1. Introduction

The currently used type of reverse shoulder arthroplasty (RSA) was designed in 1985 by Paul Grammont [1,2] and approved in the United States in 2003. It was initially aimed at patients with cuff tear arthropathy [3,4], but indications have expanded over the years to the revision of failed arthroplasties and several other pathologies [5,6,7]. Mid-term retrospective studies and the joint registries (available in Australia, Denmark, Italy, Norway, Sweden, and United Kingdom [8,9,10,11,12]) have confirmed overall survival rates of over 90% for RSAs in the short-term or mid-term. However, these registries also combine a large number of different implants, surgeons, and operative techniques. Multicenter retrospective studies may overcome some of these biases by merging a large number of patients operated by a limited number of surgeons with similar operative techniques and rehabilitation protocols, while also allowing for a more detailed analysis of clinical notes and relevant pre- and postoperative imaging. These techniques can provide some important details for what patients and surgeons could expect from RSAs.

Our group of surgeons had experience with RSAs for more than 20 years, and our objective was to report this experience to assess the long-term survival of RSAs in a large series of patients with different etiologies operated in shoulder-specialized centers.

Our hypothesis was that the long-term survival of an RSA would depend on the indication for an RSA, the gender, and the patient’s age at the time of surgery.

2. Materials and Methods

2.1. Study Design

We conducted a retrospective study including all the patients who were operated on with a Grammont-style RSA between 1993 and 2010 in six shoulder-specialized centers. Complications, reoperations, and revisions were extracted from the medical records. The indications for RSAs were consistent between centers: cuff-tear arthropathy (Hamada IV and V), massive and irreparable rotator cuff tear with pseudoparalysis or previous failed cuff repair, primary osteoarthritis with B2/C glenoid and/or associated cuff tear, and malignant tumors.

Patients were followed clinically and radiologically on a regular basis by surgeons. Complications, revisions, and standard x-rays were retrieved from medical records and assessed by two specialized shoulder surgeons (LF and MC).

A revision surgery was defined as any surgical procedure following the index surgery for which a glenoid and/or humeral implant or part of the implant was changed, added, or removed.

A reoperation was defined as any surgical procedure following the index surgery for which all the implants were retained, such as a reduction in dislocations, a washout and debridement, or a hematoma evacuation.

2.2. Patient Demographics

Between 1993 and 2010, 1611 RSAs were implanted in 1462 patients, at a mean age of 73.2 years (±9.0, range 18–94), including 1088 female (74.4%) and 374 male patients. In 149 cases (10.2%), patients had bilateral RSAs. Patients were followed for a mean of 5.6 years (±3.9, range 2–20). The distribution was as follows:

• -. 0 to 2 years: 354 shoulders;

• -. 2 to 5 years: 348 shoulders;

• -. 5 to 10 years: 661 shoulders;

• -. 10 to 15 years: 225 shoulders;

• -. 15+ years: 23 shoulders.

The cuff-deficient shoulders (Massive Cuff Tear + Cuff Tear Arthropathy + Failed cuff repairs) represented half of the indications of RSA (Table 1).

2.3. Surgical Technique

All the patients were operated on in the beach-chair position with an appropriate prophylactic antibiotic cover. The six surgeons used similar operative techniques and rehabilitation protocols. A deltopectoral approach was used in 89% of the cases, and an anterosuperior approach was used in 11%. A medialized (Grammont type) Aequalis Reverse (Wright–Tornier, Memphis, TN, USA) RSA was used in 79.6% of cases, and the Delta III (Depuy, Warsaw, IN, USA) was used in 20.4% of cases. The humeral stem was cemented in 88%, and the glenosphere was sized at 36 mm in 86% of cases and at 42 mm in 14% of cases and lateralized with a BIO-RSA in 21% of cases. A tendon transfer to restore active external rotation (L’Episcopo: Latissimus Dorsi ± Teres Major) was performed in 47 cases (3%).

2.4. Statistical Analysis

Numeric outcomes were expressed by their mean (±standard deviation), and discrete outcomes were expressed by their absolute and relative frequencies (%). The Fisher’s exact test was used for between-group comparisons. We used the Kaplan–Meier method to estimate the survival probabilities and their pointwise 95% confidence intervals. The log-rank non-parametric test was used to compare the survival distributions. The significance was set at p < 0.05. Statistical analysis was performed with EasyMedStat (www.easymedstat.com; version 2.0, France) (accessed on 12 March 2018).

3. Results

3.1. Postoperative Complications

The most frequent complications were instability (n = 61, 3.8%) and infection (n = 45, 2.8%) (Table 2). The most frequent causes for revision were infection (n = 37, 2.3%), instability (n = 24, 1.5%), glenoid loosening (n = 22, 1.4%), and humeral loosening (n = 14, 0.9%).

3.2. Survival Analysis

Overall, 266 RSAs (16.5%) had at least one complication leading to 64 reoperations (4.0%) and 110 revision surgeries (6.8%). At 10 years, the survival without revision was 91.0% (87.9–93.3%) in primary RSAs and 80.9% (73.6–86.3%) in revision RSAs for failed arthroplasties (Table 3).

The reoperation-free survival and the revision-free survivals were both higher in primary RSAs as compared to revision RSAs (p = 0.002 and p < 0.001, Figure 1). No difference was observed between the revisions of HA and the revisions of other arthroplasties (p = 0.441).

3.3. Predictive Factors for Survival without Revision Surgery

3.3.1. Influence of Gender and Age

The rates of complications and revision surgeries were higher in male patients: the 5-year and 10-year revision-free survivals were 90.3% and 83.2% in male patients and 95.4% and 91.5% in female patients (p < 0.001, Table 4 and Table 5, Figure 2).

However, after stratification over the etiology, this difference was found only in the revision RSA group (72.3% vs. 84.5% at 10 years, p = 0.020, Figure 3), and was not found in any other etiology.

A younger age at surgery was associated with higher rates of complications and revisions: patients younger than 60 years at the time of RSA had a 10-year survival of 75.7% while patients between 60 and 69, 70 and 79 and over 80 years had a 10-year survival of 88.8%, 91.3% and 94.3% respectively (p < 0.001, Table 4, Figure 4).

This association was maintained after stratification over gender with males and females requiring more revision surgeries when operated younger (Table 5). In the 70–79 age group, the males had more revisions than the females (8.5% vs. 4.5%; p = 0.034) but the difference was not significant for other age groups. Revision RSA performed in male younger than 60 years led to a 10-year survival rate of 72.3%.

The indication for RSA was also associated with age (p < 0.001), with the younger patients being operated on for tumors (51.9 years), instability arthropathy (68.9 years), and revision (69.0 years) and with the older patients being operated on for acute fractures (80.1 years), CTA (76.3 years), POA (76.1 years), and MCT (73.3 years).

3.3.2. Influence of Diagnosis

The rates of complication and revision surgery varied according to the etiology (p < 0.001). The highest revision rates were observed in tumors (20%), revision RSAs (16%), and fracture sequelae (11%); the lowest rates were observed in instability arthropathy (0%), rheumatoid arthritis (2%), and acute fractures (2%) (Table 6).

4. Discussion

In this series, primary RSA led to a 10-year revision-free survival rate of over 90% and a 15-year survival rate of 85%. This 10-year rate is comparable to those reported in retrospective studies [13,14,15,16,17,18] and national joint registries [8,12,19]. For rotator cuff arthropathy, the UK registry reports a 10-year revision rate of 5.9% and the Australian registry reports a 7-year revision rate of 5.6%. The retrospective series reports 10-year overall survival rates between 88% and 93% for different etiologies (Table 7).

The most frequent complications leading to revision surgery were infection, instability, and loosening, which is consistent with the systematic review of 21 studies and 782 RSAs by Zumstein et al. [20]. These complications differ from what can be found with an anatomical total shoulder arthroplasty, where the most frequent complications are related to the glenoid and the cuff [21,22]. Contrarily, in an RSA, the humerus is the main source of complications with 2.8% of patients suffering a humeral loosening or a humeral fracture, while glenoid loosening was found in only 1.6% of cases [23].

Revision RSA was associated with a lower survival at every time point compared to primary RSA (80.4% vs. 91.0% at 10 years, p = 0.002), as reported by other authors in previous studies [6,24,25]. Saltzman et al. [25] found that the revision status was the most significant predictor of intraoperative and postoperative complications in a retrospective series of 137 patients. Zumstein et al. [20] reported a complication rate that was more than twice as high in cases of revision compared to primary RSAs (33% vs. 13%). Although revision RSA is sometimes the only solution after a failed unconstrained arthroplasty, surgeons should be aware that it is a challenging surgery with high rates of complications and revision surgeries. The main complication in a revision RSA is a low-grade infection.

The diagnosis for a primary RSA is one of the main predictive factors of postoperative complications and revision surgeries. While MCT and failed cuff repairs led to 10-year survivals of over 95%, fracture sequelae and tumors had much lower survivals (83.9% and 53.1% at 10 years, respectively). The latter two etiologies and revision RSAs are associated with major complications such as instability and humeral loosening [26,27,28,29] because of the frequency of missing proximal bone stock preventing rotational control of the stem [30]. The 10-year survival of an RSA for primary osteoarthritis was high (90.3%), which confirms it is a viable option in cases of severe humeral subluxation and/or subluxation [31,32,33]. RSA for rheumatoid arthritis led to a 10-year survival of 97.6%, which is superior to that reported for HA and TSA in the same indication [34,35,36].

We observed that younger patients were more likely to have revision surgery after an RSA. The 10-year survival of patients younger than 60 at the time of surgery was only 75.7% vs. a 94.3% survival for patients older than 80 years at the time of the RSA. This might be related to the higher activity in younger patients and less favorable indications such as tumors and revision RSAs. The influence of age could not be highlighted in previous studies comparing younger and older patients, potentially due to the lack of statistical power and the shorter follow-up time [37,38,39].

Male patients had a higher risk of revision as it has been found in the Nordic registry [8]. However, the Australian registry found this difference only in the first three months after surgery [19]. After stratification over the indication, we found a higher risk for males that were only in the revision RSA group. These results may show that this higher revision rate of male patients in the revision RSA group and in the first three months is due to a higher risk of infection, as demonstrated by the Norwegian registry [40] and the Mayo clinic study [41].

Our study is limited by its retrospective design. Subjective and functional outcomes were not assessed and remain important factors for surgeons to decide which surgical option they should consider. However, this study is unique as it reports a 17-year experience of a group of shoulder-specialist surgeons with two models of Grammont-type RSAs. To the best of our knowledge, this series represents the largest series of RSAs published in the literature, with the longest follow-up (up to 20 years). The large number of patients reviewed and the long-term follow up allowed for the analysis of survival rates and complications in RSAs implanted for a wide range of conditions. This source of information is of paramount importance for surgeons as it also provides further useful information to inform the patients about the expected survivorship of these implants according to their etiology and age.

Mid-term and long-term survivals of reverse shoulder arthroplasty reported in the literature.

MCT: Massive Cuff Tear, CTA: Cuff Tear Arthropathy, FS: Fracture Sequelae, POA: Primary OsteoArthritis, RA: Rheumatoid Arthritis, ANHH: Avascular Necrosis of Humeral Head.

5. Conclusions

The ten-year revision-free survival of a primary RSA for cuff-deficient shoulders, primary osteoarthritis, and rheumatoid arthritis is above 90%; however, some indications are associated with a higher complication rate and a lower survivorship (tumor, fracture sequelae, and revision RSA). Younger patients are also more likely to have postoperative complications and revision surgeries. The most frequent complications are instability, infection, and humerus-related complications.

The survival of an RSA depends on the diagnosis and on the patient’s age and gender. Surgeons should be aware of the high rates of complications and the lower survival rates of RSAs in younger patients, in males, and in RSAs for revision surgery. While the 10-year survival rate free of revision is over 95% in RSAs for MCTs and failed cuff repairs, it drops down to 80% or below in RSAs for fracture sequelae, tumors, and previous failed arthroplasties. The two main complications are low-grade infections and humeral loosening because of proximal humeral bone loss.

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Figure 1. Revision-free survival in primary RSA and revision RSA.

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Figure 2. Revision-free survival according to the gender.

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Figure 3. Revision-free survival of 239 revision RSA according to gender.

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Figure 4. Revision-free survival according to the age at surgery.

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