Difference between revisions of "Acute Renal Failure"

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==Introduction==
 
==Introduction==
  
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This section only covers the intrinsic causes or ARF, as pre- and post-renal failure are very different disease processes.  
 
This section only covers the intrinsic causes or ARF, as pre- and post-renal failure are very different disease processes.  
  
'''[[Toxicology|Toxic injury]]''' is the most common cause. Drugs such as '''aminoglycosides, fluroquinolones, amphotericine , [[NSAIDs|NSAIDs]],  and ACE-inhibitors''' are known to cause acute renal failure, if used unjudiciously.  [[Ethylene Glycol Toxicity|Ethylene glycol]], [[House Plant Toxicity|easter lillies]], hemotoxic snake venoms etc. contribute to toxic ARF. However, the access to different kinds of toxins varies as per geographic distribution. Some toxic agents act directly on tubular cells, some act on the haemodynamics of the kidney, whilst others cause damage by precipitating within the tubules.  
+
'''[[Toxicology|Toxic injury]]''' is the most common cause. Drugs such as '''aminoglycosides, fluroquinolones, amphotericine , [[NSAIDs|NSAIDs]],  and ACE-inhibitors''' are known to cause acute renal failure.  [[Ethylene Glycol Toxicity|Ethylene glycol]], [[House Plant Toxicity|easter lillies]], Hemotoxic snake venoms etc. contribute to toxic ARF. However, the access to different kinds of toxins varies as per geographic distribution. Some toxic agents act directly on tubular cells, some act on the haemodynamics of the kidney, whilst others cause damage by precipitating within the tubules.  
  
 
'''[[Ischaemia|Ischaemic injury]]''' is also common, especially following hospitalisation. It is therefore essential to monitor the fluid therapy requirements of hospital patients, especially peri- and post-operatively to prevent pre-renal [[Azotaemia|azotaemia]] and subsequent ischaemia.  
 
'''[[Ischaemia|Ischaemic injury]]''' is also common, especially following hospitalisation. It is therefore essential to monitor the fluid therapy requirements of hospital patients, especially peri- and post-operatively to prevent pre-renal [[Azotaemia|azotaemia]] and subsequent ischaemia.  
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* '''[[Vomiting|Vomiting]]'''
 
* '''[[Vomiting|Vomiting]]'''
  
The intensity of these signs will depend upon the time elapsed between the renal insult and presentation to the veterinarian. The different kinds of extra-renal systems involved will detect the kind of signs a patient may show at presentation.
+
The intensity of these signs will depend upon the time elapsed between the renal insult and presentation to the Vet. The different kinds of extra-renal systems involved will detect the kind of signs a patient may show at presentation.
  
 
There may also be evidence of swollen or painful kidneys on abdominal palpation, an increased or decreased heart rate, hypothermia and oral ulceration or signs of a concurrent disease.  
 
There may also be evidence of swollen or painful kidneys on abdominal palpation, an increased or decreased heart rate, hypothermia and oral ulceration or signs of a concurrent disease.  
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The aim of treatment is to '''support the patient whilst the tubules repair'''. If the ingestion of a specific toxin is known then further exposure should be prevented and  an '''antidote''' may be given if available (for example ethanol in [[Ethylene Glycol Toxicity|ethylene glycol toxicity]]). More commonly, by the time of presentation the damage to the kidneys has already occurred and it is no longer appropriate to administer the antidote. If any other underlying cause has been identified (such as [[Pyelonephritis|pyelonephritis]]), this should be treated appropriately.
 
The aim of treatment is to '''support the patient whilst the tubules repair'''. If the ingestion of a specific toxin is known then further exposure should be prevented and  an '''antidote''' may be given if available (for example ethanol in [[Ethylene Glycol Toxicity|ethylene glycol toxicity]]). More commonly, by the time of presentation the damage to the kidneys has already occurred and it is no longer appropriate to administer the antidote. If any other underlying cause has been identified (such as [[Pyelonephritis|pyelonephritis]]), this should be treated appropriately.
  
'''Aggressive [[Fluid therapy|fluid therapy]] is the mainstay of treatment in ARF cases'''. A mild level of volume overload is ideal as it promotes urine production, however as animals are often oliguric, care should be taken not to overload the body with too much fluid. In addition [[Diuretics Effects on Kidneys - Anatomy & Physiology|'''diuretics''']] such as '''frusemide and mannitol''' can be administered to stimulate urine production. A '''closed collection system''' should be used to '''monitor urine output'''.  
+
'''Aggressive [[Fluid therapy|fluid therapy]] is the mainstay of treatment in ARF cases'''. A mild level of volume overload is ideal as it promotes urine production, however as animals are often oliguric, care should be taken not to overload the body with too much fluid. In addition [[Diuretics Effects on Kidneys - Anatomy & Physiology|'''diuretics''']] such '''frusemide and mannitol''' can be administered to stimulate urine production. A '''closed collection system''' should be used to '''monitor urine output'''.  
  
 
Severe '''metabolic disturbances''' occur secondary to ARF. '''Hyperkalaemia''' is a common occurrence and is also treated with '''fluid therapy''' using a product such as saline. If it is severe and compromising the cardiac function of the animal then '''calcium gluconate''' can be administered to stabilise the heart (whilst levels are reduced by fluid therapy).  
 
Severe '''metabolic disturbances''' occur secondary to ARF. '''Hyperkalaemia''' is a common occurrence and is also treated with '''fluid therapy''' using a product such as saline. If it is severe and compromising the cardiac function of the animal then '''calcium gluconate''' can be administered to stabilise the heart (whilst levels are reduced by fluid therapy).  
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If this treatment is not sufficient to maintain the animal then a method of '''dialysis''' may be considered.
 
If this treatment is not sufficient to maintain the animal then a method of '''dialysis''' may be considered.
<br>'''Peritoneal Dialysis:''' This technique uses the omentum within the peritoneum as a filter to remove uraemic toxins. It is used in specialist referral centres when it is considered likely that the cat may recover from ARF. The technique is labour intensive but well tolerated by the animal.  
+
:'''Peritoneal Dialysis:''' This technique uses the omentum within the peritoneum as a filter to remove uraemic toxins. It is used in specialist referral centres when it is considered likely that the cat may recover from ARF. The technique is labour intensive but well tolerated by the animal.  
<br>'''Hemodialysis:''' This is rarely performed due to the high cost of equipment and ethical questions surrounding longterm treatment. It is only available at a limited number of specialist hospitals. However, the technical advances and increased experience with the clinical applications of hemodialysis is changing the face of therapeutic options available for acute renal failure patients worldwide. If applied early in the course of acute renal insult, hemodialysis can significantly reduce mortality and/or progression towards chronic renal parenchymal changes.
+
:'''Hemodialysis:''' This is rarely performed due to the high cost of equipment and ethical questions surrounding longterm treatment. It is only available at a limited number of specialist hospitals.
 
+
 
==Prognosis==
 
==Prognosis==
 
Prognosis is entirely dependant on whether the animal can be supported whilst the tubules repair. Often intensive care for prolonged peroids (up to eight weeks) is required to achieve this. Generally, animals presenting with '''oliguria''', particularly with a history of toxin ingestion have a '''grave prognosis'''. Renal biopsy may give an indication of the reversibility of the condition (if the basement membrane is intact) and therefore prognosis - it should be considered prior to starting dialysis. If urine production is not restored following treatment, prognosis is very poor and euthanasia may be the only appropriate option.  
 
Prognosis is entirely dependant on whether the animal can be supported whilst the tubules repair. Often intensive care for prolonged peroids (up to eight weeks) is required to achieve this. Generally, animals presenting with '''oliguria''', particularly with a history of toxin ingestion have a '''grave prognosis'''. Renal biopsy may give an indication of the reversibility of the condition (if the basement membrane is intact) and therefore prognosis - it should be considered prior to starting dialysis. If urine production is not restored following treatment, prognosis is very poor and euthanasia may be the only appropriate option.  
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{{review}}
 
{{review}}
 
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[[Category:Renal Failure]]
 
[[Category:Renal Failure]]
 
[[Category:Expert Review - Small Animal]]
 
[[Category:Expert Review - Small Animal]]

Revision as of 19:19, 27 December 2011

Introduction

Acute Renal Failure is a syndrome caused by the acute failure of haemodynamic, filtration and excretory functions in the kidney. This results in the accumulation of uraemic toxins and the dysregulation of acid-base, fluid and electrolyte balances. It is rapidly progressive but may be reversible. It can result from pre-renal, intra-renal or post-renal factors.

  • Pre-renal factors include ischaemia and reduced renal perfusion
  • Post-renal factors include lower urinary tract obstruction

Clinical signs include oliguria or anuria, vomiting and anorexia; blood sample analysis shows azotaemia.

Aetiology

This section only covers the intrinsic causes or ARF, as pre- and post-renal failure are very different disease processes.

Toxic injury is the most common cause. Drugs such as aminoglycosides, fluroquinolones, amphotericine , NSAIDs, and ACE-inhibitors are known to cause acute renal failure. Ethylene glycol, easter lillies, Hemotoxic snake venoms etc. contribute to toxic ARF. However, the access to different kinds of toxins varies as per geographic distribution. Some toxic agents act directly on tubular cells, some act on the haemodynamics of the kidney, whilst others cause damage by precipitating within the tubules.

Ischaemic injury is also common, especially following hospitalisation. It is therefore essential to monitor the fluid therapy requirements of hospital patients, especially peri- and post-operatively to prevent pre-renal azotaemia and subsequent ischaemia.

Tubulointerstital disease resulting in inflammation and oedema can also cause acute renal failure. This is normally precipitated by infections (pyelonephritis and leptospirosis), autoimmune reactions and allergy.

Pathogenesis

A reduction in GFR is caused by the decrease in surface area or conductivity of glomerular capillaries (resulting in a drop in the ultra-filtration coefficient). Epithelial cells and debris obstruct the tubules. Toxin precipitates may contribute to this. Tubular fluid leaks out of the tubules and across the epithelium, back into the interstitium - causing a drop in GFR. Ischaemic injury to the peripheral medulla occurs due to intra-renal vasoconstriction.

Clinical Signs

The most significant information can be gleaned from the history. It is important to ask the owners about toxin ingestion and urine production.

Clinical exam normally reveals fairly non-specific signs such as:

The intensity of these signs will depend upon the time elapsed between the renal insult and presentation to the Vet. The different kinds of extra-renal systems involved will detect the kind of signs a patient may show at presentation.

There may also be evidence of swollen or painful kidneys on abdominal palpation, an increased or decreased heart rate, hypothermia and oral ulceration or signs of a concurrent disease.

The most suggestive sign of severe acute renal failure is oliguria or anuria. It does not occur in all cases so should not be completely relied on for diagnosis. Bloodwork should show azotaemia.

Diagnosis

On presentation is it important to establish two things:

  1. Whether the renal failure is acute or chronic as they present in a very similar manner but have different treatment protocols and prognoses.
  2. Whether the renal failure is pre-renal, renal or post-renal.

As mentioned it is important to differentiate ARF from decompensated CRF, as ARF is potentially reversible with aggressive therapy. The only diagnostic test that can achieve this is biopsy, but due to the high level of risk involved in an already sick animal this is normally not performed. Instead the following factors can be used by the clinician to guide diagnosis:

(1) History

With ARF there may be a history of ingestion of or access to toxins/nephrotoxic drugs, and oliguria. Cats with CRF normally have a history of chronic weight loss, anorexia and polyuria/polydypsia (PU/PD).

(2) Clinical Exam

ARF cats tend to have a good body condition score, and healthy skin and coat. CRF cases have a poor body condition score and a dull/scruffy coat.

(3) Renal Parameters - palpation, ultrasound, radiography

The kidneys in ARF cats are normal sized or enlarged, and normally painful. In CRF, the kidneys are shrunken, firm and non-painful.

(4) Other

The presence of secondary renal hyperparathyroidism and non regenerative anaemia is suggestive of CRF


Secondly the type of azotaemia must be identified:

(1) Pre-renal

Caused by severe dehydration, shock or any other pathology that results in poor renal perfusion. In these cases USG is >1.035 in the cat and >1.030 in the dog before fluid therapy. There should be no evidence of inflammation and urine sodium concentrations are low. Diagnosis is confirmed by a rapid and dramatic response to fluid therapy.

(2) Renal

This is caused by a direct insult to the kidney, with intrinsic damage. In these cases azotaemia is present, and urine specific gravity is between 1.007 and 1.025. There may be evidence of inflammation in the urine sediment and a high sodium content. There is only a minimal response to fluid therapy. The hallmark of primary renal failure is azotaemia in the presence of poorly concentrated urine.

(3) Post-renal

Post-renal failure is caused by an obstruction or rupture within the urinary system. This is normally identifiable following a thorough history and physical exam.


Treatment

The aim of treatment is to support the patient whilst the tubules repair. If the ingestion of a specific toxin is known then further exposure should be prevented and an antidote may be given if available (for example ethanol in ethylene glycol toxicity). More commonly, by the time of presentation the damage to the kidneys has already occurred and it is no longer appropriate to administer the antidote. If any other underlying cause has been identified (such as pyelonephritis), this should be treated appropriately.

Aggressive fluid therapy is the mainstay of treatment in ARF cases. A mild level of volume overload is ideal as it promotes urine production, however as animals are often oliguric, care should be taken not to overload the body with too much fluid. In addition diuretics such frusemide and mannitol can be administered to stimulate urine production. A closed collection system should be used to monitor urine output.

Severe metabolic disturbances occur secondary to ARF. Hyperkalaemia is a common occurrence and is also treated with fluid therapy using a product such as saline. If it is severe and compromising the cardiac function of the animal then calcium gluconate can be administered to stabilise the heart (whilst levels are reduced by fluid therapy).

Hemodialysis machine (Wikimedia Commons)

Metabolic acidosis also occurs, and again can be treated with fluid therapy. A fluid such as Hartmanns which contains bicarbonate should be used. If this is insufficient to resolve the acidosis then bicarbonate can be administered directly. The use of dopamine in dogs to cause renal vasodilation is currently not recommended.

Additional supportive treatment includes anti-emetic drugs and gastro-protectants such as sucralfate and ranitidine. A low protein diet can be fed to reduce the levels of uraemic toxins and an oesophageal tube should be placed in any anorexic animals.

If this treatment is not sufficient to maintain the animal then a method of dialysis may be considered.

Peritoneal Dialysis: This technique uses the omentum within the peritoneum as a filter to remove uraemic toxins. It is used in specialist referral centres when it is considered likely that the cat may recover from ARF. The technique is labour intensive but well tolerated by the animal.
Hemodialysis: This is rarely performed due to the high cost of equipment and ethical questions surrounding longterm treatment. It is only available at a limited number of specialist hospitals.

Prognosis

Prognosis is entirely dependant on whether the animal can be supported whilst the tubules repair. Often intensive care for prolonged peroids (up to eight weeks) is required to achieve this. Generally, animals presenting with oliguria, particularly with a history of toxin ingestion have a grave prognosis. Renal biopsy may give an indication of the reversibility of the condition (if the basement membrane is intact) and therefore prognosis - it should be considered prior to starting dialysis. If urine production is not restored following treatment, prognosis is very poor and euthanasia may be the only appropriate option.


Acute Renal Failure Learning Resources
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Feline Medicine Q&A 23
Feline Medicine Q&A 24


References

Gleadhill, A (1994) Differential diagnosis of renal failure in the dog In Practice 1994 16: 216-22

Merck & Co (2009) The Merck Veterinary Manual (Ninth Edition), Merial

RVC staff (2009) Urogenital system RVC Intergrated BVetMed Course, Royal Veterinary College

Sparks, AH & Caney, SMA (2005) Self-Assessment Colour Review Feline Medicine Manson Publishing