Pathogenesis

An imbalance between mucosal aggressive factors (i.e., hydrochloric acid, pepsin, bile acids, and organic acids) and mucosal protective factors (bicarbonate, mucus) is the likely cause of EGUS. Because the glandular mucosa has more protective factors than the nonglandular mucosa, the causes of ulceration in the two parts of the stomach may be different. The mucus-bicarbonate layer covers the surface of the glandular mucosa. Prostaglandin E₂ enhances mucosal blood flow, promotes secretion of this layer, and increases production of mucus and bicarbonate. In addition, prostaglandins maintain the integrity of the nonglandular and glandular mucosa by stimulation of production of surface-active protective phospholipids, enhancement of mucosal repair, and prevention of cell swelling by stimulation of transepithelial sodium transport. Stress resulting from parturition in foals or the stress of training and confinement in adult horses may lead to the release of excess endogenous corticosteroids, which can inhibit prostaglandin synthesis. This decrease in prostaglandins may lead to breakdown of mucosal protective factors and can promote development of ulcers. Glandular and nonglandular mucosal ulceration requires exposure to acid but probably also involves concurrent failure or disruption of mucosal protective factors.

Ulcers in the nonglandular mucosa primarily are caused by prolonged exposure to hydrochloric acid (HCl) and organic acids such as volatile fatty acids (VFAs), similar to the pathophysiology underlying gastroesophageal reflux disease (GERD) in humans. Excessive exposure to HCl and, to a lesser extent, VFAs (acetic, butyric, propionic, and valeric acids), may be the primary cause of ulcers in the nonglandular mucosa. The nonglandular mucosa has no overlying mucus layer and responds to acid irritation by increasing the thickness of its keratin layer, which provides only minimal protection from acid. Gastric lesion formation also may be related to desquamation of the stratified squamous epithelium of the stomach, because replacement of desquamated epithelium seems to be delayed in foals with gastric ulcers. Stomach pH has been strongly implicated in gastric ulceration in adult horses, and the pH at the margo plicatus, where most ulcers occur, can be lower than in some areas of the glandular mucosa. In addition, approximately 50% of horses with moderate to severe ulceration have a significantly lower stomach pH than those with mild or no ulceration.

In foals, when similar stomach regions are compared, mucosal surface pH does not differ among those with or without lesions. However, gastric fluid pH values are lower in recumbent foals and those that nurse infrequently, suggesting that milk buffers gastric acid, whereas recumbency may lead to increased exposure of the nonglandular mucosa to acid. Delayed gastric emptying or decreased gastric motility also may be contributory in neonatal foals with concurrent disease or gastric outflow obstruction.

In addition to stomach HCl, VFAs, which are byproducts of fermentation of carbohydrates by resident stomach bacteria, act synergistically to cause EGUS in horses. When gastric pH is less than 4.0, VFAs become undissociated (lipid soluble) and penetrate into nonglandular squamous epithelial cells, resulting in cell acidification, inhibition of sodium transport, cell swelling, and ulceration. Furthermore, HCl- and VFA-induced squamous mucosal cell injury is dose and time dependent. Because performance horses consume diets high in fermentable carbohydrates, VFAs generated in those animals are of sufficient quantity to cause ulceration.

Helicobacter pylori is the primary cause of glandular gastric ulcers in humans. However, H pylori has not been cultured from the mucosa of either region of the equine stomach; moreover, gastric ulcers in horses arise chiefly in the non­glandular (squamous) region and therefore likely have a different pathogenesis than those found in H pylori infections in humans. Investigators have isolated Helicobacter-specific DNA from normal and eroded glandular and squamous epithelia of horses. In addition, a new Helicobacter species, Helicobacter equorum, was recently cultured from feces of 2 of 7 (28.6%) foals aged less than 1 month and from 40 of 59 (67.8%) foals aged 1 to 6 months. Furthermore, Helicobacter-like DNA was detected in the stomachs of 10 Thoroughbreds and in 2 of 7 horses with gastric ulcers, 3 of 5 horses with gastritis, 5 of 6 horses with both conditions, and 1 horse with normal gastric mucosa. In that same study, however, 39% of the Helicobacter-positive horses did not have gastric lesions. These results indicate that H equorum is able to colonize the lower bowel and is excreted in the feces, but there appears to be no association of Helicobacter spp with gastrointestinal disease.

After a gastric ulcer is formed in the nonglandular mucosa, resident stomach bacteria can colonize the ulcer bed and delay ulcer healing. A variety of bacteria, including Escherichia coli, are found in the horse stomach; E coli are known to rapidly colonize acetic acid–induced gastric ulcers and impair healing in rats. Because oral administration of lactulose results in growth and colonization of the ulcer bed by Lactobacillus spp, which improves healing, antimicrobial treatment or treatment with probiotics containing Lactobacillus organisms may be indicated in some horses with chronic resistant ulcers.