VI - Thorax and Serous Membranes

Editors: Mills, Stacey E.

Title: Histology for Pathologists, 3rd Edition

Copyright 2007 Lippincott Williams & Wilkins

> Table of Contents > VII - Alimentary Tract > 23 - Stomach

23

Stomach

David A. Owen

Embryology and Postnatal Development

The stomach develops as a fusiform dilatation of the foregut caudal to the esophagus. This occurs first when the embryo is 7 mm in length. Initially, it is attached to the back of the abdomen by the dorsal mesogastrium and to the septum transversum (diaphragm) by the ventral mesogastrium. As the stomach enlarges, the dorsal mesogastrium becomes the greater omentum and the ventral mesogastrium becomes the lesser omentum.

The stomach is derived from endoderm, and early glandular differentiation of the mucosal lining occurs first at the 80-mm stage of fetal development. Enzyme and acid production first occur at the fourth month of fetal life and are well established by the time of birth. The newborn stomach is fully developed and similar to that of the adult.

Gross Morphologic Features

The stomach is a flattened J-shaped organ located in the left upper quadrant of the abdomen. At its upper end, it joins the esophagus several centimeters below the level of the diaphragm. At its distal end, it merges with the duodenum, just to the right of the midline. The stomach is extremely distensible, and its size varies, depending on the volume of food present.

For the purposes of gross description, the stomach can be divided into four regions: cardia, fundus, corpus (or body), and antrum (1,2) (Figure 23.1). The superomedial margin is termed the lesser curvature, and the inferolateral margin is termed the greater curvature. The cardia is found just distal to the lower end of the esophagus. It is a small and ill-defined area, extending 1 to 3 cm from the gastroesophageal junction. The fundus is that portion of the stomach that lies above the gastroesophageal junction, just below the left

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hemidiaphragm. The antrum comprises the distal third of the stomach, proximal to the pyloric sphincter (pylorus), with the remainder of the stomach referred to as the corpus. The junction between the antrum and corpus is poorly demarcated. By external examination, it comprises the portion of stomach distal to the incisura, a notch on the lesser curvature (1). Internally, the gastric mucosa is usually thrown into coarse folds called rugae. These are prominent when the stomach is empty but flattened out when the organ is distended. The rugae are most prominent in the corpus and fundus because this is where the major dilatation to accommodate food occurs. The antrum is characterized by mucosa that is flatter and more firmly anchored to the underlying submucosa (Figure 23.2).

Figure 23.1 Gross anatomical zones of the stomach.

The wall of the stomach has four layers: mucosa, submucosa, muscularis propria, and subserosa. Apart from the mucosa, these layers are structurally similar to the bowel wall elsewhere in the gastrointestinal tract. When viewed close up, the surface of the mucosa is dissected by thin shallow grooves termed areae gastricae (3). These are structurally fixed and do not flatten out when the stomach is distended. They are best seen when the mucosa is viewed en face with a hand lens. Areae gastricae may be demonstrated radiologically via double-contrast barium examination but also can be recognized on histologic sections particularly from gastrectomy specimens, where they appear as shallow depressions on an otherwise monotonously smooth surface (Figure 23.3).

Blood Supply

Five arteries supply blood to the stomach. The left gastric artery arises directly from the celiac axis and supplies the cardiac region. The right gastric artery (which supplies the lesser curve) and the right gastroepiploic artery (which supplies the greater curve) arise from the hepatic artery. The left gastroepiploic and the short gastric arteries arise from the splenic artery and also supply the greater curvature. All these vessels anastomose freely, both on the subserosal layer of the stomach and in the muscularis propria, with extensive true plexus formation present within the submucosa. This richness of blood supply explains why it is so

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unusual to see gastric infarcts. The mucosal arteries are derived from this submucosal plexus but are end arteries and supply an area of mucosa that is largely independent of the adjacent mucosal arteries (4).

Figure 23.2 Mucosal zones of the stomach. The cardiac mucosa (C) is present distal to the lower end of the esophagus (E). The pyloric mucosa (P) occupies a triangular zone proximal to the duodenum (D). Elsewhere, the fundic mucosa (F) shows prominent rugal folds.

Figure 23.3 Low-power view of the gastric fundal mucosa. The grooves in the mucosa are fixed anatomical features called areae gastricae.

Nerve Supply

The sympathetic nerve supply to the stomach is derived from the celiac plexus via nerves that follow the gastric and gastroepiploic arteries. Branches also are received from the left and right phrenic nerves. The parasympathetic supply is the vagus nerve via the main anterior and posterior trunks that lie adjacent to the esophagogastric junction. Shortly after entering the abdomen, the anterior vagus nerve gives off a hepatic branch, and the posterior vagus nerve gives off a celiac branch. Therefore, truncal vagotomy above these branches results in denervation of not only the stomach but the entire intestinal tract. Sectioning below these nerves results only in gastric denervation. A highly selective vagotomy (gastric corpus denervation) is achieved by sectioning lateral branches as the two main gastric nerves pass along the lesser curvature, with preservation of the terminal portion of the vagi that supply the antrum. No true nerve plexuses occur on either subserosal layer of the stomach but instead are concentrated in Meissner's plexus in the submucosa and Auerbach's plexus between the circular and longitudinal fibers of the muscularis propria.

Lymphatics

Recent studies (5,6) have disproved the former view that lymphatic channels are present at all levels of the lamina propria. By using careful ultrastructural techniques, lymphatics have been demonstrated to be limited to the portion of the lamina propria immediately superficial to the muscularis mucosae. From there, efferents penetrate the muscle and communicate with larger lymphatic channels running in the submucosa. This arrangement implies that an early gastric cancer may have lymphatic metastases, even though the primary tumor is entirely superficial to the muscularis mucosae.

The lymphatic trunks of the stomach generally follow the main arteries and veins. Four areas of drainage can be identified, each with its own group of nodes. The largest area comprises the lower end of the esophagus and most of the lesser curvature, which drains along the left gastric artery to the left gastric nodes. From the immediate region of the pylorus, on the lesser curvature, drainage is to the right gastric and hepatic nodes. The proximal portion of the greater curvature drains to pancreaticosplenic nodes in the hilum of the spleen, and the distal portion of the greater curvature drains to the right gastroepiploic nodes in the greater omentum and to pyloric nodes at the head of the pancreas. Efferents from all four groups ultimately pass to celiac nodes around the main celiac axis.

General Histologic Features

Histologically, the mucosa has a similar pattern throughout the stomach. It consists of a superficial layer containing foveolae (pits), which represent invaginations of the surface epithelium, and a deep layer consisting of coiled glands that empty into the base of the foveolae (Figure 23.4). The glandular layer differs in structure and function in different zones of the stomach that correspond roughly, but not precisely, to the gross anatomic regions (Figure 23.1).

Adjacent to the gastroesophageal junction is the cardiac mucosa, where the glands are mucus secreting. Extending proximally from the pylorus is the pyloric mucosa (sometimes called the antral mucosa), where the glands are also mucus secreting. This zone is triangular, extending much further (5 7 cm) proximally along the lesser curvature than it does along the greater curvature (3 4 cm). The pyloric mucosal zone is not identical to the antral region, although some accounts use these terms interchangeably. Also, contrary to what is implied in some descriptions, the incisura has no fixed relationship to the proximal margin of the pyloric mucosal zone. Elsewhere within the stomach (corpus and fundus), the mucosa is exclusively fundic in type, where the glands are specialized to secrete acid and pepsin.

Histologic transition between pyloric and fundal mucosa is gradual rather than abrupt, with intervening junctional mucosae (1 2 cm in width) having a mixed histologic appearance. A broad mucosal transition zone is also present at the pylorus, where gastric and duodenal mucosae merge. However, at the lower end of the normal esophagus, the change from nonkeratinizing squamous epithelium to columnar epithelium is abrupt, both grossly and microscopically. The position of this squamocolumnar junction is variable and does not always coincide with the

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strict anatomic esophagogastric junction, that is, the point where the tubular esophagus becomes the saccular stomach. In some individuals the mucosal junction is located 0.5 to 2.5 cm proximal to the anatomic junction and often is serrated, rather than being a regular circumferential line (Z line) (2).

Figure 23.4 Diagrammatic representation of gastric fundal mucosa. Zymogenic (chief) cells are seen mainly in the basal portion of the glands and parietal cells mainly in the isthmic portion. The neck portion contains zymogenic cells, parietal cells, and mucous neck cells. A small number of endocrine cells are present in the basal zone.

Surface Epithelium

Histologically, the gastric mucosa is covered by tall, columnar, mucus-secreting cells with intervening foveolae that are lined by a similar epithelium (Figure 23.5). The surface and foveolar lining cells are similar throughout all the mucosal zones of the stomach. The gastric glands empty into the base of the foveolae. Separating the foveolae and the glands is the lamina propria. In the cardiac and pyloric mucosal zones, the foveolae are wider than in other areas, sometimes giving the mucosa a slightly villous appearance (Figure 23.6).

Figure 23.5 Gastric surface epithelium with each cell having a mucous globule in the superficial cytoplasm. Intraepithelial lymphocytes are present. These are surrounded by a clear halo (formalin fixation artifact).

The cells of the surface epithelium and foveolae are tall and columnar with basally situated nuclei and superficial cytoplasm that is almost entirely filled with mucus (Figure 23.7). The nuclei have an even distribution of chromatin, with single inconspicuous nucleoli. On hematoxylin and eosin (H&E) stained sections, the appearance of the mucus varies, depending on the staining routine and type of stain used. For example, with alcoholic eosin, the mucus appears as a single vacuole that is clear or lightly eosinophilic. With aqueous eosin, the mucus is more heavily eosinophilic and is seen to be present in numerous, small, closely aggregated

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vacuoles. Histochemically, the foveolar mucus is all neutral, periodic acid- Schiff (PAS) positive, but Alcian blue-negative at pH 2.5 and lower (7).

Figure 23.6 Gastric pyloric mucosa. Note that the glands are loosely packed and occupy about half the mucosal thickness. The surface epithelium appears slightly villous.

Figure 23.7 Gastric surface epithelium showing cytoplasmic mucus present in multiple small vacuoles.

Cardiac and Pyloric Mucosa

In the cardiac and pyloric zone, the foveolae occupy approximately one-half of the mucosal thickness (Figure 23.6). Both the cardiac and pyloric glands are mucus secreting and are loosely packed with abundant intervening lamina propria (Figure 23.8). Occasional cystic glands may be found in the cardiac mucosa but usually are not encountered in the pyloric mucosa. The cells of the mucus glands have ill-defined borders and a bubbly cytoplasm that is different from the foveolar and surface epithelium. They resemble Brunner's glands of the duodenum. Isolated parietal cells are not infrequently found either singly or in small groups, particularly in the pyloric mucosa and especially at the junctional zone, where it meets the fundic mucosa (1). However, it is uncommon for zymogenic (chief) cells to be present outside of the fundic mucosa and junctional area. The pyloric glands secrete neutral mucin only. The cardiac glands secrete predominantly neutral mucin with small amounts of sialomucin (7).

Figure 23.8 Pyloric glands containing cells with a bubbly, foamy appearance.

The extent of the cardiac mucosa and even its existence as a component of the normal gastroesophageal junction has been disputed. Chandrasoma and his associates (8) studied the gastroesophageal region in unselected adult autopsies. They found that when one histologic section was taken through this region only 27% of cases had a zone of pure cardiac mucosa, 44% of cases had a zone of cardiofundic mucosa (glands containing a mixture of mucus-secreting cells and parietal cells), and 29% of cases had only pure fundic mucosa. When the entire gastroesophageal junction from a selected group of adult autopsies was examined, all cases had cardiofundic mucosa present, but only 44% had a zone of pure cardiac mucosa. They also found that the zones of pure cardiac mucosa and cardiofundic mucosae were incomplete so that in some sections the esophageal squamous epithelium was present immediately adjacent to pure fundic mucosa. The average length of the cardiac and cardiofundic mucosa was 5 mm, and it never extended beyond 15 mm from the lower margin of the squamous esophageal epithelium. Other investigators have obtained similar results (9). In contrast, Kilgore and associates (10) and Zhou and associates (11) examined autopsy material from fetuses, infants, and young children. They found that pure cardiac mucosa was present in every case and measured 1.0 to 4.0 mm in length (average 1.8 mm). In 38% of cases, there was an abrupt transition from cardiac to fundic glands; and, in the remainder of cases, an additional zone of cardiofundic mucosa was present that generally measured less than 1.0 mm in length. In all instances where cardiofundic mucosa was present, it was in addition to a zone of pure cardiac mucosa. These findings suggest that pure cardiac mucosa and cardiofundic mucosa are normal findings but that the extent of the mucus-secreting mucosa is less than was previously thought. Cardiac mucosal abnormalities may occur when there is gastroesophageal reflux or when the stomach is infected by Helicobacter pylori. The changes may include inflammatory nuclear atypia, intestinal metaplasia, and the presence of hybrid mucosa (12). Hybrid mucosa is multilayered, with squamous cells at the base of the mucosa and columnar epithelium on the surface. With the development of these inflammatory changes, it may be difficult or even impossible to distinguish between damaged cardiac mucosa and glandular metaplasia of esophageal squamous epithelium (Barrett's esophagus). Reference to specialized pathology texts is required (13). This distinction has a practical importance because Barrett's esophagus carries a higher potential for malignant change than does metaplastic cardiac mucosa (14).

Figure 23.9 Gastric fundic mucosa. Note the short foveolae and the tightly packed glands. Purplish zymogenic cells predominate at the base, and pinkish parietal cells predominate in the upper part of the glands.

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Fundic Gland Mucosa

The fundic (or oxyntic) gland mucosa has foveolae that occupy less than one-quarter of the mucosal thickness. In contrast to the cardiac and pyloric mucosa, the glands are tightly packed and are straight rather than coiled (Figure 23.9). For descriptive purposes, they can be divided into three portions: base, neck, and isthmus. The basal portion consists mainly of zymogenic cells (pepsinogen secreting). These are cuboidal and have a basally situated nucleus, which typically contains one or more small nucleoli and cytoplasm that usually stains pale blue-gray with some variation, depending on the type of hematoxylin used (Figure 23.10). The isthmic portion of the glands contains predominantly parietal cells (acid- and intrinsic factor-secreting). These are roughly triangular, with their base along the basement membrane. The nuclei are centrally placed with evenly distributed chromatin, and the cytoplasm stains a deep pink on well-differentiated H&E sections (Figure 23.10). The neck portion of the fundic glands contains a mixture of zymogenic and parietal cells, together with a third type, mucous neck cells (Figure 23.11). These are difficult to recognize on an H&E stain but are easily identified using a PAS stain, where they are seen to resemble the mucus-secreting cells of the cardiac and pyloric glands. These cells produce neutral and acidic mucin, especially sialomucin, which stains positively with Alcian blue at pH 2.5 (15). Mucous neck cells are found in lesser numbers in the isthmic portion of the glands, and occasional parietal cells can be encountered in the basal portion of the glands. Mucous neck cells are also present in the pyloric mucosa.

Figure 23.10 Fundic glands, showing parietal cell cytoplasm staining light pink and zymogenic cell cytoplasm staining purplish (H&E).

Figure 23.11 Fundic mucosa. The surface and foveolar lining epithelium is intensely positive. Paler staining mucus neck cells are present within the glands (PAS).

Studies indicate that the mucous neck cells located in glands from all areas of the stomach have proliferation and mucosal regeneration as their major functions. These undifferentiated cells act as stem cells and may migrate upward to renew foveolar and surface epithelium or downward to renew zymogenic, parietal, or neuroendocrine cells (16). It has been estimated that, in humans, the gastric surface epithelium is normally replaced every four to eight days. The parietal and zymogenic cells turn over much more slowly, likely every one to three years.

Endocrine Cells

The stomach contains a wide variety of hormone-producing cells. In the antrum, about 50% of the whole endocrine cell population are G cells (gastrin-producing), 30% are enterochromaffin (EC) cells (serotonin-producing), and 15% are D cells (somatostatin-producing). In the fundic mucosa, however, a major portion of the endocrine cells are enterochromaffin-like (ECL) and secrete histamine. Small numbers of X cells (secretion product unknown) and EC cells are also present. In the fundic mucosa, the cells secreting these

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hormones are mostly located in the glands, particularly toward the base. In the pyloric mucosa, they are most common in the neck region just below the foveolae. Within these neuroendocrine cells, the hormones are present as cytoplasmic granules located between the nucleus and basement membrane; but, because the granules are generally inconspicuous on H&E sections, special techniques are required for their demonstration (Figure 23.12). Hormones from the endocrine cells either enter the blood or modulate other locally situated cells (paracrine effect).

Figure 23.12 Endocrine cells in gastric antral glands. The granules are located between the nucleus and the basement membrane (immunostain for chromogranin).

The EC cells and some of the ECL cells have argentaffin granules, which can be stained by Fontana, Masson, or the diazo technique. Other cells are argyrophilic but not argentaffinic and may be stained by the Grimelius technique (17). Silver stains have now been replaced by more sensitive immunologic techniques (synaptophysin and chromogranin) (18). Individual hormones, for example gastrin and somatostatin, may be demonstrated by specific antibodies. In addition to the presence of hormones in epithelial cells, some hormones also are found in neurons and nerve endings present in the stomach wall and mucosa. It is generally believed that vasoactive intestinal peptide is predominant in neural tissue and that catecholamines, bombesin, substance P, enkephalins, and possibly gastrin are also found at these sites. When hyperplasia of G cells occurs, it is generally linear. Overgrowth of ECL cells in the fundic mucosa occurs secondary to hypergastrinemia, arising as a consequence of pernicious anemia. This has been divided into five growth patterns: pseudohyperplasia, hyperplasia, dysplasia, microinfiltration, and neoplasia (19).

Lamina Propria

The epithelial cells of the surface, foveolae, and glands all rest on a basement membrane, which is similar to that seen elsewhere in the intestinal tract. Within the mucosa is a well-developed lamina propria that provides structural support, consisting of a fine meshwork of reticulin with occasional collagen and elastic fibers that are condensed underneath the basement membrane (Figure 23.13). The lamina propria is more abundant in the superficial portion of the mucosa between the pits, especially in the pyloric mucosa. It contains numerous cell types, including fibroblasts, histiocytes, plasma cells, and lymphocytes. It is also normal to find occasional polymorphs and mast cells. As mentioned, the lamina propria also contains capillaries, arterioles, and nonmyelinated nerve fibers. A few fibers of smooth muscle extend upward from the muscularis mucosa into the lamina propria, occasionally reaching the superficial portion of the mucosa, especially in the distal antrum.

The lymphoid tissue of the stomach has not been studied as extensively as that of the small bowel. The isolated lymphocytes and plasma cells in the lamina propria are predominantly of B-cell lineage and IgA secreting. Intraepithelial lymphocytes are present in the stomach but are much less frequent than in the small bowel. They are commonly surrounded by a clear halo, which represents a formalin fixation artifact. These lymphocytes, as well as small numbers of lamina propria lymphocytes, are of T-cell origin.

Recently it has been shown that small numbers of primary lymphoid follicles (aggregates of small lymphocytes) can be found in the normal stomach (20). However, secondary lymphoid follicles (follicles with germinal centers) are found only in gastritis, usually secondary to infection with Helicobacter pylori.

Submucosa

The submucosa is located between the muscularis mucosae and the muscularis propria and also forms the cores of the gastric rugae. It consists of loose connective tissue, in which many elastic fibers are found. The autonomic nerve plexus of Meissner is found in the submucosa, as are plexuses of veins, arteries, and lymphatics.

Figure 23.13 Normal gastric fundic mucosa (reticulin).

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Muscular Components

In classical anatomy texts (21,22), the main muscle mass of the stomach is referred to as the muscularis externa. In North America, however, the alternative name, muscularis propria, is widely used and preferred. This is because the term muscularis externa is ambiguous, and it is sometimes not clear whether it refers to the whole of the main muscle mass or only its external layer.

Three layers of fibers can be recognized in the muscularis propria: outer longitudinal, inner circular, and innermost oblique. The external fibers are continuous with the longitudinal muscle of the esophagus. The inner circular layer is aggregated into a definite sphincter mass at the pylorus, where it is sharply separated from the circular fibers of the duodenum by a connective tissue septum. The oblique muscular fibers are an incomplete layer present interior to the circular fibers and are most obvious in the cardiac area. Evidence for the presence of a circular sphincter at the cardia is controversial (23). Histologic examination is not conclusive; and, although radiologic techniques show arrest of swallowed food at this level, this may be due to external compression from the adjacent crura of the diaphragm.

The muscularis mucosae consist of two layers, the inner circular and outer longitudinal, together with some elastic fibers. Thin bundles of smooth muscle also penetrate into the lamina propria, where they terminate in the basement membrane of the epithelium. This is most obvious in the antral area.

Figure 23.14 Ultrastructural appearances of the parietal cell canaliculus (C). Note the fingerlike microvilli (MV) and the microtubular invaginations (MT). (Original magnifications: left, 9000; right, 41,000.)

Ultrastructure

The surface and foveolar lining epithelial cells are ultrastructurally similar. They are characterized by multiple, rounded, electron-dense mucous vacuoles in the superficial cytoplasm and stubby microvilli projecting from the luminal surface. The basal cytoplasm contains moderate amounts of rough endoplasmic reticulum and some mitochondria. Adjacent epithelial cells are joined by tight junctions (zona occludens) at their luminal aspect and by adherence junctions along the rest of the cell interfaces. These tight junctions are considered to play an important role in maintaining mucosal integrity and the gastric mucosal barrier.

Parietal cells are unique ultrastructurally (Figure 23.14) (24). In the unstimulated state, the cytoplasm contains an apical crescent-shaped canaliculus lined by stubby microvilli (Figure 23.14). Between the microvilli are elongated membrane invaginations termed microtubules. Upon stimulation, the microtubules disappear, to be replaced by a dense meshwork of intracellular canaliculi (25). The canalicular system is considered essential for the formation of hydrochloric acid. This is achieved by active transport of hydrogen ions across the canalicular membrane. Because this process has high energy requirements, most of the remainder of the parietal cell cytoplasm is occupied by mitochondria.

The zymogenic cells are similar to protein-secreting exocrine cells elsewhere in the body. They have rough-surfaced

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vesicles in the superficial cytoplasm and abundant rough endoplasmic reticulum in the remainder of the cell.

Gastric Function

The function of the stomach is to act as a reservoir and mixer of food and to initiate the digestive process. Gastric secretion of acid, pepsin, and electrolytes is partly under nervous control by the vagus and partly under the control of gastrin, produced by G cells in the antrum. Gastrin release from the G cells may occur either as a result of distention of the antrum or by direct stimulation from ingested food, particularly amino acids and peptides. Hydrochloric acid is produced by the active transport of hydrogen ions across the cell membrane. High concentrations of hydrochloric acid are achieved so that most ingested microorganisms are killed and the contents of the stomach are normally sterile.

Gastric mucus is secreted in two forms: a soluble fraction produced by the gastric glands and an insoluble form produced by the surface and foveolar lining cells. Biochemically, the mucus is a complex glycoprotein consisting of a protein core with branched carbohydrate side chains. Histochemically, gastric mucin is almost entirely neutral, although the mucous neck cells may secrete small amounts of sulfomucin and sialomucin (15). By immunohistochemistry, mucins MUC5AC and MUC6 are detected in the normal stomach (26). The exact physiologic role of gastric mucin is not determined. Clearly, the soluble mucin plays a role in lubrication. The insoluble fraction acts as a surface layer, forming a barrier that, together with bicarbonate secreted by the superficial epithelial cells, prevents back diffusion of acid and gastric autodigestion. The actual structural barrier is formed by the continuous layer of luminal mucosal cells and the tight junctions between adjacent cells. This process is likely modulated by prostaglandins which promote mucosal blood flow.

Special Techniques and Procedures

Relatively few special techniques are applicable to routine diagnosis. Mucin stains are the most widely used, and the combined PAS/Alcian blue is the most versatile. This stains neutral mucin magenta, acid mucin light blue, and combinations purple. The combined stain is preferred over a straight PAS because the mucus in some gastric carcinomas is PAS-negative. A mucicarmine stain is not recommended because it does not permit identification of the mucin type and is also negative with some types of acid mucin. Sialomucin and sulphomucin may be distinguished by a combined high iron diamine and Alcian blue stain, which stains sulphomucin black and sialomucin light blue. At the present time, however, this distinction is of limited diagnostic utility.

Usually there is no difficulty in distinguishing zymogenic and parietal cells on a good H&E stain (Figure 23.10). If necessary, special stains, such as a Maxwell stain (27), can aid this distinction. Parietal cells can be recognized and quantified by use of a human milk fat globulin antibody (28).

At the present time, the use of cytokeratin 7 and cytokeratin 20 immunostains to distinguish gastric cardiac mucosa from the mucosa of Barrett's esophagus is controversial. Different results have been obtained by different observers, so this methodology cannot be recommended for routine use (13).

Age Changes

Many older adults have a reduced gastric acid output. Histologically, this is characterized by a reduction in the area of fundic mucosa with expansion of the zone of pyloric mucosa. This results in proximal displacement of the pylorofundic junction, a change termed pyloric (or pseudopyloric) metaplasia. Recently it has become recognized that hypochlorhydria of the elderly is not simply the result of aging but is secondary to chronic gastritis (29).

Artifacts

A variety of artifacts may occur in gastric biopsy specimens (Figure 23.15). Most of these artifacts relate to rough handling of the specimen, either at the time the biopsy sample is taken or when it is removed from the forceps. Crushing is common and can result in compression of the lamina propria, leading to a false impression of an inflammatory infiltrate. Crush artifact also produces telescoping of the foveolar lining cells. Stretching of the mucosa results in separation of the pits and glands, leading to the impression of edema. Hemorrhage into the lamina propria is also common in gastric biopsy samples and has to be distinguished from hemorrhagic gastritis. This can be difficult in small biopsy samples, but usually the microscopic appearances of hemorrhagic gastritis are characteristic. They include superficial epithelial damage and erosions.

Differential Diagnosis

One of the problems for pathologists examining gastric biopsy samples is determining whether the specimen is normal or shows minor degrees of gastritis. It is therefore

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appropriate to review briefly certain aspects of the classification and diagnosis. Specific types of gastritis, for example, acute hemorrhagic gastritis or granulomatous gastritis, are usually so distinct that confusion with a normal stomach is unlikely (30). On the other hand, Helicobacter pylori gastritis may be patchy and may be associated with atrophy. In the early stage of H. pylori gastritis (chronic superficial gastritis), an infiltrate of inflammatory cells is observed in the superficial portion of the mucosa, particularly in the lamina propria between the gastric pits (Figure 23.16). Later, the inflammation spreads deeply to involve the whole thickness of the mucosa and is accompanied by atrophy of gastric glands (chronic atrophic gastritis). Ultimately, the inflammation may burn itself out and all glands are destroyed, leaving only a thinned mucosa containing foveolar structures (gastric atrophy) (30).

Figure 23.15 Biopsy artifacts: crushing, producing an apparent lamina propria infiltrate (A); crushing, resulting in displacement (telescoping) of cells into pit lumen (B); biopsy-induced hemorrhage (C); and stretching, producing an appearance of superficial edema (D).

The superficial gastric lamina propria normally contains some chronic inflammatory cells. It is often a matter of judgment whether these are considered normal or increased in number because there is no simple satisfactory method of objective measurement. In actual practice, it may be even more difficult to evaluate these cells because the gastric biopsy samples obtained by endoscopists are frequently distorted by crushing or stretching. In assessing possible minor

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degrees of inflammation, therefore, study should also be made of the superficial and foveolar lining epithelium, where a number of useful diagnostic features may be identified, depending on the degree of activity of the inflammation. The earliest changes seen are a reduction in the mucin content of the cytoplasm, an increase in nuclear size, and the presence of one or more prominent nucleoli (Figure 23.17). At the base of the foveolae, there may be increased numbers of mitoses, reflecting a more rapid cell turnover. These findings are features of epithelial damage and regeneration and are common to all forms of gastritis and to reactive gastropathy (chemical gastritis). In severe active H. pylori-related inflammation, the epithelium and the lamina propria are infiltrated by acute inflammatory cells (Figure 23.18) and organisms may be seen on the mucosal surface (Figure 23.19). Optimum recognition of organisms is enhanced by using special stains (Giemsa, methylene blue, immunohistochemical stains).

Figure 23.16 Mild chronic superficial gastritis with chronic inflammatory cells present in the superficial lamina propria in excess of normal. This is a borderline biopsy sample and illustrates the least number of cells acceptable for a diagnosis of gastritis.

Figure 23.17 Gastritis showing cytoplasmic mucin loss with enlarged nuclei that contain prominent nucleoli.

Figure 23.18 Gastric pits infiltrated by neutrophils in a case of Helicobacter pylori gastritis.

Where gastritis has been present for some time, there may be atrophy of the mucosal glands, which can be accompanied by an increase in inflammatory cells in the deeper layers of the mucosa. On an H&E section, this is seen as a separation of the glands with increased intervening lamina propria. However, minor degrees of atrophy may be difficult to distinguish, particularly if there is biopsy artifact. In these instances, a reticulin stain can be useful in confirming atrophy by demonstrating coarse condensation of fibers in the lamina propria (Figure 23.20).

Reactive gastropathy occurs when there is increased exfoliation of cells from the mucosal surface. Chemical agents, especially refluxed bile and nonsteroidal anti-inflammatory drugs, are common causes. The gastric surface and foveolar epitheium show regenerative changes as described above, but the mucosa is not infltrated by inflammatory cells. The more severe examples of reactive gastropathy may be characterized by a cork screw appearance of the foveolae.

Figure 23.19 Helicobacter pylori organisms present in the mucous layer on the gastric mucosal surface.

Figure 23.20 Coarse condensation of mucosal fibers in atrophic gastritis (reticulin).

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Metaplasia

There are two major types of metaplasia that are seen in the stomach: intestinal metaplasia (IM) and pyloric (pseudopyloric) metaplasia. Both are thought to be the result of chronic gastritis, and consequently both are more frequently encountered in elderly individuals; neither type is considered symptomatic.

In pyloric metaplasia, there is a replacement of the specialized acid- and enzyme-secreting cells of the fundic glands by mucus-secreting glands of the type present in normal pyloric mucosa. This change occurs in the zone of fundic mucosa adjacent to the histologic fundopyloric junction, and what were typical fundic glands now come to resemble typical pyloric glands. Therefore, in persons with extensive pyloric metaplasia, the fundic gland area of the stomach contracts, the pyloric gland area expands, and the junctional zone is moved proximally toward the cardia (30). Unless the site of biopsy is known with accuracy, pyloric metaplasia cannot be diagnosed on routine H&E sections. However, although the fundic glands lose zymogenic and parietal cells, they still retain pepsinogen I activity. This can be demonstrated by immunohistochemical methods (31).

In IM, there is a change in the cells of the surface and pit epithelium so that morphologically and histochemically they come to resemble the cells of either the small or large bowel; IM may be complete (type I) or incomplete (type II) (32,33). In complete small bowel IM, the gastric mucosa changes to resemble normal small bowel epithelium, characterized by fully developed goblet cells and enterocytes with a brush border (Figure 23.21). In advanced cases, the contour of the mucosa changes with the development of villi and crypts. Paneth's cells may be present in the base of the crypts. In incomplete metaplasia, recognizable absorptive cells are not seen. The epithelium consists of a mixture of intestinal-type goblet cells and columnar mucus-secreting cells, morphologically resembling those of the normal gastric epithelium.

Figure 23.21 Complete intestinal metaplasia (IM).

Histochemical changes detected in the mucus production of the various types of IM are interesting and complex (15,32). In the normal stomach, mucus secreted by the columnar cells is neutral in type, recognized histochemically as PAS-positive and Alcian blue-negative. In complete IM, the enterocyte cytoplasm, apart from the brush border, is mucin-negative, but the goblet cells secrete either sialomucin (an acid mucin that is PAS-positive, Alcian blue-positive at pH 2.5 but Alcian blue-negative at pH 0.5) or sulfomucin (a strongly acidic mucin that is weakly PAS-positive and Alcian blue-positive at pH 2.5 and at pH 0.5) (Figure 23.22). In incomplete small bowel metaplasia, sialomucin is present in the columnar cells; and, in incomplete large bowel metaplasia (also called type III metaplasia) (34), the columnar cells contain sulfomucin (Figure 23.23). Sulfomucin may be recognized separately from sialomucin because it stains positively with high iron diamine (33). The details of

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these methods are well described in standard textbooks of histochemistry (34).

Figure 23.22 Complete intestinal metaplasia (PAS/Alcian blue).

Figure 23.23 Incomplete large bowel metaplasia. The pit contains columnar cells with cytoplasmic sulphomucin (high iron diamine and Alcian blue).

Minor degrees of gastric IM are relatively common in persons in North America and elsewhere. The variants described above rarely exist as a pure entity, and mixtures of the various types within the same gastric foveola are encountered frequently. However, IM should never be considered normal and almost always reflects some degree of gastric damage, usually from chronic gastritis.

Less commonly encountered forms of metaplasia include subnuclear vacuolation (35) and ciliated metaplasia (36). These changes all involve the pyloric mucus glands. Subnuclear vacuolation is not strictly a metaplastic change because it does not simulate the appearance of any other type of normal cells and probably represents a degenerative change secondary to gastritis or duodenal reflux. The vacuoles are clear on H&E sections and indent the nucleus. Ultrastructurally, they consist of a membrane-lined space derived either from endoplasmic reticulum or Golgi and probably contain nonglycoconjugated mucus core protein (37). Ciliated cells are found at the base of antral glands where there is superficial IM (36). The cause and significance of this change is not known.

Pancreatic acinar metaplasia (38) may be present in up to 1.2% of gastric biopsy samples or 13% of gastrectomy specimens. The cells, which are indistinguishable from normal acinar cells, also produce lipase and trypsinogen. Seventy-five percent of cases are positive for amylase. Cells are present in nests and variably sized lobules scattered among the cardiac and fundic mucosae.

Specimen Handling

Gastric mucosa is delicate and should be handled with care. Tissue should be gently removed from the biopsy forceps and oriented before being placed flat on a supportive mesh, such as filter paper or gelfoam. A variety of fixatives are suitable, depending on personal preferences, although routine formalin is suitable for most purposes. Sections are cut in ribbons, usually at two or three levels.

For the best results, it is suggested that gastrectomy specimens be opened and pinned out on a cork board or wax platform before being immersed in formalin and fixed overnight. If sections are taken directly from a fresh specimen, they almost invariably curl up, resulting in irregular orientation of the final slide.

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Histology for Pathologists
Histology for Pathologists
ISBN: 0781762413
EAN: 2147483647
Year: 2004
Pages: 53

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