Abstract
Extent of resection needed to treat lung cancer has long been an issue. The sole randomised controlled trial, reported by the Lung Cancer Study Group, advised against limited resection as standard surgery even for small peripheral non-small-cell lung cancers (⩽3 cm), because of frequent local recurrences. Elsewhere, conflicting results have been reported from different institutions. We therefore conducted a meta-analysis of reported studies to compare survival of stage I patients between limited resection and standard lobectomy. A MEDLINE web search for computer-archived bibliographic data yielded 14 articles suitable for analysis. Combined survival differences (survival rate with lobectomy minus that with limited resection) at 1, 3, and 5 years after resection according to the DerSimonian–Laird random effects model were 0.7% (95% CI, −0.8 to 2.1; P=0.3659), 1.9% (95% CI, −3.7 to 7.4; P=0.5088), and 3.6% (95% CI, −0.4 to 10.5; P=0.3603), respectively. None of these survival differences were significant, indicating that survival after limited resection for stage I lung cancer was comparable to that after lobectomy. However, since interstudy heterogeneity was detected, caution is required in interpretation of the results.
Similar content being viewed by others
Main
Limited resection for lung cancer was proposed in the early 1970s (Le Roux, 1972). Acceptable results of segmentectomy in a large number of patients were reported by Jensik et al (1973). Since then, several retrospective studies (Breyer and Jensik, 1985; Stair et al, 1985; Jensik, 1987; Temeck et al, 1992) considering efficacy of limited resection have been reported. In 1995, the Lung Cancer Study Group (LCSG) published final results of a randomised controlled trial (RCT) (Ginsberg and Rubinstein, 1995; Lederle, 1996) comparing local recurrence and survival after limited resection with those after standard lobectomy for stage IA non-small-cell lung cancer (NSCLC). Representing the only randomised trial worldwide to address the question of whether limited resection truly is comparable to standard lobectomy, that trial showed frequent locoregional recurrences and a tendency toward poorer survival in the limited resection group.
Although the randomised trial (Ginsberg and Rubinstein, 1995) concluded that limited resection should not be standard surgery even for small peripheral NSCLC, several surgeons (Kodama et al, 1997; Tsubota et al, 1998; Koike et al, 2003) have continued to perform some intentional limited resections. Indeed, results reported from various institutions up to now have been conflicting. Considering recent implementation of minimally invasive surgical techniques such as video-assisted thoracoscopic surgery (VATS), efficacy of limited resection in small, node-negative NSCLC needs to be re-evaluated (Sugarbaker and Strauss, 2000).
We therefore conducted a meta-analysis of published studies to quantitatively review survival data for limited resection of lung cancer in comparison with data for standard lobectomy.
Materials and methods
Eligibility criteria for meta-analysis
This meta-analysis was limited to studies comparing survival data of limited resection with those of standard lobectomy. The following eligibility criteria were established before collecting articles: (1) ‘Limited resection’ was defined as sublobular resection, including wedge resection and segmentectomy. (2) Operative approaches could include either thoracotomy or VATS. (3) Survival rates for a specific time interval after operation were stated in the article. (4) Study subjects had to be limited to clinical stage I patients. (5) Median follow-up time was to exceed 2 years. (6) Articles were published in English in the periodical medical literature from 1970 to August 2004. (7) When multiple articles by the same author or study group analysed the same series of patients, a single most informative article was chosen for the meta-analysis.
Collection of published studies
The MEDLINE web search for computer-archived bibliographic data concerning limited resection and postoperative survival in lung cancer was primarily performed in August 2004. Keywords lung ‘cancer+limited resection’, ‘lung cancer+wedge resection’, ‘lung cancer+segmentectomy’, and ‘limited resection +lobectomy’ hit 627, 344, 193, and 117 citations, respectively. Manual selection of relevant studies was carried out based on the summary analysis. Overlapping or unrelated articles were excluded, and items from hand-searched bibliographies were added. Of 18 articles initially found by the methods above, two were excluded for being reported by the same author or study group analysing a series of patients more informatively considered in another article. In three articles, advanced disease stages were included. One report of these three also was among the two representing overlap. Thus, four articles (Errett et al, 1985; Pastorino et al, 1991; Sugarbaker and Strauss, 2000; Miller et al, 2002) were excluded (Table 1), while 14 articles fulfilled eligibility criteria.
Statistical analyses
DerSimonian–Laird random effects analysis (DerSimonian and Laird, 1986) was used to estimate the survival difference (i.e. survival rate after standard lobectomy minus that of limited resection) at the end points of 1, 3, and 5 years after operation. Generally used to combine heterogeneous studies, this method produces a combined survival difference and a 95% confidence interval with a heterogeneity test at each end point. Survival rates were derived from published survival curves when not provided explicitly in the text or tables. Subjects censored prior to each end point were subtracted from the denominators (number of patients for follow-up), giving a conservative confidence interval for the summary statistic. Censored cases were counted by placing tick marks on survival curves when provided, as described by Mitsudomi et al (2000). The correlation coefficient (r) was calculated to examine the relationship between two variables. Significance was tested by the Bartlett test. For these tests, a P-value <0.05 was considered significant.
Publication bias was tested by the method of Egger et al (1997); for this, a P-value <0.1 was considered significant.
Results
A total of 14 studies (Hoffmann and Ransdell, 1980; Read et al, 1990; Date et al, 1994; Warren and Faber, 1994; Ginsberg and Rubinstein, 1995; Harpole et al, 1995; Lederle, 1996; Kodama et al, 1997; Landreneau et al. 1997; Pastorino et al, 1997; Kwiatkowski et al, 1998; Okada et al, 2001; Koike et al, 2003; Campione et al, 2004; Keenan et al, 2004) served as data sources for the present meta-analysis (Table 2). Their designs were retrospective in 12, matched-pair in one, and RCT in one. Limited resection was performed for a total of 903 patients, while comparable standard lobectomy was performed for 1887 patients. Overall classification of histologic types including additional 125 pneumonectomies in three studies (Harpole et al, 1995; Pastorino et al, 1997; Kwiatkowski et al, 1998) were 878 squamous cell carcinomas and 1617 nonsquamous cell carcinomas. Histologic types were not mentioned in two studies (Landreneau et al, 1997; Keenan et al, 2004) including 420 patients. Stages and tumour–nodes–metastasis (TNM) profiles of patients who underwent limited resection were IA (T1N0M0) and IB (T2N0M0).
Studies included were considered highly heterogeneous for the following reasons. The percentage of nonsquamous cell carcinoma in each study ranged from 39.7% (Hoffmann and Ransdell, 1980) to 90.5% (Koike et al, 2003). Further, the percentage of male patients in each study ranged from 50.6% (Koike et al, 2003) to 100% (Hoffmann and Ransdell, 1980). Percentages of squamous cell carcinoma in each study showed strong association with male gender (Figure 1, r=0.931, P<0.000l). The reason for limited resection differed from study to study; the most frequent reason was poor cardiopulmonary function in seven studies; limited resection was intentional in four studies and was part of an RCT design in one. The reason was not clearly mentioned in 3 studies. All of these differences might affect the respective studies and contribute to interstudy heterogeneity in the present meta-analysis.
A strong correlation is evident between percentages of squamous cell carcinoma in the various studies and those of male patients (r=0.931, P<0.0001).
Combined survival differences at 1, 3, and 5 years after resection were 0.7, 1.9, and 3.6%, respectively (Figure 2A–C). None of these combined survival differences were significant (see legend to Figure 2). Heterogeneity testing indicated that studies were heterogeneous at 3- and 5-year time points (see legend to Figure 2).
Meta-analysis of survival differences between limited resection and lobectomy. Bars, 95% CI of survival rates in patients with lobectomy minus those in patients with limited resection. Areas of squares are proportional to weights used for combining data. The centre of the lozenge gives the combined survival difference. The survival difference was considered statistically significant if the 95% CI for the overall survival difference did not overlap zero. (A) The combined survival difference at 1 year was 0.7% (95% CI, −0.8 to 2.1; P=0.3659). The 1-year survival rate was not available in studies by Harpole (1995) and Pastorino (1997). (B) The combined survival difference at 3 years was 1.9% (95% CI, −3.7 to 7.4; P=0.5088). The 3-year survival rate was not available in studies by Hoffmann (1980), Harpole (1995), and Pastorino (1997). (C) The combined survival difference at 5 years was 3.6% (95% CI, −0.4 to 10.5; P=0.3603). The 5-year survival rate was not available in studies by Landreneau (1997) and Keenan (2004). Q-statistics and P-value for the heterogeneity test at 1, 3, and 5 years were as follows: (Q=4.6, P=0.9471; Q=27.0, P=0.0026; and Q=33.6, P=0.0004).
Publication bias was not detected at 1, 3, or 5 years; all P-values >0.1; 0.5402, 0.1807, and 0.3633, respectively.
Discussion
The extent of lung resection most appropriate for small cancers has been discussed for a number of decades. Although limited resection for patients with poor cardiopulmonary reserve is regarded reasonable, intentional limited resection for patients expected to withstand standard lobectomy has not been established. We therefore performed a meta-analysis to examine published data. Some authors (Stewart and Parmar, 1993) are considering meta-analysis based on individual patient's data is the best. However, we did not take that approach because collecting all those data is hard to accomplish, and needs exhaustive labour.
As meta-analysis originally was developed to combine the results of RCTs (Yusuf et al, 1985), applying this methodology to suitability of limited resection for lung cancer is problematic. Since we could find only one RCT, we included additional 13 retrospective studies to obtain the summary statistics. Consequently, we found significant variation between studies for tumour size, distribution of histologic types, male/female ratio, reasons for limited resection, and details of the operation. All of these differences might contribute to interstudy heterogeneity, and indeed the heterogeneity test detected considerable heterogeneity between combined studies at time points 3 and 5 years after resection.
Publication bias (Egger et al, 1997) also is a problem in meta-analysis, but this was not detected in our present study; the selected articles apparently were reasonably representative of the actual average.
Combining 14 published reports, we concluded that while survival after lobectomy was slightly better than that after limited resection at 1, 3, and 5 years postoperatively, the differences were not statistically significant. Since most included articles were retrospective studies, we should interpret the present results carefully.
We believe that the most important factor affecting results in each study was the choice of indications for limited resection. In this meta-analysis, the most frequent reason was poor cardiopulmonary reserve. If so, overall survival in limited resection should be worse than that in lobectomy, since many poor-risk patients will die of diseases other than lung cancer. In a single-institution study, overall 5-year survival in patients undergoing limited resection because of such compromise (48%) was significantly lower than that of patients undergoing intentional limited resection (93%) (Kodama et al, 1997). However, if prognosis is evaluated by cancer-specific survival (CSS), the survival rate should be higher in compromised patients because expected deaths from lung cancer might be diminished by prior deaths from cardiopulmonary diseases. In the present study, since two studies (Read et al, 1990; Harpole et al, 1995) evaluated CSS after operation, good prognosis after limited resection might have been overevaluated. In most studies, limited resection was performed for smaller nodules than those resected by lobectomy, which in itself would favour better survival in the limited resection group, since the postoperative prognosis with IA disease is better than with IB. Specifications of operative procedures also are important. In intentional segmentectomy studies (Okada et al, 2001; Koike et al, 2003), nodal metastases were carefully sought during the operation, and cases with these were strictly excluded from limited resection. This procedure would yield a different limited resection group from that obtained by simple wedge resection without intraoperative nodal examination. Of 89 patients (tumour ⩽2 cm) scheduled for limited resection in an intentional study (Okada et al, 2001), 19 patients (21.3%) had to undergo different procedures because nodal involvement was found in 12 and local invasion was found in seven. A relatively high frequency of lymph node metastases from small lung cancers strongly suggests that tumour size alone is not a good criterion for limited resection.
Histologic type of the tumour also may affect results of limited resection. In our study (Nakamura et al, 2004), analyzsng 100 patients who underwent limited resection without systematic lymph node dissection, the overall 5-year survival rate for 73 patients with small adenocarcinomas (⩽2 cm) was 93.7%, which was significantly better than for those with larger adenocarcinomas (24.8%). In addition, we found the overall 5-year survival rate for patients with well-differentiated adenocarcinoma (81.2%) to be significantly better than for a group combining moderately and poorly differentiated adenocarcinomas (30.7%). Thus, in addition to tumour size, biologic characteristics importantly affect survival after limited resection. Since the most reliable results are likely to be those of the RCT, we believe that limited resection truly is inferior to lobectomy in terms of locoregional recurrence and survival in a study where eligibility for randomisation depends solely on tumour size (⩽3 or ⩽2 cm). However, we also would maintain that a subset of NSCLC can be resected completely by limited resection. One example would be a small, slowly growing, localised bronchioloalveolar carcinoma showing only ground-glass opacity (GGO) on computed tomography (Kaneko et al, 1996; Sone et al, 1998). In our opinion, these lesions can be resected completely by VATS wedge resection (Watanabe et al, 2002; Nakamura et al, 2004), given their low invasiveness and absence of lymph node metastases (Nakata et al, 2002).
In conclusion, the present meta-analysis of published data disclosed that survival after limited resection for stage I lung cancer is comparable to lobectomy. However, considerable heterogeneity among studies suggests that clinicopathologic features of patients who underwent limited resection in the studies analysed were quite different. We believe that some lung cancers can be cured by limited resection, if we can identify tumours of minimally invasive nature, such as small bronchioloalveolar carcinomas diagnosed by CT (Nakamura et al, 2004). Further clinicopathologic studies of the biologic nature of various lung cancers should help to address this problem.
Change history
16 November 2011
This paper was modified 12 months after initial publication to switch to Creative Commons licence terms, as noted at publication
References
Breyer R, Jensik R (1985) Lung-sparing operations in elderly patients. Ann ThoracSurg 40: 636–637
Campione A, Iigabue T, Luzzi L, Ghiribelli C, Voltolini L, Paladini P, Di BM, D’Agata A, Gotti G (2004) Comparison between segmentectomy and larger resection of stage IA non-small cell lung carcinoma. J Cardiovasc Surg (Torino) 45: 67–70
Date H, Andou A, Shimizu N (1994) The value of limited resection for ‘clinical’ stage I peripheral non-small cell lung cancer in poor-risk patients: comparison of limited resection and lobectomy by a computer-assisted matched study. Tumori 80: 422–426
DerSimonian R, Laird N (1986) Meta-analysis in clinical trials. Control Clini Trials 7: 177–188
Egger M, Smith G, Schneider M (1997) Bias in meta-analysis detected by a simple, graphical test. BMJ 315: 629–634
Errett L, Wilson J, Chiu R, Munro D (1985) Wedge resection as an alternative procedure for peripheral bronchogenic carcinoma in poor-risk patients. J Thorac Cardiovasc Surg 90: 656–661
Ginsberg R, Rubinstein L (1995) Randomized trial of lobectomy versus limited resection for T1 N0 non-small cell lung cancer. Lung Cancer Study Group. Ann Thorac Surg 60: 615–622; discussion 622–623
Harpole D, Herndon J, Young W, Wolfe W, Sabiston D (1995) Stage I nonsmall cell lung cancer. A multivariate analysis of treatment methods and patterns of recurrence. Cancer 76: 787–796
Hoffmann T, Ransdell H (1980) Comparison of lobectomy and wedge resection for carcinoma of the lung. J Thorac Cardiovasc Surg 79: 211–217
Jensik R (1987) Miniresection of small peripheral carcinomas of the lung. Surg Clin North Am 67: 951–958
Jensik R, Faber L, Milloy F, Monson D (1973) Segmental resection for lung cancer. A fifteen-year experience. J Thorac Cardiovasc Surg 66: 563–572
Kaneko M, Eguchi K, Ohmatsu H, Kakinuma R, Naruke T, Suemasu K, Moriyama N (1996) Peripheral lung cancer: screening and detection with low-dose spiral CT versus radiography. Radiology 201: 798–802
Keenan R, Landreneau R, Maley R, Singh D, Macherey R, Bartley S, Santucci T (2004) Segmental resection spares pulmonary function in patients with stage I lung cancer. Ann Thorac Surg 78: 228–233
Kodama K, Doi O, Higashiyama M, Yokouchi H (1997) Intentional limited resection for selected patients with T1 N0 M0 non-small-cell lung cancer: a single-institution study. J Thorac Cardiovasc Surg 114: 347–353
Koike T, Yamato Y, Yoshiya K, Shimoyama T, Suzuki R (2003) Intentional limited pulmonary resection for peripheral T1 N0 M0 small-sized lung cancer. J Thorac Cardiovasc Surg 125: 924–928
Kwiatkowski D, Harpole D, Godleski J, Herndon J, Shieh D, Richards W, Blanco R, Xu H, Strauss G, Sugarbaker D (1998) Molecular pathologic substaging in 244 stage I non-small-cell lung cancer patients: clinical implications. J Clin Oncol 16: 2468–2477
Landreneau R, Sugarbaker D, Mack M, Hazelrigg S, Luketich J, Fetterman L, Liptay M, Bartley S, Boley T, Keenan R, Ferson P, Weyant R, Naunheim K (1997) Wedge resection versus lobectomy for stage I (T1 N0 M0) non-small-cell lung cancer. J Thorac Cardiovasc Surg 113: 691–698; discussion 698–700
Le Roux B (1972) Management of bronchial carcinoma by segmental resection. Thorax 27: 70–74
Lederle F (1996) Lobectomy versus limited resection in T1 N0 lung cancer. Ann Thorac Surg 62: 1249–1250
Miller D, Rowland C, Deschamps C, Allen M, Trastek V, Pairolero P (2002) Surgical treatment of non-small cell lung cancer 1 cm or less in diameter. Ann Thorac Surg 73: 1545–1550; discussion 1550–1551
Mitsudomi T, Hamajima N, Ogawa M, Takahashi T (2000) Prognostic significance of p53 alterations in patients with non-small cell lung cancer: a meta-analysis. Clin Cancer Res 6: 4055–4063
Nakamura H, Saji H, Ogata A, Saijo T, Okada S, Kato H (2004) Lung cancer patients showing pure ground-glass opacity on computed tomography are good candidates for wedge resection. Lung Cancer 44: 61–68
Nakata M, Saeki H, Takata I, Segawa Y, Mogami H, Mandai K, Eguchi K (2002) Focal ground-glass opacity detected by low-dose helical CT. Chest 121: 1464–1467
Okada M, Yoshikawa K, Hatta T, Tsubota N (2001) Is segmentectomy with lymph node assessment an alternative to lobectomy for non-small cell lung cancer of 2 cm or smaller? Ann Thorac Surg 71: 956–960, discussion 961
Pastorino U, Andreola S, Tagliabue E, Pezzella F, Incarbone M, Sozzi G, Buyse M, Menard S, Pierotti M, Rilke F (1997) Immunocytochemical markers in stage I lung cancer: relevance to prognosis. J Clin Oncol 15: 2858–2865
Pastorino U, Valente M, Bedini V, Infante M, Tavecchio L, Ravasi G (1991) Limited resection for Stage I lung cancer. Eur JSurg Oncol 17: 42–46
Read R, Yoder G, Schaeffer R (1990) Survival after conservative resection for T1 N0 M0 non-small cell lung cancer. Ann Thorac Surg 49: 391–398; discussion 399–400
Sone S, Takashima S, Li F, Yang Z, Honda T, Maruyama Y, Hasegawa M, Yamanda T, Kubo K, Hanamura K, Asakura K (1998) Mass screening for lung cancer with mobile spiral computed tomography scanner. Lancet 351: 1242–1245
Stair J, Womble J, Schaefer R, Read R (1985) Segmental pulmonary resection for cancer. Am JSurg 150: 659–664
Stewart LA, Parmar MK (1993) Meta-analysis of the literature or of individual patient data: is there a difference? Lancet 341: 418–422
Sugarbaker D, Strauss G (2000) Extent of surgery and survival in early lung carcinoma: implications for overdiagnosis in stage IA nonsmall cell lung carcinoma. Cancer 89: 2432–2437
Temeck B, Schafer P, Saini N (1992) Wedge resection for bronchogenic carcinoma in high-risk patients. South Med J 85: 1081–1083
Tsubota N, Ayabe K, Doi O, Mori T, Namikawa S, Taki T, Watanabe Y (1998) Ongoing prospective study of segmentectomy for small lung tumors. Study Group of Extended Segmentectomy for Small Lung Tumor. Ann Thorac Surg 66: 1787–1790
Warren W, Faber L (1994) Segmentectomy versus lobectomy in patients with stage I pulmonary carcinoma. Five-year survival and patterns of intrathoracic recurrence. J Thorac Cardiovasc Surg 107: 1087–1093; discussion 1093–1094
Watanabe S, Watanabe T, Arai K, Kasai T, Haratake J, Urayama H (2002) Results of wedge resection for focal bronchioloalveolar carcinoma showing pure ground-glass attenuation on computed tomography. Ann Thorac Surg 73: 1071–1075
Yusuf S, Peto R, Lewis J, Collins R, Sleight P (1985) Beta blockade during and after myocardial infarction: an overview of the randomized trials. Prog Cardiovasc Dis 27: 335–371
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
From twelve months after its original publication, this work is licensed under the Creative Commons Attribution-NonCommercial-Share Alike 3.0 Unported License. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc-sa/3.0/
About this article
Cite this article
Nakamura, H., Kawasaki, N., Taguchi, M. et al. Survival following lobectomy vs limited resection for stage I lung cancer: a meta-analysis. Br J Cancer 92, 1033–1037 (2005). https://doi.org/10.1038/sj.bjc.6602414
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/sj.bjc.6602414
Keywords
This article is cited by
-
Quality of life after lung cancer surgery: sublobar resection versus lobectomy
BMC Surgery (2023)
-
One-step nucleic acid amplification for intraoperative diagnosis of lymph node metastasis in lung cancer patients: a single-center prospective study
Scientific Reports (2022)
-
Feasibility of limited resection for peripheral small-sized non-small cell lung cancer: a retrospective single-center-based study
Journal of Cancer Research and Clinical Oncology (2021)
-
Surgical treatment to multiple primary lung cancer patients: a systematic review and meta-analysis
BMC Surgery (2019)
-
Progress in the Treatment and Outcomes for Early-Stage Non-Small Cell Lung Cancer
Lung (2018)
