Posterior stability of the shoulder depends on acromial anatomy: a biomechanical study of 3D surface models

Bettina Hochreiter; Silvan Beeler; Simon Hofstede; Bastian Sigrist; Jess G. Snedeker; Christian Gerber

doi:10.1186/s40634-023-00623-x

Journal of Experimental Orthopaedics (Jan 2023)

Posterior stability of the shoulder depends on acromial anatomy: a biomechanical study of 3D surface models

Bettina Hochreiter,
Silvan Beeler,
Simon Hofstede,
Bastian Sigrist,
Jess G. Snedeker,
Christian Gerber

Affiliations

Bettina Hochreiter: Department of OrthopaedicsUniversity of ZurichBalgrist University HospitalZurichSwitzerland
Silvan Beeler: Department of OrthopaedicsUniversity of ZurichBalgrist University HospitalZurichSwitzerland
Simon Hofstede: Department of OrthopaedicsBiomechanical Research LaboratoryUniversity of ZurichBalgrist CampusZurichSwitzerland
Bastian Sigrist: Research in Orthopaedic Computer Science (ROCS)University of ZurichBalgrist University HospitalZurichSwitzerland
Jess G. Snedeker: Department of OrthopaedicsBiomechanical Research LaboratoryUniversity of ZurichBalgrist CampusZurichSwitzerland
Christian Gerber: Department of OrthopaedicsUniversity of ZurichBalgrist University HospitalZurichSwitzerland

DOI: https://doi.org/10.1186/s40634-023-00623-x
Journal volume & issue: Vol. 10, no. 1
pp. n/a – n/a

Abstract

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Abstract Purpose Primary glenohumeral osteoarthritis is commonly associated with static posterior subluxation of the humeral head. Scapulae with static/dynamic posterior instability feature a superiorly and horizontally oriented acromion. We investigated whether the acromion acts as a restraint to posterior humeral translation. Methods Five three‐dimensional (3D) printed scapula models were biomechanically tested. A statistical shape mean model (SSMM) of the normal scapula of 40 asymptomatic shoulders was fabricated. Next, a SSMM of scapular anatomy associated with posterior subluxation was generated using data of 20 scapulae (“B1”). This model was then used to generate three models of surgical correction: glenoid version, acromial orientation, and acromial and glenoid orientation. With the joint axially loaded (100N) and the humerus stabilized, an anterior translation force was applied to the scapula in 35°, 60° and 75° of glenohumeral flexion. Translation (mm) was measured. Results In the normal scapula, the humerus translates significantly less to contact with the acromion compared to all other configurations (p < .000 for all comparisons; i.e. 35°: “normal” 8,1 mm (± 0,0) versus “B1” 11,9 mm (± 0,0) versus “B1 Acromion Correction” 12,2 mm (± 0,2) versus “B1 Glenoid Correction” 13,3 mm (± 0,1)). Restoration of normal translation was only achieved with correction of glenoid and acromial anatomy (i.e. 75°: “normal” 11 mm (± 0,8) versus “B1 Acromion Correction” 17,5 mm (± 0,1) versus “B1 Glenoid Correction” 19,7 mm (± 1,3) versus “B1 Glenoid + Acromion Correction” 11,5 mm (± 1,1)). Conclusions Persistence or recurrence of static/dynamic posterior instability after correction of glenoid version alone may be related to incomplete restoration of the intrinsic stability that is conferred by a normal acromial anatomy. Level of Evidence V biomechanical study

Published in Journal of Experimental Orthopaedics

ISSN: 2197-1153 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Medicine: Surgery: Orthopedic surgery
Website: https://esskajournals.onlinelibrary.wiley.com/journal/21971153

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