Abdelhady et al 2015 1818. Abdelhady A, Abouelsoud M, Eid M. Latarjet procedure in patients with multiple recurrent anterior shoulder dislocation and generalized ligamentous laxity. Eur J Orthop Surg Traumatol. 2015;25(4):705-8. |
Prospective cohort |
13 (10 men/3 women) |
Latarjet open |
1) Hill-Sachs < 20% humeral head diameter; 2) Ligament hyperlaxity |
1) Lateral rotation in adduction |
Weak |
33.64 |
Abouelsoud and Abdelrahman 2015 2828. Abouelsoud MM, Abdelrahman AA. Recurrent anterior shoulder dislocation with engaging Hill-Sachs defect: remplissage or Latarjet? Eur Orthop Traumatol. 2015;6:151-6. |
Randomized controlled trial |
32 (no gender was mentioned) |
Latarjet open (16) x Remplissage (16) |
1) 3 episodes of dislocation in 12 months of conservative treatment; 2) Hill-Sachs 20-30% of the size of the humeral head on NMR |
1) Loss of lateral rotation in adduction |
Appendix 2 |
31.31 |
Ali et al. 2020 1919. Ali J, Altintas B, Pulatkan A, Boykin RE, Aksoy DO, Bilsel K. Open versus arthroscopic Latarjet procedure for the treatment of anterior glenohumeral instability with glenoid bone loss. Arthroscopy. 2020;36(4):940-9. |
Prospective cohort |
48 (open Latarjet: 12 Men/3 women; arthrsoscopic Latarjet: 29 men/4 women) |
Open Latarjet (15) x Arthroscopic Latarjet (33) |
1) > 18 years old; 2) Osteochondral glenoid defect > 13.5%; 3) ISIS > 3 combined to seizure in the intermediate range of motion |
Loss of: 1) Elevation; 2) Abduction; 3) Lateral rotation in abduction; 4) Medial rotation in abduction |
Weak |
30.5 |
Auffarth et al. 2008 2020. Auffarth A, Schauer J, Matis N, Kofler B, Hitzl W, Resch H. The J-bone graft for anatomical glenoid reconstruction in recurrent posttraumatic anterior shoulder dislocation. Am J Sports Med. 2008;36(4):638-47. |
Prospective cohort |
46 (40 men/6 women) |
Open Eden-Hybinette |
1) Glenoid defect > 5mm in length on AP and axial radiographs |
Loss of: 1) Elevation; 2) Abduction; 3) Lateral rotation in adduction; 4) Lateral rotation in abduction |
Weak |
90 |
Belangero et al. 2021 2929. Belangero PS, Lara PHS, Figueiredo EA, Andreoli CV, Pochini AC, Ejnisman B, Smith RL. Bristow versus Latarjet in high-demand athletes with anterior shoulder instability: a prospective randomized comparison. JSES Int. 2021;5(2):165-70. |
Randomized controlled trial |
41 (37 men/4 women) |
Open Latarjet (22) x Open Bristow (19) |
1) Competitive sport 2) 10-20% anterior glenoid wear (CT) |
1) Elevation; 2) Lateral rotation in adduction |
Appendix 2 |
60 |
Burkhart et al. 2007 1212. Burkhart SS, De Beer JF, Barth JRH, Cresswell T, Roberts C, Richards DP. Results of modified Latarjet reconstruction in patients with anteroinferior instability and significant bone loss. Arthroscopy. 2007;23(10):1033-41. |
Prospective cohort |
47 (46 men/1 woman) |
Open Latarjet |
1) Inverted pear glenoid; 2) Hill-Sachs with engaging |
1) Elevation; 2) Lateral rotation in adduction |
Weak |
52 |
Cautiero et al. 2017 3030. Cautiero F, Russo R, Di Pietto F, Sabino G. Computerized tomographic assessment and clinical evaluation in shoulder instability treated with the Latarje-Patte procedure using one screw and washer. Muscles Ligaments Tendons J. 2017;7(1):26-33. |
Prospective cohort |
26 (does not mention genders) |
Open Latarjet |
1) Glenoid bone loss > 15% (CT - PICO method); 2) Hill-Sachs > 1/3 humeral head diameter; 3) Competitive sport of contact or above the head; 4) HAGL injury; 5) Very thin capsular tissue |
Loss of: 1) Elevation; 2) Lateral rotation in adduction; 3) Medial rotation in adduction |
Weak |
53 |
Frank et al. 2018 2121. Frank RM, Romeo AA, Richardson C, Sumner S, Verma NN, Cole BJ, et al. Outcomes of Latarjet versus distal tibia allograft for anterior shoulder instability repair: a matched cohort analysis. Am J Sports Med. 2018;46(5):1030-8. |
Prospective cohort |
100 (96 men/4 women) |
Open Latarjet (50) x Open tibia allograft (50) |
1) Glenoid bone loss > 15%; 2) Tibia allograft preference: glenoid bone loss > 25%; important cartilaginous component |
1) Elevation; 2) Medial rotation in abduction; 3) Lateral rotation in abduction; 4) Extension; 5) Abduction |
Regular |
45 |
Kordasiewicz et al 2016 2222. Kordasiewicz B, Małachowski K, Kicinski M, Chaberek S, Pomianowski S. Comparative study of open and arthroscopic coracoid transfer for shoulder anterior instability (Latarjet)-clinical results at short term follow-up. Int Orthop. 2017;41(5):1023-33. |
Prospective cohort |
48 (46 men/2 women) |
Open Latarjet (48) x Arthroscopic Latarjet (62) |
1) Hill-Sachs engaging injury |
1) Elevation; 2) Abduction; 3) Lateral rotation in adduction; 4) Lateral rotation in abduction |
Regular |
54.2 |
Kordasiewicz et al. 2019 2323. Kordasiewicz B, Kiciński M, Małachowski K, Boszczyk A, Chaberek S, Pomianowski S. Arthroscopic Latarjet stabilization: analysis of the learning curve in the first 90 primary cases: early clinical results and computed tomography evaluation. Arthroscopy. 2019;35(12):3221-37. |
Prospective cohort |
90 (80 men/10 women) |
Latarjet Arthroscopic |
1) Hill-Sachs engaging injury |
1) Elevation; 2) Abduction; 3) Lateral rotation in adduction; 4) Lateral rotation in abduction |
Regular |
23.7 |
Moroder et al. 2018 2424. Moroder P, Stefanitsch V, Auffarth A, Matis N, Resch H, Plachel F. Treatment of recurrent anterior shoulder instability with the Latarjet or Bristow procedure in older patients. J Shoulder Elbow Surg. 2018;27(5):824-30. |
Prospective cohort |
25 (13 men/12 women) |
Open Latarjet (15) x Open Bristow (10) |
1) > 40 years old; 2) Glenoid defect associated with clinically compensated cuff injuries |
1) Elevation; 2) Abduction; |
Weak |
29 |
Vadalà et al. 2017 2525. Vadalà A, Lanzetti RM, De Carli A, Lupariello D, Guzzini M, Desideri D, Ferretti A. Latarjet procedure: evolution of the bone block and correspondent clinical relevance-a clinical and radiological study. Musculoskelet Surg. 2017;101(Suppl 2):113-20. |
Prospective cohort |
24 (22 men/2 women) |
Open Latarjet |
1) ISIS > 6; 2) Participation in sports |
1) Elevation; 2) Abduction; 3) Lateral rotation in adduction; 4) Lateral rotation in abduction |
Weak |
24 |
Yang et al. 2018 2626. Yang JS, Mehran N, Mazzocca AD, Pearl ML, Chen VW, Arciero RA. Remplissage versus modified Latarjet for off-track Hill-Sachs lesions with subcritical glenoid bone loss. Am J Sports Med. 2018;46(8):1885-91. |
Prospective cohort |
91 (86 men/5 women) |
Open Latarjet |
Hill-Sachs injury with engagement |
1) Elevation; 2) Lateral rotation in adduction; 3) Lateral rotation in abduction; 4) Medial rotation in abduction |
Good |
38.4 |
Zhu et al. 2017 2727. Zhu Y, Jiang C, Song S. Arthroscopic versus open Latarjet in the treatment of recurrent anterior shoulder dislocation with marked glenoid bone loss: a prospective comparative study. Am J Sports Med. 2017;45(7):1645-53. |
Prospective cohort |
44 (32 men/12 women) |
Open Latarjet |
1) Glenoid bone loss > 20% |
1) Elevation; 2) Lateral rotation in adduction; 3) Medial rotation in adduction |
Weak |
37.4 |