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Department of Medicine, University of Washington, Seattle, Washington
Given name(s)
William D.
Family name
Chey
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MD

Taking the Detour

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Taking the detour

A 60‐year‐old woman presented to a community hospital's emergency department with 4 days of right‐sided abdominal pain and multiple episodes of black stools. She reported nausea without vomiting. She denied light‐headedness, chest pain, or shortness of breath. She also denied difficulty in swallowing, weight loss, jaundice, or other bleeding.

The first priority when assessing a patient with gastrointestinal (GI) bleeding is to ensure hemodynamic stability. Next, it is important to carefully characterize the stools to help narrow the differential diagnosis. As blood is a cathartic, frequent, loose, and black stools suggest vigorous bleeding. It is essential to establish that the stools are actually black, as some patients will mistake dark brown stools for melena. Using a visual aid like a black pen or shoes as a point of reference can help the patient differentiate between dark stool and melena. It is also important to obtain a thorough medication history because iron supplements or bismuth‐containing remedies can turn stool black. The use of any antiplatelet agents or anticoagulants should also be noted. The right‐sided abdominal pain should be characterized by establishing the frequency, severity, and association with eating, movement, and position. For this patient's presentation, increased pain with eating would rapidly heighten concern for mesenteric ischemia.

The patient reported having 1 to 2 semiformed, tarry, black bowel movements per day. The night prior to admission she had passed some bright red blood along with the melena. The abdominal pain had increased gradually over 4 days, was dull, constant, did not radiate, and there were no evident aggravating or relieving factors. She rated the pain as 4 out of 10 in intensity, worst in her right upper quadrant.

Her past medical history was notable for recurrent deep venous thromboses and pulmonary emboli that had occurred even while on oral anticoagulation. Inferior vena cava (IVC) filters had twice been placed many years prior; anticoagulation had been subsequently discontinued. Additionally, she was known to have chronic superior vena cava (SVC) occlusion, presumably related to hypercoagulability. Previous evaluation had identified only hyperhomocysteinemia as a risk factor for recurrent thromboses. Other medical problems included hemorrhoids, gastroesophageal reflux disease, and asthma. Her only surgical history was an abdominal hysterectomy and bilateral oophorectomy many years ago for nonmalignant disease. Home medications were omeprazole, ranitidine, albuterol, and fluticasone‐salmeterol. She denied using nonsteroidal anti‐inflammatory drugs, aspirin, or any dietary supplements. She denied smoking, alcohol, or recreational drug use.

Because melena is confirmed, an upper GI tract bleeding source is most likely. The more recent appearance of bright red blood is concerning for acceleration of bleeding, or may point to a distal small bowel or right colonic source. Given the history of thromboembolic disease and likely underlying hypercoagulability, vascular occlusion is a leading possibility. Thus, mesenteric arterial insufficiency or mesenteric venous thrombosis should be considered, even though the patient does not report the characteristic postprandial exacerbation of pain. Ischemic colitis due to arterial insufficiency typically presents with severe, acute pain, with or without hematochezia. This syndrome is typically manifested in vascular watershed areas such as the splenic flexure, but can also affect the right colon. Mesenteric venous thrombosis is a rare condition that most often occurs in patients with hypercoagulability. Patients present with variable degrees of abdominal pain and often with GI bleeding. Finally, portal venous thrombosis may be seen alongside thromboses of other mesenteric veins or may occur independently. Portal hypertension due to portal vein thrombosis can result in esophageal and/or gastric varices. Although variceal bleeding classically presents with dramatic hematemesis, the absence of hematemesis does not rule out a variceal bleed in this patient.

On physical examination, the patient had a temperature of 37.1C with a pulse of 90 beats per minute and blood pressure of 161/97 mm Hg. Orthostatics were not performed. No blood was seen on nasal and oropharyngeal exam. Respiratory and cardiovascular exams were normal. On abdominal exam, there was tenderness to palpation of the right upper quadrant without rebound or guarding. The spleen and the liver were not palpable. There was a lower midline incisional scar. Rectal exam revealed nonbleeding hemorrhoids and heme‐positive stool without gross blood. Bilateral lower extremities had trace pitting edema, hyperpigmentation, and superficial venous varicosities. On skin exam, there were distended subcutaneous veins radiating outward from around the umbilicus as well as prominent subcutaneous venous collaterals over the chest and lateral abdomen.

The collateral veins over the chest and lateral abdomen are consistent with central venous obstruction from the patient's known SVC thrombus. However, the presence of paraumbilical venous collaterals (caput medusa) is highly suggestive of portal hypertension. This evidence, in addition to the known central venous occlusion and history of thromboembolic disease, raises the suspicion for mesenteric thrombosis as a cause of her bleeding and pain. The first diagnostic procedure should be an esophagogastroduodenoscopy (EGD) to identify and potentially treat the source of bleeding, whether it is portal hypertension related (portal gastropathy, variceal bleed) or from a more common cause (peptic ulcer disease, stress gastritis). If the EGD is not diagnostic, the next step should be to obtain computed tomography (CT) of the abdomen and pelvis with intravenous (IV) and oral contrast. In many patients with GI bleed, a colonoscopy would typically be performed as the next diagnostic study after EGD. However, in this patient, a CT scan is likely to be of higher yield because it could help assess the mesenteric and portal vessels for patency and characterize the appearance of the small intestine and colon. Depending on the findings of the CT, additional dedicated vascular diagnostics might be needed.

Hemoglobin was 8.5 g/dL (12.4 g/dL 6 weeks prior) with a normal mean corpuscular volume and red cell distribution. The white cell count was normal, and the platelet count was 142,000/mm3. The blood urea nitrogen was 27 mg/dL, with a creatinine of 1.1 mg/dL. Routine chemistries, liver enzymes, bilirubin, and coagulation parameters were normal. Ferritin was 15 ng/mL (normal: 15200 ng/mL).

The patient was admitted to the intensive care unit. An EGD revealed a hiatal hernia and grade II nonbleeding esophageal varices with normal=appearing stomach and duodenum. The varices did not have stigmata of a recent bleed and were not ligated. The patient continued to bleed and received 2 U of packed red blood cells (RBCs), as her hemoglobin had decreased to 7.3 g/dL. On hospital day 3, a colonoscopy was done that showed blood clots in the ascending colon but was otherwise normal. The patient had ongoing abdominal pain, melena, and hematochezia, and continued to require blood transfusions every other day.

Esophageal varices were confirmed on EGD. However, no high‐risk stigmata were seen. Findings that suggest either recent bleeding or are risk factors for subsequent bleeding include large size of the varices, nipple sign referring to a protruding vessel from an underlying varix, or red wale sign, referring to a longitudinal red streak on a varix. The lack of evidence for an esophageal, gastric, or duodenal bleeding source correlates with lack of clinical signs of upper GI tract hemorrhage such as hematemesis or coffee ground emesis. Because the colonoscopy also did not identify a bleeding source, the bleeding remains unexplained. The absence of significant abnormalities in liver function or liver inflammation labs suggests that the patient does not have advanced cirrhosis and supports the suspicion of a vascular cause of the portal hypertension. At this point, it would be most useful to obtain a CT scan of the abdomen and pelvis.

The patient continued to bleed, requiring a total of 7 U of packed RBCs over 7 days. On hospital day 4, a repeat EGD showed nonbleeding varices with a red wale sign that were banded. Despite this, the hemoglobin continued to drop. A technetium‐tagged RBC study showed a small area of subumbilical activity, which appeared to indicate transverse colonic or small bowel bleeding (Figure 1). A subsequent mesenteric angiogram failed to show active bleeding.

Figure 1
Tagged red blood cell (RBC) scan. A focus of activity is centrally located in the lower half of the midabdomen below the umbilicus (white solid arrow) at 5 minutes following the intravenous administration of 27.4 mCi of Tc‐99m–labeled RBCs that fades over time. There are prominent vascular patterns around and within the abdomen (black dotted arrow).

A red wale sign confers a higher risk of bleeding from esophageal varices. However, this finding can be subjective, and the endoscopist must individualize the decision for banding based on the size and appearance of the varices. It was reasonable to proceed with banding this time because the varices were large, had a red wale sign, and there was otherwise unexplained ongoing bleeding. Because her hemoglobin continued to drop after the banding and a tagged RBC study best localized the bleeding to the small intestine or transverse colon, it is unlikely that the varices are the primary source of bleeding. It is not surprising that the mesenteric angiogram did not show a source of bleeding, because this study requires active bleeding at a sufficient rate to radiographically identify the source.

The leading diagnosis remains an as yet uncharacterized small bowel bleeding source related to mesenteric thrombotic disease. Cross‐sectional imaging with IV contrast to identify significant vascular occlusion should be the next diagnostic step. Capsule endoscopy would be a more expensive and time‐consuming option, and although this could reveal the source of bleeding, it might not characterize the underlying vascular nature of the problem.

Due to persistent abdominal pain, a CT without intravenous contrast was done on hospital day 10. This showed extensive collateral vessels along the chest and abdominal wall with a distended azygos vein. The study was otherwise unrevealing. Her bloody stools cleared, so she was discharged with a plan for capsule endoscopy and outpatient follow‐up with her gastroenterologist. On the day of discharge (hospital day 11), hemoglobin was 7.5 g/dL and she received an eighth unit of packed RBCs. Overt bleeding was absent.

As an outpatient, intermittent hematochezia and melena recurred. The capsule endoscopy showed active bleeding approximately 45 minutes after the capsule exited the stomach. The lesion was not precisely located or characterized, but was believed to be in the distal small bowel.

The capsule finding supports the growing body of evidence implicating a small bowel source of bleeding. Furthermore, the ongoing but slow rate of blood loss makes a venous bleed more likely than an arterial bleed. A CT scan was performed prior to capsule study, but this was done without intravenous contrast. The brief description of the CT findings emphasizes the subcutaneous venous changes; a contraindication to IV contrast is not mentioned. Certainly IV contrast would have been very helpful to characterize the mesenteric arterial and venous vasculature. If there is no contraindication, a repeat CT scan with IV contrast should be performed. If there is a contraindication to IV contrast, it would be beneficial to revisit the noncontrast study with the specific purpose of searching for clues suggesting mesenteric or portal thrombosis. If the source still remains unclear, the next steps should be to perform push enteroscopy to assess the small intestine from the luminal side and magnetic resonance angiogram with venous phase imaging (or CT venogram if there is no contraindication to contrast) to evaluate the venous circulation.

The patient was readmitted 9 days after discharge with persistent melena and hematochezia. Her hemoglobin was 7.2 g/dL. Given the lack of a diagnosis, the patient was transferred to a tertiary care hospital, where a second colonoscopy and mesenteric angiogram were negative for bleeding. Small bowel enteroscopy showed no source of bleeding up to 60 cm past the pylorus. A third colonoscopy was performed due to recurrent bleeding; this showed a large amount of dark blood and clots throughout the entire colon including the cecum (Figure 2). After copious irrigation, the underlying mucosa was seen to be normal. At this point, a CT angiogram with both venous and arterial phases was done due to the high suspicion for a distal jejunal bleeding source. The CT angiogram showed numerous venous collaterals encasing a loop of midsmall bowel demonstrating progressive submucosal venous enhancement. In addition, a venous collateral ran down the right side of the sternum to the infraumbilical area and drained through the encasing collaterals into the portal venous system (Figure 3). The CT scan also revealed IVC obstruction below the distal IVC filter and an enlarged portal vein measuring 18 mm (normal <12 mm).

Figure 2
Third colonoscopy showing a large amount of dark red blood and clots through the entire colon, including the cecum (left pane), which after copious irrigation revealed normal‐appearing underlying mucosa (right pane).
Figure 3
Computed tomography with intravenous contrast, venous phase. There are prominent venous collaterals (white solid arrow) encasing a loop of small bowel, showing submucosal venous enhancement in axial (left pane) and sagittal view (center pane). There are extensive collaterals along the anterior abdominal wall that drains blood from the intrathoracic veins into the inferior vena cava (right pane, grey arrow), some of which drains into the collaterals encasing the loop of small bowel.

The CT angiogram provides much‐needed clarity. The continued bleeding is likely due to ectopic varices in the small bowel. The venous phase of the CT angiogram shows thrombosis of key venous structures and evidence of a dilated portal vein (indicating portal hypertension) leading to ectopic varices in the abdominal wall and jejunum. Given the prior studies that suggest a small bowel source of bleeding, jejunal varices are the most likely cause of recurrent GI bleeding in this patient.

The patient underwent exploratory laparotomy. Loops of small bowel were found to be adherent to the hysterectomy scar. There were many venous collaterals from the abdominal wall to these loops of bowel, dilating the veins both in intestinal walls and those in the adjacent mesentery. After clamping these veins, the small bowel was detached from the abdominal wall. On unclamping, the collaterals bled with a high venous pressure. Because these systemic‐portal shunts were responsible for the bleeding, the collaterals were sutured, stopping the bleeding. Thus, partial small bowel resection was not necessary. Postoperatively, her bleeding resolved completely and she maintained normal hemoglobin at 1‐year follow‐up.

COMMENTARY

The axiom common ailments are encountered most frequently underpins the classical stepwise approach to GI bleeding. First, a focused history helps localize the source of bleeding to the upper or lower GI tract. Next, endoscopy is performed to identify and treat the cause of bleeding. Finally, advanced tests such as angiography and capsule endoscopy are performed if needed. For this patient, following the usual algorithm failed to make the diagnosis or stop the bleeding. Despite historical and examination features suggesting that her case fell outside of the common patterns of GI bleeding, this patient underwent 3 upper endoscopies, 3 colonoscopies, a capsule endoscopy, a technetium‐tagged RBC study, 2 mesenteric angiograms, and a noncontrast CT scan before the study that was ultimately diagnostic was performed. The clinicians caring for this patient struggled to incorporate the atypical features of her history and presentation and failed to take an earlier detour from the usual algorithm. Instead, the same studies that had not previously led to the diagnosis were repeated multiple times.

Ectopic varices are enlarged portosystemic venous collaterals located anywhere outside the gastroesophageal region.[1] They occur in the setting of portal hypertension, surgical procedures involving abdominal viscera and vasculature, and venous occlusion. Ectopic varices account for 4% to 5% of all variceal bleeding episodes.[1] The most common sites include the anorectal junction (44%), duodenum (17%33%), jejunum/emleum (5%17%), colon (3.5%14%), and sites of previous abdominal surgery.[2, 3] Ectopic varices can cause either luminal or extraluminal (i.e., peritoneal) bleeding.[3] Luminal bleeding, seen in this case, is caused by venous protrusion into the submucosa. Ectopic varices present as a slow venous ooze, which explains this patient's ongoing requirement for recurrent blood transfusions.[4]

In this patient, submucosal ectopic varices developed as a result of a combination of known risk factors: portal hypertension in the setting of chronic venous occlusion from her hypercoagulability and a history of abdominal surgery (hysterectomy). [5] The apposition of her abdominal wall structures (drained by the systemic veins) to the bowel (drained by the portal veins) resulted in adhesion formation, detour of venous flow, collateralization, and submucosal varix formation.[1, 2, 6]

The key diagnostic study for this patient was a CT angiogram, with both arterial and venous phases. The prior 2 mesenteric angiograms had been limited to the arterial phase, which had missed identifying the venous abnormalities altogether. This highlights an important lesson from this case: contrast‐enhanced CT may have a higher yield in diagnosing ectopic varices compared to repeated endoscopiesespecially when captured in the late venous phaseand should strongly be considered for unexplained bleeding in patients with stigmata of liver disease or portal hypertension.[7, 8] Another clue for ectopic varices in a bleeding patient are nonbleeding esophageal or gastric varices, as was the case in this patient.[9]

The initial management of ectopic varices is similar to bleeding secondary to esophageal varices.[1] Definitive treatment includes endoscopic embolization or ligation, interventional radiological procedures such as portosystemic shunting or percutaneous embolization, and exploratory laparotomy to either resect the segment of bowel that is the source of bleeding or to decompress the collaterals surgically.[9] Although endoscopic ligation has been shown to have a lower rebleeding rate and mortality compared to endoscopic injection sclerotherapy in patients with esophageal varices, the data are too sparse in jejunal varices to recommend 1 treatment over another. Both have been used successfully either alone or in combination with each other, and can be useful alternatives for patients who are unable to undergo laparotomy.[9]

Diagnostic errors due to cognitive biases can be avoided by following diagnostic algorithms. However, over‐reliance on algorithms can result in vertical line failure, a form of cognitive bias in which the clinician subconsciously adheres to an inflexible diagnostic approach.[10] To overcome this bias, clinicians need to think laterally and consider alternative diagnoses when algorithms do not lead to expected outcomes. This case highlights the challenges of knowing when to break free of conventional approaches and the rewards of taking a well‐chosen detour that leads to the diagnosis.

KEY POINTS

  1. Recurrent, occult gastrointestinal bleeding should raise concern for a small bowel source, and clinicians may need to take a detour away from the usual workup to arrive at a diagnosis.
  2. CT angiography of the abdomen and pelvis may miss venous sources of bleeding, unless a venous phase is specifically requested.
  3. Ectopic varices can occur in patients with portal hypertension who have had a history of abdominal surgery; these patients can develop venous collaterals for decompression into the systemic circulation through the abdominal wall.

Disclosure

Nothing to report.

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References
  1. Helmy A, Kahtani K, Fadda M. Updates in the pathogenesis, diagnosis and management of ectopic varices. Hepatol Int. 2008;2:322334.
  2. Norton ID, Andrews JC, Kamath PS. Management of ectopic varices. Hepatology. 1998;28:11541158.
  3. Watanabe N, Toyonaga A, Kojima S, et al. Current status of ectopic varices in Japan: results of a survey by the Japan Society for Portal Hypertension. Hepatol Res. 2010;40:763766.
  4. Saad WE, Saad NE, Koizumi J. Stomal Varices: Management with decompression TIPS and transvenous obliteration or sclerosis. Tech Vasc Interv Radiol. 2013;16:126134.
  5. Yuki N, Kubo M, Noro Y, et al. Jejunal varices as a cause of massive gastrointestinal bleeding. Am J Gastroenterol. 1992;87:514517.
  6. Lebrec D, Benhamou JP. Ectopic varices in portal hypertension. Clin Gastroenterol. 1985;14:105121.
  7. Etik D, Oztas E, Okten S, et al. Ectopic varices in portal hypertension: computed tomographic angiography instead of repeated endoscopies for diagnosis. Eur J Gastroenterol Hepatol. 2011;23:620622.
  8. Darcy MD, Ray CE, Lorenz JM, et al. ACR appropriateness criteria. Radiologic management of lower gastrointestinal tract bleeding. Reston, VA: American College of Radiology; 2011. Available at: http://www.acr.org/Quality‐Safety/Appropriateness‐Criteria/∼/media/5F9CB95C164E4DA19DCBCFBBA790BB3C.pdf. Accessed January 28, 2015.
  9. Akhter NM, Haskal ZJ. Diagnosis and management of ectopic varices. Gastrointest Interv. 2012;1:310.
  10. Croskerry P. Achieving quality in clinical decision making: cognitive strategies and detection of bias. Acad Emerg Med. 2002;9:11841204.
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A 60‐year‐old woman presented to a community hospital's emergency department with 4 days of right‐sided abdominal pain and multiple episodes of black stools. She reported nausea without vomiting. She denied light‐headedness, chest pain, or shortness of breath. She also denied difficulty in swallowing, weight loss, jaundice, or other bleeding.

The first priority when assessing a patient with gastrointestinal (GI) bleeding is to ensure hemodynamic stability. Next, it is important to carefully characterize the stools to help narrow the differential diagnosis. As blood is a cathartic, frequent, loose, and black stools suggest vigorous bleeding. It is essential to establish that the stools are actually black, as some patients will mistake dark brown stools for melena. Using a visual aid like a black pen or shoes as a point of reference can help the patient differentiate between dark stool and melena. It is also important to obtain a thorough medication history because iron supplements or bismuth‐containing remedies can turn stool black. The use of any antiplatelet agents or anticoagulants should also be noted. The right‐sided abdominal pain should be characterized by establishing the frequency, severity, and association with eating, movement, and position. For this patient's presentation, increased pain with eating would rapidly heighten concern for mesenteric ischemia.

The patient reported having 1 to 2 semiformed, tarry, black bowel movements per day. The night prior to admission she had passed some bright red blood along with the melena. The abdominal pain had increased gradually over 4 days, was dull, constant, did not radiate, and there were no evident aggravating or relieving factors. She rated the pain as 4 out of 10 in intensity, worst in her right upper quadrant.

Her past medical history was notable for recurrent deep venous thromboses and pulmonary emboli that had occurred even while on oral anticoagulation. Inferior vena cava (IVC) filters had twice been placed many years prior; anticoagulation had been subsequently discontinued. Additionally, she was known to have chronic superior vena cava (SVC) occlusion, presumably related to hypercoagulability. Previous evaluation had identified only hyperhomocysteinemia as a risk factor for recurrent thromboses. Other medical problems included hemorrhoids, gastroesophageal reflux disease, and asthma. Her only surgical history was an abdominal hysterectomy and bilateral oophorectomy many years ago for nonmalignant disease. Home medications were omeprazole, ranitidine, albuterol, and fluticasone‐salmeterol. She denied using nonsteroidal anti‐inflammatory drugs, aspirin, or any dietary supplements. She denied smoking, alcohol, or recreational drug use.

Because melena is confirmed, an upper GI tract bleeding source is most likely. The more recent appearance of bright red blood is concerning for acceleration of bleeding, or may point to a distal small bowel or right colonic source. Given the history of thromboembolic disease and likely underlying hypercoagulability, vascular occlusion is a leading possibility. Thus, mesenteric arterial insufficiency or mesenteric venous thrombosis should be considered, even though the patient does not report the characteristic postprandial exacerbation of pain. Ischemic colitis due to arterial insufficiency typically presents with severe, acute pain, with or without hematochezia. This syndrome is typically manifested in vascular watershed areas such as the splenic flexure, but can also affect the right colon. Mesenteric venous thrombosis is a rare condition that most often occurs in patients with hypercoagulability. Patients present with variable degrees of abdominal pain and often with GI bleeding. Finally, portal venous thrombosis may be seen alongside thromboses of other mesenteric veins or may occur independently. Portal hypertension due to portal vein thrombosis can result in esophageal and/or gastric varices. Although variceal bleeding classically presents with dramatic hematemesis, the absence of hematemesis does not rule out a variceal bleed in this patient.

On physical examination, the patient had a temperature of 37.1C with a pulse of 90 beats per minute and blood pressure of 161/97 mm Hg. Orthostatics were not performed. No blood was seen on nasal and oropharyngeal exam. Respiratory and cardiovascular exams were normal. On abdominal exam, there was tenderness to palpation of the right upper quadrant without rebound or guarding. The spleen and the liver were not palpable. There was a lower midline incisional scar. Rectal exam revealed nonbleeding hemorrhoids and heme‐positive stool without gross blood. Bilateral lower extremities had trace pitting edema, hyperpigmentation, and superficial venous varicosities. On skin exam, there were distended subcutaneous veins radiating outward from around the umbilicus as well as prominent subcutaneous venous collaterals over the chest and lateral abdomen.

The collateral veins over the chest and lateral abdomen are consistent with central venous obstruction from the patient's known SVC thrombus. However, the presence of paraumbilical venous collaterals (caput medusa) is highly suggestive of portal hypertension. This evidence, in addition to the known central venous occlusion and history of thromboembolic disease, raises the suspicion for mesenteric thrombosis as a cause of her bleeding and pain. The first diagnostic procedure should be an esophagogastroduodenoscopy (EGD) to identify and potentially treat the source of bleeding, whether it is portal hypertension related (portal gastropathy, variceal bleed) or from a more common cause (peptic ulcer disease, stress gastritis). If the EGD is not diagnostic, the next step should be to obtain computed tomography (CT) of the abdomen and pelvis with intravenous (IV) and oral contrast. In many patients with GI bleed, a colonoscopy would typically be performed as the next diagnostic study after EGD. However, in this patient, a CT scan is likely to be of higher yield because it could help assess the mesenteric and portal vessels for patency and characterize the appearance of the small intestine and colon. Depending on the findings of the CT, additional dedicated vascular diagnostics might be needed.

Hemoglobin was 8.5 g/dL (12.4 g/dL 6 weeks prior) with a normal mean corpuscular volume and red cell distribution. The white cell count was normal, and the platelet count was 142,000/mm3. The blood urea nitrogen was 27 mg/dL, with a creatinine of 1.1 mg/dL. Routine chemistries, liver enzymes, bilirubin, and coagulation parameters were normal. Ferritin was 15 ng/mL (normal: 15200 ng/mL).

The patient was admitted to the intensive care unit. An EGD revealed a hiatal hernia and grade II nonbleeding esophageal varices with normal=appearing stomach and duodenum. The varices did not have stigmata of a recent bleed and were not ligated. The patient continued to bleed and received 2 U of packed red blood cells (RBCs), as her hemoglobin had decreased to 7.3 g/dL. On hospital day 3, a colonoscopy was done that showed blood clots in the ascending colon but was otherwise normal. The patient had ongoing abdominal pain, melena, and hematochezia, and continued to require blood transfusions every other day.

Esophageal varices were confirmed on EGD. However, no high‐risk stigmata were seen. Findings that suggest either recent bleeding or are risk factors for subsequent bleeding include large size of the varices, nipple sign referring to a protruding vessel from an underlying varix, or red wale sign, referring to a longitudinal red streak on a varix. The lack of evidence for an esophageal, gastric, or duodenal bleeding source correlates with lack of clinical signs of upper GI tract hemorrhage such as hematemesis or coffee ground emesis. Because the colonoscopy also did not identify a bleeding source, the bleeding remains unexplained. The absence of significant abnormalities in liver function or liver inflammation labs suggests that the patient does not have advanced cirrhosis and supports the suspicion of a vascular cause of the portal hypertension. At this point, it would be most useful to obtain a CT scan of the abdomen and pelvis.

The patient continued to bleed, requiring a total of 7 U of packed RBCs over 7 days. On hospital day 4, a repeat EGD showed nonbleeding varices with a red wale sign that were banded. Despite this, the hemoglobin continued to drop. A technetium‐tagged RBC study showed a small area of subumbilical activity, which appeared to indicate transverse colonic or small bowel bleeding (Figure 1). A subsequent mesenteric angiogram failed to show active bleeding.

Figure 1
Tagged red blood cell (RBC) scan. A focus of activity is centrally located in the lower half of the midabdomen below the umbilicus (white solid arrow) at 5 minutes following the intravenous administration of 27.4 mCi of Tc‐99m–labeled RBCs that fades over time. There are prominent vascular patterns around and within the abdomen (black dotted arrow).

A red wale sign confers a higher risk of bleeding from esophageal varices. However, this finding can be subjective, and the endoscopist must individualize the decision for banding based on the size and appearance of the varices. It was reasonable to proceed with banding this time because the varices were large, had a red wale sign, and there was otherwise unexplained ongoing bleeding. Because her hemoglobin continued to drop after the banding and a tagged RBC study best localized the bleeding to the small intestine or transverse colon, it is unlikely that the varices are the primary source of bleeding. It is not surprising that the mesenteric angiogram did not show a source of bleeding, because this study requires active bleeding at a sufficient rate to radiographically identify the source.

The leading diagnosis remains an as yet uncharacterized small bowel bleeding source related to mesenteric thrombotic disease. Cross‐sectional imaging with IV contrast to identify significant vascular occlusion should be the next diagnostic step. Capsule endoscopy would be a more expensive and time‐consuming option, and although this could reveal the source of bleeding, it might not characterize the underlying vascular nature of the problem.

Due to persistent abdominal pain, a CT without intravenous contrast was done on hospital day 10. This showed extensive collateral vessels along the chest and abdominal wall with a distended azygos vein. The study was otherwise unrevealing. Her bloody stools cleared, so she was discharged with a plan for capsule endoscopy and outpatient follow‐up with her gastroenterologist. On the day of discharge (hospital day 11), hemoglobin was 7.5 g/dL and she received an eighth unit of packed RBCs. Overt bleeding was absent.

As an outpatient, intermittent hematochezia and melena recurred. The capsule endoscopy showed active bleeding approximately 45 minutes after the capsule exited the stomach. The lesion was not precisely located or characterized, but was believed to be in the distal small bowel.

The capsule finding supports the growing body of evidence implicating a small bowel source of bleeding. Furthermore, the ongoing but slow rate of blood loss makes a venous bleed more likely than an arterial bleed. A CT scan was performed prior to capsule study, but this was done without intravenous contrast. The brief description of the CT findings emphasizes the subcutaneous venous changes; a contraindication to IV contrast is not mentioned. Certainly IV contrast would have been very helpful to characterize the mesenteric arterial and venous vasculature. If there is no contraindication, a repeat CT scan with IV contrast should be performed. If there is a contraindication to IV contrast, it would be beneficial to revisit the noncontrast study with the specific purpose of searching for clues suggesting mesenteric or portal thrombosis. If the source still remains unclear, the next steps should be to perform push enteroscopy to assess the small intestine from the luminal side and magnetic resonance angiogram with venous phase imaging (or CT venogram if there is no contraindication to contrast) to evaluate the venous circulation.

The patient was readmitted 9 days after discharge with persistent melena and hematochezia. Her hemoglobin was 7.2 g/dL. Given the lack of a diagnosis, the patient was transferred to a tertiary care hospital, where a second colonoscopy and mesenteric angiogram were negative for bleeding. Small bowel enteroscopy showed no source of bleeding up to 60 cm past the pylorus. A third colonoscopy was performed due to recurrent bleeding; this showed a large amount of dark blood and clots throughout the entire colon including the cecum (Figure 2). After copious irrigation, the underlying mucosa was seen to be normal. At this point, a CT angiogram with both venous and arterial phases was done due to the high suspicion for a distal jejunal bleeding source. The CT angiogram showed numerous venous collaterals encasing a loop of midsmall bowel demonstrating progressive submucosal venous enhancement. In addition, a venous collateral ran down the right side of the sternum to the infraumbilical area and drained through the encasing collaterals into the portal venous system (Figure 3). The CT scan also revealed IVC obstruction below the distal IVC filter and an enlarged portal vein measuring 18 mm (normal <12 mm).

Figure 2
Third colonoscopy showing a large amount of dark red blood and clots through the entire colon, including the cecum (left pane), which after copious irrigation revealed normal‐appearing underlying mucosa (right pane).
Figure 3
Computed tomography with intravenous contrast, venous phase. There are prominent venous collaterals (white solid arrow) encasing a loop of small bowel, showing submucosal venous enhancement in axial (left pane) and sagittal view (center pane). There are extensive collaterals along the anterior abdominal wall that drains blood from the intrathoracic veins into the inferior vena cava (right pane, grey arrow), some of which drains into the collaterals encasing the loop of small bowel.

The CT angiogram provides much‐needed clarity. The continued bleeding is likely due to ectopic varices in the small bowel. The venous phase of the CT angiogram shows thrombosis of key venous structures and evidence of a dilated portal vein (indicating portal hypertension) leading to ectopic varices in the abdominal wall and jejunum. Given the prior studies that suggest a small bowel source of bleeding, jejunal varices are the most likely cause of recurrent GI bleeding in this patient.

The patient underwent exploratory laparotomy. Loops of small bowel were found to be adherent to the hysterectomy scar. There were many venous collaterals from the abdominal wall to these loops of bowel, dilating the veins both in intestinal walls and those in the adjacent mesentery. After clamping these veins, the small bowel was detached from the abdominal wall. On unclamping, the collaterals bled with a high venous pressure. Because these systemic‐portal shunts were responsible for the bleeding, the collaterals were sutured, stopping the bleeding. Thus, partial small bowel resection was not necessary. Postoperatively, her bleeding resolved completely and she maintained normal hemoglobin at 1‐year follow‐up.

COMMENTARY

The axiom common ailments are encountered most frequently underpins the classical stepwise approach to GI bleeding. First, a focused history helps localize the source of bleeding to the upper or lower GI tract. Next, endoscopy is performed to identify and treat the cause of bleeding. Finally, advanced tests such as angiography and capsule endoscopy are performed if needed. For this patient, following the usual algorithm failed to make the diagnosis or stop the bleeding. Despite historical and examination features suggesting that her case fell outside of the common patterns of GI bleeding, this patient underwent 3 upper endoscopies, 3 colonoscopies, a capsule endoscopy, a technetium‐tagged RBC study, 2 mesenteric angiograms, and a noncontrast CT scan before the study that was ultimately diagnostic was performed. The clinicians caring for this patient struggled to incorporate the atypical features of her history and presentation and failed to take an earlier detour from the usual algorithm. Instead, the same studies that had not previously led to the diagnosis were repeated multiple times.

Ectopic varices are enlarged portosystemic venous collaterals located anywhere outside the gastroesophageal region.[1] They occur in the setting of portal hypertension, surgical procedures involving abdominal viscera and vasculature, and venous occlusion. Ectopic varices account for 4% to 5% of all variceal bleeding episodes.[1] The most common sites include the anorectal junction (44%), duodenum (17%33%), jejunum/emleum (5%17%), colon (3.5%14%), and sites of previous abdominal surgery.[2, 3] Ectopic varices can cause either luminal or extraluminal (i.e., peritoneal) bleeding.[3] Luminal bleeding, seen in this case, is caused by venous protrusion into the submucosa. Ectopic varices present as a slow venous ooze, which explains this patient's ongoing requirement for recurrent blood transfusions.[4]

In this patient, submucosal ectopic varices developed as a result of a combination of known risk factors: portal hypertension in the setting of chronic venous occlusion from her hypercoagulability and a history of abdominal surgery (hysterectomy). [5] The apposition of her abdominal wall structures (drained by the systemic veins) to the bowel (drained by the portal veins) resulted in adhesion formation, detour of venous flow, collateralization, and submucosal varix formation.[1, 2, 6]

The key diagnostic study for this patient was a CT angiogram, with both arterial and venous phases. The prior 2 mesenteric angiograms had been limited to the arterial phase, which had missed identifying the venous abnormalities altogether. This highlights an important lesson from this case: contrast‐enhanced CT may have a higher yield in diagnosing ectopic varices compared to repeated endoscopiesespecially when captured in the late venous phaseand should strongly be considered for unexplained bleeding in patients with stigmata of liver disease or portal hypertension.[7, 8] Another clue for ectopic varices in a bleeding patient are nonbleeding esophageal or gastric varices, as was the case in this patient.[9]

The initial management of ectopic varices is similar to bleeding secondary to esophageal varices.[1] Definitive treatment includes endoscopic embolization or ligation, interventional radiological procedures such as portosystemic shunting or percutaneous embolization, and exploratory laparotomy to either resect the segment of bowel that is the source of bleeding or to decompress the collaterals surgically.[9] Although endoscopic ligation has been shown to have a lower rebleeding rate and mortality compared to endoscopic injection sclerotherapy in patients with esophageal varices, the data are too sparse in jejunal varices to recommend 1 treatment over another. Both have been used successfully either alone or in combination with each other, and can be useful alternatives for patients who are unable to undergo laparotomy.[9]

Diagnostic errors due to cognitive biases can be avoided by following diagnostic algorithms. However, over‐reliance on algorithms can result in vertical line failure, a form of cognitive bias in which the clinician subconsciously adheres to an inflexible diagnostic approach.[10] To overcome this bias, clinicians need to think laterally and consider alternative diagnoses when algorithms do not lead to expected outcomes. This case highlights the challenges of knowing when to break free of conventional approaches and the rewards of taking a well‐chosen detour that leads to the diagnosis.

KEY POINTS

  1. Recurrent, occult gastrointestinal bleeding should raise concern for a small bowel source, and clinicians may need to take a detour away from the usual workup to arrive at a diagnosis.
  2. CT angiography of the abdomen and pelvis may miss venous sources of bleeding, unless a venous phase is specifically requested.
  3. Ectopic varices can occur in patients with portal hypertension who have had a history of abdominal surgery; these patients can develop venous collaterals for decompression into the systemic circulation through the abdominal wall.

Disclosure

Nothing to report.

A 60‐year‐old woman presented to a community hospital's emergency department with 4 days of right‐sided abdominal pain and multiple episodes of black stools. She reported nausea without vomiting. She denied light‐headedness, chest pain, or shortness of breath. She also denied difficulty in swallowing, weight loss, jaundice, or other bleeding.

The first priority when assessing a patient with gastrointestinal (GI) bleeding is to ensure hemodynamic stability. Next, it is important to carefully characterize the stools to help narrow the differential diagnosis. As blood is a cathartic, frequent, loose, and black stools suggest vigorous bleeding. It is essential to establish that the stools are actually black, as some patients will mistake dark brown stools for melena. Using a visual aid like a black pen or shoes as a point of reference can help the patient differentiate between dark stool and melena. It is also important to obtain a thorough medication history because iron supplements or bismuth‐containing remedies can turn stool black. The use of any antiplatelet agents or anticoagulants should also be noted. The right‐sided abdominal pain should be characterized by establishing the frequency, severity, and association with eating, movement, and position. For this patient's presentation, increased pain with eating would rapidly heighten concern for mesenteric ischemia.

The patient reported having 1 to 2 semiformed, tarry, black bowel movements per day. The night prior to admission she had passed some bright red blood along with the melena. The abdominal pain had increased gradually over 4 days, was dull, constant, did not radiate, and there were no evident aggravating or relieving factors. She rated the pain as 4 out of 10 in intensity, worst in her right upper quadrant.

Her past medical history was notable for recurrent deep venous thromboses and pulmonary emboli that had occurred even while on oral anticoagulation. Inferior vena cava (IVC) filters had twice been placed many years prior; anticoagulation had been subsequently discontinued. Additionally, she was known to have chronic superior vena cava (SVC) occlusion, presumably related to hypercoagulability. Previous evaluation had identified only hyperhomocysteinemia as a risk factor for recurrent thromboses. Other medical problems included hemorrhoids, gastroesophageal reflux disease, and asthma. Her only surgical history was an abdominal hysterectomy and bilateral oophorectomy many years ago for nonmalignant disease. Home medications were omeprazole, ranitidine, albuterol, and fluticasone‐salmeterol. She denied using nonsteroidal anti‐inflammatory drugs, aspirin, or any dietary supplements. She denied smoking, alcohol, or recreational drug use.

Because melena is confirmed, an upper GI tract bleeding source is most likely. The more recent appearance of bright red blood is concerning for acceleration of bleeding, or may point to a distal small bowel or right colonic source. Given the history of thromboembolic disease and likely underlying hypercoagulability, vascular occlusion is a leading possibility. Thus, mesenteric arterial insufficiency or mesenteric venous thrombosis should be considered, even though the patient does not report the characteristic postprandial exacerbation of pain. Ischemic colitis due to arterial insufficiency typically presents with severe, acute pain, with or without hematochezia. This syndrome is typically manifested in vascular watershed areas such as the splenic flexure, but can also affect the right colon. Mesenteric venous thrombosis is a rare condition that most often occurs in patients with hypercoagulability. Patients present with variable degrees of abdominal pain and often with GI bleeding. Finally, portal venous thrombosis may be seen alongside thromboses of other mesenteric veins or may occur independently. Portal hypertension due to portal vein thrombosis can result in esophageal and/or gastric varices. Although variceal bleeding classically presents with dramatic hematemesis, the absence of hematemesis does not rule out a variceal bleed in this patient.

On physical examination, the patient had a temperature of 37.1C with a pulse of 90 beats per minute and blood pressure of 161/97 mm Hg. Orthostatics were not performed. No blood was seen on nasal and oropharyngeal exam. Respiratory and cardiovascular exams were normal. On abdominal exam, there was tenderness to palpation of the right upper quadrant without rebound or guarding. The spleen and the liver were not palpable. There was a lower midline incisional scar. Rectal exam revealed nonbleeding hemorrhoids and heme‐positive stool without gross blood. Bilateral lower extremities had trace pitting edema, hyperpigmentation, and superficial venous varicosities. On skin exam, there were distended subcutaneous veins radiating outward from around the umbilicus as well as prominent subcutaneous venous collaterals over the chest and lateral abdomen.

The collateral veins over the chest and lateral abdomen are consistent with central venous obstruction from the patient's known SVC thrombus. However, the presence of paraumbilical venous collaterals (caput medusa) is highly suggestive of portal hypertension. This evidence, in addition to the known central venous occlusion and history of thromboembolic disease, raises the suspicion for mesenteric thrombosis as a cause of her bleeding and pain. The first diagnostic procedure should be an esophagogastroduodenoscopy (EGD) to identify and potentially treat the source of bleeding, whether it is portal hypertension related (portal gastropathy, variceal bleed) or from a more common cause (peptic ulcer disease, stress gastritis). If the EGD is not diagnostic, the next step should be to obtain computed tomography (CT) of the abdomen and pelvis with intravenous (IV) and oral contrast. In many patients with GI bleed, a colonoscopy would typically be performed as the next diagnostic study after EGD. However, in this patient, a CT scan is likely to be of higher yield because it could help assess the mesenteric and portal vessels for patency and characterize the appearance of the small intestine and colon. Depending on the findings of the CT, additional dedicated vascular diagnostics might be needed.

Hemoglobin was 8.5 g/dL (12.4 g/dL 6 weeks prior) with a normal mean corpuscular volume and red cell distribution. The white cell count was normal, and the platelet count was 142,000/mm3. The blood urea nitrogen was 27 mg/dL, with a creatinine of 1.1 mg/dL. Routine chemistries, liver enzymes, bilirubin, and coagulation parameters were normal. Ferritin was 15 ng/mL (normal: 15200 ng/mL).

The patient was admitted to the intensive care unit. An EGD revealed a hiatal hernia and grade II nonbleeding esophageal varices with normal=appearing stomach and duodenum. The varices did not have stigmata of a recent bleed and were not ligated. The patient continued to bleed and received 2 U of packed red blood cells (RBCs), as her hemoglobin had decreased to 7.3 g/dL. On hospital day 3, a colonoscopy was done that showed blood clots in the ascending colon but was otherwise normal. The patient had ongoing abdominal pain, melena, and hematochezia, and continued to require blood transfusions every other day.

Esophageal varices were confirmed on EGD. However, no high‐risk stigmata were seen. Findings that suggest either recent bleeding or are risk factors for subsequent bleeding include large size of the varices, nipple sign referring to a protruding vessel from an underlying varix, or red wale sign, referring to a longitudinal red streak on a varix. The lack of evidence for an esophageal, gastric, or duodenal bleeding source correlates with lack of clinical signs of upper GI tract hemorrhage such as hematemesis or coffee ground emesis. Because the colonoscopy also did not identify a bleeding source, the bleeding remains unexplained. The absence of significant abnormalities in liver function or liver inflammation labs suggests that the patient does not have advanced cirrhosis and supports the suspicion of a vascular cause of the portal hypertension. At this point, it would be most useful to obtain a CT scan of the abdomen and pelvis.

The patient continued to bleed, requiring a total of 7 U of packed RBCs over 7 days. On hospital day 4, a repeat EGD showed nonbleeding varices with a red wale sign that were banded. Despite this, the hemoglobin continued to drop. A technetium‐tagged RBC study showed a small area of subumbilical activity, which appeared to indicate transverse colonic or small bowel bleeding (Figure 1). A subsequent mesenteric angiogram failed to show active bleeding.

Figure 1
Tagged red blood cell (RBC) scan. A focus of activity is centrally located in the lower half of the midabdomen below the umbilicus (white solid arrow) at 5 minutes following the intravenous administration of 27.4 mCi of Tc‐99m–labeled RBCs that fades over time. There are prominent vascular patterns around and within the abdomen (black dotted arrow).

A red wale sign confers a higher risk of bleeding from esophageal varices. However, this finding can be subjective, and the endoscopist must individualize the decision for banding based on the size and appearance of the varices. It was reasonable to proceed with banding this time because the varices were large, had a red wale sign, and there was otherwise unexplained ongoing bleeding. Because her hemoglobin continued to drop after the banding and a tagged RBC study best localized the bleeding to the small intestine or transverse colon, it is unlikely that the varices are the primary source of bleeding. It is not surprising that the mesenteric angiogram did not show a source of bleeding, because this study requires active bleeding at a sufficient rate to radiographically identify the source.

The leading diagnosis remains an as yet uncharacterized small bowel bleeding source related to mesenteric thrombotic disease. Cross‐sectional imaging with IV contrast to identify significant vascular occlusion should be the next diagnostic step. Capsule endoscopy would be a more expensive and time‐consuming option, and although this could reveal the source of bleeding, it might not characterize the underlying vascular nature of the problem.

Due to persistent abdominal pain, a CT without intravenous contrast was done on hospital day 10. This showed extensive collateral vessels along the chest and abdominal wall with a distended azygos vein. The study was otherwise unrevealing. Her bloody stools cleared, so she was discharged with a plan for capsule endoscopy and outpatient follow‐up with her gastroenterologist. On the day of discharge (hospital day 11), hemoglobin was 7.5 g/dL and she received an eighth unit of packed RBCs. Overt bleeding was absent.

As an outpatient, intermittent hematochezia and melena recurred. The capsule endoscopy showed active bleeding approximately 45 minutes after the capsule exited the stomach. The lesion was not precisely located or characterized, but was believed to be in the distal small bowel.

The capsule finding supports the growing body of evidence implicating a small bowel source of bleeding. Furthermore, the ongoing but slow rate of blood loss makes a venous bleed more likely than an arterial bleed. A CT scan was performed prior to capsule study, but this was done without intravenous contrast. The brief description of the CT findings emphasizes the subcutaneous venous changes; a contraindication to IV contrast is not mentioned. Certainly IV contrast would have been very helpful to characterize the mesenteric arterial and venous vasculature. If there is no contraindication, a repeat CT scan with IV contrast should be performed. If there is a contraindication to IV contrast, it would be beneficial to revisit the noncontrast study with the specific purpose of searching for clues suggesting mesenteric or portal thrombosis. If the source still remains unclear, the next steps should be to perform push enteroscopy to assess the small intestine from the luminal side and magnetic resonance angiogram with venous phase imaging (or CT venogram if there is no contraindication to contrast) to evaluate the venous circulation.

The patient was readmitted 9 days after discharge with persistent melena and hematochezia. Her hemoglobin was 7.2 g/dL. Given the lack of a diagnosis, the patient was transferred to a tertiary care hospital, where a second colonoscopy and mesenteric angiogram were negative for bleeding. Small bowel enteroscopy showed no source of bleeding up to 60 cm past the pylorus. A third colonoscopy was performed due to recurrent bleeding; this showed a large amount of dark blood and clots throughout the entire colon including the cecum (Figure 2). After copious irrigation, the underlying mucosa was seen to be normal. At this point, a CT angiogram with both venous and arterial phases was done due to the high suspicion for a distal jejunal bleeding source. The CT angiogram showed numerous venous collaterals encasing a loop of midsmall bowel demonstrating progressive submucosal venous enhancement. In addition, a venous collateral ran down the right side of the sternum to the infraumbilical area and drained through the encasing collaterals into the portal venous system (Figure 3). The CT scan also revealed IVC obstruction below the distal IVC filter and an enlarged portal vein measuring 18 mm (normal <12 mm).

Figure 2
Third colonoscopy showing a large amount of dark red blood and clots through the entire colon, including the cecum (left pane), which after copious irrigation revealed normal‐appearing underlying mucosa (right pane).
Figure 3
Computed tomography with intravenous contrast, venous phase. There are prominent venous collaterals (white solid arrow) encasing a loop of small bowel, showing submucosal venous enhancement in axial (left pane) and sagittal view (center pane). There are extensive collaterals along the anterior abdominal wall that drains blood from the intrathoracic veins into the inferior vena cava (right pane, grey arrow), some of which drains into the collaterals encasing the loop of small bowel.

The CT angiogram provides much‐needed clarity. The continued bleeding is likely due to ectopic varices in the small bowel. The venous phase of the CT angiogram shows thrombosis of key venous structures and evidence of a dilated portal vein (indicating portal hypertension) leading to ectopic varices in the abdominal wall and jejunum. Given the prior studies that suggest a small bowel source of bleeding, jejunal varices are the most likely cause of recurrent GI bleeding in this patient.

The patient underwent exploratory laparotomy. Loops of small bowel were found to be adherent to the hysterectomy scar. There were many venous collaterals from the abdominal wall to these loops of bowel, dilating the veins both in intestinal walls and those in the adjacent mesentery. After clamping these veins, the small bowel was detached from the abdominal wall. On unclamping, the collaterals bled with a high venous pressure. Because these systemic‐portal shunts were responsible for the bleeding, the collaterals were sutured, stopping the bleeding. Thus, partial small bowel resection was not necessary. Postoperatively, her bleeding resolved completely and she maintained normal hemoglobin at 1‐year follow‐up.

COMMENTARY

The axiom common ailments are encountered most frequently underpins the classical stepwise approach to GI bleeding. First, a focused history helps localize the source of bleeding to the upper or lower GI tract. Next, endoscopy is performed to identify and treat the cause of bleeding. Finally, advanced tests such as angiography and capsule endoscopy are performed if needed. For this patient, following the usual algorithm failed to make the diagnosis or stop the bleeding. Despite historical and examination features suggesting that her case fell outside of the common patterns of GI bleeding, this patient underwent 3 upper endoscopies, 3 colonoscopies, a capsule endoscopy, a technetium‐tagged RBC study, 2 mesenteric angiograms, and a noncontrast CT scan before the study that was ultimately diagnostic was performed. The clinicians caring for this patient struggled to incorporate the atypical features of her history and presentation and failed to take an earlier detour from the usual algorithm. Instead, the same studies that had not previously led to the diagnosis were repeated multiple times.

Ectopic varices are enlarged portosystemic venous collaterals located anywhere outside the gastroesophageal region.[1] They occur in the setting of portal hypertension, surgical procedures involving abdominal viscera and vasculature, and venous occlusion. Ectopic varices account for 4% to 5% of all variceal bleeding episodes.[1] The most common sites include the anorectal junction (44%), duodenum (17%33%), jejunum/emleum (5%17%), colon (3.5%14%), and sites of previous abdominal surgery.[2, 3] Ectopic varices can cause either luminal or extraluminal (i.e., peritoneal) bleeding.[3] Luminal bleeding, seen in this case, is caused by venous protrusion into the submucosa. Ectopic varices present as a slow venous ooze, which explains this patient's ongoing requirement for recurrent blood transfusions.[4]

In this patient, submucosal ectopic varices developed as a result of a combination of known risk factors: portal hypertension in the setting of chronic venous occlusion from her hypercoagulability and a history of abdominal surgery (hysterectomy). [5] The apposition of her abdominal wall structures (drained by the systemic veins) to the bowel (drained by the portal veins) resulted in adhesion formation, detour of venous flow, collateralization, and submucosal varix formation.[1, 2, 6]

The key diagnostic study for this patient was a CT angiogram, with both arterial and venous phases. The prior 2 mesenteric angiograms had been limited to the arterial phase, which had missed identifying the venous abnormalities altogether. This highlights an important lesson from this case: contrast‐enhanced CT may have a higher yield in diagnosing ectopic varices compared to repeated endoscopiesespecially when captured in the late venous phaseand should strongly be considered for unexplained bleeding in patients with stigmata of liver disease or portal hypertension.[7, 8] Another clue for ectopic varices in a bleeding patient are nonbleeding esophageal or gastric varices, as was the case in this patient.[9]

The initial management of ectopic varices is similar to bleeding secondary to esophageal varices.[1] Definitive treatment includes endoscopic embolization or ligation, interventional radiological procedures such as portosystemic shunting or percutaneous embolization, and exploratory laparotomy to either resect the segment of bowel that is the source of bleeding or to decompress the collaterals surgically.[9] Although endoscopic ligation has been shown to have a lower rebleeding rate and mortality compared to endoscopic injection sclerotherapy in patients with esophageal varices, the data are too sparse in jejunal varices to recommend 1 treatment over another. Both have been used successfully either alone or in combination with each other, and can be useful alternatives for patients who are unable to undergo laparotomy.[9]

Diagnostic errors due to cognitive biases can be avoided by following diagnostic algorithms. However, over‐reliance on algorithms can result in vertical line failure, a form of cognitive bias in which the clinician subconsciously adheres to an inflexible diagnostic approach.[10] To overcome this bias, clinicians need to think laterally and consider alternative diagnoses when algorithms do not lead to expected outcomes. This case highlights the challenges of knowing when to break free of conventional approaches and the rewards of taking a well‐chosen detour that leads to the diagnosis.

KEY POINTS

  1. Recurrent, occult gastrointestinal bleeding should raise concern for a small bowel source, and clinicians may need to take a detour away from the usual workup to arrive at a diagnosis.
  2. CT angiography of the abdomen and pelvis may miss venous sources of bleeding, unless a venous phase is specifically requested.
  3. Ectopic varices can occur in patients with portal hypertension who have had a history of abdominal surgery; these patients can develop venous collaterals for decompression into the systemic circulation through the abdominal wall.

Disclosure

Nothing to report.

References
  1. Helmy A, Kahtani K, Fadda M. Updates in the pathogenesis, diagnosis and management of ectopic varices. Hepatol Int. 2008;2:322334.
  2. Norton ID, Andrews JC, Kamath PS. Management of ectopic varices. Hepatology. 1998;28:11541158.
  3. Watanabe N, Toyonaga A, Kojima S, et al. Current status of ectopic varices in Japan: results of a survey by the Japan Society for Portal Hypertension. Hepatol Res. 2010;40:763766.
  4. Saad WE, Saad NE, Koizumi J. Stomal Varices: Management with decompression TIPS and transvenous obliteration or sclerosis. Tech Vasc Interv Radiol. 2013;16:126134.
  5. Yuki N, Kubo M, Noro Y, et al. Jejunal varices as a cause of massive gastrointestinal bleeding. Am J Gastroenterol. 1992;87:514517.
  6. Lebrec D, Benhamou JP. Ectopic varices in portal hypertension. Clin Gastroenterol. 1985;14:105121.
  7. Etik D, Oztas E, Okten S, et al. Ectopic varices in portal hypertension: computed tomographic angiography instead of repeated endoscopies for diagnosis. Eur J Gastroenterol Hepatol. 2011;23:620622.
  8. Darcy MD, Ray CE, Lorenz JM, et al. ACR appropriateness criteria. Radiologic management of lower gastrointestinal tract bleeding. Reston, VA: American College of Radiology; 2011. Available at: http://www.acr.org/Quality‐Safety/Appropriateness‐Criteria/∼/media/5F9CB95C164E4DA19DCBCFBBA790BB3C.pdf. Accessed January 28, 2015.
  9. Akhter NM, Haskal ZJ. Diagnosis and management of ectopic varices. Gastrointest Interv. 2012;1:310.
  10. Croskerry P. Achieving quality in clinical decision making: cognitive strategies and detection of bias. Acad Emerg Med. 2002;9:11841204.
References
  1. Helmy A, Kahtani K, Fadda M. Updates in the pathogenesis, diagnosis and management of ectopic varices. Hepatol Int. 2008;2:322334.
  2. Norton ID, Andrews JC, Kamath PS. Management of ectopic varices. Hepatology. 1998;28:11541158.
  3. Watanabe N, Toyonaga A, Kojima S, et al. Current status of ectopic varices in Japan: results of a survey by the Japan Society for Portal Hypertension. Hepatol Res. 2010;40:763766.
  4. Saad WE, Saad NE, Koizumi J. Stomal Varices: Management with decompression TIPS and transvenous obliteration or sclerosis. Tech Vasc Interv Radiol. 2013;16:126134.
  5. Yuki N, Kubo M, Noro Y, et al. Jejunal varices as a cause of massive gastrointestinal bleeding. Am J Gastroenterol. 1992;87:514517.
  6. Lebrec D, Benhamou JP. Ectopic varices in portal hypertension. Clin Gastroenterol. 1985;14:105121.
  7. Etik D, Oztas E, Okten S, et al. Ectopic varices in portal hypertension: computed tomographic angiography instead of repeated endoscopies for diagnosis. Eur J Gastroenterol Hepatol. 2011;23:620622.
  8. Darcy MD, Ray CE, Lorenz JM, et al. ACR appropriateness criteria. Radiologic management of lower gastrointestinal tract bleeding. Reston, VA: American College of Radiology; 2011. Available at: http://www.acr.org/Quality‐Safety/Appropriateness‐Criteria/∼/media/5F9CB95C164E4DA19DCBCFBBA790BB3C.pdf. Accessed January 28, 2015.
  9. Akhter NM, Haskal ZJ. Diagnosis and management of ectopic varices. Gastrointest Interv. 2012;1:310.
  10. Croskerry P. Achieving quality in clinical decision making: cognitive strategies and detection of bias. Acad Emerg Med. 2002;9:11841204.
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Practice recommendations
  • Heartburn on 2 or more days a week warrants medical attention, as patients are likely to suffer from gastroesophageal reflux disease (GERD).Chronic GERD can lead to the development of complications including erosive esophagitis, stricture formation, and Barrett’s esophagus, which increases the risk of esophageal adenocarcinoma.
  • A trial with a proton pump inhibitor (PPI) is the quickest and most cost-effective way to diagnose GERD, and is at least as sensitive as 24-hour intraesophageal pH monitoring.
  • As PPIs only bind to actively secreting proton pumps, they should be dosed 30 to 60 minutes before a meal.Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take a PPI with or after a meal or did not specify the timing of dosing.
  • The patients who will have the best response to surgical therapy for GERD are those who had clearly documented acid reflux with typical symptoms, and who have responded to PPI treatment. Unfortunately, the same survey found that most physicians recommend antireflux surgery for patients in whom medical therapy has failed.
 

Gastroesophageal reflux disease (GERD) is a common, multifactorial condition that often results in decreased quality of life with interruptions of sleep, work, and social activities. Patients have reported that GERD affects emotional well-being to a greater degree than diabetes or hypertension.1,2 GERD is also associated with well-established complications, including Barrett’s esophagus. The role of reflux in carcinogenesis is controversial; the possibility of an association, however, implies that GERD should be treated aggressively and early.3

Symptoms of gerd

The typical symptoms of GERD are heartburn and regurgitation. Heartburn is best defined as a burning retrosternal discomfort starting in the epigastrium or lower chest and moving upwards towards the neck. Regurgitation is the effortless movement of gastric contents up into the esophagus or pharynx.

Most patients with GERD do not have endoscopically visible lesions; a careful analysis of symptoms generally forms the basis of a preliminary diagnosis.

The occurrence of heartburn on 2 or more days a week has been suggested as a basis for further investigation for GERD.4 However, symptoms vary greatly. Patients may be asymptomatic or experience symptoms that more closely resemble gastric disorders, infectious and motor disorders of the esophagus, biliary tract disease, or even coronary artery disease.

Extraesophageal manifestations

Adding to the complexity of diagnosis, GERD has been shown to have extraesophageal manifestations, including chronic cough, asthma, recurrent aspiration, chronic sore throat, reflux laryngitis, and paroxysmal laryngospasm or voice changes.

Although the relationship between asthma and GERD remains unclear, it has been estimated that 24% to 98% of patients with asthma also have GERD.5 Some patients with asthma have been shown to have excess acid reflux into the esophagus. Reflux-like symptoms may precede episodes of asthma that occur after meals or when lying down.6 8

Additionally, GERD has been noted in 10% to 50% of patients with non-cardiac chest pain.9,10

 

 

Diagnostic strategies

Trial of treatment

Diagnosis is usually based on typical symptoms—heartburn or regurgitation—in the clinical history. (The Figure shows a treatment algorithm for both severe and mild symptoms.)

A 2-week trial of treatment with a proton pump inhibitor (PPI) provides the quickest and most cost-effective confirmation of diagnosis and is recommended for the patient whose history suggests uncomplicated GERD. A positive response to PPI treatment in a patient with symptoms suggestive of GERD is at least as sensitive and specific as 24-hour intraesophageal pH monitoring, which is still often considered the “gold standard” for the diagnosis of GERD. Furthermore, complete lack of improvement in response to PPI treatment is highly predictive that the patient does not have GERD and indicates the need for further evaluation and a possible revision of diagnosis.11,12

H2 receptor antagonists (H2RAs) have also been investigated in empirical trials for usefulness in diagnosing GERD. H2RAs are less effective than PPIs.13,14

 

FIGURE Medical management of suspected GERD


Endoscopy

No data support routine endoscopy for patients with the recent onset of uncomplicated heartburn who respond to medical therapy. Endoscopy is recommended, however, for patients with severe or atypical GERD symptoms, when other diseases may be present, or when a treatment trial with a PPI is ineffective.15 Endoscopy is useful for diagnosing complications of GERD, such as Barrett’s esophagus, esophagitis, and strictures. Fewer than 50% of patients with GERD symptoms have evidence of esophagitis on endoscopy.16

The American Society for Gastrointestinal Endoscopy recommends endoscopy when there are clinical suggestions of severe reflux or other disease.17 The American College of Gastroenterology recommends further testing

  • when empiric therapy has failed
  • when symptoms of complicated disease exist
  • when there is dysphagia, bleeding, weight loss, choking, chest pain, or long-standing symptoms
  • when continuous therapy is required
  • to screen for Barrett’s esophagus.18

The Canadian Consensus Conference recommends endoscopy in the presence of

  • dysphagia
  • odynophagia
  • bleeding
  • weight loss
  • noncardiac chest pain
  • failure to respond to 4 to 8 weeks of pharmacologic therapy.19

It also recommends a single test if maintenance therapy is required.

Other diagnostic tests

Other diagnostic tools may be of use in some settings.

A barium esophagram can document reflux, and Bernstein testing (esophageal acid infusion test) can identify esophageal hypersensitivity to acid, although neither establishes a diagnosis of GERD. Ambulatory 24-hour intraesophageal pH monitoring can help to establish the presence of GERD by documenting the proportion of time during which the intraesophageal pH is acidic (<4) and can also establish the degree of association between patients’ symptoms and episodes of esophageal acidification.

Esophageal manometry is not recommended as a routine diagnostic test for GERD. It is important in selected patients to exclude an esophageal motility disorder and may be necessary as part of the pre-operative evaluation for patients in whom a surgical operation for GERD is being considered.

Management of gerd

GERD commonly requires long-term management that includes dietary, lifestyle, and pharmacological interventions. Surgery may be considered for the long-term management of the condition in carefully selected patients.

 

 

Diet and lifestyle

Dietary modifications. Patients should not consume large meals and should avoid lying down for 3 to 4 hours after eating. Caffeinated products, peppermint, fatty foods, chocolate, spicy foods, citrus fruits and juices, tomato-based products, and alcohol may contribute to episodes of GERD.18,21 Lozenges of any kind are able to stimulate salivary secretion, help clear refluxed acid, and hence, help relieve symptoms.

Lifestyle modifications. Changes in lifestyle may include such seemingly sensible interventions as sleeping with the head elevated, stopping smoking, and losing weight. There is little or no established evidence for the efficacy of these and other lifestyle modifications in the management of GERD. However, in1 trial of 63 patients, elevating the head of the bed with 6-inch blocks resulted in 1 less episode of heartburn or acid regurgitation per night when compared with lying flat.22 In another trial of 71 patients with esophagitis, elevating the bed was nearly as effective as ranitidine for reducing symptoms and producing endoscopically verifiable healing.23

Obstacles to effective GERD treatment in primary care

Arecent survey20 of 1046 primary care physicians found that:

  • 36% instructed patients to take PPIs during or after a meal or did not specify a time of dosing
  • 75% referred patients for surgical antireflux therapy and 20% referred patients directly to a surgeon without gastrointestinal consultation
  • 15% reported that a trial with a H2 receptor antagonist was required by their healthsystem or insurance company prior to using a PPI.

Drug interventions

Pharmacological interventions include over-the-counter remedies such as antacids and H2RAs (Table 1), as well as prescription-only doses of H2RAs and PPIs. At the time of writing, no PPI was available in an over-the-counter preparation in the United States, although over-the-counter omeprazole may soon be approved. Many authorities believe an incremental approach to the management of GERD is appropriate, beginning with lifestyle modifications and over-the-counter preparations, continuing with H2 blockers, and reserving PPIs for nonresponders. While this approach may have appeal from a cost perspective, we believe another approach (as illustrated in the Figure) is clinically superior.

Antacids. Over-the-counter antacids rapidly increase the pH of the intraesophageal contents and also neutralize acidic gastric contents that might be refluxed. They are frequently used to treat heartburn. However, few clinical trials have evaluated the efficacy of antacids. Published trials24-26 are limited by small sample sizes and a lack of intention-to-treat analysis. Only 1 showed positive evidence for antacid efficacy.25

The utility of antacids is limited by the need for frequent dosing and possible interactions with such drugs as fluoroquinolones, tetracycline, and ferrous sulfate.27 Alginate/antacids have shown statistically significant benefit compared with placebo for relief of mild-to-moderate GERD symptoms and healing of esophagitis.24,28-34

H 2 receptor antagonists. H2RAs have shown positive effects on symptoms in some studies, although symptomatic response rates observed were only around 60% to 70%. Additionally, most of the trials to date have been for 2 to 6 weeks in duration.35 43 An issue worthy of consideration with the H2RAs is the development of tolerance with continuous use.44

An H2RA-antacid combination was recently evaluated in a trial that compared it with monotherapy using either agent. Of the patients receiving combination therapy, 81% reported an excellent or good symptom response. Those receiving famotidine or atacid alone reported a 72% excellent or good symptom response.3

 

 

Proton pump inhibitors. PPIs potently reduce gastric acid secretion by inhibiting the H+-K+adenosine triphosphatase pump of the parietal cell. As a result, they suppress gastric acid secretion for a longer period than H2RAs.45 Evidence from randomized, controlled trials has demonstrated the superiority of PPIs over any other class of drugs for the relief of GERD symptoms, for healing esophagitis, and for maintaining patients in remission. Standard doses of omeprazole, lansoprazole, panto-prazole, esomeprazole, and rabeprazole have, for the most part, shown comparable rates of healing and remission in erosive esophagitis.46-52

PPIs are best absorbed in the absence of food. Ingestion of food after a PPI stimulates parietal cell activity when blood levels of the PPI are increasing; this promotes uptake of the PPI by the parietal cells. Therefore, patients should be advised to take their PPI between 30 and 60 minutes before eating. For patients on a once-daily PPI, the best time to take it is about 30 to 60 minutes before breakfast. Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take their PPI with or after a meal or did not specify the timing of dosing.53

Guidelines for proton pump inhibitor use in clinical practice

Clinical evidence indicates that a trial with a PPI provides the quickest and most cost-effective method for diagnosing GERD. Despite this, many physicians use a trial of H2 receptor antagonists prior to initiation of PPI therapy.

  • Clinicians should clearly instruct their patients regarding optimal timing of the dose, since this can have a significant effect on the success of therapy.
  • Patients for whom antireflux surgery is being considered should first be referred for consultation with a gastroenterologist to assist in patient selection, to ensure that appropriate preoperative evaluation has been performed and to help exclude other possible causes of their symptoms.21,54

PPI therapy can be tailored to control GERD symptoms. Treatment can start with the most effective dosage and then be stepped down, or start with a minimum dosage and then be stepped up (Table 2). Patients with predominantly daytime symptoms should take PPIs before breakfast. Concerns that were once expressed about the long-term use of PPIs, such as predisposing patients to stomach cancer, have been refuted by extensive clinical experience and intensive monitoring (Table 3).3

TABLE 1

Over-the-counter therapy for GERD

 

  • Prevention and rapid relief of symptoms
  • Reduction of frequency and severity of symptoms
  • Role in therapy
  • Limitations
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies.
Bethesda, Md.:American Gastroenterological Association;2002.

TABLE 2

Step-down and step-up treatments: advantages and disadvantages

 

RegimenAdvantagesDisadvantages
Step-down therapy (high-dose initial therapy)Rapid symptom reliefPotential overtreatment
Efficient for physicianHigher initial drug cost
Avoids overinvestigation and associated costs
Step-up therapy (minimum-dose initial therapy)Avoids overtreatmentPatient may continue with symptoms unnecessarily
Lower initial drug costInefficient for physician
May lead to overinvestigation
Uncertain end point (partial symptom relief)
Adapted from Dent J, et al. Management of gastro-oesophageal reflux disease in general practice.BMJ 2001;322:344-347.

TABLE 3

Potential concerns associated with the use of proton pump inhibitors

 

Potential concernLevel of Evidence*Grade Comments
Long-term PPI treatment may lead to reduced serum cobalamin levels2bBThis is most likely to occur in individuals with atrophic gastritis
Increased acid output has been seen after stopping a PPI2bBEffects of PPI treatment on corpus glandular atrophy in H pylori-infected individuals are difficult to interpret due to possible sampling error and short study duration
PPI treatment may predispose to bacterial enteric infection3BOnly shown in a single case control study
*Level of evidence:1, Evidence for and/or general agreement that treatment is useful and effective;1a, systematic review with homogeneity of randomized controlled trials (RCTs);1b, individual RCTs (with narrow confidence interval);2, conflicting evidence and/or divergent opinion about efficacy and use;2a, evidence or opinion is in favor of treatment;2b, use and efficacy is less well established by evidence or opinion;3, evidence and/or general agreement that treatment is not useful or effective and may be harmful in some cases.
†Quality grading:A, well-designed, clinical trials;B, well-designed cohort or case-control studies;C, case reports, flawed trials;D, personal clinical experience;E, insufficient evidence to form opinion.
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies. Bethesda, Md:American Gastroenterological Association, 2002.

Surgery

Surgical antireflux therapy is an option in carefully selected patients. Those who respond best to surgical therapy will have had clearly documented acid reflux, typical symptoms, and symptomatic improvement while on PPI treatment.54

Unfortunately, a recent survey suggests that physicians tend to recommend surgery for patients in whom medical therapy has failed.53 However, patients who failed to respond to PPI therapy are unlikely to have GERD and, therefore, are highly unlikely to have a good outcome from antireflux surgery. Recent studies suggest that up to 62% of patients who have had open surgery for GERD continue to require medical treatment afterward. Although some studies demonstrate that surgery has greater efficacy over medical therapy initially, long-term follow-up has shown that surgically treated patients often need further medical therapy for persistent GERD symptoms.55 Community-based studies of antireflux surgery indicate that many patients develop new symptoms that they did not have before surgery and that these substantially diminish quality of life.

New endoscopic therapies, including radiofrequency energy delivery to the region of the lower esophageal sphincter and endoscopic suturing, have recently been approved for use by the FDA. This approval was based largely on safety rather than efficacy data. Clinical evidence is limited to uncontrolled studies in patients with no or mild esophagitis.3 These techniques should not be used in preference to established medical treatment unless and until data from randomized, controlled trials become available that demonstrate safety and efficacy.56

References

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2. Revicki DA, Wood M, Maton PN, Sorensen S. The impact of gastroesophageal reflux disease on health-related quality of life. Am J Med 1998;104:252-8.

3. Peterson WL. GERD: Evidence-based therapeutic strategies. Bethesda, Md: American Gastroenterological Association; 2002.

4. Dent J, Jones R, Kahrilas P, Talley NJ. Management of gastro-oesophageal reflux disease in general practice. BMJ 2001;322:344-7.

5. Harding SM. Nocturnal asthma: role of gastroesophageal reflux. Chronobiol Int 1999;16:641-2.

6. Kjellen G, Wranne B. The prevalence of asymptomatic gastro-oesophageal relfux in adult patients with asthma. Eur J Respir Dis 1984;65:233.-

7. Schnatz PF, Castell JA, Castell DO. Pulmonary symptoms associated with gastroesophageal reflux: use of ambulatory pH monitoring to diagnose and to direct therapy. Am J Gastroenterol 1996;91:1715-8.

8. Sontag SJ, Schnell TG, Miller TQ, Khandelwal S, O’Connell S, Chejfec G, et al. Prevalence of oesophagitis in asthmatics. Gut 1992;33:872-6.

9. Schofield PM, Bennett DH, Whorwell PJ, Brooks NH, Bray CL, Ward C, et al. Exertional gastro-oesophageal reflux: a mechanism for symptoms in patients with angina pectoris and normal coronary angiograms. Br Med J (Clin Res Ed) 1987;294:1459-61.

10. Hewson EG, Sinclair JW, Dalton CB, Richter JE. Twenty-four-hour esophageal pH monitoring: the most useful test for evaluating noncardiac chest pain. Am J Med 1991;90:576-83.

11. Goyal RK. Diseases of the esophagus. In: Braunwald E, ed. Harrison’s principles of internal medicine. 15th ed. New York: McGraw-Hill; 2001;1642-9.

12. Schenk BE, Kuipers EJ, Klinkenberg-Knol EC, Festen HP, Jansen EH, Tuynman HA, et al. Omeprazole as a diagnostic tool in gastroesophageal reflux disease. Am J Gastroenterol 1997;92:1997-2000.

13. van Pinxteren B, Numans ME, Bonis PA, Lau J. Short-term treatment with proton pump inhibitors, H2-receptor antagonists and prokinetics for gastrooesophageal reflux disease-like symptoms and endoscopy negative reflux disease. Cochrane Database Syst Rev 2001;(4):CD002095.-

14. Brun J, Sorngard H. High dose proton pump inhibitor response as an initial strategy for a clinical diagnosis of gastro-oesophageal reflux disease (GERD).Swedish multi-centre group in primary health care. Fam Pract 2000;17:401-4.

15. Lundell L. Anti-reflux surgery in the laparoscopic era. Baillieres Best Pract Res Clin Gastroenterol 2000;14:793-810.

16. Chen MY, Ott DJ, Sinclair JW, Wu WC, Gelfand DW. Gastroesophageal reflux disease: correlation of esophageal pH testing and radiographic findings. Radiology 1992;185:483-6.

17. The role of endoscopy in the management of GERD: guidelines for clinical application. From the ASGE. American Society for Gastrointestinal Endoscopy. Gastrointest Endosc 1999;49:834-5.

18. DeVault KR, Castell DO. Updated guidelines for the diagnosis and treatment of gastroesophageal reflux disease. The Practice Parameters Committee of the American College of Gastroenterology. Am J Gastroenterol 1999;94:1434-42.

19. Beck IT, Champion MC, Lemire S, Thomson AB, Anvari M, Armstrong D, et al. The Second Canadian Consensus Conference on the Management of Patients with Gastroesophageal Reflux Disease. Can J Gastroenterol 1997;11(suppl B):7B-20B.

20. Chey WD, Inadomi JM, Booher AK, Fendrick AM. Primary care physicians’ perceptions and practices of the management of GERD: results of a national survey. Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

21. Fennerty MB, Castell D, Fendrick AM, Halpern M, Johnson D, Kahrilas PJ, et al. The diagnosis and treatment of gastroesophageal reflux disease in a managed care environment, Suggested disease management guidelines. Arch Intern Med 1996;156:477-84.

22. Stanciu C, Bennett JR. Effects of posture on gastro-oesophageal reflux. Digestion 1977;15:104-9.

23. Harvey RF, Gordon PC, Hadley N, Long DE, Gill TR, Macpherson RI, et al. Effects of sleeping with the bed-head raised and of ranitidine in patients with severe peptic oesophagitis. Lancet 1987;2:1200-3.

24. Graham DY, Patterson DJ. Double-blind comparison of liquid antacid and placebo in the treatment of symptomatic reflux esophagitis. Dig Dis Sci 1983;28:559-63.

25. Grove O, Bekker C, Jeppe-Hansen MG, Karstoft E, Sanchez G, Axelsson CK, et al. Ranitidine and high-dose antacid in reflux oesophagitis. A randomized, placebo-controlled trial. Scand J Gastroenterol 1985;20:457-61.

26. Weberg R, Berstad A. Symptomatic effect of a low-dose antacid regimen in reflux oesophagitis. Scand J Gastroenterol 1989;24:401-6.

27. Welage LS, Berardi RR. Evaluation of omeprazole, lansoprazole, pantopra-zole, and rabeprazole in the treatment of acid-related diseases. J Am Pharm Assoc (Wash) 2000;40:52-62.

28. Barnardo DE, Lancaster-Smith M, Strickland ID, Wright JT. A double-blind controlled trial of ‘Gaviscon’ in patients with symptomatic gastro-oesophageal reflux. Curr Med Res Opin 1975;3:388-91.

29. Beeley M, Warner JO. Medical treatment of symptomatic hiatus hernia with low-density compounds. Curr Med Res Opin 1972;1:63-9.

30. Chevrel B. A comparative crossover study on the treatment of heartburn and epigastric pain: liquid Gaviscon and a magnesium-aluminium antacid gel. J Int Med Res. 1980;8:300-2.

31. Laitinen S, Stahlberg M, Kairaluoma MI, Kiviniemi H, Paakkonen M, Lahtinen J, et al. Sucralfate and algi-nate/antacid in reflux esophagitis. Scand J Gastroenterol 1985;20:229-32.

32. Lanza FL, Smith V, Page-Castell JA, Castell DO. Effectiveness of foaming antacid in relieving induced heartburn. South Med J 1986;79:327-30.

33. McHardy G. A multicentric, randomized clinical trial of Gaviscon in reflux esophagitis. South Med J 1978;71(suppl 1):16-21.

34. Stanciu C, Bennett JR. Alginate-antacid in the reduction of gastro-oesophageal reflux. Lancet 1974;1:109-11.

35. Paul K, Redman CM, Chen M. Effectiveness and safety of nizatidine, 75 mg, for the relief of episodic heartburn. Aliment Pharmacol Ther 2001;15:1571-7.

36. Spiegel JE, Thoden WR, Pappas K, Fratarcangelo P, Furey SA. A double-blind, placebo-controlled study of the effectiveness and safety of nizatidine in the prevention of postprandial heartburn. Arch Intern Med 1997;157:1594-9.

37. Pappa KA, Buaron K, Payne JE, Sirgo MA, Giefer EE. An evaluation of increasing doses of ranitidine for treatment of heartburn. Aliment Pharmacol Ther 1999;13:475-81.

38. Pappa KA, Gooch WM, Buaron K, Payne JE, Giefer EE, Sirgo MA, et al. Low-dose ranitidine for the relief of heartburn. Aliment Pharmacol Ther 1999;13:459-65.

39. Pappa KA, Williams BO, Payne JE, Buaron KS, Mussari KL, Ciociola AA. A double-blind, placebo-controlled study of the efficacy and safety of non-pre-scription ranitidine 75 mg in the prevention of meal-induced heartburn. Aliment Pharmacol Ther 1999;13:467-73.

40. Ciociola AA, Pappa KA, Sirgo MA. Nonprescription doses of ranitidine are effective in the relief of episodic heartburn. Am J Ther 2001;8:399-408.

41. Gottlieb S, Decktor DL, Eckert JM, Simon TJ, Stauffer L, Ciccone PE. Efficacy and tolerability of famotidine in preventing heartburn and related symptoms of upper gastrointestinal discomfort. Am J Ther 1995;2:314-9.

42. Simon TJ, Berlin RG, Gardner AH, Stauffer LA, Gould AL, Getson AJ. Self-directed treatment of intermittent heartburn: a randomized, multicenter, double-blind, placebo-controlled evaluation of antacid and low doses of an H(2)-receptor antagonist (famotidine). Am J Ther 1995;2:304-13.

43. Galmiche JP, Shi G, Simon B, Casset-Semanza F, Slama A. On-demand treatment of gastro-oesophageal reflux symptoms: a comparison of ranitidine 75 mg with cimetidine 200 mg or place-bo. Aliment Pharmacol Ther 1998;12:909-17.

44. Qvigstad G, Arnestad JS, Brenna E, Waldum HL. Treatment with proton pump inhibitors induces tolerance to histamine-2 receptor antagonists in Helicobacter pylori-negative patients. Scand J Gastroenterol 1998;33:1244-8.

45. Howden CW. Optimizing the pharmacology of acid control in acid-related disorders. Am J Gastroenterol 1997;92(suppl):17S-21S.

46. Sharma VK, Leontiadis GI, Howden CW. Meta-analysis of randomized controlled trials comparing standard clinical doses of omeprazole and lansopra-zole in erosive oesophagitis. Aliment Pharmacol Ther 2001;15:227-31.

47. Edwards SJ, Lind T, Lundell L. Systematic review of proton pump inhibitors for the acute treatment of reflux oesophagitis. Aliment Pharmacol Ther 2001;15:1729-36.

48. Dupas JL, Houcke P, Samoyeau R. Pantoprazole versus lansoprazole in French patients with reflux esophagi-tis. Gastroenterol Clin Biol 2001;25:245-50.

49. Castell DO, Kahrilas PJ, Richter JE, Vakil NB, Johnson DA, Zuckerman S, et al. Esomeprazole (40 mg) compared with lansoprazole (30 mg) in the treatment of erosive esophagitis. Am J Gastroenterol 2002;97:575-83.

50. Howden CW, Ballard ED, Robison W. Evidence for therapeutic equivalence of lansoprazole 30 mg and esomeprazole 40 mg in the treatment of erosive oesophagitis. Clin Drug Invest 2002;22:99-109.

51. Thjodleifsson B, Beker JA, Dekkers C, Bjaaland T, Finnegan V, Humphries TJ. Rabeprazole versus omeprazole in preventing relapse of erosive or ulcerative gastroesophageal reflux disease: a dou-ble-blind, multicenter, European trial. The European Rabeprazole Study Group. Dig Dis Sci 2000;45:845-53.

52. Carling L, Axelsson CK, Forssell H, Stubberod A, Kraglund K, Bonnevie O, et al. Lansoprazole and omeprazole in the prevention of relapse of reflux oesophagitis: a long-term comparative study. Aliment Pharmacol Ther 1998;12:985-90.

53. Chey WD, Inadmoni JM, Boojer AK, Fendrick AM. What do primary care physicians think about Barrett’s esoph-agus, the relationship between GERD and H. pylori, and treatment of nocturnal heartburn? Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

54. Sampliner RE and The Practice Parameters Committee of the American College of Gastroenterology. Updated guidelines for the diagnosis, surveillance, and therapy of Barrett’s esophagus. Am J Gastroenterol 2002;97:1888-95.

55. Spechler SJ, Lee E, Ahnen D, Goyal RK, Hirano I, Ramirez F, et al. Long-term outcome of medical and surgical therapies for gastroesophageal reflux disease: follow-up of a randomized controlled trial. JAMA 2001;285:2331-8.

56. Katz PO. Gastroesophageal reflux disease: new treatments. Rev Gastroenterol Disord 2002;2:66-74.

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William D. Chey, MD
Associate Professor, Division of Gastroenterology, Director of the GI Physiology Laboratory, University of Michigan Health System, Ann Arbor, MI
*This special section of The Journal of Family Practice is provided by an unrestricted grant fromTAPPharmaceutical Products, Inc. The authors received a stipend for this work. Dr. Howden reports that he serves on the speakers bureaus for Merck &Co., Inc., Novartis, TAP, and Wyeth, and he has been a consultant to Novartis, Prometheus Laboratories, Inc., Takeda Pharmaceuticals North America, TAP, and Wyeth. Dr. Chey reports that he has received grants and/or serves on speakers bureaus for AstraZeneca, Janssen, and TAP.

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*This special section of The Journal of Family Practice is provided by an unrestricted grant fromTAPPharmaceutical Products, Inc. The authors received a stipend for this work. Dr. Howden reports that he serves on the speakers bureaus for Merck &Co., Inc., Novartis, TAP, and Wyeth, and he has been a consultant to Novartis, Prometheus Laboratories, Inc., Takeda Pharmaceuticals North America, TAP, and Wyeth. Dr. Chey reports that he has received grants and/or serves on speakers bureaus for AstraZeneca, Janssen, and TAP.

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William D. Chey, MD
Associate Professor, Division of Gastroenterology, Director of the GI Physiology Laboratory, University of Michigan Health System, Ann Arbor, MI
*This special section of The Journal of Family Practice is provided by an unrestricted grant fromTAPPharmaceutical Products, Inc. The authors received a stipend for this work. Dr. Howden reports that he serves on the speakers bureaus for Merck &Co., Inc., Novartis, TAP, and Wyeth, and he has been a consultant to Novartis, Prometheus Laboratories, Inc., Takeda Pharmaceuticals North America, TAP, and Wyeth. Dr. Chey reports that he has received grants and/or serves on speakers bureaus for AstraZeneca, Janssen, and TAP.

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Practice recommendations
  • Heartburn on 2 or more days a week warrants medical attention, as patients are likely to suffer from gastroesophageal reflux disease (GERD).Chronic GERD can lead to the development of complications including erosive esophagitis, stricture formation, and Barrett’s esophagus, which increases the risk of esophageal adenocarcinoma.
  • A trial with a proton pump inhibitor (PPI) is the quickest and most cost-effective way to diagnose GERD, and is at least as sensitive as 24-hour intraesophageal pH monitoring.
  • As PPIs only bind to actively secreting proton pumps, they should be dosed 30 to 60 minutes before a meal.Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take a PPI with or after a meal or did not specify the timing of dosing.
  • The patients who will have the best response to surgical therapy for GERD are those who had clearly documented acid reflux with typical symptoms, and who have responded to PPI treatment. Unfortunately, the same survey found that most physicians recommend antireflux surgery for patients in whom medical therapy has failed.
 

Gastroesophageal reflux disease (GERD) is a common, multifactorial condition that often results in decreased quality of life with interruptions of sleep, work, and social activities. Patients have reported that GERD affects emotional well-being to a greater degree than diabetes or hypertension.1,2 GERD is also associated with well-established complications, including Barrett’s esophagus. The role of reflux in carcinogenesis is controversial; the possibility of an association, however, implies that GERD should be treated aggressively and early.3

Symptoms of gerd

The typical symptoms of GERD are heartburn and regurgitation. Heartburn is best defined as a burning retrosternal discomfort starting in the epigastrium or lower chest and moving upwards towards the neck. Regurgitation is the effortless movement of gastric contents up into the esophagus or pharynx.

Most patients with GERD do not have endoscopically visible lesions; a careful analysis of symptoms generally forms the basis of a preliminary diagnosis.

The occurrence of heartburn on 2 or more days a week has been suggested as a basis for further investigation for GERD.4 However, symptoms vary greatly. Patients may be asymptomatic or experience symptoms that more closely resemble gastric disorders, infectious and motor disorders of the esophagus, biliary tract disease, or even coronary artery disease.

Extraesophageal manifestations

Adding to the complexity of diagnosis, GERD has been shown to have extraesophageal manifestations, including chronic cough, asthma, recurrent aspiration, chronic sore throat, reflux laryngitis, and paroxysmal laryngospasm or voice changes.

Although the relationship between asthma and GERD remains unclear, it has been estimated that 24% to 98% of patients with asthma also have GERD.5 Some patients with asthma have been shown to have excess acid reflux into the esophagus. Reflux-like symptoms may precede episodes of asthma that occur after meals or when lying down.6 8

Additionally, GERD has been noted in 10% to 50% of patients with non-cardiac chest pain.9,10

 

 

Diagnostic strategies

Trial of treatment

Diagnosis is usually based on typical symptoms—heartburn or regurgitation—in the clinical history. (The Figure shows a treatment algorithm for both severe and mild symptoms.)

A 2-week trial of treatment with a proton pump inhibitor (PPI) provides the quickest and most cost-effective confirmation of diagnosis and is recommended for the patient whose history suggests uncomplicated GERD. A positive response to PPI treatment in a patient with symptoms suggestive of GERD is at least as sensitive and specific as 24-hour intraesophageal pH monitoring, which is still often considered the “gold standard” for the diagnosis of GERD. Furthermore, complete lack of improvement in response to PPI treatment is highly predictive that the patient does not have GERD and indicates the need for further evaluation and a possible revision of diagnosis.11,12

H2 receptor antagonists (H2RAs) have also been investigated in empirical trials for usefulness in diagnosing GERD. H2RAs are less effective than PPIs.13,14

 

FIGURE Medical management of suspected GERD


Endoscopy

No data support routine endoscopy for patients with the recent onset of uncomplicated heartburn who respond to medical therapy. Endoscopy is recommended, however, for patients with severe or atypical GERD symptoms, when other diseases may be present, or when a treatment trial with a PPI is ineffective.15 Endoscopy is useful for diagnosing complications of GERD, such as Barrett’s esophagus, esophagitis, and strictures. Fewer than 50% of patients with GERD symptoms have evidence of esophagitis on endoscopy.16

The American Society for Gastrointestinal Endoscopy recommends endoscopy when there are clinical suggestions of severe reflux or other disease.17 The American College of Gastroenterology recommends further testing

  • when empiric therapy has failed
  • when symptoms of complicated disease exist
  • when there is dysphagia, bleeding, weight loss, choking, chest pain, or long-standing symptoms
  • when continuous therapy is required
  • to screen for Barrett’s esophagus.18

The Canadian Consensus Conference recommends endoscopy in the presence of

  • dysphagia
  • odynophagia
  • bleeding
  • weight loss
  • noncardiac chest pain
  • failure to respond to 4 to 8 weeks of pharmacologic therapy.19

It also recommends a single test if maintenance therapy is required.

Other diagnostic tests

Other diagnostic tools may be of use in some settings.

A barium esophagram can document reflux, and Bernstein testing (esophageal acid infusion test) can identify esophageal hypersensitivity to acid, although neither establishes a diagnosis of GERD. Ambulatory 24-hour intraesophageal pH monitoring can help to establish the presence of GERD by documenting the proportion of time during which the intraesophageal pH is acidic (<4) and can also establish the degree of association between patients’ symptoms and episodes of esophageal acidification.

Esophageal manometry is not recommended as a routine diagnostic test for GERD. It is important in selected patients to exclude an esophageal motility disorder and may be necessary as part of the pre-operative evaluation for patients in whom a surgical operation for GERD is being considered.

Management of gerd

GERD commonly requires long-term management that includes dietary, lifestyle, and pharmacological interventions. Surgery may be considered for the long-term management of the condition in carefully selected patients.

 

 

Diet and lifestyle

Dietary modifications. Patients should not consume large meals and should avoid lying down for 3 to 4 hours after eating. Caffeinated products, peppermint, fatty foods, chocolate, spicy foods, citrus fruits and juices, tomato-based products, and alcohol may contribute to episodes of GERD.18,21 Lozenges of any kind are able to stimulate salivary secretion, help clear refluxed acid, and hence, help relieve symptoms.

Lifestyle modifications. Changes in lifestyle may include such seemingly sensible interventions as sleeping with the head elevated, stopping smoking, and losing weight. There is little or no established evidence for the efficacy of these and other lifestyle modifications in the management of GERD. However, in1 trial of 63 patients, elevating the head of the bed with 6-inch blocks resulted in 1 less episode of heartburn or acid regurgitation per night when compared with lying flat.22 In another trial of 71 patients with esophagitis, elevating the bed was nearly as effective as ranitidine for reducing symptoms and producing endoscopically verifiable healing.23

Obstacles to effective GERD treatment in primary care

Arecent survey20 of 1046 primary care physicians found that:

  • 36% instructed patients to take PPIs during or after a meal or did not specify a time of dosing
  • 75% referred patients for surgical antireflux therapy and 20% referred patients directly to a surgeon without gastrointestinal consultation
  • 15% reported that a trial with a H2 receptor antagonist was required by their healthsystem or insurance company prior to using a PPI.

Drug interventions

Pharmacological interventions include over-the-counter remedies such as antacids and H2RAs (Table 1), as well as prescription-only doses of H2RAs and PPIs. At the time of writing, no PPI was available in an over-the-counter preparation in the United States, although over-the-counter omeprazole may soon be approved. Many authorities believe an incremental approach to the management of GERD is appropriate, beginning with lifestyle modifications and over-the-counter preparations, continuing with H2 blockers, and reserving PPIs for nonresponders. While this approach may have appeal from a cost perspective, we believe another approach (as illustrated in the Figure) is clinically superior.

Antacids. Over-the-counter antacids rapidly increase the pH of the intraesophageal contents and also neutralize acidic gastric contents that might be refluxed. They are frequently used to treat heartburn. However, few clinical trials have evaluated the efficacy of antacids. Published trials24-26 are limited by small sample sizes and a lack of intention-to-treat analysis. Only 1 showed positive evidence for antacid efficacy.25

The utility of antacids is limited by the need for frequent dosing and possible interactions with such drugs as fluoroquinolones, tetracycline, and ferrous sulfate.27 Alginate/antacids have shown statistically significant benefit compared with placebo for relief of mild-to-moderate GERD symptoms and healing of esophagitis.24,28-34

H 2 receptor antagonists. H2RAs have shown positive effects on symptoms in some studies, although symptomatic response rates observed were only around 60% to 70%. Additionally, most of the trials to date have been for 2 to 6 weeks in duration.35 43 An issue worthy of consideration with the H2RAs is the development of tolerance with continuous use.44

An H2RA-antacid combination was recently evaluated in a trial that compared it with monotherapy using either agent. Of the patients receiving combination therapy, 81% reported an excellent or good symptom response. Those receiving famotidine or atacid alone reported a 72% excellent or good symptom response.3

 

 

Proton pump inhibitors. PPIs potently reduce gastric acid secretion by inhibiting the H+-K+adenosine triphosphatase pump of the parietal cell. As a result, they suppress gastric acid secretion for a longer period than H2RAs.45 Evidence from randomized, controlled trials has demonstrated the superiority of PPIs over any other class of drugs for the relief of GERD symptoms, for healing esophagitis, and for maintaining patients in remission. Standard doses of omeprazole, lansoprazole, panto-prazole, esomeprazole, and rabeprazole have, for the most part, shown comparable rates of healing and remission in erosive esophagitis.46-52

PPIs are best absorbed in the absence of food. Ingestion of food after a PPI stimulates parietal cell activity when blood levels of the PPI are increasing; this promotes uptake of the PPI by the parietal cells. Therefore, patients should be advised to take their PPI between 30 and 60 minutes before eating. For patients on a once-daily PPI, the best time to take it is about 30 to 60 minutes before breakfast. Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take their PPI with or after a meal or did not specify the timing of dosing.53

Guidelines for proton pump inhibitor use in clinical practice

Clinical evidence indicates that a trial with a PPI provides the quickest and most cost-effective method for diagnosing GERD. Despite this, many physicians use a trial of H2 receptor antagonists prior to initiation of PPI therapy.

  • Clinicians should clearly instruct their patients regarding optimal timing of the dose, since this can have a significant effect on the success of therapy.
  • Patients for whom antireflux surgery is being considered should first be referred for consultation with a gastroenterologist to assist in patient selection, to ensure that appropriate preoperative evaluation has been performed and to help exclude other possible causes of their symptoms.21,54

PPI therapy can be tailored to control GERD symptoms. Treatment can start with the most effective dosage and then be stepped down, or start with a minimum dosage and then be stepped up (Table 2). Patients with predominantly daytime symptoms should take PPIs before breakfast. Concerns that were once expressed about the long-term use of PPIs, such as predisposing patients to stomach cancer, have been refuted by extensive clinical experience and intensive monitoring (Table 3).3

TABLE 1

Over-the-counter therapy for GERD

 

  • Prevention and rapid relief of symptoms
  • Reduction of frequency and severity of symptoms
  • Role in therapy
  • Limitations
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies.
Bethesda, Md.:American Gastroenterological Association;2002.

TABLE 2

Step-down and step-up treatments: advantages and disadvantages

 

RegimenAdvantagesDisadvantages
Step-down therapy (high-dose initial therapy)Rapid symptom reliefPotential overtreatment
Efficient for physicianHigher initial drug cost
Avoids overinvestigation and associated costs
Step-up therapy (minimum-dose initial therapy)Avoids overtreatmentPatient may continue with symptoms unnecessarily
Lower initial drug costInefficient for physician
May lead to overinvestigation
Uncertain end point (partial symptom relief)
Adapted from Dent J, et al. Management of gastro-oesophageal reflux disease in general practice.BMJ 2001;322:344-347.

TABLE 3

Potential concerns associated with the use of proton pump inhibitors

 

Potential concernLevel of Evidence*Grade Comments
Long-term PPI treatment may lead to reduced serum cobalamin levels2bBThis is most likely to occur in individuals with atrophic gastritis
Increased acid output has been seen after stopping a PPI2bBEffects of PPI treatment on corpus glandular atrophy in H pylori-infected individuals are difficult to interpret due to possible sampling error and short study duration
PPI treatment may predispose to bacterial enteric infection3BOnly shown in a single case control study
*Level of evidence:1, Evidence for and/or general agreement that treatment is useful and effective;1a, systematic review with homogeneity of randomized controlled trials (RCTs);1b, individual RCTs (with narrow confidence interval);2, conflicting evidence and/or divergent opinion about efficacy and use;2a, evidence or opinion is in favor of treatment;2b, use and efficacy is less well established by evidence or opinion;3, evidence and/or general agreement that treatment is not useful or effective and may be harmful in some cases.
†Quality grading:A, well-designed, clinical trials;B, well-designed cohort or case-control studies;C, case reports, flawed trials;D, personal clinical experience;E, insufficient evidence to form opinion.
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies. Bethesda, Md:American Gastroenterological Association, 2002.

Surgery

Surgical antireflux therapy is an option in carefully selected patients. Those who respond best to surgical therapy will have had clearly documented acid reflux, typical symptoms, and symptomatic improvement while on PPI treatment.54

Unfortunately, a recent survey suggests that physicians tend to recommend surgery for patients in whom medical therapy has failed.53 However, patients who failed to respond to PPI therapy are unlikely to have GERD and, therefore, are highly unlikely to have a good outcome from antireflux surgery. Recent studies suggest that up to 62% of patients who have had open surgery for GERD continue to require medical treatment afterward. Although some studies demonstrate that surgery has greater efficacy over medical therapy initially, long-term follow-up has shown that surgically treated patients often need further medical therapy for persistent GERD symptoms.55 Community-based studies of antireflux surgery indicate that many patients develop new symptoms that they did not have before surgery and that these substantially diminish quality of life.

New endoscopic therapies, including radiofrequency energy delivery to the region of the lower esophageal sphincter and endoscopic suturing, have recently been approved for use by the FDA. This approval was based largely on safety rather than efficacy data. Clinical evidence is limited to uncontrolled studies in patients with no or mild esophagitis.3 These techniques should not be used in preference to established medical treatment unless and until data from randomized, controlled trials become available that demonstrate safety and efficacy.56

 

Practice recommendations
  • Heartburn on 2 or more days a week warrants medical attention, as patients are likely to suffer from gastroesophageal reflux disease (GERD).Chronic GERD can lead to the development of complications including erosive esophagitis, stricture formation, and Barrett’s esophagus, which increases the risk of esophageal adenocarcinoma.
  • A trial with a proton pump inhibitor (PPI) is the quickest and most cost-effective way to diagnose GERD, and is at least as sensitive as 24-hour intraesophageal pH monitoring.
  • As PPIs only bind to actively secreting proton pumps, they should be dosed 30 to 60 minutes before a meal.Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take a PPI with or after a meal or did not specify the timing of dosing.
  • The patients who will have the best response to surgical therapy for GERD are those who had clearly documented acid reflux with typical symptoms, and who have responded to PPI treatment. Unfortunately, the same survey found that most physicians recommend antireflux surgery for patients in whom medical therapy has failed.
 

Gastroesophageal reflux disease (GERD) is a common, multifactorial condition that often results in decreased quality of life with interruptions of sleep, work, and social activities. Patients have reported that GERD affects emotional well-being to a greater degree than diabetes or hypertension.1,2 GERD is also associated with well-established complications, including Barrett’s esophagus. The role of reflux in carcinogenesis is controversial; the possibility of an association, however, implies that GERD should be treated aggressively and early.3

Symptoms of gerd

The typical symptoms of GERD are heartburn and regurgitation. Heartburn is best defined as a burning retrosternal discomfort starting in the epigastrium or lower chest and moving upwards towards the neck. Regurgitation is the effortless movement of gastric contents up into the esophagus or pharynx.

Most patients with GERD do not have endoscopically visible lesions; a careful analysis of symptoms generally forms the basis of a preliminary diagnosis.

The occurrence of heartburn on 2 or more days a week has been suggested as a basis for further investigation for GERD.4 However, symptoms vary greatly. Patients may be asymptomatic or experience symptoms that more closely resemble gastric disorders, infectious and motor disorders of the esophagus, biliary tract disease, or even coronary artery disease.

Extraesophageal manifestations

Adding to the complexity of diagnosis, GERD has been shown to have extraesophageal manifestations, including chronic cough, asthma, recurrent aspiration, chronic sore throat, reflux laryngitis, and paroxysmal laryngospasm or voice changes.

Although the relationship between asthma and GERD remains unclear, it has been estimated that 24% to 98% of patients with asthma also have GERD.5 Some patients with asthma have been shown to have excess acid reflux into the esophagus. Reflux-like symptoms may precede episodes of asthma that occur after meals or when lying down.6 8

Additionally, GERD has been noted in 10% to 50% of patients with non-cardiac chest pain.9,10

 

 

Diagnostic strategies

Trial of treatment

Diagnosis is usually based on typical symptoms—heartburn or regurgitation—in the clinical history. (The Figure shows a treatment algorithm for both severe and mild symptoms.)

A 2-week trial of treatment with a proton pump inhibitor (PPI) provides the quickest and most cost-effective confirmation of diagnosis and is recommended for the patient whose history suggests uncomplicated GERD. A positive response to PPI treatment in a patient with symptoms suggestive of GERD is at least as sensitive and specific as 24-hour intraesophageal pH monitoring, which is still often considered the “gold standard” for the diagnosis of GERD. Furthermore, complete lack of improvement in response to PPI treatment is highly predictive that the patient does not have GERD and indicates the need for further evaluation and a possible revision of diagnosis.11,12

H2 receptor antagonists (H2RAs) have also been investigated in empirical trials for usefulness in diagnosing GERD. H2RAs are less effective than PPIs.13,14

 

FIGURE Medical management of suspected GERD


Endoscopy

No data support routine endoscopy for patients with the recent onset of uncomplicated heartburn who respond to medical therapy. Endoscopy is recommended, however, for patients with severe or atypical GERD symptoms, when other diseases may be present, or when a treatment trial with a PPI is ineffective.15 Endoscopy is useful for diagnosing complications of GERD, such as Barrett’s esophagus, esophagitis, and strictures. Fewer than 50% of patients with GERD symptoms have evidence of esophagitis on endoscopy.16

The American Society for Gastrointestinal Endoscopy recommends endoscopy when there are clinical suggestions of severe reflux or other disease.17 The American College of Gastroenterology recommends further testing

  • when empiric therapy has failed
  • when symptoms of complicated disease exist
  • when there is dysphagia, bleeding, weight loss, choking, chest pain, or long-standing symptoms
  • when continuous therapy is required
  • to screen for Barrett’s esophagus.18

The Canadian Consensus Conference recommends endoscopy in the presence of

  • dysphagia
  • odynophagia
  • bleeding
  • weight loss
  • noncardiac chest pain
  • failure to respond to 4 to 8 weeks of pharmacologic therapy.19

It also recommends a single test if maintenance therapy is required.

Other diagnostic tests

Other diagnostic tools may be of use in some settings.

A barium esophagram can document reflux, and Bernstein testing (esophageal acid infusion test) can identify esophageal hypersensitivity to acid, although neither establishes a diagnosis of GERD. Ambulatory 24-hour intraesophageal pH monitoring can help to establish the presence of GERD by documenting the proportion of time during which the intraesophageal pH is acidic (<4) and can also establish the degree of association between patients’ symptoms and episodes of esophageal acidification.

Esophageal manometry is not recommended as a routine diagnostic test for GERD. It is important in selected patients to exclude an esophageal motility disorder and may be necessary as part of the pre-operative evaluation for patients in whom a surgical operation for GERD is being considered.

Management of gerd

GERD commonly requires long-term management that includes dietary, lifestyle, and pharmacological interventions. Surgery may be considered for the long-term management of the condition in carefully selected patients.

 

 

Diet and lifestyle

Dietary modifications. Patients should not consume large meals and should avoid lying down for 3 to 4 hours after eating. Caffeinated products, peppermint, fatty foods, chocolate, spicy foods, citrus fruits and juices, tomato-based products, and alcohol may contribute to episodes of GERD.18,21 Lozenges of any kind are able to stimulate salivary secretion, help clear refluxed acid, and hence, help relieve symptoms.

Lifestyle modifications. Changes in lifestyle may include such seemingly sensible interventions as sleeping with the head elevated, stopping smoking, and losing weight. There is little or no established evidence for the efficacy of these and other lifestyle modifications in the management of GERD. However, in1 trial of 63 patients, elevating the head of the bed with 6-inch blocks resulted in 1 less episode of heartburn or acid regurgitation per night when compared with lying flat.22 In another trial of 71 patients with esophagitis, elevating the bed was nearly as effective as ranitidine for reducing symptoms and producing endoscopically verifiable healing.23

Obstacles to effective GERD treatment in primary care

Arecent survey20 of 1046 primary care physicians found that:

  • 36% instructed patients to take PPIs during or after a meal or did not specify a time of dosing
  • 75% referred patients for surgical antireflux therapy and 20% referred patients directly to a surgeon without gastrointestinal consultation
  • 15% reported that a trial with a H2 receptor antagonist was required by their healthsystem or insurance company prior to using a PPI.

Drug interventions

Pharmacological interventions include over-the-counter remedies such as antacids and H2RAs (Table 1), as well as prescription-only doses of H2RAs and PPIs. At the time of writing, no PPI was available in an over-the-counter preparation in the United States, although over-the-counter omeprazole may soon be approved. Many authorities believe an incremental approach to the management of GERD is appropriate, beginning with lifestyle modifications and over-the-counter preparations, continuing with H2 blockers, and reserving PPIs for nonresponders. While this approach may have appeal from a cost perspective, we believe another approach (as illustrated in the Figure) is clinically superior.

Antacids. Over-the-counter antacids rapidly increase the pH of the intraesophageal contents and also neutralize acidic gastric contents that might be refluxed. They are frequently used to treat heartburn. However, few clinical trials have evaluated the efficacy of antacids. Published trials24-26 are limited by small sample sizes and a lack of intention-to-treat analysis. Only 1 showed positive evidence for antacid efficacy.25

The utility of antacids is limited by the need for frequent dosing and possible interactions with such drugs as fluoroquinolones, tetracycline, and ferrous sulfate.27 Alginate/antacids have shown statistically significant benefit compared with placebo for relief of mild-to-moderate GERD symptoms and healing of esophagitis.24,28-34

H 2 receptor antagonists. H2RAs have shown positive effects on symptoms in some studies, although symptomatic response rates observed were only around 60% to 70%. Additionally, most of the trials to date have been for 2 to 6 weeks in duration.35 43 An issue worthy of consideration with the H2RAs is the development of tolerance with continuous use.44

An H2RA-antacid combination was recently evaluated in a trial that compared it with monotherapy using either agent. Of the patients receiving combination therapy, 81% reported an excellent or good symptom response. Those receiving famotidine or atacid alone reported a 72% excellent or good symptom response.3

 

 

Proton pump inhibitors. PPIs potently reduce gastric acid secretion by inhibiting the H+-K+adenosine triphosphatase pump of the parietal cell. As a result, they suppress gastric acid secretion for a longer period than H2RAs.45 Evidence from randomized, controlled trials has demonstrated the superiority of PPIs over any other class of drugs for the relief of GERD symptoms, for healing esophagitis, and for maintaining patients in remission. Standard doses of omeprazole, lansoprazole, panto-prazole, esomeprazole, and rabeprazole have, for the most part, shown comparable rates of healing and remission in erosive esophagitis.46-52

PPIs are best absorbed in the absence of food. Ingestion of food after a PPI stimulates parietal cell activity when blood levels of the PPI are increasing; this promotes uptake of the PPI by the parietal cells. Therefore, patients should be advised to take their PPI between 30 and 60 minutes before eating. For patients on a once-daily PPI, the best time to take it is about 30 to 60 minutes before breakfast. Despite these recommendations, a recent survey of over 1000 US primary care physicians found that 36% instructed their patients to take their PPI with or after a meal or did not specify the timing of dosing.53

Guidelines for proton pump inhibitor use in clinical practice

Clinical evidence indicates that a trial with a PPI provides the quickest and most cost-effective method for diagnosing GERD. Despite this, many physicians use a trial of H2 receptor antagonists prior to initiation of PPI therapy.

  • Clinicians should clearly instruct their patients regarding optimal timing of the dose, since this can have a significant effect on the success of therapy.
  • Patients for whom antireflux surgery is being considered should first be referred for consultation with a gastroenterologist to assist in patient selection, to ensure that appropriate preoperative evaluation has been performed and to help exclude other possible causes of their symptoms.21,54

PPI therapy can be tailored to control GERD symptoms. Treatment can start with the most effective dosage and then be stepped down, or start with a minimum dosage and then be stepped up (Table 2). Patients with predominantly daytime symptoms should take PPIs before breakfast. Concerns that were once expressed about the long-term use of PPIs, such as predisposing patients to stomach cancer, have been refuted by extensive clinical experience and intensive monitoring (Table 3).3

TABLE 1

Over-the-counter therapy for GERD

 

  • Prevention and rapid relief of symptoms
  • Reduction of frequency and severity of symptoms
  • Role in therapy
  • Limitations
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies.
Bethesda, Md.:American Gastroenterological Association;2002.

TABLE 2

Step-down and step-up treatments: advantages and disadvantages

 

RegimenAdvantagesDisadvantages
Step-down therapy (high-dose initial therapy)Rapid symptom reliefPotential overtreatment
Efficient for physicianHigher initial drug cost
Avoids overinvestigation and associated costs
Step-up therapy (minimum-dose initial therapy)Avoids overtreatmentPatient may continue with symptoms unnecessarily
Lower initial drug costInefficient for physician
May lead to overinvestigation
Uncertain end point (partial symptom relief)
Adapted from Dent J, et al. Management of gastro-oesophageal reflux disease in general practice.BMJ 2001;322:344-347.

TABLE 3

Potential concerns associated with the use of proton pump inhibitors

 

Potential concernLevel of Evidence*Grade Comments
Long-term PPI treatment may lead to reduced serum cobalamin levels2bBThis is most likely to occur in individuals with atrophic gastritis
Increased acid output has been seen after stopping a PPI2bBEffects of PPI treatment on corpus glandular atrophy in H pylori-infected individuals are difficult to interpret due to possible sampling error and short study duration
PPI treatment may predispose to bacterial enteric infection3BOnly shown in a single case control study
*Level of evidence:1, Evidence for and/or general agreement that treatment is useful and effective;1a, systematic review with homogeneity of randomized controlled trials (RCTs);1b, individual RCTs (with narrow confidence interval);2, conflicting evidence and/or divergent opinion about efficacy and use;2a, evidence or opinion is in favor of treatment;2b, use and efficacy is less well established by evidence or opinion;3, evidence and/or general agreement that treatment is not useful or effective and may be harmful in some cases.
†Quality grading:A, well-designed, clinical trials;B, well-designed cohort or case-control studies;C, case reports, flawed trials;D, personal clinical experience;E, insufficient evidence to form opinion.
Adapted from Peterson, WL.GERD:Evidence-based therapeutic strategies. Bethesda, Md:American Gastroenterological Association, 2002.

Surgery

Surgical antireflux therapy is an option in carefully selected patients. Those who respond best to surgical therapy will have had clearly documented acid reflux, typical symptoms, and symptomatic improvement while on PPI treatment.54

Unfortunately, a recent survey suggests that physicians tend to recommend surgery for patients in whom medical therapy has failed.53 However, patients who failed to respond to PPI therapy are unlikely to have GERD and, therefore, are highly unlikely to have a good outcome from antireflux surgery. Recent studies suggest that up to 62% of patients who have had open surgery for GERD continue to require medical treatment afterward. Although some studies demonstrate that surgery has greater efficacy over medical therapy initially, long-term follow-up has shown that surgically treated patients often need further medical therapy for persistent GERD symptoms.55 Community-based studies of antireflux surgery indicate that many patients develop new symptoms that they did not have before surgery and that these substantially diminish quality of life.

New endoscopic therapies, including radiofrequency energy delivery to the region of the lower esophageal sphincter and endoscopic suturing, have recently been approved for use by the FDA. This approval was based largely on safety rather than efficacy data. Clinical evidence is limited to uncontrolled studies in patients with no or mild esophagitis.3 These techniques should not be used in preference to established medical treatment unless and until data from randomized, controlled trials become available that demonstrate safety and efficacy.56

References

1. Dimenas E. Methodological aspects of evaluation of quality of life in upper gastrointestinal diseases. Scand J Gastroenterol Suppl 1993;199:18-21.

2. Revicki DA, Wood M, Maton PN, Sorensen S. The impact of gastroesophageal reflux disease on health-related quality of life. Am J Med 1998;104:252-8.

3. Peterson WL. GERD: Evidence-based therapeutic strategies. Bethesda, Md: American Gastroenterological Association; 2002.

4. Dent J, Jones R, Kahrilas P, Talley NJ. Management of gastro-oesophageal reflux disease in general practice. BMJ 2001;322:344-7.

5. Harding SM. Nocturnal asthma: role of gastroesophageal reflux. Chronobiol Int 1999;16:641-2.

6. Kjellen G, Wranne B. The prevalence of asymptomatic gastro-oesophageal relfux in adult patients with asthma. Eur J Respir Dis 1984;65:233.-

7. Schnatz PF, Castell JA, Castell DO. Pulmonary symptoms associated with gastroesophageal reflux: use of ambulatory pH monitoring to diagnose and to direct therapy. Am J Gastroenterol 1996;91:1715-8.

8. Sontag SJ, Schnell TG, Miller TQ, Khandelwal S, O’Connell S, Chejfec G, et al. Prevalence of oesophagitis in asthmatics. Gut 1992;33:872-6.

9. Schofield PM, Bennett DH, Whorwell PJ, Brooks NH, Bray CL, Ward C, et al. Exertional gastro-oesophageal reflux: a mechanism for symptoms in patients with angina pectoris and normal coronary angiograms. Br Med J (Clin Res Ed) 1987;294:1459-61.

10. Hewson EG, Sinclair JW, Dalton CB, Richter JE. Twenty-four-hour esophageal pH monitoring: the most useful test for evaluating noncardiac chest pain. Am J Med 1991;90:576-83.

11. Goyal RK. Diseases of the esophagus. In: Braunwald E, ed. Harrison’s principles of internal medicine. 15th ed. New York: McGraw-Hill; 2001;1642-9.

12. Schenk BE, Kuipers EJ, Klinkenberg-Knol EC, Festen HP, Jansen EH, Tuynman HA, et al. Omeprazole as a diagnostic tool in gastroesophageal reflux disease. Am J Gastroenterol 1997;92:1997-2000.

13. van Pinxteren B, Numans ME, Bonis PA, Lau J. Short-term treatment with proton pump inhibitors, H2-receptor antagonists and prokinetics for gastrooesophageal reflux disease-like symptoms and endoscopy negative reflux disease. Cochrane Database Syst Rev 2001;(4):CD002095.-

14. Brun J, Sorngard H. High dose proton pump inhibitor response as an initial strategy for a clinical diagnosis of gastro-oesophageal reflux disease (GERD).Swedish multi-centre group in primary health care. Fam Pract 2000;17:401-4.

15. Lundell L. Anti-reflux surgery in the laparoscopic era. Baillieres Best Pract Res Clin Gastroenterol 2000;14:793-810.

16. Chen MY, Ott DJ, Sinclair JW, Wu WC, Gelfand DW. Gastroesophageal reflux disease: correlation of esophageal pH testing and radiographic findings. Radiology 1992;185:483-6.

17. The role of endoscopy in the management of GERD: guidelines for clinical application. From the ASGE. American Society for Gastrointestinal Endoscopy. Gastrointest Endosc 1999;49:834-5.

18. DeVault KR, Castell DO. Updated guidelines for the diagnosis and treatment of gastroesophageal reflux disease. The Practice Parameters Committee of the American College of Gastroenterology. Am J Gastroenterol 1999;94:1434-42.

19. Beck IT, Champion MC, Lemire S, Thomson AB, Anvari M, Armstrong D, et al. The Second Canadian Consensus Conference on the Management of Patients with Gastroesophageal Reflux Disease. Can J Gastroenterol 1997;11(suppl B):7B-20B.

20. Chey WD, Inadomi JM, Booher AK, Fendrick AM. Primary care physicians’ perceptions and practices of the management of GERD: results of a national survey. Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

21. Fennerty MB, Castell D, Fendrick AM, Halpern M, Johnson D, Kahrilas PJ, et al. The diagnosis and treatment of gastroesophageal reflux disease in a managed care environment, Suggested disease management guidelines. Arch Intern Med 1996;156:477-84.

22. Stanciu C, Bennett JR. Effects of posture on gastro-oesophageal reflux. Digestion 1977;15:104-9.

23. Harvey RF, Gordon PC, Hadley N, Long DE, Gill TR, Macpherson RI, et al. Effects of sleeping with the bed-head raised and of ranitidine in patients with severe peptic oesophagitis. Lancet 1987;2:1200-3.

24. Graham DY, Patterson DJ. Double-blind comparison of liquid antacid and placebo in the treatment of symptomatic reflux esophagitis. Dig Dis Sci 1983;28:559-63.

25. Grove O, Bekker C, Jeppe-Hansen MG, Karstoft E, Sanchez G, Axelsson CK, et al. Ranitidine and high-dose antacid in reflux oesophagitis. A randomized, placebo-controlled trial. Scand J Gastroenterol 1985;20:457-61.

26. Weberg R, Berstad A. Symptomatic effect of a low-dose antacid regimen in reflux oesophagitis. Scand J Gastroenterol 1989;24:401-6.

27. Welage LS, Berardi RR. Evaluation of omeprazole, lansoprazole, pantopra-zole, and rabeprazole in the treatment of acid-related diseases. J Am Pharm Assoc (Wash) 2000;40:52-62.

28. Barnardo DE, Lancaster-Smith M, Strickland ID, Wright JT. A double-blind controlled trial of ‘Gaviscon’ in patients with symptomatic gastro-oesophageal reflux. Curr Med Res Opin 1975;3:388-91.

29. Beeley M, Warner JO. Medical treatment of symptomatic hiatus hernia with low-density compounds. Curr Med Res Opin 1972;1:63-9.

30. Chevrel B. A comparative crossover study on the treatment of heartburn and epigastric pain: liquid Gaviscon and a magnesium-aluminium antacid gel. J Int Med Res. 1980;8:300-2.

31. Laitinen S, Stahlberg M, Kairaluoma MI, Kiviniemi H, Paakkonen M, Lahtinen J, et al. Sucralfate and algi-nate/antacid in reflux esophagitis. Scand J Gastroenterol 1985;20:229-32.

32. Lanza FL, Smith V, Page-Castell JA, Castell DO. Effectiveness of foaming antacid in relieving induced heartburn. South Med J 1986;79:327-30.

33. McHardy G. A multicentric, randomized clinical trial of Gaviscon in reflux esophagitis. South Med J 1978;71(suppl 1):16-21.

34. Stanciu C, Bennett JR. Alginate-antacid in the reduction of gastro-oesophageal reflux. Lancet 1974;1:109-11.

35. Paul K, Redman CM, Chen M. Effectiveness and safety of nizatidine, 75 mg, for the relief of episodic heartburn. Aliment Pharmacol Ther 2001;15:1571-7.

36. Spiegel JE, Thoden WR, Pappas K, Fratarcangelo P, Furey SA. A double-blind, placebo-controlled study of the effectiveness and safety of nizatidine in the prevention of postprandial heartburn. Arch Intern Med 1997;157:1594-9.

37. Pappa KA, Buaron K, Payne JE, Sirgo MA, Giefer EE. An evaluation of increasing doses of ranitidine for treatment of heartburn. Aliment Pharmacol Ther 1999;13:475-81.

38. Pappa KA, Gooch WM, Buaron K, Payne JE, Giefer EE, Sirgo MA, et al. Low-dose ranitidine for the relief of heartburn. Aliment Pharmacol Ther 1999;13:459-65.

39. Pappa KA, Williams BO, Payne JE, Buaron KS, Mussari KL, Ciociola AA. A double-blind, placebo-controlled study of the efficacy and safety of non-pre-scription ranitidine 75 mg in the prevention of meal-induced heartburn. Aliment Pharmacol Ther 1999;13:467-73.

40. Ciociola AA, Pappa KA, Sirgo MA. Nonprescription doses of ranitidine are effective in the relief of episodic heartburn. Am J Ther 2001;8:399-408.

41. Gottlieb S, Decktor DL, Eckert JM, Simon TJ, Stauffer L, Ciccone PE. Efficacy and tolerability of famotidine in preventing heartburn and related symptoms of upper gastrointestinal discomfort. Am J Ther 1995;2:314-9.

42. Simon TJ, Berlin RG, Gardner AH, Stauffer LA, Gould AL, Getson AJ. Self-directed treatment of intermittent heartburn: a randomized, multicenter, double-blind, placebo-controlled evaluation of antacid and low doses of an H(2)-receptor antagonist (famotidine). Am J Ther 1995;2:304-13.

43. Galmiche JP, Shi G, Simon B, Casset-Semanza F, Slama A. On-demand treatment of gastro-oesophageal reflux symptoms: a comparison of ranitidine 75 mg with cimetidine 200 mg or place-bo. Aliment Pharmacol Ther 1998;12:909-17.

44. Qvigstad G, Arnestad JS, Brenna E, Waldum HL. Treatment with proton pump inhibitors induces tolerance to histamine-2 receptor antagonists in Helicobacter pylori-negative patients. Scand J Gastroenterol 1998;33:1244-8.

45. Howden CW. Optimizing the pharmacology of acid control in acid-related disorders. Am J Gastroenterol 1997;92(suppl):17S-21S.

46. Sharma VK, Leontiadis GI, Howden CW. Meta-analysis of randomized controlled trials comparing standard clinical doses of omeprazole and lansopra-zole in erosive oesophagitis. Aliment Pharmacol Ther 2001;15:227-31.

47. Edwards SJ, Lind T, Lundell L. Systematic review of proton pump inhibitors for the acute treatment of reflux oesophagitis. Aliment Pharmacol Ther 2001;15:1729-36.

48. Dupas JL, Houcke P, Samoyeau R. Pantoprazole versus lansoprazole in French patients with reflux esophagi-tis. Gastroenterol Clin Biol 2001;25:245-50.

49. Castell DO, Kahrilas PJ, Richter JE, Vakil NB, Johnson DA, Zuckerman S, et al. Esomeprazole (40 mg) compared with lansoprazole (30 mg) in the treatment of erosive esophagitis. Am J Gastroenterol 2002;97:575-83.

50. Howden CW, Ballard ED, Robison W. Evidence for therapeutic equivalence of lansoprazole 30 mg and esomeprazole 40 mg in the treatment of erosive oesophagitis. Clin Drug Invest 2002;22:99-109.

51. Thjodleifsson B, Beker JA, Dekkers C, Bjaaland T, Finnegan V, Humphries TJ. Rabeprazole versus omeprazole in preventing relapse of erosive or ulcerative gastroesophageal reflux disease: a dou-ble-blind, multicenter, European trial. The European Rabeprazole Study Group. Dig Dis Sci 2000;45:845-53.

52. Carling L, Axelsson CK, Forssell H, Stubberod A, Kraglund K, Bonnevie O, et al. Lansoprazole and omeprazole in the prevention of relapse of reflux oesophagitis: a long-term comparative study. Aliment Pharmacol Ther 1998;12:985-90.

53. Chey WD, Inadmoni JM, Boojer AK, Fendrick AM. What do primary care physicians think about Barrett’s esoph-agus, the relationship between GERD and H. pylori, and treatment of nocturnal heartburn? Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

54. Sampliner RE and The Practice Parameters Committee of the American College of Gastroenterology. Updated guidelines for the diagnosis, surveillance, and therapy of Barrett’s esophagus. Am J Gastroenterol 2002;97:1888-95.

55. Spechler SJ, Lee E, Ahnen D, Goyal RK, Hirano I, Ramirez F, et al. Long-term outcome of medical and surgical therapies for gastroesophageal reflux disease: follow-up of a randomized controlled trial. JAMA 2001;285:2331-8.

56. Katz PO. Gastroesophageal reflux disease: new treatments. Rev Gastroenterol Disord 2002;2:66-74.

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19. Beck IT, Champion MC, Lemire S, Thomson AB, Anvari M, Armstrong D, et al. The Second Canadian Consensus Conference on the Management of Patients with Gastroesophageal Reflux Disease. Can J Gastroenterol 1997;11(suppl B):7B-20B.

20. Chey WD, Inadomi JM, Booher AK, Fendrick AM. Primary care physicians’ perceptions and practices of the management of GERD: results of a national survey. Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

21. Fennerty MB, Castell D, Fendrick AM, Halpern M, Johnson D, Kahrilas PJ, et al. The diagnosis and treatment of gastroesophageal reflux disease in a managed care environment, Suggested disease management guidelines. Arch Intern Med 1996;156:477-84.

22. Stanciu C, Bennett JR. Effects of posture on gastro-oesophageal reflux. Digestion 1977;15:104-9.

23. Harvey RF, Gordon PC, Hadley N, Long DE, Gill TR, Macpherson RI, et al. Effects of sleeping with the bed-head raised and of ranitidine in patients with severe peptic oesophagitis. Lancet 1987;2:1200-3.

24. Graham DY, Patterson DJ. Double-blind comparison of liquid antacid and placebo in the treatment of symptomatic reflux esophagitis. Dig Dis Sci 1983;28:559-63.

25. Grove O, Bekker C, Jeppe-Hansen MG, Karstoft E, Sanchez G, Axelsson CK, et al. Ranitidine and high-dose antacid in reflux oesophagitis. A randomized, placebo-controlled trial. Scand J Gastroenterol 1985;20:457-61.

26. Weberg R, Berstad A. Symptomatic effect of a low-dose antacid regimen in reflux oesophagitis. Scand J Gastroenterol 1989;24:401-6.

27. Welage LS, Berardi RR. Evaluation of omeprazole, lansoprazole, pantopra-zole, and rabeprazole in the treatment of acid-related diseases. J Am Pharm Assoc (Wash) 2000;40:52-62.

28. Barnardo DE, Lancaster-Smith M, Strickland ID, Wright JT. A double-blind controlled trial of ‘Gaviscon’ in patients with symptomatic gastro-oesophageal reflux. Curr Med Res Opin 1975;3:388-91.

29. Beeley M, Warner JO. Medical treatment of symptomatic hiatus hernia with low-density compounds. Curr Med Res Opin 1972;1:63-9.

30. Chevrel B. A comparative crossover study on the treatment of heartburn and epigastric pain: liquid Gaviscon and a magnesium-aluminium antacid gel. J Int Med Res. 1980;8:300-2.

31. Laitinen S, Stahlberg M, Kairaluoma MI, Kiviniemi H, Paakkonen M, Lahtinen J, et al. Sucralfate and algi-nate/antacid in reflux esophagitis. Scand J Gastroenterol 1985;20:229-32.

32. Lanza FL, Smith V, Page-Castell JA, Castell DO. Effectiveness of foaming antacid in relieving induced heartburn. South Med J 1986;79:327-30.

33. McHardy G. A multicentric, randomized clinical trial of Gaviscon in reflux esophagitis. South Med J 1978;71(suppl 1):16-21.

34. Stanciu C, Bennett JR. Alginate-antacid in the reduction of gastro-oesophageal reflux. Lancet 1974;1:109-11.

35. Paul K, Redman CM, Chen M. Effectiveness and safety of nizatidine, 75 mg, for the relief of episodic heartburn. Aliment Pharmacol Ther 2001;15:1571-7.

36. Spiegel JE, Thoden WR, Pappas K, Fratarcangelo P, Furey SA. A double-blind, placebo-controlled study of the effectiveness and safety of nizatidine in the prevention of postprandial heartburn. Arch Intern Med 1997;157:1594-9.

37. Pappa KA, Buaron K, Payne JE, Sirgo MA, Giefer EE. An evaluation of increasing doses of ranitidine for treatment of heartburn. Aliment Pharmacol Ther 1999;13:475-81.

38. Pappa KA, Gooch WM, Buaron K, Payne JE, Giefer EE, Sirgo MA, et al. Low-dose ranitidine for the relief of heartburn. Aliment Pharmacol Ther 1999;13:459-65.

39. Pappa KA, Williams BO, Payne JE, Buaron KS, Mussari KL, Ciociola AA. A double-blind, placebo-controlled study of the efficacy and safety of non-pre-scription ranitidine 75 mg in the prevention of meal-induced heartburn. Aliment Pharmacol Ther 1999;13:467-73.

40. Ciociola AA, Pappa KA, Sirgo MA. Nonprescription doses of ranitidine are effective in the relief of episodic heartburn. Am J Ther 2001;8:399-408.

41. Gottlieb S, Decktor DL, Eckert JM, Simon TJ, Stauffer L, Ciccone PE. Efficacy and tolerability of famotidine in preventing heartburn and related symptoms of upper gastrointestinal discomfort. Am J Ther 1995;2:314-9.

42. Simon TJ, Berlin RG, Gardner AH, Stauffer LA, Gould AL, Getson AJ. Self-directed treatment of intermittent heartburn: a randomized, multicenter, double-blind, placebo-controlled evaluation of antacid and low doses of an H(2)-receptor antagonist (famotidine). Am J Ther 1995;2:304-13.

43. Galmiche JP, Shi G, Simon B, Casset-Semanza F, Slama A. On-demand treatment of gastro-oesophageal reflux symptoms: a comparison of ranitidine 75 mg with cimetidine 200 mg or place-bo. Aliment Pharmacol Ther 1998;12:909-17.

44. Qvigstad G, Arnestad JS, Brenna E, Waldum HL. Treatment with proton pump inhibitors induces tolerance to histamine-2 receptor antagonists in Helicobacter pylori-negative patients. Scand J Gastroenterol 1998;33:1244-8.

45. Howden CW. Optimizing the pharmacology of acid control in acid-related disorders. Am J Gastroenterol 1997;92(suppl):17S-21S.

46. Sharma VK, Leontiadis GI, Howden CW. Meta-analysis of randomized controlled trials comparing standard clinical doses of omeprazole and lansopra-zole in erosive oesophagitis. Aliment Pharmacol Ther 2001;15:227-31.

47. Edwards SJ, Lind T, Lundell L. Systematic review of proton pump inhibitors for the acute treatment of reflux oesophagitis. Aliment Pharmacol Ther 2001;15:1729-36.

48. Dupas JL, Houcke P, Samoyeau R. Pantoprazole versus lansoprazole in French patients with reflux esophagi-tis. Gastroenterol Clin Biol 2001;25:245-50.

49. Castell DO, Kahrilas PJ, Richter JE, Vakil NB, Johnson DA, Zuckerman S, et al. Esomeprazole (40 mg) compared with lansoprazole (30 mg) in the treatment of erosive esophagitis. Am J Gastroenterol 2002;97:575-83.

50. Howden CW, Ballard ED, Robison W. Evidence for therapeutic equivalence of lansoprazole 30 mg and esomeprazole 40 mg in the treatment of erosive oesophagitis. Clin Drug Invest 2002;22:99-109.

51. Thjodleifsson B, Beker JA, Dekkers C, Bjaaland T, Finnegan V, Humphries TJ. Rabeprazole versus omeprazole in preventing relapse of erosive or ulcerative gastroesophageal reflux disease: a dou-ble-blind, multicenter, European trial. The European Rabeprazole Study Group. Dig Dis Sci 2000;45:845-53.

52. Carling L, Axelsson CK, Forssell H, Stubberod A, Kraglund K, Bonnevie O, et al. Lansoprazole and omeprazole in the prevention of relapse of reflux oesophagitis: a long-term comparative study. Aliment Pharmacol Ther 1998;12:985-90.

53. Chey WD, Inadmoni JM, Boojer AK, Fendrick AM. What do primary care physicians think about Barrett’s esoph-agus, the relationship between GERD and H. pylori, and treatment of nocturnal heartburn? Abstract presented at: DDW 2003; May 17-23, 2003; Orlando, Fla.

54. Sampliner RE and The Practice Parameters Committee of the American College of Gastroenterology. Updated guidelines for the diagnosis, surveillance, and therapy of Barrett’s esophagus. Am J Gastroenterol 2002;97:1888-95.

55. Spechler SJ, Lee E, Ahnen D, Goyal RK, Hirano I, Ramirez F, et al. Long-term outcome of medical and surgical therapies for gastroesophageal reflux disease: follow-up of a randomized controlled trial. JAMA 2001;285:2331-8.

56. Katz PO. Gastroesophageal reflux disease: new treatments. Rev Gastroenterol Disord 2002;2:66-74.

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The Journal of Family Practice - 52(3)
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The Journal of Family Practice - 52(3)
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240-247
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240-247
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