Category:Videos of materials science

Subcategories

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

Media in category "Videos of materials science"

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

• Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s011.ogv 5.9 s, 696 × 520; 348 KB
  
• Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s012.ogv 34 s, 696 × 520; 2.54 MB
  
• Induced-Pluripotent-Stem-Cell-Derived-Cardiac-Progenitors-Differentiate-to-Cardiomyocytes-and-Form-pone.0065963.s013.ogv 26 s, 192 × 208; 1.08 MB
  
• Insertion-of-Short-Amino-Functionalized-Single-Walled-Carbon-Nanotubes-into-Phospholipid-Bilayer-pone.0040703.s008.ogv 1 min 0 s, 288 × 224; 6.87 MB
  
• Insertion-of-Short-Amino-Functionalized-Single-Walled-Carbon-Nanotubes-into-Phospholipid-Bilayer-pone.0040703.s009.ogv 46 s, 288 × 224; 5.48 MB
  
• Insertion-of-Short-Amino-Functionalized-Single-Walled-Carbon-Nanotubes-into-Phospholipid-Bilayer-pone.0040703.s010.ogv 1 min 35 s, 288 × 224; 11.02 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s001.ogv 1 min 23 s, 200 × 200; 5.77 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s002.ogv 3.7 s, 76 × 76; 18 KB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s003.ogv 1 min 40 s, 76 × 76; 143 KB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s004.ogv 11 s, 92 × 92; 109 KB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s005.ogv 15 s, 92 × 92; 177 KB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s006.ogv 41 s, 300 × 300; 1.89 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s007.ogv 17 s, 300 × 300; 562 KB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s008.ogv 21 s, 300 × 300; 6.18 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s009.ogv 7.1 s, 300 × 300; 1.72 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s010.ogv 8.3 s, 300 × 300; 1.66 MB
  
• Listeriolysin-O-Membrane-Damaging-Activity-Involves-Arc-Formation-and-Lineaction----Implication-for-ppat.1005597.s011.ogv 12 s, 300 × 300; 3.75 MB
  
• Long-Distance-Axial-Trapping-with-Focused-Annular-Laser-Beams-pone.0057984.s001.ogv 1 min 40 s, 608 × 448; 1.38 MB
  
• Long-Distance-Axial-Trapping-with-Focused-Annular-Laser-Beams-pone.0057984.s002.ogv 11 s, 608 × 448; 221 KB
  
• Long-Distance-Axial-Trapping-with-Focused-Annular-Laser-Beams-pone.0057984.s003.ogv 57 s, 608 × 448; 1 MB
  
• Long-Term-Imaging-of-Caenorhabditis-elegans-Using-Nanoparticle-Mediated-Immobilization-pone.0053419.s001.ogv 0.4 s, 752 × 460; 174 KB
  
• Magnetic-Cross-Linked-Enzyme-Aggregates-(mCLEAs)-of-Candida-antarctica-Lipase-An-Efficient-and-pone.0115202.s003.ogv 1 min 16 s, 640 × 480; 12.84 MB
  
• MAL-Is-a-Regulator-of-the-Recruitment-of-Myelin-Protein-PLP-to-Membrane-Microdomains-pone.0155317.s002.ogv 3.3 s, 788 × 734; 477 KB
  
• MAL-Is-a-Regulator-of-the-Recruitment-of-Myelin-Protein-PLP-to-Membrane-Microdomains-pone.0155317.s003.ogv 3.7 s, 685 × 740; 580 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s006.ogv 12 s, 420 × 250; 1.48 MB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s007.ogv 13 s, 200 × 300; 774 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s008.ogv 18 s, 178 × 216; 1.16 MB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s009.ogv 13 s, 320 × 320; 469 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s010.ogv 7.8 s, 306 × 312; 503 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s011.ogv 7.8 s, 220 × 220; 411 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s012.ogv 9.4 s, 420 × 250; 1.08 MB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s013.ogv 6.6 s, 312 × 268; 559 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s014.ogv 9.4 s, 462 × 228; 236 KB
  
• Maturation-of-Filopodia-Shaft-Adhesions-Is-Upregulated-by-Local-Cycles-of-Lamellipodia-Advancements-pone.0107097.s015.ogv 7.8 s, 302 × 302; 379 KB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s007.ogv 13 s, 528 × 480; 5.12 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s008.ogv 13 s, 528 × 480; 5.05 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s009.ogv 13 s, 528 × 480; 2.42 MB
  
• MEDYAN-Mechanochemical-Simulations-of-Contraction-and-Polarity-Alignment-in-Actomyosin-Networks-pcbi.1004877.s010.ogv 4.2 s, 528 × 480; 1.79 MB
  
• Membrane-Mediated-Antimicrobial-and-Antitumor-Activity-of-Cathelicidin-6-Structural-Insights-from-pone.0158702.s007.ogv 52 s, 320 × 240; 20.32 MB
  
• Membrane-Mediated-Antimicrobial-and-Antitumor-Activity-of-Cathelicidin-6-Structural-Insights-from-pone.0158702.s008.ogv 1 min 23 s, 426 × 240; 18.82 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s002.ogv 6.7 s, 1,392 × 784; 2.91 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s003.ogv 6.7 s, 1,392 × 784; 3.41 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s004.ogv 6.7 s, 1,392 × 784; 3.01 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s005.ogv 6.7 s, 1,392 × 784; 3.49 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s006.ogv 6.7 s, 1,392 × 784; 4.54 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s007.ogv 6.7 s, 1,392 × 784; 4.35 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s008.ogv 6.7 s, 1,392 × 784; 3.84 MB
  
• Micro-CT-Imaging-of-Denatured-Chitin-by-Silver-to-Explore-Honey-Bee-and-Insect-Pathologies-pone.0027448.s009.ogv 6.7 s, 1,392 × 784; 4.26 MB
  
• Migration-of-Periodontal-Ligament-Fibroblasts-on-Nanometric-Topographical-Patterns-Influence-of-pone.0015129.s001.ogv 12 s, 1,388 × 1,040; 655 KB
  
• Migration-of-Periodontal-Ligament-Fibroblasts-on-Nanometric-Topographical-Patterns-Influence-of-pone.0015129.s002.ogv 20 s, 780 × 585; 309 KB
  
• Migration-of-Periodontal-Ligament-Fibroblasts-on-Nanometric-Topographical-Patterns-Influence-of-pone.0015129.s003.ogv 20 s, 832 × 624; 1.22 MB
  
• Migration-of-Periodontal-Ligament-Fibroblasts-on-Nanometric-Topographical-Patterns-Influence-of-pone.0015129.s004.ogv 20 s, 266 × 624; 3.81 MB
  
• MiR-34a-Targeting-of-Notch-Ligand-Delta-Like-1-Impairs-CD15+CD133+-Tumor-Propagating-Cells-and-pone.0024584.s010.ogv 9.1 s, 1,388 × 1,040; 5.93 MB
  
• Modeling-and-Simulation-of-the-Transient-Response-of-Temperature-and-Relative-Humidity-Sensors-with-pone.0095874.s001.ogv 7.5 s, 1,920 × 1,080; 1.57 MB
  
• Modeling-Effects-of-RNA-on-Capsid-Assembly-Pathways-via-Coarse-Grained-Stochastic-Simulation-pone.0156547.s006.ogv 2 min 26 s, 560 × 420; 16.75 MB
  
• Modeling-Effects-of-RNA-on-Capsid-Assembly-Pathways-via-Coarse-Grained-Stochastic-Simulation-pone.0156547.s007.ogv 16 s, 560 × 420; 1.64 MB
  
• Modeling-Effects-of-RNA-on-Capsid-Assembly-Pathways-via-Coarse-Grained-Stochastic-Simulation-pone.0156547.s008.ogv 37 s, 560 × 420; 2.39 MB
  
• Modeling-Effects-of-RNA-on-Capsid-Assembly-Pathways-via-Coarse-Grained-Stochastic-Simulation-pone.0156547.s009.ogv 2.4 s, 560 × 420; 360 KB
  
• Molecular-Threading-Mechanical-Extraction-Stretching-and-Placement-of-DNA-Molecules-from-a-Liquid-pone.0069058.s009.ogv 1 min 1 s, 600 × 480; 774 KB
  
• Monitoring-and-Scoring-Counter-Diffusion-Protein-Crystallization-Experiments-in-Capillaries-by-in-pone.0033545.s003.ogv 22 s, 640 × 480; 701 KB
  
• Monitoring-and-Scoring-Counter-Diffusion-Protein-Crystallization-Experiments-in-Capillaries-by-in-pone.0033545.s004.ogv 14 s, 310 × 134; 35 KB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s011.ogv 56 s, 480 × 360; 3.85 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s012.ogv 1 min 5 s, 480 × 360; 4.04 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s013.ogv 52 s, 480 × 360; 6.07 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s014.ogv 1 min 5 s, 640 × 360; 15.66 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s015.ogv 1 min 36 s, 480 × 360; 8.03 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s016.ogv 1 min 38 s, 480 × 360; 6.03 MB
  
• Motion-and-Flexibility-in-Human-Cytochrome-P450-Aromatase-pone.0032565.s017.ogv 2 min 51 s, 480 × 360; 14.38 MB
  
• Multi-Scale-Molecular-Photoacoustic-Tomography-of-Gene-Expression-pone.0043999.s001.ogv 5.8 s, 1,280 × 608; 3.53 MB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s007.ogv 13 s, 160 × 140; 151 KB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s008.ogv 26 s, 266 × 199; 331 KB
  
• Nanoparticle-Induced-Cell-Magneto-Rotation-Monitoring-Morphology-Stress-and-Drug-Sensitivity-of-a-pone.0028475.s009.ogv 2 min 0 s, 58 × 54; 194 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s009.ogv 2.0 s, 208 × 216; 26 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s010.ogv 2.0 s, 208 × 216; 6 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s011.ogv 9.0 s, 176 × 176; 55 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s012.ogv 9.0 s, 176 × 176; 17 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s013.ogv 8.5 s, 84 × 60; 14 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s014.ogv 8.5 s, 84 × 60; 7 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s015.ogv 8.0 s, 104 × 108; 14 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s016.ogv 8.0 s, 104 × 108; 7 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s017.ogv 0.3 s, 172 × 284; 47 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s018.ogv 13 s, 72 × 60; 31 KB
  
• Neutrophil-Attack-Triggers-Extracellular-Trap-Dependent-Candida-Cell-Wall-Remodeling-and-Altered-ppat.1005644.s019.ogv 13 s, 72 × 60; 11 KB
  
• Next-Generation-Non-Vacuum-Maskless-Low-Temperature-Nanoparticle-Ink-Laser-Digital-Direct-Metal-pone.0042315.s005.ogv 26 s, 800 × 600; 4.28 MB
  
• Next-Generation-Non-Vacuum-Maskless-Low-Temperature-Nanoparticle-Ink-Laser-Digital-Direct-Metal-pone.0042315.s006.ogv 32 s, 800 × 600; 3.91 MB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s012.ogv 19 s, 1,248 × 512; 2.43 MB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s013.ogv 18 s, 1,344 × 512; 2.56 MB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s014.ogv 15 s, 672 × 512; 66 KB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s015.ogv 24 s, 672 × 512; 1.75 MB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s016.ogv 11 s, 511 × 388; 742 KB
  
• Nuclear-Motility-in-Glioma-Cells-Reveals-a-Cell-Line-Dependent-Role-of-Various-Cytoskeletal-pone.0093431.s017.ogv 11 s, 1,536 × 759; 5.18 MB
  
• Nut-Cracking-Tools-Used-by-Captive-Chimpanzees-(Pan-troglodytes)-and-Their-Comparison-with-Early-pone.0166788.s002.ogv 34 s, 854 × 480; 5.66 MB
  
• Nut-Cracking-Tools-Used-by-Captive-Chimpanzees-(Pan-troglodytes)-and-Their-Comparison-with-Early-pone.0166788.s003.ogv 28 s, 1,280 × 720; 3.98 MB
  
• Open-Source-Selective-Laser-Sintering-(OpenSLS)-of-Nylon-and-Biocompatible-Polycaprolactone-pone.0147399.s006.ogv 34 s, 1,920 × 1,080; 23.17 MB
  
• Open-Source-Selective-Laser-Sintering-(OpenSLS)-of-Nylon-and-Biocompatible-Polycaprolactone-pone.0147399.s007.ogv 22 s, 854 × 480; 1.79 MB
  
• Openstage-A-Low-Cost-Motorized-Microscope-Stage-with-Sub-Micron-Positioning-Accuracy-pone.0088977.s001.ogv 51 s, 436 × 343; 5.8 MB
  
• Openstage-A-Low-Cost-Motorized-Microscope-Stage-with-Sub-Micron-Positioning-Accuracy-pone.0088977.s002.ogv 19 s, 436 × 343; 1.88 MB
  
• Openstage-A-Low-Cost-Motorized-Microscope-Stage-with-Sub-Micron-Positioning-Accuracy-pone.0088977.s003.ogv 5.0 s, 919 × 438; 1.05 MB
  
• Optimization-and-In-Vivo-Toxicity-Evaluation-of-G4.5-Pamam-Dendrimer-Risperidone-Complexes-pone.0090393.s001.ogv 15 s, 1,280 × 720; 1.46 MB
  
• Osmotic-Effects-Induced-by-Pore-Forming-Agent-Nystatin-From-Lipid-Vesicles-to-the-Cell-pone.0165098.s002.ogv 19 s, 301 × 293; 484 KB
  
• Osmotic-Effects-Induced-by-Pore-Forming-Agent-Nystatin-From-Lipid-Vesicles-to-the-Cell-pone.0165098.s003.ogv 17 s, 314 × 309; 538 KB
  
• Performance-in-Object-Choice-Aesops-Fable-Tasks-Are-Influenced-by-Object-Biases-in-New-Caledonian-pone.0168056.s003.ogv 7 min 17 s, 854 × 480; 36.67 MB
  
• Phagocytosis-of-Bacteria-Adhering-to-a-Biomaterial-Surface-in-a-Surface-Thermodynamic-Perspective-pone.0070046.s007.ogv 1 min 20 s, 768 × 576; 5.03 MB
  
• Phagocytosis-of-Bacteria-Adhering-to-a-Biomaterial-Surface-in-a-Surface-Thermodynamic-Perspective-pone.0070046.s008.ogv 22 s, 768 × 576; 1.06 MB
  
• Phenotypic-Characterization-of-Prostate-Cancer-LNCaP-Cells-Cultured-within-a-Bioengineered-pone.0040217.s007.ogv 4.6 s, 640 × 480; 71 KB
  
• Plant-Growth-Environments-with-Programmable-Relative-Humidity-and-Homogeneous-Nutrient-Availability-pone.0155960.s001.ogv 4 min 53 s, 500 × 282; 28.93 MB
  
• Plant-Growth-Environments-with-Programmable-Relative-Humidity-and-Homogeneous-Nutrient-Availability-pone.0155960.s002.ogv 3 min 7 s, 500 × 282; 19.92 MB
  
• Polymeric-Micelles-for-Apoptosis-Targeted-Optical-Imaging-of-Cancer-and-Intraoperative-Surgical-pone.0089968.s004.ogv 14 s, 320 × 240; 171 KB
  
• Polymeric-Micelles-for-Apoptosis-Targeted-Optical-Imaging-of-Cancer-and-Intraoperative-Surgical-pone.0089968.s005.ogv 9.2 s, 320 × 240; 82 KB
  
• Polymeric-Micelles-for-Apoptosis-Targeted-Optical-Imaging-of-Cancer-and-Intraoperative-Surgical-pone.0089968.s006.ogv 9.6 s, 320 × 240; 61 KB
  
• Porous-Chitosan-Scaffolds-with-Embedded-Hyaluronic-AcidChitosanPlasmid-DNA-Nanoparticles-Encoding-pone.0069950.s004.ogv 6.6 s, 375 × 288; 41 KB
  
• Porous-Chitosan-Scaffolds-with-Embedded-Hyaluronic-AcidChitosanPlasmid-DNA-Nanoparticles-Encoding-pone.0069950.s005.ogv 6.6 s, 375 × 288; 66 KB
  
• Porous-Chitosan-Scaffolds-with-Embedded-Hyaluronic-AcidChitosanPlasmid-DNA-Nanoparticles-Encoding-pone.0069950.s006.ogv 3.9 s, 375 × 288; 11 KB
  
• Porous-Chitosan-Scaffolds-with-Embedded-Hyaluronic-AcidChitosanPlasmid-DNA-Nanoparticles-Encoding-pone.0069950.s007.ogv 6.6 s, 375 × 288; 37 KB
  
• Possible model of nanoparticles formation at non-quilibrium conditions.webm 18 s, 1,920 × 1,080; 9.66 MB
  
• Quantitative-Characterization-of-the-Influence-of-the-Nanoscale-Morphology-of-Nanostructured-pone.0025029.s006.ogv 5.0 s, 1,024 × 1,024; 3.11 MB
  
• Quantum-Dots-Do-Not-Affect-the-Behaviour-of-Mouse-Embryonic-Stem-Cells-and-Kidney-Stem-Cells-and-pone.0032650.s002.ogv 10 s, 720 × 240; 460 KB
  
• Quantum-Dots-Do-Not-Affect-the-Behaviour-of-Mouse-Embryonic-Stem-Cells-and-Kidney-Stem-Cells-and-pone.0032650.s003.ogv 10 s, 720 × 240; 244 KB
  
• Quantum-Dots-Do-Not-Affect-the-Behaviour-of-Mouse-Embryonic-Stem-Cells-and-Kidney-Stem-Cells-and-pone.0032650.s004.ogv 10 s, 720 × 240; 243 KB
  
• Quantum-Dots-Do-Not-Affect-the-Behaviour-of-Mouse-Embryonic-Stem-Cells-and-Kidney-Stem-Cells-and-pone.0032650.s005.ogv 10 s, 720 × 240; 140 KB
  
• Rapid-and-Inexpensive-Method-of-Loading-Fluorescent-Dye-into-Pollen-Tubes-and-Root-Hairs-pone.0152320.s007.ogv 40 s, 787 × 576; 662 KB
  
• Regulation-of-Heat-Exchange-across-the-Hornbill-Beak-Functional-Similarities-with-Toucans-pone.0154768.s006.ogv 1 min 31 s, 564 × 360; 4.22 MB
  
• Selective-Individual-Primary-Cell-Capture-Using-Locally-Bio-Functionalized-Micropores-pone.0057717.s002.ogv 38 s, 400 × 312; 235 KB
  
• Selective-Individual-Primary-Cell-Capture-Using-Locally-Bio-Functionalized-Micropores-pone.0057717.s003.ogv 22 s, 400 × 312; 128 KB
  
• Sensitive-and-Specific-Biomimetic-Lipid-Coated-Microfluidics-to-Isolate-Viable-Circulating-Tumor-pone.0149633.s005.ogv 13 s, 960 × 540; 845 KB
  
• Sensitive-and-Specific-Biomimetic-Lipid-Coated-Microfluidics-to-Isolate-Viable-Circulating-Tumor-pone.0149633.s006.ogv 7.9 s, 960 × 540; 436 KB
  
• Shrink-Induced-Superhydrophobic-and-Antibacterial-Surfaces-in-Consumer-Plastics-pone.0040987.s002.ogv 17 s, 640 × 480; 512 KB
  
• Silk-Film-Topography-Directs-Collective-Epithelial-Cell-Migration-pone.0050190.s001.ogv 6.1 s, 1,388 × 1,040; 5.06 MB
  
• Silk-Film-Topography-Directs-Collective-Epithelial-Cell-Migration-pone.0050190.s002.ogv 6.1 s, 1,388 × 1,040; 21.83 MB
  
• Silk-Film-Topography-Directs-Collective-Epithelial-Cell-Migration-pone.0050190.s003.ogv 6.1 s, 1,388 × 1,040; 15.6 MB
  
• Simulation of dislocations in aluminium.webm 20 s, 640 × 640; 4.85 MB
  
• Simulation-of-Force-Spectroscopy-Experiments-on-Galacturonic-Acid-Oligomers-pone.0107896.s010.ogv 42 s, 1,364 × 728; 21.02 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s007.ogv 6.8 s, 1,024 × 512; 922 KB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s008.ogv 6.8 s, 1,024 × 512; 9.96 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s009.ogv 6.7 s, 1,024 × 512; 4.1 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s010.ogv 6.8 s, 1,024 × 512; 3.76 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s011.ogv 6.3 s, 1,024 × 512; 4.74 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s012.ogv 6.3 s, 1,024 × 512; 3.85 MB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s013.ogv 7.1 s, 698 × 698; 739 KB
  
• Size-Dependent-Effects-of-Gold-Nanoparticles-Uptake-on-Maturation-and-Antitumor-Functions-of-Human-pone.0096584.s014.ogv 10 s, 698 × 698; 1.09 MB
  
• Smooth-Muscle-Strips-for-Intestinal-Tissue-Engineering-pone.0114850.s001.ogv 4.4 s, 289 × 226; 2.16 MB
  
• Smooth-Muscle-Strips-for-Intestinal-Tissue-Engineering-pone.0114850.s002.ogv 6.9 s, 289 × 226; 3.13 MB
  
• Smooth-Muscle-Strips-for-Intestinal-Tissue-Engineering-pone.0114850.s003.ogv 6.7 s, 289 × 226; 2.92 MB
  
• Smooth-Muscle-Strips-for-Intestinal-Tissue-Engineering-pone.0114850.s004.ogv 6.0 s, 289 × 226; 1.43 MB
  
• Smooth-Muscle-Strips-for-Intestinal-Tissue-Engineering-pone.0114850.s005.ogv 5.7 s, 289 × 226; 1.95 MB
  
• Snoek-effekt.ogv 13 s, 640 × 720; 1.28 MB
  
• Soft-Modular-Robotic-Cubes-Toward-Replicating-Morphogenetic-Movements-of-the-Embryo-pone.0169179.s014.ogv 2 min 41 s, 1,920 × 1,080; 81.25 MB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s008.ogv 30 s, 512 × 512; 10.4 MB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s009.ogv 30 s, 512 × 512; 857 KB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s010.ogv 30 s, 512 × 512; 10.84 MB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s011.ogv 30 s, 182 × 1,448; 3.55 MB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s012.ogv 30 s, 512 × 512; 10.66 MB
  
• Spatial-Organization-of-Mesenchymal-Stem-Cells-In-Vitro—Results-from-a-New-Individual-Cell-Based-pone.0021960.s013.ogv 30 s, 512 × 512; 1.56 MB
  
• Spatio-Temporal-Simulation-of-First-Pass-Drug-Perfusion-in-the-Liver-pcbi.1003499.s003.ogv 32 s, 800 × 600; 2.01 MB
  
• Spatio-Temporal-Simulation-of-First-Pass-Drug-Perfusion-in-the-Liver-pcbi.1003499.s004.ogv 14 s, 800 × 600; 12 MB
  
• Spatio-Temporal-Simulation-of-First-Pass-Drug-Perfusion-in-the-Liver-pcbi.1003499.s005.ogv 35 s, 800 × 600; 13.6 MB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s009.ogv 31 s, 600 × 600; 538 KB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s010.ogv 31 s, 600 × 600; 1.82 MB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s011.ogv 15 s, 600 × 600; 70 KB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s012.ogv 31 s, 600 × 600; 277 KB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s013.ogv 31 s, 600 × 600; 846 KB
  
• Structure-Guided-Mutations-in-the-Terminal-Organelle-Protein-MG491-Cause-Major-Motility-and-ppat.1005533.s014.ogv 31 s, 600 × 600; 140 KB
  
• Sub-Diffraction-Nano-Manipulation-Using-STED-AFM-pone.0066608.s001.ogv 8.0 s, 256 × 256; 270 KB
  
• Substrate-Adhesion-Regulates-Sealing-Zone-Architecture-and-Dynamics-in-Cultured-Osteoclasts-pone.0028583.s003.ogv 17 s, 320 × 240; 288 KB
  
• Surface-Microstructures-on-Planar-Substrates-and-Textile-Fibers-Guide-Neurite-Outgrowth-A-Scaffold-pone.0050714.s002.ogv 13 s, 720 × 576; 255 KB
  
• Surface-Microstructures-on-Planar-Substrates-and-Textile-Fibers-Guide-Neurite-Outgrowth-A-Scaffold-pone.0050714.s003.ogv 13 s, 720 × 576; 910 KB
  
• Synthetic-Protocells-Interact-with-Viral-Nanomachinery-and-Inactivate-Pathogenic-Human-Virus-pone.0016874.s002.ogv 37 s, 320 × 320; 94 KB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s008.ogv 5.2 s, 672 × 512; 3.18 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s009.ogv 2.0 s, 1,147 × 1,024; 2.8 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s010.ogv 2.9 s, 672 × 512; 2.73 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s011.ogv 8.9 s, 672 × 512; 5.33 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s012.ogv 7.3 s, 672 × 512; 6.19 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s013.ogv 14 s, 672 × 512; 12.7 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s014.ogv 4.8 s, 672 × 512; 3.6 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s015.ogv 11 s, 672 × 512; 8.27 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s016.ogv 2.9 s, 1,160 × 880; 6.98 MB
  
• Tension-Free-Space-and-Cell-Damage-in-a-Microfluidic-Wound-Healing-Assay-pone.0024283.s017.ogv 9.8 s, 672 × 512; 7.86 MB
  
• The-ESX-5-System-of-Pathogenic-Mycobacteria-Is-Involved-In-Capsule-Integrity-and-Virulence-through-ppat.1005696.s010.ogv 14 s, 1,600 × 1,200; 1.79 MB
  
• The-Influence-of-Electric-Field-and-Confinement-on-Cell-Motility-pone.0059447.s007.ogv 3.7 s, 720 × 576; 421 KB
  
• The-Influence-of-Electric-Field-and-Confinement-on-Cell-Motility-pone.0059447.s008.ogv 3.7 s, 770 × 576; 363 KB
  
• The-Influence-of-Electric-Field-and-Confinement-on-Cell-Motility-pone.0059447.s009.ogv 3.7 s, 720 × 576; 193 KB
  
• The-Influence-of-Electric-Field-and-Confinement-on-Cell-Motility-pone.0059447.s010.ogv 3.6 s, 720 × 576; 345 KB
  
• The-Mechanical-Behavior-of-Mutant-K14-R125P-Keratin-Bundles-and-Networks-in-NEB-1-Keratinocytes-pone.0031320.s001.ogv 9.0 s, 600 × 460; 680 KB
  
• The-Murine-Coronavirus-Hemagglutinin-esterase-Receptor-binding-Site-A-Major-Shift-in-Ligand-ppat.1002492.s005.ogv 34 s, 640 × 480; 1.62 MB
  
• The-Role-of-Membrane-Fluidization-in-the-Gel-Assisted-Formation-of-Giant-Polymersomes-pone.0158729.s013.ogv 4.8 s, 677 × 677; 839 KB
  
• The-Role-of-Membrane-Fluidization-in-the-Gel-Assisted-Formation-of-Giant-Polymersomes-pone.0158729.s014.ogv 17 s, 721 × 721; 1.37 MB
  
• Three-Dimensional-Analysis-of-Cell-Division-Orientation-in-Epidermal-Basal-Layer-Using-Intravital-pone.0163199.s007.ogv 5.7 s, 412 × 164; 1,021 KB
  
• Three-Dimensional-Analysis-of-Cell-Division-Orientation-in-Epidermal-Basal-Layer-Using-Intravital-pone.0163199.s008.ogv 5.7 s, 252 × 316; 333 KB
  
• Three-Dimensional-Analysis-of-Cell-Division-Orientation-in-Epidermal-Basal-Layer-Using-Intravital-pone.0163199.s009.ogv 1.5 s, 288 × 360; 192 KB
  
• Three-Dimensional-Analysis-of-Cell-Division-Orientation-in-Epidermal-Basal-Layer-Using-Intravital-pone.0163199.s010.ogv 1.5 s, 288 × 360; 101 KB
  
• Transient-Mild-Hyperthermia-Induces-E-selectin-Mediated-Localization-of-Mesoporous-Silicon-Vectors-pone.0086489.s006.ogv 3.0 s, 1,440 × 640; 1.24 MB
  
• Transient-Mild-Hyperthermia-Induces-E-selectin-Mediated-Localization-of-Mesoporous-Silicon-Vectors-pone.0086489.s007.ogv 0.5 s, 784 × 784; 84 KB
  
• Transient-Mild-Hyperthermia-Induces-E-selectin-Mediated-Localization-of-Mesoporous-Silicon-Vectors-pone.0086489.s008.ogv 39 s, 512 × 512; 6.58 MB
  
• Transient-Mild-Hyperthermia-Induces-E-selectin-Mediated-Localization-of-Mesoporous-Silicon-Vectors-pone.0086489.s009.ogv 5.8 s, 464 × 496; 2.61 MB
  
• Transient-Mild-Hyperthermia-Induces-E-selectin-Mediated-Localization-of-Mesoporous-Silicon-Vectors-pone.0086489.s010.ogv 2.0 s, 948 × 948; 1.37 MB
  
• Transport-of-Particles-in-Intestinal-Mucus-under-Simulated-Infant-and-Adult-Physiological-pone.0095274.s002.ogv 20 s, 320 × 240; 56 KB
  
• Transport-of-Particles-in-Intestinal-Mucus-under-Simulated-Infant-and-Adult-Physiological-pone.0095274.s003.ogv 20 s, 320 × 240; 119 KB
  
• Unique-Structural-Features-Facilitate-Lizard-Tail-Autotomy-pone.0051803.s003.ogv 23 s, 873 × 773; 5.19 MB
  
• Unique-Structural-Features-Facilitate-Lizard-Tail-Autotomy-pone.0051803.s004.ogv 9.1 s, 877 × 773; 5.29 MB
  
• Unique-Structural-Features-Facilitate-Lizard-Tail-Autotomy-pone.0051803.s005.ogv 25 s, 768 × 768; 18.84 MB