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Ann Coloproctol > Volume 36(4); 2020 > Article
Oh, Huh, Lee, Choi, Pyo, Lee, Park, Shin, Park, Cho, Yun, Kim, and Lee: Long-term Oncologic Outcome of Postoperative Complications After Colorectal Cancer Surgery

Abstract

Purpose

The impact of postoperative complications on long-term oncologic outcome after radical colorectal cancer surgery is controversial. The aim of this study was to examine the risk factors and oncologic outcomes of surgery-related postoperative complication groups.

Methods

From January 2010 to December 2010, 310 patients experienced surgery-related postoperative complications after radical colorectal cancer surgery. These stage I–III patients were classified into 2 subgroups, minor (grades I, II) and major (grades III, IV) complication groups, according to extended Clavien-Dindo classification system criteria. Clinicopathologic differences between the 2 groups were analyzed to identify risk factors for major complications. The diseasefree survival rates of surgery-related postoperative complication groups were also compared.

Results

Minor and major complication groups were stratified with 194 patients (62.6%) and 116 patients (37.4%), respectively. The risk factors influencing the major complication group were pathologic N category and operative method. The prognostic factors associated with disease-free survival were preoperative perforation, perineural invasion, tumor budding, and receiving neoadjuvant therapy. With a median follow-up period of 72.2 months, the 5-year disease-free survival rates were 84.4% in the minor group and 78.5% in the major group, but there was no statistical significance between the minor and major groups (P = 0.392).

Conclusion

Advanced cancer and open surgery were identified as risk factors for increased surgery-related major complications after radical colorectal cancer surgery. However, severity of postoperative complications did not affect disease-free survival from colorectal cancer.

INTRODUCTION

Colorectal cancer is the third most commonly occurring cancer in males and the second most commonly occurring cancer in females. Over 1.8 million new cases and 881,000 deaths occurred in 2018 [1]. Surgical resection is the main treatment of choice for patients with stages I–III colorectal cancer [2]. Despite advancements in surgical methods, postoperative complications are observed in up to 35% of patients who undergo radical colorectal cancer surgery [3-8]. The impact of postoperative complications that affect long-term oncologic outcomes after radical colorectal surgery is controversial [8-12].
Some authors have shown that injuries associated with surgery stimulate tumor growth and dissemination [13-15]. Other researchers have shown that postoperative complications affect the immunological response, which improves undetected tumor viability and increases disease recurrence [16, 17]. In most studies, researchers analyzed all complications after curative colorectal cancer surgery, whether related to the surgery or not [9, 12, 18, 19]. The elimination of complications not related to surgery, i.e., those beyond the surgeon’s control, would provide meaningful analysis in identification of surgical factors.
The aim of this study was to examine the relationship between minor and major surgery-related complication subgroups according to the Clavien-Dindo (CD) classification system. The influence of surgery-related postoperative complications on diseasefree survival between these 2 subgroups was compared.

METHODS

Patients

We retrospectively analyzed 1,149 patients who underwent radical surgery for stages I–III colorectal cancer at Samsung Medical Center from January 2010 to December 2010. The exclusion criteria were (1) recurrent colorectal cancer, (2) metachronous cancer, (3) hereditary colorectal cancer, and (4) radical surgery not performed (patient underwent local excision and polypectomy). Among 1,149 patients, 334 experienced postoperative complications within 30 days after colorectal radical surgery. Among these 334 patients, 24 experienced complications not related to surgery. This study was reviewed and approved by the Institutional Review Board at Samsung Medical Center (IRB No. 2019-08-056- 001), and informed consent was waived.
All patients underwent curative surgery performed by 6 welltrained colorectal surgeons. Cancer staging followed the 7th American Joint Committee on Cancer (AJCC) TNM classification guidelines [20]. According to radiologic evaluation, patients with locally advanced (radiological T3/T4 or N positive) rectal cancer located within 10 cm of the anal verge received preoperative therapy with a 5-fluorouracil-based chemotherapy regimen or underwent radiotherapy of the whole pelvis at a dose of 40.4−50.4 Gy.
Five-fluorouracil-based chemo-regimen was preferentially considered as adjuvant chemotherapy for patients with T3, T4, or node-positive disease after surgical resection. This decision was based on patient health status, compliance, and physician preference. Patients were followed up at 3-month intervals for the first 2 years, at 6-month intervals for the next 3 years, and yearly thereafter. Follow-up surveillance examinations included clinical history, physical examination, measurement of serum carcinoembryonic antigen level, chest X-ray, and chest and abdominopelvic computed tomography scan. Additional pelvic magnetic resonance imaging and positron emission tomography scans were performed every 6 to 12 months depending on patient status. Colonoscopy was performed 1 year after surgery and then every 2 years [20].
The 310 patients were retrospectively placed into 5 categories according to the extended CD classification system for surgical complications published by the Japan Clinical Oncology Group in 2016 [21]. The CD classification system published in 2004 provided for simple categorization of postoperative complications [22]. CD classification, along with the extended CD classification system, was established to standardize adverse event terms and provide more detailed grading guidelines in clinical practice [21].
Postoperative morbidity was defined as a complication occurring during the hospital stay or within 30 days after surgery. Patients were assigned to 2 groups according to CD classification: minor complication group including CD grades I to II and major complication group including CD grades III to IV.

Statistical analysis

Data were analyzed using IBM SPSS Statistics ver. 23.0 (IBM Corp., Armonk, NY, USA). Clinicopathologic features of the 2 groups were analyzed using chi-square test or t-test. Continuous variables were recorded as the median and minimum to maximum ranges. Variables with P-value < 0.05 were considered statistically significant in univariate analysis. Using the variables identified as statistically significant by univariate analysis, multivariate analysis was carried out using the logistic regression model and Cox regression method. Disease-free survival rates were estimated using the Kaplan-Meier method, and differences between curves were compared using the log-rank test.

RESULTS

A total of 1,149 patients with stage I–III colorectal cancer underwent curative radical surgery in 2010. Of these patients, 334 patients (29.1%) had postoperative complications; 24 patients (2.1%) who experienced complications unrelated to surgery were excluded. The remaining 310 patients (27.0%) were categorized into 1 of 5 grades according to CD classification: (1) 52 patients (4.5%) were CD grade I; (2) 142 patients (12.4%) were CD grade II; (3) 78 patients (6.8%) were CD grade IIIa; 35 patients (3.0%) were CD grade IIIb; and (4) 3 patients (0.3%) were CD grade IVa. Severe complications such as CD grade IVb and mortality were absent. The type and frequency of complications are shown in Table 1. The most common type of complication related to surgery was wound complication (31.6%); postoperative ileus (19.7%) was the second most common complication. Anastomosis leakage occurred in 11.9% of cases and was the second most common complication (20.7%) in the major complication group. Most complications unrelated to surgery were in the minor complication group (91.7%).
Patients were divided into 2 subgroups, a minor complication group (CD grade I/II) and a major complication group (CD grade III/IV) containing 194 and 116 patients, respectively. Comparisons of clinicopathologic features of patients according to complication groups (CD grade I/II vs. III/IV) are shown in Table 2. Preoperative obstruction, operative method, length of hospital stay, pathologic N category, and tumor size differed significantly between the 2 groups.
Risk factors influencing the major complication group are shown in Table 3. Univariate logistic regression indicated that preoperative obstruction, operative method, pathologic N category, and neoadjuvant therapy were risk factors. On multivariate analysis, operative method, and pathologic N category were independent risk factors for the major complication group.
In the median follow-up of 72.2 months (range, 0.2 to 113.6 months), the 5-year disease-free survival rate of this cohort was 81.5%. The 5-year disease-free survival rates of the minor complication group (CD grades I and II) and the major complication group (CD grades III and IV) were 84.4% and 78.5%, respectively. There was no statistically significant difference between minor and major complication groups (P= 0.392) (Fig. 1). The survival curves according to pathologic TNM stage differed significantly. The 5-year disease-free survival rates of patients with pStage 0, pStage I, pStage II, and pStage III were 95.5%, 94.1%, 84.2%, and 69.8%, respectively (P< 0.001) (Fig. 2).
Univariate analysis indicated that the prognostic factors associated with disease-free survival were preoperative perforation, emergency surgery, transfusion during operation, pathologic T category, pathologic N category, lymphovascular invasion (LVI), perineural invasion (PNI), tumor budding, receiving neoadjuvant therapy, and adjuvant therapy. On multivariate analysis, preoperative perforation, PNI, tumor budding, and receiving neoadjuvant therapy were independent prognostic factors for disease-free survival (Table 4).

DISCUSSION

In this study, 334 patients (29.1%) with postoperative complications after radical colorectal cancer surgery were investigated. Among these, 310 patients (27.0%) experienced surgery-related complications. The surgery-related complication cohort was classified into 2 subgroups, minor and major complication groups, encompassing 194 patients (62.6%) and 116 patients (37.4%), respectively. These complication rates are consistent with those of previous studies [3-8, 19, 23, 24]. Risk factors for major surgeryrelated complications were analyzed. There were differences in the operative method and pathologic N category between minor and major complication groups. Pathologic N category was associated with severity of cancer stage; pathologic N category positive refers to stage III colorectal cancer or higher according to the 7th AJCC TNM classification. Previous studies have shown a relationship between higher cancer stage and an increased incidence of postoperative complications [8, 25, 26].
Open surgery is considered a risk factor for increased surgeryrelated major complications. Laparoscopic surgery has advantages over open surgery with no difference in oncologic outcome; advantages include less blood loss, shorter length of wound, faster recovery of bowel function, and shorter hospital stay [3-5]. The laparoscopic approach reduces wound incision and decreases the possibility of wound complications such as seroma, infection, and the need for resuturing under local anesthesia. These complications are categorized as major complications by the extended CD classification system [21].
The impact of postoperative complications that affect oncologic long-term outcomes in colorectal cancer remains controversial. Recent studies have shown that postoperative complications have a negative effect on the oncologic outcome. In particular, infectious complications, surgical intensive care unit admission, and location of anastomosis leakage were associated with negative prognosis [7, 11, 12, 23, 27-29]. Several studies demonstrated that postoperative complications impact short-term and long-term survival as described above. However, some researchers contend that postoperative complications do not have a significant effect on the oncologic outcome or disease-free survival in colorectal cancer [8, 9, 30]. In our study, advanced cancer stage and operative method were surgery-related risk factors for major complications after radical colorectal cancer surgery. However, the results show no differences in 5-year disease-free survival between minor (84.4%) and major (78.5%) complication groups. These surgeryrelated major complications did not influence disease-free survival (P= 0.392) of colorectal cancer patients.
As described in our study, preoperative perforation, PNI, tumor budding, and receiving neoadjuvant therapy were prognostic factors of disease-free survival in colorectal cancer surgery. These results are consistent with our institute’s previous study showing that LVI, PNI, and tumor budding are as strong predictors of colorectal cancer disease-free survival [20]. Preoperative perforation and receiving neoadjuvant therapy could be related to the severity of cancer stage affecting recurrence.
An objective stratification protocol was used to classify patient complications based on treatment modality rather than clinical manifestations. The extended CD classification system that standardizes adverse event terms in more detail was used [21]. This helped us overcome the limitation of retrospective data collection. However, the CD classification system stratifies surgical complications based on the invasiveness of the treatment modality. This grading system may not reflect the impact of a patient’s systemic condition after surgery [8].
As a retrospective single center study, our study has a few limitations. Type II error may be present due to the relatively small number of patients. In our study, 57 patients underwent preoperative chemoradiotherapy, so combining of ypStage with pStage can cause bias. Another limitation is that our study did not consider patient comorbidities. Even if a patient had many comorbidities, the most invasive treatment grade was based on extended CD classification. This bias might underestimate the comorbidity effect on patients.
In conclusion, advanced cancer stage and open surgery were identified as risk factors for increasing surgery-related major complications after radical colorectal cancer surgery. However, the severity of postoperative complications did not affect the disease-free survival of patients with colorectal cancer.

Notes

CONFLICT OF INTEREST

No potential conflict of interest relevant to this article was reported.

Fig. 1.
Disease-free survival (DFS) curves by postoperative complication group of Clavien-Dindo (CD) classification after colorectal cancer surgery.
ac-2019-10-15f1.jpg
Fig. 2.
Disease-free survival (DFS) curves according to pathologic TNM stage (pStage) after colorectal cancer surgery.
ac-2019-10-15f2.jpg
Table 1.
Type and frequency of complication
Type Total Clavien-Dindo classification
I II IIIa IIIb IV
Surgery-related Minor complication 194 (62.6) Major complication 116 (37.4)
 Wound complication 98 (31.6) 20 (6.5) 12 (3.9) 63 (20.3) 3 (1.0) -
 Ileus 61 (19.7) 11 (3.5) 40 (12.9) 7 (2.3) 2 (0.6) 1 (0.3)
 Urinary retention 58 (18.7) 13 (4.2) 45 (14.5) - - -
 Anastomosis leakage 37 (11.9) - 13 (4.2) 1 (0.3) 22 (7.1) 1 (0.3)
 Postoperative bleeding 27 (8.7) 7 (2.3) 16 (5.2) - 3 (1.0) 1 (0.3)
 Chylous ascites 13 (4.2) 1 (0.3) 12 (3.9) - - -
 Intraabdominal fluid collection 12 (3.9) - 4 (1.3) 7 (2.3) 1 (0.3) -
 Rectovaginal fistula 2 (0.6) - - - 2 (0.6) -
 Bowel perforation 2 (0.6) - - - 2 (0.6) -
 Total 310 (100) 52 (16.8) 142 (45.8) 78 (25.2) 35 (11.3) 3 (1.0)
Surgery-unrelated
 Pulmonary complication 13 (54.2) 6 (25.0) 6 (25.0) - - 1 (4.2)
 Urinary dysfunction 4 (16.7) - 3 (12.5) - 1 (4.2) -
 Neurologic complication 3 (12.5) 1 (4.2) 2 (8.3) - - -
 Cardiac complication 2 (8.3) - 2 (8.3) - - -
 Other 2 (8.3) - 2 (8.3) - - -

Values are presented as number (%).

Table 2.
Clinicopathologic features of surgery-related complications cohort (n=310)
Variable CD grades I, II (n=194) CD grades III, IV (n=116) P-value
Preoperative features
 Age (yr) 60.5 (33–83) 59 (32–85) 0.545
 Sex
  Female 67 (65.5) 38 (32.8) 0.749
  Male 127 (65.5) 78 (67.2)
 ASA PS classification
  I, II 176 (95.7) 102 (94.4)a 0.641
  III, IV 8 (4.3) 6 (5.6)
 Body mass index (kg/m2) 23.78 (15.12–35.34) 23.46 (16.45–30.52) 0.415
 Preoperative CEA level (ng/mL) 1.83 (0.5–126.37) 2.23 (0.5–125.70)b 0.465
 Underlying disease
  Hypertension 63 (32.5) 42 (36.2) 0.502
  Diabetes mellitus 38 (19.6) 21 (18.1) 0.747
  Heart disease 14 (7.2) 7 (6.0) 0.689
  Cerebrovascular disease 8 (4.1) 1 (0.9) 0.980
  Pulmonary disease 12 (6.2) 8 (6.9) 0.805
 Previous abdominal surgery 57 (29.4) 35 (30.2) 0.883
 Preoperative treatment
  Chemotherapy 1 (0.5) 1 (0.7) 0.130
  Radiotherapy 0 (0) 0 (0)
  Chemoradiotherapy 28 (14.4) 27 (23.3)
 Preoperative stenting 2 (1.0) 3 (2.6) 0.293
 Obstruction 19 (9.8) 23 (19.8) 0.012
 Perforation 6 (3.1) 9 (7.8) 0.064
Intraoperative features
 Type of operation
  Right hemicolectomy 57 (29.4) 25 (21.6) 0.211
  Left hemicolectomy 6 (3.1) 7 (6.0)
  Anterior resection 32 (16.5) 17 (14.7)
  Low anterior resection 92 (47.4) 56 (48.3)
  Other 7 (3.6) 11 (9.5)
 Level of anastomosis
  Colon 111 (57.2) 60 (51.7) 0.347
  Rectum 83 (42.8) 56 (48.3)
 Operative method
  Open surgery 94 (48.5) 82 (70.7) < 0.001
  Minimally invasive surgery 100 (51.5) 34 (29.3)
 Emergency surgery 7 (3.6) 6 (5.2) 0.506
 Diverting stoma 37 (19.1) 20 (17.2) 0.687
 Operative time (min) 160 (43–492) 157 (64–490) 0.827
 Transfusion during operation 6 (3.1) 7 (6.0) 0.211
Postoperative features
 Length of hospital stay 12 (7-44) 17 (8–85) < 0.001
 Pathologic T category
  0, 1, 2 83 (42.8) 37 (31.9) 0.057
  3, 4 111 (57.2) 79 (68.1)
 Pathologic N category
  Negative 122 (62.9) 57 (49.1) 0.018
  Positive 72 (37.1) 59 (50.9)
 Lymphovascular invasion
  Negative 127 (65.5) 70 (60.3) 0.365
  Positive 67 (34.5) 46 (39.7)
 Perineural invasion
  Negative 173 (89.2) 102 (87.9) 0.738
  Positive 21 (10.8) 14 (12.1)
 Tumor budding
  Negative 124 (63.9) 71 (61.2) 0.633
  Positive 70 (36.1) 45 (38.8)
 Tumor size (cm) 3.5 (0.1–12) 4.0 (0.2–20) 0.021
 Harvested lymph nodes 16 (0–58) 17 (2–62) 0.173
 Adjuvant therapy
  Chemotherapy 90 (46.4) 65 (56.0) 0.102
  Radiotherapy 0 (0) 1 (0.9)
  Chemoradiotherapy 16 (8.2) 12 (10.3)

Values are presented as median (range) or number (%).

ASA PS, American Society of Anesthesiologists physical status; CEA, carcinoembryonic antigen; CD, Clavien-Dindo classification.

a Not available (N/A) 18 cases.

b N/A 12 cases.

Table 3.
Risk factors influencing Clavien-Dindo grades III and IV in surgery-related complication cohort
Variable Univariate analysis
Multivariate analysis
OR 95% CI P-value OR 95% CI P-value
Age (> 59/ ≤ 59 yr) 0.908 0.573–1.439 0.682
Sex (male/female) 1.083 0.665–1.764 0.749
ASA PS classification (III, IV/I, II) 1.294 0.437–3.835 0.642
BMI (> 23.6/ ≤ 23.6 kg/m2) 0.871 0.550–1.381 0.558
Preoperative CEA (> 5.0/ ≤ 5.0 ng/mL) 1.310 0.708–2.426 0.390
Underlying disease
 Hypertension 1.180 0.728–1.914 0.502
 Diabetes mellitus 0.907 0.503–1.638 0.747
 Heart disease 0.826 0.323–2.109 0.689
 Cerebrovascular disease 0.202 0.025–1.638 0.134
 Pulmonary disease 1.123 0.445–2.835 0.805
Preoperative stenting 2.549 0.420–15.484 0.309
Obstruction 2.278 1.180–4.397 0.014 1.750 0.886–3.457 0.107
Perforation 2.636 0.913–7.606 0.073
Operative method (open/MIS) 2.566 1.573–4.184 < 0.001 2.486 1.519–4.069 < 0.001
Emergency surgery 1.457 0.478–4.446 0.508
Operative time (> 160/ ≤ 160 min) 0.973 0.614–1.541 0.906
Transfusion during operation 2.012 0.659–6.140 0.219
Pathologic T category (3, 4/0, 1, 2) 1.597 0.985–2.588 0.058
Pathologic N category (+/−) 1.754 1.100–2.796 0.018 1.661 1.031–2.676 0.037
Lymphovascular invasion (+/−) 1.246 0.774–2.004 0.365
Perineural invasion (+/−) 1.131 0.551–2.321 0.738
Tumor budding (+/−) 1.123 0.698–1.805 0.633
Tumor size (> 3.6/ ≤ 3.6 cm) 1.180 0.744–1.870 0.481
Neoadjuvant therapy (+/−) 2.737 1.397–5.364 0.003 1.519 0.808–2.858 0.195

OR, odds ratio; CI, confidence interval; ASA PS, American Society of Anesthesiologists physical status; BMI, body mass index; CEA, carcinoembryonic antigen; MIS, minimally invasive surgery.

Table 4.
Prognostic factors influencing disease-free survival in surgery-related complication cohort
Pathologic T category (3, 4/0, 1, 2) Univariate analysis
Multivariate analysis
OR 95% CI P-value OR 95% CI P-value
Age (> 59/ ≤ 59 yr) 0.635 0.362–1.114 0.114
Sex (male/female) 0.583 0.336–1.010 0.054
ASA PS classification (III, IV/I, II) 1.385 0.430–4.460 0.585
BMI (> 23.6/ ≤ 23.6 kg/m2) 0.882 0.509–1.527 0.653
Preoperative CEA (> 0.5/ ≤ 5.0 ng/mL) 1.842 0.975–3.483 0.060
Underlying disease
 Hypertension 0.757 0.409–1.401 0.376
 Diabetes mellitus 0.464 0.184–1.168 0.103
 Heart disease 0.531 0.129–2.185 0.381
 Cerebrovascular disease 2.407 0.749–7.731 0.140
 Pulmonary disease 0.931 0.290–2.988 0.904
Preoperative stenting 3.012 0.731–12.416 0.127
Obstruction 1.013 0.456–2.250 0.974
Perforation 4.608 2.159–9.837 < 0.001 4.436 2.024–9.722 < 0.001
Operative method (open/MIS) 1.563 0.873–2.797 0.133
Emergency surgery 3.218 1.372–7.549 0.007 0.927 0.350–2.456 0.879
Operative time (> 160/ ≤ 160 min) 1.693 0.965–2.971 0.067
Transfusion during operation 2.970 1.178–7.486 0.021 1.635 0.501–5.338 0.416
Pathologic T category (3, 4/0, 1, 2) 3.288 1.600–6.7155 0.001 1.133 0.446–2.880 0.793
Pathologic N category (+/−) 3.361 1.860–6.074 < 0.001 1.787 0.824–3.876 0.142
Lymphovascular invasion (+/−) 3.365 1.907–5.939 < 0.001 1.072 0.518–2.217 0.852
Perineural invasion (+/−) 5.665 3.183–10.082 < 0.001 3.249 1.779–5.934 < 0.001
Tumor budding (+/−) 4.076 2.276–7.300 < 0.001 4.606 2.422–8.758 < 0.001
Tumor size (> 3.6/ ≤ 3.6) 1.156 0.667–2.004 0.605
Neoadjuvant therapy (+/−) 2.286 1.227–4.092 0.005 4.177 2.231–7.819 < 0.001
Adjuvant therapy (+/−) 2.348 1.205–4.576 0.012 0.782 0.333–1.834 0.572
CD (III, IV/I, II) 1.273 0.731–2.215 0.394

OR, odds ratio; CI, confidence interval; ASA PS, American Society of Anesthesiologists physical status; BMI, body mass index; CEA, carcinoembryonic antigen; MIS, minimally invasive surgery; CD, Clavien-Dindo classification.

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