Intestinal obstructions are a partial or complete blockage of the intestine that can cause severe abdominal pain, nausea, vomiting, and preventing the passage of stool. This procedure for creating intestinal partial obsructions in mice is reliable in studying the mechanisms underlying pathological cell growth and death in the intestine.
Intestinal obstructions, that impede or block peristaltic movement, can be caused by abdominal adhesions and most gastrointestinal (GI) diseases including tumorous growths. However, the cellular remodeling mechanisms involved in, and caused by, intestinal obstructions are poorly understood. Several animal models of intestinal obstructions have been developed, but the mouse model is the most cost/time effective. The mouse model uses the surgical implantation of an intestinal partial obstruction (PO) that has a high mortality rate if it is not performed correctly. In addition, mice receiving PO surgery fail to develop hypertrophy if an appropriate blockade is not used or not properly placed. Here, we describe a detailed protocol for PO surgery which produces reliable and reproducible intestinal obstructions with a very low mortality rate. This protocol utilizes a surgically placed silicone ring that surrounds the ileum which partially blocks digestive movement in the small intestine. The partial blockage makes the intestine become dilated due to the halt of digestive movement. The dilation of the intestine induces smooth muscle hypertrophy on the oral side of the ring that progressively develops over 2 weeks until it causes death. The surgical PO mouse model offers an in vivo model of hypertrophic intestinal tissue useful for studying pathological changes of intestinal cells including smooth muscle cells (SMC), interstitial cells of Cajal (ICC), PDGFRα+, and neuronal cells during the development of intestinal obstruction.
Intestinal obstructions are a partial or complete blockage in the small or large intestine which prevents digested food, fluids, and gas from moving through the intestines1. Due to the obstruction, the blockage induces the intestinal walls to become thickened, narrowing the lumen2. Intestinal obstruction can occur as a result of abdominal or pelvic surgeries that cause abdominal adhesion tissue formation or from GI disorders such as inflammatory bowel diseases (Crohn's disease), diverticulitis, hernias, volvulus, stricture, intussusception, constipation, fecal impaction, pseudo-obstruction, cancers and tumors3,4,5. Intestinal obstructions in these cases often lead to the hypertrophy of the tunica muscularis of the intestine6.
PO of the lumen induces intestinal distention, and increases smooth muscle layer thickness around the obstruction in response to the need to continue functional peristalsis7,8,9,10,11,12,13. Animal models of intestinal PO have been developed to study smooth muscle hypertrophy in mice7, rats10, guinea pigs11, dogs12, and cats13 that consistently develop similar hypertrophy within the intestinal muscle layers.
A mouse model of intestinal PO is the most cost effective way to generate and study intestinal obstructions in vivo. Small intestine obstructions are carried out in mice by using a silicone ring surgically placed surrounding the ileum. The PO mice showed an early increase in the number of cells (hyperplasia), and an increase in muscle layer thickness (hypertrophy) after PO surgery8,15. SMC are the primary plastic cells that are growing within smooth muscle layers in response to the hypertrophic conditions14, but other cells such as ICC and PDGFRα+ cells that are closely associated with SMC, are also repopulated. We have previously reported that the PO mice develop hypertrophy in the small intestine, in which SMC are dedifferentiated into PDGFRα+ cells that are highly proliferative7,15,16. Conversely, ICC are degenerated and lost within the hypertrophied smooth muscle layers during the development of intestinal obsruction7. Another major benefit of the PO model is its capacity to induce changes in the enteric nervous system and propagating neurogenic motor patterns. The major propagating neurogenic motor pattern in the mouse small bowel is the migrating motor complex (MMC), which is neurogenic and does not require ICC or electrical slow waves17. The PO model can provide clear insights into how MMCs and enteric nerves are remodeled by partial obstruction.
Here, we propose a murine protocol for intestinal PO surgery using a silicone ring. Mice receiving PO surgery reliably produce hypertrophy in the tunica muscularis of the small intestine. Within hypertrophic muscle, SMC, ICC, PDGFRα+, and neuronal cells are dramatically remodeled.
The following protocol has been approved by the Institutional Animal Care and Use Committee (IACUC) at the University of Nevada-Reno (UNR) Animal Resources and complies with all institutional ethical guidelines regarding the use of research animals.
1. Animals.
2. Partial Obstruction Surgery
NOTE: Surgeries are performed in a room dedicated to surgical procedures. All surgical instruments are autoclaved prior to surgery. Sterile surgical gowns and gloves should be worn by all personnel in the surgical room at all times.
3. Post-operation observation.
Partial obstruction (PO) was surgically induced in one month old mice by placing a silicone ring around the ileum close to the ileocecal sphincter. This ring created a partial blockage in the ileum. Sham operations (SO) were also performed without a ring on age/sex matched mice and these mice did not show any symptoms similar to those found in PO mice. Mice quickly recovered from PO surgery within a few hours. They showed no obvious behavioral changes or weakness within the first week, but after the first week, they progressively began to show signs of PO: a distended abdomen and the production of fewer and smaller fecal pellets. PO mice were sacrificed at 8 and 13 days post-PO surgery along with SO control mice. The small intestine was partially filled and distended at 8 days post-PO surgery and fully filled and distended at 13 days post-PO surgery, compared to SO control mice (Figure 1A). Fecal pellet formation in the colon of 8 and 13 days post-PO surgery mice was reduced in comparison to SO control mice (Figure 1B). Ileal tissue that was just upstream of the ring was dissected and the smooth muscle was analyzed by hematoxylin & eosin (H&E) staining. The smooth muscle layer was hypertrophied at 8 days post-PO surgery and much further hypertrophied at 13 days post-PO surgery (Figure 2). We also observed changes in SMC, ICC, PDGFRα+, and neuronal cells within the tunica muscularis in PO mice through the use of immunochemistry. Each cell was labeled with cell-type specific markers: MYH11 (SMC), KIT (ICC), PDGFRA (PDGFRα+ cells), and PGP9.5 (neuronal cells). SMC are found within three layers of tissue: longitudinal muscle (LM), circular muscle (CM), and the muscularis mucosae (MM) in the ileum. SMC were progressively growing at rapid rates in all three layers at 8 and 13 days post-PO surgery (Figure 3). As for ICCs, their subpopulations are located in the deep muscular plexus (DMP), myenteric region (MY), and subserosal region (SS). However, ICC-DMP, ICC-MY, and ICC-SS were degenerated within the intra/intermuscular layers (Figure 3). Similar to ICC subpopulations, subpopulations of PDGFRα+ cells (PαC) are located in the DMP, MY, and SS. In PO mice, PαC-DMP, PαC-MY, and PαC-SS were dynamically remodeled within the intermuscular layers of PO mice: they were growing at 8 days post-PO surgery and degenerated at 13 days post-PO surgery (Figure 3). Finally, myenteric plexus (MP), submucosal plexus (SP), subserosal neurons (SS), and enteric motor neurons (EMN) were significantly lost in the inter/intramuscular regions of PO mice at 8 and 13 days post-PO surgery (Figure 3).
Figure 1. Intestinal partial obstruction surgically induced in a mouse model. PO was induced by PO surgery. One month old mice were anesthetized, their abdomen was opened by an incision, a silicone ring was placed surrounding the ileum, and the opening was closed by suturing. Mice that underwent surgery were allowed to recover for either 8 or 13 days. Age and sex matched SO mice were operated on in the same manner as PO mice except there was no placement of a ring. (A) Gross images of the GI tract in mice that underwent PO or SO surgery. Images are of mice at 8 and 13 days post-surgery (B) GI tract dissected from mice in A. Small intestine upstream of the ring was distended at both 8 and 13 days post-PO surgery and fecal pellets in the colon were also smaller at both 8 and 13 day post-PO surgery as compared to 13 days post-SO surgery mice due to the partially obstructive silicone ring. Scale bars are 0.5 cm. Please click here to view a larger version of this figure.
Figure 2. Smooth muscle layer changed in the surgical mouse model. Representative H&E staining of ileal cross sections from intestinal PO, SO and no operation (NO) mice. Smooth muscle (SM) and mucosa (Mu) layers are thicker in PO mice at 8 and 13 days post-PO surgery than those in SO and NO mice. Scale bars are 50 µm. Please click here to view a larger version of this figure.
Figure 3. Dynamic cellular remodeling in smooth muscle hypertrophy induced by intestinal partial obstruction. Representative confocal laser scanning images of hypertrophic ileal cross sections, from PO, SO and NO mice. Immunohistochemically staining with antibodies (red) of MYH11 (SMC), KIT (ICC), PDGFRA (PDGFRα+ cells) or PGP9.5 (NC; neuronal cells), co-stained with DAPI (blue). SMC in mucosa muscularis (MM), circular muscle (CM), and longitudinal muscle (LM) layers, as well as PDGFRα+ cells in deep muscular plexus (DMP), myenteric region (MY), and subserosal region (SS) were growing in hypertrophic ileum at 8 and 13 days post-PO surgery while ICC in DMP, MY, and SS, myenteric plexus (MP), submucosal plexus (SP), subserosal NC (SS), and enteric motor neurons (EMN) were degenerated. Scale bars are 50 µm. Please click here to view a larger version of this figure.
Figure 4. Results of silicone rings that are too large, too small or misplaced on the colon. (A) No smooth muscle hypertrophy develops in the ileum if the ring is too large to cause obstruction. The ring made little to no blockage of the ileum. (B) Intestinal ischemia develops in the ileum if the ring is too small. The ring made an almost complete blockage of the ileum, which can damage the tissue and lead to early death before hypertrophy develops. (C) Smooth muscle hypertrophy developed in the colon due to a misplaced ring. The ring on the colon was moved down by lumenal content (feces), which damaged mesentery vasculature and caused massive hemorrhaging in the colon. Please click here to view a larger version of this figure.
We demonstrated that mice receiving the intestinal PO surgery consistently and reproducibly develop intestinal smooth muscle hypertrophy, which mimics human intestinal obstruction. Intestinal obstruction surgeries have been developed for different animals including mice7, rats10, guinea pigs11, dog12 and cats13. The mouse model of intestinal obstruction has time, cost, size, and phenotypic advantages over other larger animal models. The development of hypertrophy in mice or rats takes only 10-14 days10, compared to 2-4 weeks in guinea pigs, dogs and cats11,12,13. Cost for purchasing and maintaining mice is also a tremendous financial advantage when compared to other models. Additionally, mice are small and easy to handle for the PO surgery. Most importantly, mice receiving PO surgery progressively and extensively develop hypertrophy in the small intestine while other larger animals develop less extensive growth.
There are several key factors to consider when attempting to produce reliable hypertrophy through intestinal PO surgery. Several research groups have used rings of various sizes and placed a ring at various locations along the intestine to create partial obstructions7,9,10,11,12,13,14. However, a silicone ring of optimal size should be used for mice as a larger ring creates little or no blockage in the ileum where hypertrophy only partially, or never, developed (Figure 4A). Conversely, when a ring was too small, it created near complete blockage of the ileum which induced intestinal ischemia and/or damaged the mucosa causing sepsis, leading to early death within a week (Figure 4B). We used a silicone ring of a specific size (6 mm in length, 4 mm exterior diameter, 3.5 mm interior diameter) on one month old mice (Table of Materials). Different sizes of the rings should be tested and used for mice of different sizes in order to create the optimal blockage in the ileum. Another key factor is the location of the ring on the intestine. The ileum, close to ileocecal valve, is the best place to place the ring in order to robustly produce partial obstructions. Other regions, such as the jejunum or different regions of the ileum away from ileocecal valve, have had a similar ring placed on them in order to induce hypertrophy7. However, due to the serosal surface of the intestine being highly lubricated by peritoneal fluid, a ring placed on these parts of the intestine easily moves because of the contractile force of intestine pushing fecal material through. As the ring is pushed down the length of the intestine, it cuts off mesenteric arteries innervated into the myenteric region of intestine, causing hemorrhaging. When a ring is inserted at the end of ileum next to ileocecal valve, it is physically prevented from moving further by the bulky nature of the cecum. The cecum can be easily located and taken out of the abdomen in the surgery in order to locate the ileocecal valve region as the cecum connects to both the ileum and proximal colon. The ileum and colon connected at the cecum look quite similar and a ring can accidentally be placed on the proximal colon instead of the ileum. When a ring was misplaced on the proximal colon, as also seen on the jejunum, the ring was pushed downward and damaged mesenteric arteries, causing extensive hemorrhaging (Figure 4C). To avoid this misplacement, the ileum should always be properly located and identified before the ring is put into place. The ileum runs into the middle of cecum while the colon runs into one side of the cecum pouch.
This PO surgery protocol is considered as a major surgery for mice. All surgical instruments and materials should be sterilized before use, and surgery should be performed in the clean environment of a dedicated surgery room in order to minimize contamination, which can lead to infection and inflammation in mice. In addition, a pain medication should be provided to mice after surgery. We chose to use a slow release version of buprenorphine, which is efficacious up to 7-8 h22. Furthermore, after surgery, mice have difficulty chewing and swallowing solid food. For up to 5 days post-surgery, the mice should be provided with softened food (solid diet with a bit of water added to soften food) and switched to normal solid diet after 5 days.
Our intestinal PO surgery provides an in vivo hypertrophy model for intestinal obstruction in which SMC, ICC, and PDGFRα+ cells are abnormally remodeled. This PO model is also ideally suited to understanding how enteric neurons are modified by PO and how the major motor activities are affected in the small and large bowel23. These cells can be dynamically remodeled in pathological conditions as well as under cultured conditions15,16. We observed that these cells in SO mice behaved a bit differently than normal mice without operation (Figure 2 and Figure 3). Most intestinal obstruction in humans occurs by abdominal adhesions developed after surgery, leading to smooth muscle hypertrophy3,4,5,21. After SO surgery, we also found that SMC, ICC, and PDGFRα+ cells were slightly hypertrophic in the small intestine, compared to NO (Figure 3), suggesting that surgery itself can induce intestinal smooth muscle hypertrophy. If this is the case, SO surgery is not a complete negative control for PO surgery. NO as well as SO should be used as a comparison to PO intestine.
In summary, we have found a cost/time effective, reliable, and repeatable PO surgical protocol in mice that robustly generates intestinal obstructions. During the development of the obstruction, SMC, ICC, PDGFRα+, as well as neuronal cells are dynamically remodeled within various tissue layers and locales. This in vivo obstruction model offers new insights into our knowledge of how phenotypic changes occur in obstructed intestine at the cellular level.
The authors have nothing to disclose.
The authors would like to thank Benjamin J Weigler, D.V.M., Ph.D. and Walt Mandeville, D.V.M. (Animal Resources & Campus Attending Veterinarian, University of Nevada, Reno) for their excellent animal services provided to the mice as well as their counsel on surgical procedures.
Surgical drape | Medical and veterinary supplies | SMS40 | 40”X100 yards |
Underpad, econ, pro plus | Medical and veterinary supplies | MSC281224 | 17×24” |
Iris scissors | Braintree scientific, Inc | SC-i-130 | |
Iris scissors | Vantage | V95-304 | |
Dumont electronic & jeweler tweezers | Dumont | 98-180-3 | |
Braided absorbable suture | Covidien polysorb | SL-5687G | 5-0, polyglactin |
Nylon non-absorbable mono filament | AD surgical | S-N618R13 | 6-0, nylon |
Surgical blade | Dynarex | No.15 | |
Needle holder | Jacobson microvascular | 36-1342TC | 8.5 inch |
Scalpel handle | Flinn scientific | AB1049 | |
Microsurgical scissor | WPI | 503305 | |
Petrolatum ophthalmic ointment | Puralube VET | 3.5 g | |
Fluriso (isoflurane) | Vetone | V1 502017 | 250 ml |
Steri-strip reinforced skin closure | 3M | R1547 | |
Surgical gloves | Medline | MSG2270 | |
Ear loop face mask | The safety zone | RS700 | |
Avant gauze non-woven sponges | Caring | PRM25444 | |
Surgical cup | Admiral craft OYC-2 | 725-A42 | 2.5 oz |
Swabstick | ChloraPrep | 260103 | 2% w/v Chlorhexidine Gluconate (CHG) and 70% v/v Isopropyl Alcohol (IPA) |
Cotton tipped applicator | Puritan | 806-WC | |
Buprenorphine | Zoo pharm | BZ8069317 | 1 mg/ml |
Gentamycin sulfate | Vetone | G-6336-04 | 100 mg/ml |
Fast acting gel cream remover | Veet | 8111002 | |
Syringe | AHS | AH01T2516 | 1 ml with needle |
Silicon ring | VWR | 60985-720 | 6 mm in length, 4 mm exterior diameter, 3.5 mm interior diameter |
C57BL/6 mice | The Jackson Laboratory | 4-6 weeks old |