Abstract

The rising incidence of colorectal cancer (CRC) in India, particularly the prevalence of rectal cancer over colon cancer (0.7:1), has been a growing concern in recent decades; especially notable is the trend of increasing cases among young CRC patients. Given the diverse treatment approaches for rectal cancer globally and the varying economic capacities of patients in low to middle-income countries (LMICs) like India, it is essential to establish consensus guidelines that are specifically tailored to meet the needs of these patients. To achieve this, a panel comprising 30 eminent rectal cancer experts convened to conduct a comprehensive and impartial evaluation of existing practices and recent advancements in the field. Through meticulous scrutiny of published literature and a consensus-building process that involved voting on pertinent questions, the panel formulated management strategies. These recommendations are the result of a rigorous, evidence-based process and encapsulate the collective wisdom and judgment of leading authorities in the field.

Keywords

Indian consensus and guidelines - early rectal cancer - MRI - MSI

Introduction

Colorectal cancer (CRC) is the third most common cancer worldwide. According to Globocan data 2020,[1] in India, CRC accounted for 6.7% (89,937) of all cancer cases and 7.7% (65,068) of all deaths, with a cumulative risk of 1.85. The incidence of CRC in India has been increasing over the past few decades, with the National Cancer Registry Programme (NCRP) estimating 70,220 new cases in 2020. Men are more commonly affected than women, with an incidence rate of 10.8 per 100,000 men and 7.5 per 100,000 women. According to a recent study presented in the Journal of Clinical Oncology by All India Institute of Medical Sciences, the prevalence and incidence of rectal cancer in India are observed to be higher than colon cancer, with colon to rectal cancer ratio being 0.7:1.[2] Further analysis showed that the mean age at presentation for colon cancer was 51 years, whereas for rectal cancer, it was 45 years. Notably, a considerable proportion of patients qualified as young CRC (diagnosed at or before the age of 40 years), accounting for 34.7%-of the total patient cohort. Among this group of young CRC patients, rectal cancer was observed more frequently than colon cancer, with proportions of 41.3 and 25.4%, respectively. In light of different approaches to rectal cancer treatment worldwide, such as variations in the strategies recommended by organizations like the National Comprehensive Cancer Network (NCCN) and the European Society for Medical Oncology (ESMO), and the differing financial situations of patients in India, including some who are covered under government schemes while others face out-of-pocket expenses, it is necessary to develop consensus guidelines that are tailored to the needs of our population. Our initial step toward promoting collaboration involved gathering and scrutinizing the published literature in order to produce an informative guide specifically tailored to rectal cancer patients in low- or middle-income country such as India.

Methodology

Our recommendations for rectal cancer management ([Tables 1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11]; [Fig. 1]) were derived from the existing guidelines established by NCCN and ESMO. To ensure a comprehensive and unbiased assessment, we gathered a panel of 30 renowned experts in the field of rectal cancer and requested their participation in voting on relevant questions. ([Supplementary]) All panel members were urged to vote on every question, with those with potential conflicts of interest advised to abstain from voting on that particular issue. The panel then discussed the recommendations, highlighting areas of substantial disagreement or controversy. After incorporating recent advances and rectifying any inaccuracies, the revised recommendations were circulated to all panel members via email for further review. In accordance with the ESMO guideline methodology, each recommendation is accompanied by a level of evidence and grade of recommendation, which reflect the strength of the available evidence and the degree of agreement among experts, respectively[3] ([Appendix]). These assessments are further substantiated by a consensus determined by the number of experts who agreed to a given recommendation relative to the total number of experts who voted. These rigorous standards ensure that these recommendations are grounded in a thorough and systematic evaluation of the available evidence, and reflect the collective expertise and judgement of the leading experts.

| Fig 1 :An algorithm for management of localized rectal cancer. TME – Total mesorectal excision; TAMIS – Transanal minimally invasive surgery; LCRT – 1.8 Gy x 25# radiotherapy with chemotherapy (capecitabine); PROSPECT – perspective FOLFOX and selective RT followed by TME; PRODIGE-23 – Induction mFOLFIRINOX for 2 to 3 months → LCRT → TME or W&W (if cCR); RAPIDO – SCRT→ Consolidation CAPOX or FOLFOX for 3 to 4 months → TME or W&W (if cCR); OPRA – LCRT → Consolidation CAPOX or FOLFOX for 3 to 4 months →TME or W&W (if cCR); cCR – Clinically complete response. *preferred if the goal is to achieve cCR for W&W approach; **preferred if N2 or EMVI where risk of distant failure high. Adjuvant FOLFOX or COPOX after TME. ***may have highter local recurrence compared to LCRT.

| Figure 2: Timing of total mesorectal excision (TME) in various pivotal trials. TME, Total mesorectal excision; SCRT, Short course radiation therapy – 5 x 5 gy over 5 days; LCRT, Long course chemoradiation; 5-FU, 5-Fluorouracil; FOLFOX, 5-FU, Oxaliplation; FOLFIRINOX, 5-FU, Oxaliplation, Irinotecan; CAPOX, Capecitabine, Oxaliplation; RAPIDO, Radiotherapy and preoperative induction therapy followed by dedicated operation; OPRA, Organ preservation in rectal adenocarcinorma. *Timing from end of RT; #I-immediate – 1 wk; D-delayed – 4 to 8 wks; ^Timing from end of TNT; Wks – Weeks.

The optimal timing of surgery after SCRT is debatable, and there is no consensus on the best approach. Most of the significant trials described above, which compared SCRT followed by surgery versus surgery alone[83] or SCRT versus LCRT before surgery,[82] used an interval to surgery of 7 days after completion of SCRT. On the other hand, the further surgery if needed due to tumor overgrowth, the median interval time for surgery in the Dutch TME trial was 11 days. Some studies have reduced the time to 3 days, citing the cause of treatment-related leukopenia contributing to poor wound healing after delayed surgery.[112] [113] Similar to the ESMO guidelines, we recommend that either approach (immediate surgery <10 href="https://www.thieme-connect.com/products/ejournals/html/10.1055/s-0043-1777865#JR23741198-16" xss=removed>16] The optimal interval between completion of neoadjuvant CRT and surgery in rectal adenocarcinoma is also not established. Updated guidelines from the ESMO provide no specific recommendation other than to state that in practice, here is a wide variation in the timing of surgery, with intervals ranging from 4 to 12 weeks. Prolonging this interval may not only enhance the rate of pCR but also provide an opportunity for tumor repopulation. Moreover, delaying surgery can also postpone the administration of postoperative chemotherapy. The benefits of longer intervals must therefore be carefully weighed against the potential risk of subsequent metastases.[16]

Adjuvant Therapy

Postoperative CRT could be considered in patients with adverse histopathological features after upfront surgery—like positive CRM, perforation in the tumor area, incomplete mesorectal resection, nodal deposits with extracapsular spread close to the MRF, or if preoperative RT has not been given in patients with high risk of local recurrence.[114] The rates of local failure with surgery alone range from 15 to 30%-with T3N0 stage II disease compared to T1 and T2 disease where it is less than 10%. The failure rate increases up to 65%-with node positive status in T3/T4 disease. The suggested chemotherapy partner for treating the patient is infusional 5-FU or capecitabine at a dose of 825 mg/m2 twice daily, 5 days a week. The bolus 5-FU is not recommended because of the major hematological toxicity associated with it. Moreover, the results of the GITSG and NCCTG trials have shown that RT alone after surgery is an inferior option with a lack of survival benefit when compared to chemoradiotherapy (CRT).[115] Oxaliplatin should not be used concurrently with radiotherapy.

The available randomized controlled trials and meta-analyses have not provided clear evidence on the benefit of adjuvant chemotherapy, as the methods used in these trials for answering this question are not standard. Additionally, there is a lack of data to strongly support the use of adjuvant chemotherapy in patients with rectal cancer who have received neoadjuvant chemoradiotherapy.[114] As such, there are variations in the recommendations for adjuvant therapy between American and European nations. The NCCN recommends the use of adjuvant therapy irrespective of the outcomes of neoadjuvant chemoradiotherapy. On the other hand, the ESMO recommends adjuvant chemotherapy for high-risk patients with pathological stage II and stage III disease. According to a retrospective propensity score matched analysis conducted over a period of 6 years using the National Cancer Database in the USA, there is limited benefit in patients who achieve a complete pathological response after neoadjuvant chemoradiotherapy (CRT).[116] The Indian Society of Medical & Paediatric Oncology recommends the discretion of physicians when deciding whether to observe patients with pCR or to administer adjuvant chemotherapy to all other patients. In the adjuvant setting, the recommended regimen is a combination of 5-FU and oxaliplatin, based on data from the phase II Adjuvant Oxaliplatin in Rectal Cancer (ADORE) trial.[117] Since International Duration Evaluation of Adjuvant therapy study included exclusively colon cancer patients, there is no strong evidence to comment on duration of chemotherapy for the rectal cancer patients. The panel recommends to give a total of 6 months of chemotherapy including the period of chemoradiation[118] ([Table 9]).

W&W Strategy

De-escalation strategies are being researched in oncology to gain better quality of life without compromising the survival outcomes. Patients with LARC do suffer from significant surgical toxicities like bowel dysfunction, perianal discharge, and LAR syndrome. W&W strategy is being practiced in many institutions wherein patients who have obtained complete clinical response after neoadjuvant concurrent chemoradiotherapy is observed for local recurrence and surgical morbidities are obviated. W&W merits discussion in this important policy document. In the meta-analysis by Dossa et al on published literature primarily on retrospective studies, there was no difference between W&W and surgery in terms of OS in patients who had achieved complete clinical response.[119] However, the risk of local recurrence remains high, with rates as high as 30%, although nearly 85%-of these local recurrences can be salvaged.[120] The international registry on W&W database collected data on over 1,000 patients and found that the majority (88%) of recurrences occurred within the first 2 years, and 97%-of recurrences were in the rectum wall. Some studies have shown that the OS may be inferior with the W&W strategy.[121]

Considering the morbidity of up to a 90%-rate of LAR syndrome, which includes symptoms like tenesmus, perianal discharge, increased stool frequency, pain, and fecal incontinence,[122] many patients would not agree for surgery and or stoma. Newer approaches like total neoadjuvant treatment question the role of universal surgery for all paradigm for LARC. “Wait” is acceptable, but how to “watch” in our setup is a big challenge. The W&W strategy requires intense monitoring or surveillance for local recurrence like DRE, endoscopy, and MRI. These investigations are limited by their sensitivity and specificity. Repeated biopsies are not recommended. The majority of local recurrences in rectal cancer patients who undergo W&W can be successfully treated surgically, as shown by retrospective studies and IWWD data. In absence of strong prospective data and limitations of intense follow-up, patient selection remains a key here. Tumors located in the lower and mid-rectum that require TME can be considered for W&W, especially for patients who wish to avoid permanent stoma.

The concept of W&W is applicable to operable cases and can also be extended to medically inoperable cases, where addressing comorbidities like heart disease and diabetes mellitus can be combined with reassurance on the W&W strategy. W&W is a promising nonsurgical option for selected patients, and prospective large sample studies are needed to fill the lacuna in literature to support its universal adoption ([Table 10]).

Surveillance

The purpose of post-treatment surveillance in rectal cancer is to detect the recurrence of the disease at an early stage, allowing for timely curative interventions. The recommendations for transanal local excision patients include proctoscopy with EUS or contrast-enhanced MRI every 3 to 6 months for the first 2 years, then every half-yearly for a total of 5 years. Colonoscopy at 1 year after surgery with repeat intervals based on status of adenoma and based on expert opinion is recommended for them as well as those with stage I nonLynch rectal cancer.[123]

Stage II and III patients are recommended for intensive postoperative surveillance due to a risk of 5 to 30%-recurrence rate. A recent study reported that 95%-of CRC recurrences occur within 5 years post-treatment,[124] while data from 20,898 patients in 18 colon cancer trials found that 80%-of recurrences occur within the first 3 years.[125] Unfortunately, surveillance strategies such as imaging or CEA screening did not offer a significant survival advantage over a symptom-based approach for these patients.[126] The COLOFOL trial of 2509 patients with stage II or III CRC found no significant difference in 5-year overall or CRC-specific mortality between high-frequency and low-frequency surveillance approaches.[127] A meta-analysis reported a sensitivity of 68%-and specificity of 97%-for a CEA cutoff of 10 ng/mL; however, it showed limitations in detecting recurrences within the first 2 years post-treatment.[128] Surveillance protocol recommendations for non-Lynch patients with stage II to III rectal cancer include physical examination and CEA screening every 3 to 6 months for 2 years, then every 6 months for 5 years, along with chest/abdominal/pelvic CT every 6 to 12 months for 5 years based on expert opinion.

Lynch syndrome-associated CRCs present at a younger age, are predominantly right-sided, and progress rapidly from adenoma to cancer. Regular colonoscopy is the only effective surveillance protocol, with a decrease in CRC mortality of up to 72%. Guidelines recommend colonoscopy every 2 to 3 yearly starting as early as at age of 25 years for the patients with molecular confirmation of Lynch syndrome. More stringent surveillance may be warranted for MLH1 and MSH2 gene carriers as compared to MSH6 and PMS2.[129] Aspirin, has been found to be associated with reduced CRC risk in Lynch syndrome carriers. We aim to systematically promote this intervention for all Lynch syndrome carriers and recommend low-dose aspirin 100 to 150 mg for at least 2 years.[130]

The application of PET/CT in disease surveillance is not advisable due to potential hazards such as unwarranted medical interventions following false positive results and unjustified radiation exposure.[131] [132] While studies have shown that ctDNA detection can predict cancer relapse with high accuracy and earlier than radiologic imaging or CEA, the current evidence for its value in post-treatment surveillance is limited by small sample sizes and lack of validation cohorts. Ongoing trials are aimed at establishing ctDNA-based surveillance strategies and determining if early diagnosis impacts survival[133] ([Table 11]).

Conflict of Interest

As mentioned in the individual forms separately by each author.

All authors have read and approved the manuscript, met the requirements for authorship, and believe that the manuscript represents honest work.

Acknowledgements

We thank the following for their contribution during the consensus meetings.

Dr. Devendra Parikh

Dr. Sarthak Kumar Mohanty

Dr. Senthil Rajappa

Dr. Avanish Saklani

Dr. A S Ramakrishnan

Dr. Ninad Katdare

Dr. Vamshi Krishna

Dr. Randeep Singh

Dr. T P Sahoo

Dr. Syed Nisar

Dr. Anil Goel

Dr. Minaal Iyer

Dr. Samir Batham

Dr. Vijay Agarwal

Dr. Trinanjan Basu

Dr. Bharti Devnani

Dr. Arvind Krishnamurthy

Dr. Pinaki Mahato

Dr. Tanmoy Mandal

Dr. Jagannath Dixit

Dr. Aditi Bhatt

Dr. Madhu Sairam

Authors' Contributions

Bhawna Sirohi and Viraj Lavingia were involved in concept and design. All the authors have helped in definition of intellectual content, literature search, manuscript preparation, manuscript editing, and manuscript review.

Patient Consent

No, as in this article, the guidelines presented are derived from a comprehensive literature review and expert consensus.

Supplementary Material

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| Fig 1 :An algorithm for management of localized rectal cancer. TME – Total mesorectal excision; TAMIS – Transanal minimally invasive surgery; LCRT – 1.8 Gy x 25# radiotherapy with chemotherapy (capecitabine); PROSPECT – perspective FOLFOX and selective RT followed by TME; PRODIGE-23 – Induction mFOLFIRINOX for 2 to 3 months → LCRT → TME or W&W (if cCR); RAPIDO – SCRT→ Consolidation CAPOX or FOLFOX for 3 to 4 months → TME or W&W (if cCR); OPRA – LCRT → Consolidation CAPOX or FOLFOX for 3 to 4 months →TME or W&W (if cCR); cCR – Clinically complete response. *preferred if the goal is to achieve cCR for W&W approach; **preferred if N2 or EMVI where risk of distant failure high. Adjuvant FOLFOX or COPOX after TME. ***may have highter local recurrence compared to LCRT.

| Figure 2: Timing of total mesorectal excision (TME) in various pivotal trials. TME, Total mesorectal excision; SCRT, Short course radiation therapy – 5 x 5 gy over 5 days; LCRT, Long course chemoradiation; 5-FU, 5-Fluorouracil; FOLFOX, 5-FU, Oxaliplation; FOLFIRINOX, 5-FU, Oxaliplation, Irinotecan; CAPOX, Capecitabine, Oxaliplation; RAPIDO, Radiotherapy and preoperative induction therapy followed by dedicated operation; OPRA, Organ preservation in rectal adenocarcinorma. *Timing from end of RT; #I-immediate – 1 wk; D-delayed – 4 to 8 wks; ^Timing from end of TNT; Wks – Weeks.

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