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Overview

Practice Essentials

Radiation therapy (RT) is a mainstay in the treatment of both primary and recurrent gastrointestinal (GI) and pelvic malignancies.^{[1, 2]}Combining treatment modalities (surgery, chemotherapy, RT) allows for the best possible outcome in patients with these malignancies. One of the major and debilitating adverse effects of RT is the development of radiation enteritis and proctitis.^{[3, 4]}Both radiation enteritis and radiation proctitis have acute (early) and chronic (late) manifestations.

The direct effects of radiation on the bowel mucosa lead to acute radiation enteritis. Acute radiation enteritis is exceedingly common; virtually every patient has some manifestation of acute radiation-induced injury of the GI tract in the form of abdominal cramping, tenesmus, urgency, bleeding, diarrhea, and incontinence. Typically, these patients are managed symptomatically and supportively. The symptoms of most patients resolve within weeks of RT cessation.

Chronic radiation enteritis is an indolent but relentlessly progressive disease. Patients may present with symptoms within months or even decades after the injuring RT. Chronic intestinal radiation injury is a result of transmural bowel damage with associated obliterative endarteritis.

Treatment of these patients is extremely challenging. Initial nonoperative modalities include diet modification, nutritional support, and control of symptoms with medications.^[5] Severe, progressive disease may require surgical intervention, especially for complications, such as fistula formation, obstruction, perforation, and hemorrhage.

Although the benefits of treatment with radiation are well established, damage to the healthy, nonneoplastic tissue may be severe.^[6] The rectum is more commonly injured because of its fixed position in the pelvis. Postoperative adhesions that fix small-bowel loops within the pelvis make these loops susceptible to radiation injury. Because RT is increasingly used to treat pelvic malignancies, the surgical prevention and treatment of the complications of radiation enteritis and proctitis continue to evolve.

Just 2 years after the discovery of x-rays in 1895, Walsh reported the first case of radiation-induced enteritis. A patient who worked with x-rays had developed abdominal pain and diarrhea, symptoms that resolved with the use of a lead shield. In 1917, the first case was reported of the development of radiation enteritis following the use of radiotherapy to treat malignancy. In 1930, researchers reported the development of factitial proctitis in a group of patients who received pelvic radiation to treat malignant disease.

As the use of RT and x-rays in medicine increased, the harmful adverse effects were better recognized. Warren and Friedman described both early and late effects of RT on the intestine. Once the risks associated with RT were recognized, attempts followed to prevent these complications. The development of improved dosimetry techniques, as well as patient selection and positioning during delivery of RT, were crucial to decrease the harmful effects of radiation on the intestines.

The history of surgical prevention of small-bowel radiation injury is based on the principle of abdominopelvic partitioning. The goal of this procedure is to keep the highly radiation-sensitive small intestine out of the pelvis. In 1979, Freund et al published the first report of a surgical procedure to create abdominopelvic partitioning. In 1984, Russ et al described the use of an omental pedicle flap. In 1985, DeLuca and Ragins described the creation of an omental envelope to enclose the small bowel.

In 1992, Lechner and Cesnik again described this technique and coined the term abdominopelvic omentopexy. In 1995, Choi and Lee described the omental hammock technique. The omental pedicle, based on the left gastroepiploic artery, is sutured circumferentially to the parietal peritoneum at the level of the sacral promontory and the umbilicus. A hammock is created within which the small bowel rests; the hammock prevents the bowel from entering the pelvic cavity.

Patients often lack adequate amounts of omentum or peritoneum to create an abdominopelvic separation. In 1979, Lavery et al reported their use of gauze packs encased in a latex dam to protect the abdominal viscera during high-dose RT for osteogenic sarcoma of the iliac bone. In 1983, Sugarbaker described the use of a silicone breast implant to occupy the pelvic cavity. Hoffman reported the use of saline-filled tissue expanders to occupy the pelvic cavity. In 1984, Devereux et al described, in a group of 60 patients, the use of mesh slings after resection of rectal or gynecologic malignancies.

Historically, the surgical procedures to treat the complications of radiation enteritis have been as minimally invasive as possible, with the goal of relieving symptoms. Patients with fistulas and obstruction underwent bypass, and patients with bleeding associated with radiation proctitis underwent diverting colostomy. In 1976, Swan et al reported that resection for fistulas and obstruction was associated with prohibitive rates of morbidity and mortality. In 1984, Webbes et al and Goligher et al reaffirmed these recommendations. Multiple reports have suggested that resection reduces the reoperative rate and improves the 5-year survival rate but leads to a higher rate of postoperative mortality.

Next: Pathophysiology

Pathophysiology

Histopathologic findings in acute radiation-related intestinal damage include the following characteristics:

Transient mucosal atrophy
Submucosal edema
Inflammation and infiltration of the lamina propria with polymorphonuclear leukocytes and plasma cells

In addition, mitotic arrest, karyorrhexis, and lysis of the crypt and deep epithelial cells are observed. If the submucosal damage is not prominent, the epithelial cells regenerate and the changes regress. Conversely, severe submucosal changes lead to progression of mucosal injury, ulcerations, and erosion of the villi. The histologic findings in the acute phase correlate poorly with clinical symptoms, but amounts of malabsorption vary because of the mucosal damage.

Repopulation of the mucosal cells occurs in the later stage of the acute phase. The severity of the damage to supportive connective tissue limits the degree of reepithelialization. The fibrosis of the underlying connective tissue causes patchy ischemia of the mucosa, which may cause ulceration. Local trauma or infection often precipitates these ulcers.

Histologically, obliterative endarteritis of the small vessels in the intestinal wall characterizes chronic radiation injury to the intestine. Associated lymphoid atrophy, lymphatic dilation, and fibrosis of the submucosal tissue are observed. The progressive vascular sclerosis leads to chronic ischemia of the overlying tissue, ultimately resulting in mucosal atrophy. Scar tissue replaces the submucosal tissue, resulting in further decrease in vascularity and contracture of the intestinal wall. Chronic mucosal ulceration may result in fistula formation and hemorrhage.

In the later stages, the colon and rectum are susceptible to the development of radiation-induced carcinomas, which may manifest as ulcers or masses and are often adenocarcinomas.

There is also evidence supporting a pivotal role for gut microbiota dysbiosis in the development of radiation-induced bowel injury.^{[7, 8, 9]}

Next: Pathophysiology

Etiology

Radiation injury to the small and large bowel is due to damage to the lipid layer of the cell membrane, proteins, and cellular DNA. The effects are most marked in tissues containing cells with a high mitotic rate.

Patient-related factors and the method of RT administration may intensify the effects of radiation-induced intestinal injury. Patient-related risk factors that are associated with an increased risk of radiation-induced enteropathy include the following:

Advanced patient age
Prior abdominal surgery leading to intraperitoneal adhesions - Adhesions fix portions of the small or large intestine in the radiated field
History of pelvic inflammatory disease
Hypertension
Diabetes mellitus
Thin physique
Administration of chemotherapy
Other risk factors (eg, collagen vascular diseases, xeroderma pigmentosum, Cockayne syndrome)

Analysis of multiple risk factors for predictive value demonstrated that multiple laparotomies, hypertension, and thin physique had the highest correlation with the development of radiation enteritis.

Administration of chemotherapy with RT correlates with an increased incidence of radiation-related intestinal damage. Several studies have documented this effect as well as the recall phenomenon, in which RT followed with chemotherapy leads to a recurrence of the symptoms of radiation-induced intestinal injury.

The degree of intestinal injury is directly related to the total radiation dose, the fractionation, and the distribution of the dose in tissues peripheral to the target area. Early in the evolution of RT, large single radiation doses were noted to cause severe or even lethal adverse effects; the same cumulative dose given as small fractions over the course of several days or weeks was better tolerated.

For example, a single 30-Gy dose of radiation to the esophagus is tolerated poorly; however, when the dose is fractionated and spread over 4-6 weeks, even a total dose of 60-70 Gy is tolerated. Similarly, Deore et al demonstrated an increased incidence (8.2-33.3%) of late rectal and rectosigmoid complications as the dose per fraction increased from 2 Gy to 5.4 Gy in patients treated for cancer of the cervix with radiation alone.^[10]

Excessive exposure of adjacent normal tissue to radiation also contributes to the development of radiation-induced enteropathy. Current techniques allow for a focused delivery of radiation energy to the target tissues with intracavitary radiation as well as external beam with supervoltage radiation, multiple portals, and the improved shielding of adjacent normal structures. RT's adverse effects may be decreased with a combination of the following:

Multidirectional, sharply collimated beams
Computer-assisted dosimetry
More stable intracavitary applicators
Extended intervals between fractionated doses and a lower dose per fraction

Next: Pathophysiology

Epidemiology

More than 200,000 new cases of prostate, cervical, rectal, testicular, bladder, and endometrial cancer are diagnosed each year. Approximately 50% of these patients require RT.

Acute radiation-induced injury to the GI mucosa occurs in virtually all patients undergoing RT. In more than 80% of patients, treatment can control the symptoms of tenesmus, diarrhea, and hematochezia. The use of antispasmodics, analgesics, and antidiarrheal agents combined with intravenous (IV) fluid replacement are often adequate to treat patients with acute radiation enteritis and proctitis.

In a small number of patients, the severity of symptoms requires cessation of RT. This occurs most commonly in patients who are receiving concomitant chemotherapy or in those at high risk to develop radiation enteritis prior to initiation of therapy.

Approximately 5-15% of patients who receive abdominal or pelvic RT develop pronounced chronic radiation enteritis. Up to 50% of patients with severe chronic radiation enteropathy require surgical intervention. In patients who receive postoperative RT, as many as 30-40% experience chronic diarrhea. More than 1 million patients in the United States may have bowel dysfunction related to RT.

Abayomi et al investigated the incidence of chronic radiation enteritis in 117 women who had undergone RT for cervical or endometrial cancer.^[11]They also sought to determine whether radiation level or cancer stage was associated with an increased risk for enteritis. In response to a questionnaire relating to bowel problems and quality of life, 47% of patients had scores indicating the presence of chronic radiation enteritis. Although scores did not significantly correlate with radiation dose or cancer stage, the investigators determined that scores indicative of chronic radiation enteritis were most prevalent among younger women and among patients who had been treated for cervical cancer.

Next: Pathophysiology

Prognosis

Surgical procedures on radiated intestine carry a morbidity of 12-65% and a mortality of 2-13%. The wide range reflects the diverse surgical procedures used to treat complications of radiation.

Preoperative RT has been attributed with a reduced cancer-specific mortality compared with postoperative RT in soft-tissue sarcoma. Additional studies with larger patient numbers are needed.^[12]

Factors that adversely affect prognosis after surgery include intestinal leak, surgery for fistula or perforation, and progression of radiation-induced damage after the initial operation.

An anastomotic breakdown incidence as high as 50% has been noted after resection and anastomosis involving diseased segments of bowel in radiation enteritis.

Almost 50% of patients who survive a laparotomy for radiation-induced bowel injury require further surgery for ongoing bowel damage from radiation. A mortality as high as 25% is reported for patients who require a second surgical procedure. The mortality is directly attributable to the radiation enteritis and complications of treatment.

In an analysis of 77 patients diagnosed with radiation enteritis or proctitis, Ruiz-Tovar et al compiled various statistics relating to the location, treatment, and outcome of these injuries.^[13] Radiation injury sites were as follows:

Ileum, 55 patients (71%)
Rectum, 22 patients (29%)

Treatment course was as follows:

Medical management, 28 patients (36%)
Surgical treatment, 49 patients (64%) - Resection, 41 (53%); bypass, five (6.5%); terminal colostomy, three (4%)
Surgical complications, seven patients (9%)
Surgical mortality, three patients (4%)
Recurrence of radiation-related illness, 12 patients (16%)
Survival rate (excluding mortality from tumoral progression) at 5 years, 90%; at 10 years, 83%

Clinical Presentation

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Bhutta BS, Fatima R, Aziz M. Radiation Enteritis. Treasure Island, FL: StatPearls; 2023. [Full Text].
Araujo IK, Muñoz-Guglielmetti D, Mollà M. Radiation-induced damage in the lower gastrointestinal tract: Clinical presentation, diagnostic tests and treatment options. Best Pract Res Clin Gastroenterol. 2020 Oct-Dec. 48-49:101707. [QxMD MEDLINE Link].
Cai Z, Cai D, Yao D, Chen Y, Wang J, Li Y. Associations between body composition and nutritional assessments and biochemical markers in patients with chronic radiation enteritis: a case-control study. Nutr J. 2016 May 28. 15 (1):57. [QxMD MEDLINE Link].
Kalaiselvan R, Theis VS, Dibb M, Teubner A, Anderson ID, Shaffer JL, et al. Radiation enteritis leading to intestinal failure: 1994 patient-years of experience in a national referral centre. Eur J Clin Nutr. 2014 Feb. 68 (2):166-70. [QxMD MEDLINE Link].
Ren H, Wu Q, Sun Z, Fang M, Liu J, Luo J. Research progress and treatment of radiation enteritis and gut microbiota. Radiat Oncol J. 2023 Jun. 41 (2):61-68. [QxMD MEDLINE Link]. [Full Text].
Kumagai T, Rahman F, Smith AM. The Microbiome and Radiation Induced-Bowel Injury: Evidence for Potential Mechanistic Role in Disease Pathogenesis. Nutrients. 2018 Oct 2. 10 (10):[QxMD MEDLINE Link]. [Full Text].
Jian Y, Zhang D, Liu M, Wang Y, Xu ZX. The Impact of Gut Microbiota on Radiation-Induced Enteritis. Front Cell Infect Microbiol. 2021. 11:586392. [QxMD MEDLINE Link]. [Full Text].
Deore SM, Shrivastava SK, Supe SJ, Viswanathan PS, Dinshaw KA. Alpha/beta value and importance of dose per fraction for the late rectal and recto-sigmoid complications. Strahlenther Onkol. 1993 Sep. 169 (9):521-6. [QxMD MEDLINE Link].
Abayomi J, Kirwan J, Hackett A. The prevalence of chronic radiation enteritis following radiotherapy for cervical or endometrial cancer and its impact on quality of life. Eur J Oncol Nurs. 2009 Sep. 13 (4):262-7. [QxMD MEDLINE Link].
Sampath S, Schultheiss TE, Hitchcock YJ, Randall RL, Shrieve DC, Wong JY. Preoperative versus postoperative radiotherapy in soft-tissue sarcoma: multi-institutional analysis of 821 patients. Int J Radiat Oncol Biol Phys. 2011 Oct 1. 81 (2):498-505. [QxMD MEDLINE Link].
Ruiz-Tovar J, Morales V, Hervás A, Sanjuanbenito A, Lobo E, Martínez-Molina E. Late gastrointestinal complications after pelvic radiotherapy: radiation enteritis. Clin Transl Oncol. 2009 Aug. 11 (8):539-43. [QxMD MEDLINE Link].
Webb GJ, Brooke R, De Silva AN. Chronic radiation enteritis and malnutrition. J Dig Dis. 2013 Jul. 14 (7):350-7. [QxMD MEDLINE Link].
[Guideline] Paquette IM, Vogel JD, Abbas MA, Feingold DL, Steele SR, Clinical Practice Guidelines Committee of The American Society of Colon and Rectal Surgeons. The American Society of Colon and Rectal Surgeons Clinical Practice Guidelines for the Treatment of Chronic Radiation Proctitis. Dis Colon Rectum. 2018 Oct. 61 (10):1135-1140. [QxMD MEDLINE Link]. [Full Text].
Tas S, Ozkul F, Arik MK, Kiraz A, Vural A. The effect of amifostine on bacterial translocation after radiation ınduced acute enteritis. Acta Cir Bras. 2016 Mar. 31 (3):156-60. [QxMD MEDLINE Link].
Vidal-Casariego A, Calleja-Fernández A, de Urbina-González JJ, Cano-Rodríguez I, Cordido F, Ballesteros-Pomar MD. Efficacy of glutamine in the prevention of acute radiation enteritis: a randomized controlled trial. JPEN J Parenter Enteral Nutr. 2014 Feb. 38 (2):205-13. [QxMD MEDLINE Link].
Garcia-Peris P, Velasco C, Hernandez M, Lozano MA, Paron L, de la Cuerda C, et al. Effect of inulin and fructo-oligosaccharide on the prevention of acute radiation enteritis in patients with gynecological cancer and impact on quality-of-life: a randomized, double-blind, placebo-controlled trial. Eur J Clin Nutr. 2016 Feb. 70 (2):170-4. [QxMD MEDLINE Link].
Scartoni D, Desideri I, Giacomelli I, DI Cataldo V, DI Brina L, Mancuso A, et al. Nutritional Supplement Based on Zinc, Prebiotics, Probiotics and Vitamins to Prevent Radiation-related Gastrointestinal Disorders. Anticancer Res. 2015 Oct. 35 (10):5687-92. [QxMD MEDLINE Link].
Yan H, Wu M, Wang W, Wang D, Huang X, Dong J, et al. Dosimetry and acute radiation enteritis comparison between prone and supine position in IMRT for gynecological cancers. J Appl Clin Med Phys. 2023 Aug 24. e14135. [QxMD MEDLINE Link].
Moreira Monteiro A, Alpuim Costa D, Mareco V, Espiney Amaro C. The effectiveness of hyperbaric oxygen therapy for managing radiation-induced proctitis - results of a 10-year retrospective cohort study. Front Oncol. 2023. 13:1235237. [QxMD MEDLINE Link]. [Full Text].
Chen W, Ma Q, Yang L, Zhang L, Zhu J, Lin W. Curative effects of montmorillonite powder combined with dexamethasone on acute radiation enteritis. Am J Transl Res. 2021. 13 (6):7270-7275. [QxMD MEDLINE Link]. [Full Text].
Liu D, Wei M, Yan W, Xie H, Sun Y, Yuan B, et al. Potential applications of drug delivery technologies against radiation enteritis. Expert Opin Drug Deliv. 2023 Apr. 20 (4):435-455. [QxMD MEDLINE Link].
Polese L, Marini L, Rizzato R, Picardi E, Merigliano S. Endoscopic diode laser therapy for chronic radiation proctitis. Lasers Med Sci. 2018 Jan. 33 (1):35-39. [QxMD MEDLINE Link].
Weiner J, Schwartz D, Martinez M, Safdieh J, Aytaman A, Schreiber D. Long-term results on the efficacy of argon plasma coagulation for patients with chronic radiation proctitis after conventionally fractionated, dose-escalated radiation therapy for prostate cancer. Pract Radiat Oncol. 2017 Jan - Feb. 7 (1):e35-e42. [QxMD MEDLINE Link].
Siow SL, Mahendran HA, Seo CJ. Complication and remission rates after endoscopic argon plasma coagulation in the treatment of haemorrhagic radiation proctitis. Int J Colorectal Dis. 2017 Jan. 32 (1):131-134. [QxMD MEDLINE Link].
Montes de Oca Megías E, Morera Pérez M, Noa Pedroso G, Piñol Jiménez F, Armenteros Torres M. Short and long term response to argon plasma therapy for hemorrhagic radiation proctitis. Rev Esp Enferm Dig. 2019 Nov. 111 (11):852-857. [QxMD MEDLINE Link].
Jain N, Mohan JA, Ramita S, Kanchan S, Amandeep K, Meena S. Argon plasma coagulation therapy in hemorrhagic radiation proctitis following pelvic radiation in gynecological malignancies. J Cancer Res Ther. 2023 Apr-Jun. 19 (3):708-712. [QxMD MEDLINE Link].
McCarty TR, Garg R, Rustagi T. Efficacy and safety of radiofrequency ablation for treatment of chronic radiation proctitis: A systematic review and meta-analysis. J Gastroenterol Hepatol. 2019 Sep. 34 (9):1479-1485. [QxMD MEDLINE Link].
Huang Y, Guo F, Yao D, Li Y, Li J. Surgery for chronic radiation enteritis: outcome and risk factors. J Surg Res. 2016 Aug. 204 (2):335-343. [QxMD MEDLINE Link].
Russ JE, Smoron GL, Gagnon JD. Omental transposition flap in colorectal carcinoma: adjunctive use in prevention and treatment of radiation complications. Int J Radiat Oncol Biol Phys. 1984 Jan. 10 (1):55-62. [QxMD MEDLINE Link].
DeLuca FR, Ragins H. Construction of an omental envelope as a method of excluding the small intestine from the field of postoperative irradiation to the pelvis. Surg Gynecol Obstet. 1985 Apr. 160 (4):365-6. [QxMD MEDLINE Link].
Lechner P, Cesnik H. Abdominopelvic omentopexy: preparatory procedure for radiotherapy in rectal cancer. Dis Colon Rectum. 1992 Dec. 35 (12):1157-60. [QxMD MEDLINE Link].
Choi HJ, Lee HS. Effect of omental pedicle hammock in protection against radiation-induced enteropathy in patients with rectal cancer. Dis Colon Rectum. 1995 Mar. 38 (3):276-80. [QxMD MEDLINE Link].
Freund H, Gunderson L, Krause R, Fischer JE. Prevention of radiation enteritis after abdominoperineal resection and radiotherapy. Surg Gynecol Obstet. 1979 Aug. 149 (2):206-8. [QxMD MEDLINE Link].
Chen JS, ChangChien CR, Wang JY, Fan HA. Pelvic peritoneal reconstruction to prevent radiation enteritis in rectal carcinoma. Dis Colon Rectum. 1992 Sep. 35 (9):897-901. [QxMD MEDLINE Link].
Devereux DF, Kavanah MT, Feldman MI, Kondi E, Hull D, O'Brien M, et al. Small bowel exclusion from the pelvis by a polyglycolic acid mesh sling. J Surg Oncol. 1984 Jun. 26 (2):107-12. [QxMD MEDLINE Link].
Lavery IC, Harford FJ Jr, Fazio VW. Protection of the intestine during radiation of the pelvic bone. Surg Gynecol Obstet. 1979 Jul. 149 (1):33-5. [QxMD MEDLINE Link].
Sugarbaker PH. Intrapelvic prosthesis to prevent injury of the small intestine with high dosage pelvic irradiation. Surg Gynecol Obstet. 1983 Sep. 157 (3):269-71. [QxMD MEDLINE Link].
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Media Gallery

Contrast study of the small bowel revealing areas of extensive strictures with a loop of bowel fixed in the pelvis.
Diffuse inflammation and areas of superficial ulceration observed endoscopically in acute radiation enteritis.
Omental transposition flap based on left gastroepiploic vascular bundle is sutured in place along the left paracolic gutter, and the omental bulk is packed into the pelvic cavity.
Omental envelope is created by draping the omentum over the small bowel and suturing the lateral edges to the peritoneum in the paracolic gutters. The lower edge is sutured to the posterior abdominal wall at the level of the sacral promontory.
An omental pedicle based on the left gastroepiploic vessels is sutured circumferentially to the parietal peritoneum at the level of the sacral promontory and umbilicus. This creates a sling, or hammock, which contains the bowel and prevents it from entering the pelvis.
An absorbable mesh sling is created by suturing a Vicryl or Dexon mesh to the sacral promontory, lateral abdominal wall, and anterior abdominal wall at the level of the umbilicus. Within this mesh sling, the small bowel loops are contained and held out of the pelvic cavity.
Pelvic-space–occupying device.

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Table 1. Scoring System for Organ-Specific Radiation-Related Morbidity

	Grade 0	Grade 1	Grade 2	Grade 3	Grade 4	Grade 5
Signs and symptoms	None	Mild diarrhea, mild cramping, bowel movements 5 times per day, slight rectal discharge or bleeding	Moderate diarrhea and colic, bowel movements >5 times per day, excessive rectal mucus or intermittent bleeding	Obstruction or bleeding requiring surgery	Necrosis, perforation, fistula	Death directly related to late effects of radiation

Table 2. Surgical Procedures to Prevent Radiation Enteritis

Native Tissue		Prosthetic Materials
Reperitonealization procedures	Omentum-based procedures	Prosthetic Materials
Peritoneum and posterior rectus sheath	Omental transposition flap	Synthetic pelvic mold (spacer)
Uterine broad ligaments	Omentopexy - Omental apron or envelope	Saline-filled tissue expanders
Bladder	Omental hammock or sling	Absorbable mesh sling

Table 3. Surgical Procedures to Treat Complications of Radiation Enteritis

Obstruction	Fistula	Perforation	Hemorrhage
Resection and anastomosis	Resection and anastomosis	Resection and anastomosis	Resection and anastomosis
Bypass of multiple/long strictures	Bypass of fistula area
Strictureplasty	Diversion with proximal ostomy
Diversion with proximal ostomy

Table 4. Surgical Treatment of Radiation Proctitis Complications

Hemorrhagic Proctitis	Rectovaginal Fistulas and Strictures
Hemorrhagic Proctitis	Transabdominal procedures	Perineal procedures
Proctectomy with coloanal anastomosis	Proctectomy with coloanal anastomosis	Transanal flap
Proctectomy with end colostomy	Proctectomy with end colostomy	Transvaginal flap
	Colonic J-pouch-anal anastomosis
	Ileocecal reservoir
	Sigmoid colon onlay patch (Bricker-Johnston)

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Radiation Enteritis and Proctitis

Practice Essentials

Pathophysiology

Etiology

Epidemiology

Prognosis

References

Tables

Contributor Information and Disclosures

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