JSES International - 2026-05-01 - Journal Article
Teres minor circle and subscapularis lengthening patterns during forward elevation in lateralized reverse total shoulder arthroplasty.
Lante E, Blakeney WG, Bauer S
Topics
Key Takeaway
In lateralized rTSA, teres minor demonstrates a universal biphasic length-tension pattern with a median circle angle at 50° of forward elevation, occurring 26.9° earlier than the infraspinatus, supporting its unique role in external rotation at elevation.
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Summary
This study used 15 preoperative CT scans to generate 3D shoulder models simulating 4 lateralized rTSA configurations (Frankle-type and 3 inferiorly positioned baseplate variants with NSA 135°–155°) and computed muscle-tendon length changes for TM, SSC, ISP, and deltoid through 120° of forward elevation. TM was biphasic in 100% of simulations with a median circle angle of 50° [44–56], significantly earlier than ISP at 77° [71–83] (difference −26.9°, 95% CI −32.2 to −21.7), and exhibited greater curvature than all other muscles. SSC lengthened consistently across all 4 designs, while ISP was biphasic in 80%, SSC in 45%, and deltoid in 38% of simulations.
Key Limitation
The model excludes in vivo muscle activation, scapulothoracic rhythm, and postoperative soft tissue adaptation, limiting direct translation of length-tension predictions to functional outcomes.
Original Abstract
BACKGROUND
Lateralized reverse total shoulder arthroplasty (rTSA) designs aim to restore tension and function of the deltoid and remaining rotator cuff. Although the role of the subscapularis (SSC) is established in the native shoulder and after anatomic total shoulder arthroplasty, its repair after rTSA remains controversial. The teres minor (TM) is considered a principal contributor to external rotation in rTSA, particularly when the infraspinatus (ISP) is insufficient, yet its length-tension behavior across forward elevation has not been characterized.
METHODS
Fifteen preoperative computed tomography scans from patients undergoing rTSA were used to generate three-dimensional shoulder models. rTSA was simulated using 4 lateralized implant configurations differing in glenoid baseplate position and neck-shaft angle (NSA): (1) a Frankle-type configuration with a centrally positioned ("high") glenoid baseplate and a 135° NSA; (2) an inferiorly positioned (flush with the lower border of the glenoid) baseplate with a 135° NSA; (3) an inferiorly positioned baseplate with a 145° NSA; and (4) an inferiorly positioned baseplate with a 155° NSA. Forward elevation from 0° to 120° at 20° abduction and 0° rotation was analyzed. Muscle-tendon length changes were computed for TM, SSC, ISP, and deltoid. Outcomes included biphasic prevalence, circle angle (the forward-elevation angle at which muscle length transitions from shortening to lengthening), and curvature.
RESULTS
SSC consistently lengthened with forward elevation across all 4 lateralized rTSA designs. All TM curves (60/60, 100%) were biphasic, with early shortening followed by lengthening. The median TM circle angle occurred at 50° [44-56] and curvature was -0.015 (95% confidence interval -0.016 to -0.015). In comparison, ISP was biphasic in 80% (48/60), SSC in 45% (27/60), and deltoid in 38% (23/60). Median circle angles were 77° [71-83] for ISP, 38° [25-52] for SSC, and 33° [23-45] for deltoid. TM exhibited a significantly earlier circle angle than ISP (-26.9°, 95% confidence interval -32.2 to -21.7) and greater curvature than all other muscles. These patterns were preserved across 135°, 145°, and 155° designs.
CONCLUSION
This study confirms SSC lengthening during forward elevation across lateralized rTSA designs and describes a novel biphasic length-tension pattern of the TM circle. These findings provide a biomechanical rationale for SSC repair vulnerability and highlight the functional contribution of the TM to external rotation in elevated positions after rTSA.