Document Type
Article
Publication Date
2014
Publication Title
Journal of Biomechanical Engineering
Abstract
Tears on the bursal and articular sides of the rotator cuff tendons are known to behave differently and strain is thought to play a role in this difference. This study investigates the effect of tear location on the changes in three strain measurements (grip-to-grip, insertion, and mid-substance tissue) in a sheep infraspinatus tendon model during axial loading. We introduced a 14mm wide defect near the insertion from either the articular or bursal side of the tendon to three depths (3 mm, 7mm & full) progressively. For each condition, tendons were sinusoidally stretched (4% at 0.5 Hz) while insertion and midsubstance strains were tracked with surface markers. For a fixed load, grip-to-grip strain increased significantly compared to intact for both cuts. Insertion strain increased significantly for the bursal-side defect immediately but not for the articular-side until the 66% cut. Mid-substance tissue strain showed no significant change for partial thickness articular-side defects and a significant decrease for bursal-side defects after the 66% cut. All full thickness cuts exhibited negligible mid-substance tissue strain change. Our results suggest that the tendon strain patterns are more sensitive to defects on the bursal side, and that partial thickness tears tend to induce localized strain concentrations in regions adjacent to the damaged tissue.
Keywords
tendon, mechanics, rotator cuff
Volume
136
Issue
5
DOI
10.1115/1.4026643
ISSN
1528-8951
Recommended Citation
Frisch, Kayt E.; Marcu, David; Baer, Geoffrey S.; Thelen, Darryl G.; and Vanderby, Ray, "The Influence of Partial and Full Thickness Tears on Infraspinatus Tendon Strain Patterns" (2014). Faculty Publications - Biomedical, Mechanical, and Civil Engineering. 81.
https://digitalcommons.georgefox.edu/mece_fac/81
Included in
Biomedical Engineering and Bioengineering Commons, Musculoskeletal System Commons, Sports Medicine Commons, Sports Sciences Commons
Comments
Originally published in the Journal of Biomechanical Engineering, May 1, 2014, Vol.136(5).
DOI: 10.1115/1.4026643