Calcium response in osteocytic networks under steady and oscillatory fluid flow. - Wikidata - wikimedia - TriplyDB

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

http://www.wikidata.org/entity/Q39322166

about

Biology of Bone Tissue: Structure, Function, and Factors That Influence Bone Cells Osteocytes: master orchestrators of bone In Vitro Bone Cell Models: Impact of Fluid Shear Stress on Bone Formation Mechanotransduction as an Adaptation to Gravity.Biomechanics and mechanobiology of trabecular bone: a review.Mechanosensory responses of osteocytes to physiological forces occur along processes and not cell body and require αVβ3 integrin In situ intracellular calcium oscillations in osteocytes in intact mouse long bones under dynamic mechanical loading.Integrative transcriptomic and proteomic analysis of osteocytic cells exposed to fluid flow reveals novel mechano-sensitive signaling pathways.Biomechanical forces in the skeleton and their relevance to bone metastasis: biology and engineering considerations.Impact of cellular microenvironment and mechanical perturbation on calcium signalling in meniscus fibrochondrocytes Altered mechanical environment of bone cells in an animal model of short- and long-term osteoporosis.Microbeads-Guided Reconstruction of 3D Osteocyte Network during Microfluidic Perfusion Culture Bone's responses to mechanical loading are impaired in type 1 diabetes.Monitoring the intracellular calcium response to a dynamic hypertonic environment Studying osteocytes within their environment.T-Type voltage-sensitive calcium channels mediate mechanically-induced intracellular calcium oscillations in osteocytes by regulating endoplasmic reticulum calcium dynamics.Matrix-dependent adhesion mediates network responses to physiological stimulation of the osteocyte cell process.Biophysical regulation of stem cell differentiation.Physiological effects of microgravity on bone cells.A noninvasive approach to determine viscoelastic properties of an individual adherent cell under fluid flow.Experimental studies of bone mechanoadaptation: bridging in vitro and in vivo studies with multiscale systems.Distinct Osteomimetic Response of Androgen-Dependent and Independent Human Prostate Cancer Cells to Mechanical Action of Fluid Flow: Prometastatic Implications.Osteocyte physiology and response to fluid shear stress are impaired following exposure to cobalt and chromium: Implications for bone health following joint replacement.Fluid flow-induced calcium response in osteoclasts: signaling pathways.UTP-induced ATP release is a fine-tuned signalling pathway in osteocytes.Simultaneous tracking of 3D actin and microtubule strains in individual MLO-Y4 osteocytes under oscillatory flow.Oscillatory flow accelerates autocrine signaling due to nonlinear effect of convection on receptor-related actions.Effect of Osteocyte-Ablation on Inorganic Phosphate Metabolism: Analysis of Bone-Kidney-Gut Axis.Osteocyte calcium signals encode strain magnitude and loading frequency in vivo.Microfluidics approach to investigate the role of dynamic similitude in osteocyte mechanobiology.Fluid shear stress induces osteoblast differentiation and arrests the cell cycle at the G0 phase via the ERK1/2 pathway.Calcium signaling of in situ chondrocytes in articular cartilage under compressive loading: Roles of calcium sources and cell membrane ion channels.A multiscale fluidic device for the study of dendrite-mediated cell to cell communication.Computer modelling of bone's adaptation: the role of normal strain, shear strain and fluid flow.The Lineage Specification of Mesenchymal Stem Cells Is Directed by the Rate of Fluid Shear Stress.Mechanically induced Ca2+ oscillations in osteocytes release extracellular vesicles and enhance bone formation.The modulation of stem cell behaviors by functionalized nanoceramic coatings on Ti-based implants.

P2860

Q26801599-91B25A68-7906-426E-8D70-E5977A513A79 Q27022407-1773F1AD-B52A-44BE-A089-4D9E5CDDA517 Q28069176-E4062D3F-979B-4849-B4EA-A5498E771855 Q28584642-FF3C4930-74A1-4E0C-9918-7C6C4963650B Q30369765-3C4BB849-0935-4F3D-8C20-0C1BF7EAA118 Q30561021-5F86434B-44C5-4189-87BB-6072EC0CA49D Q30574510-5E681CDD-0BA9-4357-ABDB-640947E5BFF5 Q33683096-8592DDD9-664C-4E08-9F75-9FDA4DF8608B Q34646678-D87FD503-BD41-4D9D-AA6C-321B1ECDE65A Q35183538-D43A2B16-F156-4153-BAC4-F8DDAC839E10 Q35333544-219A0865-1360-4109-AAB3-B45014284FA4 Q36092081-4AE4E309-C012-4F8F-B925-7734310CA16E Q36269054-ABCC2EC0-17C8-4C75-940E-86D2FBA6035A Q36719353-71600F83-A5FE-46CF-87D8-203193F44F85 Q36839461-4AA0B075-1DFB-45B4-819D-ACA57CF34CA7 Q36984760-51B5A114-B65F-4391-AC18-939A396AE186 Q37031872-62CD684A-FCDB-44E3-AF15-2FDFF6A2B569 Q38093443-D8975E12-3346-406B-9A15-14D00E2A5C3E Q38200946-7E3B4667-C565-41E9-9A2D-9C2B08D7F253 Q38600783-6ABCA407-68C4-4CA7-AB54-B85A1947DE20 Q38726181-D4B35DAB-0DE0-46E3-B112-BE915956E492 Q38733024-1F11E001-8238-4644-886E-B9F311F8E304 Q38743516-409458D5-224D-452C-8E79-A25DE02A23C8 Q39006749-49837E0A-9721-4CC3-9574-CCEE14AFA34F Q39038836-A401595A-7CEA-4929-AB06-BC6DEDFD1871 Q39204398-238DD0F4-F6F7-4535-9AB4-7335EA9D8F34 Q41994419-C951A79C-7B28-4AFD-AFA4-B7EE569175BF Q47221759-D8AA5F06-CA43-460F-98A0-0A459267FC12 Q47403141-4FC708A5-521E-4596-9992-B146A39195FE Q47448568-3625D3D7-F571-4621-ADF1-1118F7D327E9 Q47589728-9FD09D7A-45FA-4191-9CB5-15244DD0B126 Q47599194-849A39AD-7006-4034-8D8A-D0C6B3922210 Q47816014-74BE8B36-C42C-438A-9F4F-ECD94541345E Q51175875-38D4C881-DBFF-455F-8A63-FAD79BD5DE19 Q53259682-40229011-0E7E-4686-A8F8-B5C933E9202A Q55092293-34744268-EB57-479E-B182-204174F8ECBF Q55333479-7E66D5C1-63D1-42A2-803F-0808EDF6D915

P2860

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

http://www.wikidata.org/entity/Q39322166

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年学术文章

@wuu

2012年学术文章

@zh-cn

2012年学术文章

@zh-hans

2012年学术文章

@zh-my

2012年学术文章

@zh-sg

2012年學術文章

@yue

2012年學術文章

@zh

2012年學術文章

@zh-hant

name

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@en

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@nl

type

label

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@en

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@nl

prefLabel

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@en

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@nl

P1433

Q39322166-E14A54D8-218F-42D3-A1B6-7795F60B962F

P1476

Q39322166-2306101C-0EAD-4F49-8677-4F81D83AF61B

P2093

Q39322166-4F2BBA49-9D16-4136-8F7B-76BBDA06F2EC

Q39322166-5BC65D7B-B085-401B-BF84-125D99A0A2C9

Q39322166-BE679094-B099-48AE-8D38-55C18E1DA34D

Q39322166-EC417B03-DA47-4980-9233-8E80708735F7

P2860

Q39322166-101BDC02-DAA5-465B-BA79-5FF76006A3E6

Q39322166-16B7A4A5-9C2D-43CE-820D-78EA28758C6B

Q39322166-1B46C90A-0446-4B5B-B65B-8765FB310EA4

Q39322166-2A9F65CC-FE23-4948-B32E-2CF3F0CB8C03

Q39322166-3AAC7B59-A959-4CBB-83D6-3B6DB9F10B18

Q39322166-4E824C6A-3475-40E9-AC5D-53731AB7D09F

Q39322166-56A9BD15-4D29-47CD-86CE-E02A24483D73

Q39322166-5A1843F5-C399-4DAE-880A-42FE6AD0B0DE

Q39322166-62CD6914-37BD-4594-90C5-664D08468BAA

Q39322166-6E692143-8021-44AC-929B-8C2976F6517F

P304

Q39322166-41E9652D-5030-4D09-82A7-F549A1208651

P31

Q39322166-465AF4A4-9432-4D01-9C69-045BF224D54F

P356

Q39322166-4ADEA1E4-41D9-44AB-8155-CE36EB4A140E

P433

Q39322166-20FD7092-23B3-4C75-B42B-0BD8268F3DB1

P478

Q39322166-E70B4D7B-DC70-44D4-B064-CFBC8BBFBE99

P577

Q39322166-F07C765C-DD60-4245-8D10-D6761FA95A96

P5875

Q39322166-3465B02B-CF41-49E5-A454-A4C5CDC604CB

P698

Q39322166-5C4DD356-B1C8-472E-81ED-8BDB89A58DD3

P932

Q39322166-672FAF9E-7E37-42AA-828E-160FFAEDB651

P356

J.BONE.2012.05.021

P1433

P1476

Calcium response in osteocytic networks under steady and oscillatory fluid flow.

@en

P2093

Bo Huo

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

Miri Park

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

X Edward Guo

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

X Lucas Lu

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

P2860

The amazing osteocyte

Nitric oxide and cGMP activate Ca2+-release processes in rat parotid acinar cells

The versatility and universality of calcium signalling

Parathyroid hormone enhances fluid shear-induced [Ca2+]i signaling in osteoblastic cells through activation of mechanosensitive and voltage-sensitive Ca2+ channels.

An in-situ fluorescence-based optical extensometry system for imaging mechanically loaded bone.

An ATP-dependent mechanism mediates intercellular calcium signaling in bone cell network under single cell nanoindentation.

Mechanically induced intracellular calcium waves in osteoblasts demonstrate calcium fingerprints in bone cell mechanotransduction

Functional gap junctions between osteocytic and osteoblastic cells.

Oscillating fluid flow activation of gap junction hemichannels induces ATP release from MLO-Y4 osteocytes.

A Trabecular Bone Explant Model of Osteocyte-Osteoblast Co-Culture for Bone Mechanobiology.

P304

466-473

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

P31

scholarly article

P356

10.1016/J.BONE.2012.05.021

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

P433

3

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

P478

51

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

P577

2012-06-28T00:00:00Z

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

P5875

228101687

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

P698

22750013

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

P932

3412915

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