Evaluation of Hepatobiliary Disorders PDF

Summary

This document provides a clinical overview of hepatobiliary disorders, focusing on diagnosis, history, clinical presentation, and potential causes. It covers diseases like hepatic necrosis and drug-induced hepatopathy, and includes discussion of GIT signs, abdominal pain, polyuria and polydipsia, abdominal effusion, and hepatic encephalopathy.

Full Transcript

Evaluation o f Hepatobiliary Disorders
 Diagnosis????
History
✓Vaccination will decrease risk for viral affections.
✓Administration of some drug can affect liver for
example glucocorticoids, mebendazole, paracetamol,
and anticonvulsant.
✓Onset of signs correlated with disease process as in
hepatic disease, acute signs seen in hepatic necrosis
and drug induced hepatopathy, infection.
Clinical
presentation and
physical findings

Individual animals will show
some but not all of these signs,
and many animals with
hepatobiliary disease will show
no clinical signs at all.
 GIT signs
Vomiting, diarrhea, and anorexia are common clinical signs associated with liver
disease. Vomiting in dogs and cats with liver disease can be as a result of local
inflammation, portal hypertension, or HE. Animals with portal hypertension may have
hematemesis and melena as a result of upper GI ulceration.
 ABDOMINAL PAIN

Some forms of liver disease also cause abdominal pain; the liver parenchyma is poorly supplied
with pain fibers, but the liver capsule and biliary tract are well innervated. Biliary tract disease
is particularly painful in dogs and cats; gallstones in cats, gallbladder mucoceles in dogs, and
extrahepatic biliary obstruction in both species are particularly painful.

Dogs and cats with hepatomegaly of any cause often show pain on cranial abdominal palpation,
presumably due to stretching of the liver capsule.
 POLYURIA AND POLYDIPSIA

The underlying mechanisms are poorly understood, but several factors are suspected to
contribute to polydipsia (PD) and polyuria (PU), which are seen primarily in dogs and rarely in
cats. Altered sense of thirst may be a manifestation of HE.

Changes in the function of portal vein osmoreceptors that stimulate renal water loss early after
drinking, before a change in systemic osmolality, may also be partly responsible for PU in
patients with liver disease, although studies have been published only for rodents and humans.
Loss of the renal medullary-concentrating gradient for urea because of the inability to produce
urea from ammonia may also be involved and would first cause PU and then compensatory PD.
 ABDOMINAL EFFUSION

It is much more common in dogs than in cats with liver disease. With
the exception of liver disease associated with feline infectious
peritonitis (FIP) or congenital ductal plate abnormalities, cats with
liver disease rarely have ascites.
A small amount of effusion is suspected when abdominal palpation
yields a slippery sensation during physical examination.
the general pathogeneses of third-space fluid accumulation (excessive
formation by increased venous hydrostatic pressure, decreased
intravascular oncotic pressure, or altered vascular permeability and
insufficient resorption), singly or in combination, apply to cats and
dogs with hepatobiliary diseases.
 In parenchymal liver disease, the commonest cause of ascites formation is portal
hypertension, which is a sustained increase in pressure in the portal system, with or without a
contribution from reduced serum albumin concentration.
A low protein transudate is occasionally seen in animals with liver disease and concurrent
hypoalbuminemia.
The pathogenesis of the development of ascites in portal hypertension is complex and has
really been studied only in humans; it is assumed that the mechanisms of ascites are similar
in dogs.
Sodium retention by the kidneys is an important mechanism in the development of ascites in
liver disease. Portal hypertension results in congestion of splanchnic vessels with pooling of
blood in the splanchnic circulation. This results in a drop in systemic circulating blood
volume and thus blood pressure that leads to increased renal sodium retention, partly as a
result of reduced glomerular filtration rate and decreased sodium delivery to the tubules and
partly as a result of increased release of renin-angiotensin-aldosterone (RAAS) that results in
increased sodium retention in the distal tubules.
This leads to an increase in circulating fluid volume, which precipitates the formation of ascites,
which in turn reduces venous return because of increased pressure on the caudal vena cava and
initiates a vicious cycle of renal sodium retention and ascites.

This is the “over-fill” theory of ascites formation in liver disease. Therefore, aldosterone
antagonists (e.g., spironolactone) are usually most effective in dogs with ascites secondary to
portal hypertension, whereas loop diuretics, such as furosemide used alone, can be ineffective or
even, in some cases, actually increase the volume of effusion by causing a further decrease in
systemic blood pressure as a result of hemoconcentration and secondary increases in RAAS
activation.
 HEPATIC ENCEPHALOPATHY

HE describes neurologic dysfunction in patients with liver disease as a result of exposure of the
cerebral cortex to toxins.
In dogs with cirrhosis and acquired PSS secondary to portal hypertension, in dogs and cats with
acute liver failure, and in cats with hepatic lipidosis (which is in effect a reversible acute liver
failure).
The most important toxin implicated is ammonia (NH3), which crosses the blood-brain barrier.
Buildup of NH3 in the systemic circulation occurs as a result of diversion of portal flow from
the liver by the development of PSS or as a result of a marked reduction in functional hepatic
mass. In most cases of acquired portosystemic shunting, there is a combination of vascular and
functional mechanisms leading to HE.
The sources of increased blood ammonia levels in
animals with liver disease include the following:
Small intestinal enterocyte catabolism of glutamine
as their main energy source
Endogenous hepatic protein metabolism from excess
dietary protein, GI bleeding, or breakdown of lean
body mass
Bacterial breakdown of undigested amino acids and
purines that reach the colon
Bacterial and intestinal urease action on urea, which
freely diffuses into the colon from the blood.
In many cases it is the precipitating factors (rather than
the diet) that are most important in triggering HE.
 Typical Clinical Signs of Hepatic Encephalopathy in Dogs and Cats

Hepatic encephalopathy (HE) may wax and wane, though
certain elements could exacerbate signs as high-protein
diet, Sedatives or anesthetics, Azotemia, hypokalemia,
constipation, GI hemorrhage and metabolic alkalosis.
 CHANGE IN LIVER SIZE

In normal cats and dogs, the liver is palpable just caudal to the costal arch along the ventral
body wall, but it may not be palpable at all..
 JAUNDICE, BILIRUBINURIA, AND CHANGE IN FECAL COLOR

✓ Jaundice in cats and dogs is the yellow staining of serum or tissues by an
excessive amount of bile pigment or bilirubin.
✓ Jaundice may be prehepatic, due to very marked red cell breakdown;
hepatic, due to primary liver disease; or posthepatic, due to biliary tract
obstruction or rupture. Because the normal liver has the ability to take up
and excrete a large amount of bilirubin, there must be either a large,
persistent increase in the production of bile pigment (hyperbilirubinemia)
or a major impairment in bile excretion (cholestasis with
hyperbilirubinemia) before jaundice is detectable as yellow-stained
tissues (serum bilirubin concentration ≥2 mg/dL) or serum (serum
bilirubin concentration ≥1.5 mg/dL).
Jaundice
Acholic stool: result from the total absence of bile pigment in the
intestine (Fig. 33.10). Only a small amount of bile pigment is needed
to be changed to stercobilin and yield a normal fecal color; therefore,
bile flow into the intestine must be completely discontinued to result
in acholic feces.
Bilirubinuria
Canine renal tubules have a low resorptive threshold for bilirubin
bilirubinuria (up to 2+ to 3+ reaction by dipstick analysis) may be a
normal finding in canine urine specimens. Cats do not have this
ability, and they have a ninefold higher tubular absorptive capacity for
bilirubin than dogs. Bilirubinuria in cats is associated with
hyperbilirubinemia and is always pathologic.
 Coagulopathies

Liver plays important role in hemostasis. The inability to form Vitamin K-dependent factors (II, VII, IX, X) as a
result of absence of bile-acid-dependant fat absorption consequent to extrahepatic bile duct obstruction (EBDO) can
cause bleeding.

Severe liver diseases cause change in coagulation factors activities. DIC can play a role. Dogs with hepatic
necrosis (acute) characterized by thrombocytopenia caused by increase usage or sequestration.

Portal hypertension elicits vascular congestion and fragility causing hemorrhage especially in GIT. Though
mechanism of GIT hemorrhage is poorly understood, it was presumed to be correlated with poor mucosal perfusion and
reduction of epithelial turnover caused by portal hypertension and splanchnic blood pooling.
 Diagnostic Tests for the Hepatobiliary System

❑ A battery of tests must be used to assess the hepatobiliary system. A reasonable package of
screening tests recommended for an animal suspected of having hepatobiliary disease
includes a complete blood count (CBC), serum biochemical profile, urinalysis, fecal
analysis, and survey abdominal radiography or ultrasonography (US).
❑ Results of these tests may suggest evidence of hepatobiliary disease that can be confirmed by
other, more specific tests, which would usually be some form of tissue sample. It is
important at this stage to rule out secondary hepatopathy as much as possible because, with
hepatopathies secondary to other diseases, time and resources should be devoted as soon as
possible to identify and treat the underlying cause rather than investigate the liver.
 Serum
biochemistry
COMPLETE BLOOD COUNT
There are few changes in blood cells that suggest hepatobiliary disease:
Microcytosis (mean corpuscular volume [MCV] < 60 fL in canine breeds other than the Japanese
Akita or Shiba Inu), with normochromasia or slight hypochromasia (mean cell hemoglobin
concentration, 32-34 g/dL), is a common finding in dogs with congenital PSS.
A marked microcytic anemia greatly increases the index of suspicion for chronic GI blood loss.
Strongly regenerative anemia, with macrocytosis, high reticulocyte count, and normal to slightly
increased serum protein concentration in a jaundiced dog, especially if spherocytes are also identified,
indicates hemolytic anemia.

COAGULATION TESTS
ABDOMINOCENTESIS—FLUID ANALYSIS—IN LIVER AND PANCREAS DISEASE
Characteristics of Abdominal Effusion in Hepatobiliary Disease
 DIAGNOSTIC IMAGING

SURVEY RADIOGRAPHY: Survey radiographs provide
subjective information regarding the size and shape of the liver.

Lateral abdominal radiographs demonstrating gastric axis (white line) as
an indication of liver size. (A) Lateral abdominal radiograph of a normal
cat with normal liver size. (B) Lateral abdominal radiograph of a cat with
diffuse hepatic amyloidosis demonstrating hepatomegaly and caudal
displacement of the gastric axis. (C) Lateral abdominal radiograph of a
middle-aged English Springer Spaniel with cirrhosis demonstrating
microhepatica and cranial displacement of the gastric axis.
 ULTRASONOGRAPHY
Abdominal US is the preferred diagnostic modality for evaluating the hepatobiliary system in dogs and
cats

Subcostal approach with a dog or a cat in dorsal
recumbency:
liver (L); The gallbladder (GB), located to the
right of the midline, is a useful landmark;
Branching portal veins (PV) with hyperechoic
boundaries.
The normal hepatic parenchyma is uniformly
hypoechoic, with a coarser echotexture, when
compared with the spleen. Its echogenicity
relative to the renal cortices is more variable,
although usually hyperechoic to isoechoic
Liver, spleen, and kidney relative echogenicities and echotextures. A: Sagittal image
obtained in the left cranial abdomen of a normal dog. The liver (L) is in contact with the
spleen (S), and is relatively hypoechoic and more granular in echotexture. B: Sagittal
image obtained in the right cranial abdomen of a normal dog. The liver (L) appears
relatively isoechoic to the cortex of the right kidney (RK). Acoustic shadowing (arrow) is
caused by one of the last ribs.
B: Leptospirosis. Ultrasonographic
image of a portion of the liver in a dog
with acute leptospirosis. The liver is
diffusely hypoechoic, and its portal
walls are prominent, appearing as
double lines and “donuts” throughout
the parenchyma. These findings are
common in dogs with leptospirosis
C: Chronic suppurative hepatitis. In this
6-year-old Labrador, the liver (L) is
heterogeneously hyperechoic. St,
stomach.

Liver biopsy is usually needed to
establish definitive diagnosis. It could be
performed blind percutaneous method
(without ultrasound guidance),
ultrasound guided or during laparoscopy.
The acronym DAMNIT includes a large number of broad etiological categories and is useful for
the generation of an initial list of potential diagnoses that can then be used in making diagnostic
plans.
Not all etiological categories will apply to all problems. Potential etiologies for hepatomegaly
using this system include:
Degenerative/Developmental – No relevant diagnoses
Anomalous/Autoimmune
– Cysts (may be associated with polycystic kidney disease)
Metabolic/Mechanical
– Vacuolar hepatopathiesm – Glycogen accumulation (i.e., steroid hepatopathy, diabetes mellitus)
– Fat accumulation – Venous congestion (mechanical), (i.e., right-sided heart failure)
– Nodular hyperplasia
Neoplastic/Nutritional
– Primary neoplasia – Hepatocellular carcinoma – Hemangiosarcoma – Biliary carcinoma
– Secondary/Systemic neoplasia – Lymphosarcoma – Mast cell tumor – Metastasis (i.e., Hemangiosarcoma)
Infectious/Idiopathic/Inflammatory/Ischemic/Iatrogenic
– Parasitic cysts (i.e., Echinococcus) – Liver lobe torsion (Ischemic, congestion) – Granulomas
Toxic/Traumatic
– Hematoma