Fluid pressure and flow as a cause of bone resorption. - Wikidata - wikimedia - TriplyDB

Fluid pressure and flow as a cause of bone resorption.

Fluid pressure and flow as a cause of bone resorption.

http://www.wikidata.org/entity/Q41959805

about

The biology and clinical evidence of microfracture in hip preservation surgery Peri-implant bone strains and micro-motion following in vivo service: a postmortem retrieval study of 22 tibial components from total knee replacements Innate immunity sensors participating in pathophysiology of joint diseases: a brief overview.Interface micromotion of uncemented femoral components from postmortem retrieved total hip replacements.Intermittent Parathyroid Hormone Enhances Cancellous Osseointegration of a Novel Murine Tibial Implant.Changes in microgaps, micromotion, and trabecular strain from interlocked cement-trabecular bone interfaces in total knee replacements with in vivo service Direct subcutaneous injection of polyethylene particles over the murine calvaria results in dramatic osteolysis Fluid-structure interactions in micro-interlocked regions of the cement-bone interface Experimental and computational micromechanics at the tibial cement-trabeculae interface Damage in total knee replacements from mechanical overload.Cancellous and cortical bone mineral density around an elastic press-fit socket in total hip arthroplasty.Osteolysis around total knee arthroplasty: a review of pathogenetic mechanisms.Mechanical instability and titanium particles induce similar transcriptomic changes in a rat model for periprosthetic osteolysis and aseptic loosening.GSK-3β Inhibition Suppresses Instability-induced Osteolysis by a Dual Action on Osteoblast and Osteoclast Differentiation.Micromotion-induced peri-prosthetic fluid flow around a cementless femoral stem.Fluid flow-induced calcium response in osteoclasts: signaling pathways.Emerging ideas: Instability-induced periprosthetic osteolysis is not dependent on the fibrous tissue interface A novel in vitro loading system to produce supraphysiologic oscillatory fluid shear stress.Sheep Hip Arthroplasty Model of Failed Implant Osseointegration.Morphological analysis of subchondral talar cysts on microCT.Supraphysiological loading induces osteocyte-mediated osteoclastogenesis in a novel in vitro model for bone implant loosening.Trabecular resorption patterns of cement-bone interlock regions in total knee replacements.Is the proximal bone resorption around the femoral stem after hip arthroplasty really caused by reduced stress?Does particle disease really exist?Strain shielding in trabecular bone at the tibial cement-bone interface.Peri-Implant Distribution of Polyethylene Debris in Postmortem-Retrieved Knee Arthroplasties: Can Polyethylene Debris Explain Loss of Cement-Bone Interlock in Successful Total Knee Arthroplasties?

P2860

Q28072782-47A6D22B-E992-4EB3-BE73-F23F4DD8FD85 Q33911237-3976E3D0-CF42-4CA6-960D-D0F371235EFB Q35206138-FE43CBE3-1495-43ED-AB0D-1825B1591301 Q35457217-D8566B92-A6B2-44DC-B819-50AEE4F3771D Q36072673-5A962FAD-4DF9-461E-B1D8-3502B454347C Q36927773-718727E6-3047-4D6E-827B-733C17721825 Q36937839-3C97E1CC-1112-44FD-AF5B-33DBF79385A1 Q36940933-E94C153E-A946-4C1E-811E-7FFF3CA835C0 Q36948506-CA3B72AC-234D-4D42-951E-ABA2A93616CB Q37004302-E3B36097-E072-411E-A783-FEA780AD5D48 Q37428896-2A10B5D9-242F-4C9B-AD4C-9C8005A2CE0A Q37730881-2A22DE01-F0AD-4EE2-9233-B63A5F71BCF9 Q38631292-1B9034C2-E211-406F-8BDD-8C8A7C8E1618 Q38668332-E93FDB63-259B-433A-A673-437C36D5ED99 Q38921662-A85F3944-66AA-49A3-BAAC-39F1D06BBFEC Q39006749-683AA2E4-052A-4B17-9C21-579AEC843D5A Q39456900-F0949BFF-1377-418F-9A20-A2E4B50D70B7 Q41889794-7AD0FF5F-83B6-4378-9371-AE7881360758 Q43141857-AB0946E6-BE90-4C57-955B-A592201C8966 Q45797612-898C9F5A-0E33-4DF8-8CD3-8D8A7746231E Q48130067-01467BF8-B2E9-4340-B40A-8A939CDA9E5D Q48220437-235E530D-8295-4BD0-8B7E-4DBB95F1DAB0 Q49620574-3BEDE13C-97A8-4FCE-8470-71DFD19EEC86 Q50073666-11D601C1-7A58-4753-AF77-E253F80EDD40 Q51092607-EFA23958-D8B4-4BD7-97D6-E6AB826AB983 Q55447352-716A16F1-11CD-4C7A-AEBA-BE1D288F28EA

P2860

Fluid pressure and flow as a cause of bone resorption.

http://www.wikidata.org/entity/Q41959805

description

2010 nî lūn-bûn

@nan

2010年の論文

@ja

2010年論文

@yue

2010年論文

@zh-hant

2010年論文

@zh-hk

2010年論文

@zh-mo

2010年論文

@zh-tw

2010年论文

@wuu

2010年论文

@zh

2010年论文

@zh-cn

name

Fluid pressure and flow as a cause of bone resorption.

@en

type

label

Fluid pressure and flow as a cause of bone resorption.

@en

prefLabel

Fluid pressure and flow as a cause of bone resorption.

@en

P1433

Q41959805-1480B9C6-7142-445E-8B99-392B2B1A2580

P1476

Q41959805-1063ED4A-8FFB-492B-B387-9A170786AC7F

P2093

Q41959805-22EF34AB-DA8B-4174-B161-7F5CCE405BC3

Q41959805-572FDDDF-2238-4730-9EF3-5DEA4C7F24DB

Q41959805-6EAC4701-4C6D-4740-9F07-46E93E4DFCFF

Q41959805-B41C1BE6-3682-4261-8919-5007FBC28E89

Q41959805-D3920E1D-E02A-422A-8610-0F0172DB5692

Q41959805-D8A335F6-8FC0-4946-B67C-D9F4A76BD526

Q41959805-F34EA442-C091-48A3-BEBC-EF4AB98BFA2E

P2860

Q41959805-02F9E425-41B3-4C97-88D1-CC05A3C69A48

Q41959805-3120E152-650B-4C02-84B5-2275243D7F05

Q41959805-3231DB2F-196D-4DC5-9535-BBBD4AD0ED0B

Q41959805-3882DD83-5A6D-4F7C-AB12-C4448B6D6708

Q41959805-4823DDFD-E055-473B-BFA8-84BA44D2CF71

Q41959805-4BD803E2-CC33-4342-A406-5B2A96F37EF4

Q41959805-4EACBD4E-651F-4930-BB01-334A22BC12CB

Q41959805-52339C5E-305C-4B5F-8849-FE999FA81104

Q41959805-652083FE-6FC5-4F45-A54C-10473D31C99E

Q41959805-6A9FF7F6-C6F1-4653-9654-38C9B4347FFE

P304

Q41959805-E204565A-D6A5-4FB3-97C9-E85A96FC7F02

P31

Q41959805-EBD8DCCE-5E7C-4C47-97BB-1D445404A5D4

P356

Q41959805-7EAF5C59-01EF-4BEF-8825-4C59915E277C

P433

Q41959805-7F112FC8-E51F-4D3D-B471-5B4FC144E98F

P478

Q41959805-998BDF37-C3FD-4AFB-8714-34E37A2334C3

P577

Q41959805-8108158F-0554-4782-AA7C-3E2E50ECFE5B

P5875

Q41959805-006A092E-B9FE-4BE5-B6D0-7F46FB300C80

P698

Q41959805-BC1DC620-2529-43A3-9CD8-B0478D582E84

P932

Q41959805-14C6C450-C4F5-4542-8D8C-E9387AD75749

P356

17453674.2010.504610

P1433

Acta Orthopaedica

P1476

Fluid pressure and flow as a cause of bone resorption.

@en

P2093

Anna Fahlgren

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

Fredrik Agholme

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

Lars Johansson

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

Mathias P G Bostrom

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

Per Aspenberg

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

Ulf Edlund

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

Xu Yang

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

P2860

High-turnover periprosthetic bone remodeling and immature bone formation around loose cemented total hip joints.

Roentgen stereophotogrammetric analysis as a predictor of mechanical loosening of knee prostheses.

Does early micromotion of femoral stem prostheses matter? 4-7-year stereoradiographic follow-up of 84 cemented prostheses.

Evolution of the internal fixation of long bone fractures. The scientific basis of biological internal fixation: choosing a new balance between stability and biology.

One mechanostat or many? Modifications of the site-specific response of bone to mechanical loading by nature and nurture.

Flow through interstitium and other fibrous matrices.

Proteolytic processing and polarized secretion of tartrate-resistant acid phosphatase is altered in a subpopulation of metaphyseal osteoclasts in cathepsin K-deficient mice.

The theory of early loosening of hip prostheses.

A rat model for testing pharmacologic treatments of pressure-related bone loss.

Pressure-loaded MSCs during early osteodifferentiation promote osteoclastogenesis by increase of RANKL/OPG ratio.

P304

508-516

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

P31

scholarly article

P356

10.3109/17453674.2010.504610

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

P433

4

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

P478

81

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

P577

2010-08-01T00:00:00Z

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

P5875

45706692

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

P698

20718695

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

P932

2917576

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