Video-assisted thoracic surgery utility in veterans: a narrative review
Introduction
Since its development in the 1990s, the use of video-assisted thoracic surgery (VATS; also called “thoracoscopic” surgery) has grown from a highly specialized and infrequently used modality to a core pillar of modern thoracic surgery. In recent history, the techniques gained traction after safety and feasibility was robustly demonstrated in a prospective and multi-institutional study by the Cancer and Leukemia Group B (CALGB) (1). The group used a standardized definition for VATS lobectomy for the trial, marked by mandated avoidance of rib spreading and a specimen removal incision of maximum length of 8 cm, as well as dissection of the vein, arteries, and airway with standard node sampling.
VATS is currently the preferred approach for surgical resection of early-stage lung cancer (2,3), and is becoming commonplace in a variety of other intra-thoracic procedures, including fundoplication and thymectomy. However, VATS uptake in veterans affairs (VA) facilities is thought to be slow, though evidence documenting this phenomenon over time has been minimal (4,5).
It is established that the veteran population suffers from unique medical needs, some secondary to combat exposure (6), and some secondary to stress and trauma related disorders (7,8). Even in other areas, veterans continue to have overall poorer health status and more medical comorbidities than their peers in the civilian population (9). Given that there is evidence that VATS is better tolerated than open surgery in patients with poorer health (10-12), this would seem to provide a prime opportunity for the techniques to be used to their greatest advantage.
Despite the unique and sometimes increased medical needs of the US veteran population, surgical outcomes at VA medical centers are often equivalent to civilian centers. Specifically within the field of thoracic surgery, however, the evidence is mixed. Evidence has demonstrated both equivalent (13) and also worsened (14,15) perioperative outcomes for lung cancer patients at VA vs. non-VA centers. Lung cancer outcomes have historically been worse in the VA population (16), though there is evidence that this has been improving over time (17-19). Outcomes are generally improved at higher volume centers (20), though some studies have demonstrated no association between case volumes at VA centers and 30-day mortality rate (21). With evidence that continues to be mixed in nature, it remains important to investigate the mechanisms of these differences to identify systemic issues and target them to optimize care in our veteran population. Below, we review the available literature on the utilization of VATS in the VA system.
Understanding the patterns of utilization of minimally invasive technologies in the field of thoracic surgery is critical not only to the assessment of the usefulness of these techniques in improving VA patient outcomes, but also as a means of identifying potential obstacles in implementation, particularly since technology continues to advance at a rapid rate. The integration of new technologies into surgical care in an evidence-based manner is important to ensuring that the VA continues to deliver optimal care to its large population of our nation’s servicemembers. A body of evidence regarding these topics has accumulated since the development of VATS techniques, and the field of thoracic surgery has subsequently undergone a change towards minimally invasive approaches. This review aims to outline the available evidence related to the use of VATS techniques within the VA system. We present this article in accordance with the Narrative Review reporting checklist (available at https://vats.amegroups.com/article/view/10.21037/vats-22-51/rc).
Methods
We performed a review of studies that investigated thoracoscopic surgery at VA centers in PubMed (Table 1). We identified studies that were published in the English language. There were no publication date restrictions. Randomized controlled trials, prospective observational, and retrospective cohort studies were included, with the exclusion of review articles or systematic reviews with no accompanying meta-analysis. Studies were evaluated for inclusion based on title and abstract. The authors then performed a more detailed review of the full manuscript for inclusion. A total of 10 studies met inclusion criteria and were included in our review.
Table 1
Items | Specification |
---|---|
Date of search | 9/06/2022 |
Databases and other sources searched | PubMed |
Search terms used | VATS OR video assisted thoracic surgery AND Veterans OR robotics OR Veteran Health Administration |
Timeframe | No date restriction |
Inclusion and exclusion criteria | Excluded review articles and systematic review articles without meta-analysis, English language |
Selection process | Literature selection by Drs. Halbert, Napolitano, Antevil, and Trachiotis |
VATS as an alternative to open pulmonary resection
Most investigations on the implementation and efficacy of VATS within the VA healthcare system have focused on the treatment of early-stage lung cancers, comparing patient outcomes using VATS techniques vs. open resections. In one such study, Cajipe et al. analyzed the outcomes of patients undergoing lobectomy to treat stage 1 and 2 lung cancers at a single VA center (Table 2) (5). Perioperatively, the VATS and the open surgery groups experienced similar blood loss, surgical time, number of lymph nodes resected, number of N2 stations dissected, percentage of complete resections, median tumor size, pathological stage, and percentage of centrally located tumors (Table 3). This suggests that using the VATS technique resulted in an equivalent oncologic operation. VATS patients also had chest tubes removed 1 day earlier on average than patients who underwent thoracotomy (P<0.001), had shorter length of hospital stay (LOS) by three days (P=0.02), and suffered fewer postoperative complications (30% vs. 58%, P=0.009), including pulmonary complications (24% vs. 48%, P=0.01) (Table 4). On multivariate analysis, VATS approach was an independent predictor of reduced complications (OR =0.359; 95% CI: 0.13–0.96; P=0.04) (Table 4). These improved outcomes support the more widespread use of VATS procedures in veteran populations. However, the authors did note that these patients experienced higher complication rates and longer hospital stays than had been observed in similar analyses with non-veteran populations. This may be accounted for, though, by the poorer health status in their population, as well as the inclusion of stage 2 and centrally located disease.
Table 2
Study | Year of publication | Design | N | Patient population |
---|---|---|---|---|
Cajipe et al. | 2012 | Single center, retrospective cohort | 91 | Patients undergoing lobectomy for primary stage I or stage II lung cancer |
DeArmond et al. | 2012 | Retrospective cohort, single surgeon, three centers: VA, university-affiliated county hospital, private community hospital | 50 | Patients with early-stage lung cancer, adequate pulmonary reserve and comorbidities; VA patients with higher # of preoperative risk factors (P=0.006) and higher rate of smokers (P=0.02) |
Maiga et al. | 2019 | Retrospective cohort study, national VA database | 11,004 | Patients undergoing resection for known or suspected lung cancer |
Holleran et al. | 2022 | Retrospective cohort study, national VA database | 4,216 | Patients undergoing VATS lobectomy, divided into cohorts based on development of a pulmonary complication within 30 days (11.3%) and those who did not (88.7%) (excluding patients with preoperative pneumonia or ventilator dependence, or emergent cases |
Holleran et al. | 2021 | Retrospective cohort study, national VA database | 594 | Patients undergoing thymectomy |
Skancke et al. | 2017 | Retrospective cohort study, single center | 27 | Newly diagnosed esophageal cancer with resectable malignancy (before or after neoadjuvant treatment) |
Dyas et al. | 2022 | Retrospective cohort, single center | 108 | Patients undergoing surgery for intention to treat lung masses; divided into pre- (n=63) and post-robotic (n=45) implementation at the center, with subgroups of VATS (19%), robotic (30%), and open (51%) sub-groups |
Holleran et al. | 2022 | Retrospective cohort study, national VA database | 8,212 | Patients undergoing pulmonary resections via uniportal (n=176) or multiportal (n=8,036) VATS approaches |
Napolitano et al. | 2022 | Retrospective cohort study, national VA database | 16,895 | Patients undergoing pulmonary resections (i.e., wedge, segmentectomy, lobectomy, sleeve lobectomy, and pneumonectomy): 5,748 VATS and 5,748 open after propensity matching |
Cornwell et al. | 2018 | Single center, retrospective cohort | 183 | Patients undergoing VATS lobectomy (n=127) or stereotactic body radiotherapy (n=56) for clinical stage I NSCLC |
VATS, video-assisted thoracic surgery; VA, veterans affairs; NSCLC, non-small cell lung cancer.
Table 3
Study | Approach and operation | Operative time | Blood loss (cc) | Operative details (P value) |
---|---|---|---|---|
Cajipe et al., 2012 | Open vs. VATS lobectomy | No difference (P=0.17) | No difference (P=0.9) | No differences in: nodes resected (0.70), N2 stations (0.30), R0 resection (0.36), Central tumors (0.86), tumor size (0.47), pathologic stage (0.55), %AC (0.43), %SCC (0.61), and % other pathologies (0.76) |
DeArmond et al., 2012 | VATS lobectomy | VA with longer operative time (237 vs. 196 min, P=0.002) | – | Higher incidence of pathologies other than NSCLC in non-VA population (0.04), no difference in rate of conversion to open (1.0), pathologic stage (0.26), patients with post-operative event (0.14) |
Maiga et al., 2019 | Lobectomy (77.5%) or wedge (22.5%); 64.5% open, 35.5% VATS | – | – | VATS with higher rate benign pathology than open (8.9% vs. 4.9%, OR 0.53; 95% CI: 0.45–0.62; P<0.001); |
Holleran et al., 2022 | VATS lobectomy | Shorter operative time with no pulmonary complications (3.6 vs. 4 hours, P<0.001) |
– | – |
Holleran et al., 2021 | Transsternal (63.3%), VATS, including robotic (19.0%) VATS, transcervical (17.7%) | VATS and transsternal cases with shorter operative time than transcervical 2.7, 2.9, 3.2 hours, P=0.006) | – | Transsternal with higher proportion of 1+ complications (13.6% vs. 6.2% and 4.8%, P=0.008), higher rate pulmonary complications (7.5% vs. 0.9% and 1.9%, P=0.006) |
Skancke et al., 2017 | Open (67%, transhiatal or Ivor Lewis) vs. minimally invasive (33%, Ivor Lewis) | No difference (P=0.81) | Open approach with higher blood loss (822 vs. 222 mL, P=0.001) | More nodes harvested in minimally invasive cohort (10 vs. 4, P=0.001), no difference in positive margins (R1, P=0.21), MIE with greater rate of pathological upstaging (33% vs. 0%, P=0.016) |
Dyas et al., 2022 | Open, VATS, robotic lobectomy | – | Open approach with higher EBL (67 vs. 28 mL VATS vs. 58 mL robotic, P<0.001) | No subgroup difference in intraoperative complications (0.32), MI (0.75), vascular injury (0.21) |
Holleran et al., 2022 | VATS: uniportal and multiportal | Uniportal shorter (1.7 vs. 3.1 hours, P<0.001) | – | – |
Napolitano et al., 2022 | Open, VATS, robotic pulmonary resection | No difference (P=0.31) | No difference (P=0.12) | – |
Cornwell et al., 2018 | VATS lobectomy, SBRT | – | – | All VATS patients achieved R0 resection; seven patients (18.9%) who received VATS had pathologic upstaging; SBRT total dose: 50–56 Gy, 4–5 fractions, 86.5% complete response, 5.4% partial response, 8.1% no change |
VATS, video-assisted thoracic surgery; VA, veterans affairs; AC, adenocarcinoma; SCC, squamous cell carcinoma; NSCLC, non-small cell lung cancer; MIE, minimally-invasive esophagectomy; EBL, estimated blood loss; MI, myocardial infarction; SBRT, stereotactic body radiotherapy.
Table 4
Study | Postoperative complications/outcomes (P value) | Length of stay | Outcomes (P value) |
---|---|---|---|
Cajipe et al., 2012 | VATS patients had fewer complications (30% vs. 58%, P=0.009), shorter chest tube duration (3 vs. 4 days, P=0.0001); |
VATS shorter LOS (7 vs. 10 days, P=0.02) |
Operative mortality: no difference (0.2); multivariate analysis: VATS was an independent predictor of reduced complications (OR =0.36, 95% CI: 0.13–0.96, P=0.04) |
DeArmond et al., 2012 | No difference in: days with chest tube (0.15), ICU days (0.07) | longer LOS for VA patients (6.4 vs. 3.6 days, P=0.022) |
No difference in 30-day mortality (1.0) |
Maiga et al., 2019 | – | – | VATS use increased over time, from 15.6% in 2002 to 50.6% in 2015; VATS use by facility ranged from 0% to 81.7%, with higher volume correlated with increased VATS use (Pearson r=0.35; 95% CI: 0.15–0.52; P<0.001) |
Holleran et al., 2022 | – | – | Complication cohort with higher prevalence of COPD (49.0% vs. 38.6%; P<0.001), subjective dyspnea (33.5% vs. 24.4%; P<0.001), ASA class >3 (20.8% vs. 12.4%; P<0.001), unhealthy alcohol consumption (20.8% vs. 12.4%; P=0.016), and hyponatremia (9.4% vs. 6.9%; P=0.048); no differences in proportions of smokers between cohorts (0.265); multivariate analysis- the following risk factors were associated with higher odds of pulmonary complication after VATS lobectomy: COPD [aOR =1.37 (1.12–1.69); P=0.003], subjective dyspnea [aOR =1.33 (1.06–1.66); P=0.013], ASA class >3 [aOR =1.67 (1.29–2.17); P=0.001], and hyponatremia [aOR =1.50 (1.06–2.11); P=0.021]. Unhealthy alcohol consumption was independently associated with pulmonary complication on a trend level [aOR =1.31 (1.00–1.73); P=0.052]; smoking within 1 year preoperatively not associated with 30-day pulmonary complications [aOR =0.90 (0.73–1.11); P=0.325] |
Holleran et al., 2021 |
– | Transsternal with longer LOS (4 vs. 2 vs. 2 days, P<0.001) | VATS use increased from 0% in 2008 to 61% of case volume in 2019; multivariable analysis showed transsternal correlated with more than 13 times higher adjusted odds of pulmonary complications (aOR, 13.29; 95% CI: 1.20 to 146.93; P=0.035) |
Skancke et al., 2017 | No difference in anastomotic leak (P=0.70) | no difference in LOS (P=0.22) | No difference in 30-day mortality (0.49) |
Dyas et al., 2022 | No subgroup difference in intrahospital complications (0.39), including arrhythmia (0.28), pneumonia (0.34), UTI (0.57), SSI (0.75), reintubation (0.57), reoperation (0.34), stroke (0.75) | open with longer LOS (7 vs. 2 days VATS vs. 5 days robotic, P<0.001) | No 30-day mortalities observed |
Holleran et al., 2022 | Uniportal with higher rate of superficial wound infection (2.8% vs. 0.8%, P=0.017), clostridium difficile (1.7% vs. 0.4%, P=0.044) | uniportal longer (6 vs. 5 days, P=0.04) | No difference in 30-day mortality (P=0.76) |
Napolitano et al., 2022 | Open approach with higher rates of: return to operating room (7.3% vs. 4.8%, P<0.001), cardiac arrest (1.5% vs. 0.8%, P<0.001), failure to wean from the ventilator (5.4% vs. 3.2%, P<0.001), pneumonia (8.0% vs. 5.5%, P<0.001), reintubation (7.1% vs. 4.3%, P<0.001), acute renal failure (0.8% vs. 0.4%, P=0.007), progressive renal insufficiency (0.9% vs. 0.4%, P=0.002), superficial wound infection (1.2% vs. 0.7%, P=0.014), UTI (1.6% vs. 1.1%, P=0.021), sepsis (3.7% vs. 2.6%, P<0.001), return to operating room (7.3% vs. 4.8%, P<0.001) | Open approach with longer LOS (7 vs. 5 days, P<0.001) | No difference in 30-day mortality (P=0.112); proportion of VATS increased over time (24.2% cases in 2008 and 69.9% cases 2018) Decrease in complication rates for both approaches. Specifically for VATS: 8% lower rate of major complications in 2008, 2018 with 58% lower rate of complications (P<0.001). Composite pulmonary complications decreased significantly over time in both VATS and open groups (P<0.001) |
Cornwell et al., 2018 |
VATS: 24.3% had complications, none greater than grade 2; SBRT: 24.3% late toxicity | – | VATS: no operative, 30-day, or 90-day mortality; SBRT: no operative, 30-day mortality, 2.7% 90-day mortality; overall Survival worsened with SBRT (3.1 vs. 8 years, P=0.0016); 1-year overall, 3-year overall, and 3-year recurrence-free survivals were 89.2%, 52.9%, and 38.5% after SBRT and 94.6%, 85.7%, and 82.8% after VATS (P<0.005 for all); SBRT independently predicts poorer overall survival and recurrence rates (mortality OR =11.6, P=0.019; recurrence OR =9.9, P=0.031) |
VATS, video-assisted thoracic surgery; VA, veterans affairs; LOS, length of stay; ICU, intensive care unit; COPD, chronic obstructive pulmonary disease; ASA, American Society of Anesthesiologists classification; aOR, adjusted odds ratio; UTI, urinary tract infection, SSI, surgical site infection; SBRT, stereotactic body radiotherapy.
Given the expedient rate at which medical technology develops, the feasibility and ease of implementation for new approaches is often limited. One study by DeArmond et al. focused on comparing the implementation of VATS lung resections at VA and non-VA centers, in this case a university-affiliated county hospital, a community hospital, and a Veterans Administration hospital (4) (Table 2). As noted above, the veteran population has an inherently different risk profile than a civilian population, which can limit the interpretation of these results. In this case, patients at the VA were in overall poorer health than their non-VA counterparts: they had a higher number of preoperative risk factors (P=0.006), a higher percentage of current smokers (68% vs. 35%, P=0.02), and a lower diffusing capacity for carbon monoxide (DLCO; 56 vs. 70, P=0.046) (Table 2). By surgical notes, procedures at the VA hospital were longer (237 vs. 196 min, P=0.002), involved more concurrent procedures (P=0.004), and had more documented cases of pleural adhesions or hilar lymphadenopathy (53% vs. 19%; P=0.01) (Table 3). However, there was no difference between groups with respect to intraoperative conversion to thoracotomy, 30-day mortality, number of postoperative events, rate of postoperative atrial fibrillation, or number of days within the ICU (Table 4). These results demonstrate that VATS is equally feasible to implement in VA centers, and that it can be as safe as open resection, even for a population with poorer baseline health status.
These results are encouraging, and so there has understandably been a growing interest in determining if surgical approach (i.e., VATS) can independently predict improved rates of pulmonary complications after pulmonary resections. This interest has been investigated in both veteran and civilian hospitals, since pulmonary complications are themselves independently associated with worsened patient outcomes (22,23). In a review of VA VATS cases, Holleran et al. specifically queried patients via the Veterans Affairs Surgical Quality Improvement Program (VASQIP) database who underwent VATS lobectomy between 2008 and 2018 looking at the rates of pulmonary complications in the perioperative period (Table 2) (24). They identified 4,216 non-emergent cases; 11.3% of these developed at least one pulmonary complication, which was in turn associated with increased mortality (12.1% vs. 0.8%; P<0.001) and longer length of stay (12.0 vs. 6.8 days; P<0.001) (Table 4). This is consistent with rates found in civilian populations, which can range from 3% to 14% (25-27).
Although the Holleran study did not make any comparisons to non-VATS procedures; one contemporary study by Geraci et al. (14) did find increased rates of postoperative pneumonia in VA patients when comparing propensity matched VA and academic medical center populations (11% vs. 1.2%, P=0.01), but similarly did not perform any sub-analyses comparing surgical approaches. However, the same surgical group did perform an analysis on a separate civilian population, comparing patient outcomes after muscle-sparing thoracotomy vs. VATS resection (28). In this case, the authors found no association between surgical approach and postoperative complications, disease-free survival, or overall survival. Unfortunately, the evidence remains mixed, with yet other studies demonstrating improvements in rates of postoperative pulmonary complications after VATS procedures when compared with open thoracotomy (29-32).
Other studies, like the one by Maiga et al. in 2019 (33), have performed analyses deliberately tracking the use of thoracoscopic techniques over time. This retrospective study using the VASQIP database included a total of more than 11,000 veterans between 2002 and 2015 who underwent open vs. VATS resection for known or suspected lung cancer (Table 2). Encouragingly, the proportion of VATS procedures increased steadily from 15.6% system-wide in 2002 to 50.6% by 2015 (Pearson r=0.97; 95% CI: 0.91–0.99; P<0.001) (Table 4). However, uptake of VATS varied widely across regions, (P<0.001), with higher volume regions using VATS more frequently (Pearson r=0.35; 95% CI: 0.15–0.52; P<0.001) (Table 4). This is consistent with a contemporary analysis of utilization and outcomes in civilian cases (34), which demonstrated less common use of VATS in similar regions, particularly in the Western US. The study demonstrates that the implementation of VATS still lags in less populated areas of the country and at some VA hospitals.
The benefits of VATS have led to it becoming the predominant technique used in VA pulmonary resections. In one recent study, Napolitano et al. identified patients who underwent VATS resection (including wedge or segmental resection, lobectomy, or pneumonectomy) at the VA between 2008 and 2018 (Table 2) (35). Analysis of propensity matched groups, which included 5,748 patients each, demonstrated that use of a VATS approach was associated with lower rates of cardiac complications (P<0.001), prolonged ventilation (P<0.001), pneumonia (P<0.001), reintubation (P<0.001), acute renal failure (P=0.007), progressive renal insufficiency (P=0.002), superficial wound infection (P=0.014), urinary tract infection (P=0.021), sepsis (P<0.001), and a return to the OR (P<0.001), as well as a 2-day reduction in hospital stay (P<0.001) (Table 4). The authors demonstrated that while 76% of lung resections were performed using an open approach in 2008, nearly 70% of procedures were performed using VATS by 2018. Additionally, while total complication rates decreased in both groups over time, undergoing VATS lung resection in 2018 was associated with a 58% reduced risk of major complications than thoracotomy (P<0.001), compared with an 8% lower risk of major complications in 2008 (Table 4). These results are encouraging. Not only do they demonstrate overall improved outcomes for lung resection patients at the VA over the last decade, but they also demonstrate the increased utilization of what is now becoming standard of care, minimally invasive techniques in this unique population.
Other areas of VATS application
There is less literature on the utilization of VATS techniques for other types of thoracic surgery procedures within the VA system. However, the available studies demonstrate increased use of VATS approaches over the last decade, with equivalent or improved perioperative outcomes. In one analysis, Holleran et al. compared the use of thoracoscopic vs. open approaches for thymectomy cases within the VA between 2008 to 2019 (Table 2) (36). Similar to the trends seen with contemporary VATS pulmonary resections, the authors demonstrated a large increase in the proportion of thymectomies performed using VATS, and transsternal thymectomy decreased from 90.2% of operative volume in 2008 to 22.2% of operative volume in 2019 (Table 4). VATS thymectomy increased from 0% of cases in 2008 to 61.1% of operative volume in 2019. There was a downtrend in complication rate across all cases from 17.7% in 2008 to 5.6% in 2019 (P=0.014). However, patients undergoing VATS had better outcomes than their open-surgery counterparts, including decreased LOS (2 vs. 4 days; P<0.001), decreased complications overall (6.2% vs. 13.6%; P=0.008), and fewer pulmonary complications (0.9% vs. 7.5%; P=0.006) (Table 3). On subgroup analyses, there were no differences in survival between surgical groups for patients undergoing procedures for thymic cancer, and no differences in perioperative morbidity or mortality for patients with myasthenia gravis.
These favorable results demonstrate the potential for improved patient outcomes with the use of thoracoscopic techniques outside the sphere of pulmonary resections. This has the potential to greatly influence not only outcomes, but patient selection for VATS and surgical planning. Additionally, the absence of oncologic staging data further limits the interpretation of this study, as the extent of locoregional disease also influences surgical approach and has the potential to significantly impact perioperative outcomes.
The VA has also seen an increase in the use of minimally invasive techniques to treat esophageal malignancy (37,38). The integration of VATS techniques at the VA for these procedures is both feasible and safe (38), and has positively impacted patient outcomes. In one retrospective analysis by Skancke et al. comparing minimally invasive to open techniques (Table 2) (37), VATS esophagectomy patients lost less blood intraoperatively (222 vs. 822 mL, P<0.001), had a larger number of lymph nodes harvested (10.33 vs. 2.72, P<0.001), and experienced equivalent anastomotic leak rates (11% vs. 17%, P=0.703) and equivalent postoperative mortality (0% vs. 6%, P=0.490) (Table 3).
The next step: uniportal VATS and robotics
Uniportal VATS
As VATS has become more widespread, further efforts have focused on reducing the number of ports used in these procedures. Uniportal VATS wedge resection was first described by Rocco et al. in 2004 (39), and there is some evidence to suggest that the use of only one port decreases patients’ postoperative pain, reduces length of hospital stay, and improves patient satisfaction when compared with multi-port VATS (40-42). Other studies have demonstrated noninferior oncologic outcomes with uniportal approaches (43,44).
In one study comparing uniportal and multiportal lung resection at the VA, Holleran et al. found that a uniportal technique was associated with shorter operative time (1.7 vs. 3.1 hours, P<0.001) and no difference in 30-day mortality (P=0.76) (Table 4) (45). However, it was also associated with longer length of stay (LOS; 6 vs. 5 days, P=0.04) and higher rates of superficial surgical site infection (SSI; 2.8% vs. 0.8%, P=0.017) and postoperative clostridium difficile infection (1.7% vs. 0.4%, P=0.044) (Tables 2,3). The study had some significant limitations, though, as all of the uniportal procedures were performed at one center by one surgeon. Indeed, there are fewer surgeons using the uniportal technique within the VA system, and so there is limited data available regarding its utility and outcomes for the VA population. As more evidence becomes available regarding the use of uniportal VATS at civilian hospitals, it may be worth considering the increased use of this approach in VA patients.
Robotics
Robotic thoracic surgery approaches have also demonstrated significant improvements in patient outcomes compared to open thoracotomy (46). Additionally, robotic surgery provides multiple ergonomic and technical advantages to surgeons, including the neutral positioning of the console, the three-dimensional operating field, and the use of wristed instruments which circumvent the fulcrum effect of most laparoscopic tools (47-49). However, numerous comparative studies have failed to find any improvement in patient outcomes when comparing robotic surgery to VATS (50,51).
In one study, Dyas et al. hypothesized that initiation of a robotics program at a VA medical center would decrease length of stay and complication rates (Table 2) (52). To do this, they reviewed cases from a 5-year period spanning both pre- and post-robotic thoracic surgery integration. After implementation, robotic operations accounted for 53% of cases of lung resections. This period also saw a large rise in the overall use of minimally invasive approaches (85% vs. 42%, P<0.001). Minimally invasive surgery was also associated with shorter LOS (4 vs. 7 days, P<0.001), lower estimated blood loss (EBL) (50 vs. 100 mL, P<0.001), and more discharges to home (OR 13.00, 95% CI: 1.61–104.70, P=0.02) (Table 4). However, on subgroup multivariate analysis, both VATS and robotic approaches were independent predictors of shorter LOS for patients (P<0.001 and P=0.009, respectively), with use of robotics predicting no outcomes advantages for patients over the use of VATS.
Still, the novelty of robotic surgery at many VA centers should not be ignored when drawing conclusions from these studies. Robotic surgery within the VA is relatively new, as the VA center with the highest case volume only started their program in 2017 (53). Surgeons, staff, and care facilities are still learning the best ways to care for these patients. Patient outcomes are likely to improve as the use of robotic surgery becomes more routine, and so the relative benefits of robotic surgery when compared to other approaches is also likely to shift as this happens. Thus, further investigation comparing robotic-assisted and VATS procedures focusing on their respective benefits and drawbacks will be important to ensure that patients continue to receive optimal, cost effective care.
VATS vs. stereotactic body radiotherapy (SBRT)
Other competing technologies have also emerged for the treatment of early-stage lung cancer. SBRT, in particular, has begun to gain traction for stage I non-small cell lung cancer (NSCLC), particularly in patients who are not operative candidates (54). There is increasing evidence that the procedure is safe and effective (55,56), and a number of patients have begun to choose SBRT over surgical therapy as a way to avoid more invasive treatment (57,58). However, studies directly comparing surgical and SBRT approaches have not been encouraging, with VATS often out-performing SBRT regarding long-term patient outcomes (59). Evidence within the veteran population is limited. One study by Cornwell et al. reviewed data from a propensity-matched cohort of patients with clinical stage I NSCLC who underwent either SBRT (n=56) or VATS resection (Table 2) (22). The authors demonstrated that not only was overall survival worsened with SBRT (3.1 vs. >8 years, P=0.0016), the 1-year overall, 3-year overall, and 3-year recurrence-free survivals were 89.2%, 52.9%, and 38.5% after SBRT and 94.6%, 85.7%, and 82.8% after VATS (P<0.005 for all), respectively (Table 4). The authors also demonstrated on multivariate analysis that SBRT treatment was an independent predictor of poorer overall survival and recurrence rates (mortality OR =11.6, P=0.019; recurrence OR =9.9, P=0.031). Ergo, surgical resection at this juncture remains vital in ensuring optimal oncologic outcomes for patients who are operative candidates.
Conclusions
VATS procedures decrease perioperative pain and disability, improve patient outcomes, and are feasible to perform within the VA system. Minimally invasive procedures should be considered in patients who meet criteria, particularly at centers which already have experience performing VATS procedures. It is critically important that the VA continue to incorporate minimally invasive techniques in an effort to optimize care for the veteran population and its unique set of needs. As the field of thoracic surgery continues to move towards the standardized use of advanced technologies, this will likely require a proactive effort in order to remain up to date with the most recent developments in evidence-based care.
Acknowledgments
Funding: None.
Footnote
Reporting Checklist: The authors have completed the Narrative Review reporting checklist. Available at https://vats.amegroups.com/article/view/10.21037/vats-22-51/rc
Peer Review File: Available at https://vats.amegroups.com/article/view/10.21037/vats-22-51/prf
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://vats.amegroups.com/article/view/10.21037/vats-22-51/coif). GT serves as an unpaid editorial board member of Video-Assisted Thoracic Surgery from February 2023 to January 2025. The other authors have no conflicts of interest to declare.
Ethical Statement:
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References
- Swanson SJ, Herndon JE 2nd, D'Amico TA, et al. Video-assisted thoracic surgery lobectomy: report of CALGB 39802--a prospective, multi-institution feasibility study. J Clin Oncol 2007;25:4993-7. [Crossref] [PubMed]
- Howington JA, Blum MG, Chang AC, et al. Treatment of stage I and II non-small cell lung cancer: Diagnosis and management of lung cancer, 3rd ed: American College of Chest Physicians evidence-based clinical practice guidelines. Chest 2013;143:e278S-313S.
- Ettinger DS, Wood DE, Aisner DL, et al. Non-Small Cell Lung Cancer, Version 3.2022, NCCN Clinical Practice Guidelines in Oncology. J Natl Compr Canc Netw 2022;20:497-530. [Crossref] [PubMed]
- DeArmond DT, Simmons JD, Cline AM, et al. Feasibility of video-assisted thoracoscopic surgery lobectomy in Veterans Administration patients. Am J Surg 2012;204:e15-20. [Crossref] [PubMed]
- Cajipe MD, Chu D, Bakaeen FG, et al. Video-assisted thoracoscopic lobectomy is associated with better perioperative outcomes than open lobectomy in a veteran population. Am J Surg 2012;204:607-12. [Crossref] [PubMed]
- National Academies of Sciences, Engineering, and Medicine, Health and Medicine Division, Board on Population Health and Public Health Practice, Committee to Review the Health Effects in Vietnam Veterans of Exposure to Herbicides (Eleventh Biennial Update). No title. 2018 Nov 15. Available online: https://nap.nationalacademies.org/catalog/25137/veterans-and-agent-orange-update-11-2018
- Clausen AN, Clarke E, Phillips RD, et al. Combat exposure, posttraumatic stress disorder, and head injuries differentially relate to alterations in cortical thickness in military Veterans. Neuropsychopharmacology 2020;45:491-8. [Crossref] [PubMed]
- Sachs-Ericsson N, Joiner TE, Cougle JR, et al. Combat Exposure in Early Adulthood Interacts with Recent Stressors to Predict PTSD in Aging Male Veterans. Gerontologist 2016;56:82-91. [Crossref] [PubMed]
- Agha Z, Lofgren RP, VanRuiswyk JV, et al. Are patients at Veterans Affairs medical centers sicker? A comparative analysis of health status and medical resource use. Arch Intern Med 2000;160:3252-7. [Crossref] [PubMed]
- Demmy TL, Curtis JJ. Minimally invasive lobectomy directed toward frail and high-risk patients: a case-control study. Ann Thorac Surg 1999;68:194-200. [Crossref] [PubMed]
- Ceppa DP, Kosinski AS, Berry MF, et al. Thoracoscopic lobectomy has increasing benefit in patients with poor pulmonary function: a Society of Thoracic Surgeons Database analysis. Ann Surg 2012;256:487-93. [Crossref] [PubMed]
- Jeon JH, Kang CH, Kim HS, et al. Video-assisted thoracoscopic lobectomy in non-small-cell lung cancer patients with chronic obstructive pulmonary disease is associated with lower pulmonary complications than open lobectomy: a propensity score-matched analysis. Eur J Cardiothorac Surg 2014;45:640-5. [Crossref] [PubMed]
- Heiden BT, Eaton DB Jr, Chang SH, et al. Comparison Between Veteran and Non-Veteran Populations With Clinical Stage I Non-small Cell Lung Cancer Undergoing Surgery. Ann Surg 2023;277:e664-9. [Crossref] [PubMed]
- Geraci T, Baratta V, Young J, et al. Lobectomy for Lung Cancer at Veterans Administration Medical Center Versus Academic Medical Center. Ann Thorac Surg 2017;103:1715-22. [Crossref] [PubMed]
- St Julien JB, Pinkerman R, Aldrich MC, et al. Poor survival for veterans with pathologic stage I non-small-cell lung cancer. Am J Surg 2012;204:637-42. [Crossref] [PubMed]
- Campling BG, Hwang WT, Zhang J, et al. A population-based study of lung carcinoma in Pennsylvania: comparison of Veterans Administration and civilian populations. Cancer 2005;104:833-40. [Crossref] [PubMed]
- Boyer MJ, Williams CD, Harpole DH, et al. Improved Survival of Stage I Non-Small Cell Lung Cancer: A VA Central Cancer Registry Analysis. J Thorac Oncol 2017;12:1814-23. [Crossref] [PubMed]
- Zullig LL, Sims KJ, McNeil R, et al. Cancer Incidence Among Patients of the U.S. Veterans Affairs Health Care System: 2010 Update. Mil Med 2017;182:e1883-91. [Crossref] [PubMed]
- American Cancer Society. Facts & Figures 2023, Special Section: Lung Cancer. American Cancer Society. Atlanta, GA. 2023. Available online: https://nap.nationalacademies.org/catalog/25137/veterans-and-agent-orange-update-11-2018
- Silvestri GA, Handy J, Lackland D, et al. Specialists achieve better outcomes than generalists for lung cancer surgery. Chest 1998;114:675-80. [Crossref] [PubMed]
- Khuri SF, Daley J, Henderson W, et al. Relation of surgical volume to outcome in eight common operations: results from the VA National Surgical Quality Improvement Program. Ann Surg 1999;230:414-29; discussion 429-32. [Crossref] [PubMed]
- Cornwell LD, Echeverria AE, Samuelian J, et al. Video-assisted thoracoscopic lobectomy is associated with greater recurrence-free survival than stereotactic body radiotherapy for clinical stage I lung cancer. J Thorac Cardiovasc Surg 2018;155:395-402. [Crossref] [PubMed]
- Lugg ST, Agostini PJ, Tikka T, et al. Long-term impact of developing a postoperative pulmonary complication after lung surgery. Thorax 2016;71:171-6. [Crossref] [PubMed]
- Holleran TJ, Napolitano MA, Duggan JP, et al. Predictors of 30-Day Pulmonary Complications after Video-Assisted Thoracoscopic Surgery Lobectomy. Thorac Cardiovasc Surg 2023;71:327-35. [Crossref] [PubMed]
- Agostini P, Lugg ST, Adams K, et al. Video-assisted thoracoscopic lobectomy: which patients require postoperative physiotherapy? Physiotherapy 2020;106:87-93. [Crossref] [PubMed]
- Paul S, Sedrakyan A, Chiu Y, et al. Outcomes after lobectomy using thoracoscopy vs thoracotomy: a comparative effectiveness analysis utilizing the Nationwide Inpatient Sample database. Eur J Cardiothorac Surg 2013;43:813-7. [Crossref] [PubMed]
- Wang Z, Zhang J, Cheng Z, et al. Factors affecting major morbidity after video-assisted thoracic surgery for lung cancer. J Surg Res 2014;192:628-34. [Crossref] [PubMed]
- Kuritzky AM, Aswad BI, Jones RN, et al. Lobectomy by Video-Assisted Thoracic Surgery vs Muscle-Sparing Thoracotomy for Stage I Lung Cancer: A Critical Evaluation of Short- and Long-Term Outcomes. J Am Coll Surg 2015;220:1044-53. [Crossref] [PubMed]
- Villamizar NR, Darrabie MD, Burfeind WR, et al. Thoracoscopic lobectomy is associated with lower morbidity compared with thoracotomy. J Thorac Cardiovasc Surg 2009;138:419-25. [Crossref] [PubMed]
- Agostini P, Lugg ST, Adams K, et al. Postoperative pulmonary complications and rehabilitation requirements following lobectomy: a propensity score matched study of patients undergoing video-assisted thoracoscopic surgery versus thoracotomy†. Interact Cardiovasc Thorac Surg 2017;24:931-7. [Crossref] [PubMed]
- Cao C, Manganas C, Ang SC, et al. Video-assisted thoracic surgery versus open thoracotomy for non-small cell lung cancer: a meta-analysis of propensity score-matched patients. Interact Cardiovasc Thorac Surg 2013;16:244-9. [Crossref] [PubMed]
- Laursen LØ, Petersen RH, Hansen HJ, et al. Video-assisted thoracoscopic surgery lobectomy for lung cancer is associated with a lower 30-day morbidity compared with lobectomy by thoracotomy. Eur J Cardiothorac Surg 2016;49:870-5. [Crossref] [PubMed]
- Maiga AW, Deppen SA, Denton J, et al. Uptake of Video-Assisted Thoracoscopic Lung Resections Within the Veterans Affairs for Known or Suspected Lung Cancer. JAMA Surg 2019;154:524-9. [Crossref] [PubMed]
- Shroyer AL, Quin JA, Grau-Sepulveda MV, et al. Geographic Variations in Lung Cancer Lobectomy Outcomes: The General Thoracic Surgery Database. Ann Thorac Surg 2017;104:1650-5. [Crossref] [PubMed]
- Napolitano MA, Sparks AD, Werba G, et al. Video-Assisted Thoracoscopic Surgery Lung Resection in United States Veterans: Trends and Outcomes versus Thoracotomy. Thorac Cardiovasc Surg 2022;70:346-54. [Crossref] [PubMed]
- Holleran TJ, Napolitano MA, Crowder HR, et al. Clinical Outcomes and Technical Approach of Thymectomy in the Veterans Health Administration. Ann Thorac Surg 2022;113:1648-55. [Crossref] [PubMed]
- Skancke MD, Grossman RA, Marino G, et al. Analysis of Minimally Invasive Esophagectomy at a Single Veterans Affairs Medical Center. J Laparoendosc Adv Surg Tech A 2017;27:784-9. [Crossref] [PubMed]
- Rossidis G, Kissane N, Hochwald SN, et al. Overcoming challenges in implementing a minimally invasive esophagectomy program at a Veterans Administration medical center. Am J Surg 2011;202:395-9. [Crossref] [PubMed]
- Rocco G, Martin-Ucar A, Passera E. Uniportal VATS wedge pulmonary resections. Ann Thorac Surg 2004;77:726-8. [Crossref] [PubMed]
- Mier JM, Chavarin A, Izquierdo-Vidal C, et al. A prospective study comparing three-port video-assisted thoracoscopy with the single-incision laparoscopic surgery (SILS) port and instruments for the video thoracoscopic approach: a pilot study. Surg Endosc 2013;27:2557-60. [Crossref] [PubMed]
- Sihoe ADL. Uniportal Lung Cancer Surgery: State of the Evidence. Ann Thorac Surg 2019;107:962-72. [Crossref] [PubMed]
- Tamura M, Shimizu Y, Hashizume Y. Pain following thoracoscopic surgery: retrospective analysis between single-incision and three-port video-assisted thoracoscopic surgery. J Cardiothorac Surg 2013;8:153. [Crossref] [PubMed]
- Abouarab AA, Rahouma M, Kamel M, et al. Single Versus Multi-Incisional Video-Assisted Thoracic Surgery: A Systematic Review and Meta-analysis. J Laparoendosc Adv Surg Tech A 2018;28:174-85. [Crossref] [PubMed]
- Yang Z, Shen Z, Zhou Q, et al. Single-incision versus multiport video-assisted thoracoscopic surgery in the treatment of lung cancer: a systematic review and meta-analysis. Acta Chir Belg 2018;118:85-93. [Crossref] [PubMed]
- Holleran TJ, Napolitano MA, Sparks AD, et al. Uniportal Video-Assisted Thoracoscopic Lung Resection: A Single-Surgeon Experience and Comparison with Multiportal Technique in the Veteran Population. J Laparoendosc Adv Surg Tech A 2022;32:149-57. [Crossref] [PubMed]
- Oh DS, Reddy RM, Gorrepati ML, et al. Robotic-Assisted, Video-Assisted Thoracoscopic and Open Lobectomy: Propensity-Matched Analysis of Recent Premier Data. Ann Thorac Surg 2017;104:1733-40. [Crossref] [PubMed]
- Ramadan OI, Wei B, Cerfolio RJ. Robotic surgery for lung resections-total port approach: advantages and disadvantages. J Vis Surg 2017;3:22. [Crossref] [PubMed]
- Cao C, Manganas C, Ang SC, et al. A systematic review and meta-analysis on pulmonary resections by robotic video-assisted thoracic surgery. Ann Cardiothorac Surg 2012;1:3-10. [PubMed]
- Leal Ghezzi T, Campos Corleta O. 30 Years of Robotic Surgery. World J Surg 2016;40:2550-7. [Crossref] [PubMed]
- Ye X, Xie L, Chen G, et al. Robotic thoracic surgery versus video-assisted thoracic surgery for lung cancer: a meta-analysis. Interact Cardiovasc Thorac Surg 2015;21:409-14. [Crossref] [PubMed]
- Louie BE, Wilson JL, Kim S, et al. Comparison of Video-Assisted Thoracoscopic Surgery and Robotic Approaches for Clinical Stage I and Stage II Non-Small Cell Lung Cancer Using The Society of Thoracic Surgeons Database. Ann Thorac Surg 2016;102:917-24. [Crossref] [PubMed]
- Dyas AR, Stuart CM, Wojcik BM, et al. Evaluating the implementation of robotic thoracic surgery on a Veterans Administration Hospital. J Robot Surg 2023;17:365-74. [Crossref] [PubMed]
- VAntagePoint, Tampa VA completes 1000th robotic surgery. U.S. Department of Veterans Affairs: News Sections: Health. 2019 Nov 25. Available online: https://blogs.va.gov/VAntage/68672/tampa-va-completes-1000th-robotic-surgery/. Accessed 14 Oct 2022.
- Boily G, Filion É, Rakovich G, et al. Stereotactic Ablative Radiation Therapy for the Treatment of Early-stage Non-Small-Cell Lung Cancer: CEPO Review and Recommendations. J Thorac Oncol 2015;10:872-82. [Crossref] [PubMed]
- Timmerman R, Papiez L, McGarry R, et al. Extracranial stereotactic radioablation: results of a phase I study in medically inoperable stage I non-small cell lung cancer. Chest 2003;124:1946-55. [Crossref] [PubMed]
- McGarry RC, Papiez L, Williams M, et al. Stereotactic body radiation therapy of early-stage non-small-cell lung carcinoma: phase I study. Int J Radiat Oncol Biol Phys 2005;63:1010-5. [Crossref] [PubMed]
- Senan S, Paul MA, Lagerwaard FJ. Treatment of early-stage lung cancer detected by screening: surgery or stereotactic ablative radiotherapy? Lancet Oncol 2013;14:e270-4. [Crossref] [PubMed]
- Lagerwaard FJ, Verstegen NE, Haasbeek CJ, et al. Outcomes of stereotactic ablative radiotherapy in patients with potentially operable stage I non-small cell lung cancer. Int J Radiat Oncol Biol Phys 2012;83:348-53. [Crossref] [PubMed]
- Hamaji M, Chen F, Matsuo Y, et al. Video-assisted thoracoscopic lobectomy versus stereotactic radiotherapy for stage I lung cancer. Ann Thorac Surg 2015;99:1122-9. [Crossref] [PubMed]
Cite this article as: Halbert S, Napolitano M, Antevil J, Trachiotis G. Video-assisted thoracic surgery utility in veterans: a narrative review. Video-assist Thorac Surg 2023;8:15.