Summary

METHODS
Twenty-seven patients with locally advanced rectal cancer (cT3-4N0-2M0) between November 2014 and August 2016 were included in the study. A 2-week schedule of hypofractionated radiotherapy, 33 Gy/10 fractions, with concurrent 1 cycle of oral capecitabine (1650 mg/m2/day) was applied. Patients were planned to undergo surgery 6-8 weeks after the completion of chemoradiotherapy. End points were tumor responses and toxicity.

RESULTS
All patients underwent total mesorectal excision except for only 1 patient, and statistical analysis was performed on 26 patients. Of the 27 patients, 10 (38.4%) were downstaged, and 3 (11.5%) had a pathologically complete response. No grade 3-4 toxicity was observed in the patient group. Grade 1-2 hematologic toxicity developed in 2 (8%) patients, and no biochemical abnormality was observed. Gastrointestinal toxicity was observed in 17 (65%), genitourinary toxicity in 8 (30%), and radiodermatitis in 3 (11%) patients. One patient had permanent anastomosis and wound dehiscence, and presacral abscess was also seen in one patient. Enterocutaneous fistula developed in only one patient.

CONCLUSION
A 2-week schedule of radiotherapy with oral capecitabine in patients with locally advanced rectal cancer resulted in similar toxicity levels and tumor response rate in comparison with previous results.

Introduction

Although the most remarkable advantage of LCCRT over SCRT is the increased tumor response, two randomized phase III trials comparing neoadjuvant SCRT and LCCRT indicated no significant difference with regard to local control, disease-free survival, overall survival, organ preservation, and late toxicity rates.[2,3] Additionally, SCRT provides better patient compliance, shorter treatment time, and lower costs than standard fractionation with chemotherapy. In addition, according to recently published studies, shortterm radiotherapy with delayed surgery for >4 weeks provides better pathological outcomes and fewer postoperative complications.[4]

To create a better treatment scheme with regard to patient comfort and quality of life, as well as to establish an equivalent treatment plan with regard to treatment efficacy and safety, we used a new protocol that is biologically similar to standard radiotherapy dose and previously observed by Lee et al.[5] for toxicity profile and reliability. We aimed to prospectively monitor the use of a 2-week schedule of hypofractionated radiotherapy regimen delivered as a total dose of 33 Gy/10 fractions, with 1 cycle of oral capecitabine in rectal cancer in our patient group in the presence of radiological and pathological data.

Methods

Evaluation
In this prospective observational study, all patients with resectable locally advanced rectal adenocarci noma received preoperative radiotherapy (33 Gy/10 fractions) with 1 cycle of oral capecitabine (1650 mg/ m²/day) from November 2014 to August 2016.

For clinical staging, we used clinical history, physical examination, digital rectal examination, carcinoembryonic antigen determination, blood profile, and staging examinations, including colonoscopy with biopsy, chest and abdomen computed tomography (CT) scans, endoscopic ultrasound, pelvic MRI, and positron emission tomography/CT. A lymph node size of >1 cm in MRI and/or EUS is considered to be clinically positive.

All patients were clinically staged to determine the pretreatment and posttreatment stages according to the American Joint Committee on Cancer criteria, 7^th edition. Circumferential radial margin is defined as involvement within tumor margin ≤2 mm. The tumor regression grade (TRG) was assessed according to the classification recommended by Ryan TRG system.[6] Pathologic complete response (pCR) was defined as no visible microscopic disease in the primary tumor.

Patients were seen in the polyclinic two times during chemoradiotherapy to evaluate acute toxicity and compliance. Patients were also monitored 4 weeks after the completion of radiotherapy and time to surgery.

Treatment
All patients received pelvic RT with concurrent oral capecitabine. Pelvic RT was planned by the Eclipse 10.0 treatment planning system on the Rapid Arc Millennium 120 MLC system using intensity-modulated radiation therapy (IMRT) or volumetric arc therapy (VMAT) with a total dose of 33 Gy/10 fractions. All patients were simulated in the supine position. Fullness or empty bladder was not implemented. RT was delivered to the clinical target volume (CTV), including the entire mesorectum and obturator, presacral, and internal iliac lymph nodes (plus external iliac lymph nodes in cT4 patients and patients with positive obturator lymph nodes). The planning target volume was symmetrically generated with a 7 mm margin around the CTV. Peritoneal cavity, bladder, and femur heads were the organs at risk. Oral capecitabine was prescribed at a dose of 1650 mg/m²/day only during radiotherapy with drug holidays on weekends, as used in the routine. Patients underwent total mesorectal excision 6-8 weeks after the completion of chemoradiation. Postoperative chemotherapy was at the discretion of the medical oncologist. The treatment scheme is shown in Figure 1.

Fig 1: Treatment scheme.

Statistical analysis
All statistical data were analyzed using SPSS version 17.0 (SPSS Inc., Chicago, IL, USA). All results were presented as the rate for categorical values or mean and median for continuous variables. A clinically and statistically significant correlation between continuous variables was calculated by Spearman's rank correlation test, rs (Spearman's correlation coefficient), and p value (two-tailed). A p value <0.05 was considered statistically significant.

Results

Table 1: Patients characteristics

The median interval between the completion of chemoradiotherapy and surgery was 56 (36-88) days. Of the 26 patients, 24 (92.3%) underwent low anterior resection including 2 patients who had tumor within ≤2 cm to the anal verge. There were 3 patients in the sphincter-saving R1 resection group and 1 patient in the abdominoperineal resection R1 group. Among the 26 patients, 10 (38.4%) were downstaged, 3 (12%) had pCR, 6 (23.1%) were TRG1 with total tumor regression and single cells or small groups of cancer cells, 14 (53.8%) were TRG2 with residual cancer outgrown by fibrosis, and 6 (23.1%) were TRG3 with significant fibrosis outgrown by cancer and no fibrosis with extensive residual cancer. Three patients did not receive adjuvant chemotherapy due to comorbidity, treatment rejection, and surgical morbidity.

Early and late side effects that occurred during and within 1 month after chemoradiotherapy are listed in Table 2. No grade 3-4 toxicity was observed in the patient group. Grade 1-2 hematologic toxicity (leukopenia, anemia, and thrombocytopenia) developed in 2 (8%) patients, and no biochemical abnormality was observed. Grade 1-2 gastrointestinal toxicity (diarrhea, nausea, vomiting, and abdominal pain) was observed in 17 (65%), genitourinary toxicity in 8 (30%), and radiodermatitis in 3 (11%) patients, respectively. One patient had permanent anastomosis and wound dehiscence, and presacral abscess was also seen in one patient. Enterocutaneous fistula developed in only one patient.

Table 2: Acute toxicity of preoperative treatment

Discussion

In this trial, downstaging was observed in 10 (38%) patients. In addition, 3 (12%) patients had pCR, and 6 (23.1%) patients had pCR with minimal tumor cells in fibrosis at the final pathology. As a result, we achieved to obtain comparable results with Lee et al.[4] who had 13.8% pCR and 33.8% downstaging.[5] In comparison with the results of previous studies, this regimen appears to be equal to preoperative chemoradiotherapy protocols that further increased the pCR rate to approximately 11% to 18%.[9-12] In addition, there are various studies in which SCRT with delay surgery had been tested to increase the pCR rates.[4,13] Two randomized studies that compared SCRT with immediate surgery and SCRT with delayed surgery reported a higher rate of pCR in the delayed surgery group.[14,15] In another randomized trial, the comparison of SCRT and delayed surgery with LCCRT showed a higher rate of pCR in the chemoradiation groups (3% vs. 13%).[16] Additionally, in the literature, there are some publications that had tested SCRT, followed by consolidation chemotherapy before surgery. Bujko et al.[17] stated that SCRT, followed by 3 cycles of 5-fluorouracil, oxaliplatin, and leucovorin (FOLFOX) chemotherapy in comparison with long-course oxaliplatin-based preoperative chemoradiation, reveals a higher pCR rate in the SCRT group (21% vs. 8%). Similarly, Myerson et al.[18] used a regimen of 5 fractions of pelvic radiation therapy, followed by 4 cycles of FOLFOX evaluated as a preoperative regimen for cT3-4 rectal cancer. There were a total of 21 (28%) ypT0 including 19 (25%) ypT0N0 complete response.[18]

Acute toxicity during SCRT is most often of grade 1-2. However, most of the post-radiation toxicity in the immediate surgery group occurred before the occurrence of acute post-radiation toxicity, and more side effects were seen when surgery was delayed. In the interim analysis of the Stockholm III randomized trial, severe acute toxicity in 4.2% of patients in the SCRT and delayed surgery group and in none of the patients in the immediate surgery group was reported. [4] Nevertheless, SCRT with delayed surgery showed a significantly lower incidence of postoperative complications than PSRT with immediate surgery (39.4% vs. 52.5%), and LCCRT caused prolonged treatment time with similar results.[14] In only one study, Yeo et al.[19] (KROG 10-01) reported short-course radiation concurrently combined with 5-Fu and leucovorin, followed by surgery 4-8 weeks later. The pCR rate was only 1.4%, and the acute grade 3-4 toxicity was 38%.[19] In this study, the most common side effect was grade 1-2 gastrointestinal toxicity as observed in 17 (65%) patients. Although this toxicity was slightly higher than the literature, there were no grade 3-4 toxicity and no toxicity-related treatment break.

In this study, a 2-week scheduled chemoradiotherapy with oral capecitabine showed very low toxicity profiles as Lee et al.[5] A shortened duration of treatment with 1 cycle of capecitabine probably prevented to observe more acute toxicity. Compared with the main study, toxicity profiles were similar, but any grade 3 toxicity was not observed in our study. That can be caused by a small number of patients or using highly conformal radiotherapy technologies, such as IMRT and VMAT in comparison with the standard three or four field box technique. Nowadays, especially developing technologies provide the opportunity for more reliable implementation of more intensive treatment modalities. Radiotherapy applied with technologies, such as IMRT and VMAT, compared with previous series, can reduce acute bowel toxicities by decreasing the radiation exposure of the small bowel.[20] Although there is a distinct advantage of IMRT in intestinal doses as shown in dosimetric studies, additional research is needed to determine whether IMRT is able to reduce the side effects during and after pelvic RT with hypofractionated radiotherapy.[21,22]

It has been reported that short-term radiation can lead to late intestinal obstruction and sexual dysfunction.[23] Hereby, instead of acute toxicity for hypofractionated radiotherapy, the risk of long-term complications raises doubt on reliability.[24-26] Therefore, concern regarding late toxicity due to hypofractionated schedule can be a significant deterrent for physicians. A 2-week course of preoperative chemoradiotherapy achieved a satisfying downstaging rate and low incidence in toxicity profiles, considering that the late effects of 33 Gy/10 fractions are similar with 25 Gy/5 fractions. According to the linear-quadratic model, assuming that a/b is 3 Gy at the late effect, biologically effective doses were 69.3 Gy3 and 66.7 Gy3, respectively.

Conclusion

Peer-review: Externally peer-reviewed.
Conflict of Interest: None declared.
Ethics Committee Approval: This study was conducted in accordance with local ethical rules.
Financial Support: None.
Authorship contributions: Concept - S.O.; Design - S.O., H.A.; Supervision - S.O.; Materials - S.O., H.A., S.D.T., S.A., Y.S., İ.M., S.Ş.E.; Data collection &/or processing - S.O., H.A.; Analysis and/or interpretation - S.O., S.B.Y.; Literature search - S.O.; Writing - S.O.; Critical review - S.O.

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