Liver dialysis

Liver dialysis is a detoxification treatment for liver failure and has shown promise for patients with hepatorenal syndrome. It is similar to hemodialysis and based on the same principles. Like a bioartificial liver device, it is a form of artificial extracorporeal liver support.[1][2]

Liver dialysis
ICD-9-CM50.92

A critical issue of the clinical syndrome in liver failure is the accumulation of toxins not cleared by the failing liver. Based on this hypothesis, the removal of lipophilic, albumin-bound substances such as bilirubin, bile acids, metabolites of aromatic amino acids, medium-chain fatty acids and cytokines should be beneficial to the clinical course of a patient in liver failure. This led to the development of artificial filtration and absorption devices.

Hemodialysis is used for kidney failure and primarily removes water-soluble toxins. However, it does not remove toxins bound to albumin that accumulate in liver failure.

Liver dialysis is performed by physicians and surgeons and specialized nurses with training in gastroenterological medicine and surgery, namely, in hepatology, the study of the liver, alongside their colleagues in the intensive or critical care unit and the transplantation department, which is responsible for procuring and implanting a new liver, or a part (lobe) of one, if and when it becomes available in time and the patient is eligible. Because of the need for these experts, as well as the relative newness of the procedure in certain areas, it is usually available only in larger hospitals, such as level I trauma center teaching hospitals connected with medical schools.

Prognosis/survival

While the technique is in its infancy, the prognosis of patients with liver failure remains guarded. Liver dialysis, currently, is only considered to be a bridge to transplantation or liver regeneration (in the case of acute liver failure)[3][4][5] and, unlike kidney dialysis (for kidney failure), cannot support a patient for an extended period of time (months to years).

Devices

Artificial detoxification devices currently under clinical evaluation include the Single Pass Albumin Dialysis (SPAD), Molecular Adsorbent Recirculating System (MARS)®, Prometheus system, and Dialive.

Single Pass Albumin Dialysis (SPAD)

Single pass albumin dialysis (SPAD) is a simple method of albumin dialysis using standard renal replacement therapy machines without an additional perfusion pump system: The patient's blood flows through a circuit with a high-flux hollow fiber hemodiafilter, identical to that used in the MARS system. The other side of this membrane is cleansed with an albumin solution in counter-directional flow, which is discarded after passing the filter. Hemodialysis can be performed in the first circuit via the same high-flux hollow fibers.

Molecular adsorbents recirculation system

The Molecular Adsorbents Recirculation System (MARS), is the best known extracorporal liver dialysis system and has existed for approximately fifteen years. It consists of two separate dialysis circuits. The first circuit consists of human serum albumin, is in contact with the patient's blood through a semipermeable membrane and has two filters to clean the albumin after it has absorbed toxins from the patient's blood. The second circuit consists of a hemodialysis machine and is used to clean the albumin in the first circuit, before it is recirculated to the semipermeable membrane in contact with the patient's blood.

Comparing SPAD, MARS and CVVHDF

SPAD, MARS and continuous veno-venous haemodiafiltration (CVVHDF) were compared in vitro with regard to detoxification capacity.[6] SPAD and CVVHDF showed a significantly greater reduction of ammonia compared with MARS. No significant differences could be observed between SPAD, MARS and CVVHDF concerning other water-soluble substances. However, SPAD enabled a significantly greater bilirubin reduction than MARS. Bilirubin serves as an important marker substance for albumin-bound (non-water-soluble) substances. Concerning the reduction of bile acids no significant differences between SPAD and MARS were seen. It was concluded that the detoxification capacity of SPAD is similar or even higher when compared with the more sophisticated, more complex and hence more expensive MARS.

As albumin dialysis is a costly procedure, financial aspects are important: For a seven-hour treatment with MARS, approximately €300 for 600 ml human serum albumin solution (20%), €1740 for a MARS treatment kit, and €125 for disposables used by the dialysis machine have to be spent. The cost of this therapy adds up to approximately €2165. Performing SPAD according to the protocol by Sauer et al., however, requires 1000 ml of human albumin solution (20%) at a cost of €500. A high-flux dialyzer costing approximately €40 and the tubings (€125) must also be purchased. The overall costs of a SPAD treatment is approximately €656—30% of the costs of an equally efficient MARS therapy session. The expenditure for the MARS monitor necessary to operate the MARS disposables is not included in this calculation.

Prometheus

The Prometheus system (Fresenius Medical Care, Bad Homburg, Germany) is a device based on the combination of albumin adsorption with high-flux hemodialysis after selective filtration of the albumin fraction through a specific polysulfon filter (AlbuFlow). It has been studied[7] in a group of eleven patients with hepatorenal syndrome (acute-on-chronic liver failure and accompanying kidney failure). The treatment for two consecutive days for more than four hours significantly improved serum levels of conjugated bilirubin, bile acids, ammonia, cholinesterase, creatinine, urea and blood pH. Prometheus was proven to be a safe supportive therapy for patients with liver failure.

Dialive

Dialive (Yaqrit Limited, London, UK) incorporates albumin removal and replacement and, endotoxin removal. It is at "Technology readiness level" (TRL) 5, which means it is validated in the disease environment.[8][9]

See also

References

  1. https://scholar.google.com/scholar?as_ylo=2015&q=liver+dialysis&hl=en&as_sdt=0,14
  2. "Advanced Search | Cochrane Library".
  3. O'Grady J (June 2006). "Personal view: current role of artificial liver support devices". Aliment. Pharmacol. Ther. 23 (11): 1549–57. doi:10.1111/j.1365-2036.2006.02931.x. PMID 16696802.
  4. van de Kerkhove MP, Hoekstra R, Chamuleau RA, van Gulik TM (August 2004). "Clinical application of bioartificial liver support systems". Ann. Surg. 240 (2): 216–30. doi:10.1097/01.sla.0000132986.75257.19. PMC 1356396. PMID 15273544.
  5. Neuberger J (January 2005). "Prediction of survival for patients with fulminant hepatic failure". Hepatology. 41 (1): 19–22. doi:10.1002/hep.20562. PMID 15690476.
  6. Sauer IM, Goetz M, Steffen I, et al. (May 2004). "In vitro comparison of the molecular adsorbent recirculation system (MARS) and single-pass albumin dialysis (SPAD)". Hepatology. 39 (5): 1408–14. doi:10.1002/hep.20195. PMID 15122770.
  7. Rifai K, Ernst T, Kretschmer U, et al. (December 2003). "Prometheus—a new extracorporeal system for the treatment of liver failure". J. Hepatol. 39 (6): 984–90. doi:10.1016/S0168-8278(03)00468-9. PMID 14642616.
  8. "DIALIVE Concept – Aliver".
  9. "Yaqrit". yaqrit.com. Retrieved 4 November 2019.

Further reading

  • Sen S, Williams R, Jalan R (February 2005). "Emerging indications for albumin dialysis". Am. J. Gastroenterol. 100 (2): 468–75. doi:10.1111/j.1572-0241.2005.40864.x. PMID 15667509.
  • Evenepoel P, Maes B, Wilmer A, et al. (2003). "Detoxifying capacity and kinetics of the molecular adsorbent recycling system. Contribution of the different inbuilt filters". Blood Purif. 21 (3): 244–52. doi:10.1159/000070697. PMID 12784051.
  • Mitzner S, Klammt S, Stange J, Nöldge-Schomburg GF, Schmidt R (April 2005). "[Extracorporeal blood purification in severe liver failure with the albumin dialysis MARS – impact on relevant intensive care parameters]". Anasthesiol Intensivmed Notfallmed Schmerzther (in German). 40 (4): 199–206. doi:10.1055/s-2004-826116. PMID 15832238.
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