Biomechanical evaluation of a novel suturing scheme for grafting load-bearing collagen scaffolds for rotator cuff repair

Abstract Background Currently, there are no well-established suture protocols to attach fully load-bearing scaffolds which span tendon defects between bone and muscle for repair of critical sized tendon tears. Methods to attach load-bearing tissue repair scaffolds could enable functional repair of t...

Full description

Saved in:
Bibliographic Details
Published in:Clinical biomechanics (Bristol) 2015-08, Vol.30 (7), p.669-675
Main Authors: Islam, Anowarul, Bohl, Michael S, Tsai, Andrew G, Younesi, Mousa, Gillespie, Robert, Akkus, Ozan
Format: Article
Language:English
Subjects:
Animals
Biomechanical Phenomena
Collagen - therapeutic use
Collagen suture technique
Disease Models, Animal
Female
Infraspinatus tendon
Mechanical properties
Physical Medicine and Rehabilitation
Rabbits
Rotator Cuff - surgery
Rotator Cuff Injuries
Scaffold
Segmental rotator cuff defect
Strength
Suture Techniques
Tendon Injuries - surgery
Tissue Scaffolds
Weight-Bearing - physiology
Wound Healing - physiology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract Background Currently, there are no well-established suture protocols to attach fully load-bearing scaffolds which span tendon defects between bone and muscle for repair of critical sized tendon tears. Methods to attach load-bearing tissue repair scaffolds could enable functional repair of tendon injuries. Methods Sixteen rabbit shoulders were dissected (New Zealand white rabbits, 1 yr. old, female) to isolate the humeral–infraspinatus muscle complex. A unique suture technique was developed to allow for a 5 mm segmental defect in infraspinatus tendon to be replaced with a mechanically strong bioscaffold woven from pure collagen threads. The suturing pattern resulted in a fully load-bearing scaffold. The tensile stiffness and strength of scaffold repair were compared with intact infraspinatus and regular direct repair. Findings The failure load and displacement at failure of the scaffold repair group were 59.9 N (standard deviation, SD = 10.7) and 10.3 mm (SD = 2.9), respectively and matched those obtained by direct repair group which were 57.5 N (SD = 15.3) and 8.6 mm (SD = 1.5), ( p > 0.05). Failure load, displacement at failure and stiffness of both of the repair groups were half of the intact infraspinatus shoulder group. Interpretation With the developed suture technique, scaffold repair showed similar failure load, displacement at failure and stiffness to the direct repair. This novel suturing pattern and the mechanical robustness of the scaffold at time zero indicates that the proposed model is mechanically viable for future in vivo studies which has a higher potential to translate into clinical uses.
ISSN:0268-0033
1879-1271
DOI:10.1016/j.clinbiomech.2015.05.007