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Items: 1 to 20 of 94

1.

Resonance in the mouse tibia as a predictor of frequencies and locations of loading-induced bone formation.

Zhao L, Dodge T, Nemani A, Yokota H.

Biomech Model Mechanobiol. 2014 Jan;13(1):141-51. doi: 10.1007/s10237-013-0491-2. Epub 2013 Apr 11.

2.

Constrained tibial vibration in mice: a method for studying the effects of vibrational loading of bone.

Christiansen BA, Bayly PV, Silva MJ.

J Biomech Eng. 2008 Aug;130(4):044502. doi: 10.1115/1.2917435.

3.

Mechanical loading, damping, and load-driven bone formation in mouse tibiae.

Dodge T, Wanis M, Ayoub R, Zhao L, Watts NB, Bhattacharya A, Akkus O, Robling A, Yokota H.

Bone. 2012 Oct;51(4):810-8. doi: 10.1016/j.bone.2012.07.021. Epub 2012 Jul 31.

4.
5.

Cortical and trabecular bone adaptation to incremental load magnitudes using the mouse tibial axial compression loading model.

Weatherholt AM, Fuchs RK, Warden SJ.

Bone. 2013 Jan;52(1):372-9. doi: 10.1016/j.bone.2012.10.026. Epub 2012 Oct 27.

6.

Frequency-dependent enhancement of bone formation in murine tibiae and femora with knee loading.

Zhang P, Tanaka SM, Sun Q, Turner CH, Yokota H.

J Bone Miner Metab. 2007;25(6):383-91. Epub 2007 Oct 25.

7.

Aging diminishes lamellar and woven bone formation induced by tibial compression in adult C57BL/6.

Holguin N, Brodt MD, Sanchez ME, Silva MJ.

Bone. 2014 Aug;65:83-91. doi: 10.1016/j.bone.2014.05.006. Epub 2014 May 15.

8.

Characterization of cancellous and cortical bone strain in the in vivo mouse tibial loading model using microCT-based finite element analysis.

Yang H, Butz KD, Duffy D, Niebur GL, Nauman EA, Main RP.

Bone. 2014 Sep;66:131-9. doi: 10.1016/j.bone.2014.05.019. Epub 2014 Jun 9.

PMID:
24925445
9.

Cancellous bone adaptation to tibial compression is not sex dependent in growing mice.

Lynch ME, Main RP, Xu Q, Walsh DJ, Schaffler MB, Wright TM, van der Meulen MC.

J Appl Physiol (1985). 2010 Sep;109(3):685-91. doi: 10.1152/japplphysiol.00210.2010. Epub 2010 Jun 24.

10.

Constrained tibial vibration does not produce an anabolic bone response in adult mice.

Christiansen BA, Kotiya AA, Silva MJ.

Bone. 2009 Oct;45(4):750-9. doi: 10.1016/j.bone.2009.06.025. Epub 2009 Jul 1.

11.

Modification of the in vivo four-point loading model for studying mechanically induced bone adaptation.

Forwood MR, Bennett MB, Blowers AR, Nadorfi RL.

Bone. 1998 Sep;23(3):307-10.

PMID:
9737355
12.

Loading induces site-specific increases in mineral content assessed by microcomputed tomography of the mouse tibia.

Fritton JC, Myers ER, Wright TM, van der Meulen MC.

Bone. 2005 Jun;36(6):1030-8.

PMID:
15878316
13.

Mechanical loading enhances the anabolic effects of intermittent parathyroid hormone (1-34) on trabecular and cortical bone in mice.

Sugiyama T, Saxon LK, Zaman G, Moustafa A, Sunters A, Price JS, Lanyon LE.

Bone. 2008 Aug;43(2):238-48. doi: 10.1016/j.bone.2008.04.012. Epub 2008 May 1.

PMID:
18539556
14.

Low-amplitude, broad-frequency vibration effects on cortical bone formation in mice.

Castillo AB, Alam I, Tanaka SM, Levenda J, Li J, Warden SJ, Turner CH.

Bone. 2006 Nov;39(5):1087-1096. doi: 10.1016/j.bone.2006.04.026. Epub 2006 Jun 21.

PMID:
16793358
15.
16.

Enabling bone formation in the aged skeleton via rest-inserted mechanical loading.

Srinivasan S, Agans SC, King KA, Moy NY, Poliachik SL, Gross TS.

Bone. 2003 Dec;33(6):946-55.

PMID:
14678854
17.

Mice lacking thrombospondin 2 show an atypical pattern of endocortical and periosteal bone formation in response to mechanical loading.

Hankenson KD, Ausk BJ, Bain SD, Bornstein P, Gross TS, Srinivasan S.

Bone. 2006 Mar;38(3):310-6. Epub 2005 Nov 14.

PMID:
16290255
18.
19.

Sympathetic nervous system does not mediate the load-induced cortical new bone formation.

de Souza RL, Pitsillides AA, Lanyon LE, Skerry TM, Chenu C.

J Bone Miner Res. 2005 Dec;20(12):2159-68. Epub 2005 Aug 8.

20.

Mechanotransduction in bone: do bone cells act as sensors of fluid flow?

Turner CH, Forwood MR, Otter MW.

FASEB J. 1994 Aug;8(11):875-8.

PMID:
8070637

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