Difference between revisions of "Hepatic Encephalopathy"

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Also known as: '''''Portosystemic encephalopathy — Hepatic coma
  
 +
See also: '''[[Hepatic Encephalopathy - Horse|Hepatic Encephalopathy in Horses]]'''
  
 +
==Introduction==
 +
'''Hepatic encephalopathy''' (HE) is characterised by a complex of neurological abnormalities that occur due to congenital or acquired abnormalities in hepatic structure or function.  HE is usually associated with some form of [[Portosystemic Shunt|'''portosystemic shunt''']] (PSS) in dogs and cats, although it may also be caused by a marked reduction in functional hepatic mass.  Other causes of HE, such as [[Hepatic Microvascular Dysplasia|'''microvascular dysplasia''']], '''congenital defects of enzymes of the urea cycle''', '''arginine deficiency''' or '''organic acidaemias''', are very rare or of only experimental interest.  The clinical signs of HE are associated with increases in the blood concentration of several metabolites:
 +
*'''Ammonia''' is a by-product of protein degradation which is transported in the portal vein and metabolised to urea in the liver via the urea cycle.  In animals with PSS, ammonia is not removed from the portal blood as this bypasses the liver, leading to an increase in its blood concentration.  For ammonia generation in normal animals see [[Ammonia|ammonia]].
 +
*'''Mercaptans''' are products of the bacterial degradation of the amino acid methionine in the colon which are usually removed from the portal blood in the liver.
 +
*'''Aromatic amino acids''' may be involved especially when the ratio of aromatic to branched chain amino acids is very high.  This is considered to be a significant component in the pathogenesis of HE in horses.
 +
*'''GABA''' (gamma amino butyric acid) is an endogenous neurotransmitter which is produced from ammonia. 
 +
*'''Short-chain fatty acids''' (such as butyrate and propionate) make a questionable contribution to HE.
 +
*'''Endogenous benzodiazepine receptor ligands''' are also of questionable importance.
  
 +
HE represents a reversible alteration in cerebral metabolism whose pathogenesis is not yet fully understood.  An increased blood concentration of '''ammonia''' is the most commonly cited cause of HE and it is known that this metabolite is able to cross the blood brain barrier and exert a directly toxic effect on neurones of the central nervous system (CNS).  Since the cells of the CNS are not able to express the constituent enzymes of the urea cycle, they convert ammonia into '''glutamine''' rather than urea.  Glutamine is a potent neurotransmitter in the CNS and its levels correlate with the clinical signs observed in HE.  Increased concentrations of ammonia in the cerebro-spinal fluid are reported to have additional effects on cerebral metabolism, including reducing levels of the excitatory neurotransmitter serotonin and increasing the levels of NMDA (N-methyl-D-aspartate) and peripheral-type benzodiazepine receptors. 
  
{| cellpadding="10" cellspacing="0" border="1"
+
'''Aromatic amino acids''' (especially tryptophan and its metabolites) share an antiport transporter with ammonia in the blood brain barrier and dogs with congenital PSS are therefore reported to have increased levels of these amino acids in their CSF.  The neurotransmitter '''GABA''' is produced from ammonia and, as the blood ammonia concentration rises, so too do the levels of GABA in the CNS.  This transmitter imbalance is thought to increase the number of inhibitory GABA receptors present in the CNS. 
| Also known as:
 
| '''Portosystemic encephalopathy<br>
 
'''Hepatic coma'''
 
|-}
 
  
 +
HE may be precipitated by severel conditions in animals, all of which cause an increase in the blood concentrations of ammonia and/or mercaptans:
 +
*'''Metabolic alkalosis''' increases the production of ammonia by the kidneys and increases the uptake of urea across the blood brain barrier.
 +
*'''Hypokalaemia'''
 +
*'''Constipation''', increasing the length of time that colonic bacteria are able to act on undigested amino acids.
 +
*'''Gastro-intestinal haemorrhage''', increasing the amount of protein available to GI bacteria.
 +
*'''Diet with a high protein, purine or methionine content'''
 +
*'''Azotaemia''', increasing the concentration of urea in the GI tract and also causing GI haemorrhage if [[Uraemia|uraemia]] develops.
 +
*'''Hypermetabolic state or fever''', as may occur in many forms of systemic illness due to the effects of inflammatory cytokines and which leads to the catabolism of lean body protein.  A similar phenemenon may occur if glucocorticoids are administered at high doses.
 +
*'''Dehydration''' increases the effective circulating ammonia concentraton.
  
 
==Signalment==
 
==Signalment==
*Relatively common in dog, especially small breed dogs
+
HE occurs in those breeds that often develop congenital PSS, of which small breeds of dog are most at risk.  Most dogs with PSS present before the end of their first year of lifeMicrovascular dysplasia and congenital defects of the urea cycle are very rareAcquired PSS may occur in animals with '''[[Hepatitis, Chronic|chronic hepatitis]]''', to which Labrador retrievers, West Highland white terriers, English cocker spaniels and Dobermans are predisposed.
*Purebred dogs are more at risk
 
 
 
 
 
==Description==
 
'''Hepatic encephalopathy''' is characterised by a complex of neurological abnormalities that may occur in the presence of advanced liver diseaseBy far the most common cause in dog and cat is [[Portosystemic Shunt|portosystemic shunt]] (PSS), although a marked reduction in functional mass of hepatic tissue can also lead to hepatic encephalopathyIn rare cases, when severe acquired shunt due to hepatobiliary disease and congenital PSS have been ruled out, congenital urea enzyme cycle deficiencies and organic acidaemias, where there is lack of ability to degrade ammonia to urea, can be considered.
 
 
 
This is a reversible abnormality of the cerebral metabolismIts pathogenesis is not yet fully understood.  Increased concentration of ammonia level is the most common cause of this disease manifestation, due to its toxicity effect on brain cells.  Due to the lack of urea cycle in the brain, ammonia in [[Cerebral Spinal Fluid - Anatomy & Physiology|cerebrospinal fluid (CSF)]] is detoxified into glutamine.  Level of glutamine can be shown to correlate with clinical signs.  Aromatic amino acids, especially tryptophan and its metabolites, share an antiport transporter with ammonia in CSF.  Consequently, dogs with congenital PSS are reported to have increased aromatic amino acid concentrations in CSF.  Increased ammonia concentrations also have a number of other effects on the central nervous system, including a reduction in serotonin activity, an increased in NMDA (N-methyl-D-aspartic acid) and peripheral-type benzodiazepine receptors.
 
 
 
The sources responsible for an increase in ammonia levels include:
 
 
 
*the bacterial and intestinal breakdown of urea by urease, which then diffuse into the [[Colon - Anatomy & Physiology|colon]] from the blood.
 
*the bacterial breakdown of undigested amino acids in the [[Colon - Anatomy & Physiology|colon]].
 
*the catabolic metabolism of glutamine as an energy source by small intestinal enterocytes.
 
*endogenous hepatic protein metabolism by excess dietary protein intake, breakdown of lean body mass and gastrointestinal bleeding.
 
  
 
==Diagnosis==
 
==Diagnosis==
 
===Clinical Signs===
 
===Clinical Signs===
 
 
====Dog====
 
====Dog====
 
Typical signs include:
 
Typical signs include:
*anorexia, depression and lethargy
+
*'''Anorexia, depression''' and '''lethargy'''.
*aimless wandering, head pressing, circling and pacing
+
*'''Bizarre behaviour''', including aimless wandering, head pressing, circling, pacing, pica and compulsive eating and drinking.
*central blindness
+
*'''Central or amaurotic blindness''', where animals retain a menace response but will collide with objects when ambulatory.
*poor growth rate
+
*'''Comas''' and reactive '''seizures''' are uncommon.
*gastrointestinal signs such as [[Stomach and Abomasum Consequences of Gastric Disease - Pathology|vomiting]]
+
*'''Gastrointestinal signs''' may be observed, including [[Vomiting|vomiting]].
*coma (uncommon)
 
*seizures (uncommon)
 
 
 
Other signs include:
 
*temporary resolution of clinical signs with antimicrobial therapy
 
*prolonged recovery from sedation or anaesthesia
 
*polyuria and polydipsia in 33% of cases
 
  
 +
Other signs that occur in animals with congenital PSS or microvascular dysplasia include:
 +
*Temporary '''resolution of clinical signs with antimicrobial therapy''', due to a reduction in the number of colonic bacteria.
 +
*'''Prolonged recovery from sedation or anaesthesia''' because the metabolic capacity of the liver is reduced.
 +
*'''Polyuria and polydipsia''' in 33% of cases and other signs of urinary tract disease.
  
 
====Cat====
 
====Cat====
 
Typical signs include:
 
Typical signs include:
*well grown and in good body condition which in contrast to dogs
+
*'''Hypersalivation''' or ptyalism is the most commonly reported clinical feature but this is rarely reported in dogs.
*hypersalivation or ptyalism is the most commonly reported clinical feature, but rarely reported in dogs
+
*'''Seizures''' occur in 50% of cases but are uncommon in dogs.
*seizures, found in 50% of cases, but uncommon in dogs
+
*'''Compulsive behaviour''' is less common than in dogs.
*anorexia, vomiting and diarrhoea, polyuria and polydipsia are less common
 
*compulsive behaviour is less common compared to in dogs
 
 
 
  
 
===Laboratory Tests===
 
===Laboratory Tests===
====Biochemistry====
+
Although many parameters are likely to be altered in animals with HE, most of these changes result from the underlying disease.  '''Fasting hyperammonaemia''' provides an explanation for HE and should increase suspicion of congenital (or acquired) PSS.  An '''ammonia tolerance test''' can also be performed, in which ammonium chloride is administered by orogastric tube or by high colonic infusion.  Blood samples taken 30 minutes later should show an increased level of circulating ammonia.  Since this procedure may be dangerous to the animal, it may be preferable to perform a '''modified ammonia tolerance test''' by feeding a meal containing 25% of the animal's daily requirement and measuring blood ammonia concentration 6 hours later.
*Hypoproteinaemia
 
*Mild to moderate increase in alanine aminotransferase (ALT) and alkaline phosphatase (ALP)
 
*Decreased blood urea nitrogen (BUN)
 
*Hypoglycaemia in a small number of dogs
 
 
 
====Other Tests====
 
*Fasting hyperammonaemia
 
*Increased postprandial ± preprandial bile acids
 
 
 
  
 
===Diagnostic Imaging===
 
===Diagnostic Imaging===
====Radigraphy====
+
Imaging is not required to make a diagnosis of HE but it may reveal abnormalities relating to the underlying cause.
Abdominal radiography shows microhepatica and often renomegaly.  Renomegaly may relate to an altered splanchnic blood flow or to an increased metabolic activity of the kidney due to hyperammonaemia.  These findings in a young dog are highly suggestive of [[Portosystemic Shunt]].
 
 
 
Confirmation of a [[Portosystemic Shunt]] requires visualisation of the shunting blood vessel.  This may be done with either ultrasonography or contrast portography or at surgery.
 
  
 +
==Pathology==
 +
Myelin degeneration, consisting of vacuoles between the grey and white matter, may be observed on histopathological examination of cerebral tissues from affected animals.
  
 
==Treatment==
 
==Treatment==
===Surgical management===
+
The underlying cause of the HE should be treated, including surgical ligation of '''congenital''' PSS. In the meantime, the HE should be managed medically with a typical regime involving the following components:
*Surgical ligation of shunt is recommended in cases of [[Portosystemic Shunt]].
+
*'''Food should be withheld'''
 
+
*'''Intra-venous fluid therapy''', which can also be used to correct any hypokalaemia or metabolic alkalosis which may be precipitating the HE.
===Medical management===
+
*'''Enemas''' of warm water or lactulose to decrease the population of bacteria in the [[Colon - Anatomy & Physiology|colon]].
*Enemas to decrease the amount of bacteria in the [[Colon - Anatomy & Physiology|colon]].
+
*'''Antibiotics''' given orally or per rectum to reduce the number of colonic bacteria.  Suitable products include [[Penicillins|ampicillin]], [[Aminoglycosides|neomycin]] (which, although highly toxic when administered systemically, is also highly polar and therefore restricted to the GI tract) or [[Nitroimidazoles|metronidazole]].
*Oral antibiotics such as [[Penicillins|ampicillin]], [[Aminoglycosides|neomycin]] or [[Nitroimidazoles|metronidazole]] can be given initially reduce the amount of bacteria in intestines and hence decrease the production of ammonia.
+
*[[Lactulose|'''Lactulose''']] can be given orally or by enema.  It is a synthetic disaccharide which, when metabolised by the acidifying colonic bacteria, donates a hydrogen ion to ammonia to form ammonium ionsBecause these ions are charged, the are not absorbed freely and are rather trapped in the colon and excreted in faeces.  Lactulose also acts as an osmotic laxative, preventing constipation and reducing the time that colonic bacteria are able to act on undigested amino acids to form ammonia.  
*[[Drugs Acting on the Intestines#Osmotic Laxatives|Lactulose]] PO
+
*When the animal is to be fed, a '''diet with a high carbohydrate, low protein (2g/kg/day) and low fat''' content is recommended.  Both soluble and insoluble fibre may be beneficial in appropriate quantities as the former traps ammonia in the colon and the latter reduces intestinal transit time and prevents constipation.  In an animals with PSS or severe hepatic insufficiency, it may not be advisable to restrict protein too assiduously as these animals are likely to be [[Hypoalbuminaemia|hypoalbuminaemic]].
**This is a synthetic disaccharide which is metabolised by the acidifying colonic bacteria.  Ammonia is converted into ammonium ions, which cannot be absorbed and hence trapped in the colon and excreted in the faeces.  [[Drugs Acting on the Intestines#Osmotic Laxatives|Lactulose]] also acts as an osmotic laxative, allowing more faeces and bacteria to be washed out.
+
*'''Seizures''' should be treated with anticonvulsant medication but [[Benzodiazepines|benzodiazepines]] should be avoided as they may worsen the HE.
*A high carbohydrate, low protein (2g/kg/day) and low fat diet is recommended.
+
*Inclusion of L - Ornithine-l-aspartate enzymes, which accelerate the urea cycle and in turn facilitate conversion of ammonia to urea; may be helpful in acute episodes of HE. It may also be recommended to prevent HE in patients with severe hepatic functional compromise. It can, however, be safely used in patients with normal renal function.
**The aim is to provide adequate nutrients and energy to support hepatic tissue [[Liver Fibrosis|repair]], reduce the metabolic load on the liver and minimise the development of hepatic encephalopathy
 
 
 
  
 
==Prognosis==
 
==Prognosis==
In cases of PSS, the prognosis in dogs for resolution of clinical signs after total surgical ligation is excellent.  However, the response of cat to surgical intervention in cats is less promising than in dogs.
+
In cases of PSS, the prognosis in dogs for resolution of clinical signs after total surgical ligation is excellent.  However, the response to surgical intervention in cats is less promising than in dogs.
  
 +
{{Learning
 +
|literature search = [http://www.cabdirect.org/search.html?q=%28%28title%3A%28%22Portosystemic+encephalopathy%22%29%29%29+OR+%28%28title%3A%28%22Hepatic+coma%22%29%29%29+OR+%28%28title%3A%28%22Hepatic+Encephalopathy%22%29%29%29 Hepatic Encephalopathy publications]
 +
|Vetstream = [https://www.vetstream.com/felis/Content/Disease/dis02457.asp Hepatic encephalopathy]
 +
}}
  
 
==References==
 
==References==
Line 98: Line 85:
  
  
==From Pathology==
+
{{review}}
 
 
===Clinical===
 
*non-specific neurological signs (attributed to the retention of ammonia and gamma aminobutyric acid in [[Liver - Anatomy & Physiology|liver]] failure and their effects on the brain)
 
**dullness
 
**apparent unawareness of surroundings
 
**pointless or compulsive movements
 
**mania
 
**generalised convulsions
 
NB: usually soon followed by death
 
===Microscopically===
 
*lesions in the brain vary in expression
 
**most species may show myelin degeneration consisting of vacuoles between the grey and white matter
 
**the horse may show very little visible neural changes, perhaps an increase in astrocytes
 
 
 
===Causes===
 
::[[Portosystemic Shunt|Portosystemic Shunting]]
 
  
 +
{{OpenPages}}
  
::Chronic [[Liver - Anatomy & Physiology|liver]] damage
+
[[Category:Liver_-_General_Pathology]]
*due to ingestion of toxic compounds over a long period of time
+
[[Category:Liver Diseases - Dog]][[Category:Liver Diseases - Cat]]
*E.g. [[Ragwort|ragwort]] [[Category:Liver_-_General_Pathology]]
+
[[Category:Neurological Diseases - Dog]][[Category:Neurological Diseases - Cat]]
[[Category:To_Do_-_Bara]]
+
[[Category:Expert_Review]]
[[Category:To_Do_-_Workshop]]
 
[[Category:Dog]][[Category:Cat]]
 

Latest revision as of 10:21, 21 May 2016


Also known as: Portosystemic encephalopathy — Hepatic coma

See also: Hepatic Encephalopathy in Horses

Introduction

Hepatic encephalopathy (HE) is characterised by a complex of neurological abnormalities that occur due to congenital or acquired abnormalities in hepatic structure or function. HE is usually associated with some form of portosystemic shunt (PSS) in dogs and cats, although it may also be caused by a marked reduction in functional hepatic mass. Other causes of HE, such as microvascular dysplasia, congenital defects of enzymes of the urea cycle, arginine deficiency or organic acidaemias, are very rare or of only experimental interest. The clinical signs of HE are associated with increases in the blood concentration of several metabolites:

  • Ammonia is a by-product of protein degradation which is transported in the portal vein and metabolised to urea in the liver via the urea cycle. In animals with PSS, ammonia is not removed from the portal blood as this bypasses the liver, leading to an increase in its blood concentration. For ammonia generation in normal animals see ammonia.
  • Mercaptans are products of the bacterial degradation of the amino acid methionine in the colon which are usually removed from the portal blood in the liver.
  • Aromatic amino acids may be involved especially when the ratio of aromatic to branched chain amino acids is very high. This is considered to be a significant component in the pathogenesis of HE in horses.
  • GABA (gamma amino butyric acid) is an endogenous neurotransmitter which is produced from ammonia.
  • Short-chain fatty acids (such as butyrate and propionate) make a questionable contribution to HE.
  • Endogenous benzodiazepine receptor ligands are also of questionable importance.

HE represents a reversible alteration in cerebral metabolism whose pathogenesis is not yet fully understood. An increased blood concentration of ammonia is the most commonly cited cause of HE and it is known that this metabolite is able to cross the blood brain barrier and exert a directly toxic effect on neurones of the central nervous system (CNS). Since the cells of the CNS are not able to express the constituent enzymes of the urea cycle, they convert ammonia into glutamine rather than urea. Glutamine is a potent neurotransmitter in the CNS and its levels correlate with the clinical signs observed in HE. Increased concentrations of ammonia in the cerebro-spinal fluid are reported to have additional effects on cerebral metabolism, including reducing levels of the excitatory neurotransmitter serotonin and increasing the levels of NMDA (N-methyl-D-aspartate) and peripheral-type benzodiazepine receptors.

Aromatic amino acids (especially tryptophan and its metabolites) share an antiport transporter with ammonia in the blood brain barrier and dogs with congenital PSS are therefore reported to have increased levels of these amino acids in their CSF. The neurotransmitter GABA is produced from ammonia and, as the blood ammonia concentration rises, so too do the levels of GABA in the CNS. This transmitter imbalance is thought to increase the number of inhibitory GABA receptors present in the CNS.

HE may be precipitated by severel conditions in animals, all of which cause an increase in the blood concentrations of ammonia and/or mercaptans:

  • Metabolic alkalosis increases the production of ammonia by the kidneys and increases the uptake of urea across the blood brain barrier.
  • Hypokalaemia
  • Constipation, increasing the length of time that colonic bacteria are able to act on undigested amino acids.
  • Gastro-intestinal haemorrhage, increasing the amount of protein available to GI bacteria.
  • Diet with a high protein, purine or methionine content
  • Azotaemia, increasing the concentration of urea in the GI tract and also causing GI haemorrhage if uraemia develops.
  • Hypermetabolic state or fever, as may occur in many forms of systemic illness due to the effects of inflammatory cytokines and which leads to the catabolism of lean body protein. A similar phenemenon may occur if glucocorticoids are administered at high doses.
  • Dehydration increases the effective circulating ammonia concentraton.

Signalment

HE occurs in those breeds that often develop congenital PSS, of which small breeds of dog are most at risk. Most dogs with PSS present before the end of their first year of life. Microvascular dysplasia and congenital defects of the urea cycle are very rare. Acquired PSS may occur in animals with chronic hepatitis, to which Labrador retrievers, West Highland white terriers, English cocker spaniels and Dobermans are predisposed.

Diagnosis

Clinical Signs

Dog

Typical signs include:

  • Anorexia, depression and lethargy.
  • Bizarre behaviour, including aimless wandering, head pressing, circling, pacing, pica and compulsive eating and drinking.
  • Central or amaurotic blindness, where animals retain a menace response but will collide with objects when ambulatory.
  • Comas and reactive seizures are uncommon.
  • Gastrointestinal signs may be observed, including vomiting.

Other signs that occur in animals with congenital PSS or microvascular dysplasia include:

  • Temporary resolution of clinical signs with antimicrobial therapy, due to a reduction in the number of colonic bacteria.
  • Prolonged recovery from sedation or anaesthesia because the metabolic capacity of the liver is reduced.
  • Polyuria and polydipsia in 33% of cases and other signs of urinary tract disease.

Cat

Typical signs include:

  • Hypersalivation or ptyalism is the most commonly reported clinical feature but this is rarely reported in dogs.
  • Seizures occur in 50% of cases but are uncommon in dogs.
  • Compulsive behaviour is less common than in dogs.

Laboratory Tests

Although many parameters are likely to be altered in animals with HE, most of these changes result from the underlying disease. Fasting hyperammonaemia provides an explanation for HE and should increase suspicion of congenital (or acquired) PSS. An ammonia tolerance test can also be performed, in which ammonium chloride is administered by orogastric tube or by high colonic infusion. Blood samples taken 30 minutes later should show an increased level of circulating ammonia. Since this procedure may be dangerous to the animal, it may be preferable to perform a modified ammonia tolerance test by feeding a meal containing 25% of the animal's daily requirement and measuring blood ammonia concentration 6 hours later.

Diagnostic Imaging

Imaging is not required to make a diagnosis of HE but it may reveal abnormalities relating to the underlying cause.

Pathology

Myelin degeneration, consisting of vacuoles between the grey and white matter, may be observed on histopathological examination of cerebral tissues from affected animals.

Treatment

The underlying cause of the HE should be treated, including surgical ligation of congenital PSS. In the meantime, the HE should be managed medically with a typical regime involving the following components:

  • Food should be withheld
  • Intra-venous fluid therapy, which can also be used to correct any hypokalaemia or metabolic alkalosis which may be precipitating the HE.
  • Enemas of warm water or lactulose to decrease the population of bacteria in the colon.
  • Antibiotics given orally or per rectum to reduce the number of colonic bacteria. Suitable products include ampicillin, neomycin (which, although highly toxic when administered systemically, is also highly polar and therefore restricted to the GI tract) or metronidazole.
  • Lactulose can be given orally or by enema. It is a synthetic disaccharide which, when metabolised by the acidifying colonic bacteria, donates a hydrogen ion to ammonia to form ammonium ions. Because these ions are charged, the are not absorbed freely and are rather trapped in the colon and excreted in faeces. Lactulose also acts as an osmotic laxative, preventing constipation and reducing the time that colonic bacteria are able to act on undigested amino acids to form ammonia.
  • When the animal is to be fed, a diet with a high carbohydrate, low protein (2g/kg/day) and low fat content is recommended. Both soluble and insoluble fibre may be beneficial in appropriate quantities as the former traps ammonia in the colon and the latter reduces intestinal transit time and prevents constipation. In an animals with PSS or severe hepatic insufficiency, it may not be advisable to restrict protein too assiduously as these animals are likely to be hypoalbuminaemic.
  • Seizures should be treated with anticonvulsant medication but benzodiazepines should be avoided as they may worsen the HE.
  • Inclusion of L - Ornithine-l-aspartate enzymes, which accelerate the urea cycle and in turn facilitate conversion of ammonia to urea; may be helpful in acute episodes of HE. It may also be recommended to prevent HE in patients with severe hepatic functional compromise. It can, however, be safely used in patients with normal renal function.

Prognosis

In cases of PSS, the prognosis in dogs for resolution of clinical signs after total surgical ligation is excellent. However, the response to surgical intervention in cats is less promising than in dogs.


Hepatic Encephalopathy Learning Resources
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References

  • Hall, E.J, Simpson, J.W. and Williams, D.A. (2005) BSAVA Manual of Canine and Feline Gastroenterology (2nd Edition) BSAVA
  • Nelson, R.W. and Couto, C.G. (2009) Small Animal Internal Medicine (Fourth Edition) Mosby Elsevier.
  • Ettinger, S.J. and Feldman, E. C. (2000) Textbook of Veterinary Internal Medicine Diseases of the Dog and Cat Volume 2 (Fifth Edition) W.B. Saunders Company.




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