Open-access Evaluation of the application of enemas containing sucralfate in tissue content of neutral and acid mucins in experimental model of diversion colitisI

Abstract

PURPOSE:   To evaluate the effects of sucralfate on tissue content of neutral and acids mucins in rats with diversion colitis.

METHODS:  Thirty-six rats were submitted to a proximal right colostomy and a distal mucous fistula. They were divided into two groups according to sacrifice to be performed two or four weeks after intervention. Each group was divided into three subgroups according daily application of enemas containing saline, sucralfate at 1.0 g/kg/day or 2.0 g/kg/day. Colitis was diagnosed by histological analysis and neutral and acid mucins by Periodic Acid Schiff and Alcian Blue techniques, respectively. The contents of mucins were quantified by computer-assisted image analysis. Student's t paired and ANOVA test were used to compare the contents of both types of mucins among groups, and to verify the variance with time, establishing level of signification of 5% for both (p<0.05).

RESULTS:  Enemas containing sucralfate improves the inflammation and increases the tissue contents of neutral and acid mucins. The content of neutral mucins does not change with the time or concentration of sucralfate used, while acid mucins increases with concentration and time of intervention.

CONCLUSIONS:   Sucralfate enemas improve the inflammatory process and increase the tissue content of neutral and acid mucins in colon without fecal stream.

Colitis; Colostomy; Fatty Acids, Volatile; Mucins; Sucralfate; Image Processing, Computer-Assisted; Rats


Introduction

Glotzer et al. 1 were the first to describe the development of an inflammatory process in the mucosa of colon segments without fecal stream. They called this new form of inflammatory bowel disease (IBD) diversion colitis (DC). Subsequently, it has been demonstrated that the etiopathogenesis of DC is related to intraluminal deficiency of short-chain fatty acids (SCFAs), the main energy substrate for the cells of the colon epithelium2. The most common histological finds in patients with DC include epithelial erosions or ulcerations, decreased length or modified architecture of the colonic glands, inflammatory infiltrate and, depletion of the number of goblet cells, with consequent modifications on tissue content of mucins2 -4These histological alterations are similar to those found in other forms of IBD, particularly in the distal proctitis founded after pelvic radiotherapy and in rectal compromising of ulcerative colitis (UC)

The mucous layer covering the colon epithelium is the first line of defense against invasion of the intestinal wall by bacteria and antigen that are present in the intestinal lumen4 , 5. Most of the protective effect provided by the mucous layer relates to the presence of mucins, which are the predominant glycoproteins in the chemical composition of colonic mucous6 - 8. Mucins in addition to forming a mechanical barrier exhibit antimicrobial activity that protects the intestinal wall against existing pathogens in the intestinal lumen9. The histochemical expression of mucins in the colonic mucosa is well known and, selectively, the presence of neutral and acid mucins can be demonstrated10. The proportions between neutral and acid mucins may be modified in IBD and changes to the tissue expression of this glycoprotein in the colon mucosa of patients with UC and Crohn's disease have already been demonstrated11 , 12. The capacity of the colonic epithelium to produce mucins depends on adequate supply of SCFAs7. Recent studies have shown the importance of maintaining the supply of SCFAs, particularly butyrate, in order to have adequate gene expression relating to mucin formation and content of the glycoprotein4 , 5 , 8 , 13.

Despite the histopathological similarities between UC and DC, few studies has evaluated the modifications in the tissue contents and pattern of expression of neutral and acid mucins on glands of the colonic mucosa without fecal stream4 , 5 , 13. The results of these studies showed that the deviation of the fecal stream reduce the content and modify the pattern of tissue expression of neutral and acid mucins. In other words, the deficiency in the supply of SCFAs can modify the mucus that overlying the colonic mucosa, reducing the effectiveness of this first line of defense against luminal aggression5 , 13.

Sucralfate (SCF) is a basic aluminum salt of sucrose octasulphate which was employed for prevention and treatment of several gastrointestinal diseases14. SCF has used as a topical treatment to healing several types of epithelial wounds such as venous ulcers, mucositis and perianal wounds15 , 16. The molecule of SCCF has other properties such as antioxidant, stimulating the formation of gastrointestinal mucus, increase the production of prostaglandins and epidermal growth factor (EGF)14. Kochhar et al.16 were the first author to demonstrate the efficacy of enemas containing SCF in control of rectal bleeding due to radiation proctitis (RP). Since then, a string of well-conducted studies have confirmed the beneficial therapeutic effects of the substance in clinical, endoscopic and histological improvement in patients with RP, as well as in other forms of IBD where occur the formation of ulcers in the colonic mucosa, such as UC and solitary rectal ulcer17 , 18. Despite the DC course with the formation of superficial epithelial ulcerations and aphthous ulcers in the colonic mucosa, to the best of our knowledge, the effects of SCF on tissue expression of mucins has not yet been evaluated in patients or experimental models of DC. Therefore, the objective of this study is to determine the effects of application of daily enemas with SCF on tissue content of mucins in colonic mucosa devoid of the fecal stream.

Methods

The experiments were performed in accordance with the principles outlined by Federal Law nº 11.794 (10/08/2008) and were approved by the Ethics Committee in Animal Research of Sao Francisco University (Nº 2211/2007).

Thirty-six male, SPF, Wistar rats (300-350g) were obtained from the Sao Francisco University, School of Medicine, barrier facility and maintained on light/dark cycles of 12 hours, and fed a standard rodent chow diet. They were deprived of food, but not water, for 24h prior to the surgical procedure.

Surgical technique

The diversion of the fecal stream was performed in all animals under general anesthesia by intramuscular administration of 0.1 ml/100 g of a 1:1 (v/v) solution of ketamine (50 mg/ml) and xylazine (20 mg/ml). The abdomen was shaved, and a 3 cm long midline incision was made. The left colon was exteriorized and sectioned in its mid-portion, corresponding to the descending colon, approximately 3 cm above the Peyer's lymphoid patch located in the rectal-sigmoid transition. Two circular skin pellets, 3 mm in diameter and 3 cm apart, were made in the left side of the abdominal wall at the same vertical level. The proximal end of the colon was exteriorized through the cranial cutaneous orifice, and the distal stoma was exteriorized through the caudal skin opening after splitting the abdominal wall muscles. The proximal end and the distal stoma were fixed to the skin with full-thickness sutures. Before the fixation of distal stoma to the skin, the distal colon was cleaned by means of an infusion of a physiologic solution until the fecal contents were completely removed. The abdominal incision was closed in two stages (aponeurosis and the skin). In this way, two colostomies were performed: the proximal colostomy as a terminal colostomy with intestinal transit and the second colostomy, as a distal stoma devoid of the fecal stream. Rats were maintained in individual cages, without particular care being taken with regard to the stomas and abdominal incisions.

Experimental groups

The animals were divided into two experimental groups with 18 animals each according the euthanasia had done after two or four weeks. Each experimental group was divided into six subgroups (n=6) according to the intervention solution employed and time of intervention. In the first and second subgroups, 12 animals received daily rectal enemas containing 40 ml of 0.9% saline solution (control subgroup) at 37ºC for two weeks (n=6) and four weeks (n=6). In the second subgroup, 12 animals received daily rectal enemas containing 40 ml of SCF (Sigma-Aldrich, St Louis, MO, USA) at a concentration of 1.0 g/kg for two weeks (n=6) and four weeks (n=6). Finally, 12 animals of the third subgroup received daily enemas containing 40 ml of SCF at a concentration of 2.0 g/kg for two weeks (n=6) and four weeks (n=6). In order to standardize the speed and time of application, the enemas were administered in all animals with an infusion pump whose speed was standardized at 2/ml/min.

Sample collection

Upon completion of the pre-determined irrigation period, the animals were anesthetized as described above, and the midline incision was opened again. In both groups, specimens were taken from the intra-abdominal part of the excluded (colon without fecal stream) subjected to irrigation with the proposed substances. The removed specimen, measuring approximately 4.0 cm, was longitudinally opened through the anti-mesenteric border fixed in a piece of cork and referred to histological and histochemical analysis.

Histological and histochemical analysis

Fragments prepared for histological analysis were immersed in 10% neutral formalin buffer (Sigma-Aldrich, St. Louis, MO, USA) for 24 h, dehydrated by exposure to increasing ethanol concentrations, and embedded in paraffin. Thereafter, sections of tissue were cut at 5 µm on a rotary microtome (Leica Biosystems, Nussloch, Germany), mounted on a glass slide, cleared, hydrated and stained with hematoxylin-eosin (HE) for evaluation of the presence of colitis. Slide analysis was performed with optical microscope (Eclipse DS-50, Nikon Inc., Osaka, Japan) with final magnification of x200. Photomicrographs were taken with a digital video-capture camera (DS-Fi-50; Nikon Inc., Osaka, Japan) coupled to the microscope body and digitized by a computer system of image analysis (NIS-Elements; Nikon Inc., Osaka, Japan). The diagnosis of colitis was made based on presence of three independent histological parameters: reduction of the crypt length, neutrophil infiltration of the mucosa and epithelial loss. These variables were stratified as crosses, according to the degree of each, as follows: a) + absent or no alterations; b) ++ when intensity was mild d) +++ moderate and e) ++++ intense. For all variables analyzed, the final value considered for each animal was the mean value after quantification of three distinct histological fields.

The tissue expression of the neutral mucins was determined individually by means of the histochemical technique of Periodic Acid Schiff (PAS), while the expression of acid mucins was determined using the Alcian Blue (AB) technique. The neutral mucins stained magenta, while the acid mucins stained blue19. The pattern of tissue expression was by a pathologist with experience of diseases of the digestive tract who was unaware of the origin of the material and the objectives of the study.

Image processing, computer-assisted

The tissue content of neutral and acid mucins was quantified by means of image processing computer-assisted and was always performed in a focal field in which there were at least three complete and contiguous colonic crypts, with a magnification of x200. The images selected were captured on a video camera that had been coupled to an optical microscope. These images were processes and analyzed using the NIS-Elements 3.1 software (Nikon Inc., Osaka, Japan), installed in a microcomputer. By means of colored histograms in RGB system the software determined the color intensity in number of pixels in each field selected, and transformed the final data into percentage expressions by analyzed fields (%/fields). The final value taken for each field measured in the segments with and without intestinal transit was the mean of the values found from evaluating three different fields.

Statistical analysis

The statistical analysis on the results obtained was performed by taking the significance level of 5% (p < 0.05). The data from each colon segment analyzed, in each experimental group, were expressed as the mean value with the respective standard error, and were analyzed using the Biostat for Windows statistical software (version 5.0). To compare the mucin content in the segments with and without transit, Student's t paired test was used. To analyze the variance in the mucin expression between the different experimental groups, ANOVA was used with the Newman-Keuls post-test.

Results

Figure 1A shows the colonic epithelium without fecal stream submitted to intervention with S.F. 0.9% for 4 weeks, while Figure 1B shows the colon segment without fecal stream irrigated with SCF at concentration of 2.0 g/kg/day.

Figure 1-A
Colonic mucosa devoid of the fecal stream submitted to intervention with saline for four weeks. Note the epithelial loss with formation of superficial ulcers and irregularity of the colonic glands (HE-x100). B. Colonic mucosa devoid of the fecal stream submitted to intervention with SCF (2.0 g/kg/day) for four weeks. It's possible verify the formation of a protective layer of SCF on the colonic mucosa, preservation of the epithelial colonic surface without the formation of ulcers.

Figure 2 shows the inflammatory score comparing animals submitted to intervention with saline, SCF 1.0 g/kg/day and SCF 2.0 g/kg/day for two and four weeks.

Figure 2
Inflammatory score comparing animals submitted to intervention with saline, SCF 1.0 g/Kg/day and 2.0 g/Kg/day for two and for weeks. * = significant (p<0.05). Student t test.

Figure 3A show the tissue expression of neutral mucins, evaluated in segments without fecal stream submitted to intervention with S.F. 0.9% for four weeks, while Figure 3B shows the colon segment without fecal stream irrigated with SCF at concentration of 2.0 g/kg/day.

Figure 3-A
Tissue content of neutral mucins in animals submitted to intervention with saline for four weeks. It's possible verify loss of epithelium surface, distortion of the colon crypts and reduction of tissue content of neutral mucins in colon glands (PAS-x200). B. Neutral mucins on glands of colonic mucosa devoid of the fecal stream submitted to intervention with SCF 2.0 g/Kg/day for four weeks. The epithelial surface is preserved, and the neutral mucin expression occurs uniformly along the colonic glands (PAS-x200).

Figure 4 shows the mean, with respective standard error, from quantification of neutral mucins comparing colon segments without intestinal transit, submit to daily intervention with saline and SCF at concentration of 1.0g/kg and 2.0g/kg. We found a significant increase in tissue content of neutral mucins in animals subjected to irrigation with SCF compared to animals irrigated with S.F. 0.9%, regardless of the concentration and duration of intervention. The tissue contents of neutral mucins did not vary with the time of intervention established, independent of concentration.

Figure 4
Tissue content of neutral mucins comparing animals submitted to intervention with saline, SCF 1.0 g/Kg/day and 2.0 g/Kg/day for two and for weeks. ** = significant (p<0.01). Student t test.

Figure 5A shows the tissue expression of acid mucins, evaluated using the Alcian-Blue technique in colonic segments without fecal stream submitted to intervention with S.F. 0.9% for four weeks, while Figure 5B shows the colon segment without fecal stream irrigated with SCF at concentration of 2.0 g/kg/day.

Figure 5
A. Tissue content of acid mucins in animals submitted to intervention with saline for four weeks. Reduction of tissue content of acid mucins in colon glands (AB-x100). B. Acid mucins on glands of colonic mucosa devoid of the fecal stream submitted to intervention with SCF 2.0 g/ Kg/day for four weeks. The expression of acids mucin occurs uniformly along the colonic glands (AB-x200).

Figure 6 shows the mean, with respective standard error, from quantification of acid mucins comparing colon segments without intestinal transit, submmit to daily intervention with S.F.0.9% and SCF at concentration of 1.0g/kg and 2.0g/kg. We found a significant increase in tissue content of acid mucins in animals subjected to irrigation with SCF compared to animals irrigated with S.F. 0.9%, regardless of the concentration and duration of intervention. The tissue contents of acid mucins increase with the concentration established, independent of the time.

Figure 6
Tissue content of acid mucins comparing animals submitted to intervention with saline, SCF 1.0 g/Kg/day and 2.0 g/Kg/day for two and for weeks. ** = significant (p<0.01) **SCF 1.0 g/kg/day and SCF 2.0 g/kg/day × Saline. †† SCF 1.0 g/kg/day × SCF 2.0 g/kg/day Student t test.

Discussion

DC is defined as an IBD that affects colorectal segments without fecal stream2. A variety of theories have been put forward to explain the etiopathogenesis of DC. Prominent among these is a theory that relates the appearance of this disease to decreased quantities of SCFAs in the intestinal lumen2 , 3 , 20 - 22. SCFAs are the main energy source for colonocytes and account for approximately 80% of the energy needs of the colon epithelium20. In colon segments without fecal stream, absence of the diet fibers impedes the formation of SCFAs and also their absorption and use by the epithelial cells. Recent studies have shown that an absence of SCFAs modifies energetic metabolism of the mitochondrial respiratory chain of the colonocytes leading an increase on production of reactive oxygen species (ROS)23. The increased production of ROS in a tissue recognized to be deficient in antioxidant systems can cause oxidative damage to the cells of the colonic epithelium23. It has been shown the deleterious effects of ROS against the mechanisms of defense of colonic epithelial barrier, in particular the mucus layer overlying the intestinal mucosa and the cellular adhesion moleculles5 , 13 , 24 - 25. These studies showed a relationship between increased of ROS production and reduction in tissue content of neutral and acid mucins in colon segments without fecal steam5 - 13. Reinforcing the importance of oxidative stress in the intestinal epithelium aggression in colonic segments devoid of fecal stream had been demonstrated that the application of enemas containing substances with antioxidant activity, such as 5-aminosalicylic acid and n-acetylcysteine, improves tissue damage by reducing levels of ROS by cells of the colonic mucosa26 - 27.

The main function of mucus is to serve as protection for the epithelial cells of the intestinal mucosa, against aggression caused by enzymes, antigens and bacteria that are present in the intestinal lumen6 , 9. The expression of mucins in the colon epithelium is well known and can be categorized by histochemical techniques as neutral or acid4 , 13. The proportion among all types of mucins is usually constant in the mucosa of normal colon tissue, but may undergo changes in various diseases5. The capacity for mucin synthesis shown by the goblet cells of the colon mucosa depends on an adequate supply of energy substrate7 , 8. Reductions in the supply of SCFAs, as occurs during intestinal diversion operations, are accompanied by morphological and functional changes, thereby causing reductions in protein synthesis capacity5 , 8. The mechanisms through which shortages of SCFAs lead to lower capacity for mucins production are still not completely clear. Studies have shown that intestinal diversion reduces the quantities of dietary fiber and modifies the bacterial populations in the segment excluded and it decreases the production of SCFAs, thereby causing a state of nutritional deficiency for the cells of the colon mucosa5 , 20 , 21 , 28. This nutritional deficiency reduces the mucin synthesis capacity of these cells7. Reinforcing this evidence, studies have shown that administration of SCFA enemas increases the mucin synthesis capacity of the colon mucosa cells, while administration of enemas containing sodium bromo-octanoate (a powerful inhibitor of SCFA metabolization) completely blocks mucin synthesis and causes the appearance of colitis8 , 28. SCFAs also induce the expression of various genes that transcribe mucins, thereby increasing the expression of MUC-2 around twentyfold7 , 8 ,. SCFAs increase cell metabolism by more than 80% and the production and secretion of mucins by the colon epithelium more than twentyfold8 , 29. Recent research has also demonstrated that shortages of SCFAs greatly reduces the expression of the MUC-2 gene, which is the main agent responsible for transcription of the protein fraction of colon mucins8 , 30. Two studies adopting an experimental model of DC showed that the deviation of the fecal stream reduce the tissue content of neutral and acid mucins, particularly scialomucins quantified by computer assisted image analysis, confirming the importance of correct supply of SCFAs in maintaining the synthesis of the glycoprotein5 , 13. All these points reinforce the important role played by SCFAs in relation to the capacity of the colon epithelium to produce mucins and consequently to protect the mucosa against aggression coming from the intestinal lumen5 , 7 , 13 , 31.

These features suggest that the ideal substance for the treatment of DC should have as principal precepts: enhance protection of the intestinal epithelium that lost the protection afforded by the mucus layer, stimulating the production of mucins by intestinal epithelium and improve the tissue repair of the damaged epithelium. If the substance still presents an antioxidant activity, could reduce the oxidative tissue stress and consequently the epithelial damage caused by overproduction of ROS23.

SCF is a cytoprotective agent that has been used for more than three decades in the treatment of several disorders such gastritis, duodenal, stress ulcers, burns, skin lesions, and DII14 - 18 , 32. SCF does not have any adverse effects and it's use is known to have multiple beneficial effects on mucocutaneous wound healing, because the drug can induce the proliferation of dermal fibroblasts, and limiting the inflammation might decrease fibrosis formation and EGF expression as well as the expression of other factors involved in tissue repair processes32 , 33. Stimulating effects on vascular factors, such as angiogenesis, which play important roles in tissue repair, have been demonstrated by SCF14 , 35. The substance is a sucrose and sulfate-aluminum complex which, when in contact with gastrointestinal secretions, forms a viscous gel that adheres to the mucosa creating a physical barrier that protects the mucosa15 - 18. The complex formed, in addition to preventing the degradation of the mucus that covers the gastrointestinal epithelium has antimicrobial properties31 , 36. Studies have shown that SCF also has a bactericidal effect, effective against Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus 37. SCF adheres tightly to proteins on the surface of ulcerations, mainly albumin and fibrinogen, thus forming a stable and insoluble complex, creating a protective layer that covers and protects the ulcerated epithelium. Recent studies have shown that SCF stimulates the production of prostaglandin E2 (PGE2), EGF and gastrointestinal mucus38. It has been shown that the use of SCF increase in 8% the dimension of the mucus gel layer, and increase the contents of acid mucins, sulfomucins and sialomucin, 63 and 81%, respectively. Furthermore, SCF showed a marked increase in the proportion of the high-molecular-weight form of mucin38. The results indicate that the protective qualities of SCF lie mainly in its ability to enhance the mucus gel viscosity, content of mucin and its proportion in the high-molecular-weight form. Recently it was shown that the use of high concentrations of SCF decreases the production of ROS by leukocytes or by the xanthine-xanthine oxidase system after cell injury induced by H2O2, showing that the substance has antioxidant activity39. SCF prevented the delay of wound repair in cells damage induced by H2O2 probably through induction of COX-2 and an anti-apoptotic mechanism. These effects of SCF might be given through the activation of the NF-kappaB pathway.

When we consider the issues involved in the pathogenesis of DC all of these pharmacological properties suggest that the use of SCF may be an interesting therapeutic strategy for treating DC. Although the application of enemas containing SCF have been used successfully for the treatment of RP, UC and other diseases associate with a formation of ulcers and erosions on colonic epithelium, to the best of our knowledge, only a single experimental study of our group and recently published evaluated the effects of this strategy in an experimental model of DC14 , 15 , 29. In this study we verified that daily use of enemas with SCF decreased epithelial loss, abscess formation in the colon crypts, inflammatory infiltrate and was able to preserve the population of goblet cells40. However, although in this study we showed that the application of enemas containing SCF was able to increase the population of goblet cells, we did not studied modifications on tissue content of neutral and acidic mucins in colonic epithelial glands.

The results of the present study confirm the beneficial effects of the use of enemas with SCF in the prevention of the most frequently found histological alterations in DC. We found that the topical application of SCF in the proposed model reduced of the crypt atrophy, neutrophil infiltration of the mucosa, and epithelial loss mainly when the substance is applied at a higher concentration and for a longer period of time. However, the improvement of the inflammatory score can be obtained when using a higher concentration of the substance and a longer intervention time. It is possible that the results could be even better if we had used a higher concentration of the substance, as well as more frequent interventions (e.g. every 12 h). Despite these aspects our findings were similar to those found by other authors who evaluated the effects of SCF on chemically-induced colitis model41. In the animals from the group where intervention was performed with saline, the epithelial surface was irregular, with a "brush border" aspect, and in some areas we observed the formation of small or larger ulcers (Fig.1A). In all animals treated with SCF, regardless of the concentration used, there was the formation of a gelatinous layer on the colonic mucosa that preserved the epithelial surface, without epithelial ulcerations (Fig. 1B).

Previous studies have shown that there is significant reduction in the content of neutral and acidic mucins in the mucosa devoid of the fecal stream13. The authors found that although there is a reduction in both types of mucins the reduction of the tissue content of acidic mucins was more important13. Subsequently, the same group studying the tissue content of both subtypes of mucins in an experimental model of DC suggested that the reduction was given, mainly at the expense of the mucins rich in sialic acid (sialomucins), usually found in the deeper regions of colonic5. The results of both studies clearly show that the derivation of fecal stream interferes with the synthesis of mucus layer that cover the intestinal mucosa. The absence of this morphofunctional barrier expose the colonic epithelial surface biological and antigens of the in the intestinal lumen, determining the onset of colitis. In this study when we evaluated the content of neutral mucins within the goblet cells throughout the length colonic glands, we verified that intervention with SCF increased the content of neutral mucin when compared to animals treated with saline intervention regardless of concentration used. The contents of neutral mucins not vary with time independent of the concentration used intervention. Similarly, with occurs with tissue content of neutral mucins we found that daily intervention with SCF can increase the tissue content of acid mucins. Other than that was verified with the content of neutral mucins, the increase in tissue content of acidic mucins was directly related to the concentration used. However, the tissue content did not change with the time of intervention. These results suggest that the use of enemas SCF is able to maintain the release of acidic mucin content in goblet cells even after 4 weeks of derivation of de fecal stream. These results showed that there application of SCF enemas maintains production of mucins from goblet cells of colon crypts. It is possible that this effect may be related protective properties of the substance to the colonic epithelium, stimulation of mucin by the cells to increase production of EGF, antibacterial action, and antioxidant effects that the substance presents, reducing the aggression by ROS.

Studies correlating tissue mucins with tissue levels of PGE-2, EGF and ROS are needed to verify if the effects of SCF are related only to increased production of mucus or even the substance can reduce levels of oxidative stress found in transit devoid of intestinal mucosa. We are currently studying in the same group of animals the tissue levels of oxidative stress, PGE-2, EGF, NK-kappaB and COX-2 with immunohistochemical and biochemical techniques to assess this possibility.

Conclusion

The daily application of enemas containing sucralfate, in an experimental model of diversion colitisC, decrease the inflammatory alterations and increases tissue content of neutral and acidic mucins on colonic mucosa. The increase on tissue content of acidic mucin is related to concentration used of sucralfate.

References

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  • 25 Kadri CJ, Pereira JA, Silva CM, Nonose R, Nascimento EF, Jacomo Al, Martinez CA. E-cadherin expression in colonic mucosa with and without fecal stream. J Invest Surg. 2013 Apr;26(2):72-9. doi: 10.3109/08941939.2012.693334.
    » https://doi.org/10.3109/08941939.2012.693334
  • 26 Caltabiano C, Máximo FR, Spadari AP, da Conceição Miranda DD, Serra MM, Ribeiro ML, Martinez CA. 5-aminosalicylic acid (5-ASA) can reduce levels of oxidative DNA damage in cells of colonic mucosa with and without fecal stream. Dig Dis Sci. 2011 Apr;56(4):1037-46. doi: 10.1007/s10620-010-1378-z.
    » https://doi.org/10.1007/s10620-010-1378-z
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    » https://doi.org/10.1007/s10620-013-2768-9
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  • Financial source: Sao Paulo Research Foundation (FAPESP). Project N°. 2010/12492-7.
  • 1
    Research performed at Laboratory of Medical Investigation, Medical School, Sao Francisco University (USF), Bragança Paulista-SP, Brazil. Part of Master degree thesis, Postgraduate Program in Health Sciences, USF. Tutor: Carlos Augusto Real Martinez.

Publication Dates

  • Publication in this collection
    Sept 2014

History

  • Received
    15 Apr 2014
  • Reviewed
    17 June 2014
  • Accepted
    14 July 2014
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