The influence of mechanical stimulation on osteocyte apoptosis and bone viability in human trabecular bone

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Mann, V.¹; Huber, C.¹; Kogianni, G.¹; Jones, D.²; Noble, B.¹

The influence of mechanical stimulation on osteocyte apoptosis and bone viability in human trabecular bone

J Musculoskel Neuron Interact. December 2006;6(4):408-417

Affiliations

¹Musculoskeletal Tissue Engineering Collaboration, University of Edinburgh Medical School, Edinburgh, UK

²Dept. Experimental Orthopaedics and Biomechanics, Phillipps University, Marburg, Germany
Abstract and keywords

It has been shown previously using in vivo and ex vivo animal models, that cyclical mechanical stimulation is capable of maintaining osteocyte viability through the control of apoptotic cell death. Here we have studied the effect of mechanical stimulation on osteocyte viability in human trabecular bone maintained in a 3-D bioreactor system. Bone samples, maintained in the bioreactor system for periods of 3, 7 and 27 days, were subjected to either cyclical mechanical stimulation which engendered a maximum of 3,000 μstrain in a waveform corresponding to physiological jumping exercise for 5 minutes daily or control unloading. Unloading resulted in a decrease in osteocyte viability within 3 days that was accompanied by increased levels of cellular apoptosis. Mechanical stimulation significantly reduced apoptosis (p≤0.032) and improved the maintenance of osteocyte viability in bone from all patient samples. The percentage Alkaline Phosphatase (ALP) labelled bone surface was significantly increased (p≤0.05) in response to mechanical stimulation in all samples as was the Bone Formation Rate (BFR/BS) (p=0.005) as determined by calcein label incorporation in the 27-day experiment. These data indicate that in this model system, mechanical stimulation is capable of maintaining osteocyte viability in human bone

Keywords: Human Bone; Mechanical Stimulation; Osteocyte; Viability; Apoptosis
Links

PubMed: 17185839

PubMedCentral: PMC1847464
History

Accepted: 2006-10-09

Cited Works (16)

Year	Entry
1993	Dunstan CR, Somers NM, Evans RA. Osteocyte death and hip fracture. Calcif Tiss Int. February 1993;53(1):S113-S117.
2003	Noble BS, Peet N, Stevens HY, Brabbs A, Mosley JR, Reilly GC, Reeve J, Skerry TM, Lanyon LE. Mechanical loading: biphasic osteocyte survival and targeting of osteoclasts for bone destruction in rat cortical bone. Am J Physiol Cell Physiol. April 2003;284(4):C934-C943.
2006	Davies CM, Jones DB, Stoddart MJ, Koller K, Smith E, Archer CW, Richards RG. Mechanically loaded ex vivo bone culture system “Zetos”: systems and culture preparation. Eur Cell Mater. January–June 2006;11:57-75.
1960	Frost HM. In vivo osteocyte death. J Bone Joint Surg. January 1960;42A(1):138-143.
2000	Knothe Tate M, Knothe U. An ex vivo model to study transport processes and fluid flow in loaded bone. J Biomech. February 2000;33(2):247-254.
1997	Noble BS, Stevens H, Loveridge N, Reeve J. Identification of apoptotic changes in osteocytes in normal and pathological human bone. Bone. March 1997;20(3):273-282.
2006	Rubin J, Rubin C, Jacobs CR. Molecular pathways mediating mechanical signaling in bone. Gene. February 15, 2006;367:1-16.
1997	Tomkinson A, Reeve J, Shaw RW, Noble BS. The death of osteocytes via apoptosis accompanies estrogen withdrawal in human bone. J Clin Endocrinol Metab. September 1997;82(9):3128-3135.
2005	Qiu S, Rao DS, Fyhrie DP, Palnitkar S, Parfitt AM. The morphological association between microcracks and osteocyte lacunae in human cortical bone. Bone. July 2005;37(1):10-15.
2003	Jones DB, Broeckmann E, Pohl T, Smith EL. Development of a mechanical testing and loading system for trabecular bone studies for long term culture. Eur Cell Mater. January–June 2003;5:48-60.
2006	Aguirre JI, Plotkin LI, Stewart SA, Weinstein RS, Parfitt AM, Manolagas SC, Bellido T. Osteocyte apoptosis is induced by weightlessness in mice and precedes osteoclast recruitment and bone loss. J Bone Miner Res. April 2006;21(4):605-615.
1994	Aarden EM, Burger EH, Nijweide PJ. Function of osteocytes in bone. J Cell Biochem. July 1994;55(3):287-299.
2000	Verborgt O, Gibson GJ, Schaffler MB. Loss of osteocyte integrity in association with microdamage and bone remodeling after fatigue in vivo. J Bone Miner Res. January 2000;15(1):60-67.
1997	Mori S, Harruff R, Ambrosius W, Burr DB. Trabecular bone volume and microdamage accumulation in the femoral heads of women with and without femoral neck fractures. Bone. December 1997;21(6):521-526.
1998	Tomkinson A, Gevers EF, Wit JM, Reeve J, Noble BS. The role of estrogen in the control of rat osteocyte apoptosis. J Bone Miner Res. August 1998;13(8):1243-1250.
1993	Chow JW, Jagger CJ, Chambers TJ. Characterization of osteogenic response to mechanical stimulation in cancellous bone of rat caudal vertebrae. Am J Physiol Endocrinol Metab. August 1993;265(2, pt 1):E340-E347.

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2022	Loundagin LL, Cooper DML. Towards novel measurements of remodelling activity in cortical bone: implications for osteoporosis and related pharmaceutical treatments. Eur Cell Mater. 2022;43:202-227.
2014	Aiyangar AK, Vivanco J, Au AG, Anderson PA, Smith EL, Ploeg H-L. Dependence of anisotropy of human lumbar vertebral trabecular bone on quantitative computed tomography-based apparent density. J Biomech Eng. September 2014;136(9):091003.
2013	Vivanco J, Garcia S, Ploeg HL, Alvarez G, Cullen D, Smith EL. Apparent elastic modulus of ex vivo trabecular bovine bone increases with dynamic loading. Proc Inst Mech Eng Part H-J Eng Med. August 2013;227(8):904-912.
2014	Fonseca H, Moreira-Gonçalves D, Coriolano H-JA, Duarte JA. Bone quality: the determinants of bone strength and fragility. Sports Med. January 2014;44(1):37-53.
2017	Lewis KJ. Osteocyte Calcium Signaling Responses to Mechanical Load in Vivo: A Novel Experimental Approach [PhD thesis]. New York, NY: The City College of New York; 2017.
2017	Shah FA. Osteocytes as Indicators of Bone Quality: Multiscale Structure-Composition Characterisation of the Bone-Implant Interface [PhD thesis]. University of Gothenburg; 2017.
2015	Coughlin TR. Mechanobiological Signals in Trabecular Bone and Marrow [PhD thesis]. University of Notre Dame; July 2015.
2022	Kunath BA. Design and Validation of an Open-Source 3D Printable Bioreactor System for Ex Vivo Bone Culture [Master's thesis]. Queen's University; June 2022.
2011	Aiyangar AK. Physical and Computational Modeling of Subsidence of Anterior Interbody Fusion Devices [PhD thesis]. University of Wisconsin – Madison; 2011.
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2016	Johnson MG. Endothelin-Converting Enzyme-1 Dependent Endothelin 1 Signaling in Osteogenesis [PhD thesis]. University of Wisconsin – Madison; 2016.
2016	Meyer LA. Testing and Modeling Mechanical Properties of Ex Vivo Trabecular Bone [PhD thesis]. University of Wisconsin – Madison; 2016.