Exercise alters mineral and matrix composition in the absence of adding new bone - Wikidata - wikimedia - TriplyDB

Exercise alters mineral and matrix composition in the absence of adding new bone

Exercise alters mineral and matrix composition in the absence of adding new bone

http://www.wikidata.org/entity/Q42238338

about

Load-induced changes in bone stiffness and cancellous and cortical bone mass following tibial compression diminish with age in female mice Effect of in vivo loading on bone composition varies with animal age Raman assessment of bone quality.Inbred strain-specific effects of exercise in wild type and biglycan deficient mice.Osteopontin deficiency increases bone fragility but preserves bone mass.Mineral distributions at the developing tendon enthesis.Prediction of local ultimate strain and toughness of trabecular bone tissue by Raman material composition analysis.Bone fracture toughness and strength correlate with collagen cross-link maturity in a dose-controlled lathyrism mouse model.Measuring differences in compositional properties of bone tissue by confocal Raman spectroscopy.Mechanical Loading Synergistically Increases Trabecular Bone Volume and Improves Mechanical Properties in the Mouse when BMP Signaling Is Specifically Ablated in Osteoblasts.Calcium- and Phosphorus-Supplemented Diet Increases Bone Mass after Short-Term Exercise and Increases Bone Mass and Structural Strength after Long-Term Exercise in Adult Mice.Exercise increases pyridinoline cross-linking and counters the mechanical effects of concurrent lathyrogenic treatment.PTH Signaling During Exercise Contributes to Bone Adaptation.PTH signaling mediates perilacunar remodeling during exercise.Compressive loading of the murine tibia reveals site-specific micro-scale differences in adaptation and maturation rates of bone.Fracture healing with alendronate treatment in the Brtl/+ mouse model of osteogenesis imperfecta Betwixt and Between: Intracranial Perspective on Zygomatic Arch Plasticity and Function in Mammals.Limitations of a morphological criterion of adaptive inference in the fossil record.The bone diagnostic instrument III: testing mouse femora.Sustained swimming increases the mineral content and osteocyte density of salmon vertebral bone.Bone up: craniomandibular development and hard-tissue biomineralization in neonate mice.Exercise improves femoral whole-bone and tissue-level biomechanical properties in hyperphagic OLETF rats.Bone adaptation in response to treadmill exercise in young and adult mice.Raman and Fourier Transform Infrared (FT-IR) Mineral to Matrix Ratios Correlate with Physical Chemical Properties of Model Compounds and Native Bone Tissue.Differential Adaptive Response of Growing Bones From Two Female Inbred Mouse Strains to Voluntary Cage-Wheel Running Combined mineral-supplemented diet and exercise increases bone mass and strength after eight weeks and maintains increases after eight weeks detraining in adult mice

P2860

Q28385925-41E75900-539C-4C7F-BBA1-27BA98C9D790 Q30389625-CA89029F-A3F5-4499-B02D-2536769714C3 Q30465076-067B022F-ECFD-4AED-A071-06BB4BF655B6 Q33833523-0F72215B-E4A5-40E1-80EA-1465BE2C4FF1 Q33872326-56F626F0-B3A7-4755-A177-A0CF63627CE2 Q34477400-8015D577-38F9-4569-849C-F29740ECEA0A Q35071764-9C8F3056-299C-4EA3-86F1-8901A5114888 Q35096771-6C306352-E1D1-4EA9-9ED2-6497DCDDACB6 Q35754709-1AAE787A-8CEA-4FD7-BACB-C8AF9149F2C0 Q35816356-A6CAEF61-C6F0-4900-AACC-8F09780D6183 Q35967934-71744C93-86D1-49C6-B42D-710CFED396CC Q36269087-81C88D3F-4F2C-4837-91BE-57DEE9AA5EE7 Q36525466-7B97F096-E3D0-4C80-94C7-461D4BF9E8DF Q36923638-EE009B29-C279-4647-BAB0-F8D77C7C8AE7 Q37639355-F63BDCF2-A30E-4D7B-AF0E-B9390A6C2C63 Q37722288-EE4B002E-17B6-48E9-8E17-F8EE973175C3 Q39168311-EA94384C-6BAF-426D-9F1E-39EAFDE1E222 Q40860341-34A8245E-11D9-4AA6-B6FD-09B78FA33B93 Q42678901-A2E676D2-CDCA-46D1-9C9B-CF7876C3CFF9 Q45877009-23950CF8-3AA0-4F18-8D86-9E9072D670C3 Q46274447-214ACE65-41FD-4E40-8BC9-AE6C6666BEF6 Q47900890-A4BA2292-C4D1-40F0-B5D7-2C44E7F0DE8A Q49590399-6A93300D-3EFE-4385-B205-FBFC844F7B8F Q50882841-9BA7D70E-9F33-4736-972E-91D85D7DBCB0 Q57148030-AB350AF6-807F-44D5-824E-47F9FD78E612 Q58707339-818F3850-7C6C-406F-A2FF-82E0C9F6A239

P2860

Exercise alters mineral and matrix composition in the absence of adding new bone

http://www.wikidata.org/entity/Q42238338

description

2008 nî lūn-bûn

@nan

2008年の論文

@ja

2008年論文

@yue

2008年論文

@zh-hant

2008年論文

@zh-hk

2008年論文

@zh-mo

2008年論文

@zh-tw

2008年论文

@wuu

2008年论文

@zh

2008年论文

@zh-cn

name

Exercise alters mineral and matrix composition in the absence of adding new bone

@en

Exercise alters mineral and matrix composition in the absence of adding new bone

@nl

type

label

Exercise alters mineral and matrix composition in the absence of adding new bone

@en

Exercise alters mineral and matrix composition in the absence of adding new bone

@nl

prefLabel

Exercise alters mineral and matrix composition in the absence of adding new bone

@en

Exercise alters mineral and matrix composition in the absence of adding new bone

@nl

P1433

Q42238338-B7F65D13-B9A2-41DD-BB3A-7594AFC5F13F

P1476

Q42238338-83859FD5-EFA4-4DDB-AD2F-98576B0C0AD2

P2093

Q42238338-1DD26D26-9872-4F10-8BF4-CCDB635E55F5

Q42238338-5D909E51-0B00-41D6-B3AE-0FC027F81CE2

Q42238338-79CE2D99-5D8A-42A0-9AF4-432724B9DD2C

Q42238338-7EDE03E8-6CB6-4938-9E1D-8F63206C7A4C

P2860

Q42238338-084F8F70-E3C2-457F-8D43-D655BA7C52F5

Q42238338-42A72A77-A695-477F-AA09-17327E50AAE2

Q42238338-483F87FD-6F1B-4B36-82B9-394B5E57B41F

Q42238338-58F86979-34A4-42C1-A80E-8125A07579CD

Q42238338-62CA0BC0-B012-4D1D-860A-953186A752C4

Q42238338-69ECC151-0D39-437C-98DF-0F042CCBC892

Q42238338-702AF19A-9C0B-4F81-A299-025350758ECC

Q42238338-86A5EE09-62E0-4527-88F9-A6EB2CCDA8F1

Q42238338-A0AE4E47-66A7-4EFE-8370-2BB06D998AC9

Q42238338-B99732D1-04A9-460D-91BE-E20E11E7E12A

P304

Q42238338-47841C08-277F-4C75-BF58-0E94B1005D89

P31

Q42238338-74D68B3A-1205-42C3-A932-C769144A177F

P356

Q42238338-43D31653-DA7E-4181-9204-292E6036FA93

P433

Q42238338-DA6D63F7-9FCF-4C81-AB84-1AA0C1EF81AE

P478

Q42238338-80457126-9D7F-4208-BE5B-5219FCD9B494

P50

Q42238338-0F2451BF-DCD4-4AE4-B5EF-9A1B11401566

P577

Q42238338-B86E7697-803B-4E6A-80C6-703781F25775

P5875

Q42238338-92D4E14E-95A5-490F-972E-1588C39E2A56

P698

Q42238338-73FD5415-D8EB-48DD-B6C2-D166206C5847

P932

Q42238338-42868999-703C-4CC2-A0EC-D06B000BDA5E

P356

P1433

Cells Tissues Organs

P1476

Exercise alters mineral and matrix composition in the absence of adding new bone

@en

P2093

David H Kohn

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

Kurtulus Golcuk

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

Michael D Morris

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

Nadder D Sahar

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

P2860

Cooperative deformation of mineral and collagen in bone at the nanoscale.

Effects of tower climbing exercise on bone mass, strength, and turnover in growing rats.

Highly ordered interstitial water observed in bone by nuclear magnetic resonance.

Three structural roles for water in bone observed by solid-state NMR.

Bone structure: from angstroms to microns.

Collagen and bone strength.

Mechanotransduction in bone--role of the lacuno-canalicular network.

Exercise-induced changes in the cortical bone of growing mice are bone- and gender-specific

Mechanotransduction and the functional response of bone to mechanical strain.

Mechanical factors in bone growth and development.

P304

33-37

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

P31

scholarly article

P356

10.1159/000151452

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

P433

1-4

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

P478

189

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

P50

Joseph M. Wallace

P577

2008-08-15T00:00:00Z

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

P5875

23171560

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

P698

18703871

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

P932

2824184

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