Category:Media from Scientific Reports

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Subcategories

This category has the following 12 subcategories, out of 12 total.

A

An early Devonian flora from the Baviaanskloof Formation (Table Mountain Group) of South Africa (9 F)

E

Evidence of diet, deification, and death within ancient Egyptian mummified animals (1 F)

I

Images from Scientific Reports (3 C, 122 F)

J

K

Media from Korshunova et al. 2019 - 10.1038/s41598-019-42297-5 (9 F)

L

M

Media from Lanzoni et al. 2019 - 10.1038/s41598-018-37629-w (3 F)

O

Old African fossils provide new evidence for the origin of the American crocodiles (2 F)

S

Media from Sigl, Steibl and Laforsch 2016 - 10.1038/srep30834 (2 F)

T

Media from Tanabe et al. 2015 - 10.1038/srep10467 (2 F)

Media in category "Media from Scientific Reports"

The following 200 files are in this category, out of 6,386 total.

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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
1.0-T-open-configuration-magnetic-resonance-guided-microwave-ablation-of-pig-livers-in-real-time-srep13551-s2.ogv 59 s, 1,280 × 720; 56.53 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
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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
2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s5.ogv 6.4 s, 810 × 270; 854 KB
2D-map-projections-for-visualization-and-quantitative-analysis-of-3D-fluorescence-micrographs-srep12457-s6.ogv 9.6 s, 810 × 270; 2 MB
3D-Holographic-Observatory-for-Long-term-Monitoring-of-Complex-Behaviors-in-Drosophila-srep33001-s1.ogv 14 s, 2,048 × 1,024; 2.66 MB
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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
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3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s3.ogv 33 s, 478 × 480; 2.11 MB
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3D-Imaging-of-Water-Drop-Condensation-on-Hydrophobic-and-Hydrophilic-Lubricant-Impregnated-Surfaces-srep23687-s5.ogv 0.9 s, 480 × 480; 1.4 MB
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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
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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
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3D-microtumors-in-vitro-supported-by-perfused-vascular-networks-srep31589-s3.ogv 13 s, 852 × 488; 1.18 MB
3D-Printable-Graphene-Composite-srep11181-s2.ogv 56 s, 320 × 240; 2.45 MB
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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
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3D-Printing-of-Meso-structurally-Ordered-Carbon-FiberPolymer-Composites-with-Unprecedented-srep43401-s2.ogv 25 s, 704 × 480; 1.41 MB
3D-Representation-of-the-predicted-discontinuous-epitopes--A-to-C--of-Zika-E-protein--E-to-H--of-Zika-NS3-protein-and--I.jpg 787 × 1,038; 476 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
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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
41598 2019 56965 Fig1 HTML.webp 995 × 992; 99 KB
41598 2020 71387 Fig2 HTML.webp 2,011 × 1,916; 122 KB
4D-(x-y-z-t)-imaging-of-thick-biological-samples-by-means-of-Two-Photon-inverted-Selective-Plane-srep23923-s1.ogv 36 s, 618 × 748; 3.11 MB
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5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s2.ogv 16 s, 1,168 × 852; 3.79 MB
5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s3.ogv 39 s, 1,228 × 852; 5.54 MB
5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s4.ogv 23 s, 1,970 × 1,220; 17.75 MB
5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s5.ogv 15 s, 1,567 × 1,073; 6.04 MB
5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s6.ogv 11 s, 1,568 × 1,074; 2.09 MB
5D-imaging-via-light-sheet-microscopy-reveals-cell-dynamics-during-the-eye-antenna-disc-primordium-srep44945-s7.ogv 24 s, 852 × 920; 2.81 MB
A-2D-virtual-reality-system-for-visual-goal-driven-navigation-in-zebrafish-larvae-srep34015-s2.ogv 16 s, 960 × 540; 1.19 MB
A-2D-virtual-reality-system-for-visual-goal-driven-navigation-in-zebrafish-larvae-srep34015-s3.ogv 1 min 2 s, 960 × 540; 1,024 KB
A-2D-virtual-reality-system-for-visual-goal-driven-navigation-in-zebrafish-larvae-srep34015-s4.ogv 1 min 32 s, 960 × 540; 1.12 MB
A-3D-self-organizing-multicellular-epidermis-model-of-barrier-formation-and-hydration-with-srep43472-s2.ogv 28 s, 1,110 × 678; 28.46 MB
A-3D-self-organizing-multicellular-epidermis-model-of-barrier-formation-and-hydration-with-srep43472-s3.ogv 28 s, 1,110 × 678; 27.99 MB
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A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s1.ogv 30 s, 960 × 540; 5.84 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s2.ogv 30 s, 960 × 540; 6.19 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s3.ogv 30 s, 960 × 540; 3.85 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s4.ogv 30 s, 960 × 540; 3.82 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s5.ogv 30 s, 960 × 540; 5.07 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s6.ogv 30 s, 960 × 540; 5.35 MB
A-Balanced-Mixture-of-Antagonistic-Pressures-Promotes-the-Evolution-of-Parallel-Movement-srep39428-s7.ogv 30 s, 960 × 540; 3.68 MB
A-Bayesian-Perspective-on-Accumulation-in-the-Magnitude-System-41598 2017 680 MOESM2 ESM.ogv 20 s, 768 × 576; 61 KB
A-Bayesian-Perspective-on-Accumulation-in-the-Magnitude-System-41598 2017 680 MOESM3 ESM.ogv 20 s, 768 × 576; 59 KB
A-Bayesian-Perspective-on-Accumulation-in-the-Magnitude-System-41598 2017 680 MOESM4 ESM.ogv 16 s, 768 × 576; 55 KB
A-bizarre-theropod-from-the-Early-Cretaceous-of-Japan-highlighting-mosaic-evolution-among-srep20478-s2.ogv 30 s, 320 × 240; 273 KB
A-Branching-Process-to-Characterize-the-Dynamics-of-Stem-Cell-Differentiation-srep13265-s2.ogv 1 min 40 s, 364 × 720; 1.95 MB
A-Branching-Process-to-Characterize-the-Dynamics-of-Stem-Cell-Differentiation-srep13265-s3.ogv 1 min 32 s, 364 × 720; 1.88 MB
A-bulk-sub-femtoliter-in-vitro-compartmentalization-system-using-super-fine-electrosprays-srep26257-s2.ogv 13 s, 640 × 424; 703 KB
A-bulk-sub-femtoliter-in-vitro-compartmentalization-system-using-super-fine-electrosprays-srep26257-s3.ogv 9.2 s, 256 × 256; 62 KB
A-burrowing-frog-from-the-late-Paleocene-of-Mongolia-uncovers-a-deep-history-of-spadefoot-toads-srep19209-s3.ogv 33 s, 640 × 480; 5.8 MB
A-chimeolysin-with-extended-spectrum-streptococcal-host-range-found-by-an-induced-lysis-based-rapid-srep17257-s1.ogv 3.5 s, 211 × 235; 173 KB
A-chimeolysin-with-extended-spectrum-streptococcal-host-range-found-by-an-induced-lysis-based-rapid-srep17257-s2.ogv 3.5 s, 211 × 235; 159 KB
A-clinically-authentic-mouse-model-of-enterovirus-71-(EV-A71)-induced-neurogenic-pulmonary-oedema-srep28876-s2.ogv 12 s, 320 × 240; 627 KB
A-clinically-authentic-mouse-model-of-enterovirus-71-(EV-A71)-induced-neurogenic-pulmonary-oedema-srep28876-s3.ogv 10 s, 320 × 240; 958 KB
A-closer-look-into-the-α-helix-basin-srep38341-s4.ogv 12 s, 140 × 462; 3.42 MB
A-closer-look-into-the-α-helix-basin-srep38341-s5.ogv 15 s, 120 × 472; 1.67 MB
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A-combined-system-of-microbial-fuel-cell-and-intermittently-aerated-biological-filter-for-energy-srep18070-s2.ogv 50 s, 480 × 360; 1.76 MB
A-compact-light-sheet-microscope-for-the-study-of-the-mammalian-central-nervous-system-srep26317-s2.ogv 2 min 24 s, 2,048 × 512; 3.33 MB
A-Comparative-Analysis-of-Sonic-Defences-in-Bombycoidea-Caterpillars-srep31469-s1.ogv 1 min 31 s, 352 × 288; 4.25 MB
A-Comparative-Analysis-of-Sonic-Defences-in-Bombycoidea-Caterpillars-srep31469-s2.ogv 11 s, 960 × 540; 1.14 MB
A-critical-role-for-Piezo2-channels-in-the-mechanotransduction-of-mouse-proprioceptive-neurons-srep25923-s1.ogv 30 s, 380 × 136; 102 KB
A-critical-role-for-Piezo2-channels-in-the-mechanotransduction-of-mouse-proprioceptive-neurons-srep25923-s2.ogv 37 s, 358 × 398; 426 KB
A-critical-role-for-Piezo2-channels-in-the-mechanotransduction-of-mouse-proprioceptive-neurons-srep25923-s3.ogv 51 s, 304 × 226; 436 KB
A-critical-role-of-solute-carrier-22a14-in-sperm-motility-and-male-fertility-in-mice-srep36468-s2.ogv 9.2 s, 1,280 × 720; 1.69 MB
A-critical-role-of-solute-carrier-22a14-in-sperm-motility-and-male-fertility-in-mice-srep36468-s3.ogv 9.3 s, 1,280 × 720; 1.42 MB
A-crystal-clear-zebrafish-for-in-vivo-imaging-srep29490-s2.ogv 1 min 5 s, 435 × 435; 38.88 MB
A-crystal-clear-zebrafish-for-in-vivo-imaging-srep29490-s3.ogv 26 s, 1,200 × 768; 9.73 MB
A-crystal-clear-zebrafish-for-in-vivo-imaging-srep29490-s4.ogv 42 s, 512 × 512; 30.77 MB
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A-dinosaurian-facial-deformity-and-the-first-occurrence-of-ameloblastoma-in-the-fossil-record-srep29271-s3.ogv 17 s, 240 × 268; 766 KB
A-DNA-aptamer-recognising-a-malaria-protein-biomarker-can-function-as-part-of-a-DNA-origami-assembly-srep21266-s2.ogv 26 s, 506 × 506; 4.55 MB
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A-DNA-aptamer-recognising-a-malaria-protein-biomarker-can-function-as-part-of-a-DNA-origami-assembly-srep21266-s4.ogv 7.3 s, 506 × 506; 663 KB
A-DNA-aptamer-recognising-a-malaria-protein-biomarker-can-function-as-part-of-a-DNA-origami-assembly-srep21266-s5.ogv 17 s, 506 × 506; 315 KB
A-DNA-aptamer-recognising-a-malaria-protein-biomarker-can-function-as-part-of-a-DNA-origami-assembly-srep21266-s6.ogv 16 s, 506 × 506; 2.1 MB
A-DNA-aptamer-recognising-a-malaria-protein-biomarker-can-function-as-part-of-a-DNA-origami-assembly-srep21266-s7.ogv 34 s, 506 × 506; 2.15 MB
A-dynamic-interaction-process-between-KaiA-and-KaiC-is-critical-to-the-cyanobacterial-circadian-srep25129-s1.ogv 50 s, 320 × 240; 5.24 MB
A-dynamic-interaction-process-between-KaiA-and-KaiC-is-critical-to-the-cyanobacterial-circadian-srep25129-s2.ogv 1 min 16 s, 320 × 240; 9.96 MB
A-fast-3D-reconstruction-system-with-a-low-cost-camera-accessory-srep10909-s2.ogv 14 s, 640 × 480; 963 KB
A-fast-3D-reconstruction-system-with-a-low-cost-camera-accessory-srep10909-s3.ogv 12 s, 640 × 480; 434 KB
A-fast-and-effective-approach-for-reversible-wetting-dewetting-transitions-on-ZnO-nanowires-srep35073-s2.ogv 17 s, 932 × 634; 4.21 MB
A-fast-and-effective-approach-for-reversible-wetting-dewetting-transitions-on-ZnO-nanowires-srep35073-s3.ogv 3.0 s, 640 × 480; 85 KB
A-flexible-and-biocompatible-triboelectric-nanogenerator-with-tunable-internal-resistance-for-srep22233-s1.ogv 7.2 s, 540 × 480; 95 KB
A-flexible-proximity-sensor-formed-by-duplex-screenscreen-offset-printing-and-its-application-to-srep19947-s2.ogv 1 min 32 s, 640 × 480; 5.79 MB
A-fossil-biting-midge-(Diptera-Ceratopogonidae)-from-early-Eocene-Indian-amber-with-a-complex-srep34352-s2.ogv 1 min 0 s, 1,920 × 1,080; 45.53 MB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s2.ogv 13 s, 400 × 272; 479 KB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s3.ogv 13 s, 400 × 272; 549 KB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s4.ogv 13 s, 482 × 325; 1.03 MB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s5.ogv 13 s, 482 × 325; 1.04 MB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s6.ogv 20 s, 445 × 300; 1.01 MB
A-four-dimensional-snapshot-hyperspectral-video-endoscope-for-bio-imaging-applications-srep24044-s7.ogv 20 s, 445 × 300; 1.13 MB
A-fully-roll-to-roll-gravure-printed-carbon-nanotube-based-active-matrix-for-multi-touch-sensors-srep17707-s2.ogv 45 s, 720 × 480; 11.68 MB
A-Global-Approach-for-Quantitative-Super-Resolution-and-Electron-Microscopy-on-Cryo-and-Epoxy-41598 2017 33 MOESM2 ESM.ogv 14 s, 500 × 468; 3.48 MB
A-Global-Approach-for-Quantitative-Super-Resolution-and-Electron-Microscopy-on-Cryo-and-Epoxy-41598 2017 33 MOESM3 ESM.ogv 27 s, 500 × 500; 5.32 MB
A-Global-Approach-for-Quantitative-Super-Resolution-and-Electron-Microscopy-on-Cryo-and-Epoxy-41598 2017 33 MOESM4 ESM.ogv 14 s, 500 × 710; 6.51 MB
A-gonogenic-stimulated-transition-of-mouse-embryonic-stem-cells-with-enhanced-control-of-diverse-srep25104-s2.ogv 12 s, 240 × 240; 669 KB
A-Haptotaxis-Assay-for-Neutrophils-using-Optical-Patterning-and-a-High-content-Approach-41598 2017 2993 MOESM2 ESM.ogv 17 s, 1,912 × 956; 25.64 MB
A-Haptotaxis-Assay-for-Neutrophils-using-Optical-Patterning-and-a-High-content-Approach-41598 2017 2993 MOESM3 ESM.ogv 17 s, 930 × 930; 24.43 MB
A-Haptotaxis-Assay-for-Neutrophils-using-Optical-Patterning-and-a-High-content-Approach-41598 2017 2993 MOESM4 ESM.ogv 6.2 s, 905 × 301; 4.67 MB
A-Haptotaxis-Assay-for-Neutrophils-using-Optical-Patterning-and-a-High-content-Approach-41598 2017 2993 MOESM5 ESM.ogv 9.3 s, 1,000 × 1,000; 47.77 MB
A-hierarchical-view-on-material-formation-during-pulsed-laser-synthesis-of-nanoparticles-in-liquid-srep16313-s1.ogv 22 s, 432 × 248; 6.21 MB
A-high-throughput-microfluidic-approach-for-1000-fold-leukocyte-reduction-of-platelet-rich-plasma-srep35943-s2.ogv 1 min 49 s, 1,920 × 1,080; 55.13 MB
A-high-throughput-microfluidic-approach-for-1000-fold-leukocyte-reduction-of-platelet-rich-plasma-srep35943-s3.ogv 20 s, 1,920 × 1,080; 4.35 MB
A-high-throughput-microfluidic-approach-for-1000-fold-leukocyte-reduction-of-platelet-rich-plasma-srep35943-s4.ogv 20 s, 1,920 × 1,080; 5.23 MB
A-High-Throughput-Microfluidic-Platform-for-Mammalian-Cell-Transfection-and-Culturing-srep23937-s2.ogv 9.2 s, 1,024 × 1,024; 208 KB
A-High-Throughput-Microfluidic-Platform-for-Mammalian-Cell-Transfection-and-Culturing-srep23937-s3.ogv 9.2 s, 1,024 × 1,024; 80 KB
A-High-Throughput-Microfluidic-Platform-for-Mammalian-Cell-Transfection-and-Culturing-srep23937-s4.ogv 9.2 s, 1,024 × 1,024; 4.68 MB
A-High-Throughput-Multi-Cell-Phenotype-Assay-for-the-Identification-of-Novel-Inhibitors-of-srep22273-s2.ogv 30 s, 1,134 × 375; 5.62 MB
A-High-Throughput-Multi-Cell-Phenotype-Assay-for-the-Identification-of-Novel-Inhibitors-of-srep22273-s3.ogv 12 s, 640 × 1,500; 3.2 MB
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A-highly-sensitive-underwater-video-system-for-use-in-turbid-aquaculture-ponds-srep31810-s2.ogv 11 s, 704 × 480; 1.55 MB
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A-Long-Term-and-Slow-Releasing-Hydrogen-Sulfide-Donor-Protects-against-Myocardial-41598 2017 3941 MOESM2 ESM.ogv 35 s, 1,280 × 720; 4.78 MB
A-Macroscopic-Reaction-Direct-Covalent-Bond-Formation-between-Materials-Using-a-Suzuki-Miyaura-srep06348-s1.ogv 31 s, 640 × 480; 1.79 MB
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A-microfluidic-device-for-measuring-cell-migration-towards-substrate-bound-and-soluble-chemokine-srep36440-s2.ogv 30 s, 588 × 138; 3.03 MB
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A-microfluidic-device-to-study-neuronal-and-motor-responses-to-acute-chemical-stimuli-in-zebrafish-srep12196-s4.ogv 38 s, 768 × 576; 1.69 MB
A-Microstructured-Fiber-with-Defined-Borosilicate-Regions-to-Produce-a-Radial-Micronozzle-Array-for-srep21279-s2.ogv 28 s, 320 × 240; 361 KB
A-miniature-solar-device-for-overall-water-splitting-consisting-of-series-connected-spherical-srep24633-s2.ogv 44 s, 854 × 480; 4.24 MB
A-molecular-beacon-based-approach-for-live-cell-imaging-of-RNA-transcripts-with-minimal-target-41598 2017 1740 MOESM2 ESM.ogv 8.5 s, 206 × 204; 32 KB
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