Reduction of Elevated Cytokine Levels in Acute/Acute‐on‐Chronic Liver Failure Using Super‐Large Pore Albumin Dialysis Treatment: An In Vitro Study

The removal of small water soluble toxins and albumin‐bound toxins in acute liver failure patients (ALF) or acute‐on‐chronic liver failure (AocLF) patients has been established using extracorporeal liver support devices (e.g. Molecular Adsorbents Recirculating System; MARS). However, reduction of elevated cytokines in ALF/AocLF using MARS is still not efficient enough to lower patients' serum cytokine levels. New membranes with larger pores or higher cut‐offs should be considered in extracorporeal liver support devices based on albumin dialysis in order to address these problems, as the introduction of super‐large pore membranes could counterbalance high production rates of cytokines and further improve detoxification in vivo. Using an established in vitro two compartment albumin dialysis model, three novel membranes of different pore sizes were compared with the MARS Flux membrane for cytokine removal and detoxification qualities in vitro. Comparing the membranes, no improvement in the removal of water soluble toxins was found. Albumin‐bound toxins were removed more efficiently using novel large (Emic2) to super‐large pore sized membranes (S20; HCO Gambro). Clearance of cytokines IL‐6 and tumor necrosis factor‐α was drastically improved using super‐large pore membranes. The Emic2 membrane predominantly removed IL‐6. In vitro data suggest that the usage of larger pore sized membranes in albumin dialysis can efficiently reduce elevated cytokine levels and liver failure toxins. Using large to super‐large pore membranes might exert effects on patients' serum cytokine levels. Combined with increased detoxification this could lead to higher survival in ALF/AocLF. Promising membranes for clinical evaluation have been identified.     

Emerging indications for albumin dialysis

The accumulation of albumin-bound toxins in liver failure is believed to be responsible for the development of associated end-organ dysfunctions (kidney, circulation, brain). Albumin dialysis utilizes the scavenging functions of albumin for the removal of toxins. The Molecular Adsorbents Recirculating System (MARS) is one such extracorporeal liver support device where blood is dialyzed across an albumin-impregnated membrane against 20% albumin. Charcoal and anion exchange resin columns in the circuit cleanse and regenerate the albumin dialysate. Clinical studies in the last decade have demonstrated proven reduction in hyperbilirubinemia, along with an improvement in encephalopathy in liver failure patients, as well as apparent improvement in survival. Some studies have also reported improvement of systemic hemodynamics and renal function in these patients. Amelioration of intractable pruritus and treatment of toxicities with albumin-bound substances are some of the newer indications emerging. However, the specific underlying pathophysiological mechanisms are still not clear. Two other systems based on the removal of albumin-bound toxins, the Prometheus (using the principle of fractionated plasma separation and adsorption [FPSA]), and the single pass albumin dialysis (SPAD) are also currently under development but available clinical data are limited.     

Extracorporeal liver support-albumin dialysis with the Molecular Adsorbent Recirculating System (MARS)

Extracorporeal liver support has been a much studied topic throughout the last 50 years. Albumin dialysis as a therapeutic option for patients with acute liver failure or acute decompensation of chronic liver disease was introduced in the mid-nineties. The Molecular Adsorbent Recirculating System (MARS) is based on the concept of albumin dialysis and allows for the removal of protein-bound as well as water-soluble toxins. Besides its role as a sufficient volume expander human serum albumin is an important scavenger for molecules with pathophysiological relevance in liver failure. Albumin dialysis enables the selective regeneration of patient's albumin resulting in an increase of albumin binding capacity. Clinically, an improvement of central and local hemodynamics as well as liver-, brain-, and kidney-functions were observed. Thus, the treatment can contribute to liver regeneration and stabilization of vital organ functions and thus help to bridge patients to liver transplantation or to recovery of native liver function. Proper patient selection is critical for clinical success. Aggressive treatment of infections and sepsis seems to be a decisive pre-requisite for its safe and efficient use. Cautious anticoagulation with heparin is the common standard. Citrate use is recommended for patients prone to bleeding. Today, albumin dialysis MARS is among the best studied liver support methods. It appears as a valuable therapeutic tool for the treatment of various complications of of liver failure, especially hemodynamic instability and hepatic encephalopathy. Further studies will need to help defining the optimal patient selection and technical process parameters such as session length and frequency of treatment.     

Extracorporeal albumin dialysis

Previous studies reported that dialysis with albumin dialysate (AD) was effective in removing albumin-binding toxins (ABT), and the Molecular Adsorption Recycling System (MARS) and Continuous Albumin Purification System (CAPS) have been developed. These blood purification therapies were categorized into the concept of extracorporeal albumin dialysis (ECAD). ECAD is defined as extracorporeal therapies using AD for the removal of not only water-soluble but also ABT. It was reported that symmetric as well as asymmetric membrane dialyzers had the effect of the removal of bilirubin by AD. The larger pore size membrane can remove more bilirubin. In the greater albumin concentration in AD, the removal capacity for bilirubin by AD increased. Bilirubin in AD could be removed by a charcoal and a bilirubin adsorption column, and its concentration in AD remained approximately constant. In clinical performance of CAPS, cellulose triacetate membrane, 5% AD, bilirubin adsorber columns, and charcoal adsorber columns were used. This system was applied continuously for 24 h for treatment. CAPS could control not only renal but also liver function during the 24 h, without any adverse effect. MARS removes many toxic substances including ABT, and has beneficial effect on brain, liver, renal, and cardiovascular functions, and improvement of 30-day survival were reported. ECAD may become a possible therapeutic tool in patients with the disease state of ABT accumulation as an artificial kidney and liver. However, several attempts such as the application of recombinant human albumin and acetate free dialysate, should be required.     

Albumin dialysis: single pass vs. recirculation (MARS)

The single pass albumin dialysis (SPAD) was reported to be an alternative to the Molecular Adsorbent Recirculating System (MARS) for the effective removal of protein bound substances in liver failure. Three SPAD experiments using different albumin concentrations and dialysate flow rates were performed. In each experiment, 1000 ml human donor plasma, spiked with 250 mg unconjugated bilirubin, 200 mg sulfobromophthalein (BSP) and 115 mg glycocholic acid (N-[3alpha,7alpha,12alpha-trihydroxy-24-oxycholan-24-yl]glycine) - a conjugated bile acid (BA), circulated in a closed loop with 150 ml/min and was dialysed against albumin solution. These substances are bound to the different binding sites of albumin and have different association constants. For the comparison, the standard MARS experiment was performed using the same plasma flow rate of 150 ml/min. Moreover, the clearances of bilirubin for MARS and SPAD during clinical treatments were calculated using own data and those reported by Seige, Kreymann, Jeschke, et al. in Transplant Proc 1999; 31: 1371-5. The concentrations of bilirubin, BSP and BA were measured in plasma and dialysate and for these substances clearances (Cl) were calculated. It is known that the elimination rate of bilirubin is not very high during albumin dialysis in comparison to other substances, like bile acids, due to the high association constant. An increase of albumin concentration or the flow rate improved the efficacy but also raised the costs substantially. In this study, we have shown that MARS is the more effective kind of albumin dialysis for the important substances like bile acids. By SPAD an improvement of efficacy can be reached only by dramatic increase of the costs. Also, the earlier experiments showed that MARS is safer because of the removal of the stabilizers, which are normally included in the commercial albumin solutions.     

Effect of Extracorporeal Liver Support by Molecular Adsorbents Recirculating System and Prometheus on Redox State of Albumin in Acute‐on‐Chronic Liver Failure

Oxidative stress is believed to play an important role in acute‐on‐chronic liver failure (AoCLF). Albumin, an important transport vehicle, was found to be severely oxidized in AoCLF patients. Extracorporeal liver support systems may exert beneficial effects in AoCLF via removal of albumin‐bound toxins. At present, two systems are commercially available, the molecular adsorbents recirculating system (MARS) and fractionated plasma separation, adsorption and dialysis (FPAD, also known as Prometheus). The aim of this study was to compare the effect of MARS and Prometheus treatments on the redox state of human serum albumin. Eight patients with AoCLF underwent alternating treatments with either MARS or Prometheus in a randomized cross‐over design. Sixteen treatments (eight MARS and eight Prometheus) were available for analysis. The fraction of human mercaptalbumin (HMA), human nonmercaptalbumin‐1 (HNA1), and human nonmercaptalbumin‐2 (HNA2) were measured before and after single MARS and Prometheus treatments and during follow‐up. In AoCLF patients the oxidized fractions of albumin, HNA1, and HNA2 were markedly increased. Both MARS and Prometheus treatments resulted in a shift of HNA1 to HMA, while HNA2 was not significantly affected. This shift in albumin fractions was transient and disappeared within 24 h after treatment. There were no significant differences between MARS and Prometheus treatments with respect to the redox state of albumin. Both MARS and Prometheus treatments lead to transient improvements of the redox state of albumin, which could be beneficial in the treatment of AoCLF.     

Albumin dialysis with MARS for the treatment of anabolic steroid-induced cholestasis

Background and aims. Steroid-related hepatotoxicity has become one of the most relevant causes of drug induced liver cholestasis. Some patients do not improve after standard medical treatment (SMT) and may therefore require other approaches, like extracorporeal liver support.Material and methods. We report four cases of patients with pruritus, abnormal liver function tests and biopsy-proven anabolic steroid-induced cholestasis who were unresponsive to SMT. They underwent treatment with albumin dialysis (Molecular Adsorbent Recirculating System -MARS®-). A minimum of two MARS sessions were performed.Results. After MARS® procedure, patients’ symptoms improved, as well as liver function tests, thus avoiding liver transplantation.Conclusion. Albumin dialysis appears as a valuable therapeutic option for the management of anabolic steroid-induced cholestasis in patients that are unresponsive to SMT.     

Efficiency of dialysis with albumin in the treatment of patients with advanced hepatic insufficiency: initial experience with the MARS system in Spain

During liver failure there is an accumulation of toxic substances secondary to the loss of liver function. In order to eliminate these substances various extracorporeal depuration therapies have been employed. Recently, we have used a new treatment, MARS (Molecular Adsorbent Recirculating System), in 3 patients diagnosed with severe liver failure. This system consists of an albumin rich (20%) dialysate circuit, with two areas of depuration. In one area, the albumin dialysate is in contact with blood through a high-flux albumin coated membrane, where albumin bound substances are eliminated. In the other area, the albumin dialysate is in contact with a standard bicarbonate dialysate through a low-flux membrane, which permits the elimination of water soluble substances. The albumin of the circuit is continuously regenerated through charcoal and ion exchanger filters. In order to determine those liver failure patients suitable to receive MARS therapy we established several inclusion criteria. All patients underwent a complete clinical and biochemical evaluation before and after each treatment. All of them showed an improvement of their clinical (attenuation of pruritus and encephalopathy) and biochemical (decrease of bilirubin levels) parameters. During the period of treatment 2 patients developed an increase in plasma creatinine levels together with a decrease of urinary volume. There were no hemodynamic or technical complications during the treatment. These promising results deserve further controlled studies large enough to permit confirmation.     

Increase of Octanoate Concentrations During Extracorporeal Albumin Dialysis Treatments

Extracorporeal liver support procedures based on albumin dialysis require the use of pharmaceutical‐grade human serum albumin (HSA). Those preparations contain octanoate, which is added as stabilizer during the production process. For octanoate, a direct involvement in the pathogenesis of liver failure complications as well as an indirect influence by competitive displacement effects at the albumin molecule have been described. During five Single Pass Albumin Dialysis (SPAD) and three Molecular Adsorbent Recirculating System (MARS) treatments the changes of octanoate concentrations in blood and dialysate were investigated. An octanoate increase in patient blood was observed during passage of the filter for both SPAD (585 µmol/L [338–1022 µmol/L]) (median [range]) and MARS (182 µmol/L [71–437 µmol/L]) during the first three hours of treatment. The molar ratio of octanoate/albumin at the blood outflow was significantly higher during SPAD treatments (1.73 [0.86–2.64] vs. 0.54 [0.31–1.1]; P = 0.001) during MARS. Changes of octanoate blood levels during SPAD were significantly higher than during MARS (P < 0.001). The shift of octanoate from the dialysate to the patient was persistent during SPAD (median 67.6 µmol/min), whereas during MARS a decrease over time was observed (from 25.5 to 7.5 µmol/min). During albumin dialysis procedures a transfer of octanoate into patient blood occurs. The time‐course and extent are different between both albumin dialysis procedures. Given the positive clinical effects reported mainly for MARS, the clinical impact of albumin dialysis‐associated transfer of octanoate during extracorporeal liver support needs to be evaluated further.     

Albumin regeneration in liver support-comparison of different methods

Albumin is the most abundant human plasma protein. Among many other functions it is an important transporter of hydrophobic internal and external substances such as intermediate and end products of metabolism and drugs. In liver failure the albumin binding capacity is decreased because of a disproportion between available albumin molecules caused by decreased hepatic synthesis and hydrophobic toxins because of decreased hepatic clearance. The resulting increase in plasma and tissue concentrations of these substances is associated with multiple organ dysfunctions frequently seen in severe liver failure. The scope of the present article is to compare different liver support strategies with regard to their ability to regenerate the patients albumin pool by removing albumin-bound toxins. Most prominent technique in this group is the molecular adsorbent recirculating system (MARS). It will be compared with single pass albumin dialysis (SPAD), fractionated plasma separation and adsorption system (FPSA, Prometheus), and plasma perfusion/bilirubin adsorption with special regard to efficacy and selectivity.     

Albumin dialysis has a favorable effect on amino acid profile in hepatic encephalopathy

According to one popular theory, hepatic encephalopathy (HE) is partly caused by an imbalance in plasma amino acid levels. The Fischer's ratio between branched chain amino acids (BCAAs) and aromatic amino acids (AAAs) correlates with the degree of HE; the lower Fischer's ratio, the higher the grade of HE. Extra-corporeal liver support systems, like MARS(R)-albumin dialysis (Molecular Adsorbents Recirculating System), can improve HE. The MARS(R) system uses a hyperosmolar albumin circuit to remove both water-soluble and albumin-bound substances. Plasma levels of neuroactive amino acids were analyzed in 82 consecutive patients with life-threatening liver failure admitted to our ICU. All patients fulfilled our indications for MARS treatment and most also fulfilled the criteria for liver transplantation (LTx). In patients with acute liver failure (ALF), as compared to those with acute decompensation of chronic liver failure (AcOChr), levels of leucine and isoleucine were significantly higher before MARS(R) treatment. In all patients, before MARS(R) treatment the higher the grade of HE grade the lower was the Fischer's ratio and higher were the levels of inhibitory neuroactive amino acids. During MARS(R) treatments the Fischer's ratio increased, and the grade of HE decreased. The increase in Fischer's ratio was mainly due to the decrease in AAAs. The plasma levels of neuroactive amino acids, methionine, glutamine, glutamate, histidine and taurine decreased during MARS(R)-treatment. In this study MARS(R)-albumin dialysis had a favorable effect on the plasma amino acid profile of patients with HE.     

Application of Molecular Adsorbent Recirculating System in patients with severe liver failure after hepatic resection or transplantation: initial single-centre experiences

Acute liver failure after hepatic surgery is still plaqued with high mortality rate. Recently, a liver dialysis system (MARS) that allows detoxification of albumin-bound substances and may hereby support liver regeneration and patient's recovery has been developed. In the present study, we report our experiences with MARS dialysis in patients with liver failure after hepatic resection or transplantation. Between September 1999 and January 2001, five patients were treated with MARS (2-5 courses). Though beneficial effects such as improvement of encephalopathy and renal function as well as reduced bilirubin levels were recorded during MARS therapy, only one patient survived. Neither significant technical problems nor adverse effects occurred by using MARS dialysis. We conclude that in surgical patients, acute liver failure is usually part of a complicated clinical course affecting multipleorgan systems. Thus, it is difficult to determine the specific influence of MARS on patient's outcome. However, beneficial effects observed in our patients justify its continuous use and may stimulate further evaluation in controlled studies with surgical patients.     

Albumin dialysis reduces portal pressure acutely in patients with severe alcoholic hepatitis

BACKGROUND/AIMS: In patients with alcoholic hepatitis (AH), inflammation contributes to the severity of portal hypertension. This study evaluates the acute effects of albumin dialysis, using the Molecular Adsorbents Recirculating System (MARS), on portal pressure in AH. METHODS: Eleven patients with AH and portal hypertension were treated with MARS (n=8) or haemofiltration (n=3). All patients had associated organ failure manifested by hepatic encephalopathy (Grade 2 or more) or renal failure. Hepatic venous pressure gradient (HVPG) was measured before, during and after the treatment session. RESULTS: A rapid significant reduction of HVPG was observed by 6 h (falling by > or =20% in 7/8 patients, reaching 12 mmHg in 6/8), which was sustained up to 18 h after stopping dialysis. Similar rapid sustained improvements of systemic haemodynamics were also observed. No changes occurred in three patients receiving haemofiltration alone. CONCLUSIONS: Albumin dialysis produces clinically significant, acute reduction in portal pressure but the mechanism by which this effect is achieved is not clear. Our results suggest that MARS may be a useful adjunct in management of portal hypertension, particularly in patients with severe AH with associated organ failure.     

Benign recurrent intrahepatic cholestasis with secondary renal impairment treated with extracorporeal albumin dialysis

Benign recurrent intrahepatic cholestasis (BRIC) is a rare autosomal recessive condition characterized by intermittent episodes of pruritis and jaundice that may last days to months. Treatment is often ineffective and symptoms, particularly pruritis, can be severe. Extracorporeal albumin dialysis (molecular adsorbent recycling system, MARS) is a novel treatment which removes albumin bound toxins including bilirubin and bile salts. We describe a case of a 34-year-old man with BRIC and secondary renal impairment who, having failed standard medical therapy, was treated with MARS. The treatment immediately improved his symptoms, renal and liver function tests and appeared to terminate the episode of cholestasis. We conclude that MARS is a safe and effective treatment for BRIC with associated renal impairment.     

Targeting Albumin Binding Function as a Therapy Goal in Liver Failure: Development of a Novel Adsorbent for Albumin Dialysis

Liver failure results in impaired hepatic detoxification combined with diminished albumin synthesis and is associated with secondary organ failure. The accumulation of liver toxins has shown to saturate albumin binding sites. This was previously demonstrated by an in vitro test for albumin binding capacity (ABiC) that has shown to inversely correlate with the established MELD (Model for End-Stage Liver Disease) score. In this study, we introduced a new adsorbent material for albumin dialysis treatments that improves albumin binding capacity. The new charcoal adsorbent was developed by an evolutionary test schedule. Batch testing of charcoals was performed as steady-state experiments. The charcoal reflecting the highest increase in albumin binding capacity was then introduced to kinetic models: Perfusion tests were designed to evaluate adsorption capacity and kinetics for liver failure marker toxins. A dynamic recirculation model for liver failure was used for upscaling and comparison against conventional MARS adsorbents as the gold standard in an albumin dialysis setting. Batch tests revealed that powdered activated Hepalbin charcoal displayed the highest ABiC score. Hepalbin charcoal also demonstrated higher adsorptive capacity and kinetics for liver failure marker toxins as determined by perfusion tests. These findings translated to tests of upscaled adsorbents in a dynamic model for liver failure: upscaled Hepalbin adsorbent removes bile acids, direct bilirubin and indirect bilirubin significantly better than MARS adsorbents and significantly increases ABiC. The novel adsorbent Hepalbin offers a significant improvement over both MARS adsorbents concerning liver failure marker toxin removal and ABiC improvement.     

Albumin Dialysis Molecular Adsorbents Recirculating System: Impact of Dialysate Albumin Concentration on Detoxification Efficacy

Albumin dialysis with the molecular adsorbent recirculating system (MARS) or single pass albumin dialysis (SPAD) uses human serum albumin (HSA) as an addendum of the dialysate fluid. The purpose of this in vitro study was to evaluate the impact of the dialysate albumin concentration on removal efficacy. Heparinized human plasma (3 L/test) was spiked with creatinine (1000 mg/L), unconjugated bilirubin (100 mg/L), chenodeoxycholic acid (CDCA) (100 mg/L), and diazepam (3 mg/L). The MARS albumin circuit was primed with different amounts of HSA (150, 100, 60, and 40 g). The plasma, albumin, and dialysate flow rates were 200, 200, and 40 mL/min, respectively. Clearances were calculated based on repeated sampling during the experiments, which lasted 480 min. The effective HSA concentrations in the dialysate were 175, 115, 77, and 46 g/L, respectively. They decreased over treatment time to 147, 99, 63, and 41 g/L, respectively, due to surface adsorption. The plasma–HSA concentration remained unchanged over time in all experiments (average 39 g/L). The creatinine clearance was not impacted by dialysate HSA concentration. For the albumin‐bound markers a clear correlation between HSA‐concentration and clearance was demonstrated with the highest clearances for the 100 and 150 g HSA experiments. The 100 g HSA setup appeared to be the one with best cost–benefit ratio, resulting in clearances (after 1 h of treatment) of 31 mL/min creatinine, 0.3 mL/min unconjugated bilirubin, 11 mL/min CDCA, and 35 mL/min diazepam. Low albumin concentrations, such as in SPAD, result in low clearance rates for albumin‐bound substances. The optimal clearances in these experiments were reached with a priming dose of 100 g HSA.     

分子吸附再循环系统治疗肝衰竭多脏器功能不全

目的 评价分子吸附再循环系统(MARS)对肝衰竭合并多脏器功能不全(MODS)患者的治疗作用和机制。方法 24例肝衰竭合并MODS患者进行了60次6～24 h的MARS治疗。结果 MARS治疗可有效清除白蛋白结合毒素和水溶性毒素,降低一氧化氮(NO)及肿瘤坏死因子-α,白细胞介素-6、-8,和γ干扰素等细胞因子水平,改善肝性脑病、肾功能、呼吸功能以及血流动力学紊乱,序贯性脏器衰竭评估(SOFA)的计分由9.72±1.89降至6.98±2.34,24例危重肝衰竭患者中9例痊愈出院或接受肝移植,总存活率为37.5％。结论 MARS人工肝支持系统对肝衰竭合并MODS有肯定的治疗作用,其疗效除与全面清除肝衰竭蓄积的毒素外,尚与降低NO及细胞因子水平有关。     

Albumin Dialysis in Liver Failure: Comparison of Molecular Adsorbent Recirculating System and Single Pass Albumin Dialysis—A Retrospective Analysis

Despite improvement in critical care, liver failure is still associated with high mortality. Therapeutic concepts are aimed at restoring endogenous liver function or to bridge the time to liver transplantation. In addition to standard medical treatment, extracorporeal liver support with albumin dialysis is used for this purpose. The aim of this study was to analyze the efficacy of single pass albumin dialysis (SPAD) in comparison to the molecular adsorbent recirculating system (MARS) in patients treated at our university hospital intensive care unit between July 2004 and August 2008. In this retrospective analysis we studied patients presenting with liver failure who were treated with albumin dialysis. Laboratory parameters, daily health scoring, the number of transfusions, and mortality were recorded. The (paired) t‐test, Mann–Whitney U‐test, and Wilcoxon test were used for statistical analysis. In all, 163 albumin dialysis treatments, 126 with MARS and 37 with SPAD, in 57 patients were performed. MARS resulted in a significant decrease in bilirubin (?38 ± 66.5 µmol/L from a baseline of 301 ± 154.6 µmol/L), γ‐glutamyltransferase (γ‐GT), alanine aminotransferase, creatinine, and urea. SPAD resulted in a significant decrease in bilirubin (?41 ± 111.2 µmol/L from a baseline of 354 ± 189.4 µmol/L) and γ‐GT, while lactate levels increased. No differences in the need for blood transfusion, health scoring, or mortality between the two treatment modalities were detected. This retrospective analysis suggests equal efficacy of MARS and SPAD; however, prospective assessment to further define the role of SPAD in the treatment of acute or acute‐on‐chronic liver failure is needed.     

Albumin dialysis: effective removal of copper in a patient with fulminant Wilson disease and successful bridging to liver transplantation: a new possibility for the elimination of protein-bound toxins

BACKGROUND: Acute liver failure may be the first manifestation of Wilson disease. If copper elimination fails, liver transplantation is the only remaining therapeutic option. Albumin dialysis, a new method for the removal of protein-bound toxins, was performed in a patient with fulminant Wilson disease. METHODS: An 18-year-old man with Wilson disease presented with hyperacute liver failure, hepatic encephalopathy III, oligo-anuric renal failure, haemolytic anaemia, rhabdomyolysis, pancreatitis and thrombocytopenia. He was treated with albumin dialysis using a 44 g/l albumin-containing dialysate and a slow dialysate flow rate (1-2 l/h). The other details of the technique used are similar to routine continuous veno-venous haemodiafiltration. RESULTS: One hundred and five milligrams of copper were removed by albumin dialysis within the first six treatments, resulting in normalisation of blood-copper levels. Successful treatment of the multiorgan failure was achieved. Hepatic encephalopathy improved within 2 days. The patient initially refused liver transplantation. Therefore 35 additional albumin dialysis treatments were performed. Forty-three grams of bilirubin (an indicator of detoxified substances in the liver) and 196 mg of copper were removed. Multiorgan failure, in particular hepatic encephalopathy, did not recur during 59 days of treatment. Eventually, the patient agreed to liver transplantation and that was successful. CONCLUSION: Albumin dialysis is a new method for the effective treatment of fulminant Wilson disease, resulting in the removal of protein-bound toxins copper and bilirubin. It may serve as a new treatment option in hyperacute liver failure of other origin, acting as an extracorporeal detoxifier.     

Albumin liver dialysis as pregnancy-saving procedure in cholestatic liver disease and intractable pruritus

Progressive familial intrahepatic cholestasis type 3 （PFIC3） is a rare cholestatic liver disease. Such liver disease can get worse by female hormone disorder. Albumin dialysis or Molecular Adsorbent Recirculating System （MARS） has been reported to reverse severe cholestasis-linked pruritus. Here, we report the first use of MARS during a spontaneous pregnancy and its successful outcome in a patient with PFIC3 and intractable pruritus. Albumin dialysis could be considered as a pregnancy-saving procedure in pregnant women with severe cholestasis and refractory pruritus.