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Abstract

Background

In a reverse total shoulder arthroplasty, the altered glenohumeral joint center of rotation subjects the glenoid baseplate to increased shear forces and potential loosening.

Methods

This study examined glenoid baseplate micromotion and initial fixation strength with the application of direct shear force in a Sawbone model. The reverse total shoulder arthroplasty systems examined were the DJO Reverse® Shoulder Prosthesis, the Exactech Equinoxe® Reverse System, and the Tornier Aequalis^TM Reverse Shoulder Prosthesis. Specimens were cyclically tested with increasing shear loads until 150 µm of displacement between the implant and glenoid was achieved, and subsequently until failure, classified as either 1 cm of implant/glenoid displacement or fracture.

Results

The average load withstood for the 150 µm threshold for DJO, Tornier, and Exactech was 460 ± 88 N, 525 ± 100 N, and 585 ± 160 N, respectively. The average total load at device failure for DJO, Tornier, and Exactech was 980 ± 260 N, 1260 ± 120 N, and 1350 ± 230 N, respectively.

Discussion

The Exactech implant design trended toward requiring more load to induce micromotion at each threshold and to induce device failure, most commonly seen as inferior screw pull out. This study proposes design features that may enhance fixation and suggests little risk of initial micromotion or failure during initial post-operative recovery.

Keywords

Baseplate loosening implant failure shoulder rehabilitation compressive forces

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References

Farshad

Gerber

. Reverse total shoulder arthroplasty – from the most to the least common complication. Int Orthop 2010; 34: 1075–1082.

Ackland

Patel

Knox

. Prosthesis design and placement in reverse total shoulder arthroplasty. J Orthop Surg Res 2015; 10: 1–9.

Zumstein

Pinedo

Old

, et al. Problems, complications, reoperations, and revisions in reverse total shoulder arthroplasty: a systematic review. J Shoulder Elbow Surg 2011; 20: 146–157.

Cheung

Willis

Walker

, et al. Complications in reverse total shoulder arthroplasty. J Am Acad Orthop Surg 2011; 19: 439–449.

Russo

Della

Ciccarelli

, et al. Analysis of complications of reverse total shoulder arthroplasty. Joints 2015; 3: 62–66.

Wierks

Skolasky

, et al. Reverse total shoulder srthroplasty: Intraoperative and early postoperative complications. Clin Orthop Relat Res 2009; 467: 225–234.

Pilliar

Lee

Maniatopoulos

. Observations on the effect of movement on bone ingrowth into porous-surfaced implants. Clin Orthop Relat Res 1996; 208: 108–113.

Jasty

Bragdon

Burke

, et al. In vivo skeletal responses to porous-surfaced implants subjected to small induced motions. J Bone Joint Surg Am 1997; 79: 707–714.

Virani

Harman

, et al. In vitro and finite element analysis of glenoid bone/baseplate interaction in the reverse shoulder design. J Shoulder Elbow Surg 2008; 17: 509–521.

10.

Ackland

Roshan-Zamir

Richardson

, et al. Muscle and joint-contact loading at the glenohumeral joint after reverse total shoulder arthroplasty. J Orthop Res 2011; 29: 1850–1858.

11.

Chebli

Huber

Watling

, et al. Factors affecting fixation of the glenoid component of a reverse total shoulder prothesis. J Shoulder Elbow Surg 2008; 17: 323–327.

12.

Ackland

Thomas

, et al. Muscle and joint function after anatomic and reverse total shoulder arthroplasty using a modular shoulder prosthesis. J Orthop Res 2019; 37: 1988–2003.

13.

Boudreau

DPTED

Higgins

, et al. Rehabilitation following reverse total shoulder arthroplasty. J Orthop Sport Phys Ther 2007; 37: 734–743.

14.

Roche

Stroud

Flurin

, et al. Reverse shoulder glenoid baseplate fixation: a comparison of flat-back versus curved-back designs and oval versus circular designs with 2 different offset glenospheres. J Shoulder Elbow Surg 2014; 23: 1388–1394.

15.

Stroud

DiPaola

Flurin

, et al. Reverse shoulder glenoid loosening: an evaluation of the initial fixation associated with six different reverse shoulder designs. Bull Hosp Jt Dis 2013; 71: S12–S17.

16.

Kenter

Marchek

Dines

, et al. An analysis of shear forces comparing different glenoid designs and cement techniques. J Shoulder Elbow Surg 1998; 7: 315–316.

17.

Escamilla

Yamashiro

Paulos

, et al. Shoulder muscle activity and function in common shoulder rehabilitation exercises. Sport Med 2009; 39: 663–685.

18.

Elfar

Menorca

RMG

Reed

, et al. Composite bone models in orthopaedic surgery research and education. J Am Acad Orthop Surg 2014; 22: 111–120.

19.

Windell

Kulkarni

Alabort

, et al. Biomechanical comparison of periprosthetic femoral fracture risk in three femoral components in a sawbone model. J Arthroplasty 2021; 36: 387–394.

Assessment of glenoid baseplate initial micromotion and fixation strength in reverse total shoulder arthroplasty designs using a direct shear force methodology

Abstract

Background

Methods

Results

Discussion

Keywords

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References