Three‐dimensional reconstruction of Haversian systems in human cortical bone using synchrotron radiation‐based micro‐CT:​ morphology and quantification of branching and transverse connections across age

Maggiano, Isabel S.; Maggiano, Corey M.; Clement, John G.; Thomas, C. David L.; Carter, Yasmin; Cooper, David M. L.

Affiliations

¹Department of Anatomy and Cell Biology, University of Saskatchewan, Saskatoon, SK, Canada

²Department of Anthropology, University of West Georgia, Carrollton, GA, USA

³Department of Anthropology, University of Western Ontario, London, ON, Canada

⁴Melbourne Dental School, University of Melbourne, Melbourne, Vic., Australia

⁵Department of Radiology, University of Massachusetts Medical School, Worchester, MA, USA

Abstract and keywords

This study uses synchrotron radiation‐based micro‐computed tomography (CT) scans to reconstruct three‐dimensional networks of Haversian systems in human cortical bone in order to observe and analyse interconnectivity of Haversian systems and the development of total Haversian networks across different ages. A better knowledge of how Haversian systems interact with each other is essential to improve understanding of remodeling mechanisms and bone maintenance; however, previous methodological approaches (e.g. serial sections) did not reveal enough detail to follow the specific morphology of Haversian branching, for example. Accordingly, the aim of the present study was to identify the morphological diversity of branching patterns and transverse connections, and to understand how they change with age. Two types of branching morphologies were identified: lateral branching, resulting in small osteon branches bifurcating off of larger Haversian canals; and dichotomous branching, the formation of two new osteonal branches from one. The reconstructions in this study also suggest that Haversian systems frequently target previously existing systems as a path for their course, resulting in a cross‐sectional morphology frequently referred to as ‘type II osteons’. Transverse connections were diverse in their course from linear to oblique to curvy. Quantitative assessment of age‐related trends indicates that while in younger human individuals transverse connections were most common, in older individuals more evidence of connections resulting from Haversian systems growing inside previously existing systems was found. Despite these changes in morphological characteristics, a relatively constant degree of overall interconnectivity is maintained throughout life. Altogether, the present study reveals important details about Haversian systems and their relation to each other that can be used towards a better understanding of cortical bone remodeling as well as a more accurate interpretation of morphological variants of osteons in cross‐sectional microscopy. Permitting visibility of reversal lines, synchrotron radiation‐based micro‐CT is a valuable tool for the reconstruction of Haversian systems, and future analyses have the potential to further improve understanding of various important aspects of bone growth, maintenance and health.

Keywords: ge; branching; cortical bone; Haversian system; micro-CT; osteon; synchrotron; three-dimensional

Links

DOI: 10.1111/joa.12430

PubMed: 26749084

PubMedCentral: PMC4831337

WoS: 000374979700001

History

Accepted: 2015-11-19

Online: 2016-01-07

Cited Works (21)

Year	Entry
2007	Schneider P, Stauber M, Voide R, Stampanoni M, Donahue LR, Müller R. Ultrastructural properties in cortical bone vary greatly in two inbred strains of mice as assessed by synchrotron light based micro‐ and nano‐CT. J Bone Miner Res. October 2007;22(10):1557-1570.
1994	Parfitt AM. Osteonal and hemi‐osteonal remodeling: the spatial and temporal framework for signal traffic in adult human bone. J Cell Biochem. July 1994;55(3):273-286.
1963	Frost HM. Bone Remodelling Dynamics. Springfield, IL: Charles C. Thomas; 1963.
1977	Tappen NC. Three‐dimensional studies of resorption spaces and developing osteons. Am J Anat. July 1977;149(3):301-331.
1969	Frost HM. Tetracycline-based histological analysis of bone remodeling. Calcif Tiss Res. 1969;3(1):211-237.
1998	Martin RB, Burr DB, Sharkey NA. Skeletal Tissue Mechanics. New York, NY: Springer-Verlag; 1998.
2001	Bell KL, Loveridge N, Reeve J, Thomas CDL, Feik SA, Clement JG. Super‐osteons (remodeling clusters) in the cortex of the femoral shaft: influence of age and gender. Anat Rec. December 1, 2001;264(4):378-386.
2002	Martin RB. Is all cortical bone remodeling initiated by microdamage? Bone. January 2002;30(1):8-13.
1994	Heřt J, Fiala P, Petrtýl M. Osteon orientation of the diaphysis of the long bones in man. Bone. May–June 1994;15(3):269-277.
1965	Kerley ER. The microscopic determination of age in human bone. Am J Phys Anthropol. 1965;23(2):149-163.
2005	Skedros JG, Holmes JL, Vajda EG, Bloebaum AD. Cement lines of secondary osteons in human bone are not mineral‐deficient: new data in a historical perspective. Anat Rec. September 2005;286A(1):781-803.
1972	Jaworski ZF, Meunier P, Frost HM. Observations on two types of resorption cavities in human lamellar cortical bone. Clin Orthop Relat Res. March–April 1972;83:279-285.
2011	Cooper DML, Erickson B, Peele AG, Hannah K, Thomas CDL, Clement JG. Visualization of 3D osteon morphology by synchrotron radiation micro-CT. J Anat. October 2011;219(4):481-489.
1995	Schaffler MB, Choi K, Milgrom C. Aging and matrix microdamage accumulation in human compact bone. Bone. December 1995;17(6):521-525.
2004	Cooper DML, Matyas JR, Katzenberg MA, Hallgrimsson B. Comparison of microcomputed tomographic and microradiographic measurements of cortical bone porosity. Calcif Tiss Int. May 2004;75(5):437-447.
2003	Cooper DML, Turinsky AL, Sensen CW, Hallgrímsson B. Quantitative 3D analysis of the canal network in cortical bone by micro-computed tomography. Anat Rec. September 2003;274B(1):169-179.
2002	Parfitt AM. Targeted and nontargeted bone remodeling: relationship to basic multicellular unit origination and progression. Bone. January 2002;30(1):5-7.
1958	Cohen J, Harris WH. The three-dimensional anatomy of Haversian systems. J Bone Joint Surg. April 1958;40A(2):419-434.
2007	Martin RB. Targeted bone remodeling involves BMU steering as well as activation. Bone. June 2007;40(6):1574-1580.
1993	Burr DB. Remodeling and the repair of fatigue damage. Calcif Tiss Int. February 1993;53(suppl 1):S75-S81.
1966	Cooper RR, Milgram JW, Robinson RA. Morphology of the osteon: an electron microscopic study. J Bone Joint Surg. October 1966;48A(7):1239-1271.

Cited By (20)

Year	Entry
2021	Smit TH. Closing the osteon: do osteocytes sense strain rate rather than fluid flow? BioEssays. August 2021;43(8):2000327.
2018	Andreasen CM, Delaisse J-M, van der Eerden BCJ, van Leeuwen JPTM, Ding M, Andersen TL. Understanding age-induced cortical porosity in women: is a negative BMU balance in quiescent osteons a major contributor? Bone. December 2018;117:70-82.
2020	Andreasen CM, Bakalova LP, Brüel A, Hauge EM, Kiil BJ, Delaisse J-M, Kersh ME, Thomsen JS, Andersen TL. The generation of enlarged eroded pores upon existing intracortical canals is a major contributor to endocortical trabecularization. Bone. January 2020;130:115127.
2022	Lamarche BA, Thomsen JS, Andreasen CM, Lievers WB, Andersen TL. 2D size of trabecular bone structure units (BSU) correlate more strongly with 3D architectural parameters than age in human vertebrae. Bone. July 2022;160:116399.
2023	Cooper DML, Harrison KD, Hiebert BD, King GA, Panahifar A, Zhu N, Swekla KJ, Pivonka P, Chapman LD, Arnason T. Daily administration of parathyroid hormone slows the progression of basic multicellular units in the cortical bone of the rabbit distal tibia. Bone. November 2023;176:116864.
2023	van Dijk Christiansen P, Andreasen CM, El-Masri BM, Laursen KS, Delaisse J-M, Andersen TL. Osteoprogenitor recruitment and differentiation during intracortical bone remodeling of adolescent humans. Bone. December 2023;177:116896.
2020	Toniolo I, Salmaso C, Bruno G, De Stefani A, Stefanini C, Gracco ALT, Carniel EL. Anisotropic computational modelling of bony structures from CT data: an almost automatic procedure. Comput Methods Prog Biomed. June 2020;189:105319.
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.
2018	Andreasen CM, Delaisse J, van der Eerden BCJ, van Leeuwen JPTM, Ding M, Andersen TL. Understanding age-induced cortical porosity in women: the accumulation and coalescence of eroded cavities upon existing intracortical canals is the main contributor. J Bone Miner Res. April 2018;33(4):606-620.
2018	Bakalova LP, Andreasen CM, Thomsen JS, Brüel A, Hauge E-M, Kiil BJ, Delaisse J-M, Andersen TL, Kersh ME. Intracortical bone mechanics are related to pore morphology and remodeling in human bone. J Bone Miner Res. December 2018;33(12):2177-2185.
2020	Obata Y, Bale HA, Barnard HS, Parkinson DY, Alliston T, Acevedo C. Quantitative and qualitative bone imaging: a review of synchrotron radiation microtomography analysis in bone research. J Mech Behav Biomed Mater. October 2020;110:103887.
2020	Andronowski JM, Davis RA, Holyoke CW. A sectioning, coring, and image processing guide for high-throughput cortical bone sample procurement and analysis for synchrotron micro-CT. JOVE. June 2020;160:e61081.
2019	Livingston E. Morphological and Mechanical Analysis of the Porous Structure of Cortical Bone [Master's thesis]. University of Illinois at Urbana-Champaign; 2019.
2022	van Dijk Christiansen P. The Relevance of Reversal Cells and Intermittent Parathyroid Hormone on the Duration of the Reversal-Resorption Phase in Intracortical Bone Remodeling Events [PhD thesis]. University of Southern Denmark (SDU); November 2022.
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.
2020	Loundagin LL. The Influence of Intracortical Microarchitecture on the Mechanical Fatigue of Bone [PhD thesis]. Calgary, AB: University of Calgary; July 2020.
2021	Arshad M. Modified Dental Composites for Bone Repair [PhD thesis]. University College London; 2021.
2018	Pratt I. Interpreting the 3D Orientation of Vascular Canals in Cortical Bone in Birds and Bats [PhD thesis]. University of Saskatchewan; September 2018.
2022	Sales EdS. The Spatio-Temporal Behavior of Basic Multicellular Units in a PTH-Induced Cortical Bone Remodeling Rabbit Model [Master's thesis]. University of Saskatchewan; August 2022.
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.