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Cancer Research and Treatment > Volume 50(4); 2018 > Article
Kim, Won, Park, Kim, Kim, Oh, Sohn, Kang, and Lee: Effect of Adjuvant Chemotherapy on Stage II Colon Cancer: Analysis of Korean National Data

Abstract

Purpose

Debates exist regarding the effectiveness of adjuvant chemotherapy for stage II colon cancer. This study aimed to investigate the current status of adjuvant chemotherapy and its impact on survival for Korean stage II colon cancer patients by analyzing the National Quality Assessment data.

Materials and Methods

A total of 7,880 patientswho underwent curative resection for stage II colon adenocarcinoma between January 2011 andDecember 2014 in Koreawere selected randomly as evaluation subjects for the quality assessment. The factors that influenced overall survival were identified. The high-risk group was defined as having at least one of the following: perforation/obstruction, lymph node harvest less than 12, lymphovascular/perineural invasion, positive resection margin, poor differentiation, or pathologic T4 stage.

Results

The median follow-up period was 38 months (range, 1 to 63 months). Chemotherapy was a favorable prognostic factor for either the high- (hazard ratio [HR], 0.76; 95% confidence interval [CI], 0.38 to 0.59; p < 0.001) or low-risk group (HR, 0.74; 95% CI, 0.61 to 0.89; p=0.002) in multivariate analysis. This was also the case in patients over 70 years of age. The hazard ratio was significantly increased as the number of involved risk factors was increased in patients who didn’t receive chemotherapy. Adding oxaliplatin showed no difference in survival (HR, 1.36; 95% CI, 0.91 to 2.03; p=0.132).

Conclusion

Adjuvant chemotherapy can be recommended for stage II colon cancer patients, but the addition of oxaliplatin to the regimen must be selective.

Introduction

The benefit of adjuvant chemotherapy (AC) for stage III colon cancer is well-established. However, it is debatable for stage II [1-4]. Conclusive randomized controlled trials are lacking, and retrospective small cohort studies have reported conflicting results. The estimated number of needed patients is approximately 5,000 to 8,000 to reliably detect a treatment benefit for AC in stage II colon cancer, with 90% of power and 18% relative risk reduction as shown in the NSABP C-01 to C-04 trials [5]. Therefore, it is difficult to obtain the answer to this question through a successful randomized controlled trial.
Despite the limitations of its retrospective design, a study dealing with a nation-wide large scale cohort might answer this question. Recent studies [6-9] that have analyzed data including approximately 2,000 to 150,000 patients with stage II colon cancer have been part of that effort. These studies allow the general patient trends to be identified and minimize the limitations of the retrospective study.
In Korea, the Health Insurance Review and Assessment Service (HIRA), a national government agency, has been evaluating the appropriateness of care for colorectal cancer since 2011, and this initiated large scale data collection about patient baseline characteristics and colorectal cancer management. Our study aimed to investigate the current status and efficacy of AC for stage II colon cancer patients in Korea by analyzing these data.

Materials and Methods

1. Data source: National Quality Assessment program in Korea

In the Korean public health system, the HIRA assesses the appropriateness of the cost of medical services provided by medical institutions and determines the costs to be paid by the National Health Insurance Service. Based on the data that can be obtained through the review process, the HIRA started to evaluate the appropriateness of the treatment of medical institutions for the major diseases, so-called the “National Quality Assessment”, and the target diseases have been expanded. The National Quality Assessment program aims to improve the quality of care by giving feedback to medical institutions.
Quality assessment for colorectal cancer treatment has been conducted since 2011. Patients who were diagnosed with colorectal cancer and were charged for the surgical treatment were selected for the evaluation. For the institutions that had more than 150 cases, 150 cases among all cases were randomly selected using computer randomization for each institutional cases. If the institution had less than 150 cases for the examining year, all patients were selected, and their data were sent to the HIRA (however, the reference value was 100 cases for the year 2011 for administrational reasons, not medical or statistical reasons). The National Quality Assessment data are formulated based on the colorectal cancer questionnaire with 21 criteria presented by the HIRA, and information about patient baseline characteristics (admission date, diagnosis, operation name, discharge date, weight, height, etc.), surgery (past surgical history, emergency, the American Society of Anesthesiologists [ASA] grade, completeness of surgery, etc.), pathologic report, and chemotherapy (timing, regimen, usage, etc.) are required to be submitted for the questionnaire.
The total treatment quality grade is determined by a formula calculated for each item in the questionnaire, and the medical institutions are divided into five groups according to this grade. Each year, this rating is officially announced to the general public, so medical institutions are encouraged to actively participate in the National Quality Assessment program. Details of the assessment and its results are available on the internet, but only as Korean version (http://www.hira.or.kr→hospital/pharmacy→hospital evaluation information→evaluation items: surgery, detailed field: colorectal cancer→assessment report).

2. Patient selection and chemotherapy

The purpose of this study was to analyze the patients who underwent curative treatment for stage II colon cancer. Therefore, the following patients were excluded from a total 8,639 patients who underwent surgery for colon cancer in 2011-2014 and submitted for the National Quality Assessment: patients without R0 resection or no data, patients who had received chemotherapy prior to surgery, patients who didn’t have the data about any of the risk factor checked specifically in that evaluating year (however, patients were not excluded when there is no data about the status of specific risk factor which was not officially checked for the National Quality Assessment in that evaluating year, patients whose survival could not be confirmed, and those who died within 1 month postoperatively). As a result, a total 7,880 patients were included in the final analysis. The decision to perform chemotherapy was based on the clinical judgment of the medical staff, but it was recommended that 5-fluorouracil (FU) based therapy (with or without oxaliplatin) be started within 8 weeks after surgery when using chemotherapy.

3. Measured outcome

The primary outcome was overall survival (OS). The OS was calculated from the operation date to the date of death or July 15, 2016 on which survival was finally verified. Survival was confirmed by the termination of health insurance. Patient age, sex, body mass index (BMI), university hospital treatment or not, hospital scale, the ASA grade and emergency surgery or not were presented as baseline data. Known risk factors for survival such as obstruction/perforation, positive resection margin, lymphovascular or perineural invasion, lymph node (LN) harvest less than 12, and pathologic T4 grade were checked selectively according to each year. The patients who had at least one of these factors were placed in the high risk group and those who did not in the low risk group (Table 1).

4. Statistical analysis

The clinical characteristics of patients were expressed as number (%) for categorical variables. Differences between categorical variables were analyzed using the chi-square test or Fisher exact test. The prognostic significance of demographic and pathologic characteristics were determined using univariable and multivariable Cox proportional hazard regression analyses. For cox proportional hazard regression analysis, supremum test for proportionals hazards assumption was performed for checking assumption and it was judged to satisfy the assumption by presenting p ≥ 0.05. Two-sided p-values of < 0.05 were considered statistically significant.
All statistical analyses were performed using the software package SAS Enterprise Guide ver. 6.1 (SAS Institute, Inc., Cary, NC), R software ver. 3.0.2 (R Foundation for Statistical Computing, Vienna, Austria; http://www.r-project.org) with the support and supervision of the Clinical Research Coordinating Center of the Catholic University of Korea which consisted of statistical experts.

Results

1. Patient characteristics

Of the total 7,880 patients, 4,645 (59.0%) were males, and 3,414 (43.3%) were over 70 years of age. ASA classification I-II was 6,461 (82.0%), and emergency surgeries were performed in 616 (7.8%). There were 2,196 patients (27.9%) in the high risk group, and 5,684 (72.1%) in the low risk group. Among the high risk group, 1,900 (86.5%) had one risk factor, 280 (12.8%) had two, and 16 (0.7%) had more than three.
In the high risk group, 1,333 (60.7%) received AC, whereas 2,758 (48.5%) of the low-risk patients received AC. Males, 70 years of age or younger, BMI over 18, and the ASA classification I-II were more likely to receive AC in the entire cohort. More AC was performed for the low risk group patients in the general hospitals than in tertiary hospitals. In the high risk group, the patients who underwent emergent surgery or had more than one risk factor were less likely to receive AC. The proportion of patients who received AC was higher when there was lymphovascular or perineural invasion, or pathologic T4 grade, but the differentiation had no effect on whether patients received AC. Patients who had negative resection margin or LN harvest more than 12 received AC more (Table 2).

2. Effect of AC on survival in the whole patients

The median follow-up period was 38 months (range, 1 to 63 months). Death was occurred in 866 patients (11.0%) during the study period. The OS was higher in patients with AC (hazard ratio [HR], 0.48; 95% confidence interval [CI], 0.42 to 0.55; p < 0.001), female, younger, BMI over 18, tertiary hospital, and ASA grade I-II in univariate analysis. In terms of risk factors, emergency surgery caused by obstruction or perforation, lymphovascular or perineural invasion, harvested LNs less than 12, and pathologic T4 grade had an adverse effect on survival, but positive margin or differentiation did not. The more the risk factors involved, the lower the survival rate.
In the multivariate analysis, the effects of individual risk factors and AC were not analyzed because the presence or absence of risk factors and with or without AC were divided into four categories and then analyzed. This analysis showed that male gender, age greater than 70, BMI 18 or less and greater than 25, general hospital treatment and ASA grade over II had adverse effects on the OS (Table 3).
When the group of patients who had no risk factors and did not receive AC was used as a reference category, the HR was decreased in cases of receiving AC in patients who had no risk factors (adjusted HR, 0.73; 95% CI, 0.60 to 0.87; p=0.001). On the contrary, when the patient who had risk factors did not receive AC, the HR was increased (adjusted HR, 1.73; 95% CI, 1.43 to 2.10; p < 0.001). However, the hazard ratio showed no significant difference compared with the reference group when the high risk group patients received AC (adjusted HR, 0.84; 95% CI, 0.68 to 1.04; p=0.115) (Fig. 1).

3. Effect of AC on survival in the low-risk group

For the low-risk group, AC, female, aged 70 or younger, BMI 18 or less and greater than 25, tertiary hospital treatment (compared to general hospital), and ASA grade I-II were favorable factors for survival either in the univariate and multivariate analysis (Table 4, S1 Table). In particular, AC was shown to reduce the relative risk of death by 26% after adjusting for the effects of other factors (HR, 0.74; 95% CI, 0.61 to 0.89; p=0.002) (Fig. 2A).

4. Effect of AC on survival in the high-risk group

Whether the patient received AC, the number of involved risk factors, age, BMI, ASA grade, and emergency surgery were the identified factors that had significant impact on survival in univariate analysis of the high-risk patients (S1 Table). However, individual known risk factors such as obstruction/perforation, positive resection margin, lymphovascular or perineural invasion, harvested LNs less than 12, poor differentiation, or pathologic T4 stage did not affect survival. The results of multivariate analysis are presented as Table 4.
The multivariate analysis revealed that without AC (HR of AC, 0.76; 95% CI, 0.38 to 0.59; p < 0.001), male, age greater than 70, BMI 18 or less and greater than 25, and ASA grade over II worsened the survival outcome (Table 4, Fig. 2B).

5. Relationship between chemotherapy and number of involved risk factors in high-risk group

The effect of the number of involved risk factors on survival in patients receiving chemotherapy and those not receiving chemotherapy was examined (Table 5). In the multivariate analysis in which the sex, age, BMI, type of institutions, ASA grade, and emergency operation were adjusted, the hazard ratio was significantly increased as the number of involved risk factors increased in patients who did not receive AC (when the patients with no involved risk factors was the reference group, an HR of one involved risk factor was 1.59 [95% CI, 1.29 to 1.96], p < 0.001, HR of two or more of involved risk factors was 1.67 [95% CI, 1.19 to 2.36], p=0.003). However, there was no survival difference between no risk factors involved and one risk factor involved in patients who received AC (HR, 1.16; 95% CI 0.90 to 1.50; p=0.249), though more than two involved risk factors significantly worsened survival outcome (HR, 2.53; 95% CI, 1.63 to 3.92; p < 0.001).

6. AC for patients older than 70 years of age

There were 2,535 low-risk and 1,122 high-risk patients among the patients aged 70 years or older. After adjustment for sex, age, BMI, type of institutions, ASA grade and emergency surgery (and number of risk in the high-risk group), AC was an independent prognostic factor for survival in both the low-risk (HR, 0.75; 95% CI, 0.60 to 0.94; p=0.012) and the high-risk (HR, 0.48; 95% CI, 0.37 to 0.63; p < 0.001) groups (Table 6).

7. Effect of adding oxaliplatin to chemotherapy regimen

Comparisons of OS were made according to the different chemotherapy regimens among the high-risk group patients (Table 7). There were a total of 1,333 high-risk patients who received AC in the study period, and among them, 174 patients were excluded from the analysis because they used more than two of the recommended regimens or their regimen was not covered by the National Health Insurance system during the whole study period. Among the remaining 1,159 high-risk patients, 592 patients received 5-FU‒based AC without oxaliplatin (5-FU/leucovorine, capecitabine, tegafur-uracil/leucovorin, LV5FU2), and the other 567 patients received oxaliplatin (FLOX, FOLFOX, mFOLFOX). After adjustment for other factors, there was no significant difference in OS between the two groups (HR, 1.36; 95% CI, 0.91 to 2.03; p=0.132).

Discussion

The most important result of this study was that AC was revealed to have favorable effect on survival for Korean stage II colon cancer patients regardless of their high- or low-risk group assignments. This is consistent with the randomized controlled trial of the Quasar Collaborative Group [2], which reported a 16% reduction in all-cause mortality using LF chemotherapy for stage II colorectal cancer, and the study of Casadaban et al. [6], which reported that AC was a favorable prognostic factor in both the high-risk and low-risk groups based on 153,000 American stage II colon cancer patients.
However, there are still many contradictory results from other recently published papers. A study analyzing a large dataset of 2,488 Canadian patients reported that AC had no effect on survival either for the high-risk patients or the whole patient cohort [7]. Verhoeff et al. [9] and Kumar et al. [10] analyzed 10,935 and 1,697 patients, respectively, and concluded that only pathologic T4 stage among the risk factors necessitated AC. In particular, the later showed that AC in the low-risk group could decrease the relapsing free survival. Lewis et al. [11] announced that AC in stage II colon cancer could decrease both the overall and disease-free survival after following up 453 patients for 2 years by e-mails.
Because of these conflicting results, the current consensus guidelines such as the American Society for Clinical Oncology, the European Society for Medical Oncology and the National Comprehensive Cancer Network [12-14] are ambiguous about the chemotherapy for stage II colon cancer (using expressions like “not routinely recommended”, “can be considered”, etc.), and the chemotherapy is mainly devoted to the clinical judgment of individual medical staff or institution.
The reasons why the study results are confusing may be as follows. First, the characteristics of patients involved in each study could be different because stage II colon cancer has a diverse clinico-pathologic spectrum. Second, the definitions for high- and low-risk groups could be different. Third, the primary outcome of each study could be different. Finally, the treatment outcome of colon cancer can be influenced by other factors such as race, economy scale of the society, medical insurance system, lifestyle, and culture.
Hence, these potential biases must be considered when comparing heterogenous results to that of our study. It must be recognized that big data reflects both the medical and non-medical characteristics of a society. The EURECA study, which analyzed approximately 60,000 patients from seven European countries who had similar racial and social characteristics showed survival differences among the countries after the treatment for stage II colon cancer [8].
The high proportion of patients who received AC is one way in which our study differs from others. The chemotherapy rate was 59.4% for the high-risk group and 48.2% for the low-risk group in our study, whereas it was only 21.7% to 29% for the high-risk patients in the western countries [6-8,10]. This is probably due to the Korean Clinical Practice Guideline for Colon and Rectal Cancer (http://www.colon.or.kr/index.html, only Korean version exists). The Korean guideline recommends observation or use of fluoropyrimidine-based chemotherapy for the low-risk patients, and AC, especially the FOLFOX regimen for the high-risk patients in Korea. Our study could analyze relatively more data on patients receiving chemotherapy because of this differential recommendation.
To identify whether our results are consistent with the results of previous studies, it is necessary to compare them with those of racially and socially similar groups. Therefore, it is meaningful that a previous small study with Korean stage II colon cancer patients and the Japanese, which have similar genetic compositions to that of Koreans, presented similar results. Jee et al. [12] performed a study with 363 Korean stage II colon cancer patients and announced that AC was a significantly favorable prognostic factor for survival in both the low- and high-risk groups. Sato et al. [13] reported that AC was an independent prognostic factor for all patients, and the survival rate of some high-risk group patients was significantly higher.
Our study showed that AC lowered the risk of death by 26% in the low-risk patients and by 24% in the high-risk group, even after controlling for the effects of other variables, such as age, gender, BMI, ASA, and other risk factors. If high-risk patients did not receive the chemotherapy, the risk of death increased by more than 170% in the low-risk patients who did not receive the chemotherapy. On the contrary, the risk of death in high-risk patients was similar to that of low-risk patients without the chemotherapy when they received the chemotherapy. In patients without the chemotherapy, the HR increased as the involved number of risk factors increased. However, in patients who received chemotherapy, involving one more risk factor did not lead to a significant increase in hazard ratio. This means the more the risk factors involved, the worse the survival rate, and chemotherapy can offset this effect to some degree. This was also seen in the results from previous studies [6,9].
In a subgroup analysis of patients aged 70 years or older, AC was found to have a positive effect on survival. Because of possible adverse effects on survival due to the side effects of chemotherapeutic agents, chemotherapy is not recommended for elderly patients. However, the use of AC for older patients in stage III colon cancer has been shown to increase survival [14-16]. Although Hernosillo-Rodriguez et al. [17] showed the effect of AC in elderly patients in their study of high risk stage II and stage III colon cancer patients, this study is the first to analyze the effectiveness of AC in elderly stage II colon cancer patients to the author’s knowledge. It is important to note that the survival rates of elderly patients with AC were significantly higher in both the low- and high-risk groups.
Another issue in chemotherapy for stage II colon cancer is the addition of oxaliplatin to the regimen. In the 1990s, fluorouracil-based AC for stage III colon cancer was found to have a beneficial effect on survival [18,19], and after about 10 years, the advantage of adding oxaliplatin was well established for stage III colon cancer [20-22]. However, it is vague for stage II colon cancer because data from stage II patients were usually analyzed with those of stage III patients as in NSABP study [22] or Gill et al. [23] There was no difference in OS among the regimens in the MOSAIC study [21]. The ACCENT study [20], which is a pooled analysis of randomized controlled trials, also concluded that the addition of oxaliplatin did not affect the OS. This was also the case in a recent study of 153,000 patients [6]. However, the Korean recommendation for colorectal cancer treatment is primarily to add oxaliplatin to the high-risk patients.
Our study revealed that there was no survival difference between the 592 patients without oxaliplatin and the 567 patients with oxaliplatin in high risk group patients through the multivariate analysis. It is quite a small number to be conclusive. However, adding oxaliplatin to chemotherapy regimen increases the medical cost and the risk of neurotoxicity up to 50% in patients, which significantly reduces the quality of life [24]. Hence, addition of oxaliplatin to the chemotherapeutic regimen for stage II colon cancer must be cautious until solid evidence is established. In other words, it can be used when there are many risk factors involved, when a patient actively agrees with the oxaliplatin usage after full explanation about the uncertain survival benefit and the possibility of neurotoxicity.
The limitations of this study are as follows. First, selection bias could have occurred from its retrospective design. The fact that the chemotherapy was more prevalent in male patients less than 70 years of age and ASA grade I or II patients may indicate the patients who were healthy enough to receive the chemotherapy and therefore had a higher chance of survival would have received the chemotherapy. However, our results demonstrated that chemotherapy was still a significant factor for OS even after adjustment for the effects of these factors. Second, the big data itself presents a limitation. We could not confirm whether the AC was on a complete schedule. Therefore, it is assumed that chemotherapy was completed when the chemotherapy was just started. Also, cancer recurrence was not checked, and the checked risk factor variables were different for each evaluation period. Therefore, there was many missing data, and of the patients classified as low-risk groups, in fact, there may be patients might have been classified as high-risk group if all needed variables had been checked. The analysis about the effect of number of involved risk factors could also be biased. Because the patients included in the definition of high risk group differed by year, we examined the effect of chemotherapy on high-risk and low-risk patients after adjusting the effect of year variable (S2 Table). Regardless of the year (except only for the low risk group of year 2011), chemotherapy showed a significant benefit in survival. Third, the follow-up period was relatively short. Follow-up periods of more than 5 years would be necessary to fully confirm the impact of therapy on survival. However, we expect that the tendency of the survival curve is difficult to change according to the results of ACCENT trial [20], which showed that the risk of death was highest 2 years after the treatment, stable between 2-4 years, and then diminished after 4 years. Median follow-up periods of more than 3 years of our study may be enough, but we are planning the following study with same data for the longer follow-up period. Fourth, other factors that could affect the treatment outcome of stage II colon cancer were not included. Responses to chemotherapy or survival rate may be different according to MSI status, and socioeconomic status of individual may also affect treatment outcome [25,26].
Despite these limitations, this study is meaningful for the first analysis of the status and results of treatment for stage II colon cancer in Korea through nation-wide data. The results showed that the AC was the independent favorable prognostic factor for survival for the stage II colon cancer patients regardless of age, risk-group status, and chemotherapy regimen.
In conclusion, this study suggests that AC for stage II colon cancer patients would be beneficial. However, addition of oxaliplatin to the chemotherapeutic regimen must be selective until sufficient evidence to prove its survival benefit are accumulated. Additional follow-up data need to be analyzed, and a prospective multicenter trial can be considered based on these data.

Electronic Supplementary Material

Supplementary materials are available at Cancer Research and Treatment website (http://www.e-crt.org).

Conflicts of Interest

Conflict of interest relevant to this article was not reported.

Fig. 1.
Adjusted survival probability curve from multi-variate cox regression analysis of four categories classified according to the risk status and adjuvant chemotherapy (AC) in the whole patients. Survival probability was adjusted for sex, age, body mass index, type of institutions, American Society of Anesthesiologists, and emergency operation. HR, hazard ratio; CI, confidence interval.
crt-2017-194f1.gif
Fig. 2.
Adjusted survival curve of stage II colon cancer patients according to the chemotherapy. (A) Low-risk group (adjusted for sex, age, body mass index [BMI], type of institutions, American Society of Anesthesiologists [ASA], and emergency operation). (B) High-risk group (adjusted for number of risk, sex, age, BMI, type of institutions, ASA, and emergency operation). AC, adjuvant chemotherapy; HR, hazard ratio; CI, confidence interval.
crt-2017-194f2.gif
Table 1.
Variables checked for defining high-risk patients at each measuring year
2011 2012 2013-2014
Harvested lymph nodes < 12 + + +
Obstruction/Perforation + + +
Lymphovascular/Perineural invasion +
Positive resection margin + +
Poorly differentiation + +
Pathologic T4 +

“+” means having data, while “–“ means having no data about the variable.

Table 2.
Baseline characteristics of the patients with stage II colon cancer
Overall (n=7,880) Low-risk (n=5,684)
High-risk (n=2,196)
Low-risk group (without AC vs. with AC)
High-risk group (without AC vs. with AC)
Without AC (n=2,926) With AC (n=2,758) Without AC (n=863) With AC (n=1,333) p-value p-value
Sex
 Male 4,645 (59.0) 1,680 (57.4) 1,677 (60.8) 438 (50.8) 850 (63.8) 0.009 < 0.001
 Female 3,235 (41.0) 1,246 (42.6) 1,081 (39.2) 425 (49.3) 483 (36.2)
Age (yr)
 ≤ 45 371 (4.7) 96 (3.3) 182 (6.6) 10 (1.2) 83 (6.2) < 0.001 < 0.001
 > 45 and ≤ 70 4,095 (52.0) 1,317 (45.0) 1,726 (62.6) 270 (31.3) 782 (58.7)
 > 70 3,414 (43.3) 1,513 (51.7) 850 (30.8) 583 (67.6) 468 (35.1)
BMI (n=7,823)
 ≤ 18 408 (5.2) 164 (5.6) 109 (4.0) 69 (8.2) 66 (5.0) 0.012 < 0.001
 > 18 and ≤ 25 5,217 (66.7) 1,895 (65.2) 1,840 (67.0) 599 (70.9) 883 (66.6)
 > 25 2,198 (28.1) 847 (29.2) 797 (29.0) 177 (21.0) 377 (28.4)
Type of institution
 Tertiary hospital 4,072 (51.7) 1,749 (59.8) 1,344 (48.7) 383 (44.4) 596 (44.7) < 0.001 0.930
 General hospital 3,408 (43.3) 1,031 (35.2) 1,230 (44.6) 451 (52.3) 696 (52.2)
 Hospital or clinic 400 (5.1) 146 (5.0) 184 (6.7) 29 (3.4) 41 (3.1)
ASA
 I-II 6,461 (82.0) 2,340 (80.0) 2,418 (87.7) 585 (67.8) 1,118 (83.9) < 0.001 < 0.001
 III 1,351 (17.1) 565 (19.3) 332 (12.0) 252 (29.2) 202 (15.2)
 IV 68 (0.9) 21 (0.7) 8 (0.3) 26 (3.0) 13 (1.0)
Emergency operation
 No 7,264 (92.2) 2,904 (99.3) 2,736 (99.2) 581 (67.3) 1,043 (78.2) 0.844 < 0.001
 Yes 616 (7.8) 22 (0.8) 22 (0.8) 282 (32.7) 290 (21.8)
  Others 79 (12.8) 22 (100) 22 (100) 13 (4.6) 22 (7.6) 0.138
  Perforated/Obstructive 537 (87.2) 0 0 269 (95.4) 268 (92.4)
Resection margin (n=6,470)
 Negative 6,398 (98.9) 2,582 (100) 2,455 (100) 515 (93.5) 846 (95.9) - 0.039
 Positive 72 (1.1) 0 0 36 (6.5) 36 (4.1)
LVP invasion (n=1,369)
 No 739 (54.0) 336 (100) 289 (100) 67 (22.3) 47 (10.6) - < 0.001
 Yes 630 (46.0) 0 0 233 (77.7) 397 (89.4)
Lymph node (n=7,494)
 < 12 511 (6.8) 0 0 227 (30.7) 284 (23.7) - 0.001
 ≥ 12 6,983 (93.2) 2,869 (100) 2,869 (100) 513 (69.3) 915 (76.3)
Differentiation (n=3,488)
 Well 572 (16.4) 212 (18.7) 173 (14.2) 89 (18.9) 98 (14.6) 0.003 0.158
 Moderate 2,760 (79.1) 920 (81.3) 1,042 (85.8) 319 (67.7) 479 (71.5)
 Poorly+others 156 (4.5) 0 0 63 (13.4) 93 (13.9)
Stage (n=4,392)
 IIA 3,789 (86.3) 1,794 (100) 1,543 (100) 210 (53.6) 242 (36.5) - 0.001
 IIB-IIC 603 (13.7) 0 0 182 (46.4) 421 (63.5)
No. of risks
 0 5,684 (72.1) 2,926 (100) 2,758 (100) 0 0 - 0.012
 1 1,900 (24.1) 0 0 725 (84.0) 1,175 (88.2)
 2 280 (3.6) 0 0 129 (15.0) 151 (11.3)
 3 or 4 16 (0.2) 0 0 9 (1.0) 7 (0.5)

Values are presented as numbers (%). AC, adjuvant chemotherapy; BMI, body mass index; ASA, American Society of Anesthesiologists; LVP, lymphovascular or perineural.

Table 3.
Univariate and multivariate analysis of risk factors for survival in whole patients
Alive (n=7,014) Death (n=866) Univariate analysis
Multivariate analysis
HR (95% CI) p-value HR (95% CI) p-value
Adjuvant chemotherapy
 Without AC 3,234 (85.4) 555 (14.6) Reference
 With AC 3,780 (92.4) 311 (7.6) 0.48 (0.42-0.55) < 0.001
No. of risks
 0 5,198 (91.4) 486 (8.6) Reference
 1 1,600 (84.2) 300 (15.8) 1.75 (1.52-2.02) < 0.001
 2 206 (73.6) 74 (26.4) 3.08 (2.41-3.93) < 0.001
 3 or 4 10 (62.5) 6 (37.5) 4.44 (1.99-9.94) < 0.001
  Low-risk (< 1) 5,198 (91.4) 486 (8.6) Reference
  High-risk (≥ 1) 1,816 (82.7) 380 (17.3) 1.93 (1.69-2.21) < 0.001
Combination of risk and AC
 Low-risk and without AC 2,616 (89.4) 310 (10.6) Reference Reference
 Low-risk and with AC 2,582 (93.6) 176 (6.4) 0.56 (0.47-0.68) < 0.001 0.73 (0.60-0.87) 0.001
 High-risk and without AC 618 (71.6) 245 (28.4) 2.65 (2.24-3.13) < 0.001 1.73 (1.43-2.10) < 0.001
 High-risk and with AC 1,198 (89.9) 135 (10.1) 0.85 (0.69-1.04) 0.106 0.84 (0.68-1.04) 0.115
Sex
 Male 4,096 (88.2) 549 (11.8) Reference Reference
 Female 2,918 (90.2) 317 (9.8) 0.82 (0.71-0.94) 0.004 0.66 (0.57-0.76) < 0.001
Age (yr)
 ≤ 45 361 (97.3) 10 (2.7) Reference Reference
 > 45 and ≤ 70 3,873 (94.6) 222 (5.4) 2.05 (1.09-3.87) 0.026 1.92 (1.02-3.63) 0.044
 > 70 2,780 (81.4) 634 (18.6) 7.92 (4.24-14.8) < 0.001 5.44 (2.90-10.20) < 0.001
BMI (n=7,823)
 ≤ 18 317 (77.7) 91 (22.3) 2.23 (1.79-2.78) < 0.001 1.77 (1.41-2.21) < 0.001
 > 18 and ≤ 25 4,614 (88.4) 603 (11.6) Reference Reference
 > 25 2,043 (93.0) 155 (7.1) 0.59 (0.49-0.70) < 0.001 0.73 (0.61-0.87) 0.001
Type of institution
 Tertiary hospital 3,667 (90.1) 405 (10.0) Reference Reference
 General hospital 2,975 (87.3) 433 (12.7) 1.34 (1.17-1.53) < 0.001 1.20 (1.04-1.38) 0.011
 Hospital or clinic 372 (93.0) 28 (7.0) 0.71 (0.49-1.05) 0.083 1.00 (0.68-1.47) 0.985
ASA
 I-II 5,925 (91.7) 536 (8.3) Reference Reference
 III 1,045 (77.4) 306 (22.7) 3.14 (2.73-3.61) < 0.001 1.94 (1.67-2.25) < 0.001
 IV 44 (64.7) 24 (35.3) 5.33 (3.54-8.03) < 0.001 2.12 (1.37-3.30) 0.001
Emergency operation
 No 6,561 (90.3) 703 (9.7) Reference Reference
 Yes 453 (73.5) 163 (26.5) 3.13 (2.64-3.71) < 0.001 1.71 (1.39-2.09) < 0.001
  Others 63 (79.8) 16 (20.3) Reference
  Perforated/Obstructive 390 (72.6) 147 (27.4) 1.84 (1.09-3.09) 0.022
Resection margin (n=6,470)
 Negative 5,744 (89.8) 654 (10.2) Reference
 Positive 63 (87.5) 9 (12.5) 1.18 (0.61-2.27) 0.631
LVP invasion (n=1,369)
 No 651 (88.1) 88 (11.9) Reference
 Yes 525 (83.3) 105 (16.7) 1.44 (1.08-1.91) 0.013
Lymph node (n=7,494)
 < 12 425 (83.2) 86 (16.8) Reference
 ≥ 12 6,281 (90.0) 702 (10.1) 0.63 (0.50-0.79) < 0.001
Differentiation (n=3,488)
 Well 491 (85.8) 81 (14.2) Reference
 Moderate 2,403 (87.1) 357 (12.9) 0.9 (0.71-1.15) 0.396
 Poorly+others 126 (80.8) 30 (19.2) 1.38 (0.91-2.1) 0.129
Stage (n=4,392)
 IIA 3,480 (91.8) 309 (8.2) Reference
 IIB-IIC 514 (85.2) 89 (14.8) 1.89 (1.49-2.39) < 0.001

The HR in multi-variate analysis was adjusted for sex, age, BMI, type of institutions, ASA, and emergency operation. HR, hazard ratio; CI, confidence interval; AC, adjuvant chemotherapy; BMI, body mass index; ASA, American Society of Anesthesiologists; LVP, lymphovascular or perineural.

Table 4.
Factors affecting survival outcome for each risk groups in multivariate analysis
Low-risk group (n=5,684)
High-risk group (n=2,196)
Alive (n=5,198) Death (n=486) Adjusted HR (95% CI) p-value Alive (n=1,816) Death (n=380) Adjusted HR (95% CI) p-value
Adjuvant chemotherapy
 Without AC 2,616 (89.4) 310 (10.6) Reference 618 (71.6) 245 (28.4) Reference
 With AC 2,582 (93.6) 176 (6.4) 0.74 (0.61-0.89) 0.002 1,198 (89.9) 135 (10.1) 0.76 (0.38-0.59) < 0.001
No. of risks
 0 5,198 (91.5) 486 (8.6) - - -
 1 - - - - 1,600 (84.2) 300 (15.8) Reference
 2 - - - - 206 (73.6) 74 (26.4) 1.26 (0.97-1.65) 0.088
 3 or 4 - - - - 10 (62.5) 6 (37.5) 1.76 (0.78-3.99) 0.175
Sex
 Male 3,036 (90.4) 321 (9.6) Reference 1,060 (82.3) 228 (17.7) Reference
 Female 2,162 (92.9) 165 (7.1) 0.66 (0.54-0.80) < 0.001 756 (83.3) 152 (16.7) 0.68 (0.55-0.84) < 0.001
Age (yr)
 ≤ 45 272 (97.8) 6 (2.2) Reference 89 (95.7) 4 (4.3) Reference
 > 45 and ≤ 70 2,911 (95.7) 132 (4.3) 1.94 (0.85-4.39) 0.114 962 (91.4) 90 (8.6) 1.89 (0.69-5.16) 0.215
 > 70 2,015 (85.3) 348 (14.7) 5.74 (2.55-12.93) < 0.001 765 (72.8) 286 (27.2) 4.90 (1.81-13.27) 0.002
BMI (n=7,823)
 ≤ 18 226 (82.8) 47 (17.2) 1.67 (1.23-2.27) 0.001 91 (67.4) 44 (32.6) 1.95 (1.40-2.71) < 0.001
 > 18 and ≤ 25 3,382 (90.6) 353 (9.5) Reference 1,232 (83.1) 250 (16.9) Reference
 > 25 1,565 (95.2) 79 (4.8) 0.56 (0.44-0.72) < 0.001 478 (86.3) 76 (13.7) 1.02 (0.78-1.32) 0.900
Type of institution
 Tertiary hospital 2,851 (92.2) 242 (7.8) Reference 816 (83.4) 163 (16.6) Reference
 General hospital 2,034 (90.0) 227 (10.0) 1.28 (1.06-1.54) 0.009 941 (82.0) 206 (18.0) 1.13 (0.91-1.39) 0.249
 Hospital or clinic 310 (94.8) 17 (5.2) 0.78 (0.48-1.28) 0.330 59 (84.3) 11 (15.7) 1.75 (0.94-3.24) 0.078
ASA
 I-II 4,446 (93.4) 312 (6.6) Reference 1,479 (86.8) 224 (13.2) Reference
 III 732 (81.6) 165 (18.4) 2.11 (1.73-2.57) < 0.001 313 (68.9) 141 (31.1) 1.75 (1.40-2.20) < 0.001
 IV 20 (69.0) 9 (31.0) 3.33 (1.65-6.74) 0.001 24 (61.5) 15 (38.5) 1.67 (0.95-2.92) 0.074
Emergency operation
 No 5,162 (91.5) 478 (8.5) - 1,399 (86.1) 225 (13.9) Reference
 Yes 36 (81.8) 8 (18.2) - - 417 (72.9) 155 (27.1) 1.82 (1.45-2.28) < 0.001
  Others 36 (81.8) 8 (18.2) 27 (77.1) 8 (22.9)
  Perforated/Obstructive - - 390 (72.6) 147 (27.4)
Proximal or distal resection margin (n=6,470)
 Negative 4,622 (91.8) 415 (8.2) 1,122 (82.4) 239 (17.6)
 Positive - - 63 (87.5) 9 (12.5)
LVP invasion (n=1,369)
 No 558 (89.3) 67 (10.7) 93 (81.6) 21 (18.4)
 Yes - - 525 (83.3) 105 (16.7)
Lymph node (n=7,494)
 < 12 - - 425 (83.2) 86 (16.8)
 ≥ 12 5,082 (91.5) 473 (8.5) 1,199 (84.0) 229 (16.0)
Differentiation (n=3,488)
 Well 346 (89.9) 39 (10.1) 145 (77.5) 42 (22.5)
 Moderate 1,753 (89.4) 209 (10.7) 650 (81.5) 148 (18.6)
 Poorly+others - - 126 (80.8) 30 (19.2)
Stage (n=4,392)
 IIA 3,099 (92.9) 238 (7.1) 381 (84.3) 71 (15.7)
 IIB-IIC - - 514 (85.2) 89 (14.8)

The HR for the low-risk group was adjusted for sex, age, BMI, type of institutions, ASA, and emergency operation. The HR for the high-risk group was adjusted for number of risk, sex, age, BMI, type of institutions, ASA, and emergency operation. HR, hazard ratio; CI, confidence interval; AC, adjuvant chemotherapy; BMI, body mass index; ASA, American Society of Anesthesiologists; LVP, lymphovascular or perineural.

Table 5.
Relationship of adjuvant chemotherapy and number of involved risk factors
Alive Death HR (95% CI) p-value Adjusted HR (95% CI) p-value
Without chemotherapy (n=3,789)
 No. of risks
 0 2,616 (89.4) 310 (10.6) Reference Reference
 1 530 (73.1) 195 (26.9) 2.50 (2.08-2.99) < 0.001 1.59 (1.29-1.96) < 0.001
 ≥ 2 88 (63.8) 50 (36.2) 3.60 (2.67-4.86) < 0.001 1.67 (1.19-2.36) 0.003
With chemotherapy (n=4,091)
 No. of risks
 0 2,582 (93.6) 176 (6.4) Reference Reference
 1 1,070 (91.1) 105 (8.9) 1.32 (1.03-1.68) 0.026 1.16 (0.90-1.50) 0.249
 ≥ 2 128 (81.0) 30 (19.0) 2.88 (1.95-4.27) < 0.001 2.53 (1.63-3.92) < 0.001

The HR was adjusted for sex, age, body mass index, type of institutions, American Society of Anesthesiologists, and emergency operation. HR, hazard ratio; CI, confidence interval.

Table 6.
Effect of adjuvant chemotherapy on stage II colon cancer patients who are aged over 70
Risk group Adjuvant treatment Alive Death HR (95% CI) p-value Adjusted HR (95% CI) p-value
Low-risk (n=2,535) Without chemotherapy 1,356 (84.4) 250 (15.6) Reference Reference
With chemotherapy 812 (87.4) 117 (12.6) 0.74 (0.60-0.93) 0.008 0.75 (0.60-0.94) 0.012
High-risk (n=1,122) Without chemotherapy 399 (65.7) 208 (34.3) Reference Reference
With chemotherapy 429 (83.3) 86 (16.7) 0.42 (0.33-0.54) < 0.001 0.48 (0.37-0.63) < 0.001

The HR for the low-risk group was adjusted for sex, age, BMI, type of institutions, ASA, and emergency operation. The HR for the high-risk group was adjusted for number of risk, sex, age, BMI, type of institutions, ASA, and emergency operation. HR, hazard ratio; CI, confidence interval; BMI, body mass index; ASA, American Society of Anesthesiologists.

Table 7.
Effect of adding oxaliplatin for high-risk patients on survival in multivariate analysis
Alive (n=1,054) Death (n=105) HR (95% CI) p-value Adjusted HR (95% CI) p-value
Regimen
 5-FU/leucovorin or capecitabine or UFT/leucovorin or LV5FU2 536 (90.5) 56 (9.5) Reference Reference
 FLOX or FOLFOX or mFOLFOX 518 (91.4) 49 (8.6) 0.97 (0.66-1.43) 0.882 1.36 (0.91-2.03) 0.132
Age (yr)
 ≤ 45 72 (97.3) 2 (2.7) Reference Reference
 > 45 and ≤ 70 660 (94.0) 42 (6.0) 2.27 (0.55-9.35) 0.258 2.30 (0.56-9.51) 0.251
 > 70 322 (84.1) 61 (15.9) 6.58 (1.61-26.88) 0.009 6.41 (1.54-26.66) 0.011
ASA
 I-II 911 (92.5) 74 (7.5) Reference Reference
 III 136 (82.4) 29 (17.6) 2.68 (1.74-4.12) < 0.001 1.98 (1.27-3.08) 0.003
 IV 7 (77.8) 2 (22.2) 4.25 (1.04-17.36) 0.044 3.19 (0.78-13.08) 0.107

HR, hazard ratio; CI, confidence interval; FU, fluorouracil; UFT, tegafur-uracil; LV, leucovorin; FLOX, fluorouracil, leucovorin, and oxaliplatin; FOLFOX, folinic acid, fluorouracil, and oxaliplatin; mFOLFOX, modified FOLFOX regimen; ASA, American Society of Anesthesiologists.

References

1. Wolmark N, Rockette H, Fisher B, Wickerham DL, Redmond C, Fisher ER, et al. The benefit of leucovorin-modulated fluorouracil as postoperative adjuvant therapy for primary colon cancer: results from National Surgical Adjuvant Breast and Bowel Project protocol C-03. J Clin Oncol. 1993;11:1879–87.
crossref pmid
2. Quasar Collaborative Group, Gray R, Barnwell J, McConkey C, Hills RK, Williams NS, et al. Adjuvant chemotherapy versus observation in patients with colorectal cancer: a randomised study. Lancet. 2007;370:2020–9.
crossref pmid
3. Wilkinson NW, Yothers G, Lopa S, Costantino JP, Petrelli NJ, Wolmark N. Long-term survival results of surgery alone versus surgery plus 5-fluorouracil and leucovorin for stage II and stage III colon cancer: pooled analysis of NSABP C-01 through C-05. A baseline from which to compare modern adjuvant trials. Ann Surg Oncol. 2010;17:959–66.
crossref pmid pmc
4. Efficacy of adjuvant fluorouracil and folinic acid in B2 colon cancer. International Multicentre Pooled Analysis of B2 Colon Cancer Trials (IMPACT B2) Investigators. J Clin Oncol. 1999;17:1356–63.
pmid
5. Buyse M, Piedbois P. Should Dukes' B patients receive adjuvant therapy? A statistical perspective. Semin Oncol. 2001;28(1 Suppl 1):20–4.
crossref
6. Casadaban L, Rauscher G, Aklilu M, Villenes D, Freels S, Maker AV. Adjuvant chemotherapy is associated with improved survival in patients with stage II colon cancer. Cancer. 2016;122:3277–87.
crossref pmid pmc
7. Booth CM, Nanji S, Wei X, Peng Y, Biagi JJ, Hanna TP, et al. Adjuvant chemotherapy for stage II colon cancer: practice patterns and effectiveness in the general population. Clin Oncol (R Coll Radiol). 2017;29:e29–38.
crossref pmid
8. Breugom AJ, Bastiaannet E, Boelens PG, Iversen LH, Martling A, Johansson R, et al. Adjuvant chemotherapy and relative survival of patients with stage II colon cancer: A EURECCA international comparison between the Netherlands, Denmark, Sweden, England, Ireland, Belgium, and Lithuania. Eur J Cancer. 2016;63:110–7.
crossref pmid
9. Verhoeff SR, van Erning FN, Lemmens VE, de Wilt JH, Pruijt JF. Adjuvant chemotherapy is not associated with improved survival for all high-risk factors in stage II colon cancer. Int J Cancer. 2016;139:187–93.
crossref pmid
10. Kumar A, Kennecke HF, Renouf DJ, Lim HJ, Gill S, Woods R, et al. Adjuvant chemotherapy use and outcomes of patients with high-risk versus low-risk stage II colon cancer. Cancer. 2015;121:527–34.
crossref pmid
11. Lewis C, Xun P, He K. Effects of adjuvant chemotherapy on recurrence, survival, and quality of life in stage II colon cancer patients: a 24-month follow-up. Support Care Cancer. 2016;24:1463–71.
crossref pmid pdf
12. Jee SH, Moon SM, Shin US, Yang HM, Hwang DY. Effectiveness of adjuvant chemotherapy with 5-FU/leucovorin and prognosis in stage II colon cancer. J Korean Soc Coloproctol. 2011;27:322–8.
crossref pmid pmc
13. Sato H, Maeda K, Sugihara K, Mochizuki H, Kotake K, Teramoto T, et al. High-risk stage II colon cancer after curative resection. J Surg Oncol. 2011;104:45–52.
crossref pmid
14. Abraham A, Habermann EB, Rothenberger DA, Kwaan M, Weinberg AD, Parsons HM, et al. Adjuvant chemotherapy for stage III colon cancer in the oldest old: results beyond clinical guidelines. Cancer. 2013;119:395–403.
crossref pmid
15. Sanoff HK, Carpenter WR, Sturmer T, Goldberg RM, Martin CF, Fine JP, et al. Effect of adjuvant chemotherapy on survival of patients with stage III colon cancer diagnosed after age 75 years. J Clin Oncol. 2012;30:2624–34.
crossref pmid pmc
16. Hines RB, Bimali M, Johnson AM, Bayakly AR, Collins TC. Prevalence and survival benefit of adjuvant chemotherapy in stage III colon cancer patients: comparison of overall and age-stratified results by multivariable modeling and propensity score methodology in a population-based cohort. Cancer Epidemiol. 2016;44:77–83.
crossref pmid
17. Hermosillo-Rodriguez J, Anaya DA, Sada Y, Walder A, Amspoker AB, Berger DH, et al. The effect of age and comorbidity on patient-centered health outcomes in patients receiving adjuvant chemotherapy for colon cancer. J Geriatr Oncol. 2013;4:99–106.
crossref pmid
18. Efficacy of adjuvant fluorouracil and folinic acid in colon cancer. International Multicentre Pooled Analysis of Colon Cancer Trials (IMPACT) investigators. Lancet. 1995;345:939–44.
pmid
19. O'Connell MJ, Mailliard JA, Kahn MJ, Macdonald JS, Haller DG, Mayer RJ, et al. Controlled trial of fluorouracil and low-dose leucovorin given for 6 months as postoperative adjuvant therapy for colon cancer. J Clin Oncol. 1997;15:246–50.
crossref pmid
20. Shah MA, Renfro LA, Allegra CJ, Andre T, de Gramont A, Schmoll HJ, et al. Impact of patient factors on recurrence risk and time dependency of oxaliplatin benefit in patients with colon cancer: analysis from modern-era adjuvant studies in the Adjuvant Colon Cancer End Points (ACCENT) database. J Clin Oncol. 2016;34:843–53.
crossref pmid pmc
21. Andre T, Boni C, Navarro M, Tabernero J, Hickish T, Topham C, et al. Improved overall survival with oxaliplatin, fluorouracil, and leucovorin as adjuvant treatment in stage II or III colon cancer in the MOSAIC trial. J Clin Oncol. 2009;27:3109–16.
crossref pmid
22. Kuebler JP, Wieand HS, O'Connell MJ, Smith RE, Colangelo LH, Yothers G, et al. Oxaliplatin combined with weekly bolus fluorouracil and leucovorin as surgical adjuvant chemotherapy for stage II and III colon cancer: results from NSABP C-07. J Clin Oncol. 2007;25:2198–204.
crossref pmid
23. Gill S, Loprinzi CL, Sargent DJ, Thome SD, Alberts SR, Haller DG, et al. Pooled analysis of fluorouracil-based adjuvant therapy for stage II and III colon cancer: who benefits and by how much? J Clin Oncol. 2004;22:1797–806.
crossref pmid
24. Tofthagen C. Surviving chemotherapy for colon cancer and living with the consequences. J Palliat Med. 2010;13:1389–91.
crossref pmid
25. Watson MM, Soreide K. The prognostic yield of biomarkers harvested in chemotherapy-naive stage II colon cancer: can we separate the wheat from the chaff? Mol Med. 2016;22:271–3.
crossref pmid pmc
26. Smith JJ, Tilney HS, Heriot AG, Darzi AW, Forbes H, Thompson MR, et al. Social deprivation and outcomes in colorectal cancer. Br J Surg. 2006;93:1123–31.
crossref pmid
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