Don W. Powell

Villous Atrophy, Crypt Hyperplasia, Cellular Infiltration, and Impaired Glucose-NA Absorption in Enteric Cryptosporidiosis of Pigs

Intestinal morphology and fluid and electrolyte transport were examined in a neonatal porcine model of cryptosporidiosis. Sections of jejunum, ileum, and colon were obtained for morphometric analysis on days 3, 6, 9, and 12 postinfection, and in vivo perfusion studies of jejunum and ileum were conducted on days 3 and 4 postinfection. The most severe morphologic lesion was seen in the ileum on day 3, and consisted of villous atrophy, crypt hyperplasia, and cellular infiltration. Villous surface area was reduced from 2.1 +/- 0.4 x 10(5) microns2 in control ileum to 0.8 +/- 0.1 x 10(5) microns2 in infected ileum, a result associated with enterocytes that were fewer in number and reduced in cross-sectional area. Conversely, the number of inflammatory cells in the lamina propria of the villus increased from 456 +/- 116 in control to 1014 +/- 187 in infected villus without a significant change in the volume of the lamina propria. At the height of infection, there was an approximate 1:2 ratio of both organisms and inflammatory cells to villous enterocytes. In contrast, organisms were not observed in the crypts, and the concentration of inflammatory cells in crypt lamina propria was unaltered. Disappearance of organisms and polymorphonuclear cells from the ileum was associated with restoration of normal structure and was complete by day 12. Although organisms were seen in the colon, the general architecture was not severely affected. On days 3 and 4 postinfection, there was a complete impairment of the glucose-stimulated Na and water absorption in both jejunum and ileum of infected pigs; however, absorption of electrolytes and water from a basic Ringers solution, in the absence of glucose, was not significantly affected. These results are consistent with a malabsorptive diarrheal disease associated with the morphological damage and are very similar to those seen in enteric viral disease in pigs, except that the upper intestine is more severely affected in the latter.

Granulomatous enterocolitis induced in rats by purified bacterial cell wall fragments

This study was designed to determine if poorly biodegradable bacterial cell wall components can produce chronic intestinal inflammation. A sterile aqueous suspension of sonically disrupted group A or group D streptococcal cell wall fragments was injected intramurally into the small intestine and cecum of 100 rats. Gross findings in rats killed at intervals of 1 day to 6 mo included intestinal thickening, adhesions, and mesenteric contraction. Acute histologic inflammation subsided by 2 wk, but chronic granulomatous inflammation persisted for 6 mo in the rats injected with group A streptococcal cell wall fragments and 3 mo in the rats injected with group D streptococcal cell wall fragments. Ninety-six control rats identically injected with human serum albumin or phosphate-buffered saline demonstrated mild acute inflammation that resolved, with only 1 rat having chronic intestinal inflammation. Granulomas in the intestine, mesentery, and mesenteric lymph nodes developed in 46% of the rats injected with group A fragments and 45% of the rats injected with group D streptococcal cell wall fragments, compared with 20% of the controls injected with albumin and 4% of the controls injected with phosphate-buffered saline. Group A streptococcal antigen was detected by immunofluorescence at the site of inflammation for 4 mo, and possible reactivation of acute inflammation was seen up to 6 mo after injection. We conclude that bacterial cell wall fragments are capable of producing chronic granulomatous inflammation in the intestinal wall if present in appropriate particle size and concentration. We speculate that cell walls from the enteric microflora may leak across a permeable mucosa in chronic inflammatory bowel disease to initiate and sustain local and systemic inflammation.

Immune system control of rat and rabbit colonic electrolyte transport. Role of prostaglandins and enteric nervous system.

The role of the immune system in controlling intestinal electrolyte transport was studied in rat and rabbit colon in Ussing chambers. A phagocyte stimulus, the chemotactic peptide FMLP, and a mast cell stimulus, sheep anti-rat IgE, caused a brief (less than 10 min) increase in short-circuit current (Isc). Products of immune system activation, platelet-activating factor (PAF) and reactive oxygen species (ROS), caused a sustained, biphasic increase in the Isc. Ion replacement and flux studies indicated that these agonists stimulated electrogenic Cl secretion and inhibited neutral NaCl absorption; responses that were variably inhibited by the cyclooxygenase blockers indomethacin and piroxicam. Lesser degrees of inhibition by nordihydroguaiaretic acid could be accounted for by decreased prostaglandin synthesis rather than by lipoxygenase blockade. Tetrodotoxin, hexamethonium, and atropine also inhibited immune agonist-stimulated Isc, but had no effect on immune agonist-stimulated production of PGE2 or PGI2. These results indicate that immune system agonists alter intestinal epithelial electrolyte transport through release of cyclooxygenase products from cells in the lamina propria with at least 50% of the response being due to cyclooxygenase product activation of the enteric nervous system. The immune system, like the enteric nervous system and the endocrine system, may be a major regulating system for intestinal water and electrolyte transport in health and disease.

Pathophysiology of acute acid injury in rabbit esophageal epithelium.

To increase our understanding of the pathophysiology of reflux esophagitis, we sought the early sequence of changes in mucosal structure and function in acutely acid-damage rabbit esophagus. Using a perfused catheter technique esophageal potential difference (PD) profiles were obtained in anesthetized rabbits before, during, and after perfusion of the lower one-half of the esophagus with phosphate-buffered saline or 80 mM NaCl. When acid perfusion reduced the lower esophageal PD by 40-50% or 80-100% of the initial values, the esophagus was removed, sectioned, and the mucosa studied with light microscopy, transmission electron microscopy, and Ussing chamber technique for evaluation of sodium and mannitol transport. The earlier stage of acid damage (PD 40-50%) was associated with reduced mucosal resistance fom 2,180 +/- 199 to 673 +/- 157 ohm cm2 and increased passive transport of sodium (0.10 +/- 0.06 to 1.82 +/- 0.48 microeq/h.cm2) and mannitol (0.008 +/- 0.003 to 0.051 +/- 0.012 microM/h.cm2) (p less than 0.05). There was no significant change in shirt circuit current (0.35 +/- 0.05 to 0.35 +/- 0.04) or net sodium transport (0.32 +/- 0.06 to 0.37 +/- 0.12) at this stage, and the only morphologic finding was dilated intercellular spaces on electron microscopy. The later stage of acid damage (PD 80-100%) exhibited a further reduction in resistance to 299 +/- 65 ohm.cm2 (p less than 0.05), a finding now accompanied by a reduction in short circuit current (0.35 +/- 0.05 to 0.21 +/- 0.04 microeq/h.cm2) and complete inhibition of net sodium transport (0.32 +/- 0.06 to 0.01 +/- 0.13) (p less than 0.05). Morphologic studies at this time revealed cellular necrosis, edema, and vesicle formation in the stratum spinosum. Both gross mucosal changes and transmural necrosis were notably absent. When esophageal perfusion was performed with a combination of acid (80 mM HCl-80 mM NaCl) and pepsin (100 microgram/ml), the morphologic and physiologic findings were essentially the same as with acid alone; however, the time of perfusion to reach either the 50 or 100% reduction in PD was shortened. The findings in this model can be explained on an initial increase in cellular and/or paracellular permeability followed by inhibition of active sodium transport. The resulting loss of osmolar regulation leads to cell necrosis in the stratum spinosum.

Prostanoids inhibit intestinal NaCl absorption in experimental porcine cryptosporidiosis.

BACKGROUND Recent studies of piglet cryptosporidiosis have shown that impaired Na(+)-coupled glucose absorption is associated with a loss of two thirds of the villous absorptive surface and an inflammatory infiltration of the lamina propria. Because inflammatory cells release eicosanoids that may alter electrolyte transport, the present study examined the role of prostanoids on NaCl transport. METHODS Ileal mucosa was stripped of its muscle layers and mounted in Ussing chambers in the presence or absence of indomethacin. Adjacent tissue was also frozen for subsequent extraction and radioimmunoassay of prostaglandin E2 (PGE2). RESULTS Results showed that net Na+ absorption is inhibited and net Cl- secretion is induced in infected piglets. Indomethacin restored net Na+ and Cl- absorption to control levels and exogenous PGE reversed this effect. Radioimmunoassay of tissue extracts showed that PGE2 increased from 56.7 +/- 9.6 ng/cm2 in control to 134 +/- 16.8 ng/cm2 in infected ileum (P < 0.01). CONCLUSIONS These data indicate that in addition to the Na-glucose malabsorption arising from structural damage, part of the diarrhea of these infected animals must be attributed to local prostanoid production.

Hydrogen peroxide stimulates rat colonic prostaglandin production and alters electrolyte transport.

The changes in short circuit current (electrogenic Cl- secretion) of rat colon brought about by xanthine/xanthine oxidase in the Ussing chamber were inhibited by catalase and diethyldithiocarbamate, but not by superoxide dismutase. These results, the reproduction of the response with glucose/glucose oxidase and with exogenous H2O2, and the lack of effect of preincubation with deferoxamine or thiourea implicate H2O2, and not O2- or OH., as the important reactive oxygen metabolite altering intestinal electrolyte transport. 1 mM H2O2 stimulated colonic PGE2 and PGI2 production 8- and 15-fold, respectively, inhibited neutral NaCl absorption, and stimulated biphasic electrogenic Cl secretion with little effect on enterocyte lactic dehydrogenase release, epithelial conductance, or histology. Cl- secretion was reduced by cyclooxygenase inhibition. Also, the Cl- secretion, but not the increase in prostaglandin production, was reduced by enteric nervous system blockade with tetrodotoxin, hexamethonium, or atropine. Thus, H2O2 appears to alter electrolyte transport by releasing prostaglandins that activate the enteric nervous system. The change in short circuit current in response to Iloprost, but not PGE2, was blocked by tetrodotoxin. Therefore, PGI2 may be the mediator of the H2O2 response. H2O2 produced in nontoxic concentrations in the inflamed gut could have significant physiologic effects on intestinal water and electrolyte transport.

Development of a scoring system to predict mortality from upper gastrointestinal bleeding

Despite the widespread application of endoscopy in acute upper gastrointestinal bleeding, there is little evidence of improved survival among those who undergo the procedure. To select high-risk patients who might benefit most from diagnostic and therapeutic endoscopy, the authors developed and validated a scoring system based on prognostic indicators of increased mortality. The scoring system was developed from the best clinical predictors of mortality, determined in a prospective study of consecutive bleeding patients. The model was then tested in a prospective validation phase at three hospitals. Three main factors in the model predict mortality: bleeding, including hematochezia, drop in hematocrit of 5%, short duration of bleeding, absence of melena, and hypotension; liver disease, manifested by prolonged prothrombin time and encephalopathy; and renal disease. Patients determined to be at high risk for death using the scoring system might be candidates for aggressive management and for therapeutic endoscopy.

Effect of aspirin on normal and cholera toxin-stimulated intestinal electrolyte transport.

The effect of aspirin on normal and cholera toxin-stimulated electrolyte transport has been investigated in vitro, because this drug appears to inhibit cholera toxin-induced intestinal secretion in in vivo animal models. In the Ussing chamber, 10 mM aspirin decreased the control rabbit ileal potential difference and short-circuit current by 50% and increased conductance by 28%. Bidirectional electrolyte flux determinations showed that aspirin significantly increased both Na and Cl absorption and reduced flux (which probably represents HCO3 secretion) to zero. This effect of aspirin appears to be identical to that reported to others with catecholamines as determined with similar techniques. However, alpha-adrenergic blockers did not prevent the electrical effects of aspirin, suggesting that aspirin does not have its effect through release of tissue stores of catecholamines. In the presence of aspirin, cholera toxin increased the potential difference and short-circuit current, and decreased the conductance of rabbit ileum in a fashion qualitatively similar to control tissues. However, aspirin reversed cholera toxin-stimulated Na transport from secretion to absorption, inhibited cholera toxin, induced Cl secretion by 58% and partially, but not significantly, inhibited HCO3 secretion. Thus, the inhibitory effect of aspirin on cholera toxin-induced electrolyte secretion appears to be due to aspirin-stimulated Na and Cl absorption. Although aspirin reduced tissue cyclic AMP concentrations in normal and cholera toxin-stimulated ileum, it also inhibited the electrolyte secretion induced by exogenous cyclic AMP. Thus, if aspirins stimulatory effect on sodium and anion absorption in normal tissue and its inhibitory effect on cholera toxin-stimulated sodium and anion secretion involves a cyclic AMP-mediated system, the effect must be a step distal to cyclic AMP production or degradation. The exact mechanism of aspirins effect on normal and cholera toxin-induced electrolyte transport, and its possible usefulness in the treatment of cholera diarrhea, remains to be determined.

Major gastrointestinal hemorrhage from peripancreatic blood vessels in pancreatitis: treatment by embolotherapy

Seven cases of gastrointestinal bleeding originating from peripancreatic blood vessels seen between 1977 and 1982 are presented. The bleeding originated either from true aneurysms, formed when the pancreatic inflammatory processes weaken the walls of peripancreatic blood vessels, from pseudoaneurysms which occurred after vascular leakage into pancreatic pseudocyst, or from veins. Gastrointestinal bleeding occurs when these entities rupture into gastrointestinal viscera. Hemorrhage of this nature must be considered in the clinical setting of patients who have a history of alcoholism, chronic relapsing pancreatitis, and known pseudocysts. Endoscopy, bleeding scans, and barium contrast studies are only occasionally helpful in diagnosis. Selective visceral angiography during acute hemorrhage is often diagnostic and concomitant arterial embolization techniques may offer a temporizing or permanent modality for hemostasis. This technique may be especially useful in the unstable, acutely ill patient with alcoholic hepatitis, sepsis, or an immature pseudocyst who poses a poor operative risk.

Ion and Water Transport in the Intestine

Disorders of membrane function in the gastrointestinal tract are frequent and cause significant morbidity and mortality. In the developed nations, diarrheal disease is a cause of loss of productivity at work, and death of neonatal livestock; thus, it is primarily of economic significance. However, in the Third World, diarrheal diseases account for the deaths of over 5 million infants and young children each year. Whereas such economic or social issues might direct the investigator to the gastrointestinal tract, its easy accessibility is perhaps the main reason why such research has flourished. As a result, studies of gastrointestinal tissue have added much to our understanding of mechanisms of transport in all epithelia.