Specific sorbent of apolipoprotein B-containing lipoproteins for plasmapheresis. Characterization and experimental use in hypercholesterolemic rabbits

Integrated Dual-Mode Chromatography to Enrich Extracellular Vesicles from Plasma

Purifying extracellular vesicles (EVs) from complex biological fluids is a critical step in analyzing EVs molecularly. Plasma lipoprotein particles (LPPs) are a significant confounding factor as they outnumber EVs >104 -fold. Given their overlap in size, LPPs cannot be completely removed using standard size-exclusion chromatography. Density-based separation of LPPs can be applied but is impractical for routine use in clinical research and practice. Here a new separation approach, known as dual-mode chromatography (DMC), capable of enriching plasma EVs, and depleting LPPs is reported. DMC conveniently integrates two orthogonal separation steps in a single column device: i) size exclusion to remove high-density lipoproteins (HDLs) that are smaller than EVs; and ii) cation exchange to clear positively charged ApoB100-containing LPPs, mostly (very) low-density lipoproteins (V)LDLs, from negatively charged EVs. The strategy enables DMC to deplete most LPPs (>97% of HDLs and >99% of (V)LDLs) from human plasma, while retaining EVs (>30% of input). Furthermore, the two-in-one operation is fast (15 min per sample) and equipment-free. With abundant LPPs removed, DMC-prepared samples facilitate EV identification in imaging analyses and improve the accuracy for EV protein analysis.

Familial Hypercholesterolemia and Lipoprotein Apheresis

Lipoprotein apheresis has been developed as the treatment for refractory familial hypercholesterolemia (FH) to remove low-density lipoprotein (LDL), which is the main pathogenic factor. Currently, three procedures are available in Japan, including the plasma exchange, double-membrane filtration, and selective LDL adsorption. Selective LDL adsorption, which was developed in Japan, has been one of the most common treatment methods in the world. Lipoprotein apheresis enabled the prevention of atherosclerosis progression even in homozygous FH (HoFH) patients. However, in our observational study, HoFH patients who started lipoprotein apheresis in adulthood had a poorer prognosis than those who started in childhood. Therefore, HoFH patients need to start lipoprotein apheresis as early as possible. Although the indication for lipoprotein apheresis in heterozygous FH (HeFH) patients has been decreasing with the advent of strong statins, our observational study showed that HeFH patients who discontinued lipoprotein apheresis had a poorer prognosis than patients who continued apheresis therapy. These results suggest that it is beneficial for very-high-risk HeFH patients to be treated by lipoprotein apheresis even if their LDL cholesterol is controlled well by lipid-lowering agents. Since launching a new class of lipid-lowering agents, proprotein convertase subtilisin/kexin type 9 (PCSK9) antibody and microsome triglyceride transfer protein inhibitors, the indication for lipoprotein apheresis in FH has been changing. However, despite the development of these drugs, lipoprotein apheresis is still an option with a high therapeutic effect for FH patients with severe atherosclerotic cardiovascular disease.

Therapeutic Plasma Adsorption. A Review

Alternative techniques to the traditional plasma exchange are emerging in clinical practice for the treatment of different pathological conditions, particularly autoimmune diseases. Filtration is a technique used to separate blood cells from plasma, which may be further “treated” with other filters or columns. The case for cascade filtration and absorption onto a column is becoming stronger and stronger and the patient population is increasing. Alongside the “historical” techniques of adsorption onto a column, new systems (pairs of self-regenerating columns) and new products (columns with dextran sulphate, tryptophane, anti-human lipoprotein antibodies) are now available. Protein A in particular seems to open up new horizons; in therapeutic plasmapheresis, there are two versions, one Swedish and the other American, based on different theoretical premises and obtaining different results, with different biocompatibilities but good clinical results.

Adsorption of Lipoprotein Containing Apolipoprotein-B through Plasma Separation for Treatment of Familial Hypercholesterolemia

For the treatment of familial hypercholesterolemia, Liposorber LA-40 was clinically applied. The Liposorber is a commercially developed affinity adsorbent for plasma perfusion which selectivily adsorbs low density lipoproteins and very low density lipoproteins and is specially designed for plasmapheretic treatment of hypercholesterolemia.

The Liposorber column, containing activated cellulose beads having an affinity for liporpotein containing apolipoprotein-B, has an excellent adsorption capacity, excellent selectivity, minimum albumin loss. This new apheresis system was applied to 2 clinical cases.

After seven months of trial perfusion every 2 weeks, patient condition was good, with a level of total cholesterol under 300 mg/dl. No replacement fluids were given during or after treatment.

In this paper, clinical results of these patients were shown and the mechanism of adsorption of this specific adsorbent was discussed.

Changes in Coagulation Factors by Passage through a Dextran Sulfate Cellulose Column during Low-Density Lipoprotein Apheresis

To determine the extent of adsorption of coagulation factors by a dextran sulfate cellulose column used for selective removal of low-density lipoprotein (LDL), various coagulation factors were measured before and after application to the column during LDL apheresis. The column almost completely adsorbed many coagulation factors. Although the bradykinin concentration was markedly increased by passing the plasma through the column, this increment was suppressed by nafamostat mesilate which inhibits the initial contact phase of the intrinsic coagulation pathway. The von Willebrand factor, which forms a complex with factor VIII in plasma, is reduced in apheresis with nafamostat mesilate to the same extent as in apheresis without nafamostat mesilate. Thus, coagulation factors seem to be adsorbed by different mechanisms which include activation of the initial contact phase by the negative charges of dextran sulfate and concomitant adsorption with the phospholipid portion of lipoproteins containing apolipoprotein B or with von Willebrand factor.

Lipoprotein apheresis to treat elevated lipoprotein (a)

An elevated plasma concentration of lipoprotein (a) [Lp(a)] is an independent risk factor for cardiovascular disease. Life style modification and currently available drugs either fail to effectively lower plasma Lp(a) levels or do not result in clinical benefit. However, lipoprotein apheresis is very efficient in decreasing Lp(a) concentrations. A single apheresis session can acutely decrease Lp(a) by approximately 60-75%, and apheresis performed weekly or biweekly results in considerably decreased mean interval concentrations (approximately 25-40% reduction). While most apheresis systems (heparin-induced extracorporeal LDL precipitation, direct adsorption of lipoproteins, lipoprotein apheresis with dextran-sulfate, lipid filtration, immunoadsorption) decrease LDL and Lp(a), Lipopac is specific and only decreases Lp(a). Lp(a) apheresis is expensive and time consuming, but associated with very few side effects. Two randomized controlled trials give conflicting consults with respect to the effect on angiographic changes. Retrospective analyses indicate that regular apheresis translates into clinical benefit in patients with elevated Lp(a), but adequate randomized controlled trials are lacking.

Lipoprotein-apheresis reduces circulating microparticles in individuals with familial hypercholesterolemia

Lipoprotein-apheresis (apheresis) removes LDL-cholesterol in patients with severe dyslipidemia. However, reduction is transient, indicating that the long-term cardiovascular benefits of apheresis may not solely be due to LDL removal. Microparticles (MPs) are submicron vesicles released from the plasma membrane of cells. MPs, particularly platelet-derived MPs, are increasingly being linked to the pathogenesis of many diseases. We aimed to characterize the effect of apheresis on MP size, concentration, cellular origin, and fatty acid concentration in individuals with familial hypercholesterolemia (FH). Plasma and MP samples were collected from 12 individuals with FH undergoing routine apheresis. Tunable resistive pulse sensing (np200) and nanoparticle tracking analysis measured a fall in MP concentration (33 and 15%, respectively; P < 0.05) pre- to post-apheresis. Flow cytometry showed MPs were predominantly annexin V positive and of platelet (CD41) origin both pre- (88.9%) and post-apheresis (88.4%). Fatty acid composition of MPs differed from that of plasma, though apheresis affected a similar profile of fatty acids in both compartments, as measured by GC-flame ionization detection. MP concentration was also shown to positively correlate with thrombin generation potential. In conclusion, we show apheresis nonselectively removes annexin V-positive platelet-derived MPs in individuals with FH. These MPs are potent inducers of coagulation and are elevated in CVD; this reduction in pathological MPs could relate to the long-term benefits of apheresis.

Lipoprotein apheresis standard for apheresis competence centers--an updated synthesis and amendment to pre-existing standards

With several techniques of selective apheresis treatment, some of which have been established for over 30 years, severe and pharmacologically unmanageable dyslipidemia can be treated successfully. The long-term lowering of LDL cholesterol and lipoprotein(a) by 60-80 percent, together with pleiotropic effects, allow for significant risk reduction in otherwise progressive chronic atherosclerotic disease, i.e. chronic coronary artery disease in most apheresis patients, and improvement of quality of life. For various reasons, worldwide only an estimated 2500 patients, among them 1400 to 1500 in Germany, are regularly treated by apheresis. This relatively small number of apheresis patients in Germany is being cared for in more than 200 centers, by more than 750 physicians approved for extracorporeal treatment, resulting in unraveling of expertise and diversity of treatment strategies instead of the needed concentration. Here we present a comprehensive standard for competence centers in apheresis treatment, which is an updated synthesis and amendment to previously published standards, based on the experience from more than 30,000 apheresis treatments in our own center. The presented standard provides a guideline for apheresis treatments, comprising all procedures, indications, detailing the application procedure, as well as suggestions for supportive care in extracorporeal therapy. In the absence of large studies of sufficient quality, this standard represents our "good clinical practice" and refers the "best available evidence", providing the indispensable basis for working in an apheresis center. The apheresis standard also aims to contribute to quality assurance, another intention is to increase the acceptance of this valuable treatment, with a view to admitting more patients in need to apheresis programs, on the basis of reliable cost reimbursement.

Role of lipid apheresis in changing times

During the last decades, LDL-apheresis was established as an extracorporeal treatment option for patients with severe heterozygous or homozygous familial hypercholesterolemia (FH) that is resistant to conventional treatment strategies such as diet, drugs, and changes in lifestyle. Nearly half a century ago, the first LDL-apheresis treatment was performed by plasma exchange in a child with homozygous FH. At the beginning of the 1970s, the clinical advantage of regular extracorporeal LDL-elimination was demonstrated in siblings suffering from homozygous FH. These findings encouraged researchers especially from Germany and Japan to develop extracorporeal devices to selectively eliminate LDL-cholesterol in the 1980s. Although the selectivity of the currently available LDL-apheresis devices is different, the efficacy of LDL-elimination during a single treatment is rather similar and ranges between 55 and 65 % of the pretreatment LDL plasma concentration.In the 1990s, the patients regularly treated by extracorporeal LDL-elimination, diet, and drugs were included in regression studies assessed by angiography. It was shown that the combined treatment with LDL-apheresis, diet, and drugs resulted in less progression of coronary lesions than drugs and/or diet alone. However, although a tendency was evident, results did not reach criteria for significance. During the last decade, apheresis registries were established to collect data on efficiency, safety, and clinical outcome of regular long-term LDL-apheresis. The evaluation of registry data will certainly permit further insights in the therapeutic benefit of this expensive and time-consuming therapeutic approach. Furthermore, the future of LDL-apheresis will depend upon the availability of highly efficient new drugs and molecular genetic approaches such as RNA silencing of the apoB gene, whereas the liver transplantation and gene therapy of the LDL-receptor deficiency will not replace LDL-apheresis in severe familial hypercholesterolemia in the near future.

Successful treatment of homozygous familial hypercholesterolemia using cascade filtration plasmapheresis

OBJECTIVE

The aim of this study was to report the efficacy of low-density lipoprotein cholesterol (LDL-C) apheresisusing a cascade filtration system in pediatric patients with homozygous familial hypercholesterolemia (FH), and toclarify the associated adverse effects and difficulties.

MATERIAL AND METHODS

LDL-C apheresis using a cascade filtration system was performed in 3 pediatric patientswith homozygous FH; in total, 120 apheresis sessions were performed.

RESULTS

Cascade filtration therapy significantly reduced the mean LDL-C values from 418 ± 62 mg/dL to 145 ± 43 mg/dL (p= 0.011). We observed an acute mean reduction in the plasma level of total cholesterol (57.9%), LDL-C (70.8%),and high-density lipoprotein cholesterol (HDL-C) (40.7%). Treatments were well tolerated. The most frequent clinicaladverse effects were hypotension in 3 sessions (2.5%), chills (1.7%) in 2 sessions, and nausea/vomiting in 3 sessions(2.5%).

CONCLUSION

Our experience using the cascade filtration system with 3 patients included good clinical outcomes andlaboratory findings, safe usage, and minor adverse effects and technical problems.

CONFLICT OF INTEREST

None declared.

Long-term effects of LDL apheresis in patients with severe hypercholesterolemia

Familial hypercholesterolemia (FH) is an inherited disorder of lipoprotein metabolism involving mutations in the LDL receptor (LDL-R). Patients with mutation in one (heterozygous) or both (homozygous) genes have markedly elevated LDL cholesterol and are at increased risk for coronary heart disease (CHD). Aggressive lipid lowering is required for homozygous and many heterozygous FH patients. This often involves LDL-apheresis, where LDL and other apo-B containing lipoproteins are selectively removed from the plasma. We have retrospectively studied 34 patients treated with biweekly LDL-apheresis at the Hospital of the University of Pennsylvania. In our patient population, adverse events were uncommon and rarely resulted in shortened treatment time. There was a dramatic decrease in the relative risk of cardiovascular events and cardiovascular interventions in patients treated with LDL-apheresis for an average of 2.5 years. Some but not all patients had long-term reduction in their LDL levels as a result of LDL-apheresis, suggesting that time-averaged reduction in LDL and/or LDL:HDL ratios were responsible for clinical improvement. These data support the use of LDL-apheresis in patients with FH, as well as medication-intolerant patients that have elevated LDL cholesterol despite maximal pharmacological treatment.

Analysis of protein absorbed by LDL column (Liposorber) with special reference to complement component factor D

BACKGROUND

A dextran sulfate column (Liposorber) has been developed and proven effective in LDL apheresis for removing LDL from patients with hyperlipemia. Chronic renal failure (CRF) patients with arteriosclerosis obliterans (ASO) treated with Liposorber have been shown good results.

METHODS

We analyzed proteins absorbed by Liposorber in CRF patients with ASO by means of 2-dimensional electrophoresis and found some noteworthy protein spots. One of these proteins was purified by Sephacryl S-100 column and DEAE Sepharose fast flow column chromatography.

RESULTS

The purified protein was finally identified as complement factor D by Western blotting. The average of recovery amount from three experiments was 6.5 mg. The total recovered amount of factor D was calculated to be about 21.7% out of the estimated amount of factor D in the plasma of CRF patients with ASO receiving LDL apheresis using Liposorber.

CONCLUSIONS

These results indicate that Liposorber absorbs factor D remarkably well.

Brief history of low-density lipoprotein apheresis

Low-density lipoprotein (LDL) apheresis is a technology used to remove LDL from hypercholesterolemic patients. The technique includes both specific and non-specific removal of LDL such as exchange of the whole plasma and selective adorption of LDL. The therapy is mainly used for homozygotes and in severe cases of heterozygotes of familial hypercholesterolemia (FH) (LDL receptor deficiency). Since HMG-CoA reductase inhibitors, statins, were introduced in late 1980s, the number of patients who required LDL apheresis decreased, in particular for the heterozygous FH patients with more recent powerful statins. Modern LDL apheresis technology is very sophisticated and perhaps expensive, while the number of the patients is very limited. Several companies developed the instruments for this procedure, but found the market is limited. Nevertheless, these companies are expected to remain in the market for an ethical reasons, as the patients using their LDL apheresis machines are entirely dependent on them for their life.

Long-term effect of low-density lipoprotein apheresis in patients with homozygous familial hypercholesterolemia

Patients that are homozygous for familial hypercholesterolemia (FH) exhibit severe hypercholesterolemia, cutaneous and tendon xanthomas and premature atherosclerosis beginning in childhood. They are resistant to drug therapy and low-density lipoprotein (LDL) apheresis is the practical treatment. Here we review the technique of LDL apheresis treatment, the long-term effects of LDL apheresis, the effect of apheresis on pregnancy, and the drugs that have proven beneficial in patients with homozygous FH. We also record our experiences of treating eight homozygous FH patients using the LDL apheresis treatment. Among the eight patients, one has been free from cardiovascular disease and two patients have each regressed once. In two patients, aortic valve stenosis developed and the other two patients died for acute myocardial infarction. Furthermore, two patients delivered healthy babies in spite of coronary artery disease. Thus, LDL apheresis therapy has the possibility of preventing the progression of atherosclerosis, but the prognosis assessed by long-term observation is still not satisfactory. A recent clinical trial showed some efficacy of the combination therapy of LDL apheresis and atorvastatin for reducing serum cholesterol levels in homozygous FH, suggesting that this combination therapy may be useful for prevention of atherosclerosis in patients homozygous for FH.

Long-term effect of low-density lipoprotein apheresis in patients with heterozygous familial hypercholesterolemia

Clinical efficacy and safety of the therapeutic tool which directly removes LDL particles from circulation (LDL apheresis) have already been established in the treatment for refractory hypercholesterolemia in patients with familial hypercholesterolemia (FH). Two clinical studies with event-based assessment have demonstrated remarkably beneficial outcomes of long-term LDL apheresis using dextran sulfate cellulose columns plus adjunctive cholesterol-lowering drug therapy in the prevention of cardiovascular events in heterozygous FH with coronary artery disease. The results of several studies with angiographic and ultrasound-based assessment indicate a possible role for LDL apheresis in restructuring and stabilization of atherosclerotic lesions. These clinical improvements caused by LDL apheresis in heterozygous FH support the efficacy and importance of aggressive cholesterol-lowering therapy for secondary prevention of atherosclerotic cardiovascular disease in hypercholesterolemic patients.

LDL apheresis

Low density lipoprotein (LDL) apheresis provides a safe and effective means of treating patients with homozygous familial hypercholesterolaemia (FH). It also has a role in preventing the progression of coronary artery disease in heterozygotes and others with severe dyslipidaemia who are refractory to or intolerant of high doses of lipid-lowering drugs. Established methods involve either adsorption of apolipoprotein B-containing lipoproteins by affinity columns containing anti-apolipoprotein B antibodies or dextran sulphate, or their precipitation at low pH by heparin, in each instance after first separating plasma from blood cells with a cell separator. The most recently developed method enables lipoproteins to be adsorbed directly from whole blood, using polyacrylate columns. All 4 methods have proved to be similarly efficient when used weekly or biweekly to lower LDL cholesterol and Lp(a) without unduly reducing HDL cholesterol. Economic constraints restrict the use of LDL apheresis to the treatment of potentially fatal disorders such as FH, where there is clear evidence of benefit compared with conventional therapy. Widening the indications to include the treatment of other dyslipidaemic disorders such as steroid-resistant nephrotic syndrome, post-transplant donor vessel disease, stroke and prevention of re-stenosis after coronary angioplasty requires evidence from controlled trials that is currently lacking.

Apheresis technology for prevention and regression of atherosclerosis

Familial hypercholesterolemia (FH) is a congenital disorder of cholesterol metabolism, which is due to a deficiency in low-density lipoprotein (LDL) receptors. The homozygous form of FH is especially liable to coronary artery disease (CAD) in youth because of the very high LDL-cholesterol levels. It is resistant to drug therapy, and LDL-apheresis is the only practical way of treatment for these patients. Some patients with heterozygous FH also have high LDL-cholesterol levels that cannot be brought down into the optimum range by any combination drug therapy. We have treated or are treating 10 homozygous and 28 heterozygous FH patients in our hospital or in affiliated hospitals expert in blood purification. Among the 10 homozygous patients, 2 died of myocardial infarction. Only one young female patient is still free of symptoms, and the other patients have been suffering from regurgitation through the aortic valve although they have not experienced myocardial infarction. Rapid rebound of LDL-cholesterol after each apheresis treatment limits the period during which LDL-cholesterol is in the optimum range. The use of atorvastatin at a high dose (40 mg/day) was attempted to suppress this rebound. In contrast with good results in receptor-defective-type patients, receptor-negative-type patients did not show a response in LDL-cholesterol levels to the statin therapy although there was a slight increase in high-density lipoprotein (HDL)-cholesterol with a decrease in very-low-density lipoprotein-triglyceride and -cholesterol. Follow-up study of the patients with heterozygous FH revealed that LDL-apheresis was effective in lengthening the life expectancy of the patients with pre-existing CAD, especially those who had received intervention coronary artery bypass grafting (CABG) or percutaneous transluminal coronary angioplasty (PTCA). It was also shown that the use of probucol in combination with LDL-apheresis was effective in reducing coronary events as shown by the necessity of CABG or PTCA. Clinical data on the effect of LDL-apheresis, recently reported from some other institutions in Japan, will also be reviewed.

Development of a novel polycationic adsorbent for cryogel removal

Cryogel, prevalent in the plasma of rheumatism patients, is a plasma fibronectin (pFN)-extra domain A containing FN (EDA(+)FN)-fibrinogen (Fbg) complex formed by adding heparin (HP) at a low temperature (4 degrees C). Although EDA(+)FN does not usually exist in normal plasma, its prevalence in rheumatic patients causes cryogelation in plasma. Removal of cryogel is thus a promising and novel approach to treating rheumatism. As HP-EDA(+)FN aggregate, which is induced by the main component of cryogel, is considered to be an anion, cationic materials capable of eliminating this anionic conjugate were innovated in this study. We found that an amino group density of 100-130 micromol/g (dry weight) of adsorbents prompted selective adsorption of the EDA(+)FN-HP complex. Elimination of EDA(+)FN as high as 80% accompanied by removal of the components of total FN (pFN) (10%) and Fbg (10%) in the model patient plasma was established.

Ellipsometry Studies of Lipoprotein Adsorption

The adsorption of a number of lipoproteins, i.e., low-density lipoprotein (LDL), oxidized LDL (oxLDL), high-density lipoprotein (HDL), and lipoprotein (a), at silica and methylated silica as well as at the latter surface modified through adsorption of proteoheparan sulfate, was investigated with in situ ellipsometry at close to physiological conditions. It was found that LDL, oxLDL, HDL, and lipoprotein (a) all adsorbed more extensively at silica than at methylated silica. Upon exposure of the methylated silica surface to proteoheparan sulfate, this proteoglycan adsorbs through its hydrophobic moiety, thereby forming a layer similar to that in the biological system, with the polysaccharide chains forming brushes oriented toward the aqueous solution. Analogous to the biological system, both lipoprotein (a) and LDL were found to deposit at such surfaces, the latter particularly in the simultaneous presence of Ca(2+). After HDL pre-exposure, however, no LDL deposition was observed, even at high LDL and Ca(2+) concentrations. These findings correlate well with those obtained from clinical investigations on risk factors for atherosclerosis. Copyright 2000 Academic Press.

Evaluation of adsorption selectivity dextran sulfate bound cellulose beads for the removal of anti-DNA antibodies

The purpose of this study was to clarify the basic adsorption selectivity characteristics of dextran sulfate (DS) columns (Selesorb, Kaneka Corporation, Osaka, Japan). Recovery rates of blood chemical components, hormones, coagulation factors, and antinuclear antibodies (anti-SS-A, SS-B, Sm, Scl-70, and RNP antibody) in vitro were assessed by mixing normal volunteers' or patients' sera with DS bound cellulose beads. For tested blood chemical components other than triglyceride and total cholesterol, the recovery rate was not changed significantly by incubation. No significant changes in hormone levels resulted from incubation. Among coagulation factors, the activities of antithrombin III, plasminogen, and factors V, VIII, IX, XI, and XII were significantly reduced by incubation. Among antinuclear antibodies tested, anti-SS-A and anti-RNP were absorbed to some extent, but not anti-SS-B, Sm, or Scl-70 antibodies. Taking into account these characteristics, apheresis therapy using a DS column should be performed.

Long-term efficacy of low-density lipoprotein apheresis on coronary heart disease in familial hypercholesterolemia. Hokuriku-FH-LDL-Apheresis Study Group

Familial hypercholesterolemia (FH) is characterized by severe hypercholesterolemia and premature coronary heart disease (CHD). The lower the plasma cholesterol level, the more likely it is that CHD can be prevented or retarded; aggressive cholesterol-lowering therapies may be indicated for FH patients with CHD. This study describes the long-term (6 years) safety and efficacy of intensive cholesterol-lowering therapies with low-density lipoprotein (LDL) apheresis in heterozygous FH patients with CHD. One hundred thirty heterozygous FH patients with CHD documented by coronary angiography had been treated by cholesterol-lowering drug therapy alone (n=87) or LDL apheresis combined with cholesterol-lowering drugs (n=43). Serum lipid levels and outcomes in each treatment group were compared after approximately 6 years. Both treatment groups had significant reductions in serum cholesterol, LDL cholesterol, and high density lipoprotein cholesterol levels. LDL apheresis significantly reduced LDL cholesterol levels from 7.42+/-1.73 to 3.13+/-0.80 mmol/L (58%) compared with group taking drug therapy, from 6.03+/-1.32 to 4.32+/-1.53 mmol/L (28%). With Kaplan-Meier analyses of the coronary events including nonfatal myocardial infarction, percutaneous transluminal coronary angioplasty, coronary artery bypass grafting, and death from CHD, the rate of total coronary events was 72% lower in the LDL-apheresis group (10%) than in drug therapy group (36%) (p=0.0088). It is concluded that LDL-apheresis is effective as treatment of CHD in FH heterozygotes, and may become the therapy of choice in severe types of FH.

The effect of selective low-density lipoprotein apheresis on plasma lipoperoxides and antioxidant vitamins in familial hypercholesterolemic patients

Familial hypercholesterolemia (FH) is an autosomal dominant genetic disorder characterized by a lifelong elevation in the concentration of low-density lipoprotein (LDL) bound cholesterol in blood by cholesterol deposits and by early coronary artery disease. The LDL apheresis technique has been introduced with the goal of reducing LDL cholesterol levels, thereby preventing the development of atherosclerosis. The literature on LDL apheresis reports 2 different facets, the therapeutic aspect associated with the lessening of LDL concentration and the initiation of a peroxidation process associated with the biocompatibility of the artificial membrane. Lipid and protein peroxidation gives rise to toxic and atherogenic hydroperoxide, mostly lipid hydroperoxides, and derivative compounds, which may offset the benefit of the procedure. In this paper, plasma hydroperoxide levels are determined along with the elevation of the serum and LDL antioxidant status in hypercholesterolemic patients before and following repeated LDL apheresis sessions. Hydroperoxide concentration has been expressed both in terms of plasma volume and LDL concentration. A highly significant increase in LDL lipid hydroperoxides is demonstrated when expressed in terms of LDL concentration and is associated with the LDL apheresis procedure. The usefulness of antioxidant supplementation in LDL apheresis is discussed.

A new low density lipoprotein (LDL) adsorbent

Crosslinked O-Carboxymethyl (O-CM) Chitosan beads were prepared by the reaction of O-CM Chitosan with glutaraldehyde solution. Results in vitro experiments with this new developed LDL adsorbent are presented. This adsorbent is capable of cutting down LDL-Cholesterol without significantly affecting HDL and TP (Total Proteins) levels in the plasma.

Apheresis technology for prevention and regression of atherosclerosis: an overview

Low density lipoprotein (LDL) apheresis is at present one method of treatment in homozygous cases of familial hypercholesterolemia (FH). It is also effective in the prevention of the development of coronary atherosclerosis in patients with heterozygous FH and other types of mild hypercholesterolemia, leading to the regression of the stenosing lesions. In this paper, an overview is presented on the development of the devices for LDL apheresis and its short- and long-term effects on FH mainly based upon experience with the Liposorber system. LDL apheresis has served to protect the lives of patients from life threatening diseases like myocardial infarction although observations for more than 10 years in some laboratories have shown that the progression of atherosclerosis has taken place in many patients, and more importantly, the involvement of the aortic valve with calcification has developed, especially in patients who had homozygous FH, making this the most obstinate complication of FH. Therefore, more aggressive treatment or the combination of LDL apheresis with other therapies is required in the future. LDL apheresis has also been approved for the treatment of glomerulosclerosis and arteriosclerosis obliterans.

Effect of LDL-apheresis on the pharmacokinetics of the lipophilic antilipidemic agent probucol

The effect of LDL-apheresis on the pharmacokinetics of antilipidemic agents has not been evaluated thoroughly. In this study, we investigated the effect of LDL-apheresis on the pharmacokinetics of probucol, a lipophilic antilipidemic agent, by studying its distribution and changes in the blood concentration of probucol after LDL-apheresis. The concentrations of lipoproteins were measured before and after LDL-apheresis in eight patients with familial hypercholesterolemia taking probucol. Concentrations of probucol in the various lipoprotein fractions and plasma were measured by HPLC. The serum concentrations of probucol before and after LDL-apheresis were 39.8 +/- 3.3 and 16.5 +/- 1.6 micrograms/ml, and the correlation coefficient between the changes in the serum probucol concentration and those in the serum cholesterol concentration before and after LDL-apheresis was significant (r = 0.73, P < 0.01). Changes in the probucol and cholesterol concentrations after LDL-apheresis were mainly found in the LDL fraction. The calculated reductions in the serum contents of probucol and cholesterol were similar to the contents of probucol and cholesterol in the irrigation fluid of the dextran sulfate column. These data suggest that changes of probucol concentration in plasma by LDL-apheresis are mainly due to reductions in the LDL fraction.

Isolation of low density lipoprotein subfraction containing apolipoprotein B-like protein from Japanese eel Anguilla japonica plasma using dextran sulfate cellulose

Japanese eel (Anguilla japonica) possessed a unique lipoprotein profile in their plasma, reflecting high utilization of lipids. Low density lipoprotein (LDL) fraction isolated at the densities from 1.006 to 1.085 g/ml comprised the heterogeneous components with molecular weight (Mr) 1200 K, 470 K, and 250 K. LDL subfraction with Mr 1200 K was completely adsorbed to dextran sulfate cellulose (DSC) column which had been developed for LDL apheresis treatment of the patients with familial hypercholesterolemia, while LDL subfractions with Mr 470 K and 250 K had no affinity for the DSC column. LDL subfractions with Mr 470 K and 250 K were floated and settled, respectively, by centrifuging the unbound fraction of DSC column at a density of 1.063 g/ml. LDL subfraction with Mr 1200 K possessed apolipoprotein (apo) B-like protein of Mr 230 K, while apo A-I- and A-II-like proteins of Mr 25 K and 14 K were the main components in LDL subfractions with Mr 470 K and 250 K. The presence of apo B-like protein seemed to be responsible for the adsorption of LDL subfraction with Mr 1200 K for the DSC column. LDL subfractions with Mr 470 K and 250 K seemed to belong to high density lipoprotein (HDL) with respect to molecular weights and apolipoprotein features. To our knowledge, this is the first report of the separation of LDL and HDL from the plasma of Japanese eels using the DSC column.

Human low density lipoprotein and human serum albumin adsorption onto model surfaces studied by total internal reflection fluorescence and scanning force microscopy

The adsorption of low density lipoprotein (LDL) and human serum albumin (HSA) to model surfaces of different hydrophobicities has been studied using two, surface-sensitive, real-time, in situ techniques: total internal reflection fluorescence (TIRF) and scanning force microscopy (SFM). The model surfaces used were: (1) hydrophilic negatively charged silica (TIRF) and mica (SFM) surfaces, (2) hydrophobic octadecyldimethylsilyl-(ODS)-modified silica (TIRF) and ODS-modified oxidized silicon (SFM) surfaces and (3) amphiphilic ODS-silica gradient surfaces (TIRF). The kinetics of fluorescein isothiocyanate-LDL adsorption onto the ODS-silica gradient surface from FITC-LDL solution and from a solution mixture of LDL and HSA showed that a transport-limited process on the clean silica changed into an adsorption-limited process with increasing surface coverage of ODS chains. SFM analysis of the in situ adsorption of LDL on hydrophilic mica demonstrated a steady increase in surface coverage with time which was somewhat lower than determined by TIRF for FITC-LDL adsorption on silica. The adsorption behavior of a binary mixture of HSA and LDL suggested that lateral interactions between HSA and LDL affect the adsorption process. The diameter of LDL adsorbed on mica and ODS-modified silicon has been determined using SFM to be approximately 55 nm. Tetrameric LDL aggregates were observed on all of the surfaces in addition to some dimers and trimers. Imaging LDL and HSA adsorption on clean oxidized silicon surfaces using "contact mode' SFM techniques was hindered by probe manipulation of the proteins.

Development of selective low-density lipoprotein (LDL) apheresis system: immobilized polyanion as LDL-specific adsorption for LDL apheresis system

Low-density lipoprotein (LDL) is widely recognized as one of the major risk factors for developing coronary heart diseases. Despite intensive development of LDL-lowering drugs, there still exist those patients with refractory hyperlipidemia whose plasma LDL levels are not sufficiently lowered by drugs. LDL apheresis, direct removal of plasma LDL from circulating blood, is thought to be the most promising treatment for such refractory patients. Various techniques, such as the use of an immunoadsorbent utilizing an anti-LDL antibody, have been used in an attempt to achieve the selective removal of LDL. However, none were widely used because of complications, poor selectivity, and so forth. To establish a safe and effective LDL apheresis system, we chose a synthetic affinity adsorbent as the LDL-removing device. Synthetic polyanion compounds were used as the affinity ligands for LDL adsorbent to simulate the anion-rich sequence of LDL binding sites in the human LDL receptor. Among various polyanion compounds, those polyanions with sulfate or sulfonate groups and hydrophilic backbone were found to have strong affinity for LDL. In contrast, polyanions with carboxyl groups showed poor affinity. Dextran sulfate (DS) was selected as the affinity ligand of LDL adsorbent for its high affinity and low toxicity. The influence of its charge density and molecular weight on its affinity for LDL was suitable. The affinity rapidly increased as the charge density increased, then, reached a constant value. Little affinity was found for either the DS monomer (glucose sulfate) or DS with a molecular weight higher than 10(4) daltons whereas DS with molecular weights in the midrange showed strong affinity. DS with a midrange molecular weight was immobilized on cellulose hard gel to give LDL adsorbent clinical application. The adsorbent demonstrated an excellent selectivity for LDL and very low density lipoprotein (VLDL) in vitro. Adsorption of high-density lipoprotein and major plasma proteins was almost negligible. Additional study of the LDL-binding mechanism revealed that DS directly interacts with positively charged sites on LDL, which demonstrates that the nature of the interaction is the same as that of LDL receptor. An LDL adsorption column (Liposorber) packed with an LDL adsorbent and polysulfone hollow-fiber plasma separator (Sulflux) was developed as an efficient LDL apheresis system. Clinical investigation proved that this system is capable of intensively lowering the plasma LDL level without affecting major plasma components.

Lipid apheresis: from a heroic treatment to routine clinical practice

Lipid apheresis has developed from a heroic treatment into a routine clinical therapy and currently is the major indication for performing extracorporeal plasma therapy. Whereas it was once reserved for patients with homozygous familial hypercholesterolemia, today it has a place in the secondary prevention of severe coronary heart disease when low-density lipoprotein (LDL)-cholesterol level exceeds 150 mg/dl, despite conservative treatment, in any type of primary hypercholesterolemia. Unselective plasma exchange has been replaced by a variety of selective procedures. The efficacy of the treatment can be maximized by combining LDL apheresis with the use of cholesterol synthesis enzyme inhibitors. Clinical studies have shown that drastic cholesterol reduction can result in regression of coronary atherosclerosis as well as in reduced cardiac morbidity and mortality. Technical progress comprises improved selectivity, online regeneration of adsorbers, and LDL adsorption from whole blood. Recently, a new LDL hemoperfusion procedure was successfully tested in a clinical pilot study; blood is passed directly over a lipid sorbent without prior plasma separation. If this system is demonstrated to be safe and effective in clinical Phase III trials, a further qualitative step in the rapid development of LDL apheresis will have made.

Extracorporeal removal of lipids by dextran sulfate cellulose adsorption

Extracorporeal removal of low-density lipoprotein (LDL) cholesterol by dextran sulfate adsorption is indicated in patients with diet and drug resistant hyper-cholesterolemia to prevent or to regress coronary heart disease. Plasma separation is the first step in the process, followed by adsorption of LDL cholesterol and lipoprotein (a) (Lp[a]) to negatively charged dextran sulfate covalently bound to cellulose beads. The reduction per treatment in LDL cholesterol is 65-75% and in Lp(a) 40-60%. In most patients one treatment per week is sufficient to reduce mean LDL to 100-150 mg/dl. Minor side effects occur in 2-6% of treatments. Major side effects are rare. In uncontrolled studies long-term treatment was associated with inhibition of progression and induction of regression of coronary artery disease. LDL apheresis by dextran sulfate may increase blood perfusion of some tissues, and preliminary results indicate a beneficial effect on therapy resistant nephrotic syndrome with hypercholesterolemia.

A variety of clinical applicabilities of immobilized dextran sulphate as lipoprotein adsorbent and avoidance of anaphylactoid (anion-blood contact) reaction in its use

Dyslipidemia including hyper-LDL(low density lipoprotein) cholesterol which is very often refractory to dietary/medical treatments is known to be a risk factor of many arteriosclerotic lesions. An extracorporeal procedure of plasma adsorption, LDL adsorption, utilizing dextran sulphate as a ligand immobilized on cellulose gel beads has been clinically applied in a variety of dyslipidemic conditions as listed below. Its usefulness in secure reduction of the serum LDL level and consequent symptomatic improvements has been confirmed. Familial hypercholesterolemia(FH): A regular repetition of the LDL adsorption ameliorates hyper-LDL cholesterolemia as resulting in regression of the multiple stenoses in the coronary arteries. Focal glomerulosclerosis(FGS): A seesion of the LDL adsorption improves kidney function and reduces a urinary protein excretion in FGS patients with dyslipidemia. Arteriosclerosis obliterans(ASO): More than 60 ASO patients with dyslipidemia have been treated by the LDL adsorption in our center. In over 80% of the patients, marked improvement in clinical symptoms such as leg pain/intermittent claudication has been brought out. Hemodialysis-relevant dyslipidemia(HDDL): HDDL which develops in the long-term HD patients has been treated. Transplantation-relevant dyslipidemia(TXDL): TXDL with deterioration of the transplanted kideny function has been treated by the LDL adsorption. Kidney function improves. Anaphylactoid reaction which is tentatively explained as a result of release of bradykinin in contact of blood with polyanionic material of the adsorbent, dextran sulphate, develops, in particular, while an angiotensin-converting enzyme inhibitor is administered as a depressant. However, it can be avoided in a use of nafmostat mesilate, a protease inhibitor, as an anticoagulant.

Low-density lipoprotein apheresis as long-term treatment for children with homozygous familial hypercholesterolemia

OBJECTIVE

To determine the safety and efficacy of long-term dextran sulfate-affinity column low-density lipoprotein (LDL) apheresis for the treatment of children with receptor-negative homozygous familial hypercholesterolemia (HFH).

STUDY DESIGN

Two children with HFH (pretreatment cholesterol levels 22.1 to 24.7 mmol/L (ranges 850 to 950 mg/dl) began LDL apheresis treatments at ages 7 and 10 years, respectively. The LDL apheresis treatment interval was generally either 7 or 14 days; for the last 2 years of the study the treatment interval was 7 days. The patients had 167 and 188 LDL apheresis procedures during 64 and 70 months, respectively.

RESULTS

Individual procedures decreased total blood cholesterol levels by 63% to 68%. When the treatment interval was 7 days, the patients' time-averaged mean total cholesterol levels decreased to 7.3 +/- 0.65 mmol/L (280 +/- 25 mg/dl) and 6.4 +/- 0.55 mmol/L (247 +/- 22 mg/dl), respectively. Both children remained clinically well with normal growth and development. There was significant regression of xanthomas in both patients. The older patient required heart surgery for preexisting aortic stenosis and coronary ostial stenosis, but neither patient had progression of hypercholesterolemia-related cardiovascular disease. With the exception of iron (deficiency in patient 1), there was no evidence of depletion of serum components. Adverse reactions to LDL apheresis were rare and never severe.

CONCLUSIONS

Dextran sulfate-affinity column LDL apheresis is effective long-term treatment for children with receptor-negative HFH.

Effect of nafamostat mesilate on bradykinin generation and hemodynamics during LDL apheresis

Dextran-sulfate (DS) cellulose used for low-density lipoprotein (LDL) apheresis seems to be a weak activator of the contact phase of the intrinsic coagulation pathway because the surface of this substance has negative charges. Heparin, a commonly used anticoagulant, has no effect on this process whereas the process is inhibited by a newly developed anticoagulant, nafamostat mesilate (NM). The effects on bradykinin generation were compared between heparin and NM. Five patients with severe hypercholesterolemia were treated with LDL apheresis using either heparin or NM on a different day. During apheresis with heparin, factor XII, high molecular weight kininogen, and prekallikrein were markedly decreased by passing through the DS column. A distinct generation of bradykinin was observed by passing plasma through the DS column, and this led to the rise of bradykinin levels from 12 +/- 5 (mean +/- SE) to 72 +/- 14 pg/ml after treatment of 1,000 ml of plasma. NM suppressed almost completely the rise of bradykinin levels. Although blood pressure was apt to decrease during apheresis with heparin, there was no significant difference in blood pressure between heparin and NM. Since an angiotensin-converting enzyme inhibitor may lead to a marked rise in blood levels of bradykinin by suppressing its degradation, the use of NM is recommended for apheresis in patients taking this drug.

Non-steady-state kinetics of low density lipoproteins in man: studies after plasma exchange in healthy subjects and patients with familial hypercholesterolaemia

Five patients with heterozygous familial hypercholesterolaemia (FH), one patient with non-familial hypercholesterolaemia, and four healthy normals were treated with plasma exchange (PE). In order to achieve a non-steady-state situation with low plasma cholesterol levels, PE was performed twice in each subject at an interval of 1-3 days. At each time, 1500 ml of plasma were removed and replaced with colloids and albumin. Lipoprotein analyses were performed daily in all subjects for a period of 14 days following PE. Kinetic calculation of LDL cholesterol data using a two-compartment open model was performed, and rate constants, synthetic rate and apparent clearance of LDL were determined. A lower clearance and a tendency towards a higher synthesis of LDL were observed in the FH patients. In four of the subjects, LDL kinetics was also studied with the conventional 125I-LDL turnover technique. The synthetic rates of LDL were compared using data derived from PE and 125I-LDL kinetics. The two techniques showed a good correlation (r = +0.93) although synthetic rates in general were higher when calculated from the 125I-LDL procedure (3.98 vs. 2.64 mmol d-1 for LDL cholesterol synthesis). The results indicate that non-steady-state kinetics of LDL, as measured using the PE technique, is a useful method for analysis of LDL metabolism.

Purification, characterization, and conformational analysis of rabbit plasma lipid transfer protein

A procedure for rapid isolation of lipid transfer protein (LTP) from commercially available rabbit plasma is described. Use of protease inhibitors was important for obtaining intact, stable LTP. After lipoproteins were precipitated from the plasma by dextran sulfate, column chromatographies through Butyl-Toyopearl 650M, CM-Toyopearl 650M, and Butyl-Toyopearl 650M were employed. Overall purification from plasma was (3830 +/- 710)-fold with a yield of 3-5%. The isolated LTP migrated as a single band during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with M(r) = 74K and had an NH2-terminal amino acid sequence and amino acid composition closely matching those predicted by its cDNA. This band was recognized by immunoblotting with an anti-human LTP monoclonal antibody, TP2. Gel permeation chromatography revealed that LTP behaved as a globular protein of M(r) = 83K. Isoelectric focusing of the isolated LTP demonstrated a ladder of bands with pI's of 5.7-5.9. The specific activity of rabbit LTP was similar to that of human LTP. Monoclonal antibody TP2, that blocked human plasma LTP activity almost completely, only partially inhibited purified rabbit LTP, and rabbit plasma LTP activity to a similar extent. By a centrifugation binding assay, rabbit LTP was shown to predominantly associate with lipid microemulsion in its presence. Circular dichroism spectroscopy indicated a high content of beta structure, and Provencher and Glöckner analysis gave estimated fractional values of 0.30, 0.39, 0.12, and 0.19 for alpha-helix, beta-sheet, beta-turn, and remainder content, respectively. Upon lipid binding, the helical content did not change drastically, although there was some disordering of beta structure.

Treatment with a combination of low-density lipoprotein aphaeresis and pravastatin of a patient with drug-resistant nephrotic syndrome due to focal segmental glomerulosclerosis

Results of recent animal studies have lent support to the hypothesis that hyperlipidaemia may contribute to renal injury. This report documents the case of a 15-year-old boy with drug-resistant nephrotic syndrome due to focal segmental glomerulosclerosis (FGS) who showed an improvement in renal function and proteinuria as a result of treatment with low-density lipoprotein aphaeresis (LDL-A) combined with pravastatin. Although further work is required to determine the efficacy of lipid-lowering therapy in progressive glomerular disease in humans, the combination of LDL-A and pravastatin is likely be included in the choice of treatment modalities available for patients with drug-resistant nephrotic syndrome due to FGS.

Treatment of refractory familial hypercholesterolemia by low-density lipoprotein apheresis using an automated dextran sulfate cellulose adsorption system. The Liposorber Study Group

A subgroup of patients with familial hypercholesterolemia (FH) respond inadequately to standard diet and drug therapy, and are therefore at high risk for the premature development or progression of coronary artery disease. This study evaluated low-density lipoprotein (LDL) cholesterol and lipoprotein (a) removal in a multicenter, controlled trial with a new LDL apheresis procedure (Liposorber LA-15 System). The study comprised patients with FH who had not responded adequately to diet and maximal drug therapy. There were 54 patients with heterozygous FH (45 randomized to treatment and 9 control subjects) and 10 with homozygous FH (all of whom received LDL apheresis). The study included three 6-week treatment phases and a 4-week rebound phase. Treatments were administered at 7- to 14-day intervals. Mean acute reductions in LDL cholesterol were 76% in heterozygous FH patients and 81% in homozygous ones. Time-averaged levels of LDL cholesterol were reduced 41% (243 to 143 mg/dl) in heterozygous FH patients and 53% (447 to 210 mg/dl) in homozygous ones. The substantial acute reduction of lipoprotein (a) (means: 65%, heterozygous FH; 68%, homozygous FH) has not been reported with other therapies. The Liposorber LA-15 System represents an important therapeutic option in FH patients who respond inadequately to diet and drug therapy.

Siblings with normal LDL receptor activity and severe hypercholesterolemia

We report about a brother and sister having clinical symptoms similar to those of homozygous familial hypercholesterolemia (FH) but surprisingly who have normal low density lipoprotein (LDL) receptor activities (M. Harada-Shiba et al, J Jpn Atheroscler Soc 1991; 19:227-242). The LDL receptor activities in the cultured fibroblasts of the patients were compared with those of FH heterozygotes and homozygotes for the LDL receptor mutation. The LDL receptor activities in the cultured fibroblasts of the patients were in the normal range, but their plasma cholesterol concentrations were similar to patients with homozygous FH. After the plasma LDL was removed by plasmapheresis in both patients, plasma cholesterol levels started to increase. The "rebound" of plasma cholesterol was compared with those for heterozygous and homozygous FH. The plasma cholesterol levels of the patients, which were greater than 410 mg/dl 2 weeks after plasmapheresis, were much higher than those of FH heterozygotes (232-311 mg/dl) but similar to those of FH homozygotes (345-464 mg/dl). The urinary mevalonate excretion rate, which reflects the rate of whole-body cholesterol synthesis, was higher for the brother (patient 1, 32.6 nmol/kg.day-1) than for the normal subjects (17.7 +/- 4.1 nmol/kg.day-1) but was similar to those of FH homozygotes (31.2 +/- 4.3 nmol/kg.day-1) and heterozygotes (29.8 +/- 10.9 nmol/kg.day-1). To estimate the catabolic and production rates of cholesterol in the brother, the time course for the increment in the total cholesterol level after plasmapheresis was analyzed by the two-compartment model.(ABSTRACT TRUNCATED AT 250 WORDS)

Blood rheology after LDL apheresis using dextran sulfate cellulose absorption--a case report

The authors describe a thirty-eight-year-old woman with familial hypercholesterolemia treated by dextran sulfate cellulose adsorption apheresis. This technique and the selective extracorporeal LDL cholesterol elimination by immunoabsorption or heparin-induced precipitation not only dramatically decrease blood lipids but also result in a marked improvement in the rheologic profile. It is suggested that the amelioration of blood rheology by LDL apheresis may represent the cause for the early clinical improvement felt by most patients with severe coronary heart disease and hypercholesterolemia.

Regression of coronary atherosclerosis by combined LDL-apheresis and lipid-lowering drug therapy in patients with familial hypercholesterolemia: a multicenter study. The LARS Investigators

The purpose of the LDL-Apheresis Regression Study (LARS) group, which included 13 institutions in Japan, was to investigate the effects on coronary atherosclerosis of LDL-apheresis combined with cholesterol-lowering drugs. Changes in coronary artery stenosis were assessed angiographically in 37 patients with familial hypercholesterolemia (7 homozygotes and 25 heterozygotes) and hypercholesterolemia which had not been defined as familial hypercholesterolemia (5 patients) by visual judgement and computer analysis. Definite regression was observed in 14 cases, including 4 homozygotes and 10 heterozygotes and others. Regression occurred as often in patients with severe coronary artery disease (2 or more vessel disease) as in those having less severe disease. Our results encourage initiation of aggressive cholesterol-lowering therapy to produce regression of coronary atherosclerosis in FH patients at high risk for cardiovascular events.