Category:Epithelial-mesenchymal transitions

Subcategories

This category has only the following subcategory.

Media in category "Epithelial-mesenchymal transitions"

The following 92 files are in this category, out of 92 total.

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  3311.fig.1.jpg 1,170 × 612; 218 KB
  
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  A brief view of EMT and MET.jpg 2,763 × 1,419; 227 KB
  
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  A schematic view of the tumor microenvironment.png 768 × 388; 372 KB
  
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  An overview of epithelial–mesenchymal plasticity causes and consequences.png 2,790 × 2,059; 913 KB
  
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  Apical-apical epithelial apposition, orofacial clefting, and apoptosis.jpg 1,772 × 1,208; 1.09 MB
  
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  Biological role of FOXM1 in breast cancer tumorigenesis.png 5,300 × 3,100; 927 KB
  
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  Cancer metastasis and neural crest cell migration exhibit striking similarities.jpg 1,990 × 1,191; 428 KB
  
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  Cell lineages during Müllerian development and oviduct differentiation.jpg 2,300 × 2,423; 299 KB
  
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  Cell morphology and mechanics are vimentin dependent.jpg 1,612 × 1,150; 748 KB
  
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  Cellular adhesion on submicron topographies controls EMTMET.jpg 916 × 1,840; 891 KB
  
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  Cellular and molecular changes associated with epithelial-mesenchymal transition.png 3,000 × 1,688; 857 KB
  
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  Cell–cell interactions and external signals regulating collective cell migration of cephalic NC cells.jpg 1,654 × 1,158; 387 KB
  
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  Chemical structures of TET-oxidized products.jpg 839 × 590; 129 KB
  
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  Collective invasion and EMT in 3D matrix.jpg 1,601 × 2,476; 2.01 MB
  
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  Contact-Inhibition, chemotaxis and Co-Attraction cooperate to promote collective migration in Xenopus cephalic NC cells.jpg 1,305 × 1,564; 294 KB
  
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  Contribution of EMT to cancer progression.jpg 1,704 × 344; 425 KB
  
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  Crosstalk between metabolic and epigenetic regulation.jpg 2,693 × 1,277; 251 KB
  
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  Crosstalk between the tumor and its microenvironment, makes EMT cancer cells able to invade the surrounding stroma, and later the blood vessels, contributing to cancer metastatic spread.png 3,188 × 2,180; 3.83 MB
  
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  Cytoskeletal proteins and mechanics.jpg 1,620 × 694; 439 KB
  
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  Delamination of the cephalic and trunk neural crest cells.jpg 2,963 × 2,818; 873 KB
  
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  Development of diverse invasion modes from differentiated epithelium.jpg 1,386 × 849; 473 KB
  
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  Different types of EMT.jpg 1,233 × 935; 179 KB
  
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  Early migration of cephalic NC cells.jpg 1,777 × 1,351; 373 KB
  
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  Early migration of trunk NC cells.jpg 1,637 × 1,151; 387 KB
  
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  EMT and fibrosis.jpg 1,662 × 609; 631 KB
  
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  EMT and MET while metastasis.jpg 709 × 356; 57 KB
  
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  EMT and MET. Schematic view of EMT-MET and the main related molecules.png 4,015 × 3,125; 1.51 MB
  
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  EMT and resistance to anoikis.jpg 850 × 564; 687 KB
  
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  EMT and vimentin in confined spaces.jpg 1,614 × 1,384; 1.12 MB
  
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  EMT diversity represented by an epithelial–mesenchymal plasticity model.png 1,733 × 2,172; 1.84 MB
  
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  EMT-phenotype-detection-of-spheroid-adherent-cells.png 1,476 × 1,802; 1.45 MB
  
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  EMTMET intermediates. (A–E) Intermediate cells hybrid partial EMT cells.jpg 4,222 × 2,718; 600 KB
  
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  Ephrin and semaphorin codes regulating the formation of NC-free spaces in the hindbrain of the chick embryo.jpg 1,670 × 1,006; 215 KB
  
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  Epithelial to Mesenchymal Transition Comparison Chart.png 688 × 1,416; 141 KB
  
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  Epithelial-mesenchymal transition process during wound healing and fibrosis.png 3,000 × 1,688; 554 KB
  
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  Epithelial–mesenchymal transition scheme.png 589 × 346; 34 KB
  
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  Fonc-10-597743-g001.jpg 2,126 × 1,229; 326 KB
  
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  Fonc-10-626129-g003.jpg 1,791 × 1,729; 409 KB
  
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  Gene regulation by TET proteins.png 1,438 × 935; 491 KB
  
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  Histological evaluation of HNSCC-derived tumor spheroids.png 685 × 1,069; 237 KB
  
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  Hypothetical contribution of EMT to the pathophysiology of pSS.png 3,169 × 1,958; 313 KB
  
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  Hypothetical contribution of EMT-like process to the pathophysiology of RA.png 3,240 × 2,129; 1.13 MB
  
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  In EMT processes, tumor cells change from epithelial-like cells to mesenchymal-like cells and get the ability to metastasis.png 768 × 767; 236 KB
  
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  Major categories of EMP stimuli and markers involved in EMP.jpg 1,517 × 763; 614 KB
  
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  Mechanisms of TET-mediated transcription.jpg 718 × 531; 168 KB
  
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  Methylation status and 5hmC levels in normal, tumor, and hypoxic tumor cells.jpg 821 × 425; 106 KB
  
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  Microenvironment drivers of the EMT as potential therapeutic target to overcome therapy resistance.jpg 2,031 × 1,128; 735 KB
  
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  Molecular cascade controlling NC cell delamination at rostral trunk and cephalic levels in chick embryo.jpg 1,852 × 992; 296 KB
  
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  Molecular control of early trunk NC cell migration in the chick embryo.jpg 1,914 × 953; 256 KB
  
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  Morphological character and molecular marker expression of adherent spheroid cells of HCT-116 and HT29.png 1,571 × 1,437; 1.14 MB
  
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  Morphological modifications during EMT.png 3,297 × 2,071; 333 KB
  
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  Morphology of HNSCC-derived tumor spheroids. Morphology of HNSCC cell lines cultured as 3D tumor spheroids in ULA 96-well plates.png 685 × 795; 238 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in adipose tissue fibrosis.jpg 2,773 × 3,074; 372 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in cardiac fibrosis a.jpg 2,773 × 3,474; 363 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in intestinal fibrosis.jpg 2,739 × 3,807; 392 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in liver Fibrosis.jpg 2,773 × 2,473; 321 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in pulmonary fibrosis..jpg 2,773 × 3,807; 381 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in renal fibrosis.jpg 2,773 × 3,474; 415 KB
  
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  Most relevant molecular mechanisms and possible drugs for the treatment of EMT in scleroderma.jpg 2,773 × 2,474; 274 KB
  
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  Multiple mechanisms can lead to EMT-associated population heterogeneity.png 2,004 × 2,164; 2.01 MB
  
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  Myofibroblasts multicellular origin.png 3,619 × 2,590; 1.18 MB
  
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  Notch–Delta and Notch–Jagged signaling give rise to opposite cell patterning of EMT.png 1,610 × 2,115; 2.32 MB
  
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  Origin of fibroblasts during fibrosis and its reversal by BMP-7.jpg 1,709 × 864; 796 KB
  
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  PD-1, PD-L1 and CTLA-4 targets of immune checkpoint inhibitors.png 1,244 × 922; 602 KB
  
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  Potential avenues to target EMP.jpg 1,487 × 867; 662 KB
  
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  Regulation of EMT–MET during reprogramming.jpg 2,651 × 1,285; 182 KB
  
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  Regulation of HIF in normoxia and hypoxia.png 768 × 615; 235 KB
  
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  Regulation of major EMT transcription factors by signalling pathways.jpg 3,828 × 4,004; 1.42 MB
  
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  Remote metastasis formation by circulating tumor cells (CTCs) undergoing epithelial to mesenchymal transition-mesenchymal-to-epithelial transition (EMT-MET) changes of their cellular characterist.png 3,741 × 2,580; 2.09 MB
  
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  Schematic diagram of the TGF-β signaling a.jpg 1,069 × 870; 537 KB
  
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  Schematic diagram showing the basic mechanism of the Epithelial-to-Mesenchymal Transition.jpg 4,990 × 2,541; 611 KB
  
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  Schematic of EMT progression.jpg 1,551 × 1,794; 1.79 MB
  
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  Schematic of Epithelial-Mesenchymal Transition.jpg 553 × 926; 105 KB
  
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  Schematic representation of various mechanisms that have been reported to regulate epithelial–mesenchymal transition (EMT) in SACC patients.png 3,971 × 3,326; 3.15 MB
  
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  Signal integration. Summary of the different classes of signaling pathways involved in regulating cephalic NC cell motility and polarity.jpg 1,988 × 972; 222 KB
  
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  Signaling pathways regulating EMT.png 3,262 × 2,266; 588 KB
  
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  Signaling pathways regulating epithelial-mesenchymal transition mechanism.png 3,000 × 1,688; 904 KB
  
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  Signaling pathwaysMolecular mechanisms that negatively or positively modulate EMT.jpg 991 × 973; 303 KB
  
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  Signalling pathways regulate EMT-TFs.jpg 1,460 × 815; 255 KB
  
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  Summary of the possible anti-EMT therapeutic strategies.jpg 2,980 × 2,241; 402 KB
  
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  TET enzymes target signalling pathways.jpg 807 × 901; 257 KB
  
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  TET-mediated DNA modifications and demethylation.png 1,587 × 1,115; 358 KB
  
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  The epithelial-mesenchymal transition (EMT).jpg 1,432 × 513; 532 KB
  
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  The main signaling pathways involved in EMT.png 1,526 × 894; 638 KB
  
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  The metastasis cascade.png 723 × 345; 186 KB
  
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  The metastatic cascade (01).jpg 2,815 × 1,668; 432 KB
  
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  The regulation of the epithelial-mesenchymal transition (EMT) by miR-200s and specific transcriptional factors.png 1,235 × 1,036; 905 KB
  
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  The spatial patterning of CSCs with different EMT phenotypes.png 1,581 × 944; 609 KB
  
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  The TET protein family and their structures.jpg 951 × 288; 144 KB
  
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  Types of EMT. Type-1 EMT, Type-2 EMT, Type-3 EMT.png 3,192 × 2,652; 860 KB
  
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  Types of epithelial-mesenchymal transition.jpg 2,463 × 1,977; 1.4 MB
  
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  Visual illustration of a typical epithelial–mesenchymal transition (EMT) program.png 3,997 × 2,382; 1.08 MB