Category:Embryonic development

Subcategories

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

Media in category "Embryonic development"

The following 200 files are in this category, out of 352 total.

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  1-day-old newt egg.jpg 603 × 396; 86 KB
  
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  10-day-old newt eg.jpg 839 × 547; 40 KB
  
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  12-day-old newt egg.jpg 983 × 716; 50 KB
  
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  14-day-old newt egg.jpg 800 × 534; 40 KB
  
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  15-day-old newt egg.jpg 800 × 441; 13 KB
  
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  2-day-old newt egg.jpg 800 × 575; 34 KB
  
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  20-day-old newt larva.jpg 800 × 587; 41 KB
  
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  2904 Preembryonic Development-02.jpg 1,957 × 1,792; 1.12 MB
  
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  2905 Implantation.jpg 1,950 × 2,440; 1.04 MB
  
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  2907 Embroyonic Disc, Amniotic Cavity, Yolk Sac-02-NLtxt.jpg 1,503 × 1,055; 689 KB
  
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  2907 Embroyonic Disc, Amniotic Cavity, Yolk Sac-02.jpg 1,529 × 1,055; 551 KB
  
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  2908 Germ Layers-02-nltxt.jpg 1,854 × 1,658; 1.45 MB
  
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  2908 Germ Layers-02.jpg 1,781 × 1,590; 1.06 MB
  
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  2909 Embryo Week 3-02 NLtxt.jpg 1,446 × 1,276; 855 KB
  
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  2909 Embryo Week 3-02.jpg 1,447 × 1,252; 634 KB
  
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  2913 Embryonic Folding.jpg 1,894 × 1,735; 831 KB
  
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  3-day-old newt egg.jpg 800 × 523; 32 KB
  
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  3311.fig.1.jpg 1,170 × 612; 218 KB
  
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  5-day-old newt egg.jpg 731 × 532; 35 KB
  
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  6-day-old newt egg.jpg 800 × 619; 41 KB
  
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  8-day-old newt egg.jpg 800 × 571; 34 KB
  
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  A conserved developmental mode emerges upon removal of species-specific extraembryonic environments.jpg 1,500 × 815; 216 KB
  
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  A generalized embryo demonstrating the three functional types of cranial nerves.png 1,204 × 904; 521 KB
  
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  A human embryo of 2 mm. in median sagittal section.jpg 838 × 1,006; 310 KB
  
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  A putative model of how the organizer induces germ layer specification and patterning.png 3,666 × 2,059; 911 KB
  
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  A stereogram of the trunk region of a vertebrate embryo, based upon Elasmobranchii embryos.jpg 1,183 × 788; 1.14 MB
  
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  A, Transverse section through the yolk-sac and stalk of a 5 mm. pig embryo showing attachment of amnion. B, Diagram of the fetal membranes and allantoic placenta of a pig embryo in median.jpg 1,117 × 1,573; 818 KB
  
• A-Broad-Requirement-for-TLS-Polymerases-η-and-κ-and-Interacting-Sumoylation-and-Nuclear-Pore-pgen.1002800.s010.ogv 34 s, 407 × 473; 2.51 MB
  
• A-Broad-Requirement-for-TLS-Polymerases-η-and-κ-and-Interacting-Sumoylation-and-Nuclear-Pore-pgen.1002800.s011.ogv 17 s, 400 × 514; 1,017 KB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s001.ogv 7.3 s, 900 × 470; 1.97 MB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s002.ogv 3.7 s, 432 × 208; 74 KB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s003.ogv 2.8 s, 432 × 208; 44 KB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s004.ogv 10 s, 658 × 517; 3.91 MB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s005.ogv 8.5 s, 600 × 300; 7.4 MB
  
• A-Novel-Role-for-MAPKAPK2-in-Morphogenesis-during-Zebrafish-Development-pgen.1000413.s006.ogv 19 s, 400 × 300; 135 KB
  
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  Abatus cordatus Developmental stages.jpg 1,311 × 1,679; 1.1 MB
  
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  Absence of the portal system in a first trimester human.jpg 3,048 × 1,840; 2.58 MB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s004.ogv 5.6 s, 640 × 208; 21 KB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s005.ogv 2.2 s, 350 × 210; 14 KB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s006.ogv 7.2 s, 350 × 210; 17 KB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s007.ogv 7.6 s, 640 × 202; 50 KB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s008.ogv 0.7 s, 640 × 208; 17 KB
  
• Acute-Drug-Treatment-in-the-Early-C.-elegans-Embryo-pone.0024656.s009.ogv 1.2 s, 640 × 208; 17 KB
  
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  Agenesis of ductus venosus human.jpg 3,240 × 1,000; 2.1 MB
  
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  AMEs extended from the grafted st. 4 node or isolated st. 5 AME elicits the gathering of surrounding epiblast cells, which develop into secondary brain tissues.jpg 1,170 × 878; 951 KB
  
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  Amniota The embryonic origins of the jaw are highly conserved across amniotes despite species-specific differences in form and function.jpg 1,638 × 1,831; 1.31 MB
  
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  An anterior to posterior gradient of proliferation counteracts ingression in the anterior primitive streak (PS) epiblast chicken embryo.jpg 1,268 × 1,637; 353 KB
  
• An-analysis-of-segmentation-dynamics-throughout-embryogenesis-in-the-centipede-Strigamia-maritima-1741-7007-11-112-S1.ogv 12 s, 511 × 511; 283 KB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s10.ogv 23 s, 319 × 277; 1,014 KB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s11.ogv 19 s, 952 × 404; 805 KB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s12.ogv 11 s, 1,211 × 895; 1.83 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s13.ogv 5.5 s, 1,224 × 649; 1.17 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s2.ogv 3.6 s, 394 × 360; 1.78 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s3.ogv 42 s, 756 × 900; 4.82 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s4.ogv 17 s, 871 × 992; 7.5 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s5.ogv 29 s, 1,344 × 1,024; 51.2 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s6.ogv 1 min 2 s, 658 × 524; 31.81 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s7.ogv 40 s, 2,100 × 1,361; 12.4 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s8.ogv 14 s, 1,406 × 608; 5.38 MB
  
• An-automated-microfluidic-platform-for-C.-elegans-embryo-arraying-phenotypingand-long-term-live-srep10192-s9.ogv 11 s, 375 × 319; 685 KB
  
• An-ensemble-averaged-cell-density-based-digital-model-of-zebrafish-embryo-development-derived-from-srep08601-s2.ogv 59 s, 966 × 1,088; 43.13 MB
  
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  Anatomic and histopathological aspects of FT organs human.jpg 3,948 × 1,292; 4.99 MB
  
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  Anatomical dispositions of the viscera in the different types of “situs” (radiological convention).png 3,684 × 2,681; 1.3 MB
  
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  Apical-apical epithelial apposition, orofacial clefting, and apoptosis.jpg 1,772 × 1,208; 1.09 MB
  
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  Arquénteron.jpg 1,066 × 1,061; 73 KB
  
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  Assessment of potential FGF and-or BMP dependencies of neural crest streams emerging segmentally from the rhombomeres 4, 6, and 7. 9–14 somite mouse embryos, cultured for 24 h.jpg 940 × 1,957; 797 KB
  
• Automated-Microinjection-of-Recombinant-BCL-X-into-Mouse-Zygotes-Enhances-Embryo-Development-pone.0021687.s007.ogv 49 s, 640 × 480; 2.66 MB
  
• Automated-Microinjection-of-Recombinant-BCL-X-into-Mouse-Zygotes-Enhances-Embryo-Development-pone.0021687.s008.ogv 59 s, 640 × 480; 3.1 MB
  
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  Aves Diagram of a chick embryo of the fifth day showing amnion, chorion and allantois.jpg 997 × 790; 497 KB
  
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  Bilaminar-embryonic-disc-at-14-days-in-the-implantation-site-in-endometrium.png 850 × 592; 696 KB
  
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  Blastocyt hatch from the zona pellucida and then transition to large spherical, tubular and filamentous conseptuses.png 1,302 × 904; 806 KB
  
• Bmp-and-Nodal-Independently-Regulate-lefty1-Expression-to-Maintain-Unilateral-Nodal-Activity-during-pgen.1002289.s008.ogv 17 s, 616 × 400; 3.59 MB
  
• Bmp-and-Nodal-Independently-Regulate-lefty1-Expression-to-Maintain-Unilateral-Nodal-Activity-during-pgen.1002289.s009.ogv 17 s, 616 × 400; 3.11 MB
  
• Bmp-and-Nodal-Independently-Regulate-lefty1-Expression-to-Maintain-Unilateral-Nodal-Activity-during-pgen.1002289.s010.ogv 17 s, 640 × 480; 2.27 MB
  
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  Bulk cell density and WntTGFbeta signalling regulate mesendodermal patterning of human pluripotent stem cells Decisive factors in PS patterning.jpg 1,453 × 811; 349 KB
  
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  Canal of nuck svg hariadhi.svg 512 × 512; 28 KB
  
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  Cell contacts and pericellular matrix in the Xenopus gastrula chordamesoderm Abundance of cell contacts but not relative adhesiveness is reduced in adhesion factor morphants.PNG 1,685 × 2,100; 2.68 MB
  
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  Cell contacts and pericellular matrix in the Xenopus gastrula chordamesoderm LSM in FN, Has1 and Syn-4 depleted CM.PNG 1,338 × 2,011; 2.32 MB
  
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  Cell contacts and pericellular matrix in the Xenopus gastrula chordamesoderm LSM in gaps..PNG 1,342 × 1,857; 876 KB
  
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  Cell contacts and pericellular matrix in the Xenopus gastrula chordamesoderm LSM in normal and C-cad depleted CM..PNG 1,656 × 1,947; 2.9 MB
  
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  Cell signalling events that mediate the switch between self-renewal and differentiation in mouse embryonic stem cells.png 1,198 × 873; 257 KB
  
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  Cells of the SOX2T-positive territory of the anterior primitive streak epiblast contribute to the neural tube and paraxial mesoderm tissues during axis formation chicken embryo.jpg 1,803 × 2,306; 855 KB
  
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  Cent uw ściana z embriogenezą.jpg 4,112 × 3,024; 4.66 MB
  
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  Changes during neurulation of the anterior neural section.png 3,147 × 1,864; 935 KB
  
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  Characterization of MZfz7ab mutants at the embryo and tissue level.jpg 2,199 × 2,662; 667 KB
  
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  Characterization of the SOX2T-positive territory of the epiblast in chicken embryo.jpg 2,113 × 1,581; 1.21 MB
  
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  Cleavage process; egg cytoplasm is homogenous. Aphidoletes aphidimyza.png 1,513 × 1,022; 1.33 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s001.ogv 25 s, 1,024 × 768; 23.14 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s002.ogv 12 s, 1,024 × 768; 14.4 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s003.ogv 8.2 s, 680 × 512; 7.95 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s004.ogv 0.0 s, 512 × 340; 13.15 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s005.ogv 8.1 s, 1,024 × 768; 43.09 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s006.ogv 8.0 s, 1,384 × 1,040; 48.61 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s007.ogv 15 s, 1,024 × 768; 53.72 MB
  
• Collective-Motion-of-Cells-Mediates-Segregation-and-Pattern-Formation-in-Co-Cultures-pone.0031711.s008.ogv 11 s, 1,024 × 768; 58.71 MB
  
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  Columnar trophoblast-cells from the base of a fcetal villus of the placenta of the cow at the third month of pregnancy, to show phagocytosis.jpg 868 × 830; 208 KB
  
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  Coordination of Cell Polarity during Xenopus Gastrulation A heterogeneous combination of tissues can confer planar cell polarity..png 2,916 × 4,607; 4.35 MB
  
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  Coordination of Cell Polarity during Xenopus Gastrulation EB3 shows polarized movement independent of cell morphology in the early phases..png 3,487 × 4,215; 6.24 MB
  
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  Coordination of Cell Polarity during Xenopus Gastrulation Notochord-somite boundary andor extra-notochord tissue attracts EB3 movement..png 2,989 × 2,442; 4.15 MB
  
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  Cortical neurogenesis in the mouse embryo.png 1,143 × 815; 530 KB
  
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  CpG methylation in mouse development.png 1,660 × 807; 188 KB
  
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  Cross-sectional views of the developing embryo demonstrating the stomodeum and the pharynx.png 647 × 927; 315 KB
  
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  Crown-cells-sense-nodal-flow-through-Pkd2-a-Pkd2-expression-throughout-the-node-pit.jpg 1,251 × 1,259; 523 KB
  
• Cultured ppl explant from MZfz7ab;Tg(gscGFP-CAAX) mutant embryos expressing membrane-RFP and Opto-Fz7 and injected with 9-cis-retinal.ogv 12 s, 986 × 720; 990 KB
  
• De Novo Formation of Left–Right Asymmetry by Posterior Tilt of Nodal Cilia.ogv 13 s, 320 × 240; 2.05 MB
  
• Detection-of-Dynamic-Spatiotemporal-Response-to-Periodic-Chemical-Stimulation-in-a-Xenopus-pone.0014624.s009.ogv 5.3 s, 340 × 308; 114 KB
  
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  Developing placenta.jpg 678 × 334; 81 KB
  
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  Development of the amnion and allantois.jpg 676 × 902; 1.05 MB
  
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  Development of the biliary tree and morphology of PBGs in human and mouse.jpeg 1,761 × 1,894; 575 KB
  
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  Developmental outcome of the node graft labeled with mCherry depended on the graft sites. (A) Development of the node grafts from mCherry-expressing st. 4 Japanese quail embryos.jpg 1,336 × 962; 808 KB
  
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  Diagrams and images of human embryos at the gastrula stage.png 3,128 × 3,193; 804 KB
  
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  Diagrams showing the development of the amnion, chorion and allantois.jpg 1,269 × 1,151; 605 KB
  
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  Die Gartenlaube (1878) b 528.jpg 1,244 × 2,143; 802 KB
  
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  Different degrees of EMT correlate with different tissue morphologies a.jpg 968 × 1,292; 576 KB
  
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  Diversity of vertebrate gastrulation.jpg 1,073 × 1,021; 415 KB
  
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  Dose-dependent reshaping of primitive streak.jpg 968 × 1,236; 743 KB
  
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  Downregulation of neuromesodermal progenitors’ (NMPs) epithelial phenotype during development chicken embryo.jpg 2,079 × 2,253; 918 KB
  
• Drosophila cleavage and gastrulation.webm 30 s, 1,920 × 800; 42.28 MB
  
• Dynamics of mesodermal cell ingression chicken embryo.ogv 12 s, 226 × 720; 4.2 MB
  
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  Early craniofacial patterning and development.jpg 1,772 × 1,298; 1.18 MB
  
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  Early development stages with names.gif 311 × 360; 3.2 MB
  
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  Early gastrulation in amphibian embryos.png 3,570 × 1,358; 1,007 KB
  
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  Early hormonal interaction after implantation.jpg 1,663 × 1,189; 125 KB
  
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  Early pre- and post-implantation mouse embryonic development until the egg cylinder stage.png 1,089 × 1,228; 613 KB
  
• Echinoderm development.webm 3 min 3 s, 640 × 480; 38.31 MB
  
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  Echinoderm embryo undergoing second cleavage.jpg 1,740 × 1,700; 532 KB
  
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  Embryo 2 (PSF).png 3,551 × 2,027; 319 KB
  
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  Embryogenesis in vertebrates.jpg 1,070 × 715; 879 KB
  
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  Embryogenesis-es2.svg 512 × 384; 324 KB
  
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  Embryogenesis.jpg 2,424 × 2,859; 3.27 MB
  
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  Embryogenesis1.jpg 1,220 × 1,430; 359 KB
  
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  Embryological development of the human venous system.png 2,980 × 1,672; 1.37 MB
  
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  Embryonic and pelagic stages of select neuston.jpg 1,498 × 1,015; 354 KB
  
• Embryonic development of a salamander, filmed in the 1920s.ogv 14 min 52 s, 400 × 300; 59.31 MB
  
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  EmbyronicDevelopmentMicroarray.png 1,328 × 614; 102 KB
  
• Endothelial-Rictor-is-crucial-for-midgestational-development-and-sustained-andextensive-FGF2-srep17705-s1.ogv 11 s, 854 × 480; 4.35 MB
  
• Endothelial-Rictor-is-crucial-for-midgestational-development-and-sustained-andextensive-FGF2-srep17705-s2.ogv 11 s, 854 × 480; 8.31 MB
  
• Endothelial-Rictor-is-crucial-for-midgestational-development-and-sustained-andextensive-FGF2-srep17705-s3.ogv 17 s, 854 × 480; 8.6 MB
  
• Endothelial-Rictor-is-crucial-for-midgestational-development-and-sustained-andextensive-FGF2-srep17705-s4.ogv 15 s, 854 × 480; 5.07 MB
  
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  Ernst Heinrich Philipp August Haeckel.- Anthropogenie, baby, placenta (cropped).png 317 × 298; 58 KB
  
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  Ernst Heinrich Philipp August Haeckel.- Anthropogenie, baby, placenta.png 447 × 520; 168 KB
  
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  Experimental manipulation of the gastrulation mode in different organisms.jpg 1,166 × 1,480; 850 KB
  
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  Expression of neuromesodermal progenitor (NMP) signature genes in chicken and mouse embryos.jpg 1,518 × 3,202; 721 KB
  
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  Expression patterns of foxc1a, tbx1 and tbx20 genes resolve into three longitudinal strips in zebrafish head mesoderm (3ss, 11hpf).jpg 1,602 × 799; 843 KB
  
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  Expression patterns of L. fluviatilis NogginA (a–j), NogginC (k–r) and NogginD (s–v).jpg 1,495 × 2,037; 1.69 MB
  
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  Expression patterns of wnt3 (a–d), pkdcc (e–h), eomes (i–l) and tbx6 (m–p) in en face views at stages 0 (a, e, i, m), 1 (b, f, j, n), 2 (c, g, k, o) and 3 (d, h, l, p) in rabbit embryo.tif 2,055 × 2,033; 7.88 MB
  
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  Extra-embryonic membranes of the chic (01).jpg 641 × 783; 558 KB
  
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  Extra-embryonic membranes of the chick.jpg 897 × 455; 438 KB
  
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  Fate of germ layers of the embryo.png 500 × 433; 183 KB
  
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  Fertilization.jpg 1,920 × 1,080; 1.35 MB
  
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  Fetal hepatic vasculature.jpeg 1,761 × 2,072; 556 KB
  
• Flow Generated by the Mechanical Model cilia primitive node.ogv 9.9 s, 320 × 240; 77 KB
  
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  Flow Generation Mechanism of cilia primitve node.png 2,020 × 1,451; 238 KB
  
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  Formation and patterning of the mouse neural tube.png 1,305 × 1,505; 636 KB
  
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  Formation of notochord by primitive streak.jpg 1,091 × 1,071; 167 KB
  
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  Formation of the primitive body plan following gastrulation in the mouse.png 1,279 × 1,187; 1,016 KB
  
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  Four diagrams showing hypothetical stages of early human embryos.jpg 1,631 × 1,434; 943 KB
  
• Functional-anterior-pituitary-generated-in-self-organizing-culture-of-human-embryonic-stem-cells-ncomms10351-s2.ogv 26 s, 960 × 540; 1.45 MB
  
• Functional-anterior-pituitary-generated-in-self-organizing-culture-of-human-embryonic-stem-cells-ncomms10351-s3.ogv 22 s, 960 × 540; 5.02 MB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s008.ogv 20 s, 320 × 240; 586 KB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s009.ogv 20 s, 320 × 240; 541 KB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s010.ogv 20 s, 240 × 300; 727 KB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s011.ogv 5.1 s, 528 × 528; 133 KB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s012.ogv 5.1 s, 528 × 528; 193 KB
  
• Functional-Dissection-of-Caenorhabditis-elegans-CLK-2TEL2-Cell-Cycle-Defects-during-Embryogenesis-pgen.1000451.s013.ogv 8.7 s, 528 × 528; 186 KB
  
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  Gastrulation forms in vertebrates.jpeg 1,280 × 1,173; 88 KB
  
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  Gastrulation gives rise to the three primary germ layers of the mouse embryo proper..png 1,209 × 806; 202 KB
  
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  Gastrulation stomodeal invagination, dorsal folds form; elongation of germ band; clear parasegmentation. Aphidoletes aphidimyza.png 850 × 592; 591 KB
  
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  Gray32.png 500 × 417; 53 KB
  
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  Hans Spemann.jpg 849 × 1,371; 500 KB
  
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  Head involution. Aphidoletes aphidimyza.png 850 × 584; 597 KB
  
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  Hematopoietic stem cell niche in fetal liver versus bone marrow.jpg 5,413 × 3,917; 1.21 MB
  
• High-resolution-ultrasound-guided-microinjection-for-interventional-studies-of-early-embryonic-and-1471-213X-6-10-S1.ogv 5.1 s, 608 × 744; 4.51 MB
  
• High-resolution-ultrasound-guided-microinjection-for-interventional-studies-of-early-embryonic-and-1471-213X-6-10-S2.ogv 2.9 s, 608 × 744; 4.23 MB
  
• High-resolution-ultrasound-guided-microinjection-for-interventional-studies-of-early-embryonic-and-1471-213X-6-10-S3.ogv 4.5 s, 608 × 744; 6.52 MB
  
• High-resolution-ultrasound-guided-microinjection-for-interventional-studies-of-early-embryonic-and-1471-213X-6-10-S4.ogv 5.6 s, 608 × 744; 8.13 MB
  
• High-resolution-ultrasound-guided-microinjection-for-interventional-studies-of-early-embryonic-and-1471-213X-6-10-S5.ogv 6.1 s, 608 × 744; 9.08 MB
  
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  Hipófisis embrionária e14,5.png 879 × 657; 709 KB
  
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  Histological appearance of the FT liver with normal PVS human.jpg 1,978 × 1,078; 2.72 MB
  
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  Histopathological and ultrasound aspect of normal FT liver human.jpg 4,016 × 1,092; 1.95 MB
  
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  Histotroph includes molecules secreted or transported into the uterine lumen to stimulate growth and development of the conceptus.png 618 × 587; 407 KB
  
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  How the Turtle Gets its Shell-ar.svg 2,264 × 1,673; 54 KB
  
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  How the Turtle Gets its Shell.svg 2,122 × 1,568; 54 KB
  
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  Human embryo Recent findings about tissue-specific lymphatic progenitor cells..jpg 1,380 × 912; 289 KB
  
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  Human embryo Section of embryonic rudiment in Peters' ovum (first week).jpg 1,141 × 857; 540 KB
  
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  Human embryo The molecular pathways involved in LEC differentiation from embryonic progenitors..jpg 2,211 × 1,888; 1.31 MB
  
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  Human embryo The molecular pathways responsible for LEC differentiation during adulthood stage.jpg 2,186 × 1,863; 1.2 MB
  
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  Human embryo. The origin of lymphatic progenitor cells and physiological lymphagiogenesis process at E12.5.png 3,258 × 1,593; 1.25 MB
  
• Identification-and-Functional-Characterization-of-Cardiac-Pacemaker-Cells-in-Zebrafish-pone.0047644.s006.ogv 2.6 s, 475 × 400; 6.13 MB
  
• Identification-and-Functional-Characterization-of-Cardiac-Pacemaker-Cells-in-Zebrafish-pone.0047644.s007.ogv 2.6 s, 475 × 400; 6.25 MB
  
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  Illustration (Conception to Birth) from Ornament to the Mind of Medicine Buddha- Blue Beryl Lamp Illuminating Four Tantras written around the year 1720 by Desi Sangye Gyatso (1653–1705), the regent (Desi) of the 5th Dalai Lama.png 1,245 × 1,500; 2.94 MB
  
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  Impact of FGFR and BMPR inhibition on epibranchial placode morphogenesis and neurogenesis in 9–14 somite mouse embryos, cultured for 24 h.jpg 1,749 × 2,246; 1.83 MB
  
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  Impact of FGFR or BMPR inhibition on the development of pharyngeal pouches (p1–p4) in 9–14 somite mouse embryos, cultured for 24 h.jpg 1,750 × 1,396; 1.71 MB
  
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  Implanting embryo.jpg 1,497 × 2,381; 215 KB
  
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  Internal and external view of the developing head and neck at week 4. (A) Ventral view depicting the early heart.png 891 × 931; 263 KB
  
• Invasiveness-of-mouse-embryos-to-human-ovarian-cancer-cells-HO8910PM-and-the-role-of-MMP-9-1475-2867-12-23-S1.ogv 1 min 24 s, 375 × 288; 22.21 MB
  
• Laser-surgery-of-zebrafish-(Danio-rerio)-embryos-using-femtosecond-laser-pulses-Optimal-parameters-1472-6750-8-7-S1.ogv 56 s, 320 × 240; 2.14 MB
  
• Laser-surgery-of-zebrafish-(Danio-rerio)-embryos-using-femtosecond-laser-pulses-Optimal-parameters-1472-6750-8-7-S2.ogv 15 s, 480 × 360; 319 KB
  
• Late embryonic development in Caenorhabditis elegans - pbio.1001115.s012.ogv 6.3 s, 516 × 486; 1.19 MB
  
• Latrunculin A affects actin cytoskeleton in the whole embryonic disc (01).ogv 5.8 s, 694 × 520; 2.23 MB