Trends in the Adoption of Robotic Surgery for Common Surgical Procedures

This cohort study characterizes trends in the use of robotic surgery for common surgical procedures.


Introduction
Robotic surgery continues to diffuse across an increasingly broad range of surgical procedures.However, concerns have been raised that robotic surgery is more costly 1,2 and may be no more effective 3,4 than other established operative approaches, such as traditional laparoscopic minimally invasive and open surgery.With respect to costs, for example, robotic surgery has been associated with episode costs as much as 25% higher compared with laparoscopic surgery.There are also concerns about the rapid growth of robotic surgery in areas with limited evidence to support its use and little theoretical benefit or clinical rationale (eg, inguinal hernia repair).The US Food and Drug Administration (FDA) recently issued a warning against the use of robotic surgery for the treatment of breast and cervical cancers. 5In their communication, they expressed concerns about the lack of epidemiologic data characterizing the use of robotic surgery in real-world practice settings.Current estimates are limited to single-center studies, [6][7][8] device manufacturers' financial statements, 9 and claims data, which may be inaccurate owing to unreliable coding. 10,11We used population-based data from a manually abstracted statewide clinical registry to characterize contemporary trends in the adoption of robotic surgery across a range of general surgical procedures, which now represent the largest market for the technology in the United States.

Data Source and Study Population
This cohort study used data from the Michigan Surgical Quality Collaborative (MSQC), an Agency for Healthcare Research and Quality-recognized patient safety organization.The MSQC represents a voluntary partnership between 73 Michigan hospitals and Blue Cross/Blue Shield of Michigan that focuses on clinical quality improvement for surgical care.Hospitals participating in the MSQC perform more than 90% of all surgical procedures in Michigan.The MSQC maintains a clinical registry using a standardized data collection platform, validated case-sampling methods, and trained nurse data abstractors at each participating site.Data accuracy is maintained through rigorous training, internal data audits, and annual site visits by MSQC program staff.This data source allowed us to identify robotic procedures with greater precision and accuracy than is possible using claims data.This study was approved by the University of Michigan institutional review board, which deemed the study exempt from informed consent owing to use of secondary data.This study was designed and reported in adherence to the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) reporting guideline.
We used data from the complete MSQC clinical registry file to identify all inpatient and outpatient general surgical episodes from January 1, 2012, through June 30, 2018.Procedures were identified and categorized by Current Procedural Terminology codes.We focused on general surgical procedures, which represent the clinical domain with the largest growth in robotic surgery.These files include additional information on patient age, demographic characteristics, and comorbid conditions in addition to detailed procedural information (eg, operative approach and anesthesia type), postoperative complications, death, and resource use (readmissions and emergency department visits).

Outcomes
Our primary outcome of interest was the surgical approach-robotic, laparoscopic, or open.The MSQC data were manually abstracted, and data on surgical approach were derived directly from the operative reports rather than procedural codes.Procedures were considered robotic if surgeons reported using the surgical robot in their operative report.Cases in which a robotic procedure was unexpectedly converted to another approach (eg, conversion to open procedure for bleeding) were characterized as robotic because this was the original approach chosen by the surgeon.

Statistical Analysis
Data were analyzed from March 1 through April 19, 2019.The purpose of this analysis was to characterize trends in the use of surgical approaches over time for common general surgical procedures.We first reported raw proportions that were not adjusted for patient or hospital characteristics.We evaluated trends by calculating the fold change in each approach over time by dividing the proportional use of robotic surgery in 2018 by the proportional use in 2012.We also calculated the annual increase or decrease in the proportional use of each approach using linear regression.The coefficient for study years, modeled as a continuous variable, is reported as the annual trend.We then replicated the overall analysis stratified by specific procedures to determine whether overall trends were influenced by changes in practice for certain procedures.
To determine how hospitals change their practices after they begin performing robotic surgery, we performed a multigroup interrupted time series analysis.During the study period, 23 of the 73 MSQC participating hospitals (31.5%) began performing robotic surgery (32 hospitals were already performing robotic surgery at the time that MSQC began collecting data on this approach in 2012).
We determined the date of the first robotic general surgery procedure within each of the hospitals that adopted robotic surgery during the study period.We then centered all hospitals on this date and evaluated the trends in the proportional use of each approach in the years before and after the hospital performed its first robotic operation.We used linear splines to model absolute levels and trends in the periods before and after introduction of robotic surgery.This analysis was designed to test the incremental association of adopting robotic surgery with trends in surgical practice but not to make assumptions about what would have happened had the hospital not begun performing robotic surgery.Our primary analysis was not adjusted for specific procedures, but we generated estimates for each procedure group in a sensitivity analysis.We estimated cluster-robust standard errors to account for repeated observations within hospitals.We performed all statistical analyses using Stata, version 14.2 statistical software (StataCorp LLC).

Results
Characteristics for the 169 404 patients and 73 hospitals are included in in the Supplement).Trends in robotic surgery use were similar for specific procedures, although for some, the magnitude of the increase was greater.For example, the use of robotic surgery for inguinal hernia repair increased from 0.7% to 28.8% from January 2012 through June 2018 (41.1-fold change; slope, 5.4% per year; 95% CI, 5.1%-5.7%).   2 and Table 3).The use of laparoscopic surgery decreased from 53.2% to 51.3% after hospitals began performing robotic surgery (difference, −1.9%; 95% CI, −2.2% to −1.6%) (Table 3).Before hospitals performed robotic surgery, a trend toward greater use of laparoscopic surgery occurred (slope, 1.3% per year).A trend toward less laparoscopic surgery after hospitals began performing robotic surgery occurred (slope, −0.3% per year; difference, −1.6%; 95% CI, −1.7% to −1.5%).Results remained the same when stratified across specific procedures.

Discussion
This study used a unique, clinically oriented, and manually abstracted data source to characterize the use of robotic surgery across a wide range of common general surgical procedures.These data identify the correct procedure approach with greater precision and accuracy than claims.We found that the use of robotic surgery increased dramatically from 2012 to 2018.Although the use of robotic surgery increased across all procedures, for certain operations, such as inguinal hernia repair, practice patterns shifted by an order of magnitude toward greater use of robotics.We also found that the use of robotic surgery increased rapidly and diffused widely across numerous different procedures in the years after hospitals begin performing robotic surgery.This trend was associated with a decrease in the use of open and laparoscopic minimally invasive procedures, which for most surgeons was already considered a safe and effective approach when clinically feasible.
Recent work suggests that the United States now performs more robotic surgery than any other country in the world, although overall trends in other specialties (eg, urology) toward greater use of robotic surgery have been present for many years. 9Based on robotic device manufacturers' financial statements, procedure volumes exceeded 600 000 in 2017, with the largest and fastest growing contributor being the field of general surgery. 9This finding suggests that the clinical footprint for robotic surgery will continue to increase as it has for more than a decade already.However, accurate data on how robotic surgery is being applied in contemporary practice is lacking.0,11 This inaccuracy is problematic because it may limit our ability to understand the clinical implications of this rapid change in practice.It also limits the ability of policy makers and regulators to scope oversight or, more broadly, the public health implications of rapid changes in surgical practice.
Within this context, regulators from the FDA recently expressed safety concerns about the rapidly growing use of robotic approaches for certain cancer operations. 5These concerns stem from the limited evidence of benefit (eg, fewer complications or better oncologic resection quality) for robotic surgery.For example, randomized clinical trials have failed to demonstrate the benefits of robotic surgery over other approaches in the treatment of rectal cancer 12 and have shown even potentially worse outcomes in procedures for cervical cancer. 4Observational studies that compared robotic surgery with more established laparoscopic or open approaches have also failed to demonstrate superior outcomes after inguinal hernia repair, 8 kidney resections, 1 colectomy, [13][14][15][16] or cholecystectomy. 7The discrepancy between the ongoing rapid adoption of robotic surgery and unclear clinical benefit highlights why accurate information on how it is being applied in contemporary surgical practice is necessary.
This study expands on prior work in several ways.We used manually abstracted data from a statewide surgical registry to ensure that our estimates reflect the true incidence of robotic surgery across a wide range of procedures, hospitals, and surgeons.Making further use of these unique data, we estimated how the initiation of robotic surgery within hospitals had broad associations with surgical practice for numerous procedures that differed in complexity, anatomical location, and surgical indications (eg, repair of a hernia vs removal of an organ).This investigation builds on existing literature, which has shown similar associations of an increase in robotic prostatectomy with hospital acquisitions of robotic systems. 17We also demonstrate that increasing use of robotic surgery changed existing trends toward greater use of laparoscopic surgery.For many common and low-risk procedures, such as cholecystectomy, conventional laparoscopic surgery is already the accepted standard of care.Laparoscopic approaches are also less expensive and can be performed by most general surgeons without robotics. 18This situation highlights a questionable trend: robotic surgery is replacing conventional laparoscopic approaches for procedures that may not be complex enough to warrant the consideration of an advanced, expensive, and unproven minimally invasive platform.
This study suggests that regulators and the surgical community can take additional steps to monitor the ongoing diffusion of robotic surgery and ensure that this trend does not lead to diminished patient safety.Because accurate data are necessary to inform the creation of appropriate safeguards, the FDA and the Centers for Medicare & Medicaid Services should consider providing coverage for robotic surgery with provisions for evidence development. 19This process has been previously used by the Centers for Medicare & Medicaid Services to create registries of patients treated with new and unproven surgical technologies (eg, carotid artery stenting).Use of these provisions would facilitate greater understanding of how robotic procedures are being used in realworld practice.Akin to postmarket surveillance of pharmaceuticals, such provisions would also create a common data resource from which the comparative safety and effectiveness of robotic operations can be evaluated by numerous investigators.
This action would also allow hospitals, which provide credentials to perform robotic surgery, to better understand where sufficient evidence suggests plausible benefit.At present, surgeons are largely able to use robotic surgery for any procedure at their professional discretion.As has been shown in the FDA warning and through prior studies, this discretionary use may place patients at risk for poor outcomes. 3Facilitating transparency around the allocation of robotic surgery would allow patients to make better collaborative decisions with their surgeons.After all, for many of the procedures we report in this study, little to no evidence suggests that robotic surgery increases patient safety or treatment effectiveness compared with other approaches.

Limitations
Our results should be interpreted within the context of several limitations.Our clinical registry only captures data from Michigan and therefore may not be generalizable to the country as a whole.
However, the MSQC represents a heterogeneous group of hospitals, surgeons, and practice settings.
Furthermore, we report on the most common general surgery procedures performed in the United States.Changes in patient factors, such as obesity, may influence trends in procedure choice.Our estimates may therefore be limited by a lack of adjustment for patient characteristics.That said, adjusting for patient factors may introduce its own biases because no clinical consensus exists around how robotic procedures should be allocated.Much of this decision-making is based on caseby-case surgeon assessments and clinical nuance not captured in any registry.Our results are consistent across multiple different procedures, which also suggests that these trends are independent of unique clinical domains or disease processes.Our study is unable to account for how other nonclinical factors, such as marketing, may influence the adoption of robotic surgery.However, others have found that the chances of receiving robotic surgery were 2-to 5-fold greater in highly competitive vs noncompetitive health care markets. 20Moreover, evidence suggests that hospitals immediately begin advertising their acquisition of robotic surgical services through web-based and conventional health system marketing campaigns. 21These data are complementary to ours and suggest that the greatest forces driving robotic surgery adoption may be the technological imperative and economic pressures experienced by hospitals in certain health care markets.

Conclusions
This study found that robotic surgery is rapidly diffusing across a broad range of common general surgical procedures.Trends toward greater use of the robotic platform appeared to occur rapidly after hospitals begin performing robotic surgery and were associated with a decrease in the use of established minimally invasive techniques, such as laparoscopic surgery.This trend was consistent across numerous specific procedures, even those for which conventional laparoscopic surgery is already considered standard of care and for which robotic surgery offers little theoretical clinical benefit to the patient.These findings highlight a need to continually monitor the diffusion of robotic surgery to ensure that enthusiasm for a new technology does not outpace the evidence needed to use it in the most effective clinical contexts.

Figure 1 .
Figure 1.Temporal Trends in the Proportional Use of Robotic, Laparoscopic, and Open Surgery100

Figure 2 .
Figure 2. Changes in Procedure Approach After Hospitals Began Performing Robotic Surgery

Table 2 .
Trends in the Use of Robotic Surgery for Specific Procedures, 2012-2018 Trends in the Adoption of Robotic Surgery for Common Surgical ProceduresThe proportion of hospitals and surgeons performing robotic surgery increased from January 2012 through June 2018.For example, 8.7% of surgeons performed robotic general surgery in 2012 compared with 35.1% in 2018 (eFigure in the Supplement).During the study period, 23 hospitals (31.5%) began performing robotic surgery.In those hospitals, the use of robotic surgery increased from 3.1% in the first year to 13.1% in the fourth year after hospitals began performing robotic general surgery operations (overall mean in first 4 years, 8.8%; slope, 2.8% per year; difference, 2.8% [95% JAMA Network Open.2020;3(1):e1918911.doi:10.1001/jamanetworkopen.2019.18911(Reprinted) January 10, 2020 4/9 Downloaded from jamanetwork.comby guest on 08/19/2024

Table 3 .
Mean Use and Trends in Operative Approach Before and After Hospitals Began Performing Robotic Surgery for Specific Procedures a Before and after indicate timing of adoption of robotic surgery.