The safety of outpatient total shoulder arthroplasty: a systematic review and meta-analysis

Total shoulder arthroplasty (TSA) is a successful procedure to treat end-stage glenohumeral osteoarthritis, rotator cuff arthropathy, and proximal humerus fractures. The frequency of TSA is on the rise in the USA with a five-fold increase in the past decade [1, 2] and a reported annual incidence of 9.4–12.3% [3, 4]. Improvement in implant design, surgical technique, and peri-operative management resulted in a substantial reduction in length of stay and post-operative complications [5, 6].

Health care systems are shifting toward maximizing the value of care through reducing costs while providing high-quality patient care. In an economic analysis on TSA, 24% of total costs per patient were attributed to inpatient costs, whereas, 6% was due to 90-day follow-up costs [7]. Thus, there has been an increased interest in transitioning toward outpatient TSA, with a reported 107% increase over the past five years [8]. This transition has been motivated by the well-established safety and financial effectiveness of outpatient total hip and knee arthroplasty [9‐13].

To achieve a successful outpatient pathway, careful patient risk stratification is paramount to identify who can undergo outpatient arthroplasty safely without increasing readmissions and complications [14]. This requires tremendous cooperation across several stakeholders such as surgeons, anesthesiologists, nurses, administration, insurance agencies, and rehabilitation services [15]. Several studies have shown that adjusting patient expectations, proper patient education, inquiry about living status such as the availability of assistance at home, and proximity to the surgical centre are crucial when considering outpatient pathways [16‐19]. Furthermore, pain management should be carefully planned with the anaesthetists which can include preemptive analgesia, brachial plexus catheters, interscalene blocks, peri-articular injections, and post-operative multimodal pain management [16, 20].

The primary objective of this systematic review was to determine the safety of outpatient TSA by comparing the outpatient and inpatient pathways in terms of readmission rates and post-operative complications. The secondary objective was to compare the functional outcomes and costs of outpatient with inpatient TSA. We hypothesize that outpatient TSA would have similar readmission rates, complications, revisions, functional outcomes, and reduced costs compared with inpatient TSA.

This systematic review and meta-analysis was conducted with adherence to the guidelines of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) [21].

The objective of this systematic review and meta-analysis was to evaluate the safety of outpatient TSA by comparing readmissions and complications with inpatient TSA. The rationale behind this study was that TSA is a successful procedure, yet its incidence is rapidly increasing which results in significant expenditures on health care systems. To maximize value through achieving high-quality care with the least possible costs, outpatient TSA would be advantageous in entertaining this notion. The success of outpatient total hip and knee arthroplasty in reducing costs while retaining equivalent outcomes to the inpatient setting is well-established, which has motivated surgeons to implement outpatient TSA. Our systematic review and meta-analytic comparisons demonstrated that outpatient TSA is equivalent to inpatient settings in terms of readmissions and complications while achieving satisfactory functional outcomes and reducing costs.

A vital aspect of performing outpatient TSA is careful patient risk stratification [14]. This aspect is crucial in maintaining satisfactory outcomes without further increase in complications. In our systematic review, unmatched cohort studies had significantly younger age groups in outpatient TSA and in most; the population was predominant in males as opposed to inpatient TSA. The disproportionate number of younger patients in the outpatient group can be explained by the fact that younger patients have less comorbidities and are thus safer for the outpatient pathway. However, the under representation of females in the outpatient groups could be related to surgeon selection bias, as female sex has been reported to be a significant predictor for longer hospitalization [30, 31]. Another finding in this review was that the outpatient group was generally healthier than their inpatient counterparts. In unmatched studies, outpatient TSA had significantly fewer proportions of ASA class III, diabetes mellitus, combined cardiopulmonary comorbidities, isolated cardiovascular diseases, and hypertension. Unmatched studies are helpful as they reflect the trends of patient stratification in the current practice for outpatient arthroplasty, hence this emphasizes that appropriate patient selection is key in performing a successful outpatient TSA.

The safety and savings of outpatient arthroplasty can be assessed through investigating readmission rates which our meta-analytic comparisons did not show any differences at 30 and 90 days. Our findings were comparable to most included studies, thereby supporting that outpatient TSA is a safe option that does not translate into increased readmissions. The only contradicting evidence was reported by Basques et al. [28] who reported increased re-admission in inpatient groups at 90 days using Medicare data, which could relate to inherent limitations in the Medicare database such as coding errors. Of interest, Cancienne et al. [8] reported in their matched-cohort on a national insurance database that risk factors for re-admissions within 90 days include obesity, diabetes mellitus, peripheral vascular disease, congestive heart failure, chronic lung disease, depression, and chronic anemia in both outpatient and inpatient groups. In another database study, Ode et al. [25] performed logistic regression analysis and found that readmissions were markedly increased in obese patients and were also strongly affected by the state that the procedure was performed.

Another finding of this study was that outpatient TSA was not associated with increased complications when compared with inpatient TSA. Unadjusted meta-analytic comparisons demonstrated that outpatient TSA was associated with reduced surgical (total and major) and medical complications (total, major and minor). It is important to acknowledge that this analysis included matched and nonmatched retrospective cohort studies. Therefore, subgroup analyses were constructed to further explore the outcomes of outpatient TSA. The subgroup analyses demonstrated if a study was matched, there was no significant difference in complications between outpatient and inpatient TSA for all surgical and medical complications whether major or minor. In addition, no difference in all complications was evident regardless of a study’s data source (i.e., database or nondatabase). Such findings suggest that outpatient TSA is noninferior to the inpatient pathway, and it can be performed safely with careful patient selection.

The cost reductions observed in outpatient arthroplasty have been well documented in the hip and knee literature [11, 13]. Early studies of outpatient TSA have also shown this cost saving benefit. In our systematic review, only two comparative studies reported costs with significant reduction following outpatient arthroplasty. The cost advantage of outpatient TSA is supported as well in a recent economic analysis, where inpatient TSA costs were estimated $76,000 compared to $23,000 for outpatient TSA [32]. Although the costs of inpatient arthroplasty are attributed to the increased complexity of the surgical cases and the presence of comorbidities, increased expenditures in the care pathway might include unnecessary costs that could be circumvented. Therefore, the authors performed a secondary analysis that excluded ancillary costs such as additional laboratory workup, imaging studies, and inpatient rehabilitation. Even following these exclusions, the costs of inpatient TSA were still 41% higher than outpatient TSA [32].

Several limitations to this systematic review should be acknowledged. For example, our qualitative review demonstrated that most included studies were poor in quality, with significant confounding bias in six out of ten studies and selection bias in seven out of ten studies. The level of evidence of the review is level III with all studies being retrospective cohorts, indicating a lack of high-level evidence. Another limitation was heterogeneity among the studies as we included different data sources (database and nondatabase) and different matching of controls. Outcomes measures that had low heterogeneity were the 30-day readmissions, minor medical complications, and revision rates. Moderate heterogeneity was encountered in the 90-day readmissions, major and minor surgical complications. Substantial heterogeneity was found in total surgical and medical complications, and major medical complications. Substantial heterogeneity in total complications was addressed by subgrouping total complications into major and medical complications. The remaining heterogeneity in other outcomes was addressed by further subgrouping outcomes based on data source and controls matching. Furthermore, database studies have several inherent limitations such as the accuracy of the data is affected by coding errors. In our study, total surgical and medical complications were limited by having. Additionally, database study may not capture important variables that could potentially confound the rate of readmissions and complications such as surgeon or hospital volume and surgical technique. Despite that we employed subgroup analyses to control for study-level variables such as matched control or data source, we could not account for the type of procedure such as anatomic or reverse TSA due to limitations in data extraction. An important final limitation was that we did not register this systematic review prospectively which would have improved the transparency of this study.

In conclusion, our systematic review and meta-analysis demonstrated that outpatient TSA could be a safe and effective alternative to inpatient TSA in appropriately selected patients. It was evident that outpatient TSA does not lead to increased re-admissions or complication rates. An additional benefit of outpatient TSA was the significant cost reductions in comparative studies. This meta-analysis is based on retrospective comparative studies with level three evidence. Prospective and randomized, controlled multicenter studies are still necessary to ascertain the differences in outcomes between both inpatient and outpatient TSA.