Structural differences between “dark” and “bright” isolated human osteonic lamellae

Ascenzi, Maria-Grazia; Ascenzi, Antonio; Benvenuti, Alessandro; Burghammer, Manfred; Panzavolta, Silvia; Bigid, Adriana

Affiliations

¹Department of Orthopaedic Surgery, Biomechanics Research Division, University of California at Los Angeles, Los Angeles, CA, USA

²Department of Biopathology, University of Rome, ‘‘La Sapienza’’, Rome, Italy

³European Synchrotron Radiation Facility, Grenoble, France

⁴Department of Chemistry ‘‘G. Ciamician’’, University of Bologna, via Selmi 2, Bologna IT-40126, Italy

Abstract and keywords

This investigation presents new insights into the structure of human secondary lamellae. Lamellar specimens that appear dark and bright on alternate osteon transverse sections under circularly polarizing light were isolated using a new technique, and examined by polarizing light microscopy, synchrotron X-ray diffraction, and confocal microscopy. A distribution of unidirectional collagen bundles and of two overlapping oblique bundles appears on circularly polarizing light microscopy images in relation to the angle between the specimen and the crossed Nicols’ planes. The unidirectional collagen bundles observed at 45° run parallel to the osteon axis in the dark lamellar specimens and perpendicular to it in the bright ones. Small and wide-angle micro-focus X-ray diffraction indicates that the dark lamellae are structurally quite homogeneous, with collagen fibers and apatite crystals preferentially oriented parallel to the osteon axis. Bright lamellar specimens exhibit different orientation patterns with the dominant ones bidirectional at ±45° with respect to the osteon axis. Accordingly, confocal microscopy evidences the presence of longitudinal bundles in dark lamellar specimens and oblique bundles in the bright ones. Radial bundles are evidenced in both lamellar types. The alternate osteon structure is described by a rather continuous multidirectional pattern, in which dark and bright lamellae display different mechanical and possibly biological functions.

Keywords: Bone; Collagen; Confocal microscopy; Lamellae; Plywood structure; Polarizing light; Secondary osteon; Synchrotron radiation; X-ray microdiffraction

Links

DOI: 10.1016/S1047-8477(02)00578-6

PubMed: 12576017

WoS: 000181289600003

History

Received: 2002-07-12

Revised: 2002-10-14

Cited Works (17)

Year	Entry
1967	Ascenzi A, Bonucci E. The tensile properties of single osteons. Acta Anat. 1967;158(4):375-386.
1968	Ascenzi A, Bonucci E. The compressive properties of single osteons. Anat Rec. July 1968;161(3):377-392.
1988	Ascenzi A. The micromechanics versus the macromechanics of cortical bone: a comprehensive presentation. J Biomech Eng. November 1988;110(4):357-363.
1952	Amprino R, Engström A. Studies on x-ray absorption and diffraction of bone tissue. Acta Anat. 1952;15(1-2):1-22.
1969	Boyde A, Hobdell MH. Scanning electron microscopy of lamellar bone. Z Zellforsch. 1969;93(2):213-231.
1997	Weiner S, Arad T, Sabanay I, Traub. W. Rotated plywood structure of primary lamellar bone in the rat: orientations of the collagen fibril arrays. Bone. June 1997;20(6):509-514.
1996	Fratzl P, Schreiber S, Klaushofer K. Bone mineralization as studied by small-angle x-ray scattering. Connect Tissue Res. 1996;34(4):247-254.
1986	Reid SA. A study of lamellar organisation in juvenile and adult human bone. Anat Embryol. 1986;174(3):329-338.
1982	Ascenzi A, Benvenuti A, Bonucci E. The tensile properties of single osteonic lamellae: technical problems and preliminary results. J Biomech. 1982;15(1):29-37.
1986	Ascenzi A, Benvenuti A. Orientation of collagen fibers at the boundary between two successive osteonic lamellae and its mechanical interpretation. J Biomech. 1986;19(6):455-463.
1973	Ascenzi A, Bonucci E, Simkin A. An approach to the mechanical properties of single osteonic lamellae. J Biomech. May 1973;6(3):227-235.
1947	Ruth EB. Bone studies, I: fibrillar structure of adult human bone. Am J Anat. January 1947;80(1):35-53.
1988	Giraud-Guille MM. Twisted plywood architecture of collagen fibrils in human compact bone osteons. Calcif Tiss Int. May 1988;42(3):167-180.
1960	Smith JW. The arrangement of collagen fibres in human secondary osteones. J Bone Joint Surg. August 1960;42B(3):588-605.
1976	Ascenzi A, Bonucci E, Benvenuti A. Relationship between ultrastructure and “pin test” in osteons. Clin Orthop Relat Res. November–December 1976;121:275-294.
1990	Ascenzi A, Baschieri P, Benvenuti A. The bending properties of single osteons. J Biomech. 1990;23(8):763-771.
1994	Ascenzi A, Baschieri P, Benvenuti A. The torsional properties of single selected osteons. J Biomech. July 1994;27(7):875-884.

Cited By (29)

Year	Entry
2011	Ferguson VL, Olesiak SE. Nanoindentation of bone. In: Oyen ML, ed. Handbook of Nanoindentation With Biological Applications. Singapore: Pan Stanford Publishing Pte. Ltd; 2011:185-237.
2014	Reznikov N, Shahar R, Weiner S. Bone hierarchical structure in three dimensions. Acta Biomater. September 2014;10(8):3815-3826.
2021	Smit TH. Closing the osteon: do osteocytes sense strain rate rather than fluid flow? BioEssays. August 2021;43(8):2000327.
2006	Wagermaier W, Gupta HS, Gourrier A, Burghammer M, Roschger P, Fratzl P. Spiral twisting of fiber orientation inside bone lamellae. Biointerphases. March 2006;1(1):1-5.
2013	Reznikov N, Almany-Magal R, Shahar R, Weiner S. Three-dimensional imaging of collagen fibril organization in rat circumferential lamellar bone using a dual beam electron microscope reveals ordered and disordered sub-lamellar structures. Bone. February 2013;52(2):676-683.
2014	Reznikov N, Shahar R, Weiner S. Three-dimensional structure of human lamellar bone: the presence of two different materials and new insights into the hierarchical organization. Bone. February 2014;59:93-104.
2015	Tang T, Ebacher V, Cripton P, Guy P, McKay H, Wang R. Shear deformation and fracture of human cortical bone. Bone. February 2015;71:25-35.
2015	Zimmermann EA, Busse B, Ritchie RO. The fracture mechanics of human bone: influence of disease and treatment. BoneKEy Rep. September 2015;4:743.
2015	Stock SR. The mineral–collagen interface in bone. Calcif Tiss Int. September 2015;97(3):262-280.
2020	Maghsoudi-Ganjeh M, Wang X, Zeng X. Nanomechanics and ultrastructure of bone: a review. Comput Model Eng Sci. 2020;125(1):1-32.
2006	Bigley RF, Griffin LV, Christensen L, Vandenbosch R. Osteon interfacial strength and histomorphometry of equine cortical bone. J Biomech. 2006;39(9):1629-1640.
2011	Dong XN, Almer JD, Wang X. Post-yield nanomechanics of human cortical bone in compression using synchrotron X-ray scattering techniques. J Biomech. February 24, 2011;44(4):676-682.
2009	Franzoso G, Zysset PK. Elastic anisotropy of human cortical bone secondary osteons measured by nanoindentation. J Biomech Eng. February 2009;131(2):021001.
2016	Georgiadis M, Müller R, Schneider P. Techniques to assess bone ultrastructure organization: orientation and arrangement of mineralized collagen fibrils. J R Soc Interface. June 1, 2016;13(119):20160088.
2006	Kazanci M, Roschger P, Paschalis EP, Klaushofer K, Fratzl P. Bone osteonal tissues by Raman spectral mapping: orientation–composition. J Struct Biol. December 2006;156(3):489-496.
2016	Georgiadis M, Guizar-Sicairos M, Gschwend O, Hangartner P, Bunk O, Müller R, Schneider P. Ultrastructure organization of human trabeculae assessed by 3D sSAXS and relation to bone microarchitecture. PLoS One. August 22, 2016;11(8):e0159838.
2018	Imbert L, Gourion-Arsiquaud S, Villarreal-Ramirez E, Spevak L, Taleb H, van der Meulen MCH, Mendelsohn R, Boskey AL. Dynamic structure and composition of bone investigated by nanoscale infrared spectroscopy. PLoS One. September 4, 2018;11(9):e0202833.
2011	Zimmermann EA, Schaible E, Bale H, Barth HD, Tang SY, Reichert P, Busse B, Alliston T, Ager JW III, Ritchie RO. Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales. Proc Natl Acad Sci USA. August 30, 2011;108(35):14416-14421.
2005	Yoon YJ. Estimates of Bone Elastic Constants At Sequential Hierarchical Levels [PhD thesis]. New York, NY: The City University of New York; 2005.
2012	Pacureanu AJ. Imaging the Bone Cell Network With Nanoscale Synchrotron Computed Tomography [PhD thesis]. Institut national des sciences appliquées de Lyon (INSA Lyon); 2012.
2012	Jimenez Palomar I. Mechanical Properties of Bone At the Sub-lamellar Level [PhD thesis]. London, England: Queen Mary University of London; September 2012.
2006	Gleeson JP. Composition and Mechanical Properties of Osteoarthritic Subchondral Trabecular Tibial Bone [PhD thesis]. Trinity College Dublin; November 2006.
2011	Reisinger AG. Modeling and Validation of Multiscale Lamellar Bone Elasticity [PhD thesis]. Vienna University of Technology; November 2011.
2011	Spiesz EM. Experimental and Computational Micromechanics of Mineralized Tendon and Bone [PhD thesis]. Vienna University of Technology; October 2011.
2018	Tang T. Fracture Mechanisms and Structural Fragility of Human Femoral Cortical Bone [PhD thesis]. Vancouver, BC: University of British Columbia; April 2018.
2011	Raghavan M. Investigation of Mineral and Collagen Organization in Bone Using Raman Spectroscopy [PhD thesis]. University of Michigan; 2011.
2010	Beckstrom AB. Histologic and Geometric Data Challenge the Assumption of Habitual Superior-Inferior (tension-Compression) Bending Across the Chimpanzee Proximal Femur [Master's thesis]. University of Utah; August 2010.
2012	Banglmaier RF. Enhancing the Mechanical Properties of a Hydroxyapatite-Collagen Bone Surrogate [PhD thesis]. Detroit, MI: Wayne State University; August 2012.
2014	Reznikov N. The Adaptation of Mechanical Properties of Lamellar Bone Tissue [PhD thesis]. Weizmann Institute of Science; July 2014.