New anticancer drugs are being increasingly used for advanced and recurrent gastric cancer in many institutions. Therefore, the relative importance of surgery may have changed, and there may also be controversy as to whether patients with stage IV gastric cancer should or not undergo surgical resection. The relevance of surgery in this population was studied. The relevance of surgery was studied in 304 cases of stage IV gastric cancer who were treated at KurumeUniversityHospitalfrom 1995 to 2009. Multivariate analysis showed that distant organ metastasis was significantly correlated with surgery. In stage IV cases, chemotherapy and the number of stage IV factors were independent prognostic factors. In surgery cases, venous invasion, chemotherapy, and residual tumor were independent prognostic factors. R0 was significantly higher in the surgery with chemotherapy group than in the chemotherapy alone group, but there was no significant difference in R1 or R2 cases between the surgery with chemotherapy group and the chemotherapy alone group. In R2 cases, use of a new drug was an independent prognostic factor. The rate of R0 was significantly higher in the preoperative chemotherapy group than in the surgery alone group. In preoperative chemotherapy cases, the S-1/cisplatin (CDDP) group had a 50% 2-year survival rate, and these cases underwent postoperative chemotherapy using the S-1 regimen. A multimodal treatment is considered most effective for stage IV gastric cancer, where this includes preoperative chemotherapy, surgery, and postoperative chemotherapy using the new anti-cancer drugs.
Gastric cancer is the second leading cause of cancerspecific mortality worldwide [
Between 1995 and 2009, 2145 patients with gastric cancer underwent therapy at Kurume University Hospital. The 304 cases (206 men, 98 women) defined as Stage IV according to the 14th Edition Japanese Classification of Gastric Carcinoma [
A total of about 27 clinicopathological variables were investigated including sex (male or female), age (≥60 or <60 years), macroscopic type (type 0, (1, 2), (3, 4) or 5), site (L, M, or U), tumor size (≥100 or <100 mm), the number of sites (1, 2, or ≥3), liver metastasis (H0 or H1), peritoneal metastasis (P0 or P1), lymph node metastasis (N0, N1,2, or N3), distant lymph node metastasis (M0 (LYM) or M1 (LYM)), distant organ metastasis excluding liver metastasis, peritoneal metastasis, distant lymph node metastasis (M0 or M1), peritoneal cytology (CY0 or CY1), depth of invasion ((T1, T2, T3), T4a, or T4b), histology (differentiated type or undifferentiated type), stromal pattern (medullary type (med), intermediate type (int), or scirrhous type (sci)), tumor infiltration pattern (INFa, INFb, or INFc), lymphatic invasion (ly0, ly1,2, or ly3), venous invasion (v0,1 or v2,3), proximal margin (PM0 or PM1), distal margin (DM0 or DM1), surgery (− or +), chemotherapy (− or +), the number of Stage IV factors (1, or ≥2), postoperative or preoperative chemotherapy, lymph node dissection (D0,1, D2, or ≥D2), residual tumor (R0, R1, or R2), and new anticancer drugs such as S-1, irinotecan, and taxanes (− or +).
Associations between surgery and clinical variables were compared by univariate analysis using the c2 test. Significant factors were extracted for further multivariate logistic regression analysis.
The disease-specific survival for each clinical variable was calculated using the Kaplan-Meier method for all cases, surgery cases, and R2 cases. Univariate analysis of factors thought to affect disease-specific survival was carried out using the log-rank test. The Cox proportional hazards model was used in the multivariate analysis of the factors determined to be significant for disease-specific survival on univariate analysis. Moreover, prognosis was compared between the surgery with chemotherapy group and the chemotherapy alone group.
A total of 22 Stage IV gastric cancer patients (19 men, 3 women) who underwent preoperative chemotherapy were studied. The mean age was 62.2 years (range, 41 - 73 years). Four regimens were used as preoperative chemotherapy in 21 cases, including 5-fluorouracil (FU)/cisplatin (CDDP) in 9, S-1/CDDP in 8, S-1/taxol (TXL) in 2, and S-1 in 2, and one patient was given various anticancer drugs over a long period.
The statistical analyses were performed using statistical analysis software (SPSS II; IBM Co., Armonk, NY, USA). For all analyses, significance was defined as P < 0.05.
With respect to Stage IV factors, there were 107 cases with peritoneal metastases (44.4%), 63 (26.1%) distant lymph node metastases, 40 (16.6%) liver metastases, 22 (9.1%) peritoneal cytology-positive, and 9 (3.7%) distant organ metastases among the patients with one Stage IV factor; 52 (17.1%) patients had 2 Stage IV factors, and 11 (3.6%) had 3 or 4 Stage IV factors. There were 45 metastasis sites affecting the peritoneum, 39 affecting distant lymph nodes, 32 in liver, 17 in distant organs, and 1 cytology-positive case in patients with multiple Stage IV factors. Of the 26 cases with distant organ metastases, 9 (34.6%) involved bone, 5 (19.2%) involved bone marrow, and 3 (11.5%) involved lung; there was ovary, spleen, and skin involvement in 2 (7.7%) each, bone, lung, brain, and kidney involvement in 1 (3.8%) each, and 17 of 26 cases with distant organ metastases had other Stage IV factors.
Postoperative chemotherapy was given to 134 (44.1%) patients, surgery alone was performed in 83 (27.3%), chemotherapy alone was given in 36 (11.8%), no surgery and no chemotherapy were given in 26 (8.6%), preoperative chemotherapy was given in 22 (7.2%), and treatment status was unknown in 3 (1.0%). There were 239 surgery cases, with a resection rate of 78.6%.
Disease-specific survival for all Stage IV cases was 39.8% at 1 year, 19.3% at 2 years, 8.9% at 3 years, 5.3% at 4 years, and 3.3% at 5 years. The median survival time (MST) was 9 months. Over the maximal follow-up of 121 months, 245 deaths occurred; 236 (96.3%) were due to gastric cancer, and 9 (3.7%) were not due to gastric cancer (other disease (n = 7), other malignancy (n = 1), post-operative complication (n = 1)).
Associations between surgery and clinical characteristics were compared by univariate analysis. Surgery was associated with liver metastasis, peritoneal metastasis, distant organ metastasis, and the number of Stage IV factors (
*P < 0.05 indicates statistical significance; The incidences in some cases were unknown.
B: coefficient for the constant; SE: standard error; Wald: Wald chi-square test; df: degree of freedom; Exp(B): exponentiation of the B coefficient; H: liver metastasis; P: peritoneal metastasis; M: distant organ metastasis; *P < 0.05 indicates statistical significance.
Using the log-rank test, macroscopic type, number of sites, peritoneal metastases, depth of invasion, resection, chemotherapy, and the number of Stage IV factors affected survival (
The SMT of chemotherapy cases was 13 months, and that of non-chemotherapy cases was 5 months. The SMT of cases with one Stage IV factor was 11 months, and that of cases with multiple Stage IV factors was 4 months.
The log-rank test was used to compare the results in the surgery group, macroscopic type, peritoneal metastases, depth of invasion, histology, tumor size, venous invasion, proximal margin, chemotherapy, number of Stage IV factors, lymph node dissection, and residual tumor affected the prognosis (
The log-rank test was used in the R2 group to investigate macroscopic type, histology, tumor size, proximal margin, chemotherapy, number of Stage IV factors, and new drugs affected the prognosis (
The SMT was 9 months in the chemotherapy alone group, 13 months in the R2 with chemotherapy group, 14 months in the R1 with chemotherapy group, and 27 months in the R0 with chemotherapy group. There was no significant difference in the survival curves between the chemotherapy alone group and the R2 with chemotherapy group (P = 0.2731). The survival curve of the R1 with chemotherapy group tended to be higher than that of the chemotherapy alone group (P = 0.0761). The survival curve of the R0 with chemotherapy group was significantly higher than that of the chemotherapy alone group (P = 0.0040).
Df: degree of freedom; CI: confidential interval; H: liver metastasis; P: peritoneal metastasis; M1(LYM): distant lymph node metastasis; M1: distant organ metastasis; *P < 0.05 indicates statistical significance.
Df: degree of freedom; CI: confidential interval; H: liver metastasis; P: peritoneal metastasis; N: extent of lymph node metastasis; M1(LYM): distant lymph node metastasis; M1: distant organ metastasis; CY: peritoneal cytology; INF: pattern of infiltrating growth; ly: lymphatic invasion; v: venous invasion; DM: distal margin; PM: proximal margin; R: residual tumor; *P < 0.05 indicates statistical significance.
Df: degree of freedom; CI: confidential interval; H: liver metastasis; P: peritoneal metastasis; N: extent of lymph node metastasis; M1(LYM): distant lymph node metastasis; M1: distant organ metastasis; CY: peritoneal cytology; INF: pattern of infiltrating growth; ly: lymphatic invasion; v: venous invasion; DM: distal margin; PM: proximal margin; *P < 0.05 indicates statistical significance.
Examining the rate of residual tumor according to treatment, in the surgery alone group, R0 was 13.4% (n = 11), R1 was 4.9% (n = 4), and R2 was 81.7% (n = 67). In the postoperative chemotherapy group, R0 was 21.6% (n = 29), R1 was 14.9% (n = 20), and R2 was 63.4% (n = 12). In the preoperative chemotherapy group, R0 was 36.4% (n = 8), R1 was 9.1% (n = 2), and R2 was 54.5% (n = 12). The R0 rate was significantly higher in the preoperative chemotherapy group than in the surgery alone group (P = 0.048) (
The mean numbers of administered courses of 5-FU/ CDDP, S-1/CDDP, S-1/TXL, and S-1 were 1.6, 3.4, 5.5, and 2.5, respectively. The rates of down staging were 22.2% (n = 2), 25.0% (n = 2), 50.0% (n = 1), and 0, respectively. The rates of R0 or R1 were 55.6% (n = 5), 62.5% (n = 5), 50.0% (n = 1), and 0, respectively. The response rates were 77.8% (n = 7), 50.0% (n = 4), 100% (n = 2), and 50.0% (n = 1), respectively. The rates of patients who underwent postoperative chemotherapy using the S-1 regimen were 0, 87.5% (n = 7), 100% (n = 2), and 100% (n = 2), respectively. No cases underwent postoperative chemotherapy using the S-1 regimen in the 5-FU/CDDP group, because the cases given 5-FU/CDDP were old cases. There were four 2-year survival cases (50.0%) with S-1/CDDP, but there was no 2-year survival case with the other regimens (
With the S-1/CDDP regimen, there was no case with distant organ metastases. There were three PR cases, and
R0: no residual tumor; R1: microscopic residual tumor (positive resection margin or CY1); R2: macroscopic residual tumor; *: The rate of preoperative chemotherapy cases is significantly higher than that of surgery alone cases (P = 0.048).
R0: no residual tumor; R1: microscopic residual tumor (positive resection margin or CY1); 5-FU: 5-fluorouracil; CDDP: cisplatin; TXL: taxol.
1 SD case in the 2-year survival cases. Three of four PR cases were 2-year survival cases, and another PR case with R0 resection died from other disease at 9 months after surgery. One R0, two R1, and one R2 case were 2-year survival cases, but the R2 case died of liver metastases at 25 months after surgery. The histological responses of the two 2-year survival cases were grade 2. All four 2-year survival cases underwent postoperative chemotherapy using S-1 with CDDP or TXL (
In this paper, the effect of surgery on the prognosis of Stage IV gastric cancer was examined. According to the guidelines for the treatment of gastric cancer (3rd Edition), the treatments for Stage IV gastric cancer are chemotherapy, radiation, palliative surgery, and symptommatic treatment [
Chemotherapy plays an important role in the treatment of Stage IV gastric cancer, but no effective chemotherapy regimen for unresectable or recurrent gastric carcinoma was established until the 1990s. S-1, a new oral fluoropyrimidine containing tegafur, 5-chloro-2, 4-dihydropyrimidine, and potassium oxonate, was recognized as an effective drug for gastric cancer in the mid 1990s [
In the present study, chemotherapy and the number of Stage IV factors were independent prognostic factors in all Stage IV cases. Surgery was significant on univariate analysis, but it was not an independent prognostic factor. These results suggest that the chief therapy for Stage IV gastric cancer was thought to be chemotherapy. In surgery cases, venous invasion, chemotherapy, and residual tumor were independent prognostic factors. Therefore, chemotherapy with resection might be an effective therapy for Stage IV gastric cancer. There was no significant difference in prognosis between chemotherapy with R1 or R2 resection cases and chemotherapy alone cases. However, the prognosis of chemotherapy with R0 resection cases was significantly better than that of chemotherapy alone cases. Chemotherapy with R0 resection was considered to improve the prognosis of Stage IV
cStage: clinical stage before chemotherapy; ypStage: pathological stage after surgery; R: residual tumor; chem. R0: no residual tumor; R1: microscopic residual tumor (positive resection margin or CY1); R2: macroscopic residual tumor; PR: partial response; SD: stable disease, PD: progressive disease; chem.: chemotherapy; CDDP: cisplatin; TXL: taxol; M: months after surgery; other: death due to other disease.
gastric cancer. Smith et al. [
Advances in gastric cancer chemotherapy, such as the introduction of new anticancer agents, have made macroscopic complete resection possible for some patients presenting with otherwise unresectable or metastatic gastric cancer for whom surgical resection had not been indicated at the first clinical visit. Surgical resection of a residual tumor in such patients, or the so-called salvage gastrectomy or secondary gastrectomy, has been occasionally reported since 2001. All of these reports have described surgical success and satisfactory outcomes [21-23]. The R0 rate of the preoperative chemotherapy group was significantly higher than that of the surgery alone group. Preoperative chemotherapy has several advantages over postoperative chemotherapy. First, if the case has no metastatic site target for chemotherapy on computed tomography (CT), response evaluation is possible because the primary site can be evaluated. Second, the compliance of chemotherapy is good, because there are no postoperative complications or side effects. Third, preoperative chemotherapy has a good effect on the metastatic site, such as bulky lymph nodes, so that the rate of curative resection is high. Fourth, anti-cancer drugs can be administered for micro-metastases in undissectable distant lymph nodes from the early phase. Fifth, useless surgery can be avoided in patients who have early recurrences after curative resection [
However, the resection rate was very low in cases with distant organ metastases such as bone and bone marrow. Moreover, the prognosis of cases with multiple Stage IV factors was poor, and their resection rate was low. Novel strategies for treatment will be needed for cases with distant organ metastases or cases with multiple Stage IV factors.
L: lower third portion M: middle third portion U: upper third portion H: hepatic metastasis P: peritoneal metastasis N: lymph node metastasis M: distant metastasis LYM: lymph node CY: peritoneal lavage cytology T: depth of tumor invasion medullary type (med): scanty stroma scirrhous type (sci): abundant stroma intermediate type (int): the quantity stroma is intermediate between the two above type INFa: tumor displays expanding growth with a distant border from the surroundinr tissue INFb: tumor shows an intermediate pattern between INFa and INFc INFc: tumor displays infiltrative growth with no distinct border with the surrounding tissue ly: lymphatic invasion v: venous invasion PM: proximal margin DM: distal margin D: lymph node dissection R0: No residual tumor R1: microscopic residual tumor R2: macroscopic residual tumor FU: fluorouracil CDDP: cisplatin TXL: taxol