Peptic ulcer disease is a problem of the gastrointestinal tract characterized by mucosal damage secondary to pepsin and gastric acid secretion. It usually occurs in the stomach and proximal duodenum; less commonly, it occurs in the lower esophagus, the distal duodenum, or the jejunum, as in unopposed hyperse-cretory states such as Zollinger-Ellison syndrome, in hiatal hernias (Cameron ulcers), or in ectopic gastric mucosa (e.g., in Meckel's diverticulum).
Approximately 500,000 persons develop peptic ulcer disease in the United States each year.1 In 70 percent of patients it occurs between the ages of 25 and 64 years.2 The annual direct and indirect health care costs of the disease are estimated at about $10 billion.1 However, the incidence of peptic ulcers is declining, possibly as a result of the increasing use of proton pump inhibitors and decreasing rates of Helicobacter pylori infection.3
Causes of Peptic Ulcer Disease
H. pylori infection and the use of nonsteroidal anti-inflammatory drugs (NSAIDs) are the predominant causes of peptic ulcer disease in the United States, accounting for 48 and 24 percent of cases, respectively (Table 1).4 A variety of other infections and comor-bidities are associated with a greater risk of peptic ulcer disease (e.g., cytomegalovirus, tuberculosis, Crohn's disease, hepatic cirrhosis, chronic renal failure, sarcoidosis, myeloproliferative disorder). Critical illness, surgery, or hypovolemia leading to splanchnic hypoperfusion may result in gastroduo-denal erosions or ulcers (stress ulcers); these may be silent or manifest with bleeding or perforation.5 Smoking increases the risk of ulcer recurrence and slows healing.
Although H. pylori is present in the gastroduodenal mucosa in most patients with duodenal ulcers, only a minority (10 to 15 percent) of patients with H. pylori infection develop peptic ulcer disease.6 H. pylori bacteria adhere to the gastric mucosa; the presence of an outer inflammatory protein and a functional cytotoxin-associated gene island in the bacterial chromosome increases virulence and probably ulcerogenic potential.7 Patients with H. pylori infection have increased resting and meal-stimulated gastrin levels and decreased gastric mucus production and duodenal mucosal bicarbonate secretion, all of which favor ulcer formation. Eradication of H. pylori greatly reduces the incidence of ulcer recurrence—from 67 to 6 percent in patients with duodenal ulcers and from 59 to 4 percent in patients with gastric ulcers.8
NSAIDs are the most common cause of peptic ulcer disease in patients without H. pylori infection.9 Topical effects of NSAIDs cause submucosal erosions. In addition, by inhibiting cyclooxygenase, NSAIDs inhibit the formation of prostaglandins and their protective cyclooxygenase-2–mediated effects (i.e., enhancing gastric mucosal protection by stimulating mucus and bicarbonate secretion and epithelial cell proliferation and increasing mucosal blood flow). Coexisting H. pylori infection increases the likelihood and intensity of NSAID-induced damage.10
The annual risk of a life-threatening ulcer-related complication is 1 to 4 percent in patients who use NSAIDs long-term, with older patients at the highest risk.11 NSAID use is responsible for approximately one half of perforated ulcers, which occur most commonly in older patients who are taking aspirin or other NSAIDs for cardiovascular disease or arthropathy.12,13 Other risk factors for NSAID-related ulcers are listed in Table 1.4 Proton pump inhibitors and misoprostol (Cytotec) minimize the ulcerogenic potential of NSAIDs and reduce NSAID-related ulcer recurrence.
Diagnosis of Peptic Ulcer Disease
The diagnosis of peptic ulcer disease is usually based on clinical features and specific testing, although it is important to be aware that individual signs and symptoms are relatively unreliable.
Typical symptoms of peptic ulcer disease include episodic gnawing or burning epigastric pain; pain occurring two to five hours after meals or on an empty stomach; and nocturnal pain relieved by food intake, antacids, or antisecretory agents. A history of episodic or epigastric pain, relief of pain after food intake, and nighttime awakening because of pain with relief following food intake are the most specific findings for peptic ulcer and help rule in the diagnosis.14 Less common features include indigestion, vomiting, loss of appetite, intolerance of fatty foods, heartburn, and a positive family history.14 The physical examination is unreliable—in one study, tenderness to deep palpation reduced the likelihood of ulcer.14
The natural history and clinical presentation of peptic ulcer disease differ in individual populations (Table 26,15–18).15 Abdominal pain is absent in at least 30 percent of older patients with peptic ulcers.16 Postprandial epigastric pain is more likely to be relieved by food or antacids in patients with duodenal ulcers than in those with gastric ulcers. Weight loss precipitated by fear of food intake is characteristic of gastric ulcers.
If the initial clinical presentation suggests the diagnosis of peptic ulcer disease, the patient should be evaluated for alarm symptoms. Anemia, hematemesis, melena, or heme-positive stool suggests bleeding; vomiting suggests obstruction; anorexia or weight loss suggests cancer; persisting upper abdominal pain radiating to the back suggests penetration; and severe, spreading upper abdominal pain suggests perforation. Patients older than 55 years and those with alarm symptoms should be referred for prompt upper endoscopy. Esophagogastroduodenoscopy (EGD) is more sensitive and specific for peptic ulcer disease than upper gastrointestinal barium studies and allows biopsy of gastric lesions.19
Patients younger than 55 years with no alarm symptoms should be tested for H. pylori infection and advised to discontinue the use of NSAIDs, smoking, alcohol, and illicit drug use. Presence of H. pylori can be confirmed with a serum enzyme-linked immunosorbent assay (ELISA), urea breath test, stool antigen test, or endoscopic biopsy (Table 31,19,20). Serum ELISA is the least accurate test and is useful only for diagnosing the initial infection. The stool antigen test is less convenient but is highly accurate and can also be used to confirm H. pylori eradication, as can the urea breath test.19
If test results are positive for H. pylori, the infection should be eradicated and antisecretory therapy, preferably with a proton pump inhibitor, administered for four weeks1,19 (Figure 1). Further management is based on the endoscopic or radiologic diagnosis. Patients with persistent symptoms should be referred for endoscopy to rule out refractory ulcer and malignancy.
Management of Peptic Ulcer Disease
Treatment of peptic ulcer disease should include eradication of H. pylori in patients with this infection (Table 419,21–25). The recommended duration of therapy for eradication is 10 to 14 days; however, shorter treatment courses (regimens of one, five, and seven days) are being assessed.21,22 Potential benefits of shorter regimens include better compliance, fewer adverse effects, and lower costs.
Administration of an H2 blocker or proton pump inhibitor for four weeks (Table 419,21–25) induces healing in most duodenal ulcers. Proton pump inhibitors provide superior acid suppression, healing rates, and symptom relief and are recommended as initial therapy for most patients. One meta-analysis of randomized controlled trials comparing proton pump inhibitors withH2 blockers showed earlier pain control and better healing rates at four weeks for proton pump inhibitors (85 versus 75 percent).23 A recent systematic review of randomized controlled trials showed that proton pump inhibitors healed duodenal ulcers in more than 95 percent of patients at four weeks and gastric ulcers in 80 to 90 percent of patients at eight weeks.24 Therefore, there is little reason to prescribe proton pump inhibitors for longer than four weeks for duodenal ulcers unless the ulcers are large, fibrosed, or unresponsive to initial treatment.
Eradicating H. pylori is often sufficient in patients with small duodenal ulcers. Repeated EGD with biopsy is recommended to confirm healing of gastric ulcers and to rule out malignancy. Maintenance therapy withH2 blockers or proton pump inhibitors prevents recurrence in high-risk patients (e.g., those with a history of complications, frequent recurrences, ulcers testing negative for H. pylori, refractory giant ulcers, or severely fibrosed ulcers), but it is not generally recommended for patients in whom H. pylori has been eradicated and who are not taking NSAIDs long-term.
Refractory peptic ulcer disease (i.e., disease that fails to heal after eight to 12 weeks of therapy) may be caused by persistent or resistant H. pylori infection, continued NSAID use, giant ulcers requiring longer healing time, cancer, tolerance of or resistance to medications, or hypersecretory states.26 Therapy for refractory peptic ulcer disease involves treatment of the underlying cause and prolonged administration of standard doses of a proton pump inhibitor (Figure 1). Up to 25 percent of patients with gastric ulcers who continue to take NSAIDs may require proton pump inhibitor therapy for longer than eight weeks.27
Surgery is indicated in patients who are intolerant of medications or do not comply with medication regimes, and those at high risk of complications (e.g., transplant recipients, patients dependent on steroids or NSAIDs, those with giant gastric or duodenal ulcer, those with ulcers that fail to heal with adequate treatment). Surgery should also be considered for patients who have a relapse during maintenance treatment or who have had multiple courses of medications.28
Surgical options for duodenal ulcers include truncal vagotomy and drainage (pyloroplasty or gastrojejunostomy), selective vagotomy (preserving the hepatic and celiac branches of the vagus) and drainage, highly selective vagotomy (division of only the gastric branches of the vagus, preserving Latarjet's nerve to the pylorus), or partial gastrectomy. Surgery for gastric ulcers usually involves a partial gastrectomy. Procedures other than highly selective vagotomy may be complicated by post-procedure dumping and diarrhea.
About 25 percent of patients with peptic ulcer disease have a serious complication such as hemorrhage, perforation, or gastric outlet obstruction. Silent ulcers and complications are more common in older patients and in patients taking NSAIDs.16,17 The incidence of serious upper gastrointestinal complications among persons in the general population who do not take NSAIDs is extremely low (less than one per 1,000 person-years).29
Upper gastrointestinal bleeding occurs in 15 to 20 percent of patients with peptic ulcer disease. It is the most common cause of death and the most common indication for surgery in the disease. In older persons, 20 percent of bleeding episodes result from asymptomatic ulcers.17 Patients may present with hematemesis (bright red or “coffee ground”), melena, fatigue caused by anemia, orthostasis, or syncope.
There are several risk-stratification schemes that can help physicians determine the need for urgent intervention and predict continued or recurrent bleeding after endoscopic therapy. The Rockall risk scoring system is useful in stratifying patients at higher risk of rebleeding and death and has been prospectively validated in different populations (Table 530,31).30
In stable patients with gastrointestinal bleeding, potentially ulcerogenic medications should be discontinued. A proton pump inhibitor should be administered intravenously; this reduces transfusion requirements, need for surgery, and duration of hospitalization, although it does not reduce mortality.32 EGD should be performed to find characteristics that suggest a high rate of bleeding recurrence (e.g., ulcer larger than 1 cm, visible or actively bleeding vessel).30
Patients whose condition is unstable should undergo fluid or packed-cell resuscitation followed by emergent EGD and coagulation of bleeding sites through endoscopic ligation; placement of hemoclips; injection of epinephrine, alcohol, or a sclerosant; or a combination of methods.33
Oral antisecretory therapy should be initiated as soon as patients resume oral intake. Treatment of H. pylori infection is more effective than antisecretory therapy without eradication of H. pylori for preventing recurrent bleeding. Therefore, patients with bleeding peptic ulcers should be tested for H. pylori infection and should be prescribed eradication therapy if results are positive.34 If continued administration of aspirin or NSAIDs is required, concurrent administration of misoprostol or a proton pump inhibitor should be considered.35,36 Patients with nonhealing gastric ulcers should have biopsy to rule out cancer.
Angiographic embolization of bleeding vessels or surgery is indicated if a patient's vital signs or laboratory studies suggest continued or recurrent bleeding.33 Surgical options include gastroduodenotomy and oversewing of the blood vessel with or without vagotomy and drainage in duodenal ulcer; and excision of the ulcer with vagotomy and drainage or partial gastrectomy in bleeding gastric ulcers.
Perforation occurs in approximately 2 to 10 percent of peptic ulcers.25 It usually involves the anterior wall of the duodenum (60 percent), although it may also occur in antral (20 percent) and lesser-curve (20 percent) gastric ulcers. Perforation of ulcers in children is rare.
Free peritoneal perforation and resulting chemical and bacterial peritonitis is a surgical emergency causing sudden, rapidly spreading, severe upper abdominal pain exacerbated by movement; the pain may radiate to the right lower abdomen or to both shoulders. Fever, hypotension, and oliguria suggest sepsis and circulatory compromise. Generalized abdominal tenderness, rebound tenderness, board-like abdominal wall rigidity, and hypoactive bowel sounds (clinical signs of peritonitis) may be masked in older patients and those taking steroids, immunosuppressants, or narcotic analgesics. Upright or lateral decubitus abdominal radiography or erect chest radiography may demonstrate pneumoperitoneum; however, the absence of this finding does not rule out perforation.17 Sonography, computed tomography, and gastroduodenography are confirmatory.
Initial resuscitation with large-volume crystalloids; nasogastric suction; and administration of intravenous broad-spectrum antibiotics against gram-negative rods, anaerobes, and oral flora are usually followed by laparotomy and placement of an omental patch (Graham patch plication) in patients with perforated duodenal ulcers. In otherwise healthy patients with a history of chronic ulcer and minimal peritoneal contamination, a concurrent, definitive, anti-ulcer procedure (e.g., vagotomy and drainage, highly selective vagotomy) may also be considered. Perforated gastric ulcers are treated with an omental patch, wedge resection of the ulcer, or a partial gastrectomy and reanastomosis. Coexisting H. pylori infection should be eradicated to reduce recurrence and minimize the need for long-term antisecretory therapy and further surgical intervention.25,37 In older patients, mortality rates from perforation and its management may be as high as 30 to 50 percent.1
GASTRIC OUTLET OBSTRUCTION
Peptic ulcer disease is the underlying cause in less than 5 to 8 percent of patients presenting with gastric outlet obstruction. Patients with recurrent duodenal or pyloric channel ulcers may develop pyloric stenosis as a result of acute inflammation, spasm, edema, or scarring and fibrosis.
Symptoms suggesting obstruction include recurrent episodes of emesis with large volumes of vomit containing undigested food; persistent bloating or fullness after eating; and early satiety. Weight loss, dehydration, and a hypo-chloremic, hypokalemic metabolic alkalosis may result; a tympanitic epigastric mass representing the dilated stomach with visible gastric peristalsis also may be observed.
EGD or gastroduodenography (using diatrizoate meglumine and diatrizoate sodium [Gastrografin] or barium) is recommended to determine the site, cause, and degree of obstruction. Malignancy, a more common cause of obstruction (responsible for more than 50 percent of cases), should be ruled out.38 Obstruction resulting from acute inflammation or edema responds well to nasogastric decompression, administration ofH2 blockers or proton pump inhibitors, and eradication of H. pylori. Prokinetic agents should be avoided. Endoscopic pyloric balloon dilatation or surgery (vagotomy and pyloroplasty, antrectomy, or gastroenterostomy) are options to relieve chronic obstruction.25