Recurrent abdominal pain after laparoscopic cholecystectomy

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Recurrent abdominal pain after laparoscopic cholecystectomy
Author(s)
Carole Macaron, MD
Mohammed A. Qadeer, MD, MPH
John J. Vargo, MD, MPH

Four months after undergoing laparoscopic cholecystectomy for symptomatic gallstones, an otherwise healthy 26-year-old woman begins to have episodes of epigastric and back pain similar to what she experienced before the surgery. The surgery was without complications, and her classic biliary colic disappeared afterward. Histologic evaluation of the surgical specimen revealed chronic cholecystitis with multiple small, mixed gallstones.

Now she describes a burning pain in her epigastrium and mid to upper back, starting about 30 minutes after a meal and lasting up to 4 hours. Sometimes it awakens her at night. She avoids eating for fear of inducing the pain. She has occasional chills but no fever, nausea, vomiting, jaundice, or changes in urine or stool color.

Three years ago she was diagnosed with a gastric ulcer induced by taking a nonsteroidal anti-inflammatory drug (NSAID). The ulcer was treated with a proton pump inhibitor for 1 month. She says the ulcer pain was dull and aching, different from her current pain.

Upper endoscopy 4 months ago (ie, before her laparoscopic cholecystectomy) showed no evidence of esophagitis or peptic ulcer disease.

Apart from her gallbladder operation, she has had no other surgery. According to the surgeon’s notes, intraoperative cholangiography was not performed, and no macroscopic changes of acute cholecystitis or difficult biliary anatomy were noted.

The patient does not smoke, does not drink alcohol, is not currently taking any medications, including NSAIDs or over-the-counter medications, and has not taken any recently. Her mother also had symptomatic gallstones requiring cholecystectomy.

On physical examination, only fever

On examination, her temperature is 101.2°F (38.4°C), blood pressure 117/80 mm Hg, heart rate 82 beats per minute, and blood oxygen saturation 99% on room air. Her weight is 138 lb (62.6 kg), height 5 feet 6 inches (168 cm).

There is no jaundice or pallor. Her heart and lung examinations are normal.

Her abdomen is soft and mildly tender to palpation of the epigastrium, with no distention or hepatosplenomegaly and no rebound tenderness or guarding. The scars from her laparoscopic surgery have healed well. Her bowel sounds are normal.

No costovertebral angle or spinal tenderness can be elicited.

Her laboratory values are shown in Table 1.

POSTCHOLECYSTECTOMY SYNDROME

1. After cholecystectomy, preoperative symptoms recur in what percentage of patients?

  • 10% to 40%
  • 50%
  • 60%
  • 80%

Postcholecystectomy syndrome—the recurrence of symptoms similar to those before the procedure—occurs in 10% to 40% of patients. The time to the onset of symptoms can range from 2 days to up to 25 years.1–4 Women may be at higher risk, with symptoms recurring in 43% vs 28% in men.5

Postcholecystectomy syndrome can have a biliary or a nonbiliary cause. Biliary causes include strictures, retained calculi, dropped calculi, tumors, sphincter of Oddi dysfunction, and calculi in the cystic duct remnant. Nonbiliary causes include functional and organic disorders such as peptic ulcer disease, gastroesophageal reflux, pancreatic disease, hepatocellular disorders, coronary artery disease, irritable bowel syndrome, and intercostal neuritis.

WHAT IS THE NEXT STEP?

2. Which is the most appropriate next step in the workup of this patient?

  • Ultrasonography of the right upper quadrant
  • Magnetic resonance cholangiopancreatography (MRCP)
  • Endoscopic retrograde cholangiopancreatography (ERCP)
  • Observation and reassurance
  • Review the operative record and consult with the surgeon

Although the patient is presenting with pain and fever, two features of the classic Charcot triad (pain, fever, jaundice) seen in cholangitis (infection of a bile duct), and although cholangitis almost confirms the diagnosis of common bile duct stones in a patient with gallstones (before or after cholecystectomy), other diagnoses to consider are bile duct injury, bile leak, and biloma.

Biloma can be detected with ultrasonography. Bile duct injuries are identified intraoperatively in up to 25% of patients. For those with an unrecognized injury, the clinical presentation is variable and depends on the type of injury. If a bile leak is present, patients present early, at a median of 3 days postoperatively. However, our patient presented with symptoms 4 months after her surgery. Patients with bile duct strictures without bile leak have a longer symptom-free interval and usually present with signs of biliary obstruction. Ultrasonography can then detect biliary dilatation.6

It would be very helpful to review the operative record and to talk to the surgeon to confirm that intraoperative cholangiography had not been done and to determine the level of difficulty of the surgery. (Intraoperative cholangiography involves the introduction of contrast dye into the biliary system by cannulation of the cystic duct or by direct injection into the common bile duct. An intraoperative cholangiogram is considered normal if the entire intrahepatic and extrahepatic biliary tree is seen to be filled with contrast.) A normal cholangiogram has a negative predictive value of 99.8% for the detection of ductal stones. Thus, a normal intraoperative cholangiogram can prevent unnecessary postoperative ECRP, since it almost always indicates a clean bile duct.7

Ultrasonography of the right upper quadrant has a low sensitivity (< 50%) for detecting common bile duct stones. However, it is highly operator-dependent, and it may be twice as sensitive if done by expert radiologists than by less experienced ones. Its limitations include poor visualization of the distal portion of the duct and low sensitivity in patients in whom the common bile duct is minimally dilated and also in patients with small stones. In most studies, however, it had a very high specificity—ie, greater than 95%.8

MRCP has a sensitivity of 82.6% and a specificity of 97.5% in detecting stones in the common bile duct.9 Therefore, normal results on abdominal ultrasonography and MRCP do not completely rule out stones.

Although this patient has a high pretest probability of having common bile duct stones, ERCP should be done only after a thorough review of the previous operative procedure.

Observation and reassurance are not appropriate in a patient with cholangitis, such as this patient, because waiting increases the risk of septicemia.

 

 

The patient undergoes ERCP with stone removal

Review of the operative report and discussion with the surgeon confirm that the laparoscopic procedure was uneventful and that intraoperative cholangiography was not done.

Therefore, the patient undergoes ERCP. The major papilla is normal. Cholangiography reveals nondilated common bile and intrahepatic ducts, with faint filling defects in the mid to distal common bile duct. Endoscopic sphincterotomy is performed, and three small stones are extracted from the common bile duct. Repeat balloon-occlusion cholangiography is normal.

The patient tolerates the procedure well and resumes a normal diet and normal activities.

Her pain persists, prompting an emergency room visit

Five days after her ERCP procedure, however, the same burning epigastric pain returns. As before, the pain occurs after eating and does not occur with fasting. At this time, she has no fever or chills.

The patient continues to have recurrent episodes of pain, on one occasion so severe she visits the emergency department. During this visit she reports she has no symptoms other than pain, and the examination is normal. Laboratory tests (Table 2) show that her liver function measures have normalized.

WHAT IS CAUSING HER PAIN?

3. Which is the most likely cause of her persistent pain?

  • Acute pancreatitis after ERCP
  • Peptic ulcer disease
  • Sphincter of Oddi dysfunction
  • Biliary stones

The most likely cause is persistent biliary stones. The common bile duct was recently explored and stones were removed, but she may still have stones in the intrahepatic ducts or in the cystic duct remnant, both of which were unopacified during the ERCP procedure, indicating that either the test was incomplete or a stone is obstructing the passage of contrast. Her persistent symptoms warrant repeating her liver function tests.

Acute pancreatitis is the most common and feared complication of ERCP, and it should be suspected in any patient who develops abdominal pain within 6 hours of the procedure. It is much less likely to develop after 12 hours, however. Risk factors for post-ERCP pancreatitis include patient factors (young age, female sex, history of recurrent pancreatitis), procedural factors (difficult cannulation, minor papilla sphincterotomy), and, less likely, operator-related factors.10–13 In general, the more likely a patient is to have an abnormal and irregular common bile duct or pancreatic duct, the lower the risk of post-ERCP pancreatitis. The importance of operator-dependent factors is not yet clear.10–13

Despite the postprandial pattern of our patient’s pain and her history of gastric ulcer, peptic ulcer disease is unlikely in view of a normal esophagogastroduodenoscopic examination done 4 months earlier, and since she has no recent exposure to NSAIDs.

Sphincter of Oddi dysfunction may explain her symptoms, but she recently underwent endoscopic sphincterotomy, which is regarded as the most definitive treatment.14

WHAT SHOULD BE DONE NEXT?

4. What would be the best next step in her management?

  • Repeat ERCP
  • MRCP
  • Endoscopic ultrasonography
  • Observation and reassurance

MRCP is the most appropriate next step, given her recurrent symptoms. Repeat ERCP is not appropriate, since there is no evidence of cholangitis, and since her liver function tests had completely normalized.

A recent systematic review of endoscopic ultrasonography and MRCP for diagnosing choledocholithiasis found both tests to be highly accurate, with no statistically significant differences in sensitivity or specificity between the two.15 However, MRCP has the advantage of being noninvasive and of being able to show intrahepatic stones.

Park et al,16 in a prospective study of 66 patients with primary intrahepatic stones, concluded that MRCP findings were comparable to those of percutaneous transhepatic cholangioscopy, the reference standard for locating intrahepatic stones. The sensitivity, specificity, and accuracy of MRCP for detecting and locating intrahepatic stones were high (97%, 99%, and 98%, respectively).16 However, after sphincterotomy, pneumobilia may create an appearance that can be mistaken for intraductal stones.

Figure 1. Magnetic resonance cholangiopancreatography shows a normal biliary tree (arrow) and pancreatic duct. The cystic duct cannot be seen.
Merely reassuring the patient is not appropriate at this point, given her level of pain.

She undergoes MRCP

Figure 2. Ultrasonography of the right upper quadrant shows a nondilated common bile duct 4 mm in diameter (arrow). No stones are visible.
MRCP shows a normal biliary tree without stones (Figure 1). Similarly, ultrasonography of the right upper quadrant shows no stones and a nondilated common bile duct (Figure 2).

The patient continues to have pain, and she has lost 5 pounds because she is still avoiding eating. At this point, she is beginning to wonder if her symptoms are psychogenic, since all the test results have been normal.

ERCP, MRCP, ULTRASONOGRAPHY?

5. What would be the best next step?

  • Reassurance
  • Referral to a psychiatrist
  • Referral to a pain management clinic
  • Endoscopic ultrasonography
  • Repeat ERCP

Endoscopic ultrasonography is needed to look for cystic duct stones. Although several tests have shown normal results, the patient’s pain continues as in the previous episodes, making stone disease the most likely cause.

Although no stones were seen on MRCP and ultrasonography, a detailed evaluation for stones in a cystic duct or retained gallbladder remnant was not done satisfactorily.

Reassurance and referral to a psychiatrist or pain management clinic are not appropriate, since an organic cause of her pain has not been completely ruled out.

Figure 3. Endoscopic ultrasonography from the duodenal bulb shows a 7-mm stone (arrow) in the cystic duct remnant or gallbladder remnant.
ERCP should not be used as a diagnostic test in a situation such as this.

Findings on endoscopic ultrasonography

Endoscopic ultrasonography is performed and reveals a large (7-mm) stone in the area of the cystic duct remnant or gallbladder remnant (Figure 3). The common bile duct is normal.

 

 

CAUSES OF RETAINED GALLBLADDER AND CYSTIC DUCT REMNANT

6. What may have predisposed this patient to a retained gallbladder or cystic duct remnant after her surgery?

  • Laparoscopic cholecystectomy
  • Not doing intraoperative cholangiography
  • Cholecystectomy for acute cholecystitis
  • All of the above

All of the above may have contributed.

Postcholecystectomy syndrome can pose a diagnostic and therapeutic challenge, as in our patient. Although it has been reported since the advent of the operation, it is more common after laparoscopic cholecystectomy than after open surgery. One possible cause is stones in a cystic duct remnant, ie, a stub longer than 1 cm.

During open cholecystectomy, the cystic duct is ligated and cut as close to the common bile duct as possible, leaving only a small remnant. In laparoscopic cholecystectomy, it is divided closer to the gallbladder to avoid iatrogenic injury to the common bile duct, leaving a longer remnant. A long cystic duct remnant can be prevented by accurately locating the junction of the gallbladder and the cystic duct during cholecystectomy and by routinely doing intraoperative cholangiography. The presence of stones in a cystic duct or retained gallbladder remnant is a rare cause of postcholecystectomy syndrome, and suspicion is required to make the diagnosis.17–19

We should note that stones may also lurk in the short cystic duct remnant left after open cholecystectomy. In fact, the first case of cystic duct remnant, the so-called reformed gallbladder containing stones, was described in 1912 by Flörcken.20

Intraoperative cholangiography was introduced in 1931 by Mirizzi,21 who recommended its routine use. Since the advent of laparoscopic cholecystectomy in 1988, the routine use of intraoperative cholangiography has been debated. Advocates point to its ability to detect unsuspected calculi and to delineate the biliary anatomy, thus reducing the risk of biliary duct injury.7,22–25 Those who argue against its routine use emphasize the low reported rates of unsuspected stones in the common bile duct (2% to 3%), a longer operative time, the additional cost, and false-positive results that may lead to unnecessary common bile duct exploration. Another argument against its routine use is that most small ductal stones pass spontaneously without significant sequelae.26–28 Surgeons who use intraoperative cholangiography only selectively use it in patients with unclear biliary anatomy and preoperative biochemical or radiologic evidence of choledocholithiasis.

Figure 4. Endoscopic retrograde cholangiopancreatography shows an oval filling defect in the cystic duct remnant at its insertion into the common bile duct (arrow).
Another potential explanation for the retained gallbladder remnant is that the cholecystectomy was done while the patient had acute cholecystitis, in which inflammation may obscure anatomic landmarks. Hence, cholangiography during laparoscopic cholecystectomy has been widely recognized as a means of delineating the biliary anatomy.

Case continued: She undergoes repeat ERCP

Figure 5. Endoscopic retrograde cholangiopancreatography reveals a long duct remnant (red arrow) and a small gallbladder remnant (black arrow). The stone has already been extracted.
The patient undergoes ERCP again (Figure 4 and Figure 5). Cholangiography shows a normal common bile duct with low insertion of the cystic duct and an oval filling defect in the cystic duct just proximal to its insertion into the common bile duct. Cystic duct opacification reveals a long cystic duct remnant and a small gallbladder remnant. The stone in the cystic duct is successfully removed.

IF STONES ARE DIFFICULT TO EXTRACT

7. If the cystic duct stone were not amenable to endoscopic extraction, what would be the best alternative?

  • Extracorporeal shock-wave lithotripsy (ESWL)
  • Endoscopic biliary laser lithotripsy
  • Repeat laparoscopic cholecystectomy
  • All of the above

All of the above are alternatives.

A symptomatic stone in a cystic duct remnant is uncommon and is mentioned in the literature only in case series and case reports.

ESWL is effective for treating bile duct calculi.29 In a cohort of 239 patients with bile duct stones treated by ESWL, Benninger et al30 concluded that endoscopy plus ESWL was a definitive treatment for all patients except one, who subsequently underwent cholecystectomy. Once fragmented, the stones are extracted endoscopically.

Another fragmentation technique that can be offered to patients with stones in the cystic duct that are difficult to extract is contact fragmentation with a holmium laser placed in a transpapillary position under visual guidance.17

Repeat cholecystectomy with removal of stones in the cystic duct remnant (and removal of retained gallbladder remnants and reduction of the cystic duct remnant) has good postoperative results.17,18,31,32

After incomplete cholecystectomy, the cystic duct remnant and the Calot (cystohepatic) triangle are surrounded by inflamed scar tissue, and this was thought to make laparoscopic reoperation difficult.33 However, with advances in surgical technique and increasing experience of surgeons, repeat cholecystectomy can be done laparoscopically. It has now been suggested that laparoscopic exploration to remove the gallbladder remnants is safe and feasible in such patients.34,35

Discharge and follow-up

The patient is discharged home after the procedure. She is still free of symptoms 31 months later.

 

 

LESSONS LEARNED

Remnant cystic duct stones are uncommon

The estimated incidence of a retained calculus within the cystic duct remnant after cholecystectomy is less than 2.5%.2,36 In a series of 322 patients who underwent repeat surgery because of postcholecystectomy syndrome, Rogy et al36 found only 8 who had a stone in the cystic duct or gallbladder remnant, and in a series of 371 patients, Zhou el al2 found 4 who had a stone in the cystic duct remnant.

Stones in the cystic duct remnant are difficult to diagnose

Diagnosing stones in surgical remnants of the cystic duct or gallbladder can be difficult. The sensitivity of abdominal ultrasonography in detecting cystic duct stones is low—only 27% in one study, with a specificity of 100% and an accuracy of 75%.37 Ultrasonography may occasionally suggest cystic duct stones by showing an acoustic shadow in the anatomic region of the cystic duct. However, the results should be interpreted with caution.

Determining the accuracy of ERCP and MRCP in detecting cystic duct remnant stones is also difficult, as few cases have been reported and data may be conflicting. In a review of seven patients confirmed to have retained stones in a surgical remnant, Walsh et al17 found that ERCP correctly diagnosed the retained stone in only four out of six patients; MRCP was done in one patient, and it was read as normal.

In three cases of stones in a postsurgical gallbladder remnant, Hassan and Vilmann38 reported that ERCP and MRCP failed to identify the gallbladder remnant in two out of three cases, likely because the remaining structures are small. The diagnosis was finally made by endoscopic ultrasonography, which the authors concluded was a valuable method to visualize a small gallbladder remnant with stones.

Greater suspicion is needed in patients with typical biliary colic after cholecystectomy

Retained gallbladder remnant is described in the literature as a latent complication. The main problem is not the remnant itself but the chance that it harbors retained stones, which can lead to dilatation and inflammation of the remnant.

The patient can develop symptoms of acute cholecystitis or even acute cholangitis if the stone migrates to the common bile duct. Symptoms can develop as early as 2 weeks or as late as 25 years after laparoscopic cholecystectomy.

Endoscopic ultrasonography may be the best way to look for these remnant stones and to evaluate the bile duct and pancreas. Therefore, it should be part of the diagnostic algorithm in the evaluation of postcholecystectomy pain.

Mixed results with ERCP for extracting cystic duct stones

In case reports of cystic duct calculi after cholecystectomy, ERCP by itself has had mixed results. This traditional means of removing stones may succeed, as in our case. However, the success rate depends largely on anatomic factors such as the position of the stone in the cystic duct, the degree of stone impaction, the diameter of the cystic duct, and the number of valves in the duct.17

Stones in the cystic duct that cannot be extracted with ERCP may benefit from fragmentation techniques in situ via holmium laser followed by endoscopic extraction.

Repeat cholecystectomy is generally advised for any residual gallbladder, and it can be done laparoscopically.

References
  1. Lehman GA, Sherman S. Sphincter of Oddi dysfunction (postcholecystectomy syndrome). In:Yamada T, editor. Textbook of Gastroenterology. 2nd ed. Philadelphia: Lippincott; 1995:22512262.
  2. Zhou PH, Liu FL, Yao LQ, Qin XY. Endoscopic diagnosis and treatment of post-cholecystectomy syndrome. Hepatobiliary Pancreat Dis Int 2003; 2:117120.
  3. Mergener K, Clavien PA, Branch MS, Baillie J. A stone in a grossly dilated cystic duct stump: a rare cause of postcholecystectomy pain. Am J Gastroenterol 1999; 94:229231.
  4. Goenka MK, Kochhar R, Nagi B, Bhasin DK, Chowdhury A, Singh K. Endoscopic retrograde cholangiopancreatography in postcholecystectomy syndrome. J Assoc Physicians India 1996; 44:119122.
  5. Bodvall B, Overgaard B. Cystic duct remnant after cholecystectomy: incidence studied by cholegraphy in 500 cases, and significance in 103 reoperations. Ann Surg 1966; 163:382390.
  6. Bergman JJ, van den Brink GR, Rauws EA, et al. Treatment of bile duct lesions after laparoscopic cholecystectomy. Gut 1996; 38:141147.
  7. Nickkholgh A, Soltaniyekta S, Kalbasi H. Routine versus selective intraoperative cholangiography during laparoscopic cholecystectomy: a survey of 2,130 patients undergoing laparoscopic cholecystectomy. Surg Endosc 2006; 20:868874.
  8. Gandolfi L, Torresan F, Solmi L, Puccetti A. The role of ultrasound in biliary and pancreatic diseases. Eur J Ultrasound 2003; 16:141159.
  9. Al Samaraee A, Khan U, Almashta Z, Yiannakou Y. Preoperative diagnosis of choledocholithiasis: the role of MRCP. Br J Hosp Med (Lond) 2009; 70:339343.
  10. Freeman ML, DiSario JA, Nelson DB, et al. Risk factors for post-ERCP pancreatitis: a prospective, multicenter study. Gastrointest Endosc 2001; 54:425434.
  11. Cheng CL, Sherman S, Watkins JL, et al. Risk factors for post-ERCP pancreatitis: a prospective multicenter study. Am J Gastroenterol 2006; 101:139147.
  12. Mehta SN, Pavone E, Barkun JS, Bouchard S, Barkun AN. Predictors of post-ERCP complications in patients with suspected choledocholithiasis. Endoscopy 1998; 30:457463.
  13. Badalov N, Tenner S, Baillie J. The prevention, recognition and treatment of post-ERCP pancreatitis. JOP 2009; 10:8897.
  14. Geenen JE, Hogan WJ, Dodds WJ, Toouli J, Venu RP. The efficacy of endoscopic sphincterotomy after cholecystectomy in patients with sphincter-of-Oddi dysfunction. N Engl J Med 1989; 320:8287.
  15. Verma D, Kapadia A, Eisen GM, Adler DG. EUS vs MRCP for detection of choledocholithiasis. Gastrointest Endosc 2006; 64:248254.
  16. Park DH, Kim MH, Lee SS, et al. Accuracy of magnetic resonance cholangiopancreatography for locating hepatolithiasis and detecting accompanying biliary strictures. Endoscopy 2004; 36:987992.
  17. Walsh RM, Ponsky JL, Dumot J. Retained gallbladder/cystic duct remnant calculi as a cause of postcholecystectomy pain. Surg Endosc 2002; 16:981984.
  18. Tantia O, Jain M, Khanna S, Sen B. Post cholecystectomy syndrome: role of cystic duct stump and re-intervention by laparoscopic surgery. J Minim Access Surg 2008; 4:7175.
  19. Palanivelu C, Rangarajan M, Jategaonkar PA, Madankumar MV, Anand NV. Laparoscopic management of remnant cystic duct calculi: a retrospective study. Ann R Coll Surg Engl 2009; 91:2529.
  20. Flörcken H. Gallenblasenregeneration mit Steinrecidiv nach Cholecystectomie. Deutsch Z Chir 1912; 113:604.
  21. Mirizzi PL. La colangiografía durante las operaciones de las vias biliares. Bol Soc Cirug Buenos Aires 1932; 16:1113.
  22. Soper NJ, Brunt LM. The case for routine operative cholangiography during laparoscopic cholecystectomy. Surg Clin North Am 1994; 74:953959.
  23. Cuschieri A, Shimi S, Banting S, Nathanson LK, Pietrabissa A. Intraoperative cholangiography during laparoscopic cholecystectomy. Routine vs selective policy. Surg Endosc 1994; 8:302305.
  24. Woods MS, Traverso LW, Kozarek RA, et al. Biliary tract complications of laparoscopic cholecystectomy are detected more frequently with routine intraoperative cholangiography. Surg Endosc 1995; 9:10761080.
  25. Vezakis A, Davides D, Ammori BJ, Martin IG, Larvin M, McMahon MJ. Intraoperative cholangiography during laparoscopic cholecystectomy. Surg Endosc 2000; 14:11181122.
  26. Ladocsi LT, Benitez LD, Filippone DR, Nance FC. Intraoperative cholangiography in laparoscopic cholecystectomy: a review of 734 consecutive cases. Am Surg 1997; 63:150156.
  27. Clair DG, Brooks DC. Laparoscopic cholangiography. The case for a selective approach. Surg Clin North Am 1994; 74:961966.
  28. Collins C, Maguire D, Ireland A, Fitzgerald E, O’Sullivan GC. A prospective study of common bile duct calculi in patients undergoing laparoscopic cholecystectomy: natural history of choledocholithiasis revisited. Ann Surg 2004; 239:2833.
  29. Ponsky LE, Geisinger MA, Ponsky JL, Streem SB. Contemporary ‘urologic’ intervention in the pancreaticobiliary tree. Urology 2001; 57:2125.
  30. Benninger J, Rabenstein T, Farnbacher M, Keppler J, Hahn EG, Schneider HT. Extracorporeal shockwave lithotripsy of gallstones in cystic duct remnants and Mirizzi syndrome. Gastrointest Endosc 2004; 60:454459.
  31. Demetriades H, Pramateftakis MG, Kanellos I, Angelopoulos S, Mantzoros I, Betsis D. Retained gallbladder remnant after laparoscopic cholecystectomy. J Laparoendosc Adv Surg Tech A 2008; 18:276279.
  32. Shaw C, O’Hanlon DM, Fenlon HM, McEntee GP. Cystic duct remnant and the ‘post-cholecystectomy syndrome. ’ Hepatogastroenterology 2004; 51:3638.
  33. Rozsos I, Magyaródi Z, Orbán P. Cystic duct syndrome and minimally invasive surgery. [Hungarian] Orv Hetil 1997; 138:23972401.
  34. Chowbey PK, Bandyopadhyay SK, Sharma A, Khullar R, Soni V, Baijal M. Laparoscopic reintervention for residual gallstone disease. Surg Laparosc Endosc Percutan Tech 2003; 13:3135.
  35. Clemente G, Giuliante F, Cadeddu F, Nuzzo G. Laparoscopic removal of gallbladder remnant and long cystic stump. Endoscopy 2001; 33:814815.
  36. Rogy MA, Függer R, Herbst F, Schulz F. Reoperation after cholecystectomy. The role of the cystic duct stump. HPB Surg 1991; 4:129134.
  37. Laing FC, Jeffrey RB. Choledocholithiasis and cystic duct obstruction: difficult ultrasonographic diagnosis. Radiology 1983; 146:475479.
  38. Hassan H, Vilmann P. Insufficient cholecystectomy diagnosed by endoscopic ultrasonography. Endoscopy 2004; 36:236238.
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CArole Macaron, MD
Department of Internal Medicine, Cleveland Clinic

Mohammed A. Qadeer, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Section of Endoscopy, Department of Gastroenterology and Hepatology, Digestive Disease Institute, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail vargoj@ccf.org

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Cleveland Clinic Journal of Medicine - 78(3)
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Cleveland Clinic Journal of Medicine
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Imaging
Women's Health
Pain
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IM Board Review
Symptoms to Diagnosis
Author(s)
Carole Macaron, MD
Mohammed A. Qadeer, MD, MPH
John J. Vargo, MD, MPH
Author(s)
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Mohammed A. Qadeer, MD, MPH
John J. Vargo, MD, MPH
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CArole Macaron, MD
Department of Internal Medicine, Cleveland Clinic

Mohammed A. Qadeer, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Section of Endoscopy, Department of Gastroenterology and Hepatology, Digestive Disease Institute, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail vargoj@ccf.org

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Department of Internal Medicine, Cleveland Clinic

Mohammed A. Qadeer, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Section of Endoscopy, Department of Gastroenterology and Hepatology, Digestive Disease Institute, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail vargoj@ccf.org

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Four months after undergoing laparoscopic cholecystectomy for symptomatic gallstones, an otherwise healthy 26-year-old woman begins to have episodes of epigastric and back pain similar to what she experienced before the surgery. The surgery was without complications, and her classic biliary colic disappeared afterward. Histologic evaluation of the surgical specimen revealed chronic cholecystitis with multiple small, mixed gallstones.

Now she describes a burning pain in her epigastrium and mid to upper back, starting about 30 minutes after a meal and lasting up to 4 hours. Sometimes it awakens her at night. She avoids eating for fear of inducing the pain. She has occasional chills but no fever, nausea, vomiting, jaundice, or changes in urine or stool color.

Three years ago she was diagnosed with a gastric ulcer induced by taking a nonsteroidal anti-inflammatory drug (NSAID). The ulcer was treated with a proton pump inhibitor for 1 month. She says the ulcer pain was dull and aching, different from her current pain.

Upper endoscopy 4 months ago (ie, before her laparoscopic cholecystectomy) showed no evidence of esophagitis or peptic ulcer disease.

Apart from her gallbladder operation, she has had no other surgery. According to the surgeon’s notes, intraoperative cholangiography was not performed, and no macroscopic changes of acute cholecystitis or difficult biliary anatomy were noted.

The patient does not smoke, does not drink alcohol, is not currently taking any medications, including NSAIDs or over-the-counter medications, and has not taken any recently. Her mother also had symptomatic gallstones requiring cholecystectomy.

On physical examination, only fever

On examination, her temperature is 101.2°F (38.4°C), blood pressure 117/80 mm Hg, heart rate 82 beats per minute, and blood oxygen saturation 99% on room air. Her weight is 138 lb (62.6 kg), height 5 feet 6 inches (168 cm).

There is no jaundice or pallor. Her heart and lung examinations are normal.

Her abdomen is soft and mildly tender to palpation of the epigastrium, with no distention or hepatosplenomegaly and no rebound tenderness or guarding. The scars from her laparoscopic surgery have healed well. Her bowel sounds are normal.

No costovertebral angle or spinal tenderness can be elicited.

Her laboratory values are shown in Table 1.

POSTCHOLECYSTECTOMY SYNDROME

1. After cholecystectomy, preoperative symptoms recur in what percentage of patients?

  • 10% to 40%
  • 50%
  • 60%
  • 80%

Postcholecystectomy syndrome—the recurrence of symptoms similar to those before the procedure—occurs in 10% to 40% of patients. The time to the onset of symptoms can range from 2 days to up to 25 years.1–4 Women may be at higher risk, with symptoms recurring in 43% vs 28% in men.5

Postcholecystectomy syndrome can have a biliary or a nonbiliary cause. Biliary causes include strictures, retained calculi, dropped calculi, tumors, sphincter of Oddi dysfunction, and calculi in the cystic duct remnant. Nonbiliary causes include functional and organic disorders such as peptic ulcer disease, gastroesophageal reflux, pancreatic disease, hepatocellular disorders, coronary artery disease, irritable bowel syndrome, and intercostal neuritis.

WHAT IS THE NEXT STEP?

2. Which is the most appropriate next step in the workup of this patient?

  • Ultrasonography of the right upper quadrant
  • Magnetic resonance cholangiopancreatography (MRCP)
  • Endoscopic retrograde cholangiopancreatography (ERCP)
  • Observation and reassurance
  • Review the operative record and consult with the surgeon

Although the patient is presenting with pain and fever, two features of the classic Charcot triad (pain, fever, jaundice) seen in cholangitis (infection of a bile duct), and although cholangitis almost confirms the diagnosis of common bile duct stones in a patient with gallstones (before or after cholecystectomy), other diagnoses to consider are bile duct injury, bile leak, and biloma.

Biloma can be detected with ultrasonography. Bile duct injuries are identified intraoperatively in up to 25% of patients. For those with an unrecognized injury, the clinical presentation is variable and depends on the type of injury. If a bile leak is present, patients present early, at a median of 3 days postoperatively. However, our patient presented with symptoms 4 months after her surgery. Patients with bile duct strictures without bile leak have a longer symptom-free interval and usually present with signs of biliary obstruction. Ultrasonography can then detect biliary dilatation.6

It would be very helpful to review the operative record and to talk to the surgeon to confirm that intraoperative cholangiography had not been done and to determine the level of difficulty of the surgery. (Intraoperative cholangiography involves the introduction of contrast dye into the biliary system by cannulation of the cystic duct or by direct injection into the common bile duct. An intraoperative cholangiogram is considered normal if the entire intrahepatic and extrahepatic biliary tree is seen to be filled with contrast.) A normal cholangiogram has a negative predictive value of 99.8% for the detection of ductal stones. Thus, a normal intraoperative cholangiogram can prevent unnecessary postoperative ECRP, since it almost always indicates a clean bile duct.7

Ultrasonography of the right upper quadrant has a low sensitivity (< 50%) for detecting common bile duct stones. However, it is highly operator-dependent, and it may be twice as sensitive if done by expert radiologists than by less experienced ones. Its limitations include poor visualization of the distal portion of the duct and low sensitivity in patients in whom the common bile duct is minimally dilated and also in patients with small stones. In most studies, however, it had a very high specificity—ie, greater than 95%.8

MRCP has a sensitivity of 82.6% and a specificity of 97.5% in detecting stones in the common bile duct.9 Therefore, normal results on abdominal ultrasonography and MRCP do not completely rule out stones.

Although this patient has a high pretest probability of having common bile duct stones, ERCP should be done only after a thorough review of the previous operative procedure.

Observation and reassurance are not appropriate in a patient with cholangitis, such as this patient, because waiting increases the risk of septicemia.

 

 

The patient undergoes ERCP with stone removal

Review of the operative report and discussion with the surgeon confirm that the laparoscopic procedure was uneventful and that intraoperative cholangiography was not done.

Therefore, the patient undergoes ERCP. The major papilla is normal. Cholangiography reveals nondilated common bile and intrahepatic ducts, with faint filling defects in the mid to distal common bile duct. Endoscopic sphincterotomy is performed, and three small stones are extracted from the common bile duct. Repeat balloon-occlusion cholangiography is normal.

The patient tolerates the procedure well and resumes a normal diet and normal activities.

Her pain persists, prompting an emergency room visit

Five days after her ERCP procedure, however, the same burning epigastric pain returns. As before, the pain occurs after eating and does not occur with fasting. At this time, she has no fever or chills.

The patient continues to have recurrent episodes of pain, on one occasion so severe she visits the emergency department. During this visit she reports she has no symptoms other than pain, and the examination is normal. Laboratory tests (Table 2) show that her liver function measures have normalized.

WHAT IS CAUSING HER PAIN?

3. Which is the most likely cause of her persistent pain?

  • Acute pancreatitis after ERCP
  • Peptic ulcer disease
  • Sphincter of Oddi dysfunction
  • Biliary stones

The most likely cause is persistent biliary stones. The common bile duct was recently explored and stones were removed, but she may still have stones in the intrahepatic ducts or in the cystic duct remnant, both of which were unopacified during the ERCP procedure, indicating that either the test was incomplete or a stone is obstructing the passage of contrast. Her persistent symptoms warrant repeating her liver function tests.

Acute pancreatitis is the most common and feared complication of ERCP, and it should be suspected in any patient who develops abdominal pain within 6 hours of the procedure. It is much less likely to develop after 12 hours, however. Risk factors for post-ERCP pancreatitis include patient factors (young age, female sex, history of recurrent pancreatitis), procedural factors (difficult cannulation, minor papilla sphincterotomy), and, less likely, operator-related factors.10–13 In general, the more likely a patient is to have an abnormal and irregular common bile duct or pancreatic duct, the lower the risk of post-ERCP pancreatitis. The importance of operator-dependent factors is not yet clear.10–13

Despite the postprandial pattern of our patient’s pain and her history of gastric ulcer, peptic ulcer disease is unlikely in view of a normal esophagogastroduodenoscopic examination done 4 months earlier, and since she has no recent exposure to NSAIDs.

Sphincter of Oddi dysfunction may explain her symptoms, but she recently underwent endoscopic sphincterotomy, which is regarded as the most definitive treatment.14

WHAT SHOULD BE DONE NEXT?

4. What would be the best next step in her management?

  • Repeat ERCP
  • MRCP
  • Endoscopic ultrasonography
  • Observation and reassurance

MRCP is the most appropriate next step, given her recurrent symptoms. Repeat ERCP is not appropriate, since there is no evidence of cholangitis, and since her liver function tests had completely normalized.

A recent systematic review of endoscopic ultrasonography and MRCP for diagnosing choledocholithiasis found both tests to be highly accurate, with no statistically significant differences in sensitivity or specificity between the two.15 However, MRCP has the advantage of being noninvasive and of being able to show intrahepatic stones.

Park et al,16 in a prospective study of 66 patients with primary intrahepatic stones, concluded that MRCP findings were comparable to those of percutaneous transhepatic cholangioscopy, the reference standard for locating intrahepatic stones. The sensitivity, specificity, and accuracy of MRCP for detecting and locating intrahepatic stones were high (97%, 99%, and 98%, respectively).16 However, after sphincterotomy, pneumobilia may create an appearance that can be mistaken for intraductal stones.

Figure 1. Magnetic resonance cholangiopancreatography shows a normal biliary tree (arrow) and pancreatic duct. The cystic duct cannot be seen.
Merely reassuring the patient is not appropriate at this point, given her level of pain.

She undergoes MRCP

Figure 2. Ultrasonography of the right upper quadrant shows a nondilated common bile duct 4 mm in diameter (arrow). No stones are visible.
MRCP shows a normal biliary tree without stones (Figure 1). Similarly, ultrasonography of the right upper quadrant shows no stones and a nondilated common bile duct (Figure 2).

The patient continues to have pain, and she has lost 5 pounds because she is still avoiding eating. At this point, she is beginning to wonder if her symptoms are psychogenic, since all the test results have been normal.

ERCP, MRCP, ULTRASONOGRAPHY?

5. What would be the best next step?

  • Reassurance
  • Referral to a psychiatrist
  • Referral to a pain management clinic
  • Endoscopic ultrasonography
  • Repeat ERCP

Endoscopic ultrasonography is needed to look for cystic duct stones. Although several tests have shown normal results, the patient’s pain continues as in the previous episodes, making stone disease the most likely cause.

Although no stones were seen on MRCP and ultrasonography, a detailed evaluation for stones in a cystic duct or retained gallbladder remnant was not done satisfactorily.

Reassurance and referral to a psychiatrist or pain management clinic are not appropriate, since an organic cause of her pain has not been completely ruled out.

Figure 3. Endoscopic ultrasonography from the duodenal bulb shows a 7-mm stone (arrow) in the cystic duct remnant or gallbladder remnant.
ERCP should not be used as a diagnostic test in a situation such as this.

Findings on endoscopic ultrasonography

Endoscopic ultrasonography is performed and reveals a large (7-mm) stone in the area of the cystic duct remnant or gallbladder remnant (Figure 3). The common bile duct is normal.

 

 

CAUSES OF RETAINED GALLBLADDER AND CYSTIC DUCT REMNANT

6. What may have predisposed this patient to a retained gallbladder or cystic duct remnant after her surgery?

  • Laparoscopic cholecystectomy
  • Not doing intraoperative cholangiography
  • Cholecystectomy for acute cholecystitis
  • All of the above

All of the above may have contributed.

Postcholecystectomy syndrome can pose a diagnostic and therapeutic challenge, as in our patient. Although it has been reported since the advent of the operation, it is more common after laparoscopic cholecystectomy than after open surgery. One possible cause is stones in a cystic duct remnant, ie, a stub longer than 1 cm.

During open cholecystectomy, the cystic duct is ligated and cut as close to the common bile duct as possible, leaving only a small remnant. In laparoscopic cholecystectomy, it is divided closer to the gallbladder to avoid iatrogenic injury to the common bile duct, leaving a longer remnant. A long cystic duct remnant can be prevented by accurately locating the junction of the gallbladder and the cystic duct during cholecystectomy and by routinely doing intraoperative cholangiography. The presence of stones in a cystic duct or retained gallbladder remnant is a rare cause of postcholecystectomy syndrome, and suspicion is required to make the diagnosis.17–19

We should note that stones may also lurk in the short cystic duct remnant left after open cholecystectomy. In fact, the first case of cystic duct remnant, the so-called reformed gallbladder containing stones, was described in 1912 by Flörcken.20

Intraoperative cholangiography was introduced in 1931 by Mirizzi,21 who recommended its routine use. Since the advent of laparoscopic cholecystectomy in 1988, the routine use of intraoperative cholangiography has been debated. Advocates point to its ability to detect unsuspected calculi and to delineate the biliary anatomy, thus reducing the risk of biliary duct injury.7,22–25 Those who argue against its routine use emphasize the low reported rates of unsuspected stones in the common bile duct (2% to 3%), a longer operative time, the additional cost, and false-positive results that may lead to unnecessary common bile duct exploration. Another argument against its routine use is that most small ductal stones pass spontaneously without significant sequelae.26–28 Surgeons who use intraoperative cholangiography only selectively use it in patients with unclear biliary anatomy and preoperative biochemical or radiologic evidence of choledocholithiasis.

Figure 4. Endoscopic retrograde cholangiopancreatography shows an oval filling defect in the cystic duct remnant at its insertion into the common bile duct (arrow).
Another potential explanation for the retained gallbladder remnant is that the cholecystectomy was done while the patient had acute cholecystitis, in which inflammation may obscure anatomic landmarks. Hence, cholangiography during laparoscopic cholecystectomy has been widely recognized as a means of delineating the biliary anatomy.

Case continued: She undergoes repeat ERCP

Figure 5. Endoscopic retrograde cholangiopancreatography reveals a long duct remnant (red arrow) and a small gallbladder remnant (black arrow). The stone has already been extracted.
The patient undergoes ERCP again (Figure 4 and Figure 5). Cholangiography shows a normal common bile duct with low insertion of the cystic duct and an oval filling defect in the cystic duct just proximal to its insertion into the common bile duct. Cystic duct opacification reveals a long cystic duct remnant and a small gallbladder remnant. The stone in the cystic duct is successfully removed.

IF STONES ARE DIFFICULT TO EXTRACT

7. If the cystic duct stone were not amenable to endoscopic extraction, what would be the best alternative?

  • Extracorporeal shock-wave lithotripsy (ESWL)
  • Endoscopic biliary laser lithotripsy
  • Repeat laparoscopic cholecystectomy
  • All of the above

All of the above are alternatives.

A symptomatic stone in a cystic duct remnant is uncommon and is mentioned in the literature only in case series and case reports.

ESWL is effective for treating bile duct calculi.29 In a cohort of 239 patients with bile duct stones treated by ESWL, Benninger et al30 concluded that endoscopy plus ESWL was a definitive treatment for all patients except one, who subsequently underwent cholecystectomy. Once fragmented, the stones are extracted endoscopically.

Another fragmentation technique that can be offered to patients with stones in the cystic duct that are difficult to extract is contact fragmentation with a holmium laser placed in a transpapillary position under visual guidance.17

Repeat cholecystectomy with removal of stones in the cystic duct remnant (and removal of retained gallbladder remnants and reduction of the cystic duct remnant) has good postoperative results.17,18,31,32

After incomplete cholecystectomy, the cystic duct remnant and the Calot (cystohepatic) triangle are surrounded by inflamed scar tissue, and this was thought to make laparoscopic reoperation difficult.33 However, with advances in surgical technique and increasing experience of surgeons, repeat cholecystectomy can be done laparoscopically. It has now been suggested that laparoscopic exploration to remove the gallbladder remnants is safe and feasible in such patients.34,35

Discharge and follow-up

The patient is discharged home after the procedure. She is still free of symptoms 31 months later.

 

 

LESSONS LEARNED

Remnant cystic duct stones are uncommon

The estimated incidence of a retained calculus within the cystic duct remnant after cholecystectomy is less than 2.5%.2,36 In a series of 322 patients who underwent repeat surgery because of postcholecystectomy syndrome, Rogy et al36 found only 8 who had a stone in the cystic duct or gallbladder remnant, and in a series of 371 patients, Zhou el al2 found 4 who had a stone in the cystic duct remnant.

Stones in the cystic duct remnant are difficult to diagnose

Diagnosing stones in surgical remnants of the cystic duct or gallbladder can be difficult. The sensitivity of abdominal ultrasonography in detecting cystic duct stones is low—only 27% in one study, with a specificity of 100% and an accuracy of 75%.37 Ultrasonography may occasionally suggest cystic duct stones by showing an acoustic shadow in the anatomic region of the cystic duct. However, the results should be interpreted with caution.

Determining the accuracy of ERCP and MRCP in detecting cystic duct remnant stones is also difficult, as few cases have been reported and data may be conflicting. In a review of seven patients confirmed to have retained stones in a surgical remnant, Walsh et al17 found that ERCP correctly diagnosed the retained stone in only four out of six patients; MRCP was done in one patient, and it was read as normal.

In three cases of stones in a postsurgical gallbladder remnant, Hassan and Vilmann38 reported that ERCP and MRCP failed to identify the gallbladder remnant in two out of three cases, likely because the remaining structures are small. The diagnosis was finally made by endoscopic ultrasonography, which the authors concluded was a valuable method to visualize a small gallbladder remnant with stones.

Greater suspicion is needed in patients with typical biliary colic after cholecystectomy

Retained gallbladder remnant is described in the literature as a latent complication. The main problem is not the remnant itself but the chance that it harbors retained stones, which can lead to dilatation and inflammation of the remnant.

The patient can develop symptoms of acute cholecystitis or even acute cholangitis if the stone migrates to the common bile duct. Symptoms can develop as early as 2 weeks or as late as 25 years after laparoscopic cholecystectomy.

Endoscopic ultrasonography may be the best way to look for these remnant stones and to evaluate the bile duct and pancreas. Therefore, it should be part of the diagnostic algorithm in the evaluation of postcholecystectomy pain.

Mixed results with ERCP for extracting cystic duct stones

In case reports of cystic duct calculi after cholecystectomy, ERCP by itself has had mixed results. This traditional means of removing stones may succeed, as in our case. However, the success rate depends largely on anatomic factors such as the position of the stone in the cystic duct, the degree of stone impaction, the diameter of the cystic duct, and the number of valves in the duct.17

Stones in the cystic duct that cannot be extracted with ERCP may benefit from fragmentation techniques in situ via holmium laser followed by endoscopic extraction.

Repeat cholecystectomy is generally advised for any residual gallbladder, and it can be done laparoscopically.

Four months after undergoing laparoscopic cholecystectomy for symptomatic gallstones, an otherwise healthy 26-year-old woman begins to have episodes of epigastric and back pain similar to what she experienced before the surgery. The surgery was without complications, and her classic biliary colic disappeared afterward. Histologic evaluation of the surgical specimen revealed chronic cholecystitis with multiple small, mixed gallstones.

Now she describes a burning pain in her epigastrium and mid to upper back, starting about 30 minutes after a meal and lasting up to 4 hours. Sometimes it awakens her at night. She avoids eating for fear of inducing the pain. She has occasional chills but no fever, nausea, vomiting, jaundice, or changes in urine or stool color.

Three years ago she was diagnosed with a gastric ulcer induced by taking a nonsteroidal anti-inflammatory drug (NSAID). The ulcer was treated with a proton pump inhibitor for 1 month. She says the ulcer pain was dull and aching, different from her current pain.

Upper endoscopy 4 months ago (ie, before her laparoscopic cholecystectomy) showed no evidence of esophagitis or peptic ulcer disease.

Apart from her gallbladder operation, she has had no other surgery. According to the surgeon’s notes, intraoperative cholangiography was not performed, and no macroscopic changes of acute cholecystitis or difficult biliary anatomy were noted.

The patient does not smoke, does not drink alcohol, is not currently taking any medications, including NSAIDs or over-the-counter medications, and has not taken any recently. Her mother also had symptomatic gallstones requiring cholecystectomy.

On physical examination, only fever

On examination, her temperature is 101.2°F (38.4°C), blood pressure 117/80 mm Hg, heart rate 82 beats per minute, and blood oxygen saturation 99% on room air. Her weight is 138 lb (62.6 kg), height 5 feet 6 inches (168 cm).

There is no jaundice or pallor. Her heart and lung examinations are normal.

Her abdomen is soft and mildly tender to palpation of the epigastrium, with no distention or hepatosplenomegaly and no rebound tenderness or guarding. The scars from her laparoscopic surgery have healed well. Her bowel sounds are normal.

No costovertebral angle or spinal tenderness can be elicited.

Her laboratory values are shown in Table 1.

POSTCHOLECYSTECTOMY SYNDROME

1. After cholecystectomy, preoperative symptoms recur in what percentage of patients?

  • 10% to 40%
  • 50%
  • 60%
  • 80%

Postcholecystectomy syndrome—the recurrence of symptoms similar to those before the procedure—occurs in 10% to 40% of patients. The time to the onset of symptoms can range from 2 days to up to 25 years.1–4 Women may be at higher risk, with symptoms recurring in 43% vs 28% in men.5

Postcholecystectomy syndrome can have a biliary or a nonbiliary cause. Biliary causes include strictures, retained calculi, dropped calculi, tumors, sphincter of Oddi dysfunction, and calculi in the cystic duct remnant. Nonbiliary causes include functional and organic disorders such as peptic ulcer disease, gastroesophageal reflux, pancreatic disease, hepatocellular disorders, coronary artery disease, irritable bowel syndrome, and intercostal neuritis.

WHAT IS THE NEXT STEP?

2. Which is the most appropriate next step in the workup of this patient?

  • Ultrasonography of the right upper quadrant
  • Magnetic resonance cholangiopancreatography (MRCP)
  • Endoscopic retrograde cholangiopancreatography (ERCP)
  • Observation and reassurance
  • Review the operative record and consult with the surgeon

Although the patient is presenting with pain and fever, two features of the classic Charcot triad (pain, fever, jaundice) seen in cholangitis (infection of a bile duct), and although cholangitis almost confirms the diagnosis of common bile duct stones in a patient with gallstones (before or after cholecystectomy), other diagnoses to consider are bile duct injury, bile leak, and biloma.

Biloma can be detected with ultrasonography. Bile duct injuries are identified intraoperatively in up to 25% of patients. For those with an unrecognized injury, the clinical presentation is variable and depends on the type of injury. If a bile leak is present, patients present early, at a median of 3 days postoperatively. However, our patient presented with symptoms 4 months after her surgery. Patients with bile duct strictures without bile leak have a longer symptom-free interval and usually present with signs of biliary obstruction. Ultrasonography can then detect biliary dilatation.6

It would be very helpful to review the operative record and to talk to the surgeon to confirm that intraoperative cholangiography had not been done and to determine the level of difficulty of the surgery. (Intraoperative cholangiography involves the introduction of contrast dye into the biliary system by cannulation of the cystic duct or by direct injection into the common bile duct. An intraoperative cholangiogram is considered normal if the entire intrahepatic and extrahepatic biliary tree is seen to be filled with contrast.) A normal cholangiogram has a negative predictive value of 99.8% for the detection of ductal stones. Thus, a normal intraoperative cholangiogram can prevent unnecessary postoperative ECRP, since it almost always indicates a clean bile duct.7

Ultrasonography of the right upper quadrant has a low sensitivity (< 50%) for detecting common bile duct stones. However, it is highly operator-dependent, and it may be twice as sensitive if done by expert radiologists than by less experienced ones. Its limitations include poor visualization of the distal portion of the duct and low sensitivity in patients in whom the common bile duct is minimally dilated and also in patients with small stones. In most studies, however, it had a very high specificity—ie, greater than 95%.8

MRCP has a sensitivity of 82.6% and a specificity of 97.5% in detecting stones in the common bile duct.9 Therefore, normal results on abdominal ultrasonography and MRCP do not completely rule out stones.

Although this patient has a high pretest probability of having common bile duct stones, ERCP should be done only after a thorough review of the previous operative procedure.

Observation and reassurance are not appropriate in a patient with cholangitis, such as this patient, because waiting increases the risk of septicemia.

 

 

The patient undergoes ERCP with stone removal

Review of the operative report and discussion with the surgeon confirm that the laparoscopic procedure was uneventful and that intraoperative cholangiography was not done.

Therefore, the patient undergoes ERCP. The major papilla is normal. Cholangiography reveals nondilated common bile and intrahepatic ducts, with faint filling defects in the mid to distal common bile duct. Endoscopic sphincterotomy is performed, and three small stones are extracted from the common bile duct. Repeat balloon-occlusion cholangiography is normal.

The patient tolerates the procedure well and resumes a normal diet and normal activities.

Her pain persists, prompting an emergency room visit

Five days after her ERCP procedure, however, the same burning epigastric pain returns. As before, the pain occurs after eating and does not occur with fasting. At this time, she has no fever or chills.

The patient continues to have recurrent episodes of pain, on one occasion so severe she visits the emergency department. During this visit she reports she has no symptoms other than pain, and the examination is normal. Laboratory tests (Table 2) show that her liver function measures have normalized.

WHAT IS CAUSING HER PAIN?

3. Which is the most likely cause of her persistent pain?

  • Acute pancreatitis after ERCP
  • Peptic ulcer disease
  • Sphincter of Oddi dysfunction
  • Biliary stones

The most likely cause is persistent biliary stones. The common bile duct was recently explored and stones were removed, but she may still have stones in the intrahepatic ducts or in the cystic duct remnant, both of which were unopacified during the ERCP procedure, indicating that either the test was incomplete or a stone is obstructing the passage of contrast. Her persistent symptoms warrant repeating her liver function tests.

Acute pancreatitis is the most common and feared complication of ERCP, and it should be suspected in any patient who develops abdominal pain within 6 hours of the procedure. It is much less likely to develop after 12 hours, however. Risk factors for post-ERCP pancreatitis include patient factors (young age, female sex, history of recurrent pancreatitis), procedural factors (difficult cannulation, minor papilla sphincterotomy), and, less likely, operator-related factors.10–13 In general, the more likely a patient is to have an abnormal and irregular common bile duct or pancreatic duct, the lower the risk of post-ERCP pancreatitis. The importance of operator-dependent factors is not yet clear.10–13

Despite the postprandial pattern of our patient’s pain and her history of gastric ulcer, peptic ulcer disease is unlikely in view of a normal esophagogastroduodenoscopic examination done 4 months earlier, and since she has no recent exposure to NSAIDs.

Sphincter of Oddi dysfunction may explain her symptoms, but she recently underwent endoscopic sphincterotomy, which is regarded as the most definitive treatment.14

WHAT SHOULD BE DONE NEXT?

4. What would be the best next step in her management?

  • Repeat ERCP
  • MRCP
  • Endoscopic ultrasonography
  • Observation and reassurance

MRCP is the most appropriate next step, given her recurrent symptoms. Repeat ERCP is not appropriate, since there is no evidence of cholangitis, and since her liver function tests had completely normalized.

A recent systematic review of endoscopic ultrasonography and MRCP for diagnosing choledocholithiasis found both tests to be highly accurate, with no statistically significant differences in sensitivity or specificity between the two.15 However, MRCP has the advantage of being noninvasive and of being able to show intrahepatic stones.

Park et al,16 in a prospective study of 66 patients with primary intrahepatic stones, concluded that MRCP findings were comparable to those of percutaneous transhepatic cholangioscopy, the reference standard for locating intrahepatic stones. The sensitivity, specificity, and accuracy of MRCP for detecting and locating intrahepatic stones were high (97%, 99%, and 98%, respectively).16 However, after sphincterotomy, pneumobilia may create an appearance that can be mistaken for intraductal stones.

Figure 1. Magnetic resonance cholangiopancreatography shows a normal biliary tree (arrow) and pancreatic duct. The cystic duct cannot be seen.
Merely reassuring the patient is not appropriate at this point, given her level of pain.

She undergoes MRCP

Figure 2. Ultrasonography of the right upper quadrant shows a nondilated common bile duct 4 mm in diameter (arrow). No stones are visible.
MRCP shows a normal biliary tree without stones (Figure 1). Similarly, ultrasonography of the right upper quadrant shows no stones and a nondilated common bile duct (Figure 2).

The patient continues to have pain, and she has lost 5 pounds because she is still avoiding eating. At this point, she is beginning to wonder if her symptoms are psychogenic, since all the test results have been normal.

ERCP, MRCP, ULTRASONOGRAPHY?

5. What would be the best next step?

  • Reassurance
  • Referral to a psychiatrist
  • Referral to a pain management clinic
  • Endoscopic ultrasonography
  • Repeat ERCP

Endoscopic ultrasonography is needed to look for cystic duct stones. Although several tests have shown normal results, the patient’s pain continues as in the previous episodes, making stone disease the most likely cause.

Although no stones were seen on MRCP and ultrasonography, a detailed evaluation for stones in a cystic duct or retained gallbladder remnant was not done satisfactorily.

Reassurance and referral to a psychiatrist or pain management clinic are not appropriate, since an organic cause of her pain has not been completely ruled out.

Figure 3. Endoscopic ultrasonography from the duodenal bulb shows a 7-mm stone (arrow) in the cystic duct remnant or gallbladder remnant.
ERCP should not be used as a diagnostic test in a situation such as this.

Findings on endoscopic ultrasonography

Endoscopic ultrasonography is performed and reveals a large (7-mm) stone in the area of the cystic duct remnant or gallbladder remnant (Figure 3). The common bile duct is normal.

 

 

CAUSES OF RETAINED GALLBLADDER AND CYSTIC DUCT REMNANT

6. What may have predisposed this patient to a retained gallbladder or cystic duct remnant after her surgery?

  • Laparoscopic cholecystectomy
  • Not doing intraoperative cholangiography
  • Cholecystectomy for acute cholecystitis
  • All of the above

All of the above may have contributed.

Postcholecystectomy syndrome can pose a diagnostic and therapeutic challenge, as in our patient. Although it has been reported since the advent of the operation, it is more common after laparoscopic cholecystectomy than after open surgery. One possible cause is stones in a cystic duct remnant, ie, a stub longer than 1 cm.

During open cholecystectomy, the cystic duct is ligated and cut as close to the common bile duct as possible, leaving only a small remnant. In laparoscopic cholecystectomy, it is divided closer to the gallbladder to avoid iatrogenic injury to the common bile duct, leaving a longer remnant. A long cystic duct remnant can be prevented by accurately locating the junction of the gallbladder and the cystic duct during cholecystectomy and by routinely doing intraoperative cholangiography. The presence of stones in a cystic duct or retained gallbladder remnant is a rare cause of postcholecystectomy syndrome, and suspicion is required to make the diagnosis.17–19

We should note that stones may also lurk in the short cystic duct remnant left after open cholecystectomy. In fact, the first case of cystic duct remnant, the so-called reformed gallbladder containing stones, was described in 1912 by Flörcken.20

Intraoperative cholangiography was introduced in 1931 by Mirizzi,21 who recommended its routine use. Since the advent of laparoscopic cholecystectomy in 1988, the routine use of intraoperative cholangiography has been debated. Advocates point to its ability to detect unsuspected calculi and to delineate the biliary anatomy, thus reducing the risk of biliary duct injury.7,22–25 Those who argue against its routine use emphasize the low reported rates of unsuspected stones in the common bile duct (2% to 3%), a longer operative time, the additional cost, and false-positive results that may lead to unnecessary common bile duct exploration. Another argument against its routine use is that most small ductal stones pass spontaneously without significant sequelae.26–28 Surgeons who use intraoperative cholangiography only selectively use it in patients with unclear biliary anatomy and preoperative biochemical or radiologic evidence of choledocholithiasis.

Figure 4. Endoscopic retrograde cholangiopancreatography shows an oval filling defect in the cystic duct remnant at its insertion into the common bile duct (arrow).
Another potential explanation for the retained gallbladder remnant is that the cholecystectomy was done while the patient had acute cholecystitis, in which inflammation may obscure anatomic landmarks. Hence, cholangiography during laparoscopic cholecystectomy has been widely recognized as a means of delineating the biliary anatomy.

Case continued: She undergoes repeat ERCP

Figure 5. Endoscopic retrograde cholangiopancreatography reveals a long duct remnant (red arrow) and a small gallbladder remnant (black arrow). The stone has already been extracted.
The patient undergoes ERCP again (Figure 4 and Figure 5). Cholangiography shows a normal common bile duct with low insertion of the cystic duct and an oval filling defect in the cystic duct just proximal to its insertion into the common bile duct. Cystic duct opacification reveals a long cystic duct remnant and a small gallbladder remnant. The stone in the cystic duct is successfully removed.

IF STONES ARE DIFFICULT TO EXTRACT

7. If the cystic duct stone were not amenable to endoscopic extraction, what would be the best alternative?

  • Extracorporeal shock-wave lithotripsy (ESWL)
  • Endoscopic biliary laser lithotripsy
  • Repeat laparoscopic cholecystectomy
  • All of the above

All of the above are alternatives.

A symptomatic stone in a cystic duct remnant is uncommon and is mentioned in the literature only in case series and case reports.

ESWL is effective for treating bile duct calculi.29 In a cohort of 239 patients with bile duct stones treated by ESWL, Benninger et al30 concluded that endoscopy plus ESWL was a definitive treatment for all patients except one, who subsequently underwent cholecystectomy. Once fragmented, the stones are extracted endoscopically.

Another fragmentation technique that can be offered to patients with stones in the cystic duct that are difficult to extract is contact fragmentation with a holmium laser placed in a transpapillary position under visual guidance.17

Repeat cholecystectomy with removal of stones in the cystic duct remnant (and removal of retained gallbladder remnants and reduction of the cystic duct remnant) has good postoperative results.17,18,31,32

After incomplete cholecystectomy, the cystic duct remnant and the Calot (cystohepatic) triangle are surrounded by inflamed scar tissue, and this was thought to make laparoscopic reoperation difficult.33 However, with advances in surgical technique and increasing experience of surgeons, repeat cholecystectomy can be done laparoscopically. It has now been suggested that laparoscopic exploration to remove the gallbladder remnants is safe and feasible in such patients.34,35

Discharge and follow-up

The patient is discharged home after the procedure. She is still free of symptoms 31 months later.

 

 

LESSONS LEARNED

Remnant cystic duct stones are uncommon

The estimated incidence of a retained calculus within the cystic duct remnant after cholecystectomy is less than 2.5%.2,36 In a series of 322 patients who underwent repeat surgery because of postcholecystectomy syndrome, Rogy et al36 found only 8 who had a stone in the cystic duct or gallbladder remnant, and in a series of 371 patients, Zhou el al2 found 4 who had a stone in the cystic duct remnant.

Stones in the cystic duct remnant are difficult to diagnose

Diagnosing stones in surgical remnants of the cystic duct or gallbladder can be difficult. The sensitivity of abdominal ultrasonography in detecting cystic duct stones is low—only 27% in one study, with a specificity of 100% and an accuracy of 75%.37 Ultrasonography may occasionally suggest cystic duct stones by showing an acoustic shadow in the anatomic region of the cystic duct. However, the results should be interpreted with caution.

Determining the accuracy of ERCP and MRCP in detecting cystic duct remnant stones is also difficult, as few cases have been reported and data may be conflicting. In a review of seven patients confirmed to have retained stones in a surgical remnant, Walsh et al17 found that ERCP correctly diagnosed the retained stone in only four out of six patients; MRCP was done in one patient, and it was read as normal.

In three cases of stones in a postsurgical gallbladder remnant, Hassan and Vilmann38 reported that ERCP and MRCP failed to identify the gallbladder remnant in two out of three cases, likely because the remaining structures are small. The diagnosis was finally made by endoscopic ultrasonography, which the authors concluded was a valuable method to visualize a small gallbladder remnant with stones.

Greater suspicion is needed in patients with typical biliary colic after cholecystectomy

Retained gallbladder remnant is described in the literature as a latent complication. The main problem is not the remnant itself but the chance that it harbors retained stones, which can lead to dilatation and inflammation of the remnant.

The patient can develop symptoms of acute cholecystitis or even acute cholangitis if the stone migrates to the common bile duct. Symptoms can develop as early as 2 weeks or as late as 25 years after laparoscopic cholecystectomy.

Endoscopic ultrasonography may be the best way to look for these remnant stones and to evaluate the bile duct and pancreas. Therefore, it should be part of the diagnostic algorithm in the evaluation of postcholecystectomy pain.

Mixed results with ERCP for extracting cystic duct stones

In case reports of cystic duct calculi after cholecystectomy, ERCP by itself has had mixed results. This traditional means of removing stones may succeed, as in our case. However, the success rate depends largely on anatomic factors such as the position of the stone in the cystic duct, the degree of stone impaction, the diameter of the cystic duct, and the number of valves in the duct.17

Stones in the cystic duct that cannot be extracted with ERCP may benefit from fragmentation techniques in situ via holmium laser followed by endoscopic extraction.

Repeat cholecystectomy is generally advised for any residual gallbladder, and it can be done laparoscopically.

References
  1. Lehman GA, Sherman S. Sphincter of Oddi dysfunction (postcholecystectomy syndrome). In:Yamada T, editor. Textbook of Gastroenterology. 2nd ed. Philadelphia: Lippincott; 1995:22512262.
  2. Zhou PH, Liu FL, Yao LQ, Qin XY. Endoscopic diagnosis and treatment of post-cholecystectomy syndrome. Hepatobiliary Pancreat Dis Int 2003; 2:117120.
  3. Mergener K, Clavien PA, Branch MS, Baillie J. A stone in a grossly dilated cystic duct stump: a rare cause of postcholecystectomy pain. Am J Gastroenterol 1999; 94:229231.
  4. Goenka MK, Kochhar R, Nagi B, Bhasin DK, Chowdhury A, Singh K. Endoscopic retrograde cholangiopancreatography in postcholecystectomy syndrome. J Assoc Physicians India 1996; 44:119122.
  5. Bodvall B, Overgaard B. Cystic duct remnant after cholecystectomy: incidence studied by cholegraphy in 500 cases, and significance in 103 reoperations. Ann Surg 1966; 163:382390.
  6. Bergman JJ, van den Brink GR, Rauws EA, et al. Treatment of bile duct lesions after laparoscopic cholecystectomy. Gut 1996; 38:141147.
  7. Nickkholgh A, Soltaniyekta S, Kalbasi H. Routine versus selective intraoperative cholangiography during laparoscopic cholecystectomy: a survey of 2,130 patients undergoing laparoscopic cholecystectomy. Surg Endosc 2006; 20:868874.
  8. Gandolfi L, Torresan F, Solmi L, Puccetti A. The role of ultrasound in biliary and pancreatic diseases. Eur J Ultrasound 2003; 16:141159.
  9. Al Samaraee A, Khan U, Almashta Z, Yiannakou Y. Preoperative diagnosis of choledocholithiasis: the role of MRCP. Br J Hosp Med (Lond) 2009; 70:339343.
  10. Freeman ML, DiSario JA, Nelson DB, et al. Risk factors for post-ERCP pancreatitis: a prospective, multicenter study. Gastrointest Endosc 2001; 54:425434.
  11. Cheng CL, Sherman S, Watkins JL, et al. Risk factors for post-ERCP pancreatitis: a prospective multicenter study. Am J Gastroenterol 2006; 101:139147.
  12. Mehta SN, Pavone E, Barkun JS, Bouchard S, Barkun AN. Predictors of post-ERCP complications in patients with suspected choledocholithiasis. Endoscopy 1998; 30:457463.
  13. Badalov N, Tenner S, Baillie J. The prevention, recognition and treatment of post-ERCP pancreatitis. JOP 2009; 10:8897.
  14. Geenen JE, Hogan WJ, Dodds WJ, Toouli J, Venu RP. The efficacy of endoscopic sphincterotomy after cholecystectomy in patients with sphincter-of-Oddi dysfunction. N Engl J Med 1989; 320:8287.
  15. Verma D, Kapadia A, Eisen GM, Adler DG. EUS vs MRCP for detection of choledocholithiasis. Gastrointest Endosc 2006; 64:248254.
  16. Park DH, Kim MH, Lee SS, et al. Accuracy of magnetic resonance cholangiopancreatography for locating hepatolithiasis and detecting accompanying biliary strictures. Endoscopy 2004; 36:987992.
  17. Walsh RM, Ponsky JL, Dumot J. Retained gallbladder/cystic duct remnant calculi as a cause of postcholecystectomy pain. Surg Endosc 2002; 16:981984.
  18. Tantia O, Jain M, Khanna S, Sen B. Post cholecystectomy syndrome: role of cystic duct stump and re-intervention by laparoscopic surgery. J Minim Access Surg 2008; 4:7175.
  19. Palanivelu C, Rangarajan M, Jategaonkar PA, Madankumar MV, Anand NV. Laparoscopic management of remnant cystic duct calculi: a retrospective study. Ann R Coll Surg Engl 2009; 91:2529.
  20. Flörcken H. Gallenblasenregeneration mit Steinrecidiv nach Cholecystectomie. Deutsch Z Chir 1912; 113:604.
  21. Mirizzi PL. La colangiografía durante las operaciones de las vias biliares. Bol Soc Cirug Buenos Aires 1932; 16:1113.
  22. Soper NJ, Brunt LM. The case for routine operative cholangiography during laparoscopic cholecystectomy. Surg Clin North Am 1994; 74:953959.
  23. Cuschieri A, Shimi S, Banting S, Nathanson LK, Pietrabissa A. Intraoperative cholangiography during laparoscopic cholecystectomy. Routine vs selective policy. Surg Endosc 1994; 8:302305.
  24. Woods MS, Traverso LW, Kozarek RA, et al. Biliary tract complications of laparoscopic cholecystectomy are detected more frequently with routine intraoperative cholangiography. Surg Endosc 1995; 9:10761080.
  25. Vezakis A, Davides D, Ammori BJ, Martin IG, Larvin M, McMahon MJ. Intraoperative cholangiography during laparoscopic cholecystectomy. Surg Endosc 2000; 14:11181122.
  26. Ladocsi LT, Benitez LD, Filippone DR, Nance FC. Intraoperative cholangiography in laparoscopic cholecystectomy: a review of 734 consecutive cases. Am Surg 1997; 63:150156.
  27. Clair DG, Brooks DC. Laparoscopic cholangiography. The case for a selective approach. Surg Clin North Am 1994; 74:961966.
  28. Collins C, Maguire D, Ireland A, Fitzgerald E, O’Sullivan GC. A prospective study of common bile duct calculi in patients undergoing laparoscopic cholecystectomy: natural history of choledocholithiasis revisited. Ann Surg 2004; 239:2833.
  29. Ponsky LE, Geisinger MA, Ponsky JL, Streem SB. Contemporary ‘urologic’ intervention in the pancreaticobiliary tree. Urology 2001; 57:2125.
  30. Benninger J, Rabenstein T, Farnbacher M, Keppler J, Hahn EG, Schneider HT. Extracorporeal shockwave lithotripsy of gallstones in cystic duct remnants and Mirizzi syndrome. Gastrointest Endosc 2004; 60:454459.
  31. Demetriades H, Pramateftakis MG, Kanellos I, Angelopoulos S, Mantzoros I, Betsis D. Retained gallbladder remnant after laparoscopic cholecystectomy. J Laparoendosc Adv Surg Tech A 2008; 18:276279.
  32. Shaw C, O’Hanlon DM, Fenlon HM, McEntee GP. Cystic duct remnant and the ‘post-cholecystectomy syndrome. ’ Hepatogastroenterology 2004; 51:3638.
  33. Rozsos I, Magyaródi Z, Orbán P. Cystic duct syndrome and minimally invasive surgery. [Hungarian] Orv Hetil 1997; 138:23972401.
  34. Chowbey PK, Bandyopadhyay SK, Sharma A, Khullar R, Soni V, Baijal M. Laparoscopic reintervention for residual gallstone disease. Surg Laparosc Endosc Percutan Tech 2003; 13:3135.
  35. Clemente G, Giuliante F, Cadeddu F, Nuzzo G. Laparoscopic removal of gallbladder remnant and long cystic stump. Endoscopy 2001; 33:814815.
  36. Rogy MA, Függer R, Herbst F, Schulz F. Reoperation after cholecystectomy. The role of the cystic duct stump. HPB Surg 1991; 4:129134.
  37. Laing FC, Jeffrey RB. Choledocholithiasis and cystic duct obstruction: difficult ultrasonographic diagnosis. Radiology 1983; 146:475479.
  38. Hassan H, Vilmann P. Insufficient cholecystectomy diagnosed by endoscopic ultrasonography. Endoscopy 2004; 36:236238.
References
  1. Lehman GA, Sherman S. Sphincter of Oddi dysfunction (postcholecystectomy syndrome). In:Yamada T, editor. Textbook of Gastroenterology. 2nd ed. Philadelphia: Lippincott; 1995:22512262.
  2. Zhou PH, Liu FL, Yao LQ, Qin XY. Endoscopic diagnosis and treatment of post-cholecystectomy syndrome. Hepatobiliary Pancreat Dis Int 2003; 2:117120.
  3. Mergener K, Clavien PA, Branch MS, Baillie J. A stone in a grossly dilated cystic duct stump: a rare cause of postcholecystectomy pain. Am J Gastroenterol 1999; 94:229231.
  4. Goenka MK, Kochhar R, Nagi B, Bhasin DK, Chowdhury A, Singh K. Endoscopic retrograde cholangiopancreatography in postcholecystectomy syndrome. J Assoc Physicians India 1996; 44:119122.
  5. Bodvall B, Overgaard B. Cystic duct remnant after cholecystectomy: incidence studied by cholegraphy in 500 cases, and significance in 103 reoperations. Ann Surg 1966; 163:382390.
  6. Bergman JJ, van den Brink GR, Rauws EA, et al. Treatment of bile duct lesions after laparoscopic cholecystectomy. Gut 1996; 38:141147.
  7. Nickkholgh A, Soltaniyekta S, Kalbasi H. Routine versus selective intraoperative cholangiography during laparoscopic cholecystectomy: a survey of 2,130 patients undergoing laparoscopic cholecystectomy. Surg Endosc 2006; 20:868874.
  8. Gandolfi L, Torresan F, Solmi L, Puccetti A. The role of ultrasound in biliary and pancreatic diseases. Eur J Ultrasound 2003; 16:141159.
  9. Al Samaraee A, Khan U, Almashta Z, Yiannakou Y. Preoperative diagnosis of choledocholithiasis: the role of MRCP. Br J Hosp Med (Lond) 2009; 70:339343.
  10. Freeman ML, DiSario JA, Nelson DB, et al. Risk factors for post-ERCP pancreatitis: a prospective, multicenter study. Gastrointest Endosc 2001; 54:425434.
  11. Cheng CL, Sherman S, Watkins JL, et al. Risk factors for post-ERCP pancreatitis: a prospective multicenter study. Am J Gastroenterol 2006; 101:139147.
  12. Mehta SN, Pavone E, Barkun JS, Bouchard S, Barkun AN. Predictors of post-ERCP complications in patients with suspected choledocholithiasis. Endoscopy 1998; 30:457463.
  13. Badalov N, Tenner S, Baillie J. The prevention, recognition and treatment of post-ERCP pancreatitis. JOP 2009; 10:8897.
  14. Geenen JE, Hogan WJ, Dodds WJ, Toouli J, Venu RP. The efficacy of endoscopic sphincterotomy after cholecystectomy in patients with sphincter-of-Oddi dysfunction. N Engl J Med 1989; 320:8287.
  15. Verma D, Kapadia A, Eisen GM, Adler DG. EUS vs MRCP for detection of choledocholithiasis. Gastrointest Endosc 2006; 64:248254.
  16. Park DH, Kim MH, Lee SS, et al. Accuracy of magnetic resonance cholangiopancreatography for locating hepatolithiasis and detecting accompanying biliary strictures. Endoscopy 2004; 36:987992.
  17. Walsh RM, Ponsky JL, Dumot J. Retained gallbladder/cystic duct remnant calculi as a cause of postcholecystectomy pain. Surg Endosc 2002; 16:981984.
  18. Tantia O, Jain M, Khanna S, Sen B. Post cholecystectomy syndrome: role of cystic duct stump and re-intervention by laparoscopic surgery. J Minim Access Surg 2008; 4:7175.
  19. Palanivelu C, Rangarajan M, Jategaonkar PA, Madankumar MV, Anand NV. Laparoscopic management of remnant cystic duct calculi: a retrospective study. Ann R Coll Surg Engl 2009; 91:2529.
  20. Flörcken H. Gallenblasenregeneration mit Steinrecidiv nach Cholecystectomie. Deutsch Z Chir 1912; 113:604.
  21. Mirizzi PL. La colangiografía durante las operaciones de las vias biliares. Bol Soc Cirug Buenos Aires 1932; 16:1113.
  22. Soper NJ, Brunt LM. The case for routine operative cholangiography during laparoscopic cholecystectomy. Surg Clin North Am 1994; 74:953959.
  23. Cuschieri A, Shimi S, Banting S, Nathanson LK, Pietrabissa A. Intraoperative cholangiography during laparoscopic cholecystectomy. Routine vs selective policy. Surg Endosc 1994; 8:302305.
  24. Woods MS, Traverso LW, Kozarek RA, et al. Biliary tract complications of laparoscopic cholecystectomy are detected more frequently with routine intraoperative cholangiography. Surg Endosc 1995; 9:10761080.
  25. Vezakis A, Davides D, Ammori BJ, Martin IG, Larvin M, McMahon MJ. Intraoperative cholangiography during laparoscopic cholecystectomy. Surg Endosc 2000; 14:11181122.
  26. Ladocsi LT, Benitez LD, Filippone DR, Nance FC. Intraoperative cholangiography in laparoscopic cholecystectomy: a review of 734 consecutive cases. Am Surg 1997; 63:150156.
  27. Clair DG, Brooks DC. Laparoscopic cholangiography. The case for a selective approach. Surg Clin North Am 1994; 74:961966.
  28. Collins C, Maguire D, Ireland A, Fitzgerald E, O’Sullivan GC. A prospective study of common bile duct calculi in patients undergoing laparoscopic cholecystectomy: natural history of choledocholithiasis revisited. Ann Surg 2004; 239:2833.
  29. Ponsky LE, Geisinger MA, Ponsky JL, Streem SB. Contemporary ‘urologic’ intervention in the pancreaticobiliary tree. Urology 2001; 57:2125.
  30. Benninger J, Rabenstein T, Farnbacher M, Keppler J, Hahn EG, Schneider HT. Extracorporeal shockwave lithotripsy of gallstones in cystic duct remnants and Mirizzi syndrome. Gastrointest Endosc 2004; 60:454459.
  31. Demetriades H, Pramateftakis MG, Kanellos I, Angelopoulos S, Mantzoros I, Betsis D. Retained gallbladder remnant after laparoscopic cholecystectomy. J Laparoendosc Adv Surg Tech A 2008; 18:276279.
  32. Shaw C, O’Hanlon DM, Fenlon HM, McEntee GP. Cystic duct remnant and the ‘post-cholecystectomy syndrome. ’ Hepatogastroenterology 2004; 51:3638.
  33. Rozsos I, Magyaródi Z, Orbán P. Cystic duct syndrome and minimally invasive surgery. [Hungarian] Orv Hetil 1997; 138:23972401.
  34. Chowbey PK, Bandyopadhyay SK, Sharma A, Khullar R, Soni V, Baijal M. Laparoscopic reintervention for residual gallstone disease. Surg Laparosc Endosc Percutan Tech 2003; 13:3135.
  35. Clemente G, Giuliante F, Cadeddu F, Nuzzo G. Laparoscopic removal of gallbladder remnant and long cystic stump. Endoscopy 2001; 33:814815.
  36. Rogy MA, Függer R, Herbst F, Schulz F. Reoperation after cholecystectomy. The role of the cystic duct stump. HPB Surg 1991; 4:129134.
  37. Laing FC, Jeffrey RB. Choledocholithiasis and cystic duct obstruction: difficult ultrasonographic diagnosis. Radiology 1983; 146:475479.
  38. Hassan H, Vilmann P. Insufficient cholecystectomy diagnosed by endoscopic ultrasonography. Endoscopy 2004; 36:236238.
Issue
Cleveland Clinic Journal of Medicine - 78(3)
Issue
Cleveland Clinic Journal of Medicine - 78(3)
Page Number
171-178
Page Number
171-178
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Cleveland Clinic Journal of Medicine
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Recurrent abdominal pain after laparoscopic cholecystectomy
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Recurrent abdominal pain after laparoscopic cholecystectomy
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Managing acute upper GI bleeding, preventing recurrences

Article Type
Article
Changed
Fri, 01/12/2018 - 17:00
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Managing acute upper GI bleeding, preventing recurrences
Author(s)
Mazen Albeldawi, MD
Mohammed A. Qadeer, MD, MPH
John J. Vargo, MD, MPH

Upper gastrointestinal (GI) bleeding is common, costly, and potentially life-threatening. It must be managed promptly and appropriately to prevent adverse outcomes.

More people are admitted to the hospital for upper GI bleeding than for congestive heart failure or deep vein thrombosis. In the United States, the annual rate of hospitalization for upper GI bleeding is estimated to be 165 per 100,000—more than 300,000 hospitalizations per year, at a cost of $2.5 billion.1,2

Furthermore, despite advances in therapy, the case-fatality rate has remained unchanged at 7% to 10%.3 This may be because today’s patients are older and have more comorbidities than those in the past.4

CAUSES OF UPPER GI BLEEDING

Peptic ulcers account for about 60% of severe cases of upper GI bleeding,5 and they are the focus of this paper. Fortunately, up to 80% of bleeding ulcers stop bleeding spontaneously without any intervention.6

Gastroduodenal erosions account for about 12%.3

Varices due to cirrhosis are less common but more dangerous. Variceal bleeding accounts for a relatively small percentage (6%) of upper GI bleeding, but the mortality rate from a single episode of variceal bleeding is 30%, and 60% to 70% of patients die within 1 year, mostly of underlying liver disease.

Less frequent causes include Mallory-Weiss tears, erosive duodenitis, Dieulafoy ulcer (a type of vascular malformation), other vascular lesions, neoplasms, aortoenteric fistula, gastric antral vascular ectasia, and prolapse gastropathy.5

HEMATEMESIS AND MELENA

The most common presenting signs of acute upper GI bleeding are hematemesis (vomiting of blood), “coffee grounds” emesis, and melena (tarry black stools). About 30% of patients with bleeding ulcers present with hematemesis, 20% with melena, and 50% with both.7

Hematochezia (red blood in the stool) usually suggests a lower GI source of bleeding, since blood from an upper source turns black and tarry as it passes through the gut, producing melena. However, up to 5% of patients with bleeding ulcers have hematochezia,7 and it indicates heavy bleeding: bleeding of approximately 1,000 mL into the upper GI tract is needed to cause hematochezia, whereas only 50 to 100 mL is needed to cause melena.8,9 Hematochezia with signs and symptoms of hemodynamic compromise such as syncope, postural hypotension, tachycardia, and shock should therefore direct one’s attention to an upper GI source of bleeding.

Nonspecific features include nausea, vomiting, epigastric pain, vasovagal phenomena, and syncope.

WHAT IS THE PATIENT’S RISK?

An assessment of clinical severity is the first critical task, as it helps in planning treatment. Advanced age, multiple comorbidities, and hemodynamic instability call for aggressive treatment. Apart from this simple clinical rule, scoring systems have been developed.

The Rockall scoring system, the most widely used, gives estimates of the risks of recurrent bleeding and death. It is based on the three clinical factors mentioned above and on two endoscopic ones, awarding points for:

  • Age—0 points if less than 60; 1 point if 60 to 79; or 2 points if 80 years or older
  • Shock—1 point if the pulse is more than 100; 2 points if the systolic blood pressure is less than 100 mm Hg
  • Comorbid illness—2 points for ischemic heart disease, congestive heart failure, or other major comorbidity; 3 points for renal failure, hepatic failure, or metastatic disease
  • Endoscopic diagnosis—0 points if no lesion found or a Mallory-Weiss tear; 1 point for peptic ulcer, esophagitis, or erosive disease; 2 points for GI malignancy
  • Endoscopic stigmata or recent hemorrhage—0 points for a clean-based ulcer or flat pigmented spot; 2 points for blood in the upper GI tract, active bleeding, a nonbleeding visible vessel, or adherent clot.

The Rockall score can thus range from 0 to 11 points, with an overall score of 0, 1, or 2 associated with an excellent prognosis.10

The Blatchford scoring system uses only clinical and laboratory factors and has no endoscopic component (Table 1). In contrast to the Rockall score, the main outcome it predicts is the need for clinical intervention (endoscopy, surgery, or blood transfusion). The Blatchford score ranges from 0 to 23; most patients with a score of 6 or higher need intervention.11

Other systems that are used less often include the Baylor severity scale and the Acute Physiology and Chronic Health Evaluation (APACHE) II score.

Does the patient have varices?

All variceal bleeding should be considered severe, since the 1-year death rate is so high (up to 70%). Clues pointing to variceal bleeding include previous variceal bleeding, thrombocytopenia, history of liver disease, and signs of liver disease on clinical examination.

All patients suspected of having bleeding varices should be admitted to the intensive care unit for close monitoring and should be given the highest priority, even if they are hemodynamically stable.

Is the patient hemodynamically stable?

Appropriate hemodynamic assessment includes monitoring of heart rate, blood pressure, and mental status. Tachycardia at rest, hypotension, and orthostatic changes in vital signs indicate a considerable loss of blood volume. Low urine output, dry mucous membranes, and sunken neck veins are also useful signs. (Tachycardia may be blunted if the patient is taking a beta-blocker.)

If these signs of hypovolemia are present, the initial management focuses on treating shock and on improving oxygen delivery to the vital organs. This involves repletion of the intravascular volume with intravenous infusions or blood transfusions. Supplemental oxygen also is useful, especially in elderly patients with heart disease.12

Inspection of nasogastric aspirate

In the initial assessment, it is useful to insert a nasogastric tube and inspect the aspirate. If it contains bright red blood, the patient needs an urgent endoscopic evaluation and an intensive level of care13,14; if it contains coffee-grounds material, the patient needs to be admitted to the hospital and to undergo endoscopic evaluation within 24 hours.

However, a normal aspirate does not rule out upper GI bleeding. Aljebreen et al15 found that 15% of patients with upper GI bleeding and normal nasogastric aspirate still had high-risk lesions (ie, visible bleeding or nonbleeding visible vessels) on endoscopy.

 

 

ACID-SUPPRESSION HELPS ULCERS HEAL

Acid and pepsin interfere with the healing of ulcers and other nonvariceal upper GI lesions. Further, an acidic environment promotes platelet disaggregation and fibrinolysis and impairs clot formation.16 This suggests that inhibiting gastric acid secretion and raising the gastric pH to 6 or higher may stabilize clots. Moreover, pepsinogen in the stomach is converted to its active form (pepsin) if the pH is less than 4. Therefore, keeping the pH above 4 keeps pepsinogen in an inactive form.

Histamine-2 receptor antagonists

Histamine-2 receptor antagonists were the first drugs to inhibit acid secretion, reversibly blocking histamine-2 receptors on the basolateral membrane of parietal cells. However, these drugs did not prove very useful in managing upper GI bleeding in clinical trials.17,18 In their intravenous form, they often fail to keep the gastric pH at 6 or higher, due to tachyphylaxis.19 The use of this class of drugs has declined in favor of proton pump inhibitors.

Proton pump inhibitors

Proton pump inhibitors reduce both basal and stimulated acid secretion by inhibiting hydrogen-potassium adenosine triphosphatase, the proton pump of the parietal cell.

Multiple studies have shown that proton pump inhibitors raise the gastric pH and keep it high. For example, an infusion of omeprazole (Prilosec) can keep the gastric pH above 6 for 72 hours without inducing tachyphylaxis.20,21

Started after endoscopy. Randomized controlled trials have found proton pump inhibitors to be effective when given in high doses intravenously for 72 hours after successful endoscopic treatment of bleeding ulcers with high-risk endoscopic signs, such as active bleeding or nonbleeding visible vessels.22,23

A meta-analysis indicated that these drugs decrease the incidence of recurrent peptic ulcer bleeding, the need for blood transfusions, the need for surgery, and the duration of hospitalization, but not the mortality rate.24,25 These studies also illustrate the benefit of following up endoscopic treatment to stop the bleeding with an intravenous infusion of a proton pump inhibitor.

The recommended dose of omeprazole for patients with high-risk findings on endoscopy is an 80-mg bolus followed by an 8-mg/hour infusion for 72 hours. After the patient’s condition stabilizes, oral therapy can be substituted for intravenous therapy. In patients with low-risk endoscopic findings (a clean-based ulcer or flat spot), oral proton pump inhibitors in high doses are recommended.

In either case, after the initial bleeding is treated endoscopically and hemostasis is achieved, a proton pump inhibitor is recommended for 6 to 8 weeks, or longer if the patient is also positive for Helicobacter pylori or is on daily treatment with aspirin or a nonsteroidal anti-inflammatory drug (NSAID) that is not selective for cyclo-oxygenase 2 (see below).

Started before endoscopy, these drugs reduced the frequency of actively bleeding ulcers, the duration of hospitalization, and the need for endoscopic therapy in a randomized controlled trial.26 A meta-analysis found that significantly fewer patients had signs of recent bleeding on endoscopy if they received a proton pump inhibitor 24 to 48 hours before the procedure, but it did not find any significant difference in important clinical outcomes such as death, recurrent bleeding, or surgery.27 Nevertheless, we believe that intravenous proton pump inhibitor therapy should be started before endoscopy in patients with upper GI bleeding.

Somatostatin analogues

Octreotide (Sandostatin), an analogue of the hormone somatostatin, decreases splanchnic blood flow, decreases secretion of gastric acid and pepsin, and stimulates mucus production. Although it is beneficial in treating upper GI bleeding due to varices, its benefit has not been confirmed in patients with nonvariceal upper GI bleeding.

A meta-analysis revealed that outcomes were better with high-dose intravenous proton pump inhibitor therapy than with octreotide when these drugs were started after endoscopic treatment of acute peptic ulcer bleeding.28 Nevertheless, octreotide may be useful in patients with uncontrolled nonvariceal bleeding who are awaiting endoscopy, since it is relatively safe to use.

ALL PATIENTS NEED ENDOSCOPY

All patients with upper GI bleeding need an upper endoscopic examination to diagnose and assess the risk posed by the bleeding lesion and to treat the lesion, reducing the risk of recurrent bleeding.

How urgently does endoscopy need to be done?

Endoscopy within the first 24 hours of upper GI bleeding is considered the standard of care. Patients with uncontrolled or recurrent bleeding should undergo endoscopy on an urgent basis to control the bleeding and reduce the risk of death.

However, how urgently endoscopy needs to be done is often debated. A multicenter randomized controlled trial compared outcomes in patients who underwent endoscopy within 6 hours of coming to the emergency department vs within 24 hours after the initial evaluation. The study found no significant difference in outcomes between the two groups; however, the group that underwent endoscopy sooner needed fewer transfusions.29

For a better view of the stomach

Gastric lavage improves the view of the gastric fundus but has not been proven to improve outcome.30

Promotility agents such as erythromycin and metoclopramide (Reglan) are also used to empty the stomach for better visualization.31–35 Erythromycin has been shown to improve visualization, shorten the procedure time, and prevent the need for additional endoscopy attempts in two randomized controlled studies.33,34 Furthermore, a cost-effectiveness study confirmed that giving intravenous erythromycin before endoscopy for acute upper GI bleeding saved money and resulted in an increase in quality-adjusted life-years.35

 

 

Endoscopy to diagnose bleeding and assess risk

Upper endoscopy is 90% to 95% diagnostic for acute upper GI bleeding.36

Figure 1. Endoscopic stigmata of bleeding peptic ulcer (arrows) and risk of recurrent bleeding and death.
Furthermore, some of the clinical scoring systems are based on endoscopic findings along with clinical factors on admission. These scoring systems are valuable for assessing patients with nonvariceal upper GI bleeding, as they predict the risk of death, longer hospital stay, surgical intervention, and recurrent bleeding.37,38 Patients with endoscopic findings associated with higher rates of recurrent bleeding and death (Figure 1) need aggressive management.

Certain factors, primarily clinical and endoscopic, predict that endoscopic treatment will fail to stop ulcer bleeding. Clinical factors include a history of peptic ulcer bleeding and hemodynamic compromise at presentation. Endoscopic factors include ulcers located high on the lesser curvature of the stomach, ulcers in the posterior or superior duodenal bulb, ulcers larger than 2 cm in diameter, and ulcers that are actively bleeding at the time of endoscopy.37 Other endoscopic findings that predict clinical outcome are summarized in Table 2.

Patients at high risk (ie, older than 60 years, with severe comorbidity, or hemodynamically compromised) who have active bleeding (ie, witnessed hematemesis, red blood per nasogastric tube, or fresh blood per rectum) or a nonbleeding visible vessel should be admitted to a monitored bed or intensive care unit. Observation in a regular medical ward is appropriate for high-risk patients found to have an adherent clot. Patients with low-risk findings (eg, a clean ulcer base) are at low risk of recurrent bleeding and may be considered for early hospital discharge with appropriate outpatient follow-up.

Endoscopy to treat bleeding

About 25% of endoscopic procedures performed for upper GI bleeding include some type of treatment,39 such as injections of epinephrine, normal saline, or sclerosants; thermal cautery; argon plasma coagulation; electrocautery; or application of clips or bands. They are all equally effective, and combinations of these therapies are more effective than when they are used individually. A recent meta-analysis found dual therapy to be superior to epinephrine monotherapy in preventing recurrent bleeding, need for surgery, and death.40

Endoscopic therapy is recommended for patients found to have active bleeding or nonbleeding visible blood vessels, as outcomes are better with endoscopic hemostatic treatment than with drug therapy alone (Table 3).41–44

How to manage adherent clots is controversial, but recent studies have revealed a significant benefit from removing them and treating the underlying lesions compared with drug therapy alone.43,45

Flat, pigmented spots and nonbleeding ulcers with a clean base do not require endoscopic treatment because the risk of recurrent bleeding is low.

Endoscopic therapy stops the bleeding in more than 90% of patients, but bleeding recurs after endoscopic therapy in 10% to 25%.46 Reversal of any severe coagulopathy with transfusions of platelets or fresh frozen plasma is essential for endoscopic hemostasis. However, coagulopathy at the time of initial bleeding and endoscopy does not appear to be associated with higher rates of recurrent bleeding following endoscopic therapy for nonvariceal upper GI bleeding.47

Patients with refractory bleeding are candidates for angiography or surgery. However, even when endoscopic hemostasis fails, endoscopy is important before angiography or surgery to pinpoint the site of bleeding and diagnose the cause.

A second endoscopic procedure is generally not recommended within 24 hours after the initial procedure.48 However, it is appropriate in cases in which clinical signs indicate recurrent bleeding or if hemostasis during the initial procedure is questionable. A meta-analysis found that routinely repeating endoscopy reduces the rate of recurrent bleeding but not the need for surgery or the risk of death.49

ALL PATIENTS SHOULD BE ADMITTED

Figure 2. Algorithm for patients with acute upper gastrointestinal bleeding.
All patients with upper GI bleeding should be admitted to the hospital, with the level of care dictated by the severity of their clinical condition (Figure 2).

VARICEAL BLEEDING

Variceal bleeding, a severe outcome of portal hypertension secondary to cirrhosis, carries a 6-week mortality rate of 10% to 20%.50 In view of the risk, primary prevention is indicated in patients with high-risk varices.

The mainstays of primary and secondary prevention are the nonselective beta-blockers such as nadolol (Corgard) and propranolol (Inderal). Several randomized controlled trials have shown lower rates of recurrent bleeding and death with propranolol or nadolol than with placebo.51 In doses that decrease the heart rate by 25%, beta-blockers have been shown to delay and decrease variceal hemorrhage. However, most patients require prophylactic endoscopic variceal ligation because they cannot tolerate beta-blocker therapy.

In suspected acute variceal bleeding, a somatostatin analogue should be started to decrease the portal pressure, and antibiotics should be started to reduce the risks of infection and death. Vasoactive drugs, ie, somatostatin analogues, should be started before endoscopy and continued for 5 days to reduce the chances of recurrent bleeding.52,53

Terlipressin is the only drug proven to improve the odds of survival in acute variceal bleeding. Although widely used in Europe, it has not been approved for use in the United States.

Octreotide, another option, improves hemostasis to the same extent, although it does not increase the survival rate.54,55 The recommended dose of octreotide for patients with variceal bleeding is a 50-μg intravenous bolus, followed by a 50-μg/hour infusion for 5 days.

Combining endoscopic and drug therapy improves the chances of stopping the bleeding and reduces the risk of recurrent bleeding compared with endoscopic therapy alone.56

Transjugular intrahepatic portosystemic shunting is indicated in recurrent variceal hemorrhage or in those with initial bleeding that is refractory to standard medical and endoscopic therapy. It is not the primary therapy because it doubles the risk of encephalopathy and has a high stent occlusion rate (up to 60%, lower with covered stents).

 

 

GI BLEEDING CAN CAUSE ACUTE MYOCARDIAL INFARCTION

The simultaneous presentation of acute myocardial infarction (MI) and GI hemorrhage is very serious and unfortunately common.

An acute MI occurring simultaneously with or after GI bleeding is usually precipitated by massive bleeding causing hypovolemia, hemodynamic compromise, and hypoperfusion. Conversely, the anticoagulant, antiplatelet, or thrombolytic drugs given to treat MI can precipitate GI bleeding (see below).

This distinction is important because the two scenarios have different clinical courses and prognoses. GI bleeding that precipitates an acute MI tends to be massive, whereas GI bleeding after treatment of acute MI tends to be self-limited and often resolves with reversal of underlying coagulopathy.57

Endoscopy carries a higher than average risk in patients with recent acute MI, with all-cause mortality rates as high as 1%.58 (The usual rate is 0.0004%.59) Nevertheless, endoscopy can be safely performed early on in patients with acute MI if it is done under strict monitoring in a coronary care unit.

Several studies have shown that MI patients who present with upper GI bleeding as the inciting event or patients with acute MI who are vomiting blood or who are hemodynamically unstable due to GI bleeding are significantly more likely to have a high-risk lesion and so have the greatest need for endoscopic therapy. Therefore, endoscopic intervention may be offered to MI patients at high risk who have been started on antiplatelet agents.

WARFARIN CAN PRECIPITATE BLEEDING

Acute upper GI bleeding can be a severe complication of long-term oral anticoagulation, not because the drugs cause ulcers, but rather because they exacerbate ulcers that are already present.60 Therefore, when starting warfarin (Coumadin), patients should be evaluated to determine if they have other risk factors for GI bleeding, such as ulcers.

The number of people presenting with upper GI bleeding while on warfarin therapy is increasing because of the expanding indications for long-term anticoagulation therapy, such as atrial fibrillation and deep venous thrombosis.

The risk of GI bleeding in patients who use oral anticoagulants is estimated to be 2.3 to 4.9 times higher than in nonusers.61

The goal international normalized ratio (INR) for patients on warfarin therapy is usually 2.0 to 3.0. Recent studies found that endoscopy can be safely performed in patients with acute GI bleeding whose INR is between 2.0 and 3.0.62,63 Some suggest that both the length of warfarin therapy and the INR affect the risk of bleeding.64,65

Managing patients with an INR higher than 3.0 who have an episode of GI bleeding is always a challenge. It is not uncommon to find pathologic lesions causing GI bleeding in patients who are on warfarin with a supratherapeutic INR, and thus, endoscopy is indicated. However, before endoscopy, reversal of anticoagulation should be considered.

BLEEDING IN PATIENTS ON ANTIPLATELET DRUGS

Aspirin

Aspirin decreases production of prostaglandins in the GI tract, thereby decreasing the protective and restorative properties of the gastric and duodenal mucosa and predisposing to ulcers and bleeding.

The higher the aspirin dose, the higher the risk. Aspirin doubles the risk of upper GI bleeding at daily doses of 75 mg and quadruples it at doses of 300 mg.66 Even doses as low as 10 mg can decrease gastric mucosal prostaglandin production.67 Thus, it appears that there is no risk-free dose of aspirin, and enteric-coated or buffered formulations do not appear to reduce the risk.68–70

The most important risk factor for upper GI bleeding in patients taking aspirin is a history of peptic ulcer bleeding. Approximately 15% of aspirin users who have bleeding from ulcers have recurrent bleeding within 1 year.71

As aspirin-induced GI bleeding becomes more common, health care providers often feel caught between the GI risk and the cardiovascular benefit. When considering whether to discontinue antiplatelet therapy, a cardiologist should be consulted along with a gastroenterologist to weigh the risks of GI bleeding vs thrombosis. To date, there have been no clinical trials published to suggest when antiplatelet therapy should be stopped to optimize GI and cardiovascular outcomes. An alternative is to replace aspirin with another antiplatelet drug that does not induce ulcers.

Clopidogrel

Clopidogrel (Plavix) is recommended for hospitalized patients with acute coronary syndrome who cannot tolerate the GI side effects of aspirin, according to the joint guidelines of the American College of Cardiology and the American Heart Association, with the highest level of evidence.72 This recommendation was largely based on the safety data from the CAPRIE (Clopidogrel Versus Aspirin in Patients at Risk of Ischemic Events) trial, in which the incidence of major GI bleeding was lower in the clopidogrel group (0.52%) than in the aspirin group (0.72%; P < .05).73

Aspirin plus a proton pump inhibitor

Patients who have had an episode of upper GI bleeding and who need long-term aspirin therapy should also receive a proton pump inhibitor indefinitely to prevent ulcer recurrence.

In a recent double-blind randomized controlled trial in patients with a history of aspirin-induced bleeding, the combination of low-dose aspirin plus esomeprazole (Nexium) twice a day was superior to clopidogrel by itself in terms of the rate of recurrent bleeding (0.7% vs 8.6%; P < .05).74 A similar trial showed nearly identical results: 0% upper GI bleeding in the group receiving aspirin plus esomeprazole 20 mg daily, vs 13.6% in the clopidogrel group (P = .0019).75 These studies suggest that a once-daily proton pump inhibitor combined with aspirin is a safer alternative than clopidogrel alone.

Clopidogrel plus a proton pump inhibitor

Interestingly, recent studies have shown that omeprazole decreases the antiplatelet effect of clopidogrel, possibly by inhibiting the CYP2C19 enzyme.76 However, concomitant use of pantoprazole (Protonix), lansoprazole (Prevacid), and esomeprazole did not have this effect, suggesting that although all proton pump inhibitors are metabolized to a varying degree by CYP2C19, the interaction between proton pump inhibitors and clopidogrel is not a class effect.77–79 Therefore, pantoprazole, lansoprazole, and esomeprazole may be the appropriate proton pump inhibitors to use with clopidogrel in patients who have a clear indication for the medication, consistent with current guideline recommendations.

Helicobacter pylori infection in antiplatelet drug users

Before starting any long-term antiplatelet therapy, patients with a history of ulcers should be tested and treated for H pylori (Table 4).80 Confirmation of eradication is required after H pylori treatment in patients with upper GI bleeding. Some suggest that for patients with a history of bleeding ulcer who need aspirin, eradication of H pylori substantially reduces the risk of recurrent ulcer bleeding.81

 

 

TREATMENT AND PREVENTION OF NSAID-RELATED GI INJURY

About 1 in 20 users of NSAIDs develop GI complications and ulcers of varying degrees of severity, as do one in seven NSAID users over the age of 65. In fact, NSAID use accounts for 30% of hospitalizations for upper GI bleeding and deaths from this cause.82–85 In addition, approximately 15% to 30% of NSAID users have clinically silent but endoscopically evident peptic ulcers.86

NSAIDs contribute to ulcer development by depleting prostaglandins. Thus, misoprostol (Cytotec), a synthetic prostaglandin, has been used to reduce this side effect.

In a clinical trial, misoprostol reduced the incidence of NSAID-associated GI complications by 40%.87 Furthermore, it has been shown to be better than placebo in preventing recurrent gastric ulcers in patients with a history of gastric ulcer who were receiving low-dose aspirin.88

However, misoprostol is rarely used because it can cause diarrhea and abdominal cramping. Rather, the preferred drugs for preventing and treating NSAID- and aspirin-related GI lesions are proton pump inhibitors.

Numerous clinical trials using endoscopic end points showed that proton pump inhibitors in standard doses significantly reduce the incidence of ulcers associated with the use of NSAIDs.89 Proton pump inhibitor therapy has achieved a significant reduction in relative risk of upper GI bleeding in patients who received low-dose aspirin therapy, as confirmed by epidemiologic studies.90,91 The number of NSAID-related ulcers found on endoscopy could be reduced by an estimated 90% simply by using proton pump inhibitors.92

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Mohammed A. Qadeer, MD, MPH
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John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Digestive Disease Institute, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Department of Gastroenterology and Hepatology, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail: vargoj@ccf.org

Dr. Vargo has disclosed that he has received consulting fees from Ethicon EndoSurgery and honoraria for teaching and speaking from Olympus America, Inc.

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Mohammed A. Qadeer, MD, MPH
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John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Digestive Disease Institute, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Department of Gastroenterology and Hepatology, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail: vargoj@ccf.org

Dr. Vargo has disclosed that he has received consulting fees from Ethicon EndoSurgery and honoraria for teaching and speaking from Olympus America, Inc.

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Mazen Albeldawi, MD
Department of Internal Medicine, Cleveland Clinic

Mohammed A. Qadeer, MD, MPH
Department of Gastroenterology and Hepatology, Digestive Disease Institute, Cleveland Clinic

John J. Vargo, MD, MPH
Department of Gastroenterology and Hepatology, Digestive Disease Institute, Cleveland Clinic

Address: John J. Vargo, MD, MPH, Department of Gastroenterology and Hepatology, A30, Cleveland Clinic, 9500 Euclid Avenue, Cleveland, OH 44195; e-mail: vargoj@ccf.org

Dr. Vargo has disclosed that he has received consulting fees from Ethicon EndoSurgery and honoraria for teaching and speaking from Olympus America, Inc.

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Upper gastrointestinal (GI) bleeding is common, costly, and potentially life-threatening. It must be managed promptly and appropriately to prevent adverse outcomes.

More people are admitted to the hospital for upper GI bleeding than for congestive heart failure or deep vein thrombosis. In the United States, the annual rate of hospitalization for upper GI bleeding is estimated to be 165 per 100,000—more than 300,000 hospitalizations per year, at a cost of $2.5 billion.1,2

Furthermore, despite advances in therapy, the case-fatality rate has remained unchanged at 7% to 10%.3 This may be because today’s patients are older and have more comorbidities than those in the past.4

CAUSES OF UPPER GI BLEEDING

Peptic ulcers account for about 60% of severe cases of upper GI bleeding,5 and they are the focus of this paper. Fortunately, up to 80% of bleeding ulcers stop bleeding spontaneously without any intervention.6

Gastroduodenal erosions account for about 12%.3

Varices due to cirrhosis are less common but more dangerous. Variceal bleeding accounts for a relatively small percentage (6%) of upper GI bleeding, but the mortality rate from a single episode of variceal bleeding is 30%, and 60% to 70% of patients die within 1 year, mostly of underlying liver disease.

Less frequent causes include Mallory-Weiss tears, erosive duodenitis, Dieulafoy ulcer (a type of vascular malformation), other vascular lesions, neoplasms, aortoenteric fistula, gastric antral vascular ectasia, and prolapse gastropathy.5

HEMATEMESIS AND MELENA

The most common presenting signs of acute upper GI bleeding are hematemesis (vomiting of blood), “coffee grounds” emesis, and melena (tarry black stools). About 30% of patients with bleeding ulcers present with hematemesis, 20% with melena, and 50% with both.7

Hematochezia (red blood in the stool) usually suggests a lower GI source of bleeding, since blood from an upper source turns black and tarry as it passes through the gut, producing melena. However, up to 5% of patients with bleeding ulcers have hematochezia,7 and it indicates heavy bleeding: bleeding of approximately 1,000 mL into the upper GI tract is needed to cause hematochezia, whereas only 50 to 100 mL is needed to cause melena.8,9 Hematochezia with signs and symptoms of hemodynamic compromise such as syncope, postural hypotension, tachycardia, and shock should therefore direct one’s attention to an upper GI source of bleeding.

Nonspecific features include nausea, vomiting, epigastric pain, vasovagal phenomena, and syncope.

WHAT IS THE PATIENT’S RISK?

An assessment of clinical severity is the first critical task, as it helps in planning treatment. Advanced age, multiple comorbidities, and hemodynamic instability call for aggressive treatment. Apart from this simple clinical rule, scoring systems have been developed.

The Rockall scoring system, the most widely used, gives estimates of the risks of recurrent bleeding and death. It is based on the three clinical factors mentioned above and on two endoscopic ones, awarding points for:

  • Age—0 points if less than 60; 1 point if 60 to 79; or 2 points if 80 years or older
  • Shock—1 point if the pulse is more than 100; 2 points if the systolic blood pressure is less than 100 mm Hg
  • Comorbid illness—2 points for ischemic heart disease, congestive heart failure, or other major comorbidity; 3 points for renal failure, hepatic failure, or metastatic disease
  • Endoscopic diagnosis—0 points if no lesion found or a Mallory-Weiss tear; 1 point for peptic ulcer, esophagitis, or erosive disease; 2 points for GI malignancy
  • Endoscopic stigmata or recent hemorrhage—0 points for a clean-based ulcer or flat pigmented spot; 2 points for blood in the upper GI tract, active bleeding, a nonbleeding visible vessel, or adherent clot.

The Rockall score can thus range from 0 to 11 points, with an overall score of 0, 1, or 2 associated with an excellent prognosis.10

The Blatchford scoring system uses only clinical and laboratory factors and has no endoscopic component (Table 1). In contrast to the Rockall score, the main outcome it predicts is the need for clinical intervention (endoscopy, surgery, or blood transfusion). The Blatchford score ranges from 0 to 23; most patients with a score of 6 or higher need intervention.11

Other systems that are used less often include the Baylor severity scale and the Acute Physiology and Chronic Health Evaluation (APACHE) II score.

Does the patient have varices?

All variceal bleeding should be considered severe, since the 1-year death rate is so high (up to 70%). Clues pointing to variceal bleeding include previous variceal bleeding, thrombocytopenia, history of liver disease, and signs of liver disease on clinical examination.

All patients suspected of having bleeding varices should be admitted to the intensive care unit for close monitoring and should be given the highest priority, even if they are hemodynamically stable.

Is the patient hemodynamically stable?

Appropriate hemodynamic assessment includes monitoring of heart rate, blood pressure, and mental status. Tachycardia at rest, hypotension, and orthostatic changes in vital signs indicate a considerable loss of blood volume. Low urine output, dry mucous membranes, and sunken neck veins are also useful signs. (Tachycardia may be blunted if the patient is taking a beta-blocker.)

If these signs of hypovolemia are present, the initial management focuses on treating shock and on improving oxygen delivery to the vital organs. This involves repletion of the intravascular volume with intravenous infusions or blood transfusions. Supplemental oxygen also is useful, especially in elderly patients with heart disease.12

Inspection of nasogastric aspirate

In the initial assessment, it is useful to insert a nasogastric tube and inspect the aspirate. If it contains bright red blood, the patient needs an urgent endoscopic evaluation and an intensive level of care13,14; if it contains coffee-grounds material, the patient needs to be admitted to the hospital and to undergo endoscopic evaluation within 24 hours.

However, a normal aspirate does not rule out upper GI bleeding. Aljebreen et al15 found that 15% of patients with upper GI bleeding and normal nasogastric aspirate still had high-risk lesions (ie, visible bleeding or nonbleeding visible vessels) on endoscopy.

 

 

ACID-SUPPRESSION HELPS ULCERS HEAL

Acid and pepsin interfere with the healing of ulcers and other nonvariceal upper GI lesions. Further, an acidic environment promotes platelet disaggregation and fibrinolysis and impairs clot formation.16 This suggests that inhibiting gastric acid secretion and raising the gastric pH to 6 or higher may stabilize clots. Moreover, pepsinogen in the stomach is converted to its active form (pepsin) if the pH is less than 4. Therefore, keeping the pH above 4 keeps pepsinogen in an inactive form.

Histamine-2 receptor antagonists

Histamine-2 receptor antagonists were the first drugs to inhibit acid secretion, reversibly blocking histamine-2 receptors on the basolateral membrane of parietal cells. However, these drugs did not prove very useful in managing upper GI bleeding in clinical trials.17,18 In their intravenous form, they often fail to keep the gastric pH at 6 or higher, due to tachyphylaxis.19 The use of this class of drugs has declined in favor of proton pump inhibitors.

Proton pump inhibitors

Proton pump inhibitors reduce both basal and stimulated acid secretion by inhibiting hydrogen-potassium adenosine triphosphatase, the proton pump of the parietal cell.

Multiple studies have shown that proton pump inhibitors raise the gastric pH and keep it high. For example, an infusion of omeprazole (Prilosec) can keep the gastric pH above 6 for 72 hours without inducing tachyphylaxis.20,21

Started after endoscopy. Randomized controlled trials have found proton pump inhibitors to be effective when given in high doses intravenously for 72 hours after successful endoscopic treatment of bleeding ulcers with high-risk endoscopic signs, such as active bleeding or nonbleeding visible vessels.22,23

A meta-analysis indicated that these drugs decrease the incidence of recurrent peptic ulcer bleeding, the need for blood transfusions, the need for surgery, and the duration of hospitalization, but not the mortality rate.24,25 These studies also illustrate the benefit of following up endoscopic treatment to stop the bleeding with an intravenous infusion of a proton pump inhibitor.

The recommended dose of omeprazole for patients with high-risk findings on endoscopy is an 80-mg bolus followed by an 8-mg/hour infusion for 72 hours. After the patient’s condition stabilizes, oral therapy can be substituted for intravenous therapy. In patients with low-risk endoscopic findings (a clean-based ulcer or flat spot), oral proton pump inhibitors in high doses are recommended.

In either case, after the initial bleeding is treated endoscopically and hemostasis is achieved, a proton pump inhibitor is recommended for 6 to 8 weeks, or longer if the patient is also positive for Helicobacter pylori or is on daily treatment with aspirin or a nonsteroidal anti-inflammatory drug (NSAID) that is not selective for cyclo-oxygenase 2 (see below).

Started before endoscopy, these drugs reduced the frequency of actively bleeding ulcers, the duration of hospitalization, and the need for endoscopic therapy in a randomized controlled trial.26 A meta-analysis found that significantly fewer patients had signs of recent bleeding on endoscopy if they received a proton pump inhibitor 24 to 48 hours before the procedure, but it did not find any significant difference in important clinical outcomes such as death, recurrent bleeding, or surgery.27 Nevertheless, we believe that intravenous proton pump inhibitor therapy should be started before endoscopy in patients with upper GI bleeding.

Somatostatin analogues

Octreotide (Sandostatin), an analogue of the hormone somatostatin, decreases splanchnic blood flow, decreases secretion of gastric acid and pepsin, and stimulates mucus production. Although it is beneficial in treating upper GI bleeding due to varices, its benefit has not been confirmed in patients with nonvariceal upper GI bleeding.

A meta-analysis revealed that outcomes were better with high-dose intravenous proton pump inhibitor therapy than with octreotide when these drugs were started after endoscopic treatment of acute peptic ulcer bleeding.28 Nevertheless, octreotide may be useful in patients with uncontrolled nonvariceal bleeding who are awaiting endoscopy, since it is relatively safe to use.

ALL PATIENTS NEED ENDOSCOPY

All patients with upper GI bleeding need an upper endoscopic examination to diagnose and assess the risk posed by the bleeding lesion and to treat the lesion, reducing the risk of recurrent bleeding.

How urgently does endoscopy need to be done?

Endoscopy within the first 24 hours of upper GI bleeding is considered the standard of care. Patients with uncontrolled or recurrent bleeding should undergo endoscopy on an urgent basis to control the bleeding and reduce the risk of death.

However, how urgently endoscopy needs to be done is often debated. A multicenter randomized controlled trial compared outcomes in patients who underwent endoscopy within 6 hours of coming to the emergency department vs within 24 hours after the initial evaluation. The study found no significant difference in outcomes between the two groups; however, the group that underwent endoscopy sooner needed fewer transfusions.29

For a better view of the stomach

Gastric lavage improves the view of the gastric fundus but has not been proven to improve outcome.30

Promotility agents such as erythromycin and metoclopramide (Reglan) are also used to empty the stomach for better visualization.31–35 Erythromycin has been shown to improve visualization, shorten the procedure time, and prevent the need for additional endoscopy attempts in two randomized controlled studies.33,34 Furthermore, a cost-effectiveness study confirmed that giving intravenous erythromycin before endoscopy for acute upper GI bleeding saved money and resulted in an increase in quality-adjusted life-years.35

 

 

Endoscopy to diagnose bleeding and assess risk

Upper endoscopy is 90% to 95% diagnostic for acute upper GI bleeding.36

Figure 1. Endoscopic stigmata of bleeding peptic ulcer (arrows) and risk of recurrent bleeding and death.
Furthermore, some of the clinical scoring systems are based on endoscopic findings along with clinical factors on admission. These scoring systems are valuable for assessing patients with nonvariceal upper GI bleeding, as they predict the risk of death, longer hospital stay, surgical intervention, and recurrent bleeding.37,38 Patients with endoscopic findings associated with higher rates of recurrent bleeding and death (Figure 1) need aggressive management.

Certain factors, primarily clinical and endoscopic, predict that endoscopic treatment will fail to stop ulcer bleeding. Clinical factors include a history of peptic ulcer bleeding and hemodynamic compromise at presentation. Endoscopic factors include ulcers located high on the lesser curvature of the stomach, ulcers in the posterior or superior duodenal bulb, ulcers larger than 2 cm in diameter, and ulcers that are actively bleeding at the time of endoscopy.37 Other endoscopic findings that predict clinical outcome are summarized in Table 2.

Patients at high risk (ie, older than 60 years, with severe comorbidity, or hemodynamically compromised) who have active bleeding (ie, witnessed hematemesis, red blood per nasogastric tube, or fresh blood per rectum) or a nonbleeding visible vessel should be admitted to a monitored bed or intensive care unit. Observation in a regular medical ward is appropriate for high-risk patients found to have an adherent clot. Patients with low-risk findings (eg, a clean ulcer base) are at low risk of recurrent bleeding and may be considered for early hospital discharge with appropriate outpatient follow-up.

Endoscopy to treat bleeding

About 25% of endoscopic procedures performed for upper GI bleeding include some type of treatment,39 such as injections of epinephrine, normal saline, or sclerosants; thermal cautery; argon plasma coagulation; electrocautery; or application of clips or bands. They are all equally effective, and combinations of these therapies are more effective than when they are used individually. A recent meta-analysis found dual therapy to be superior to epinephrine monotherapy in preventing recurrent bleeding, need for surgery, and death.40

Endoscopic therapy is recommended for patients found to have active bleeding or nonbleeding visible blood vessels, as outcomes are better with endoscopic hemostatic treatment than with drug therapy alone (Table 3).41–44

How to manage adherent clots is controversial, but recent studies have revealed a significant benefit from removing them and treating the underlying lesions compared with drug therapy alone.43,45

Flat, pigmented spots and nonbleeding ulcers with a clean base do not require endoscopic treatment because the risk of recurrent bleeding is low.

Endoscopic therapy stops the bleeding in more than 90% of patients, but bleeding recurs after endoscopic therapy in 10% to 25%.46 Reversal of any severe coagulopathy with transfusions of platelets or fresh frozen plasma is essential for endoscopic hemostasis. However, coagulopathy at the time of initial bleeding and endoscopy does not appear to be associated with higher rates of recurrent bleeding following endoscopic therapy for nonvariceal upper GI bleeding.47

Patients with refractory bleeding are candidates for angiography or surgery. However, even when endoscopic hemostasis fails, endoscopy is important before angiography or surgery to pinpoint the site of bleeding and diagnose the cause.

A second endoscopic procedure is generally not recommended within 24 hours after the initial procedure.48 However, it is appropriate in cases in which clinical signs indicate recurrent bleeding or if hemostasis during the initial procedure is questionable. A meta-analysis found that routinely repeating endoscopy reduces the rate of recurrent bleeding but not the need for surgery or the risk of death.49

ALL PATIENTS SHOULD BE ADMITTED

Figure 2. Algorithm for patients with acute upper gastrointestinal bleeding.
All patients with upper GI bleeding should be admitted to the hospital, with the level of care dictated by the severity of their clinical condition (Figure 2).

VARICEAL BLEEDING

Variceal bleeding, a severe outcome of portal hypertension secondary to cirrhosis, carries a 6-week mortality rate of 10% to 20%.50 In view of the risk, primary prevention is indicated in patients with high-risk varices.

The mainstays of primary and secondary prevention are the nonselective beta-blockers such as nadolol (Corgard) and propranolol (Inderal). Several randomized controlled trials have shown lower rates of recurrent bleeding and death with propranolol or nadolol than with placebo.51 In doses that decrease the heart rate by 25%, beta-blockers have been shown to delay and decrease variceal hemorrhage. However, most patients require prophylactic endoscopic variceal ligation because they cannot tolerate beta-blocker therapy.

In suspected acute variceal bleeding, a somatostatin analogue should be started to decrease the portal pressure, and antibiotics should be started to reduce the risks of infection and death. Vasoactive drugs, ie, somatostatin analogues, should be started before endoscopy and continued for 5 days to reduce the chances of recurrent bleeding.52,53

Terlipressin is the only drug proven to improve the odds of survival in acute variceal bleeding. Although widely used in Europe, it has not been approved for use in the United States.

Octreotide, another option, improves hemostasis to the same extent, although it does not increase the survival rate.54,55 The recommended dose of octreotide for patients with variceal bleeding is a 50-μg intravenous bolus, followed by a 50-μg/hour infusion for 5 days.

Combining endoscopic and drug therapy improves the chances of stopping the bleeding and reduces the risk of recurrent bleeding compared with endoscopic therapy alone.56

Transjugular intrahepatic portosystemic shunting is indicated in recurrent variceal hemorrhage or in those with initial bleeding that is refractory to standard medical and endoscopic therapy. It is not the primary therapy because it doubles the risk of encephalopathy and has a high stent occlusion rate (up to 60%, lower with covered stents).

 

 

GI BLEEDING CAN CAUSE ACUTE MYOCARDIAL INFARCTION

The simultaneous presentation of acute myocardial infarction (MI) and GI hemorrhage is very serious and unfortunately common.

An acute MI occurring simultaneously with or after GI bleeding is usually precipitated by massive bleeding causing hypovolemia, hemodynamic compromise, and hypoperfusion. Conversely, the anticoagulant, antiplatelet, or thrombolytic drugs given to treat MI can precipitate GI bleeding (see below).

This distinction is important because the two scenarios have different clinical courses and prognoses. GI bleeding that precipitates an acute MI tends to be massive, whereas GI bleeding after treatment of acute MI tends to be self-limited and often resolves with reversal of underlying coagulopathy.57

Endoscopy carries a higher than average risk in patients with recent acute MI, with all-cause mortality rates as high as 1%.58 (The usual rate is 0.0004%.59) Nevertheless, endoscopy can be safely performed early on in patients with acute MI if it is done under strict monitoring in a coronary care unit.

Several studies have shown that MI patients who present with upper GI bleeding as the inciting event or patients with acute MI who are vomiting blood or who are hemodynamically unstable due to GI bleeding are significantly more likely to have a high-risk lesion and so have the greatest need for endoscopic therapy. Therefore, endoscopic intervention may be offered to MI patients at high risk who have been started on antiplatelet agents.

WARFARIN CAN PRECIPITATE BLEEDING

Acute upper GI bleeding can be a severe complication of long-term oral anticoagulation, not because the drugs cause ulcers, but rather because they exacerbate ulcers that are already present.60 Therefore, when starting warfarin (Coumadin), patients should be evaluated to determine if they have other risk factors for GI bleeding, such as ulcers.

The number of people presenting with upper GI bleeding while on warfarin therapy is increasing because of the expanding indications for long-term anticoagulation therapy, such as atrial fibrillation and deep venous thrombosis.

The risk of GI bleeding in patients who use oral anticoagulants is estimated to be 2.3 to 4.9 times higher than in nonusers.61

The goal international normalized ratio (INR) for patients on warfarin therapy is usually 2.0 to 3.0. Recent studies found that endoscopy can be safely performed in patients with acute GI bleeding whose INR is between 2.0 and 3.0.62,63 Some suggest that both the length of warfarin therapy and the INR affect the risk of bleeding.64,65

Managing patients with an INR higher than 3.0 who have an episode of GI bleeding is always a challenge. It is not uncommon to find pathologic lesions causing GI bleeding in patients who are on warfarin with a supratherapeutic INR, and thus, endoscopy is indicated. However, before endoscopy, reversal of anticoagulation should be considered.

BLEEDING IN PATIENTS ON ANTIPLATELET DRUGS

Aspirin

Aspirin decreases production of prostaglandins in the GI tract, thereby decreasing the protective and restorative properties of the gastric and duodenal mucosa and predisposing to ulcers and bleeding.

The higher the aspirin dose, the higher the risk. Aspirin doubles the risk of upper GI bleeding at daily doses of 75 mg and quadruples it at doses of 300 mg.66 Even doses as low as 10 mg can decrease gastric mucosal prostaglandin production.67 Thus, it appears that there is no risk-free dose of aspirin, and enteric-coated or buffered formulations do not appear to reduce the risk.68–70

The most important risk factor for upper GI bleeding in patients taking aspirin is a history of peptic ulcer bleeding. Approximately 15% of aspirin users who have bleeding from ulcers have recurrent bleeding within 1 year.71

As aspirin-induced GI bleeding becomes more common, health care providers often feel caught between the GI risk and the cardiovascular benefit. When considering whether to discontinue antiplatelet therapy, a cardiologist should be consulted along with a gastroenterologist to weigh the risks of GI bleeding vs thrombosis. To date, there have been no clinical trials published to suggest when antiplatelet therapy should be stopped to optimize GI and cardiovascular outcomes. An alternative is to replace aspirin with another antiplatelet drug that does not induce ulcers.

Clopidogrel

Clopidogrel (Plavix) is recommended for hospitalized patients with acute coronary syndrome who cannot tolerate the GI side effects of aspirin, according to the joint guidelines of the American College of Cardiology and the American Heart Association, with the highest level of evidence.72 This recommendation was largely based on the safety data from the CAPRIE (Clopidogrel Versus Aspirin in Patients at Risk of Ischemic Events) trial, in which the incidence of major GI bleeding was lower in the clopidogrel group (0.52%) than in the aspirin group (0.72%; P < .05).73

Aspirin plus a proton pump inhibitor

Patients who have had an episode of upper GI bleeding and who need long-term aspirin therapy should also receive a proton pump inhibitor indefinitely to prevent ulcer recurrence.

In a recent double-blind randomized controlled trial in patients with a history of aspirin-induced bleeding, the combination of low-dose aspirin plus esomeprazole (Nexium) twice a day was superior to clopidogrel by itself in terms of the rate of recurrent bleeding (0.7% vs 8.6%; P < .05).74 A similar trial showed nearly identical results: 0% upper GI bleeding in the group receiving aspirin plus esomeprazole 20 mg daily, vs 13.6% in the clopidogrel group (P = .0019).75 These studies suggest that a once-daily proton pump inhibitor combined with aspirin is a safer alternative than clopidogrel alone.

Clopidogrel plus a proton pump inhibitor

Interestingly, recent studies have shown that omeprazole decreases the antiplatelet effect of clopidogrel, possibly by inhibiting the CYP2C19 enzyme.76 However, concomitant use of pantoprazole (Protonix), lansoprazole (Prevacid), and esomeprazole did not have this effect, suggesting that although all proton pump inhibitors are metabolized to a varying degree by CYP2C19, the interaction between proton pump inhibitors and clopidogrel is not a class effect.77–79 Therefore, pantoprazole, lansoprazole, and esomeprazole may be the appropriate proton pump inhibitors to use with clopidogrel in patients who have a clear indication for the medication, consistent with current guideline recommendations.

Helicobacter pylori infection in antiplatelet drug users

Before starting any long-term antiplatelet therapy, patients with a history of ulcers should be tested and treated for H pylori (Table 4).80 Confirmation of eradication is required after H pylori treatment in patients with upper GI bleeding. Some suggest that for patients with a history of bleeding ulcer who need aspirin, eradication of H pylori substantially reduces the risk of recurrent ulcer bleeding.81

 

 

TREATMENT AND PREVENTION OF NSAID-RELATED GI INJURY

About 1 in 20 users of NSAIDs develop GI complications and ulcers of varying degrees of severity, as do one in seven NSAID users over the age of 65. In fact, NSAID use accounts for 30% of hospitalizations for upper GI bleeding and deaths from this cause.82–85 In addition, approximately 15% to 30% of NSAID users have clinically silent but endoscopically evident peptic ulcers.86

NSAIDs contribute to ulcer development by depleting prostaglandins. Thus, misoprostol (Cytotec), a synthetic prostaglandin, has been used to reduce this side effect.

In a clinical trial, misoprostol reduced the incidence of NSAID-associated GI complications by 40%.87 Furthermore, it has been shown to be better than placebo in preventing recurrent gastric ulcers in patients with a history of gastric ulcer who were receiving low-dose aspirin.88

However, misoprostol is rarely used because it can cause diarrhea and abdominal cramping. Rather, the preferred drugs for preventing and treating NSAID- and aspirin-related GI lesions are proton pump inhibitors.

Numerous clinical trials using endoscopic end points showed that proton pump inhibitors in standard doses significantly reduce the incidence of ulcers associated with the use of NSAIDs.89 Proton pump inhibitor therapy has achieved a significant reduction in relative risk of upper GI bleeding in patients who received low-dose aspirin therapy, as confirmed by epidemiologic studies.90,91 The number of NSAID-related ulcers found on endoscopy could be reduced by an estimated 90% simply by using proton pump inhibitors.92

Upper gastrointestinal (GI) bleeding is common, costly, and potentially life-threatening. It must be managed promptly and appropriately to prevent adverse outcomes.

More people are admitted to the hospital for upper GI bleeding than for congestive heart failure or deep vein thrombosis. In the United States, the annual rate of hospitalization for upper GI bleeding is estimated to be 165 per 100,000—more than 300,000 hospitalizations per year, at a cost of $2.5 billion.1,2

Furthermore, despite advances in therapy, the case-fatality rate has remained unchanged at 7% to 10%.3 This may be because today’s patients are older and have more comorbidities than those in the past.4

CAUSES OF UPPER GI BLEEDING

Peptic ulcers account for about 60% of severe cases of upper GI bleeding,5 and they are the focus of this paper. Fortunately, up to 80% of bleeding ulcers stop bleeding spontaneously without any intervention.6

Gastroduodenal erosions account for about 12%.3

Varices due to cirrhosis are less common but more dangerous. Variceal bleeding accounts for a relatively small percentage (6%) of upper GI bleeding, but the mortality rate from a single episode of variceal bleeding is 30%, and 60% to 70% of patients die within 1 year, mostly of underlying liver disease.

Less frequent causes include Mallory-Weiss tears, erosive duodenitis, Dieulafoy ulcer (a type of vascular malformation), other vascular lesions, neoplasms, aortoenteric fistula, gastric antral vascular ectasia, and prolapse gastropathy.5

HEMATEMESIS AND MELENA

The most common presenting signs of acute upper GI bleeding are hematemesis (vomiting of blood), “coffee grounds” emesis, and melena (tarry black stools). About 30% of patients with bleeding ulcers present with hematemesis, 20% with melena, and 50% with both.7

Hematochezia (red blood in the stool) usually suggests a lower GI source of bleeding, since blood from an upper source turns black and tarry as it passes through the gut, producing melena. However, up to 5% of patients with bleeding ulcers have hematochezia,7 and it indicates heavy bleeding: bleeding of approximately 1,000 mL into the upper GI tract is needed to cause hematochezia, whereas only 50 to 100 mL is needed to cause melena.8,9 Hematochezia with signs and symptoms of hemodynamic compromise such as syncope, postural hypotension, tachycardia, and shock should therefore direct one’s attention to an upper GI source of bleeding.

Nonspecific features include nausea, vomiting, epigastric pain, vasovagal phenomena, and syncope.

WHAT IS THE PATIENT’S RISK?

An assessment of clinical severity is the first critical task, as it helps in planning treatment. Advanced age, multiple comorbidities, and hemodynamic instability call for aggressive treatment. Apart from this simple clinical rule, scoring systems have been developed.

The Rockall scoring system, the most widely used, gives estimates of the risks of recurrent bleeding and death. It is based on the three clinical factors mentioned above and on two endoscopic ones, awarding points for:

  • Age—0 points if less than 60; 1 point if 60 to 79; or 2 points if 80 years or older
  • Shock—1 point if the pulse is more than 100; 2 points if the systolic blood pressure is less than 100 mm Hg
  • Comorbid illness—2 points for ischemic heart disease, congestive heart failure, or other major comorbidity; 3 points for renal failure, hepatic failure, or metastatic disease
  • Endoscopic diagnosis—0 points if no lesion found or a Mallory-Weiss tear; 1 point for peptic ulcer, esophagitis, or erosive disease; 2 points for GI malignancy
  • Endoscopic stigmata or recent hemorrhage—0 points for a clean-based ulcer or flat pigmented spot; 2 points for blood in the upper GI tract, active bleeding, a nonbleeding visible vessel, or adherent clot.

The Rockall score can thus range from 0 to 11 points, with an overall score of 0, 1, or 2 associated with an excellent prognosis.10

The Blatchford scoring system uses only clinical and laboratory factors and has no endoscopic component (Table 1). In contrast to the Rockall score, the main outcome it predicts is the need for clinical intervention (endoscopy, surgery, or blood transfusion). The Blatchford score ranges from 0 to 23; most patients with a score of 6 or higher need intervention.11

Other systems that are used less often include the Baylor severity scale and the Acute Physiology and Chronic Health Evaluation (APACHE) II score.

Does the patient have varices?

All variceal bleeding should be considered severe, since the 1-year death rate is so high (up to 70%). Clues pointing to variceal bleeding include previous variceal bleeding, thrombocytopenia, history of liver disease, and signs of liver disease on clinical examination.

All patients suspected of having bleeding varices should be admitted to the intensive care unit for close monitoring and should be given the highest priority, even if they are hemodynamically stable.

Is the patient hemodynamically stable?

Appropriate hemodynamic assessment includes monitoring of heart rate, blood pressure, and mental status. Tachycardia at rest, hypotension, and orthostatic changes in vital signs indicate a considerable loss of blood volume. Low urine output, dry mucous membranes, and sunken neck veins are also useful signs. (Tachycardia may be blunted if the patient is taking a beta-blocker.)

If these signs of hypovolemia are present, the initial management focuses on treating shock and on improving oxygen delivery to the vital organs. This involves repletion of the intravascular volume with intravenous infusions or blood transfusions. Supplemental oxygen also is useful, especially in elderly patients with heart disease.12

Inspection of nasogastric aspirate

In the initial assessment, it is useful to insert a nasogastric tube and inspect the aspirate. If it contains bright red blood, the patient needs an urgent endoscopic evaluation and an intensive level of care13,14; if it contains coffee-grounds material, the patient needs to be admitted to the hospital and to undergo endoscopic evaluation within 24 hours.

However, a normal aspirate does not rule out upper GI bleeding. Aljebreen et al15 found that 15% of patients with upper GI bleeding and normal nasogastric aspirate still had high-risk lesions (ie, visible bleeding or nonbleeding visible vessels) on endoscopy.

 

 

ACID-SUPPRESSION HELPS ULCERS HEAL

Acid and pepsin interfere with the healing of ulcers and other nonvariceal upper GI lesions. Further, an acidic environment promotes platelet disaggregation and fibrinolysis and impairs clot formation.16 This suggests that inhibiting gastric acid secretion and raising the gastric pH to 6 or higher may stabilize clots. Moreover, pepsinogen in the stomach is converted to its active form (pepsin) if the pH is less than 4. Therefore, keeping the pH above 4 keeps pepsinogen in an inactive form.

Histamine-2 receptor antagonists

Histamine-2 receptor antagonists were the first drugs to inhibit acid secretion, reversibly blocking histamine-2 receptors on the basolateral membrane of parietal cells. However, these drugs did not prove very useful in managing upper GI bleeding in clinical trials.17,18 In their intravenous form, they often fail to keep the gastric pH at 6 or higher, due to tachyphylaxis.19 The use of this class of drugs has declined in favor of proton pump inhibitors.

Proton pump inhibitors

Proton pump inhibitors reduce both basal and stimulated acid secretion by inhibiting hydrogen-potassium adenosine triphosphatase, the proton pump of the parietal cell.

Multiple studies have shown that proton pump inhibitors raise the gastric pH and keep it high. For example, an infusion of omeprazole (Prilosec) can keep the gastric pH above 6 for 72 hours without inducing tachyphylaxis.20,21

Started after endoscopy. Randomized controlled trials have found proton pump inhibitors to be effective when given in high doses intravenously for 72 hours after successful endoscopic treatment of bleeding ulcers with high-risk endoscopic signs, such as active bleeding or nonbleeding visible vessels.22,23

A meta-analysis indicated that these drugs decrease the incidence of recurrent peptic ulcer bleeding, the need for blood transfusions, the need for surgery, and the duration of hospitalization, but not the mortality rate.24,25 These studies also illustrate the benefit of following up endoscopic treatment to stop the bleeding with an intravenous infusion of a proton pump inhibitor.

The recommended dose of omeprazole for patients with high-risk findings on endoscopy is an 80-mg bolus followed by an 8-mg/hour infusion for 72 hours. After the patient’s condition stabilizes, oral therapy can be substituted for intravenous therapy. In patients with low-risk endoscopic findings (a clean-based ulcer or flat spot), oral proton pump inhibitors in high doses are recommended.

In either case, after the initial bleeding is treated endoscopically and hemostasis is achieved, a proton pump inhibitor is recommended for 6 to 8 weeks, or longer if the patient is also positive for Helicobacter pylori or is on daily treatment with aspirin or a nonsteroidal anti-inflammatory drug (NSAID) that is not selective for cyclo-oxygenase 2 (see below).

Started before endoscopy, these drugs reduced the frequency of actively bleeding ulcers, the duration of hospitalization, and the need for endoscopic therapy in a randomized controlled trial.26 A meta-analysis found that significantly fewer patients had signs of recent bleeding on endoscopy if they received a proton pump inhibitor 24 to 48 hours before the procedure, but it did not find any significant difference in important clinical outcomes such as death, recurrent bleeding, or surgery.27 Nevertheless, we believe that intravenous proton pump inhibitor therapy should be started before endoscopy in patients with upper GI bleeding.

Somatostatin analogues

Octreotide (Sandostatin), an analogue of the hormone somatostatin, decreases splanchnic blood flow, decreases secretion of gastric acid and pepsin, and stimulates mucus production. Although it is beneficial in treating upper GI bleeding due to varices, its benefit has not been confirmed in patients with nonvariceal upper GI bleeding.

A meta-analysis revealed that outcomes were better with high-dose intravenous proton pump inhibitor therapy than with octreotide when these drugs were started after endoscopic treatment of acute peptic ulcer bleeding.28 Nevertheless, octreotide may be useful in patients with uncontrolled nonvariceal bleeding who are awaiting endoscopy, since it is relatively safe to use.

ALL PATIENTS NEED ENDOSCOPY

All patients with upper GI bleeding need an upper endoscopic examination to diagnose and assess the risk posed by the bleeding lesion and to treat the lesion, reducing the risk of recurrent bleeding.

How urgently does endoscopy need to be done?

Endoscopy within the first 24 hours of upper GI bleeding is considered the standard of care. Patients with uncontrolled or recurrent bleeding should undergo endoscopy on an urgent basis to control the bleeding and reduce the risk of death.

However, how urgently endoscopy needs to be done is often debated. A multicenter randomized controlled trial compared outcomes in patients who underwent endoscopy within 6 hours of coming to the emergency department vs within 24 hours after the initial evaluation. The study found no significant difference in outcomes between the two groups; however, the group that underwent endoscopy sooner needed fewer transfusions.29

For a better view of the stomach

Gastric lavage improves the view of the gastric fundus but has not been proven to improve outcome.30

Promotility agents such as erythromycin and metoclopramide (Reglan) are also used to empty the stomach for better visualization.31–35 Erythromycin has been shown to improve visualization, shorten the procedure time, and prevent the need for additional endoscopy attempts in two randomized controlled studies.33,34 Furthermore, a cost-effectiveness study confirmed that giving intravenous erythromycin before endoscopy for acute upper GI bleeding saved money and resulted in an increase in quality-adjusted life-years.35

 

 

Endoscopy to diagnose bleeding and assess risk

Upper endoscopy is 90% to 95% diagnostic for acute upper GI bleeding.36

Figure 1. Endoscopic stigmata of bleeding peptic ulcer (arrows) and risk of recurrent bleeding and death.
Furthermore, some of the clinical scoring systems are based on endoscopic findings along with clinical factors on admission. These scoring systems are valuable for assessing patients with nonvariceal upper GI bleeding, as they predict the risk of death, longer hospital stay, surgical intervention, and recurrent bleeding.37,38 Patients with endoscopic findings associated with higher rates of recurrent bleeding and death (Figure 1) need aggressive management.

Certain factors, primarily clinical and endoscopic, predict that endoscopic treatment will fail to stop ulcer bleeding. Clinical factors include a history of peptic ulcer bleeding and hemodynamic compromise at presentation. Endoscopic factors include ulcers located high on the lesser curvature of the stomach, ulcers in the posterior or superior duodenal bulb, ulcers larger than 2 cm in diameter, and ulcers that are actively bleeding at the time of endoscopy.37 Other endoscopic findings that predict clinical outcome are summarized in Table 2.

Patients at high risk (ie, older than 60 years, with severe comorbidity, or hemodynamically compromised) who have active bleeding (ie, witnessed hematemesis, red blood per nasogastric tube, or fresh blood per rectum) or a nonbleeding visible vessel should be admitted to a monitored bed or intensive care unit. Observation in a regular medical ward is appropriate for high-risk patients found to have an adherent clot. Patients with low-risk findings (eg, a clean ulcer base) are at low risk of recurrent bleeding and may be considered for early hospital discharge with appropriate outpatient follow-up.

Endoscopy to treat bleeding

About 25% of endoscopic procedures performed for upper GI bleeding include some type of treatment,39 such as injections of epinephrine, normal saline, or sclerosants; thermal cautery; argon plasma coagulation; electrocautery; or application of clips or bands. They are all equally effective, and combinations of these therapies are more effective than when they are used individually. A recent meta-analysis found dual therapy to be superior to epinephrine monotherapy in preventing recurrent bleeding, need for surgery, and death.40

Endoscopic therapy is recommended for patients found to have active bleeding or nonbleeding visible blood vessels, as outcomes are better with endoscopic hemostatic treatment than with drug therapy alone (Table 3).41–44

How to manage adherent clots is controversial, but recent studies have revealed a significant benefit from removing them and treating the underlying lesions compared with drug therapy alone.43,45

Flat, pigmented spots and nonbleeding ulcers with a clean base do not require endoscopic treatment because the risk of recurrent bleeding is low.

Endoscopic therapy stops the bleeding in more than 90% of patients, but bleeding recurs after endoscopic therapy in 10% to 25%.46 Reversal of any severe coagulopathy with transfusions of platelets or fresh frozen plasma is essential for endoscopic hemostasis. However, coagulopathy at the time of initial bleeding and endoscopy does not appear to be associated with higher rates of recurrent bleeding following endoscopic therapy for nonvariceal upper GI bleeding.47

Patients with refractory bleeding are candidates for angiography or surgery. However, even when endoscopic hemostasis fails, endoscopy is important before angiography or surgery to pinpoint the site of bleeding and diagnose the cause.

A second endoscopic procedure is generally not recommended within 24 hours after the initial procedure.48 However, it is appropriate in cases in which clinical signs indicate recurrent bleeding or if hemostasis during the initial procedure is questionable. A meta-analysis found that routinely repeating endoscopy reduces the rate of recurrent bleeding but not the need for surgery or the risk of death.49

ALL PATIENTS SHOULD BE ADMITTED

Figure 2. Algorithm for patients with acute upper gastrointestinal bleeding.
All patients with upper GI bleeding should be admitted to the hospital, with the level of care dictated by the severity of their clinical condition (Figure 2).

VARICEAL BLEEDING

Variceal bleeding, a severe outcome of portal hypertension secondary to cirrhosis, carries a 6-week mortality rate of 10% to 20%.50 In view of the risk, primary prevention is indicated in patients with high-risk varices.

The mainstays of primary and secondary prevention are the nonselective beta-blockers such as nadolol (Corgard) and propranolol (Inderal). Several randomized controlled trials have shown lower rates of recurrent bleeding and death with propranolol or nadolol than with placebo.51 In doses that decrease the heart rate by 25%, beta-blockers have been shown to delay and decrease variceal hemorrhage. However, most patients require prophylactic endoscopic variceal ligation because they cannot tolerate beta-blocker therapy.

In suspected acute variceal bleeding, a somatostatin analogue should be started to decrease the portal pressure, and antibiotics should be started to reduce the risks of infection and death. Vasoactive drugs, ie, somatostatin analogues, should be started before endoscopy and continued for 5 days to reduce the chances of recurrent bleeding.52,53

Terlipressin is the only drug proven to improve the odds of survival in acute variceal bleeding. Although widely used in Europe, it has not been approved for use in the United States.

Octreotide, another option, improves hemostasis to the same extent, although it does not increase the survival rate.54,55 The recommended dose of octreotide for patients with variceal bleeding is a 50-μg intravenous bolus, followed by a 50-μg/hour infusion for 5 days.

Combining endoscopic and drug therapy improves the chances of stopping the bleeding and reduces the risk of recurrent bleeding compared with endoscopic therapy alone.56

Transjugular intrahepatic portosystemic shunting is indicated in recurrent variceal hemorrhage or in those with initial bleeding that is refractory to standard medical and endoscopic therapy. It is not the primary therapy because it doubles the risk of encephalopathy and has a high stent occlusion rate (up to 60%, lower with covered stents).

 

 

GI BLEEDING CAN CAUSE ACUTE MYOCARDIAL INFARCTION

The simultaneous presentation of acute myocardial infarction (MI) and GI hemorrhage is very serious and unfortunately common.

An acute MI occurring simultaneously with or after GI bleeding is usually precipitated by massive bleeding causing hypovolemia, hemodynamic compromise, and hypoperfusion. Conversely, the anticoagulant, antiplatelet, or thrombolytic drugs given to treat MI can precipitate GI bleeding (see below).

This distinction is important because the two scenarios have different clinical courses and prognoses. GI bleeding that precipitates an acute MI tends to be massive, whereas GI bleeding after treatment of acute MI tends to be self-limited and often resolves with reversal of underlying coagulopathy.57

Endoscopy carries a higher than average risk in patients with recent acute MI, with all-cause mortality rates as high as 1%.58 (The usual rate is 0.0004%.59) Nevertheless, endoscopy can be safely performed early on in patients with acute MI if it is done under strict monitoring in a coronary care unit.

Several studies have shown that MI patients who present with upper GI bleeding as the inciting event or patients with acute MI who are vomiting blood or who are hemodynamically unstable due to GI bleeding are significantly more likely to have a high-risk lesion and so have the greatest need for endoscopic therapy. Therefore, endoscopic intervention may be offered to MI patients at high risk who have been started on antiplatelet agents.

WARFARIN CAN PRECIPITATE BLEEDING

Acute upper GI bleeding can be a severe complication of long-term oral anticoagulation, not because the drugs cause ulcers, but rather because they exacerbate ulcers that are already present.60 Therefore, when starting warfarin (Coumadin), patients should be evaluated to determine if they have other risk factors for GI bleeding, such as ulcers.

The number of people presenting with upper GI bleeding while on warfarin therapy is increasing because of the expanding indications for long-term anticoagulation therapy, such as atrial fibrillation and deep venous thrombosis.

The risk of GI bleeding in patients who use oral anticoagulants is estimated to be 2.3 to 4.9 times higher than in nonusers.61

The goal international normalized ratio (INR) for patients on warfarin therapy is usually 2.0 to 3.0. Recent studies found that endoscopy can be safely performed in patients with acute GI bleeding whose INR is between 2.0 and 3.0.62,63 Some suggest that both the length of warfarin therapy and the INR affect the risk of bleeding.64,65

Managing patients with an INR higher than 3.0 who have an episode of GI bleeding is always a challenge. It is not uncommon to find pathologic lesions causing GI bleeding in patients who are on warfarin with a supratherapeutic INR, and thus, endoscopy is indicated. However, before endoscopy, reversal of anticoagulation should be considered.

BLEEDING IN PATIENTS ON ANTIPLATELET DRUGS

Aspirin

Aspirin decreases production of prostaglandins in the GI tract, thereby decreasing the protective and restorative properties of the gastric and duodenal mucosa and predisposing to ulcers and bleeding.

The higher the aspirin dose, the higher the risk. Aspirin doubles the risk of upper GI bleeding at daily doses of 75 mg and quadruples it at doses of 300 mg.66 Even doses as low as 10 mg can decrease gastric mucosal prostaglandin production.67 Thus, it appears that there is no risk-free dose of aspirin, and enteric-coated or buffered formulations do not appear to reduce the risk.68–70

The most important risk factor for upper GI bleeding in patients taking aspirin is a history of peptic ulcer bleeding. Approximately 15% of aspirin users who have bleeding from ulcers have recurrent bleeding within 1 year.71

As aspirin-induced GI bleeding becomes more common, health care providers often feel caught between the GI risk and the cardiovascular benefit. When considering whether to discontinue antiplatelet therapy, a cardiologist should be consulted along with a gastroenterologist to weigh the risks of GI bleeding vs thrombosis. To date, there have been no clinical trials published to suggest when antiplatelet therapy should be stopped to optimize GI and cardiovascular outcomes. An alternative is to replace aspirin with another antiplatelet drug that does not induce ulcers.

Clopidogrel

Clopidogrel (Plavix) is recommended for hospitalized patients with acute coronary syndrome who cannot tolerate the GI side effects of aspirin, according to the joint guidelines of the American College of Cardiology and the American Heart Association, with the highest level of evidence.72 This recommendation was largely based on the safety data from the CAPRIE (Clopidogrel Versus Aspirin in Patients at Risk of Ischemic Events) trial, in which the incidence of major GI bleeding was lower in the clopidogrel group (0.52%) than in the aspirin group (0.72%; P < .05).73

Aspirin plus a proton pump inhibitor

Patients who have had an episode of upper GI bleeding and who need long-term aspirin therapy should also receive a proton pump inhibitor indefinitely to prevent ulcer recurrence.

In a recent double-blind randomized controlled trial in patients with a history of aspirin-induced bleeding, the combination of low-dose aspirin plus esomeprazole (Nexium) twice a day was superior to clopidogrel by itself in terms of the rate of recurrent bleeding (0.7% vs 8.6%; P < .05).74 A similar trial showed nearly identical results: 0% upper GI bleeding in the group receiving aspirin plus esomeprazole 20 mg daily, vs 13.6% in the clopidogrel group (P = .0019).75 These studies suggest that a once-daily proton pump inhibitor combined with aspirin is a safer alternative than clopidogrel alone.

Clopidogrel plus a proton pump inhibitor

Interestingly, recent studies have shown that omeprazole decreases the antiplatelet effect of clopidogrel, possibly by inhibiting the CYP2C19 enzyme.76 However, concomitant use of pantoprazole (Protonix), lansoprazole (Prevacid), and esomeprazole did not have this effect, suggesting that although all proton pump inhibitors are metabolized to a varying degree by CYP2C19, the interaction between proton pump inhibitors and clopidogrel is not a class effect.77–79 Therefore, pantoprazole, lansoprazole, and esomeprazole may be the appropriate proton pump inhibitors to use with clopidogrel in patients who have a clear indication for the medication, consistent with current guideline recommendations.

Helicobacter pylori infection in antiplatelet drug users

Before starting any long-term antiplatelet therapy, patients with a history of ulcers should be tested and treated for H pylori (Table 4).80 Confirmation of eradication is required after H pylori treatment in patients with upper GI bleeding. Some suggest that for patients with a history of bleeding ulcer who need aspirin, eradication of H pylori substantially reduces the risk of recurrent ulcer bleeding.81

 

 

TREATMENT AND PREVENTION OF NSAID-RELATED GI INJURY

About 1 in 20 users of NSAIDs develop GI complications and ulcers of varying degrees of severity, as do one in seven NSAID users over the age of 65. In fact, NSAID use accounts for 30% of hospitalizations for upper GI bleeding and deaths from this cause.82–85 In addition, approximately 15% to 30% of NSAID users have clinically silent but endoscopically evident peptic ulcers.86

NSAIDs contribute to ulcer development by depleting prostaglandins. Thus, misoprostol (Cytotec), a synthetic prostaglandin, has been used to reduce this side effect.

In a clinical trial, misoprostol reduced the incidence of NSAID-associated GI complications by 40%.87 Furthermore, it has been shown to be better than placebo in preventing recurrent gastric ulcers in patients with a history of gastric ulcer who were receiving low-dose aspirin.88

However, misoprostol is rarely used because it can cause diarrhea and abdominal cramping. Rather, the preferred drugs for preventing and treating NSAID- and aspirin-related GI lesions are proton pump inhibitors.

Numerous clinical trials using endoscopic end points showed that proton pump inhibitors in standard doses significantly reduce the incidence of ulcers associated with the use of NSAIDs.89 Proton pump inhibitor therapy has achieved a significant reduction in relative risk of upper GI bleeding in patients who received low-dose aspirin therapy, as confirmed by epidemiologic studies.90,91 The number of NSAID-related ulcers found on endoscopy could be reduced by an estimated 90% simply by using proton pump inhibitors.92

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  78. Small DS, Farid NA, Payne CD, et al. Effects of proton pump inhibitor lansoprazole on the pharmacokinetics and pharmacodynamics of prasugel and clopidogrel. J Clin Pharmacol 2008; 48:475484.
  79. Ishizaki T, Horai Y. Review article: cytochrome P450 and the metabolism of proton pump inhibitors—emphasis on rabeprazole. Aliment Pharacol Ther 1999; 13 (suppl 3):2736.
  80. Lanas A, Fuentes J, Benito R, Serrano P, Bajador E, Sainz R. Helicobacter pylori increases the risk of upper gastrointestinal bleeding in patients taking low-dose aspirin. Aliment Pharmacol Ther 2002; 16:779786.
  81. Chan FK. NSAID-Induced peptic ulcers and Helicobacter pylori infection: implications for patient management. Drug Saf 2005; 28:287300.
  82. Bombardier V, Laine L, Reicin A, et al; VIGOR Study Group. Comparison of upper gastrointestinal toxicity of rofecoxib and naproxen in patients with rheumatoid arthritis: VIGOR Study Group. N Eng J Med 2000; 343:15201528.
  83. Griffin MR, Ray WA, Schaffner W. Nonsteroidal anti-inflammatory drug use and death from peptic ulcer in elderly persons. Ann Intern Med 1988; 109:359363.
  84. Griffin MR, Piper JM, Daugherty JR, Snowden M, Ray WA. Nonsteroidal anti-inflammatory drug use and increased risk for peptic ulcer disease in elderly persons. Ann Intern Med 1991; 114:257263.
  85. Smalley WE, Ray WA, Daugherty JR, Griffin MR. Nonsteroidal anti-inflammatory drugs and the incidence of hospitalizations for peptic ulcer disease in elderly persons. Am J Epidemiol 1995; 141:539545.
  86. Laine L. Approaches to nonsteroidal anti-inflammatory drug use in the high-risk patient. Gastroenterology 2001; 120:594606.
  87. Silverstein FE, Graham DY, Senior JR, et al. Misoprostol reduces serious gastrointestinal complications in patients with rheumatoid arthritis receiving nonsteroidal anti-inflammatory drugs. A randomized, double blind, placebo controlled trial. Ann Intern Med 1995; 123:241249.
  88. Goldstein JL, Huang B, Amer F, Christopoulos NG. Ulcer recurrence in high-risk patients receiving nonsteroidal anti-inflammatory drugs plus low dose aspirin: results of a post hoc subanalysis. Clin Ther 2004; 26:16371643.
  89. Berger JS, Stebbins A, Granger CB, et al. Initial aspirin dose and outcome among ST-elevation myocardial infarction patients treated with fibrinolytic therapy. Circulation 2008; 117:192199.
  90. Lanas A, Garcia-Rodriguez LA, Arroyo MT, et al; Investigators of the Asociación Española de Gastroenterología (AEG). Effect of antisecretory drugs and nitrates on the risk of ulcer bleeding associated with nonsteroidal anti-inflammatory drugs, antiplatelet agents, and anticoagulants. Am J Gastroenterol 2007; 102:507515.
  91. Chin MW, Yong G, Bulsara MK, Rankin J, Forbes GM. Predictive and protective factors associated with upper gastrointestinal bleeding after percutaneous coronary intervention: a case-control study. Am J Gastroenterol 2007; 102:24112416.
  92. Hunt RH, Bazzoli F. Should NSAID/low dose aspirin takers be tested routinely for H. Pylori infection and treated if positive? Implications for primary risk of ulcer and ulcer relapse after initial healing. Aliment Pharmacol Ther 2004; 19 (suppl 1):916.
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  82. Bombardier V, Laine L, Reicin A, et al; VIGOR Study Group. Comparison of upper gastrointestinal toxicity of rofecoxib and naproxen in patients with rheumatoid arthritis: VIGOR Study Group. N Eng J Med 2000; 343:15201528.
  83. Griffin MR, Ray WA, Schaffner W. Nonsteroidal anti-inflammatory drug use and death from peptic ulcer in elderly persons. Ann Intern Med 1988; 109:359363.
  84. Griffin MR, Piper JM, Daugherty JR, Snowden M, Ray WA. Nonsteroidal anti-inflammatory drug use and increased risk for peptic ulcer disease in elderly persons. Ann Intern Med 1991; 114:257263.
  85. Smalley WE, Ray WA, Daugherty JR, Griffin MR. Nonsteroidal anti-inflammatory drugs and the incidence of hospitalizations for peptic ulcer disease in elderly persons. Am J Epidemiol 1995; 141:539545.
  86. Laine L. Approaches to nonsteroidal anti-inflammatory drug use in the high-risk patient. Gastroenterology 2001; 120:594606.
  87. Silverstein FE, Graham DY, Senior JR, et al. Misoprostol reduces serious gastrointestinal complications in patients with rheumatoid arthritis receiving nonsteroidal anti-inflammatory drugs. A randomized, double blind, placebo controlled trial. Ann Intern Med 1995; 123:241249.
  88. Goldstein JL, Huang B, Amer F, Christopoulos NG. Ulcer recurrence in high-risk patients receiving nonsteroidal anti-inflammatory drugs plus low dose aspirin: results of a post hoc subanalysis. Clin Ther 2004; 26:16371643.
  89. Berger JS, Stebbins A, Granger CB, et al. Initial aspirin dose and outcome among ST-elevation myocardial infarction patients treated with fibrinolytic therapy. Circulation 2008; 117:192199.
  90. Lanas A, Garcia-Rodriguez LA, Arroyo MT, et al; Investigators of the Asociación Española de Gastroenterología (AEG). Effect of antisecretory drugs and nitrates on the risk of ulcer bleeding associated with nonsteroidal anti-inflammatory drugs, antiplatelet agents, and anticoagulants. Am J Gastroenterol 2007; 102:507515.
  91. Chin MW, Yong G, Bulsara MK, Rankin J, Forbes GM. Predictive and protective factors associated with upper gastrointestinal bleeding after percutaneous coronary intervention: a case-control study. Am J Gastroenterol 2007; 102:24112416.
  92. Hunt RH, Bazzoli F. Should NSAID/low dose aspirin takers be tested routinely for H. Pylori infection and treated if positive? Implications for primary risk of ulcer and ulcer relapse after initial healing. Aliment Pharmacol Ther 2004; 19 (suppl 1):916.
Issue
Cleveland Clinic Journal of Medicine - 77(2)
Issue
Cleveland Clinic Journal of Medicine - 77(2)
Page Number
131-142
Page Number
131-142
Publications
Cleveland Clinic Journal of Medicine
Publications
Cleveland Clinic Journal of Medicine
Topics
Gastroenterology
Emergency Medicine
Drug Therapy
Article Type
Article
Display Headline
Managing acute upper GI bleeding, preventing recurrences
Display Headline
Managing acute upper GI bleeding, preventing recurrences
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Inside the Article

KEY POINTS

  • The first priority is to ensure that the patient is hemodynamically stable, which often requires admission to the intensive care unit for monitoring and fluid resuscitation.
  • Peptic ulcers account for most cases of upper GI bleeding, but bleeding from varices has a much higher case-fatality rate and always demands aggressive treatment.
  • Patients with ulcer disease should be tested and treated for Helicobacter pylori infection.
  • Patients with a history of bleeding ulcers who need long-term treatment with aspirin or a nonsteroidal anti-inflammatory drug should also be prescribed a proton pump inhibitor.
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