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Stress ulcer prophylaxis in the intensive care unit
Author
Gerald L Weinhouse, MD
Section Editor
Scott Manaker, MD, PhD
Deputy Editor
Geraldine Finlay, MD
Disclosures
All topics are updated as new evidence becomes available and our peer review process is
complete.
Literature review current through: Jun 2013. | This topic last updated: Jun 6, 2013.
INTRODUCTION — Stress ulcerations usually occur in the fundus and body of the stomach,
but sometimes develop in the antrum, duodenum, or distal esophagus. They tend to be shallow
and cause oozing of blood from superficial capillary beds. Deeper lesions may also occur, which
can erode into the submucosa and cause massive hemorrhage or perforation [1].
The epidemiology, pathophysiology, risk factors, and prognosis of stress ulceration in the
intensive care unit (ICU) are discussed in this topic review. In addition, stress ulcer prophylaxis
is reviewed. Diagnosis and treatment of bleeding peptic ulcers are discussed separately. (See
"Approach to acute upper gastrointestinal bleeding in adults" and "Overview of the treatment of
bleeding peptic ulcers".)
STRESS ULCERATION
Epidemiology — Estimates of the incidence of overt GI bleeding range from 1.5 to 8.5 percent
among all ICU patients, but may be as high as 15 percent among patients who do not receive
stress ulcer prophylaxis [2-5]. Most episodes of overt GI bleeding in critically ill patients are due
to gastric or esophageal ulceration, as determined by endoscopic studies [2,5]. Stress ulceration
can also cause perforation. However, this complication is rare, occurring in fewer than 1 percent
of surgical ICU patients [6].
Pathophysiology — Stress ulceration generally begins in the proximal regions of the stomach
within hours of major trauma or serious illness. Endoscopy performed within 72 hours of a major
burn or cranial trauma reveals acute mucosal abnormalities in greater than 75 percent of patients
[7]. Up to 50 percent of such lesions have endoscopic evidence of recent or ongoing bleeding,
although only a small percentage of patients experience hemodynamic compromise due to acute
blood loss [4]. Stress ulcerations that develop after the first several days of hospitalization tend to be deeper and more distal [8]. In a study of 67 patients with GI bleeding that occurred an average of 14 days after admission, duodenal ulceration was the most common source of bleeding [9]. It is uncertain if early and late stress ulcerations have the same pathophysiology. However, both types probably result from an imbalance between mucosal protection and gastric acid production. Impaired mucosal protection – The stomach is normally protected by a glycoprotein mucous layer that forms a physical barrier to hydrogen ion diffusion and traps bicarbonate. The bicarbonate neutralizes gastric acid adjacent to the stomach wall. This barrier may be denuded by increased concentrations of refluxed bile salts or uremic toxins, which are common in critically ill patients [10,11]. In addition, its synthesis may be decreased when there is poor gut perfusion caused by shock, sepsis, or trauma [12,13]. Hypersecretion of acid – Hypersecretion of acid due to excessive gastrin stimulation of parietal cells has been detected in patients with head trauma [14-16]. This abnormality is probably not a factor in all ICU patients, since acid secretion tends to be normal or subnormal in most other patients. H. pylori infection may also contribute to stress ulceration, but the evidence is of limited quality. A case-control study of 50 ICU patients found that patients with GI bleeding were more likely to have H. pylori infection than patients without acute GI bleeding (36 versus 16 percent) [17]. Conversely, another observational study of 99 ICU patients found that patients with H. pylori infection were more likely to have GI bleeding than patients without H. pylori infection (23 versus 13 percent), although the difference did not reach statistical significance [18]. Risk factors — A multicenter prospective cohort study of 2252 ICU patients identified two major risk factors for clinically important GI bleeding (defined as overt GI bleeding leading to hemodynamic deterioration or requiring blood transfusion) due to stress ulceration [2]: Mechanical ventilation for more than 48 hours (odds ratio 15.6) Coagulopathy (odds ratio 4.3) The incidence of clinically important GI bleeding among patients with one or both of these risk factors was 3.7 percent, compared to 0.1 percent among patients with neither risk factor. Smaller studies have reported additional risk factors for stress ulceration, including shock, sepsis, hepatic failure, renal failure, multiple trauma, burns over 35 percent of total body surface area, organ transplantation, head trauma, spinal trauma, a history of peptic ulcer disease, and a history of upper GI bleeding [1,4,19-21]. Glucocorticoid therapy is commonly cited as an indication for stress ulcer prophylaxis [22]. However, glucocorticoid therapy alone has not been conclusively shown to be a risk factor for stress ulceration [2]. Glucocorticoid therapy may increase the risk of stress ulceration when combined with other risk factors for GI ulceration, such as nonsteroidal antiinflammatory drugs or aspirin. (See "Major side effects of systemic glucocorticoids", section on 'Gastrointestinal tract'.) Prognosis — Overt GI bleeding due to stress ulceration is associated with increased mortality. In the prospective cohort study described above, mortality was higher among ICU patients with clinically important GI bleeding than among those without bleeding (49 versus 9 percent) [2]. Another study used four different statistical models to adjust for confounders and found that overt GI bleeding was associated with increased mortality using three of the models (relative risk ranged from 1.8 to 4.9) [5]. PROPHYLAXIS Indications — It is widely accepted that prophylaxis is indicated for ICU patients who are at high risk for stress ulceration, although there is disagreement about which clinical characteristics define high risk. The American Society of Health System Pharmacists developed clinical practice guidelines based upon studies that compared prophylaxis to no prophylaxis and used clinically important GI bleeding as an endpoint [23,24]. The guidelines recommend stress ulcer prophylaxis for ICU patients with any of the following characteristics: coagulopathy, mechanical ventilation for more than 48 hours, history of GI ulceration or bleeding with the past year, and two or more minor risk factors. Minor risk factors included sepsis, ICU admission lasting >1 week, occult GI bleeding lasting ≥6 days, and glucocorticoid therapy. Many clinicians also provide stress ulcer prophylaxis to patients with traumatic brain injury, traumatic spinal cord injury, or thermal injury (>35 percent of the body surface area) [25]. Their rationale is that such patients have been routinely excluded from studies of stress ulcer prophylaxis because of a presumed high risk of stress ulceration. It is frequently asked whether a patient who is receiving enteral nutrition also requires pharmacological stress ulcer prophylaxis. This question is based upon reports that enteral nutrition alone may reduce the risk of overt GI bleeding due to stress ulceration and that stress ulcer prophylaxis may be ineffective or harmful among patients who are receiving enteral nutrition: Enteral nutrition alone may reduce the risk of overt GI bleeding due to stress ulceration [26- 28]: In one observational study performed using data from a randomized trial, enteral nutrition independently reduced overt GI bleeding (relative risk 0.30, 95% CI, 0.13-0.67) in 1077 critically ill patients who were mechanically ventilated for more than 48 hours [28]. Another observational study of 526 patients in a burn intensive care unit found that the incidence of overt GI bleeding was lower among patients who received early enteral nutrition alone than among patients who received an H2 blocker without early enteral nutrition (3 versus 8 percent) [27]. While these observational data suggest that enteral nutrition may be an adequate substitute for pharmacologic stress ulcer prophylaxis in ICU patients, controlled clinical trials are necessary for confirmation. Pharmacological stress ulcer prophylaxis may be ineffective or harmful among patients who are receiving enteral nutrition: A quantitative systematic review of randomized trials comparing H2 blockers to placebo for the prevention of stress ulceration found that the effect of the H2 blockers varied according to whether the patients were receiving early enteral nutrition [29]. Among patients not receiving early enteral nutrition, H2 blockers reduced the incidence of GI bleeding and had no significant effect on mortality or the rate of hospital-acquired pneumonia. Among patients receiving early enteral nutrition, however, H2 blockers increased mortality and the incidence of hospital-acquired pneumonia, without reducing the rate of GI bleeding. This systematic review had several important limitations. Among the limitations, it included both patients who are at high risk and low risk for stress ulceration. Thus, it is possible that the harmful effects of prophylaxis seen among patients receiving enteral nutrition were due to unnecessary prophylaxis in low risk patients, rather than a more general harmful effect among all patients. While such reports are thought provoking and warrant further study, we believe that the evidence is insufficient to justify withholding stress ulcer prophylaxis from patients who are at high risk for gastrointestinal bleeding even if they are receiving enteral nutrition. Putting the evidence together, we suggest that stress ulcer prophylaxis be administered to all critically ill patients who are at high risk for gastrointestinal bleeding. This includes patients with any of the following characteristics: Coagulopathy, defined as a platelet count <50,000 per m3, an International Normalized Ratio (INR) >1.5, or a partial thromboplastin time (PTT) >2 times the control value Mechanical ventilation for >48 hours History of GI ulceration or bleeding within the past year Traumatic brain injury, traumatic spinal cord injury, or burn injury Two or more of the following: sepsis, an ICU stay >1 week, occult GI bleeding for ≥6 days, or glucocorticoid therapy (more than 250 mg hydrocortisone or the equivalent) Among patients who are not considered high risk for gastrointestinal bleeding, we believe that stress ulcer prophylaxis should be administered on a case-by-case basis. Among the considerations are whether the patient is receiving enteral nutrition, how long the patient is expected to be without enteral nutrition, the severity of the patient’s illness, and the patient’s comorbidities. Pharmacologic agents H2 blockers – Histamine-2 receptor antagonists (H2 blockers) antagonize the H2 receptors on the parietal cell, resulting in diminished gastric acid secretion. They can be given orally, via nasogastric tube, or intravenously [30]. The dose depends on which H2 blocker is used (cimetidine, ranitidine, famotidine, nizatidine). Continuous intravenous infusion is more effective than bolus intravenous infusion at controlling gastric pH [31,32]. However, there is no moderate or high quality data indicating that it is more effective at preventive clinically significant GI bleeding. H2 blockers are generally well tolerated, but a number of uncommon side effects have been reported. (See "Pharmacology of antiulcer medications", section on 'H2 receptor antagonists'.) Proton pump inhibitors – Proton pump inhibitors (PPIs) block acid secretion by irreversibly binding to and inhibiting the hydrogen-potassium ATPase pump that resides on the luminal surface of the parietal cell membrane. They can be given orally, via nasogastric tube, or intravenously [24]. The dose depends on which PPI is used (omeprazole, lansoprazole, rabeprazole, pantoprazole, esomeprazole). PPIs are an extremely safe class of drugs, although some risks have been described. (See "Pharmacology of antiulcer medications", section on 'Proton pump inhibitors' and "Overview and comparison of the proton pump inhibitors for the treatment of acid-related disorders", section on 'Safety'.) Sucralfate – Sucralfate is a sulfated polysaccharide complexed with aluminum hydroxide. It exerts its effects by coating and protecting the gastric mucosa, without altering gastric acid secretion or significantly buffering acid [33,34]. Sucralfate is administered orally or via nasogastric tube at a dose of 1 gram four times per day. It is generally well tolerated, except for infrequent aluminum toxicity. In a prospective cohort study of 11 mechanically ventilated patients who received sucralfate (6 grams per day) for 14 days, none of the patients developed an elevated plasma aluminum concentration, even in the presence of renal impairment [35]. (See "Pharmacology of antiulcer medications", section on 'Sucralfate' and "Pharmacology of antiulcer medications", section on 'Aluminum toxicity'.) Antacids – Antacids neutralize gastric acid and protect the gastric mucosa. Antacids are generally administered every one to two hours at a dose of 30 to 60 mL either orally or via nasogastric tube. Nasogastric tube obstruction can be problematic. Side effects of antacids include hypermagnesemia, hypercalcemia, hypophosphatemia, constipation, and diarrhea. (See "Causes and treatment of hypermagnesemia", section on 'Oral ingestion' and "Etiology of hypercalcemia", section on 'Milk alkali syndrome' and "Causes of hypophosphatemia", section on 'Antacids containing aluminum or magnesium' and "Pharmacology of antiulcer medications", section on 'antacids'.) Prostanoids – Prostanoids (ie, prostaglandin analogs), such as misoprostol, inhibit gastric acid secretion by selectively reducing the ability of the parietal cell to generate cyclic AMP in response to histamine. They also exert a cytoprotective effect by enhancing mucosal defense mechanisms [36,37]. As an example, prostanoid-induced capillary bed vasodilation may protect against local ischemia. Prostanoids are not commonly used for stress ulcer prophylaxis in ICU patients because there are a paucity of data regarding their impact on clinically important outcomes and they have a propensity to cause diarrhea [7,19]. (See "Pharmacology of antiulcer medications", section on 'Prostaglandins'.) Efficacy — Clinical trials have demonstrated that H2 blockers, PPIs, and antacids reduce the frequency of overt GI bleeding in ICU patients compared to placebo or no prophylaxis [4,38-42]. Comparative trials have also been performed; despite this, the body of evidence is relatively poor because many of the studies were imprecise or had other significant methodologic flaws. This section describes the moderate to high quality comparative evidence: H2 blockers versus PPI – A meta-analysis of 13 randomized trials (1587 patients) compared stress ulcer prophylaxis with a PPI to prophylaxis with an H2 blocker [43]. It found less GI bleeding among those who received a PPI (1.3 versus 6.6 percent, odds ratio 0.30, 95% CI 0.17-0.54). There was no difference in mortality or the incidence of nosocomial pneumonia. H2 blockers versus antacids – A meta-analysis that compared H2 blockers to antacids in critically ill patients found that the H2 blocker group had a significantly lower rate of overt GI bleeding (odds ratio 0.56, 95% CI, 0.33-0.97) [39]. H2 blockers versus sucralfate – A trial randomly assigned 1200 mechanically ventilated patients to receive sucralfate suspension via nasogastric tube plus an intravenous placebo, or an H2 blocker (intravenous ranitidine) plus a placebo suspension via nasogastric tube [44]. The H2 blocker decreased overt GI bleeding compared to sucralfate (1.7 versus 3.8 percent). Sucralfate versus antacids – A meta-analysis that compared sucralfate to antacids in ICU patients found that the antacids group had a lower rate of clinically important GI bleeding, but the difference was not statistically significant [38]. Other comparisons – There are a lack of moderate or high quality trials comparing PPIs to sucralfate, PPIs to antacids, sucralfate to placebo in critically ill patients. Potential harms — Randomized trials and meta-analyses suggest that prophylactic agents that increase gastric pH (eg, PPIs, H2 blockers, and antacids) may increase the frequency of nosocomial pneumonia compared to agents that do not alter gastric pH (eg, sucralfate) [38,44-47]. As an example, a trial that randomly assigned 1200 mechanically ventilated patients to receive either an intravenous H2 blocker (ranitidine) or sucralfate found that ventilator-associated pneumonia was more frequent in the H2 blocker group, although the difference was not statistically significant (19 versus 16 percent, RR 1.18, 95% CI 0.92-1.51). The clinical importance of the evidence that certain prophylactic agents may increase the incidence of nosocomial pneumonia is uncertain because many of the studies did not achieve statistical significance. However, the direction of the effect was the same in most of the studies, indicating that insufficient sample size may be the reason that the results were not statistically significant. The impact of different prophylactic agents on the incidence of nosocomial pneumonia may be variable. This was suggested by an observational study in cardiothoracic surgery patients that found a higher incidence of nosocomial pneumonia among patients who received a PPI than among those who received an H2 blocker [48], as well as a randomized trial that found a higher risk of nosocomial pneumonia among mechanically ventilated patients who received an H2 blocker than among those who received an antacid [46]. A potential mechanism for prophylaxis-related nosocomial pneumonia has been proposed. Agents that raise gastric pH promote the growth of bacteria in the stomach, particularly gram-negative bacilli that originate in the duodenum. Esophageal reflux and aspiration of gastric contents along the endotracheal tube may then lead to endobronchial colonization or pneumonia [46,49-52]. Choosing an agent — For ICU patients who are able to receive enteral medications and in whom stress ulcer prophylaxis is indicated, we recommend an oral PPI rather than an alternative prophylactic agent. In contrast, for those who cannot receive enteral medications, we suggest an intravenous H2 blocker rather than an intravenous proton pump inhibitor. Our rationale is that intravenous H2 blockers are substantially less expensive than intravenous PPIs and the lower cost probably outweighs the modest increase in efficacy, especially since the baseline risk of stress ulcer-related gastrointestinal bleeding is low. In situations where cost is not an issue, an intravenous PPI is an appropriate choice. It is important to reiterate and emphasize that this discussion is about prophylaxis; active gastrointestinal bleeding requires a different approach. (See "Approach to acute upper gastrointestinal bleeding in adults", section on 'Medications'.) The major factors on which a prophylactic agent is chosen are the balance between efficacy and potential harm, as well as cost. Efficacy versus potential harm – The evidence indicates that those prophylactic agents that reduce the frequency of overt GI bleeding in ICU patients most effectively (H2 blockers and PPIs) might be associated with more frequent nosocomial pneumonia. In contrast, a less effective prophylactic agent (sucralfate) may be associated with fewer nosocomial pneumonias. Thus, clinicians need to consider the following when choosing a prophylactic agent: whether prevention of overt GI bleeding or minimizing the incidence of nosocomial pneumonia is of greater clinical importance and the strength of the nosocomial pneumonia data. We believe the prophylactic agent should be chosen on the basis of the more definitive evidence - impact on overt GI bleeding - until the relationship between the type of prophylactic agent and the incidence of nosocomial pneumonia is confirmed by more rigorous clinical trials. For this reason, we typically use H2 blockers or PPIs for stress ulcer prophylaxis in our clinical practice. Cost – Choosing less expensive prophylactic agents or administering prophylaxis only to patients who are at high risk for stress ulceration can diminish the cost of stress ulcer prophylaxis: Choosing less expensive prophylactic agents - One analysis found that prophylaxis with oral PPI may be more cost-effective than intravenous H2 blockers [53]. This was a consequence of the lower cost of oral medications and fewer treatment failures in the oral PPI group. Administering prophylaxis only to patients who are at high risk for stress ulceration - It is estimated that only 30 patients who are at high risk for stress ulceration need to receive prophylaxis to prevent one GI bleed, compared to nearly 900 low risk patients [54]. This approach has the added advantage of decreasing the risk of adverse effects related to stress ulcer prophylaxis. In addition, remembering to discontinue prophylaxis when the patient is no longer at high risk for stress ulceration can reduce the cost of stress ulcer prophylaxis. Such prophylaxis is unnecessary because the reduction in the rate of nosocomial gastrointestinal bleeding among non-critically ill patients is minuscule due to the low baseline risk (prophylaxis decreases the rate of gastrointestinal bleeding from 0.33 to 0.22 percent) [55]. Despite this, several studies have demonstrated a high rate of ongoing stress ulcer prophylaxis among patients who are discharged from the ICU [56,57]. SUMMARY AND RECOMMENDATIONS Stress ulcerations usually occur in the fundus and body of the stomach, but sometimes develop in the antrum, duodenum, or distal esophagus. They tend to be shallow and cause oozing of blood from superficial capillary beds. Deeper lesions may also occur, which can erode into the submucosa and cause massive hemorrhage, perforation, or both. (See 'Introduction' above.) Histamine-2 receptor antagonists (H2 blockers), proton pump inhibitors (PPI), and antacids reduce overt GI bleeding in ICU patients compared to placebo or no prophylaxis. (See 'Efficacy' above.) Prophylactic agents that increase gastric pH (PPI, H2 blockers, antacids) might increase the frequency of nosocomial pneumonia, compared to prophylactic agents that do not alter gastric pH (sucralfate). (See 'Potential harms' above.) Stress ulcer prophylaxis is indicated for any critically ill patient who has one or more of the following risk factors: mechanically ventilated for more than 48 hours, coagulopathy, GI ulceration or bleeding within the past year, traumatic brain injury, traumatic spinal cord injury, severe burns, or two or more minor risk factors. Coagulopathy is defined as a platelet count <50,000 per m3, an International Normalized Ratio (INR) >1.5, or a partial thromboplastin time (PTT) >2 times the control value. Severe burns are defined as >35 percent of the body surface area. Minor risk factors include sepsis, ICU admission lasting >1 week, occult GI bleeding lasting ≥6 days, or high-dose glucocorticoid therapy (more than 250 mg hydrocortisone or the equivalent). (See 'Indications' above.) Stress ulcer prophylaxis should be considered on a case-by-case basis for patients without any of the above risk factors. Considerations include whether the patient is receiving enteral nutrition, how long the patient is expected to be without enteral nutrition, the severity of the patient’s illness, and the patient’s comorbidities. (See 'Indications' above.) For ICU patients who are able to receive enteral medications and in whom stress ulcer prophylaxis is indicated, we recommend an oral PPI rather than an alternative prophylactic agent (Grade 1B). (See 'Choosing an agent' above.) For ICU patients who cannot receive enteral medications and in whom stress ulcer prophylaxis is indicated, we suggest an intravenous H2 blocker rather than an intravenous proton pump inhibitor (Grade 2B). Intravenous H2 blockers are usually much less expensive than intravenous PPIs and the lower cost probably outweighs the modest increase in efficacy, especially since the baseline risk of stress ulcer-related gastrointestinal bleeding is low. In situations where cost is not an issue, an intravenous PPI is a reasonable choice. (See 'Choosing an agent' above.) Use of UpToDate is subject to the Subscription and License Agreement.
REFERENCES
1. Cook DJ. Stress ulcer prophylaxis: gastrointestinal bleeding and nosocomial pneumonia. Best evidence synthesis. Scand J Gastroenterol Suppl 1995; 210:48. 2. Cook DJ, Fuller HD, Guyatt GH, et al. Risk factors for gastrointestinal bleeding in critically ill patients. Canadian Critical Care Trials Group. N Engl J Med 1994; 330:377. 3. Ben-Menachem T, Fogel R, Patel RV, et al. Prophylaxis for stress-related gastric hemorrhage in the medical intensive care unit. A randomized, controlled, single-blind study. Ann Intern Med 1994; 121:568. 4. Shuman RB, Schuster DP, Zuckerman GR. Prophylactic therapy for stress ulcer bleeding: a reappraisal. Ann Intern Med 1987; 106:562. 5. Cook DJ, Griffith LE, Walter SD, et al. The attributable mortality and length of intensive care unit stay of clinically important gastrointestinal bleeding in critically ill patients. Crit Care 2001; 5:368. 6. Tsiotos GG, Mullany CJ, Zietlow S, van Heerden JA. Abdominal complications following cardiac surgery. Am J Surg 1994; 167:553. 7. DePriest JL. Stress ulcer prophylaxis. Do critically ill patients need it? Postgrad Med 8. Czaja AJ, McAlhany JC, Pruitt BA Jr. Acute gastroduodenal disease after thermal injury. An endoscopic evaluation of incidence and natural history. N Engl J Med 1974; 291:925. 9. Terdiman JP, Ostroff JW. Gastrointestinal bleeding in the hospitalized patient: a case- control study to assess risk factors, causes, and outcome. Am J Med 1998; 104:349. 10. Ritchie WP Jr. Role of bile acid reflux in acute hemorrhagic gastritis. World J Surg 1981; 11. Schindlbeck NE, Lippert M, Heinrich C, Müller-Lissner SA. Intragastric bile acid concentrations in critically ill, artificially ventilated patients. Am J Gastroenterol 1989; 84:624. 12. Navab F, Steingrub J. Stress ulcer: is routine prophylaxis necessary? Am J Gastroenterol 13. Geus WP, Lamers CB. Prevention of stress ulcer bleeding: a review. Scand J 14. Bowen JC, Fleming WH, Thompson JC. Increased gastrin release following penetrating central nervous system injury. Surgery 1974; 75:720. 15. Stremple JF, Molot MD, McNamara JJ, et al. Posttraumatic gastric bleeding: prospective gastric secretion composition. Arch Surg 1972; 105:177. 16. Watts CC, Clark K. Gastric acidity in the comatose patient. J Neurosurg 1969; 30:107. 17. Maury E, Tankovic J, Ebel A, et al. An observational study of upper gastrointestinal bleeding in intensive care units: is Helicobacter pylori the culprit? Crit Care Med 2005; 33:1513. 18. Robertson MS, Cade JF, Clancy RL. Helicobacter pylori infection in intensive care: increased prevalence and a new nosocomial infection. Crit Care Med 1999; 27:1276. 19. Martin LF, Booth FV, Reines HD, et al. Stress ulcers and organ failure in intubated patients in surgical intensive care units. Ann Surg 1992; 215:332. 20. Hatton J, Lu WY, Rhoney DH, et al. A step-wise protocol for stress ulcer prophylaxis in the neurosurgical intensive care unit. Surg Neurol 1996; 46:493. 21. McBride DQ, Rodts GE. Intensive care of patients with spinal trauma. Neurosurg Clin N 22. Daley RJ, Rebuck JA, Welage LS, Rogers FB. Prevention of stress ulceration: current trends in critical care. Crit Care Med 2004; 32:2008. 23. ASHP Therapeutic Guidelines on Stress Ulcer Prophylaxis. ASHP Commission on Therapeutics and approved by the ASHP Board of Directors on November 14, 1998. Am J Health Syst Pharm 1999; 56:347. 24. Spirt MJ, Stanley S. Update on stress ulcer prophylaxis in critically ill patients. Crit Care 25. Guillamondegui, OD, Gunter OL, et al. Practice management guidelines for stress ulcer prophylaxis, Eastern Association for the Surgery of Trauma (EAST), Chicago 2008. p.24. 26. Pingleton SK, Hadzima SK. Enteral alimentation and gastrointestinal bleeding in mechanically ventilated patients. Crit Care Med 1983; 11:13. 27. Raff T, Germann G, Hartmann B. The value of early enteral nutrition in the prophylaxis of stress ulceration in the severely burned patient. Burns 1997; 23:313. 28. Cook D, Heyland D, Griffith L, et al. Risk factors for clinically important upper gastrointestinal bleeding in patients requiring mechanical ventilation. Canadian Critical Care Trials Group. Crit Care Med 1999; 27:2812. 29. Marik PE, Vasu T, Hirani A, Pachinburavan M. Stress ulcer prophylaxis in the new millennium: a systematic review and meta-analysis. Crit Care Med 2010; 38:2222. 30. Pemberton LB, Schaefer N, Goehring L, et al. Oral ranitidine as prophylaxis for gastric stress ulcers in intensive care unit patients: serum concentrations and cost comparisons. Crit Care Med 1993; 21:339. 31. Baghaie AA, Mojtahedzadeh M, Levine RL, et al. Comparison of the effect of intermittent administration and continuous infusion of famotidine on gastric pH in critically ill patients: results of a prospective, randomized, crossover study. Crit Care Med 1995; 23:687. 32. Ballesteros MA, Hogan DL, Koss MA, Isenberg JI. Bolus or intravenous infusion of ranitidine: effects on gastric pH and acid secretion. A comparison of relative efficacy and cost. Ann Intern Med 1990; 112:334. 33. McCarthy DM. Sucralfate. N Engl J Med 1991; 325:1017. 34. Rees WD. Mechanisms of gastroduodenal protection by sucralfate. Am J Med 1991; 35. Tryba M, Kurz-Müller K, Donner B. Plasma aluminum concentrations in long-term mechanically ventilated patients receiving stress ulcer prophylaxis with sucralfate. Crit Care Med 1994; 22:1769. 36. Wilson DE. Antisecretory and mucosal protective actions of misoprostol. Potential role in the treatment of peptic ulcer disease. Am J Med 1987; 83:2. 37. Dajani EZ. Overview of the mucosal protective effects of misoprostol in man. 38. Cook DJ, Reeve BK, Guyatt GH, et al. Stress ulcer prophylaxis in critically ill patients. Resolving discordant meta-analyses. JAMA 1996; 275:308. 39. Cook DJ, Witt LG, Cook RJ, Guyatt GH. Stress ulcer prophylaxis in the critically ill: a 40. Phillips JO, Metzler MH, Palmieri MT, et al. A prospective study of simplified omeprazole suspension for the prophylaxis of stress-related mucosal damage. Crit Care Med 1996; 24:1793. 41. Lasky MR, Metzler MH, Phillips JO. A prospective study of omeprazole suspension to prevent clinically significant gastrointestinal bleeding from stress ulcers in mechanically ventilated trauma patients. J Trauma 1998; 44:527. 42. Tryba M. Prophylaxis of stress ulcer bleeding. A meta-analysis. J Clin Gastroenterol 43. Barkun AN, Bardou M, Pham CQ, Martel M. Proton pump inhibitors vs. histamine 2 receptor antagonists for stress-related mucosal bleeding prophylaxis in critically ill patients: a meta-analysis. Am J Gastroenterol 2012; 107:507. 44. Cook D, Guyatt G, Marshall J, et al. A comparison of sucralfate and ranitidine for the prevention of upper gastrointestinal bleeding in patients requiring mechanical ventilation. Canadian Critical Care Trials Group. N Engl J Med 1998; 338:791. 45. Messori A, Trippoli S, Vaiani M, et al. Bleeding and pneumonia in intensive care patients given ranitidine and sucralfate for prevention of stress ulcer: meta-analysis of randomised controlled trials. BMJ 2000; 321:1103. 46. Prod'hom G, Leuenberger P, Koerfer J, et al. Nosocomial pneumonia in mechanically ventilated patients receiving antacid, ranitidine, or sucralfate as prophylaxis for stress ulcer. A randomized controlled trial. Ann Intern Med 1994; 120:653. 47. Driks MR, Craven DE, Celli BR, et al. Nosocomial pneumonia in intubated patients given sucralfate as compared with antacids or histamine type 2 blockers. The role of gastric colonization. N Engl J Med 1987; 317:1376. 48. Miano TA, Reichert MG, Houle TT, et al. Nosocomial pneumonia risk and stress ulcer prophylaxis: a comparison of pantoprazole vs ranitidine in cardiothoracic surgery patients. Chest 2009; 136:440. 49. Torres A, El-Ebiary M, Soler N, et al. Stomach as a source of colonization of the respiratory tract during mechanical ventilation: association with ventilator-associated pneumonia. Eur Respir J 1996; 9:1729. 50. Ryan P, Dawson J, Teres D, et al. Nosocomial pneumonia during stress ulcer prophylaxis with cimetidine and sucralfate. Arch Surg 1993; 128:1353. 51. Bonten MJ, Gaillard CA, de Leeuw PW, Stobberingh EE. Role of colonization of the upper intestinal tract in the pathogenesis of ventilator-associated pneumonia. Clin Infect Dis 1997; 24:309. 52. Maier RV, Mitchell D, Gentilello L. Optimal therapy for stress gastritis. Ann Surg 1994; 53. Schupp KN, Schrand LM, Mutnick AH. A cost-effectiveness analysis of stress ulcer prophylaxis. Ann Pharmacother 2003; 37:631. 54. Cash BD. Evidence-based medicine as it applies to acid suppression in the hospitalized 55. Herzig SJ, Vaughn BP, Howell MD, et al. Acid-suppressive medication use and the risk for nosocomial gastrointestinal tract bleeding. Arch Intern Med 2011; 171:991. 56. Grube RR, May DB. Stress ulcer prophylaxis in hospitalized patients not in intensive care units. Am J Health Syst Pharm 2007; 64:1396. 57. Wohlt PD, Hansen LA, Fish JT. Inappropriate continuation of stress ulcer prophylactic therapy after discharge. Ann Pharmacother 2007; 41:1611. Topic 1611 Version 22.0
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