, 696 × 520; 1.64 MB
Dynamic-Cholesterol-Conditioned-Dimerization-of-the-G-Protein-Coupled-Chemokine-Receptor-Type-4-pcbi.1005169.s002.ogv 27 s, 640 × 360; 13.42 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
Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s005.ogv 3.1 s, 600 × 600; 410 KB
Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s006.ogv 3.1 s, 600 × 600; 310 KB
Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s007.ogv 3.1 s, 600 × 600; 228 KB
Dynamic-Filament-Formation-by-a-Divergent-Bacterial-Actin-Like-ParM-Protein-pone.0156944.s008.ogv 3.1 s, 600 × 600; 247 KB
Dynamic-Nondestructive-Imaging-of-a-Bioengineered-Vascular-Graft-Endothelium-pone.0061275.s001.ogv 12 s, 960 × 540; 567 KB
Dynamic-Prestress-in-a-Globular-Protein-pcbi.1002509.s010.ogv 0.0 s, 656 × 608; 9.08 MB
Effects-of-Nanostructures-and-Mouse-Embryonic-Stem-Cells-on-In-Vitro-Morphogenesis-of-Rat-pone.0060054.s002.ogv 2 min 24 s, 640 × 480; 12.16 MB
Electrical-Sintering-of-Silver-Nanoparticle-Ink-Studied-by-In-Situ-TEM-Probing-pone.0017209.s001.ogv 15 s, 768 × 752; 888 KB
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
End-to-End-Digitisation-and-Analysis-of-Three-Dimensional-Coral-Models-from-Communities-to-pone.0149641.s004.ogv 12 s, 1,260 × 720; 13.35 MB
Endo-Lysosomal-Vesicles-Positive-for-Rab7-and-LAMP1-Are-Terminal-Vesicles-for-the-Transport-of-pone.0026626.s007.ogv 10 s, 131 × 111; 560 KB
Engineering-of-In-Vitro-3D-Capillary-Beds-by-Self-Directed-Angiogenic-Sprouting-pone.0050582.s005.ogv 20 s, 492 × 374; 1.15 MB
Engineering-of-In-Vitro-3D-Capillary-Beds-by-Self-Directed-Angiogenic-Sprouting-pone.0050582.s006.ogv 11 s, 1,169 × 627; 279 KB
Enhanced-Nasal-Mucosal-Delivery-and-Immunogenicity-of-Anti-Caries-DNA-Vaccine-through-Incorporation-pone.0071953.s006.ogv 6.7 s, 880 × 503; 2.81 MB
Enhanced-Nasal-Mucosal-Delivery-and-Immunogenicity-of-Anti-Caries-DNA-Vaccine-through-Incorporation-pone.0071953.s007.ogv 10 s, 880 × 503; 4.02 MB
Feasibility-Study-of-the-Permeability-and-Uptake-of-Mesoporous-Silica-Nanoparticles-across-the-pone.0160705.s006.ogv 4.4 s, 680 × 680; 1.86 MB
Fetal-Fibroblasts-and-Keratinocytes-with-Immunosuppressive-Properties-for-Allogeneic-Cell-Based-pone.0070408.s005.ogv 8.9 s, 696 × 520; 7.5 MB
Fetal-Fibroblasts-and-Keratinocytes-with-Immunosuppressive-Properties-for-Allogeneic-Cell-Based-pone.0070408.s006.ogv 8.9 s, 696 × 520; 4.79 MB
Fetal-Fibroblasts-and-Keratinocytes-with-Immunosuppressive-Properties-for-Allogeneic-Cell-Based-pone.0070408.s007.ogv 8.9 s, 696 × 520; 7.53 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
First-Person-Perspective-Virtual-Body-Posture-Influences-Stress-A-Virtual-Reality-Body-Ownership-pone.0148060.s003.ogv 1 min 38 s, 854 × 480; 22.69 MB
Full-Length-Fibronectin-Drives-Fibroblast-Accumulation-at-the-Surface-of-Collagen-Microtissues-pone.0160369.s006.ogv 4.3 s, 512 × 512; 465 KB
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Full-Length-Fibronectin-Drives-Fibroblast-Accumulation-at-the-Surface-of-Collagen-Microtissues-pone.0160369.s019.ogv 4.1 s, 1,000 × 272; 636 KB
Full-Length-Fibronectin-Drives-Fibroblast-Accumulation-at-the-Surface-of-Collagen-Microtissues-pone.0160369.s020.ogv 3.7 s, 1,000 × 272; 922 KB
Full-Length-Fibronectin-Drives-Fibroblast-Accumulation-at-the-Surface-of-Collagen-Microtissues-pone.0160369.s021.ogv 4.0 s, 1,000 × 272; 801 KB
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Functional-Remineralization-of-Dentin-Lesions-Using-Polymer-Induced-Liquid-Precursor-Process-pone.0038852.s003.ogv 7.1 s, 1,088 × 896; 15.49 MB
High-Refractive-Index-Silicone-Gels-for-Simultaneous-Total-Internal-Reflection-Fluorescence-and-pone.0023807.s003.ogv 7.4 s, 256 × 256; 634 KB
High-Refractive-Index-Silicone-Gels-for-Simultaneous-Total-Internal-Reflection-Fluorescence-and-pone.0023807.s004.ogv 5.4 s, 256 × 256; 270 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s002.ogv 2.6 s, 1,024 × 768; 130 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s003.ogv 2.6 s, 1,024 × 768; 188 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s004.ogv 2.6 s, 1,024 × 768; 244 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s005.ogv 2.6 s, 1,024 × 768; 191 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s006.ogv 2.6 s, 1,024 × 768; 224 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s007.ogv 2.6 s, 1,024 × 768; 217 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s008.ogv 2.6 s, 1,024 × 768; 257 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s009.ogv 2.6 s, 640 × 480; 145 KB
Highly-Compact-Circulators-in-Square-Lattice-Photonic-Crystal-Waveguides-pone.0113508.s010.ogv 2.6 s, 640 × 480; 139 KB
Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s001.ogv 6.1 s, 800 × 600; 7.99 MB
Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s002.ogv 12 s, 824 × 658; 729 KB
Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s003.ogv 9.8 s, 1,024 × 683; 1.08 MB
Honeycomb-Actuators-Inspired-by-the-Unfolding-of-Ice-Plant-Seed-Capsules-pone.0163506.s004.ogv 7.3 s, 4,672 × 3,104; 23.3 MB
How-Fast-Does-a-Signal-Propagate-through-Proteins-pone.0064746.s002.ogv 4.0 s, 789 × 296; 777 KB
In-Vitro-Interactions-between-Bacteria-Osteoblast-Like-Cells-and-Macrophages-in-the-Pathogenesis-of-pone.0024827.s003.ogv 30 s, 640 × 480; 1.64 MB
In-Vivo-Time-Resolved-Microtomography-Reveals-the-Mechanics-of-the-Blowfly-Flight-Motor-pbio.1001823.s002.ogv 10 s, 1,440 × 680; 9.69 MB
In-Vivo-Time-Resolved-Microtomography-Reveals-the-Mechanics-of-the-Blowfly-Flight-Motor-pbio.1001823.s003.ogv 10 s, 1,200 × 720; 8.66 MB
Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s006.ogv 31 s, 696 × 520; 1.28 MB
Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s007.ogv 32 s, 696 × 520; 1.04 MB
Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s008.ogv 11 s, 696 × 520; 801 KB
Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s009.ogv 5.8 s, 696 × 520; 257 KB
Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s010.ogv 5.4 s, 696 × 520; 439 KB

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