Characterization of the structure-function relationship at the ligament-to-bone interface

Soft tissues such as ligaments and tendons integrate with bone through a fibrocartilaginous interface divided into noncalcified and calcified regions. This junction between distinct tissue types is frequently injured and not reestablished after surgical repair. Its regeneration is also limited by a...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2008-06, Vol.105 (23), p.7947-7952
Main Authors: Moffat, Kristen L, Sun, Wan-Hsuan S, Pena, Paul E, Chahine, Nadeen O, Doty, Stephen B, Ateshian, Gerard A, Hung, Clark T, Lu, Helen H
Format: Article
Language:English
Subjects:
Animals
Anterior Cruciate Ligament - metabolism
Anterior Cruciate Ligament - ultrastructure
Biological Sciences
Biomechanical Phenomena
Bone and Bones - metabolism
Bone and Bones - ultrastructure
Bones
Calcification, Physiologic
Calcium - metabolism
Cartilage
Cattle
Collagens
Fibrocartilage
Fibrocartilage - metabolism
Ligaments
Mechanical properties
Microscopy, Electron, Scanning
Minerals
Phosphorus - metabolism
Resultants
Structure-Activity Relationship
Studies
Tendons
Tissue engineering
Tissues
Youngs modulus
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Summary:Soft tissues such as ligaments and tendons integrate with bone through a fibrocartilaginous interface divided into noncalcified and calcified regions. This junction between distinct tissue types is frequently injured and not reestablished after surgical repair. Its regeneration is also limited by a lack of understanding of the structure-function relationship inherent at this complex interface. Therefore, focusing on the insertion site between the anterior cruciate ligament (ACL) and bone, the objectives of this study are: (i) to determine interface compressive mechanical properties, (ii) to characterize interface mineral presence and distribution, and (iii) to evaluate insertion site-dependent changes in mechanical properties and matrix mineral content. Interface mechanical properties were determined by coupling microcompression with optimized digital image correlation analysis, whereas mineral presence and distribution were characterized by energy dispersive x-ray analysis and backscattered scanning electron microscopy. Both region- and insertion-dependent changes in mechanical properties were found, with the calcified interface region exhibiting significantly greater compressive mechanical properties than the noncalcified region. Mineral presence was only detectable within the calcified interface and bone regions, and its distribution corresponds to region-dependent mechanical inhomogeneity. Additionally, the compressive mechanical properties of the tibial insertion were greater than those of the femoral. The interface structure-function relationship elucidated in this study provides critical insight for interface regeneration and the formation of complex tissue systems.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0712150105