Non-enzymatic glycation alters microdamage formation in human cancellous bone

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Tang, S. Y.^1,2; Vashishth, D.¹

Non-enzymatic glycation alters microdamage formation in human cancellous bone

Bone. January 2010;46(1):148-154

©2009 Published by Elsevier Inc.

Affiliations

¹Department of Biomedical Engineering, Center for Biotechnology and Interdisciplinary Studies, Rensselaer Polytechnic Institute, Troy, NY 12180, USA

²Current address: Department of Orthopedic Surgery, School of Medicine, University of California, San Francisco. San Francisco, CA, USA
Abstract and keywords

Introduction: The accumulation of advanced glycation end-products (AGEs) in bone has been suggested to adversely affect the fracture resistance of bone with aging, diabetes, and pharmacological treatments. The formation of AGEs increases crosslinking in the organic matrix of bone but it is unknown how elevated levels of AGEs affect the mechanisms of fracture resistance such as microdamage formation.

Methods: Human tibial cancellous bone cores were subjected to non-enzymatic glycation (NEG) by in vitro ribosylation and were mechanically loaded to pre- (0.6%) and post- (1.1%) yield apparent level strains. Loaded specimens were stained with lead–uranyl acetate and subjected to microCT-based 3D quantification and characterization of microdamage as either diffuse damage and linear microcracks. Damaged volume per bone volume (DV/BV) and damaged surface per damaged volume (DS/DV) ratios were used to quantify the volume and morphology of the detected microdamage, respectively.

Results: In vitro ribosylation increased the microdamage morphology parameter (DS/DV) under both pre- (p < 0.05; + 51%) and post-yield loading (p < 0.001; + 38%), indicating that the alteration of bone matrix by NEG caused the formation of crack-like microdamage morphologies. Under post-yield loading, the NEG-mediated increase in DS/DV was coupled with the reductions in microdamage formation (DV/BV; p < 0.001) and toughness (p < 0.001).

Discussion: Using a novel microCT technique to characterize and quantify microdamage, this study shows that the accumulation of AGEs in the bone matrix significantly alters the quantity and morphology of microdamage production and results in reduced fracture resistance.

Keywords: Non-enzymatic glycation; Advanced glycation end-products; Microdamage; microCT; Biomechanics; Bone; Diabetes
Links

DOI: 10.1016/j.bone.2009.09.003

PubMed: 19747573

WoS: 000274129400017
History

Received: 2009-03-10

Revised: 2009-07-25

Accepted: 2009-09-03

Online: 2009-09-09

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