Preservation and Processing of Intestinal Tissue for the Assessment of Histopathology.

The intestine is often examined histologically in connection with allergies and in search for pathological changes. To be able to examine the intestine histologically with a microscope, it must be sampled and processed correctly. For microscopic analysis, the samples have to be cut into thin sections, stained, and mounted on slides. Since it is not possible to cut fresh samples without damaging them, they must first be fixed. The most common method, which is described herein, is the fixation in formalin with subsequent embedding in paraffin and staining of the slides with hematoxylin and eosin (H&E). Hematoxylin solutions (in this case Mayer's hemalum solution) stain the acidic components of the cell, i.e., cell nuclei, blue. The staining with eosin gives a pink staining of cytoplasm. This chapter describes the method of processing intestinal tissue for paraffin-embedding, sectioning, and staining with H&E. Tissue processing can be done in tissue processing machines or manually. We describe the manual processing that is often used for smaller batches of samples.

Mucosubstances in the porcine gastrointestinal tract: Fixation, staining and quantification.

Mucins are of great interest in intestinal research and histochemical methods are often employed to identify them. Since it is in the nature of mucins that they are "hard to hold onto" once they come into contact with water, a frequently used medium in histochemistry, there are a number of challenges that may decrease diagnostic accuracy. As the outcome of methods published for microscopic detection of mucosubstances proved to be unsatisfactory in our hands, the aim was the establishment of a reliable and reproducible protocol. Tissue samples were available from pig feeding experiments. In the present study, we focus on a fixation / staining procedure without making comparisons between differently fed pigs. Several fixation and staining procedures were evaluated for their use in semiautomatic quantification and quality assessment of different mucus fractions simultaneous on one tissue section. Cryostat sectioning, subsequent fixation steps with heat, ethanol and modified Bouin's solution, followed by triple staining with high iron diamine, alcian blue and periodic acid-Schiff turned out to be the best method to identify sulfomucin, sialomucin and neutral mucin simultaneous on one tissue section. This methodology resulted in very good morphology of goblet cells with intact mucin containing vesicles within the cells, which was comparable to ultrastructural electron microscopical observations. Semiautomatic quantification of different mucins was possible. In conclusion, reliable mucus quantification and assessment of mucus quality requires strictly tested procedures. According to our experience, the most important aim after cryosectioning is fast fixation of the mucosubstances, which requires a combination of different fixation steps.

Comparison of different histological protocols for the preservation and quantification of the intestinal mucus layer in pigs.

The histological characterization of the intestinal mucus layer is important for many scientific experiments investigating the interaction between intestinal microbiota, mucosal immune response and intestinal mucus production. The aim of this study was to examine and compare different fixation protocols for displaying and quantifying the intestinal mucus layer in piglets and to test which histomorphological parameters may correlate with the determined mucus layer thickness. Jejunal and colonal tissue samples of weaned piglets (n=10) were either frozen in liquid nitrogen or chemically fixed using methacarn solution. The frozen tissue samples were cryosectioned and subsequently postfixed using three different postfixatives: paraformaldehyde vapor, neutrally buffered formalin solution and ethanol solution. After dehydration, methacarn fixed tissues were embedded in paraffin wax. Both sections of cryopreserved and methacarn fixed tissue samples were stained with Alcian blue (AB)-PAS followed by the microscopically determination of the mucus layer thickness. Different pH values of the Alcian Blue staining solution and two mucus layer thickness measuring methods were compared. In addition, various histomorphological parameters of methacarn fixed tissue samples were evaluated including the number of goblet cells and the mucin staining area. Cryopreservation in combination with chemical postfixation led to mucus preservation in the colon of piglets allowing mucus thickness measurements. Mucus could be only partly preserved in cryosections of the jejunum impeding any quantitative description of the mucus layer thickness. The application of different postfixations, varying pH values of the AB solution and different mucus layer measuring methods led to comparable results regarding the mucus layer thickness. Methacarn fixation proved to be unsuitable for mucus depiction as only mucus patches were found in the jejunum or a detachment of the mucus layer from the epithelium was observed in the colon. Correlation analyses revealed that the proportion of the mucin staining area per crypt area (relative mucin staining) measured in methacarn fixed tissue samples corresponded to the colonal mucus layer thickness determined in cryopreserved tissue samples. In conclusion, the results showed that cryopreservation using liquid nitrogen followed by chemical postfixation and AB-PAS staining led to a reliable mucus preservation allowing a mucus thickness determination in the colon of pigs. Moreover, the detected relative mucin staining area may serve as a suitable histomorphological parameter for the assessment of the intestinal mucus layer thickness. The findings obtained in this study can be used for the implementation of an improved standard for the histological description of the mucus layer in the colon of pigs.

Searching for markers to identify angiogenic endothelial cells: a proteomic approach.

In the field of angiogenesis research considerable effort is put in the development of in vitro assays of angiogenesis to replace animal experiments. Unfortunately, reproducibility of these assays frequently fails depending on the particular batch of endothelial cells delivered by the distributor. This is due to the lack of reliable markers for the identification and isolation of angiogenic microvascular endothelial cells that have the capacity to perform all stages of the angiogenic cascade. This study was carried out to identify potential markers for angiogenic versus non-angiogenic endothelial cells. The protein expression profile of four capillary-derived human microvascular primary endothelial cell cultures of which only two batches could be stimulated to angiogenesis was investigated and compared by two-dimensional gel electrophoresis. Seven proteins were found to be expressed in the angiogenic batches only. One protein was detected exclusively in the non-angiogenic batches. These proteins might be verified as markers for angiogenic endothelial cells.