Chapter 46: Canine Biliary Mucocele

Web Chapter 46


Canine Biliary Mucocele



Biliary mucoceles (cystic mucinous hyperplasia, mucinous cholecystitis) rarely were reported in dogs before 1990 but have become one of the most common causes of extrahepatic biliary disease in canine patients. Their distinct characteristics—grossly, histologically, and ultrasonographically—make it unlikely that mucoceles previously were misdiagnosed or missed altogether. Increased disease prevalence in combination with advances in routine diagnostic ultrasound examinations are the likely cause of the increased frequency of diagnosis of biliary mucoceles in dogs.



Pathogenesis


A biliary mucocele is an accumulation of the mucus component of bile within the gallbladder (GB). Grossly it appears as shiny green-black gelatinous material with lamellar striations along fracture lines (Web Figure 46-1). Functional or structural obstruction of the cystic or common bile duct is the usual cause in humans and was proposed initially as a cause in the dog. However, studies do not support this theory. Primary obstruction of the cystic or common bile ducts rarely is found on diagnostic tests or at the time of surgery, and histologically there is typically evidence of hyperplasia of the mucus-secreting glands of the GB mucosa. Current causative theories are multifactorial. Impaired gallbladder motility and cholesterol and lipid metabolism appear to be primary factors in disease development. Delayed GB motility allows the accumulation of concentrated bile salts, which stimulate mucus production from the endothelial lining. Diabetes mellitus, hypothyroidism, and exogenous steroid administration (androgenic and corticosteroids) have been associated with delayed GB emptying. A correlation between cholesterol and mucin content of bile also has been established, indicating that hypercholesterolemia and poor lipid metabolism could be contributors. One study has shown that dogs with hyperadrenocorticism are 29 times more likely to develop a biliary mucocele than dogs without hyperadrenocorticism, and a trend for association with hypothyroidism also was suggested (Mesich et al, 2009). A predisposition for endocrinopathies and abnormalities in lipid metabolism may explain the breed predisposition associated with biliary mucoceles (Shetland sheepdogs, cocker spaniels, miniature schnauzers, and dachshunds). More recently researchers have found an association of a mutation in ABCB4 transporter gene in Shetland sheepdogs and other dogs having biliary mucoceles (Mealey et al, 2010). This gene functions in transporting phosphatidylcholine across the canalicular membrane. Abnormal bile composition changes may be in part responsible for damage to the biliary endothelial lining and subsequent gallbladder mucinous hyperplasia.



The mucocele develops because of the progressive accumulation of tenacious, mucin-laden bile in the GB, which may extend into the cystic duct, common bile duct, and even into the hepatic ducts as the disease progresses. The accumulation leads to ischemic necrosis of the GB, opportunistic bacterial infection, and potentially bile peritonitis.



Diagnostics


As with any disease or disease process, the diagnosis of a biliary mucocele is achieved by assimilating data from the presentation and owner history, physical examination, laboratory data, imaging studies, and histopathology.


Patients typically present as middle-aged to older, small- to medium-breed dogs. A breed predisposition for Shetland sheepdogs and an overrepresentation of dachshunds, miniature schnauzers, and cocker spaniels have been reported (Aguirre et al, 2007). No sex predilection is evident.


Most dogs with clinical evidence of a GB mucocele have a history of subacute-to-acute onset of nonspecific clinical signs. Signs of systemic illness typically include vomiting, inappetence or anorexia, lethargy, diarrhea, polydipsia and polyuria, and vague signs of discomfort. Any combination of these symptoms may be present, or the mucocele may be found as an incidental finding with no clinical symptoms of systemic disease. Physical examination findings are also vague and may include abdominal pain, icterus, tachypnea, tachycardia, dehydration, pendulous abdomen or fluid wave, and fever. Patients also may present with no abnormal examination findings. Because historical and physical examination findings are vague and general, many animals are presumed to be suffering from other disease processes such as pancreatitis, necessitating careful examination and review of all available information to achieve an accurate and timely diagnosis.


The most common laboratory abnormalities include increases in serum liver enzyme activity (alkaline phosphatase, alanine aminotransferase, alanine aspartate aminotransferase, γ-glutamyltransferase, increased total bilirubin) and elevated white blood cell counts. Abdominal radiographs have limited usefulness in the diagnosis of a biliary mucocele but may be critical in ruling out other causes of the historical or physical findings such as gastrointestinal obstruction, abdominal mass, or other causes of vomiting and lethargy. Although uncommon, choleliths may be visible on abdominal radiographs, and these occasionally may lead to biliary tract obstruction. Abdominal ultrasound is the preferred diagnostic test for GB mucoceles, which have distinct characteristics on ultrasonographic images. The tenacious mucin along the GB wall is visualized as a hypoechoic rim. The central contents are hyperechoic and non–gravity dependent with ballottement or repositioning of the patient. Radiating striations extend from the GB wall centrally as the mucocele matures, creating the described “kiwi fruit” appearance specific to mucoceles (Web Figure 46-2). Ultrasound-guided cholecystocentesis is contraindicated for biliary mucoceles. Ultrasonography also may detect varying degrees of extrahepatic biliary obstruction caused by extension of the mucinous bile into the cystic, common, and hepatic ducts. Although the ultrasound examination can be sensitive for the diagnosis of biliary mucoceles, it does not always correspond as favorably to the severity of disease assessed at surgery, in particular the presence of pressure necrosis of the GB wall or cystic duct that can lead to eventual rupture. Evidence of necrosis or rupture include hyperechoic fat and/or a hypoechoic halo of fluid surrounding the GB.


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Jul 18, 2016 | Posted by in PHARMACOLOGY, TOXICOLOGY & THERAPEUTICS | Comments Off on Chapter 46: Canine Biliary Mucocele

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