Establishment of Novel Premature Piglet Models for Short Bowel Syndrome_CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Authors：

 DONGJing-qing ¹ , DONGQi ² , LIUMao-ling ³

1. Department of General Surgery, Nanfang Hospital of Southern Medical University, Guangzhou 510515, Guangdong Province, China;
2. Department of Pediatric Surgery, Hainan Provincial People's Hospital, Haikou 570311, Hainan Province, China;
3. School of Public Health, Guangdong Pharmaceutical University, Guangzhou 510310, Guangdong Province, China;

Corresponding author：

DONGJing-qing, Email: djq652000@126.com

Keywords：

Short bowel syndrome; Premature piglet; Large white piglet; Intestinal adaptation

DOI：

10.7507/1007-9424.20150276

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Objective To explore a new method for establishing premature piglet model of short bowel syndrome. Methods Thirty two premature piglets were randomly divided into 4 groups, including jejunoileal anastomosis group, jejunocolic anastomosis group, sham operation group, and blank control group. Each group enrolled 8 premature piglets. Jejunoileal anastomosis group:resected 75% of small intestinal, reserved the proximal jejunum (10% of the total small intestine length) and distal ileum (15% of the total small intestine length), with jejunoileal anastomosis. Jejunocolic anastomosis group:removed 75% of the small intestine, including the distal jejunum (25% of the total small intestine length), total ileum (50% of total small intestine length), the ileocecal valve, and the colon beyond 5 cm far from the ileocecal valve, retained the proximal jejunum (25% of the total length of the small intestine), with jejunocolic anastomosis. Sham group:cut off the ileum at a distance of nearly 25 cm of the ileocecal valve ileum, then anastomosed the intestine again. Blank control group:no surgery. Data included the first defecation time, duration of diarrhea and parenteral nutrition (PN) after surgery, the length and weight of the small intestine, the weight of the colon, the villus height and crypt depth of both jejunum and ileum at 21st days postoperatively, were collected and analysed. Results Compared with the sham group and blank control group, jejunoileal and jejunocolic anastomosis groups showed higher villus height and the crypt depth of jejunum and ileum (P<0.050), provided enough anatomy evidence of intestinal adaptation. However, the duration of PN in jejunocolic group was longer than in jejunoilea anastomosis group (P<0.050). The length and weight of the small intestine and the weight of colon in jejunocolic anastomosis group, were lower than in jejunoileal anastomosis group (P<0.050), improving that the ability of intestinal adaptation of jejunocolic anastomosis was better than the jejunoileal anastomosis group. Conclusions Premature piglet models of short bowel syndrome could be established by methods of jejunoileal and jejunocolic anastomosis. Both of the methods had their own different degree of intestinal adaptation and growth. The jejunoileal anastomosis is maybe a better way to establish this model.

Citation： DONGJing-qing, DONGQi, LIUMao-ling. Establishment of Novel Premature Piglet Models for Short Bowel Syndrome. CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY, 2015, 22(9): 1052-1056. doi: 10.7507/1007-9424.20150276 Copy

1.	Wales PW, de Silva N, Kim JH, et al. Neonatal short bowel synd-rome:a cohort study. J Pediatr Surg, 2005, 40(5):755-762.
2.	Andorsky DJ, Lund DP, Lillehei CW, et al. Nutritional and other postoperative management of neonates with short bowel syndrome correlates with clinical outcomes. J Pediatr, 2001, 139(1):27-33.
3.	Bueno J, Ohwada S, Kocoshis S, et al. Factors impacting the survival of children with intestinal failure referred for intestinal transplantation. J Pediatr Surg, 1999, 34(1):27-32.
4.	Kato T, Mittal N, Nishida S, et al. The role of intestinal transplan-tation in the management of babies with extensive gut resections. J Pediatr Surg, 2003, 38(2):145-149.
5.	Wales PW, de Silva N, Kim J, et al. Neonatal short bowel syndrome:population-based estimates of incidence and mortality rates. J Pediatr Surg, 2004, 39(5):690-695.
6.	Warner BW, Ziegler MM. Management of the short bowel syndrome in the pediatric population. Pediatr Clin North Am, 1993, 40(6):1335-1350.
7.	O'brien DP, Nelson LA, Huang FS, et al. Intestinal adaptation:structure, function, and regulation. Semin Pediatr Surg, 2001, 10(2):56-64.
8.	Helmrath MA, Erwin CR, Shin CE, et al. Enterocyte apoptosis is increased following small bowel resection. J Gastrointest Surg, 1998, 2(1):44-49.
9.	Shyntum Y, Iyer SS, Tian J, et al. Dietary sulfur amino acid supple-mentation reduces small bowel thiol/disulfide redox state and stimulates ileal mucosal growth after massive small bowel resection in rats. J Nutr, 2009, 139(12):2272-2278.
10.	蒋小华,李宁,朱维铭,等. 精氨酸促进短肠综合征肠道代偿及其机制的初步研究. 中华胃肠外科杂志,2009,12(5):522-525.
11.	Sukhotnik I, Coran AG, Mogilner JG, et al. Leptin affects intestinal epithelial cell turnover in correlation with leptin receptor expression along the villus-crypt axis after massive small bowel resection in a rat. Pediatr Res, 2009, 66(6):648-653.
12.	Michopoulou A, Triggas B, Hra E, et al. Early intestinal morpholo-gical changes following benzalkonium chloride treatment in a rat model of short bowel syndrome. Ann Ital Chir, 2009, 80(2):135-139.
13.	Koopmann MC, Liu X, Boehler CJ, et al. Colonic GLP-2 is not sufficient to promote jejunal adaptation in a PN-dependent rat model of human short bowel syndrome. JPEN J Parenter Enteral Nutr, 2009, 33(6):629-638.
14.	Tian J, Hao L, Chandra P, et al. Dietary glutamine and oral antibiotics each improve indexes of gut barrier function in rat short bowel syndrome. Am J Physiol Gastrointest Liver Physiol, 2009, 296(2):G348-G355.
15.	Moughan PJ, Birtles MJ, Cranwell PD, et al. The piglet as a model animal for studying aspects of digestion and absorption in milk-fed human infants. World Rev Nutr Diet, 1992, 67:40-113.
16.	Miller ER, Ullrey DE. The pig as a model for human nutrition. Annu Rev Nutr, 1987, 7:361-382.
17.	Darragh AJ, Moughan PJ. The three-week-old piglet as a model animal for studying protein digestion in human infants. J Pediatr Gastroenterol Nutr, 1995, 21(4):387-393.
18.	Healey KL, Bines JE, Thomas SL, et al. Morphological and functional changes in the colon after massive small bowel resection. J Pediatr Surg, 2010, 45(8):1581-1590.
19.	王晓宁, 孙波, 郭春宝, 等. 早产猪呼吸窘迫综合征模型的建立与治疗. 中华围产医学杂志, 2005, 8(5):334-337.
20.	Turner JM, Wales PW, Nation PN, et al. Novel neonatal piglet models of surgical short bowel syndrome with intestinal failure. J Pediatr Gastroenterol Nutr, 2011, 52(1):9-16.

1. Wales PW, de Silva N, Kim JH, et al. Neonatal short bowel synd-rome:a cohort study. J Pediatr Surg, 2005, 40(5):755-762.
2. Andorsky DJ, Lund DP, Lillehei CW, et al. Nutritional and other postoperative management of neonates with short bowel syndrome correlates with clinical outcomes. J Pediatr, 2001, 139(1):27-33.
3. Bueno J, Ohwada S, Kocoshis S, et al. Factors impacting the survival of children with intestinal failure referred for intestinal transplantation. J Pediatr Surg, 1999, 34(1):27-32.
4. Kato T, Mittal N, Nishida S, et al. The role of intestinal transplan-tation in the management of babies with extensive gut resections. J Pediatr Surg, 2003, 38(2):145-149.
5. Wales PW, de Silva N, Kim J, et al. Neonatal short bowel syndrome:population-based estimates of incidence and mortality rates. J Pediatr Surg, 2004, 39(5):690-695.
6. Warner BW, Ziegler MM. Management of the short bowel syndrome in the pediatric population. Pediatr Clin North Am, 1993, 40(6):1335-1350.
7. O'brien DP, Nelson LA, Huang FS, et al. Intestinal adaptation:structure, function, and regulation. Semin Pediatr Surg, 2001, 10(2):56-64.
8. Helmrath MA, Erwin CR, Shin CE, et al. Enterocyte apoptosis is increased following small bowel resection. J Gastrointest Surg, 1998, 2(1):44-49.
9. Shyntum Y, Iyer SS, Tian J, et al. Dietary sulfur amino acid supple-mentation reduces small bowel thiol/disulfide redox state and stimulates ileal mucosal growth after massive small bowel resection in rats. J Nutr, 2009, 139(12):2272-2278.
10. 蒋小华,李宁,朱维铭,等. 精氨酸促进短肠综合征肠道代偿及其机制的初步研究. 中华胃肠外科杂志,2009,12(5):522-525.
11. Sukhotnik I, Coran AG, Mogilner JG, et al. Leptin affects intestinal epithelial cell turnover in correlation with leptin receptor expression along the villus-crypt axis after massive small bowel resection in a rat. Pediatr Res, 2009, 66(6):648-653.
12. Michopoulou A, Triggas B, Hra E, et al. Early intestinal morpholo-gical changes following benzalkonium chloride treatment in a rat model of short bowel syndrome. Ann Ital Chir, 2009, 80(2):135-139.
13. Koopmann MC, Liu X, Boehler CJ, et al. Colonic GLP-2 is not sufficient to promote jejunal adaptation in a PN-dependent rat model of human short bowel syndrome. JPEN J Parenter Enteral Nutr, 2009, 33(6):629-638.
14. Tian J, Hao L, Chandra P, et al. Dietary glutamine and oral antibiotics each improve indexes of gut barrier function in rat short bowel syndrome. Am J Physiol Gastrointest Liver Physiol, 2009, 296(2):G348-G355.
15. Moughan PJ, Birtles MJ, Cranwell PD, et al. The piglet as a model animal for studying aspects of digestion and absorption in milk-fed human infants. World Rev Nutr Diet, 1992, 67:40-113.
16. Miller ER, Ullrey DE. The pig as a model for human nutrition. Annu Rev Nutr, 1987, 7:361-382.
17. Darragh AJ, Moughan PJ. The three-week-old piglet as a model animal for studying protein digestion in human infants. J Pediatr Gastroenterol Nutr, 1995, 21(4):387-393.
18. Healey KL, Bines JE, Thomas SL, et al. Morphological and functional changes in the colon after massive small bowel resection. J Pediatr Surg, 2010, 45(8):1581-1590.
19. 王晓宁, 孙波, 郭春宝, 等. 早产猪呼吸窘迫综合征模型的建立与治疗. 中华围产医学杂志, 2005, 8(5):334-337.
20. Turner JM, Wales PW, Nation PN, et al. Novel neonatal piglet models of surgical short bowel syndrome with intestinal failure. J Pediatr Gastroenterol Nutr, 2011, 52(1):9-16.

CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Establishment of Novel Premature Piglet Models for Short Bowel Syndrome

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