Age and distance from the surface but not menopause reduce osteocyte density in human cancellous bone

wbldb

Qiu, S.¹; Rao, D. S.¹; Palnitkar, S.¹; Parfitt, A. M.²

Age and distance from the surface but not menopause reduce osteocyte density in human cancellous bone

Bone. August 2002;31(2):313-318

©2002 Elsevier Science Inc. All rights reserved.

Affiliations

¹Bone and Mineral Research Laboratory, Henry Ford Hospital, Detroit, MI, USA

²Division of Endocrinology and Center for Osteoporosis and Metabolic Bone Disease, University of Arkansas for Medical Sciences, Little Rock, AR, USA
Abstract and keywords

Previous studies of osteocyte density in human cancellous bone have relied mainly on autopsy samples and have demonstrated an age-related decline in men, but there are insufficient data in women. Using previously obtained transiliac bone biopsies from 94 healthy white women, aged 20–73 years, 38 premenopausal and 56 postmenopausal, we measured osteocytes and lacunae in ten randomly selected areas using 5-μm-thick sections stained with Goldner trichrome. For each subject, the number of osteocytes (Ot.N/B.Ar), empty lacunae (EL.N/B.Ar), and total lacunae (Tt.L.N/B.Ar) per bone area, and the proportion of occupied lacunae (Ot.N/Tt.L.N), were calculated. In 92 cases the measurements were made separately in superficial bone (<25 μm from the surface) and in deep bone (>45 μm from the surface). Mean values and differences between extreme values (DEV) for each variable were computed from the ten measured areas. In addition, confocal microscopic examination was performed on 100 μm sections. We found that Ot.N/B.Ar, Tt.L.N/B.Ar, and Ot.N/Tt.L.N decreased, but EL.N/B.Ar increased significantly with age (p < 0.001). The rates of decline were most rapid initially, falling exponentially with increasing age; the linear regressions for all four variables were significant in premenopausal, but not postmenopausal, women. At all ages, there were significantly more osteocytes in superficial than in deep bone; there was no significant decline with age in superficial bone, but a steeper exponential decline in deep bone than in whole trabeculae. DEV did not change with age for any variable. Confocal images revealed that the morphology of the osteocyte network was heterogeneous in different regions and trabeculae. The trabeculae with lower osteocyte density contained acellular areas, especially in interstitial bone. We conclude: (1) osteocyte density declines with age in women as it does in men; (2) the decline occurs exclusively in deep bone, not in superficial bone, suggesting that it is the age of the bone rather than the age of the subject that is important; (3) the rate of age-related decline falls exponentially with age and is not significant in postmenopausal women alone; (4) except for the differences between superficial and deep bone, the pattern of osteocyte distribution within and between trabeculae was not affected by age or menopause; and (5) the data raise the possibility that one function of remodeling in iliac cancellous bone is to maintain osteocyte viability.

Keywords: Bone age; Bone remodeling
Links

DOI: 10.1016/S8756-3282(02)00819-0

PubMed: 12151084

WoS: 000177575600007
History

Received: 2001-12-12

Revised: 2002-03-28

Accepted: 2002-04-8

Cited Works (27)

Year	Entry
1990	Palumbo C, Palazzini S, Marotti G. Morphological study of intercellular junctions during osteocyte differentiation. Bone. 1990;11(6):401-406.
1997	Han Z-H, Palnitkar S, Rao DS, Nelson D, Parfitt AM. Effects of ethnicity and age or menopause on the remodeling and turnover of iliac bone: implications for mechanisms of bone loss. J Bone Miner Res. April 1997;12(4):498-508.
1993	Parfitt AM. Bone age, mineral density, and fatigue damage. Calcif Tiss Int. February 1993;53(suppl 1):S82-S86.
1995	Schaffler MB, Choi K, Milgrom C. Aging and matrix microdamage accumulation in human compact bone. Bone. December 1995;17(6):521-525.
1963	Frost HM. Bone Remodelling Dynamics. Springfield, IL: Charles C. Thomas; 1963.
1960	Frost HM. Presence of microscopic cracks in vivo in bone. Henry Ford Hosp Med Bull. 1960;8(1):25-35.
1990	Palumbo C, Palazzini S, Zaffe D, Marotti G. Osteocyte differentiation in the tibia of newborn rabbit: an ultrastructural study of the formation of cytoplasmic processes. Acta Anat. 1990;137(4):350-358.
1983	Rao DS. Practical approach to bone biopsy. In: Recker RR, ed. Bone Histomorphometry: Techniques and Interpretation. Boca Raton, FL: Inc., CRC Press; 1983:3-11.
2000	Parfitt AM, Travers R, Rauch F, Glorieux FH. Structural and cellular changes during bone growth in healthy children. Bone. October 2000;27(4):487-494.
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.
1960	Frost HM. Micropetrosis. J Bone Joint Surg. January 1960;42A(1):144-150.
1960	Frost HM. In vivo osteocyte death. J Bone Joint Surg. January 1960;42A(1):138-143.
2000	Vashishth D, Verborgt O, Divine G, Schaffler MB, Fyhrie DP. Decline in osteocyte lacunar density in human cortical bone is associated with accumulation of microcracks with age. Bone. April 2000;26(4):375-380.
2000	Martin RB. Toward a unifying theory of bone remodeling. Bone. January 2000;26(1):1-6.
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.
1994	Aarden EM, Burger EH, Nijweide PJ. Function of osteocytes in bone. J Cell Biochem. July 1994;55(3):287-299.
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	Dunstan CR, Somers NM, Evans RA. Osteocyte death and hip fracture. Calcif Tiss Int. February 1993;53(1):S113-S117.
1996	Han Z, Palnitkar S, Rao DS, Nelson D, Parfitt AM. Effect of ethnicity and age or menopause on the structure and geometry of iliac bone. J Bone Miner Res. December 1996;11(12):1967-1975.
1995	Klein-Nulend J, van der Plas A, Semeins CM, Ajubi NE, Frangos JA, Nijweide PJ, Burger EH. Sensitivity of osteocytes to biomechanical stress in vitro. FASEB J. March 1995;9(5):441-445.
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.
1998	Bentolila V, Boyce TM, Fyhrie DP, Drumb R, Skerry TM, Schaffler MB. Intracortical remodeling in adult rat long bones after fatigue loading. Bone. September 1998;23(3):275-281.
1997	Burr DB, Forwood MR, Fyhrie DP, Martin RB, Schaffler MB, Turner CH. Bone microdamage and skeletal fragility in osteoporotic and stress fractures. J Bone Miner Res. January 1997;12(1):6-15.
1990	Marotti G, Cane V, Palazzini S, Palumbo C. Structure-function relationships in the osteocyte. Ital J Min Electrol Metabol. 1990;4(2):93-106.
2000	Noble BS, Reeve J. Osteocyte function, osteocyte death and bone fracture resistance. Mol Cell Endocrinol. January 25, 2000;159(1-2):7-13.
1996	Mullender MG, van der Meer DD, Huiskes R, Lips P. Osteocyte density changes in aging and osteoporosis. Bone. February 1996;18(2):109-113.
1996	Mullender MG, Huiskes R, Versleyen H, Buma P. Osteocyte density and histomorphometric parameters in cancellous bone of the proximal femur in five mammalian species. J Orthop Res. November 1996;14(6):972-979.

Cited By (25)

Year	Entry
2004	Hernandez CJ, Majeska RJ, Schaffler MB. Osteocyte density in woven bone. Bone. November 2004;35(5):1095-1099.
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.
2010	Schneider P, Meier M, Wepf R, Müller R. Towards quantitative 3d imaging of the osteocyte lacuno-canalicular network. Bone. November 2010;47(5):848-858.
2013	Carter Y, Thomas CDL, Clement JG, Peele AG, Hannah K, Cooper DM. Variation in osteocyte lacunar morphology and density in the human femur: a synchrotron radiation micro-CT study. Bone. January 2013;52(1):126-132.
2015	Goff MG, Lambers FM, Nguyen TM, Sung J, Rimnac CM, Hernandez CJ. Fatigue-induced microdamage in cancellous bone occurs distant from resorption cavities and trabecular surfaces. Bone. October 2015;79:8-14.
2019	Tiede-Lewis LM, Dallas SL. Changes in the osteocyte lacunocanalicular network with aging. Bone. May 2019;122:101-113.
2022	Goff E, Cohen A, Shane E, Recker RR, Kuhn G, Müller R. Large-scale osteocyte lacunar morphological analysis of transiliac bone in normal and osteoporotic premenopausal women. Bone. July 1, 2022;160:116424.
2014	Bellido T. Osteocyte-driven bone remodeling. Calcif Tiss Int. January 2014;94(1):25-34.
2007	Tatsumi S, Ishii K, Amizuka N, Li M, Kobayashi T, Kohno K, Ito M, Takeshita S, Ikeda K. Targeted ablation of osteocytes induces osteoporosis with defective mechanotransduction. Cell Metab. June 2007;5(6):464-475.
2020	Milovanovic P, Busse B. Phenomenon of osteocyte lacunar mineralization: indicator of former osteocyte death and a novel marker of impaired bone quality? Endocr Connect. April 2020;9(4):R70-R80.
2004	McCreadie BR, Hollister SJ, Schaffler MB, Goldstein SA. Osteocyte lacuna size and shape in women with and without osteoporotic fracture. J Biomech. April 2004;37(4):563-572.
2003	Qiu S, Rao DS, Palnitkar S, Parfitt AM. Reduced iliac cancellous osteocyte density in patients with osteoporotic vertebral fracture. J Bone Miner Res. September 2003;18(9):1657-1663.
2022	Buettmann EG, Goldscheitter GM, Hoppock GA, Friedman MA, Suva LJ, Donahue HJ. Similarities between disuse and age-induced bone loss. J Bone Miner Res. August 2022;37(8):1417-1434.
2015	Goff M. The Role of Micro and Ultra-Structure in Microdamage Accumulation in Cancellous Bone [PhD thesis]. Ithaca, NY: Cornell University; August 2015.
2022	Goff E. Osteocyte Lacunar Biomarkers in Human Rare Bone Diseases [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2022.
2019	Davis HM. Molecular Mechanisms Underlying Osteocyte Apoptosis and the Associated Osteoclastogenesis in Cx43-Deficiency and Aging [PhD thesis]. Indiana University – Purdue University Indianapolis (IUPUI); June 2019.
2017	Hemmatian H. Does the Osteocyte Lacuna Affect Bone Adaptive Response in Aging? [PhD thesis]. Katholieke Universiteit Leuven; December 2017.
2008	Herman BC. Osteocytes and Activation of Bone Remodeling [PhD thesis]. Mount Sinai School of Medicine; 2008.
2015	Hunter RL. Variation in Cortical Osteocyte Lacunar Density and Distribution: Implications for Bone Quality Assessment [PhD thesis]. The Ohio State University; 2015.
2013	Bart ZR. Multi-Scale Analysis of Morphology, Mechanics, and Composition of Collagen in Murine Osteogenesis Imperfecta [Master's thesis]. Indianapolis, IN: Purdue University; August 2013.
2005	Ruimerman R. Modeling and Remodeling in Bone Tissue [PhD thesis]. Eindhoven University of Technology; 2005.
2022	Davis RA. Investigating the Effects of Aging and Prolonged Opioid Use on Bone Histomorphometry, Quality, and Biomechanics [PhD thesis]. University of Akron; August 2022.
2010	Hughes JM. Revisiting Harold Frost's Mechanostat Theory of Bone Functional Adaptation: New Interpretations Based on New Evidence [PhD thesis]. University of Minnesota; December 2010.
2014	Carter Y. Quantitative Imaging of Sex and Age Differences in Human Cortical Bone Osteocyte Lacunae [PhD thesis]. University of Saskatchewan; July 2014.
2016	Andronowski JM. Evaluating Differential Nuclear DNA Yield Rates Among Human Bone Tissue Types: A Synchrotron Micro-CT Approach [PhD thesis]. Knoxville, University of Tennessee; May 2016.