Abstract
Background
Persistent descending mesocolon (PDM) is caused by the absence of fusion of the descending colon to the retroperitoneum. We herein report two colorectal cancer cases with PDM that were treated with laparoscopic surgery.
Case presentation
Case 1: a 50-year-old man with sigmoid colon cancer and synchronous liver metastasis. After neoadjuvant chemotherapy, he underwent laparoscopic sigmoidectomy with lymph node dissection cutting the root of the inferior mesenteric artery (IMA) and synchronous liver resection. He experienced postoperative stenosis of the reconstructed colon possibly due to an impaired arterial blood flow in the reconstructed colon.
Case 2: a 77-year-old man with rectal cancer. Laparoscopic low anterior resection preserving the left colic artery (LCA) was performed. Intraoperative infrared ray (IR) imaging using indocyanine green (ICG) showed good blood flow of the reconstructed colon. He had no postoperative complications. In cases of PDM, the mesentery of the descending and sigmoid colon containing the LCA is often shortened, and the marginal artery of the reconstructed colon is located close to the root of the LCA. Lymph node dissection accompanied by cutting the LCA carries a risk of marginal artery injury. Therefore, we recommend lymph node dissection preserving the LCA in colorectal cancer patients with PDM in order to maintain the blood flow of the reconstructed colon. If the IMA and LCA absolutely need to be cut for complete lymph node dissection, the marginal artery should be clearly identified and preserved. In addition, intraoperative IR imaging is extremely useful for evaluating colonic perfusion and reducing the risk of anastomotic complications.
Conclusion
In colorectal cancer surgery in patients with PDM, surgeons should be aware of these tips for maintaining the blood flow of the reconstructed colon and thereby avoid postoperative complications caused by an impaired blood flow.
Similar content being viewed by others
Background
The descending mesocolon normally is fused to the posterior and lateral parietal peritoneum by the end of the fifth month of gestation [1]. Persistent descending mesocolon (PDM) is a developmental anomaly characterized by the colonic mesentery’s failure to fuse with the dorsal abdominal wall [1]. In patients with PDM, the descending colon may be shifted to a more medial position than usual, and the sigmoid colon is located at the right side of the abdomen; therefore, PDM is sometimes called “right-sided sigmoid colon” [2, 3]. Although some clinical complications of PDM, such as primary intestinal obstruction, colonic volvulus, and intussusception, have been reported [4,5,6], this condition is asymptomatic in most cases. In addition, in certain cases undergoing colon cancer surgery, characteristic anomalies, including adhesion between the mesentery and pelvic wall and a short descending mesentery, as well as the importance of careful surgical procedures have been described [7, 8].
We herein report two patients with PDM who underwent laparoscopic surgery for colorectal cancer. The first case experienced postoperative stenosis of colonic anastomosis and it seemed to be caused by impaired blood flow of the reconstructed colon. Therefore, in the second case, we tried to maintain a good blood flow of the reconstructed colon to avoid anastomotic complications.
Case presentation
Case 1
A 50-year-old man presented with a 2-month history of melena. Colonoscopy and computed tomography (CT) showed sigmoid colon cancer and synchronous liver metastasis. CT-colonography showed PDM and a primary tumor at the distal side of the sigmoid colon (Fig. 1a). After systemic chemotherapy (Panitumumab and FOLFOX), he underwent laparoscopic sigmoidectomy with the double-stapling technique (DST) anastomosis and synchronous liver resection. The sigmoid colon located at the right side of the abdomen adhered to the abdominal wall, and the adhesion was dissected laparoscopically. In this case, the root of the inferior mesenteric artery (IMA) was cut for lymph node dissection (Fig. 1b). The left colonic artery (LCA) and inferior mesenteric vein (IMV) next to the IMA were then also cut. The operation time was 835 min and the volume of bleeding was 285 ml. Two months after surgery, the patient developed abdominal distension and pain. Colonoscopy showed stenosis of the reconstructed colon (Fig. 1c), and CT showed colonic dilatation caused by stenosis at the oral side of the anastomosis (Fig. 1d–f). No findings of local recurrence were seen. The clip on the LCA was located close to the marginal artery (Fig. 1e), and contrast enhancement at the distal side of the reconstructed colon was weak. Therefore, the main cause of the stenosis seemed to be an impaired arterial blood flow of the reconstructed colon. Although the patient was admitted to our hospital and fasted, his complaint and colonic dilatation prolonged. Because he had obstructive colitis caused by severe colonic stenosis, he underwent colostomy at the transverse colon to improve the colonic dilatation 4 months after colectomy. One year after primary surgery, he experienced recurrence in his liver. He underwent second liver resection and has been treated with systemic chemotherapy, and is still alive for 24 months after primary surgery.
Case 2
A 77-year-old man who had difficulty defecating was diagnosed with rectal cancer by colonoscopy. CT-colonography showed PDM and a primary tumor at the middle rectum (Fig. 2a). Preoperative CT-angiography showed that the LCA branched from the IMA (Fig. 2b). He underwent laparoscopic low anterior resection with D3 lymph node dissection and the DST anastomosis preserving pelvic autonomic nerves. The sigmoid colon located at the right side of the abdomen adhered to the abdominal wall. In addition, the mesocolon and the mesentery of the ileum were adhered. These adhesions were dissected initially. In laparoscopic low anterior resection, the superior rectal artery (SRA) was cut while preserving the LCA (Fig. 2c). Intraoperative infrared ray (IR) imaging using indocyanine green (ICG) performed prior to the DST anastomosis showed good blood flow of the reconstructed colon (Fig. 2d). The anastomosis was located at 5 cm from the anal verge. The operation time was 333 min and the volume of bleeding was 10 ml. The preserved LCA was identified on postoperative CT-angiography (Fig. 2e). He had no postoperative complications. Pathological examination showed pT3N2bM0 pStage IIIC (TNM classification eighth edition) with a negative resection margin. He experienced an early recurrence in his liver and lung 1 month after surgery and has been treated with oxaliplatin-based systemic chemotherapy without any anastomotic complication. He is still alive for 13 months after surgery.
Discussion and conclusions
To our knowledge, there are few reports regarding laparoscopic surgery for colorectal cancer in patients with PDM [7, 8]. In this report, we described two cases of PDM treated with laparoscopic surgery for colorectal cancer. Case 1 experienced postoperative colonic stenosis near the anastomosis mainly due to an impaired arterial blood flow of the reconstructed colon. Ischemia at the anastomosis had been described as a possible risk factor of anastomotic stenosis [9]. In contrast, case 2 had no postoperative complications thanks to the following efforts to maintain a good blood flow of the reconstructed colon: (1) the evaluation of the colonic arterial supply by preoperative computed tomography-angiography, (2) confirmation of complete adhesiolysis and mobilization of sigmoid colon, (3) making the appropriate arterial cut in lymph node dissection, and (4) performing intraoperative IR imaging using ICG.
In cases of PDM, the sigmoid colon and mesocolon often adhere to the abdominal cavity [2, 3, 7, 8] and such adhesion was seen in both cases we presented. In addition, compared with the normal sigmoid colon (Fig. 3a), the descending colon is located toward the medial side and the sigmoid colon is located at the right side of the abdomen (Fig. 3b). After completing adhesiolysis and mobilizing the sigmoid colon to the normal position, the mesocolon containing the LCA consequently becomes shortened (Fig. 3c) as previously reported [2]. Importantly, the fact that the descending colon artery, sigmoid colon artery, and superior rectal artery often branch radially from the IMA should have been noted during the operation [7]. Therefore, if the IMA and LCA are cut for lymph node dissection (Fig. 3c, blue dotted line), there is a risk of injuring the marginal artery. However, cutting the SRA while preserving the LCA (Fig. 3c, blue line) can avoid such potential injury. In case 1, the marginal artery of the reconstructed colon might have been injured, as the clip on the LCA was located close to the marginal artery (Fig. 1e). Therefore, we recommend lymph node dissection preserving the LCA in colorectal cancer surgery in patients with PDM. If the IMA and LCA absolutely need to be cut for complete lymph node dissection, the marginal artery should be clearly identified and preserved after complete adhesiolysis and mobilization of the descending colon and the sigmoid colon to the normal position.
Recent reports have shown that IR imaging is extremely useful for evaluating colonic perfusion and reducing the risk of anastomotic complications [10, 11]. We ensured a good arterial blood flow of the reconstructed colon using intraoperative IR imaging and believe that this technique is extremely useful. If the blood flow of the reconstructed colon is poor, additional resection of the colon may be needed. In the present case 2, the LCA was preserved in order to avoid injuring the marginal artery, and intraoperative IR imaging was performed in order to confirm the arterial blood flow, just in case. However, we believe that the evaluation of the blood flow is useful, especially in cases of PDM with the root of the IMA cut off for lymph node dissection.
We described the tips and pitfalls associated with colorectal cancer surgery in patients with PDM. Particularly when treating patients with descending colon cancer, sigmoid colon cancer, and rectal cancer, surgeons should recognize these tips for ensuring good blood flow to the reconstructed colon and thereby avoid postoperative complications caused by an impaired blood flow.
Availability of data and materials
Not applicable
References
Popky GL, Lapayowker MS. Persistent descending mesocolon. Radiology. 1966;86:327–31.
Shrivastava P, Tuli A, Kaur S, Raheja S. Right sided descending and sigmoid colon: its embryological basis and clinical implications. Anat Cell Biol. 2013;46:299–302.
Bhadoria P, Bahksh S, Agarwal S, Pangtey B, Kakar S. Right sided sigmoid colon and redundant loop of descending colon with its embryological correlation and clinical significance. J Clin Diagn Res. 2016;10:Ad05–7.
Ogihara M, Kawamura YJ, Minami M, Watanabe T, Sunami E, Matsuda K, Masaki T, Muto T. Primary intestinal obstruction complicated by persistent descending mesocolon. Int Surg. 2000;85:226–30.
Chen A, Yang FS, Shih SL, Sheu CY. Case report. CT diagnosis of volvulus of the descending colon with persistent mesocolon. AJR Am J Roentgenol. 2003;180:1003–6.
Ongom PA, Lukande RL, Jombwe J. Anal protrusion of an ileo-colic intussusception in an adult with persistent ascending and descending mesocolons: a case report. BMC Res Notes. 2013;6:42.
Tsuruta A, Kawai A, Oka Y, Okumura H, Matsumoto H, Hirai T, Nakamura M. Laparoscopic right hemicolectomy for ascending colon cancer with persistent mesocolon. World J Gastroenterol. 2014;20:5557–60.
Hisano K, Ueki T, Kono H, Ikenaga N, Maeyama R, Konomi H, Okido M, Yamashita N, Motoshita J, Ichimiya H. Laparoscopic high anterior resection for triple colorectal cancers with persistent ascending and descending mesocolons: a case report. Asian J Endosc Surg. 2019;12:329–333.
Polese L, Vecchiato M, Frigo AC, Sarzo G, Cadrobbi R, Rizzato R, Bressan A, Merigliano S. Risk factors for colorectal anastomotic stenoses and their impact on quality of life: what are the lessons to learn? Colorectal Dis. 2012;14:e124–8.
Wada T, Kawada K, Takahashi R, Yoshitomi M, Hida K, Hasegawa S, Sakai Y. ICG fluorescence imaging for quantitative evaluation of colonic perfusion in laparoscopic colorectal surgery. Surg Endosc. 2017;31:4184–93.
Watanabe J, Ishibe A, Suwa Y, Suwa H, Ota M, Kunisaki C, Endo I. Indocyanine green fluorescence imaging to reduce the risk of anastomotic leakage in laparoscopic low anterior resection for rectal cancer: a propensity score-matched cohort study. Surg Endosc. 2019. https://doi.org/10.1007/s00464-019-06751-9.
Acknowledgements
Not applicable
Funding
Not applicable
Author information
Authors and Affiliations
Contributions
YH, YM, and HB analyzed and interpreted the patient data and wrote the manuscript. KE, YN, MI, SI, YB, and NY performed critical revision for intellectual content and were contributors in writing the manuscript. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
All of the study participants provided their informed consent, and the study design was approved by the appropriate ethics review boards.
Consent for publication
All of the study participants provided their informed consent.
Competing interests
Not applicable
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
About this article
Cite this article
Hiyoshi, Y., Miyamoto, Y., Eto, K. et al. Laparoscopic surgery for colorectal cancer with persistent descending mesocolon. World J Surg Onc 17, 190 (2019). https://doi.org/10.1186/s12957-019-1734-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12957-019-1734-1