Cellular mechanical properties reflect the differentiation potential of adipose-derived mesenchymal stem cells. - Wikidata - awgldk - TriplyDB

Cellular mechanical properties reflect the differentiation potential of adipose-derived mesenchymal stem cells.

Cellular mechanical properties reflect the differentiation potential of adipose-derived mesenchymal stem cells.

http://www.wikidata.org/entity/Q36066146

about

Viscoelastic properties of differentiating blood cells are fate- and function-dependent Properties of cells through life and death - an acoustic microscopy investigation Impact of aging on the regenerative properties of bone marrow-, muscle-, and adipose-derived mesenchymal stem/stromal cells Rare cell isolation and analysis in microfluidics.Integral role of platelet-derived growth factor in mediating transforming growth factor-β1-dependent mesenchymal stem cell stiffening.Stem cell differentiation increases membrane-actin adhesion regulating cell blebability, migration and mechanics.Long-range ordered vorticity patterns in living tissue induced by cell division.Mechanical stiffness as an improved single-cell indicator of osteoblastic human mesenchymal stem cell differentiation Differentiation Potential of Mesenchymal Stem Cells Is Related to Their Intrinsic Mechanical Properties.Standardized Nanomechanical Atomic Force Microscopy Procedure (SNAP) for Measuring Soft and Biological Samples.Adipose tissue-derived mesenchymal stem cells in long-term dialysis patients display downregulation of PCAF expression and poor angiogenesis activation.Induced pluripotent stem cells generated from human adipose-derived stem cells using a non-viral polycistronic plasmid in feeder-free conditions.Spatially coordinated changes in intracellular rheology and extracellular force exertion during mesenchymal stem cell differentiation.Adipose-derived stem cells retain their regenerative potential after methotrexate treatment.The influence of aminophylline on the nanostructure and nanomechanics of T lymphocytes: an AFM study Multivariate biophysical markers predictive of mesenchymal stromal cell multipotency Therapeutic Potential of Human Adipose-Derived Stem/Stromal Cell Microspheroids Prepared by Three-Dimensional Culture in Non-Cross-Linked Hyaluronic Acid Gel Characterization of mechanical and regenerative properties of human, adipose stromal cells.Functional consequences of glucose and oxygen deprivation on engineered mesenchymal stem cell-based cartilage constructs.Temporal heterogeneity in single-cell gene expression and mechanical properties during adipogenic differentiation Subcutaneous Adipose Tissue-Derived Stem Cell Utility Is Independent of Anatomical Harvest Site.Biomimetic Surface Patterning Promotes Mesenchymal Stem Cell Differentiation Investigation of cellular responses upon interaction with silver nanoparticles.Gene expression-based enrichment of live cells from adipose tissue produces subpopulations with improved osteogenic potential Characterizing Cellular Biophysical Responses to Stress by Relating Density, Deformability, and Size A scalable label-free approach to separate human pluripotent cells from differentiated derivatives.Cytoskeletal strains in modeled optohydrodynamically stressed healthy and diseased biological cells Tissue engineering and regenerative medicine: recent innovations and the transition to translation.Single-cell differences in matrix gene expression do not predict matrix deposition.Adipose-derived stem cell fate is predicted by cellular mechanical properties.In vivo ectopic implantation model to assess human mesenchymal progenitor cell potential.Identical effects of VEGF and serum-deprivation on phenotype and function of adipose-derived stromal cells from healthy donors and patients with ischemic heart disease Mesenchymal morphogenesis of embryonic stem cells dynamically modulates the biophysical microtissue niche.Mechanoregulation of stem cell fate via micro-/nano-scale manipulation for regenerative medicine.Optical manipulation of single molecules in the living cell.Molecular physiognomies and applications of adipose-derived stem cells.Investigating cell mechanics with atomic force microscopy.Inertial Microfluidic Cell Stretcher (iMCS): Fully Automated, High-Throughput, and Near Real-Time Cell Mechanotyping.Mechanical phenotyping of primary human skeletal stem cells in heterogeneous populations by real-time deformability cytometry.Investigation of the changes of biophysical/mechanical characteristics of differentiating preosteoblasts in vitro

P2860

Q21134049-1189F311-74B5-44B4-B396-0AABCE670EF2 Q27311381-FF14DF01-2385-4182-AEA9-EE71440EF11E Q27318545-26BE7502-0B14-4DE4-8B28-9C26FF8D7ECC Q30418365-D2B0FF2D-9582-4BCE-9642-DF893C4EE340 Q30569752-CDCBC9DD-DE17-4CBA-8CA4-2172245545A0 Q30604753-6D7C4A20-F143-44BB-8A94-212BFBF08F49 Q30608745-BCFB8568-C738-428E-A92A-A5669F3F2DF8 Q33625071-D7B51543-A20D-4E47-A965-8A37EF5BADE7 Q33662550-AD953817-6C02-41E7-ABE4-141482732BD5 Q33894794-53D5B531-AE3E-420D-A602-E30247CA0E0D Q33905105-A1914E22-70B6-44A1-B4A1-B02CDB7A1C57 Q34034169-B8AB03AE-4436-4BA3-9BE4-78BC805875CA Q34171606-74506350-01F7-460A-AFD0-6342B6B59E7F Q34183849-FB0974CD-6356-4555-B7FC-E39429723AE8 Q34241172-E97CA09A-21E3-453B-AB41-E22CB36A6382 Q34408968-77F62ECB-3D1A-49D1-99EE-A0A5E8364C32 Q34499194-90B1CC15-9AA3-4343-881B-96AFC429B6EC Q34632312-E7D3F91B-DB37-4AD4-90DC-F4712048FAA3 Q34765418-BEBCBE3A-A665-43F1-96B8-197F2A9AC164 Q35235949-F661F508-1267-4900-9816-A48891F955FB Q35836016-8F59187E-466E-4A48-B871-20ACADA98C75 Q35870669-C72D2C83-56E6-4CBF-9195-64EC5B60EF0D Q36015945-D84E9067-4738-415F-A3BD-D348BF1B6549 Q36203018-3AA721B7-3BC5-4971-A46D-F5CCF889DF34 Q36218684-FD06A8BA-F1FC-46D2-8AC6-3E7CA6E91BC3 Q36468359-25D32D6A-9EF6-4A52-B31D-F64F85E1102F Q36469108-05524461-3622-4E00-ADF5-8F4263369B72 Q36587765-70164C98-F1B4-469D-B63D-08056D0861DC Q36661576-479814A4-49F3-4489-8FD3-79D0A8A92893 Q36866060-822CE108-2E71-47D2-8938-CE9C3C66166E Q37325717-29A57B40-6198-45F6-9296-467958E65AE8 Q37367626-B0EC0BB7-390F-4308-981D-5A3689E06AEA Q37620886-F25E9826-876E-42C4-9C4C-FC065B08D012 Q38096418-30ED36BF-4263-470C-9033-268B0372F38E Q38197910-9D164008-3C64-4178-BBA2-CF9B89B6E154 Q38287656-849EF599-5015-458D-ABA8-24C52EFE9EC3 Q38318750-888D8F90-CBB0-4D52-BC56-3D372C64A0FD Q38376359-842AADF2-E69E-43B9-8236-BBE40F29DC4D Q38786057-31B37645-5553-434D-B739-1E41D60BCE23 Q41954887-09125CB3-6840-46A9-896F-5BE9CD10A603

P2860

Cellular mechanical properties reflect the differentiation potential of adipose-derived mesenchymal stem cells.

http://www.wikidata.org/entity/Q36066146

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年論文

@yue

2012年論文

@zh-hant

2012年論文

@zh-hk

2012年論文

@zh-mo

2012年論文

@zh-tw

2012年论文

@wuu

2012年论文

@zh

2012年论文

@zh-cn

name

Cellular mechanical properties ...... erived mesenchymal stem cells.

@ast

Cellular mechanical properties ...... erived mesenchymal stem cells.

@en

type

label

Cellular mechanical properties ...... erived mesenchymal stem cells.

@ast

Cellular mechanical properties ...... erived mesenchymal stem cells.

@en

prefLabel

Cellular mechanical properties ...... erived mesenchymal stem cells.

@ast

Cellular mechanical properties ...... erived mesenchymal stem cells.

@en

P1433

Q36066146-A0624E17-B1AF-49B2-8CEF-299A4FFCB561

P1476

Q36066146-660172AA-86F5-4983-99BD-DAB8D36ED549

P2093

Q36066146-4263D114-F1C4-48EA-AA3B-24CF51AE19CF

P2860

Q36066146-0183FB65-5093-4AEE-90D6-5EB2CC79D099

Q36066146-02332BE3-6A11-4C70-AA07-12576FD8D3D2

Q36066146-0341028E-243E-40CA-9865-21DCBFD4E5EC

Q36066146-08D9DE25-760B-452C-934C-D8045873FC6C

Q36066146-0BBA40B2-5679-46F0-ACE8-D7C504B2E760

Q36066146-0C0E7A72-D9AD-487E-8CB0-94BF802C18D6

Q36066146-116E8374-6A4A-4C89-9495-95C58162475E

Q36066146-1922E804-6802-4D66-A4F3-3E7079F408EA

Q36066146-19F41E23-0322-4FF0-A102-7C729CA05E5A

Q36066146-1F4BB3D7-38CE-4F5A-9187-9F94C4E7798B

P304

Q36066146-FCC36028-54C4-431B-9321-0368BE659269

P31

Q36066146-0ED6D8B0-9CE3-422D-90CF-5BDB1EAD9440

P356

Q36066146-13AB0635-393B-4096-BB26-7D5C1DEF89E7

P407

Q36066146-96033F38-2FAC-4756-80DF-C665DD19DAD7

P433

Q36066146-CD82E0AF-56D8-4DC2-91F8-BCABCEEBCF42

P478

Q36066146-9B9689D7-E2D8-466D-8193-F419CFD13BF2

P50

Q36066146-6B483A59-DA0D-4446-943E-8EB5B86F5E46

Q36066146-71E2BFC5-C84A-421A-A2EB-CF1580D5AE8E

P577

Q36066146-33E44289-5097-4FBC-9EFA-B7070758E47E

P5875

Q36066146-37F56CEB-A505-40AC-B274-830001119BA5

P698

Q36066146-3138FEA4-8FDE-4520-B031-4CB6AEC44B00

P932

Q36066146-1DCF1C82-92E3-4BC5-88F7-0C3085BF6B62

P356

PNAS.1120349109

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Cellular mechanical properties ...... derived mesenchymal stem cells

@en

P2093

Vera C Fonseca

http://www.w3.org/2001/XMLSchema#string

P2860

CellProfiler: image analysis software for identifying and quantifying cell phenotypes

Adult mesenchymal stem cells and cell-based tissue engineering

Multilineage cells from human adipose tissue: implications for cell-based therapies

Human adipose tissue is a source of multipotent stem cells

Label-free cell separation and sorting in microfluidic systems

Deformability-based flow cytometry.

Determination of elastic moduli of thin layers of soft material using the atomic force microscope

Osteoblast elastic modulus measured by atomic force microscopy is substrate dependent.

Reconfigurable microfluidic integration of a dual-beam laser trap with biomedical applications.

High-throughput rheological measurements with an optical stretcher.

P304

E1523-9

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1073/PNAS.1120349109

http://www.w3.org/2001/XMLSchema#string

P407

P433

24

http://www.w3.org/2001/XMLSchema#string

P478

109

http://www.w3.org/2001/XMLSchema#string

P50

Eric M. Darling

Rafael D. Gonzalez Cruz

P577

2012-05-21T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

225054470

http://www.w3.org/2001/XMLSchema#string

P698

22615348

http://www.w3.org/2001/XMLSchema#string

P932

3386052

http://www.w3.org/2001/XMLSchema#string