A Novel Treatment for Anterior Shoulder Instability: A Biomechanical Comparison between a Patient-Specific Implant and the Latarjet Procedure

Publication date

2019-07-17

Authors

Willemsen, K.ORCID 0000-0002-8237-6321
Berendes, Thomas D.
Geurkink, Timon
Bleys, Ronald L A WISNI 0000000050357498
Leeflang, Marius A.
Weinans, HarrieORCID 0000-0002-2275-6170ISNI 0000000393288658
Castelein, RMISNI 0000000392339484
Nelissen, Rob G.H.H.
van der Wal, Bart C.H.

Editors

Advisors

Supervisors

Document Type

Article

Collections

Open Access logo

License

cc_by_nc_nd

Abstract

Anterior glenohumeral instability with >20% glenoid bone loss is a disorder that can be treated with the Latarjet stabilizing procedure; however, complications are common. The purposes of this study were to (1) evaluate the effect of an anatomic-specific titanium implant produced by 3-dimensional (3D) printing as a treatment option for recurrent shoulder instability with substantial glenoid bone loss and (2) compare the use of that implant with the Latarjet procedure.Methods:Ten fresh-frozen cadaveric shoulders (mean age at the time of death, 78 years) were tested in a biomechanical setup with the humerus in 30° of abduction and in neutral rotation. The shoulders were tested under 5 different conditions: (1) normal situation, (2) creation of an anterior glenoid defect, (3) implantation of an anatomic-specific titanium implant produced by 3D printing, and the Latarjet procedure (4) with and (5) without 10 N of load attached to the conjoined tendon. In each condition, the humerus was translated 10 mm anteriorly relative to the glenoid, and the maximum peak translational force that was necessary for this translation was measured.Results:After creation of the glenoid defect, the mean translational peak force decreased by 30% ± 6% compared with that for the normal shoulder. After restoration of the original glenoid anatomy, the translational force needed to dislocate the humeral head from the glenoid significantly increased compared with that in the defect condition - to 119% ± 16% of normal (p < 0.01) with the 3D-printed anatomic-specific implant and to 121% ± 48% of normal (p < 0.01) following the Latarjet procedure. No significant differences in mean translational force were found between the anatomic-specific implant and the Latarjet procedure (p = 0.72).Conclusions:The mean translational peak force needed to dislocate the humerus 10 mm anteriorly on the glenoid was higher after glenoid restoration with the 3D-printed anatomic-specific implant compared with when the glenoid had a 20% surface defect but also compared with when the glenoid was intact. No differences in mean translational peak force were found between the 3D-printed anatomic-specific glenoid implant and the Latarjet procedure, although there was less variability in the 3D-implant condition.Clinical Relevance:Novel 3D-printing technology could provide a reliable patient-specific alternative to solve problems related to traditional treatment methods for shoulder instability.

Keywords

Surgery, Orthopedics and Sports Medicine

Citation

Willemsen, K, Berendes, T D, Geurkink, T, Bleys, R L A W, Leeflang, M A, Weinans, H, Castelein, R M, Nelissen, R G H H & Van Der Wal, B C H 2019, 'A Novel Treatment for Anterior Shoulder Instability : A Biomechanical Comparison between a Patient-Specific Implant and the Latarjet Procedure', Journal of Bone and Joint Surgery - American Volume, vol. 101, no. 14, e68. https://doi.org/10.2106/JBJS.18.00892