Locomotor activity influences muscle architecture and bone growth but not muscle attachment site morphology - Wikidata - awgldk - TriplyDB

Locomotor activity influences muscle architecture and bone growth but not muscle attachment site morphology

Locomotor activity influences muscle architecture and bone growth but not muscle attachment site morphology

http://www.wikidata.org/entity/Q28652940

about

Evidence in hand: recent discoveries and the early evolution of human manual manipulation Morphology of muscle attachment sites in the modern human hand does not reflect muscle architecture Evaluating the efficiency of different recording protocols for entheseal changes in regards to expressing activity patterns using archival data and cross-sectional geometric properties.Getting a head in hard soils: Convergent skull evolution and divergent allometric patterns explain shape variation in a highly diverse genus of pocket gophers (Thomomys).Occupational manual activity is reflected on the patterns among hand entheses.A review of trabecular bone functional adaptation: what have we learned from trabecular analyses in extant hominoids and what can we apply to fossils?Bone remodeling is reduced in high stress regions of the cercopithecoid mandible.Long bone histology of the subterranean rodent Bathyergus suillus (Bathyergidae): ontogenetic pattern of cortical bone thickening.The Anthropoid Crista Trochanterica and the Hip Joint Capsule.Physical activity alters limb bone structure but not entheseal morphology.Reconciling the convergence of supraspinous fossa shape among hominoids in light of locomotor differences.Dynamic Musculoskeletal Functional Morphology: Integrating diceCT and XROMM.Morphometric patterns among the 3D surface areas of human hand entheses.Digging the compromise: investigating the link between limb bone histology and fossoriality in the aardvark (Orycteropus afer).Evidence for precision grasping in Neandertal daily activities American Society of Biomechanics Journal of Biomechanics Award 2017: High-acceleration training during growth increases optimal muscle fascicle lengths in an avian bipedal model

P2860

Q28082205-FD0CAAFB-2985-4CA1-B4B8-1DFEC00865AC Q28597561-AE1B5B6A-1636-4698-A894-B311D1CDB9A0 Q30984853-AD38349F-5106-4AD8-A7D1-B59BB370C3C1 Q36159656-26E61064-2526-4042-B4AB-BEFC3219D261 Q36381115-88D691F8-6F88-44AB-960B-92D6992A5AEB Q38734740-AE616353-33A8-4471-8E1C-09D5CA09233D Q39652070-1E009AC7-1D6E-49BD-9998-9CA324D947EE Q46398062-4EDE8F82-D63E-4DC4-B9AD-CB14B67675D5 Q46640687-E3AFC644-1960-43FB-A00D-68BAC1776C29 Q47213422-76293BD2-63A6-49F2-A393-41046BB3363E Q47443708-8867A6B1-7A51-4AEF-AE37-0D0CD86F4F33 Q48043179-D22DB016-D8A2-4B20-8EDD-F0F9765AE56A Q50212159-9E0CD7E9-2B27-46BE-9A9A-731E9C423A3F Q55709654-6F2B99D4-525C-4E09-97CE-A107E542487A Q56959544-08FAF4E4-6DCA-4541-86FA-247F09C744CE Q57784232-178E4EBC-12E1-4A27-9959-4753A213CE99

P2860

Locomotor activity influences muscle architecture and bone growth but not muscle attachment site morphology

http://www.wikidata.org/entity/Q28652940

description

2015 nî lūn-bûn

@nan

2015 թուականի Յունուարին հրատարակուած գիտական յօդուած

@hyw

2015 թվականի հունվարին հրատարակված գիտական հոդված

@hy

2015年の論文

@ja

2015年論文

@yue

2015年論文

@zh-hant

2015年論文

@zh-hk

2015年論文

@zh-mo

2015年論文

@zh-tw

2015年论文

@wuu

name

Locomotor activity influences ...... cle attachment site morphology

@ast

Locomotor activity influences ...... cle attachment site morphology

@en

Locomotor activity influences ...... cle attachment site morphology

@nl

type

label

Locomotor activity influences ...... cle attachment site morphology

@ast

Locomotor activity influences ...... cle attachment site morphology

@en

Locomotor activity influences ...... cle attachment site morphology

@nl

prefLabel

Locomotor activity influences ...... cle attachment site morphology

@ast

Locomotor activity influences ...... cle attachment site morphology

@en

Locomotor activity influences ...... cle attachment site morphology

@nl

P1433

Q28652940-2D5D9750-CF13-444A-A2F0-4995171FF075

P1476

Q28652940-F7F350E0-1A9B-4735-84B3-A41243914005

P2093

Q28652940-04B08285-CFF6-402A-8A98-652951B64B51

Q28652940-4D8E5C8C-9833-44DD-825F-B5EAF6BD2E64

Q28652940-56564508-98A6-4221-A57E-B01D87BF4A9A

Q28652940-57602D0A-87C6-4CE6-B30B-D309A5FCA4C1

Q28652940-70543430-6BCA-4443-AC87-14CAD263F60E

Q28652940-A8D07FF6-3CDD-47E8-BAFA-25151EAACE95

P2860

Q28652940-089EF6FC-8186-44AF-82E0-A25F69DD883F

Q28652940-0A264FBD-173C-4519-BC37-A3DF2E7C73DB

Q28652940-0B5D3950-81F3-4333-9178-4647238CFB17

Q28652940-1A9FAA9C-0991-480C-BF85-96A2E9B17B21

Q28652940-1E0B1B2E-114F-49B0-93AB-9CCCDAB84D71

Q28652940-1F0326C7-7132-49C1-A67A-915A0A092366

Q28652940-26BA8DCE-55D5-4F34-B4D1-78C3F589D78A

Q28652940-2CB62686-2F68-4214-8670-83D7E602DFEB

Q28652940-307CFB32-1456-4137-BBA7-0E85A6156FD5

Q28652940-31E28621-474F-40F4-A57F-9C4DA922A070

P304

Q28652940-DD4E8E3B-58A8-4D2D-85F4-54CAF50273F1

P31

Q28652940-3D24DA45-96C6-4C3B-8017-CD99EB7282BA

P3181

Q28652940-18D400D5-A367-4668-A064-F0A2786E83BA

P356

Q28652940-DF9000A1-5161-4C65-8D7B-834D9CE0A639

P407

Q28652940-8C5679AF-C1E1-41BB-BB8C-163043BC2B11

P478

Q28652940-DC2E6E84-137B-4E90-9780-774B6D41C071

P577

Q28652940-72ECD282-F528-4602-B645-CDBC7FDFDF63

P5875

Q28652940-CD72EAFF-FCBF-45C4-AF1B-EC4DC06C2920

P698

Q28652940-139C787D-14D9-47B3-8270-9C2D4480CC64

P932

Q28652940-AB1E2545-33A3-4322-AA1A-DDAAA7D47931

P3181

P356

J.JHEVOL.2014.10.010

P1433

Journal of Human Evolution

P1476

Locomotor activity influences ...... cle attachment site morphology

@en

P2093

Andrea B Taylor

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

Brian G Richmond

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

David J Green

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

David R Begun

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

Karyne N Rabey

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

Shannon C McFarlin

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

P2860

Functional anatomy of the gibbon forelimb: adaptations to a brachiating lifestyle

Nebulin-deficient mice exhibit shorter thin filament lengths and reduced contractile function in skeletal muscle

3D microstructural architecture of muscle attachments in extant and fossil vertebrates revealed by synchrotron microtomography

The relationship between bone mechanical properties and ground reaction forces in normal and hypermuscular mice

Regional variability in secondary remodeling within long bone cortices of catarrhine primates: the influence of bone growth history

Morphological analysis of the hindlimb in apes and humans. I. Muscle architecture

Correlative light and backscattered electron microscopy of bone--Part I: Specimen preparation methods.

Dynamics of muscle function during locomotion: accommodating variable conditions.

The skeletal attachment of tendons--tendon "entheses".

Contractile properties of mouse single muscle fibers, a comparison with amphibian muscle fibers.

P304

91-102

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

P31

scholarly article

P3181

530380

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

P356

10.1016/J.JHEVOL.2014.10.010

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

P407

P478

78

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

P577

2015-01-01T00:00:00Z

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

P5875

268691437

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

P698

25467113

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

P932

4278956

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