DALI apheresis in hyperlipidemic patients: biocompatibility, efficacy, and selectivity of direct adsorption of lipoproteins from whole blood

Biomembrane-mimetic hemoperfusion adsorbent for efficient removal of low-density lipoprotein from hyperlipemia blood

Lowering of low-density lipoprotein (LDL) levels in blood of patients with hyperlipidaemia can effectively prevent the progression of atherosclerosis and coronary heart disease. The present study demonstrated a facile synthesis strategy to prepare biomembrane-mimetic LDL adsorbent (PVA@COOH-PE) via directional immobilization of phospholipid onto macro-porous cross-linked poly(vinyl alcohol) spheres. The binding between the prepared adsorbent and LDL particles simulates the cytosolic lipid droplets to form a lipid-packing structure. The adsorbent possesses satisfactory removal efficiency for LDL and total cholesterol (TCH) in hyperlipemia serum, while remains high-density lipoprotein (HDL) concentration within the normal range. The adsorption capacities for LDL and TCH are about 1.13 and 1.74 mg/ml respectively, which are nearly three and four times higher than that of HDL (0.42 mg/ml). The adsorbent also possesses satisfactory anticoagulant properties, causes negligible effect on blood cells and produces low hemolysis ratios. The excellent blood compatibility plus LDL removal efficiency of PVA@COOH-PE indicates its good application prospect as hemoperfusion adsorbent in the treatment of hyperlipidaemia.

Desialylation of platelet surface glycans enhances platelet adhesion to adsorbent polymers for lipoprotein apheresis

Background:

Lipoprotein apheresis is an important therapeutic option in homozygous familial hypercholesterolemia, progressive atherosclerosis, or when depletion of lipoprotein(a) is indicated. It is generally regarded as safe, but drops in platelet counts as well as sporadic episodes of thrombocytopenia have been reported. We assessed the influence of platelet desialylation, which may be induced by endogenous or pathogen-derived neuraminidases, on platelet adhesion to polyacrylate-based adsorbents for whole blood lipoprotein apheresis.

Methods:

Medical grade platelet concentrates were incubated with neuraminidase in vitro and were circulated over adsorbent columns downscaled from clinical application.

Results:

Cleavage of terminal sialic residues resulted in platelet activation with significantly elevated expression of platelet factor 4 (PF4) and in enhanced platelet adhesion to the adsorbent, accompanied by a pronounced drop in platelet counts in the column flow-through.

Conclusion:

Alterations in endogenous neuraminidase activity or exogenous (pathogen-derived) neuraminidase may trigger enhanced platelet adhesion in whole blood lipoprotein apheresis.

A Bifunctional Adsorber Particle for the Removal of Hydrophobic Uremic Toxins from Whole Blood of Renal Failure Patients

Hydrophobic uremic toxins accumulate in patients with chronic kidney disease, contributing to a highly increased cardiovascular risk. The clearance of these uremic toxins using current hemodialysis techniques is limited due to their hydrophobicity and their high binding affinity to plasma proteins. Adsorber techniques may be an appropriate alternative to increase hydrophobic uremic toxin removal. We developed an extracorporeal, whole-blood bifunctional adsorber particle consisting of a porous, activated charcoal core with a hydrophilic polyvinylpyrrolidone surface coating. The adsorption capacity was quantified using analytical chromatography after perfusion of the particles with an albumin solution or blood, each containing mixtures of hydrophobic uremic toxins. A time-dependent increase in hydrophobic uremic toxin adsorption was depicted and all toxins showed a high binding affinity to the adsorber particles. Further, the particle showed a sufficient hemocompatibility without significant effects on complement component 5a, thrombin-antithrombin III complex, or thrombocyte concentration in blood in vitro, although leukocyte counts were slightly reduced. In conclusion, the bifunctional adsorber particle with cross-linked polyvinylpyrrolidone coating showed a high adsorption capacity without adverse effects on hemocompatibility in vitro. Thus, it may be an interesting candidate for further in vivo studies with the aim to increase the efficiency of conventional dialysis techniques.

Heparin-Free DALI LDL-Apheresis in Hyperlipidemic Patients: Efficacy, Safety and Biocompatibility

Background and Aim of Study

In routine DALI apheresis - the first technique for direct adsorption of lipoproteins from whole blood - heparin plus citrate (ACD-A) is used as anticoagulation regimen. However, recently several publications have warned of heparin-induced thrombocytopenia as a rare but potentially life-threatening complication of heparin administration (HIT type 2). The aim of the present study was therefore to test the efficacy and biocompatibility of DALI using a heparin-free anticoagulation regimen consisting exclusively of citrate.

Methods

Four symptomatic hypercholesterolemic patients on regular DALI apheresis were switched to the heparin-free protocol for two sessions each. Two of the patients were on oral anticoagulation using phenprocoumon. In the weekly sessions, 1.3 patient blood volumes were processed at a blood flow rate of 60 ml/min using ACD-A at a ratio of 1:20 (v/v) during adsorber priming and the session.

Results

Clinically, all sessions were essentially uneventful. Uncorrected lipoprotein reductions amounted to 65% for LDL-C, 62% for Lp(a), 53% for VLDL-C, 24% for HDL-C, 17% for triglycerides and 19% for fibrinogen. Cell counts remained virtually constant. No signs of hemolysis or clotting could be detected. Thromboplastin time (Quick) was slightly prolonged and partial thromboplastin time (PTT) moderately elevated in all patients. In constrast, whole blood coagulation time acc. to Lee-White and activated clotting times were increased only in orally anticoagulated patients. Biocompatibility in terms of complement, leukocyte and thrombocyte activation was excellent. Bradykinin activation was moderate peaking at 3038 pg/ml in the efferent line. Systemic thrombin-antithrombin complex (TAT) reflected perfect anticoagulation in orally anticoagulated patients and adequate anticoagulation in the patients without phenprocoumon.

Conclusion

In this pilot study, heparin-free DALI apheresis was safe and effective and may thus be performed in LDL-apheresis dependent patients who suffer from heparin intolerance.

Whole Blood Selective LDL-Apheresis: A Comparison of Two Different Adsorbers

The effects of LDL-apheresis with whole blood adsorption were compared in five patients with severe familial and ARH hypercholesterolemia, using two different sorbents, polyacrylic acid with the DALI system and dextran sulfate with the DX21 system. The patients were treated bimonthly with both systems at random. For each patient, the same number of procedures with both systems was considered, ranging from 2 to 11 for each technique. During a period of observation of 26 months, a total of 80 LDL-apheresis, 40 with the DALI system and 40 with the DX21, with equivalent volumes of treated whole blood was evaluated (mean blood volume treated: 8151 mL). Total and LDL cholesterol were effectively lowered with both techniques. The mean percentage reduction of total cholesterol and LDL-cholesterol respectively was 54.1±7.7% and 62.3±9% with the DALI system, 52.7±7.8% and 59.2±9.5 with the DX21: t-test for paired data showed p: 0.01 for LDL-cholesterol. The reduced removal of LDL-C with dextran sulfate, either within the same patient or all the patients taken together was of a very limited amount compared to polyacrylic acid. The superiority of one over the other sorbent cannot be affirmed: further studies on a higher number of procedures and patients, together with an evaluation of biocompatibility effects, compared to polyacrylic acid may clarify and make evident a significant difference in efficacy between the two systems.

Rheopheresis for Sudden Hearing Loss (SHL)

Rheopheresis has met an increasing interest and application in different disease conditions affecting microcirculation. Its last applications are for the management of Macular and Cochlear disorders. The sudden hearing loss syndrome is a condition that affects 20 out of 100000 persons per year, reduces the patient's social interaction and quality of life. It is associated with vascular and coagulation risk factors and it is considered as a result of local hypoperfusion secondary both to inflammatory and dysimmune conditions determining inadequate NO release and endothelial dysfunction. Rheopheresis treatment is a new approach which brings to satisfactory clinical results. Cascade filtration, heparin induced lipid precipitation and conventional plasma exchange are equally effective, and only 2 sessions are required for producing long lasting benefits. Our experience is with 60 patients, 90% of which getting from partial to complete recovery after treatment as measured by pure tone audiometry.

The impact of citrate concentration on adhesion of platelets and leukocytes to adsorbents in whole blood lipoprotein apheresis

Lipoprotein apheresis is applied to deplete low density lipoprotein and other apolipoprotein B containing lipoproteins in patients with severe familial hypercholesterolemia, hypertriglyceridemia associated pancreatitis, or lipoprotein (a)-hyperlipoproteinemia. Anticoagulation of the extracorporeal circuit may influence cellular activation, as evidenced by a reduction of inflammatory parameters during regional citrate anticoagulation with acid citrate dextrose A (ACD-A) commonly used in whole blood lipid apheresis. While the citrate concentration in the extracorporeal circuit has to ensure efficient anticoagulation, citrate infusion into the patient should be limited to avoid citrate overload. We assessed the influence of citrate concentration on cellular activation during in vitro circulation of whole blood containing 2.8 mM citrate (ACD-A 1:40), 5.6 mM citrate (ACD-A 1:20), or 13 mM citrate over polyacrylate-based adsorbents for lipoprotein apheresis. We found increased platelet adhesion for anticoagulation with 2.8 mM citrate as compared to 5.6 or 13 mM citrate, as shown by cell counting and confirmed by scanning electron microscopy of adsorbent beads as well as by elevated levels of platelet activation markers and of platelet-derived microvesicles. Leukocytes showed an equivalent adhesion pattern, while red blood cells remained unaffected at all citrate concentrations. Passage of blood over two consecutive columns resulted in enhanced platelet adhesion to the second column, presumably due to upstream preactivation. In conclusion, citrate influences activation and adhesion of platelets and leukocytes in a concentration-dependent manner, and ACD-A 1:20, equivalent to a citrate concentration of 5.6 mM in whole blood, ensures minimal cellular activation during passage of whole blood over polyacrylate-based adsorbents.

Release and cellular origin of extracellular vesicles during circulation of whole blood over adsorbent polymers for lipid apheresis

Whole blood lipid apheresis is clinically applied in patients with familial hypercholesterolemia to reduce low density lipoprotein and other apolipoprotein B 100 containing lipoproteins. Here, the hemocompatibility of two polyacrylate-coated polyacrylamide-based polymers for lipid apheresis by evaluating the adhesion of blood cells to the adsorbent polymers, their respective activation, as well as the release of microvesicles during circulation of whole blood over the polymers was studied. Characterization of the adsorbents by scanning electron microscopy, atomic force microscopy, and X-ray photoelectron spectroscopy revealed differences with respect to their surface morphology and their surface chemical composition. Despite these differences, equivalent amounts of leukocytes and platelets adhered to both polymers during circulation of whole blood over the adsorbent columns. The release of phosphatidylserine-exposing microvesicles, in contrast, increased significantly with increasing surface roughness and with the amount of polyacrylate groups at the adsorbent surface. The majority of microvesicles generated during blood-material contact were platelet-derived, and their release was associated with enhanced thrombin generation. Microvesicles were present in free and in cell-bound form, and 75% of all monocytes, but only 0.2% and 2.3% of red blood cells and platelets, respectively, were associated with microvesicles, pointing to a role of monocytes in the clearance of released microvesicles. Taken together, microvesicles are sensitive indicators for biomaterial-induced activation of blood cells in apheresis. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 636-646, 2017.

Interactions of Apolipoproteins AI, AII, B and HDL, LDL, VLDL with Polyurethane and Polyurethane-PEO Surfaces

The lipoproteins (HDL, LDL, VLDL) are important components of blood present in high concentration. Surprisingly, their role in blood-biomaterial interactions has been largely ignored. In previous work apolipoprotein AI (the main protein component of HDL) was identified as a major constituent of protein layers adsorbed from plasma to biomaterials having a wide range of surface properties, and quantitative data on the adsorption of apo AI to a biomedical grade polyurethane were reported. In the present communication quantitative data on the adsorption of apo AI, apo AII and apoB (the latter being a constituent of LDL and VLDL), as well as the lipoprotein particles themselves (HDL, LDL, VLDL), to a biomedical segmented polyurethane (PU) with and without an additive containing poly(ethylene oxide) (material referred to as PEO) are reported. Using radiolabeled apo AI, apo AII, and apoB, adsorption levels on PU from buffer at a protein concentration of 50 μg/mL were found to be 0.34, 0.40, and 0.14 μg/cm(2) (12, 23, and 0.25 nmol/cm(2)) respectively. Adsorption to the PEO surface was <0.02 μg/cm(2) for all three apolipoproteins demonstrating the strong protein resistance of this material. In contrast to the apolipoproteins, significant amounts of the lipoproteins were found to adsorb to the PEO as well as to the PU surface. X-ray photoelectron spectra, following exposure of the surfaces to the lipoproteins, showed a strong phosphorus signal, confirming that adsorption had occurred. It therefore appears that a PEO-containing surface that is resistant to apolipoproteins may be less resistant to the corresponding lipoproteins.

Thrombocyte adhesion and release of extracellular microvesicles correlate with surface morphology of adsorbent polymers for lipid apheresis

Whole blood lipid apheresis is clinically applied to reduce low density lipoprotein cholesterol in patients with homozygous familial hypercholesterolemia. Here, we studied the correlation between physicochemical parameters, in particular, surface roughness and blood compatibility, of two polyacrylate-based and a dextran sulfate-based polymer for lipid apheresis. The adsorbent surface roughness was assessed by atomic force microscopy. Freshly isolated human thrombocytes were circulated over adsorbent columns downscaled equivalent to clinical use to study thrombocyte adhesion and microvesicle generation. Quantification of thrombocytes and microvesicles in the flow-through of the columns revealed that both thrombocyte adhesion and microvesicle generation increased with increasing adsorbent surface roughness. Activation of thrombocytes with thrombin receptor-activating peptide-6 favored their adhesion to the adsorbents, as demonstrated by preferential depletion of CD62(+) and PAC-1(+) thrombocytes. Taken together, enhanced polymer surface roughness fostered cell adhesion and microvesicle release, underscoring the role of extracellular microvesicles as markers of cellular activation and of blood compatibility.

LDL-apheresis: technical and clinical aspects

The prognosis of patients suffering from severe hyperlipidemia, sometimes combined with elevated lipoprotein (a) levels, and coronary heart disease refractory to diet and lipid-lowering drugs is poor. For such patients, regular treatment with low-density lipoprotein (LDL) apheresis is the therapeutic option. Today, there are five different LDL-apheresis systems available: cascade filtration or lipid filtration, immunoadsorption, heparin-induced LDL precipitation, dextran sulfate LDL adsorption, and the LDL hemoperfusion. There is a strong correlation between hyperlipidemia and atherosclerosis. Besides the elimination of other risk factors, in severe hyperlipidemia therapeutic strategies should focus on a drastic reduction of serum lipoproteins. Despite maximum conventional therapy with a combination of different kinds of lipid-lowering drugs, sometimes the goal of therapy cannot be reached. Hence, in such patients, treatment with LDL-apheresis is indicated. Technical and clinical aspects of these five different LDL-apheresis methods are shown here. There were no significant differences with respect to or concerning all cholesterols, or triglycerides observed. With respect to elevated lipoprotein (a) levels, however, the immunoadsorption method seems to be most effective. The different published data clearly demonstrate that treatment with LDL-apheresis in patients suffering from severe hyperlipidemia refractory to maximum conservative therapy is effective and safe in long-term application.

Pancytopenia with severe thrombocytopenia in a patient treated with twice-weekly LDL-apheresis by polyacrylate adsorption from whole blood

Pancytopenia with severe thrombocytopenia occurred in a patient treated with low-density lipoprotein (LDL)-apheresis by polyacrylate adsorption from whole blood, after treatment frequency had been increased from once to twice a week. Cell counts recovered with discontinuation of LDL-apheresis, but thrombocytopenia recurred after resumption of twice-weekly treatments. Thrombocyte counts remained stable following the replacement of polyacrylate adsorption from whole blood by double-filtration plasmapheresis. The complications' close coincidence with twice-weekly polyacrylate adsorption from whole blood suggests a causal relationship, although by a still unknown mechanism. Monitoring of thrombocytes should be advised in patients treated with LDL-apheresis by polyacrylate adsorption from whole blood.

Applications of LDL-apheresis in nephrology

LDL-apheresis (LA) was originally used for familial hyperlipidemia, and then in Japan extended to use for the treatment of patients with peripheral arterial disease (PAD) and nephrotic syndrome due to steroid-resistant focal glomerular sclerosis (FGS). The reason why this treatment is applicable for these disorders is due to the fact that LA exerts its favorable effects beyond the lipid-lowering effect. The main underlying mechanisms, for example, in the case of LA application in patients with PAD are: (1) improvement of hemorheology, (2) improvement of endothelial dysfunction, (3) elevations of serum levels of NO and bradykinin, (4) increase in serum levels of vascular endothelial growth factor, and (5) reduction of adhesion molecules on monocytes. Furthermore, we have reported that LA could have anti-inflammatory effects because LA reduces serum levels of P-selectin, which is known to play an important role in the development of atherosclerosis as well as a reduction of serum C-reactive protein levels as standard biomarker of atherosclerosis. Massive proteinuria is also an important challenge in nephrology. The possible mechanisms besides removal of toxic lipids are the reduction of the vasoconstrictive prostanoid and thromboxane A2 (TXA2) and an improvement in macrophage function evidenced by a significant amelioration of interleukin-8 production by lipopolysaccharide-stimulated peripheral blood mononuclear cells. It is intriguing to note that in terms of pharmacodynamics, LA improves steroid and cyclosporine uptake into lymphocytes. Although there are no randomized controlled trials, it is clear that LA has various effects beyond lowering lipids. Making the device more concise and changing it into a whole blood adsorption type, we need to collect more clinical cases and to study the underlying mechanisms further.

Exploring the feasibility of selective depletion of T lymphocyte subsets by whole blood immunoadsorption cytapheresis

Normal turnover of T lymphocytes is slow relative to other blood cells. Consequently, the physical removal of circulating leucocytes by thoracic duct drainage, repeated leukapheresis or blood filtration results in T cell depletion and immunosuppression. However, clinical use of such procedures is impractical compared with immunosuppressive drugs or radiation. None the less, immunosuppression by physical depletion of T cells, avoiding the systemic toxicities of drugs and radiation, might have clinical advantages if immunophenotypically distinct T cell subsets could be depleted selectively. Recent advances in targeted plasma protein apheresis using adsorbent macrobead columns prompted us to determine whether analogous techniques might permit CD4+ T lymphocytes to be removed selectively from whole blood. To explore this possibility, we linked murine anti-human-CD4 and isotype-identical control monoclonal antibodies (mAbs) to agarose, polyacrylamide and polystyrene macrobeads (150-350 microm) and then evaluated the selectivity, specificity and efficiency of macrobead columns to remove CD4+ T cells from anti-coagulated whole blood at varying mAb densities and flow rates. We also examined saturation kinetics and Fc-oriention versus random coupling of mAbs to macrobeads. Sepharose 6MB macrobead (250-350 microm) columns proved to be most effective, selectively removing up to 98% of CD4+ T cells from whole blood. Moreover, depletion efficiency and selectivity were retained when these columns were reused after elution of adherent CD4+ cells. These studies indicate that selective depletion of T lymphocyte subsets by whole blood immunoadsorption apheresis using mAb-linked macrobead columns may be feasible on a clinical scale. It is possible that such apheresis techniques could achieve targeted forms of immunosuppression not possible with drugs or radiation.

New Ligand Coupling Procedure for Formation of an Immunoadsorption Wall

To prevent the occurrence of dialysis-related amyloidosis, an immunoadsorption wall based on polyacrylamide has been manufactured by a recently developed, partially incomplete, two-stage polymerization method. During the preparation process, efficient utilization of coupling antibodies is the key to large-scale production of such a toxin removal modality. In this study, we attempted to carry out the ligand coupling procedure after formation of a cyanogen bromide (CNBr)-activated stationary phase, using anti-beta2-microglobulin (beta-2M) antibodies. In vitro immunoadsorption tests show that the levels of beta-2M decrease rapidly within the first 2 hours for all the immunoadsorption tests. After that, nearly blank values were reached for tests of initial levels of c. 30 microg/mL and c. 82 microg/mL, whereas a relatively constant level of c. 10 microg/mL was maintained for the test of initial levels of c. 185 microg/mL. The maximum surface binding capacity of the prepared immunoadsorption walls is estimated by fitting experimental data, using a mathematical model of saturation kinetics. The present comparative investigation also suggests the manufacturing process for an immunoadsorption wall could be improved and facilitated by this new ligand coupling procedure without compromising the resulting binding capacity. Furthermore, the experimental protocols as well as the present methodology could be helpful for development of a clinically applicable immunoadsorption wall.

Direct Adsorption of Low-Density Lipoprotein by DALI-LDL-Apheresis: Results of a Prospective Long-term Multicenter Follow-up Covering 12 291 Sessions

Direct adsorption of lipoproteins (DALI) is the first low density lipoprotein (LDL)-apheresis technology by which atherogenic LDL and lipoprotein(a) (Lp(a)) can be selectively removed from whole blood without plasma separation. The present follow-up was carried out to evaluate the clinical efficacy, selectivity and safety of long-term DALI apheresis. The follow-up was carried out in an open, prospective uncontrolled multicenter clinical design. Included were 158 drug-resistant hypercholesterolemic patients from 28 apheresis centers. These patients underwent 12 291 DALI sessions between January 1997 and March 2002. The patients suffered from severe atherosclerosis and their mean LDL-C was 188 mg/dL before the sessions. Mean follow-up was 25 +/- 16 (range 1-56) months during which 78 +/- 53 sessions were carried out. In most treatments, DALI 750 (63%) or DALI 1000 (30%) adsorbers were used. On average, 7423 +/- 1495 mL blood was processed at a flow rate of 84 +/- 16 mL/min in 102 +/- 25 min. Acute reductions by the single DALI sessions averaged 69 +/- 12% for LDL-C, 41 +/- 18% for TG, 15 +/- 10% for HDL-C, 19 +/- 11% for fibrinogen and 62 +/- 24% for Lp(a) (in patients with Lp(a) > 30 mg/dL). Adverse events were recorded in only 3.9% of the sessions. In this 5-year follow-up, long-term therapy with DALI was safe, effective and selective as LDL-C and Lp(a) could be reduced by >60% per session in approximately 100 min treatment time while HDL-C decrease and the incidence of AE were low.

A Serial Copolymerization Procedure for Manufacturing Immunoadsorption Walls as a Potential Unit in Conjunction With Hemodialysis Filters

A functional immunoadsorption wall for removal of beta-2-microglobulin has been made by partially incomplete two-stage copolymerization of acrylamide with immunoadsorbent. However, a substantial amount of immunoadsorbent needs to be flushed away after the copolymerization process. Thus, to enhance the utilization efficiency of immunoadsorbent, the flushed-away immunoadsorbent was further recovered, and the copolymerization was conducted in series to produce three consecutive immunoadsorption walls in this study. Preliminary removal tests show that similar removal patterns were obtained for these immunoadsorption walls. Although it is not timely to conclude that a clinically applicable immunoadsorption wall has taken shape, the development of a partially incomplete two-stage polymerization method and its associated techniques indeed provide a good basis for large-scale manufacturing immunoadsorption walls.

Hypercholesterolemia and LDL apheresis

Several trials have assessed the link between low-density lipoprotein cholesterol (LDL) and the development of coronary heart disease (CHD). LDL apheresis provides an effective role in treating patients with familial hypercholesterolemia (FH) and in preventing the progression of coronary artery disease (CAD). Five different techniques of LDL apheresis are in current use: immunoadsorption (IMA), dextran sulphate-cellulose adsorption (DSA), heparin extracorporeal LDL precipitation system (HELP), double filtration plasmapheresis (DFPP) or lipidfiltration and direct adsorption of lipoprotein using hemoperfusion (DALI). All methods are efficient,but their cost restricts LDL apheresis to the treatment of FH. Indications could include other diseases, but controlled trials are still lacking.

Hematologic and biochemical effects of the Gradiflow in an ex vivo ovine model

The Gradiflow (Life Therapeutics, Frenchs Forest, Australia) system is a novel electrophoretic technique that uses the dual characteristics of size and charge to separate target macromolecules from complex biological solutions. The system has the potential to selectively remove a range of moieties from blood and plasma in an in vivo system such as hemodialysis or, alternatively, in an in vitro setting such as a blood bank. In this study, the safety of a scaled down Gradiflow prototype device with a membrane surface area of 16 cm2 was investigated using an ex vivo ovine model. Physiologic, hematologic, and biochemical parameters were assessed in 12 sheep: 6 animals treated using the Gradiflow and 6 controls. The effects of the Gradiflow procedure on both whole blood and plasma were analyzed. The Gradiflow procedure was well tolerated, and the application of an electrical potential or exposure to the Gradiflow membrane did not cause any significant changes in the parameters measured. Hemoglobin levels remained stable in all groups during the 4-hour experiment. An early neutropenia was observed in all groups, although this appeared to be more pronounced with exposure to a plasma filter; the presence of the Gradiflow component had no separate influence. One sheep in the plasma group experienced septic shock, caused by Staphylococcus contamination of the separation membrane. Overall, the results indicate that there were no gross physiologic, hematologic, or biochemical adverse reactions to the ex vivo Gradiflow procedure.

Contact activation in low-density lipoprotein apheresis systems

BACKGROUND

Anaphylactoid reactions due to contact activation have been observed in patients on ACE inhibitor therapy and hemodialysis with negatively charged dialysis membranes. Negatively charged surfaces are functional constituents of different LDL apheresis systems. Therefore, contact activation was investigated during LDL apheresis with three different systems: (i) heparin-induced extracorporeal LDL precipitation (HELP); (ii) dextran sulfate cellulose (DSC) columns; and (iii) modified polyacrylate gels (DALI) in a clinical setting.

METHODS

24 prevalent patients on regular LDL apheresis treatment were included in the study. Bradykinin, prekallikrein, and HMW kininogen were measured during a single LDL apheresis at different sites of the systems.

RESULTS

LDL apheresis with DSC and DALI was associated with an extreme release of bradykinin after the passage of plasma or blood through the LDL adsorbers as well as with a decrease of prekallikrein and HMW kininogen during the course of the treatment. Bradykinin release exceeded the degradation capacity of the kininase II, since markedly elevated bradykinin concentrations were observed in the arterial line of the extracorporeal circuits of both systems. This was not associated with anaphylactoid reactions. In contrast to the treatments with DSC and DALI, the HELP system did not lead to any activation of the kallikrein-kinin system.

CONCLUSION

From our data we conclude that angiotensin converting enzyme (ACE) inhibitors are contraindicated in patients on LDL apheresis with the DSC and the DALI system. Because the HELP system does not activate the kallikrein-kinin system, patients who need ACE inhibitors are predisposed for this LDL apheresis procedure.

Clinical applications of long-term LDL-apheresis on and beyond refractory hypercholesterolemia

Premature coronary heart disease (CHD) can result from high LDL cholesterol levels even in the absence of any other risk factors. A striking example is found in children who have the homozygous form of familial hypercholesterolemia (FH) with extremely high levels of LDL-cholesterol, and severe atherosclerosis and CHD often develop during the first decades of life. LDL-apheresis was developed for the treatment of severe type of FH patients who are resistant to lipid-lowering drug therapy. Clinical efficacy and safety of the therapeutic tool which directly removes LDL from circulation have already been established in the treatment for refractory hypercholesterolemia in FH patients. The most recently developed method enables lipoproteins to be adsorbed directly from whole blood, using polyacrylate column. In addition to benefits derived from the stabilization or regression of arterial lesions, we highlight other possible clinical applications of LDL-apheresis. However, most of these clinical benefits came from case reports or retrospective studies. Mechanisms related these clinical improvement remain unclear, and prospective randomized controlled trials should be performed for the new clinical indications of LDL-apheresis.

Practical aspects of direct adsorption of lipoproteins from whole blood by DALI LDL-apheresis

Direct adsorption of lipoproteins (DALI) from whole blood is the first LDL-hemoperfusion procedure. The present paper addresses practical questions of DALI apheresis in order to optimise DALI therapy in sometimes critically ill coronary patients. The reduction of LDL and Lp(a) by DALI can be optimised by increasing the treated blood volume and the DALI adsorber volume. Hypotension (1.2% of sessions) may be minimised by fluid intake before the session, isovolemic connection of the patient to the ECC, reduced blood flow and low ACD-A ratio. Hypocalcemia may be avoided by low citrate anticoagulation (1:40) and reduced blood flow. Bradykinin release peaks at ca. 1000 ml of treated blood volume and may cause Quincke edema (tight throat), hypotension and flush. Reduction of the blood flow rate and decrease of citrate admixture as well as administration of iv. calcium may be helpful. While ACE inhibitors are contraindicated in DALI patients, sartans may be used without problems. Some "intrinsic" PTT increase is caused by adsorption of coagulation factors; undue PTT prolongations after DALI may be avoided by reduction of the heparin dosage during priming and treatment. In patients prone to alkalosis and hypokalemia, a reduction of the ACD-A ratio is recommended. Rises of adsorber inlet pressure may be due to insufficient anticoagulation and adsorber clotting or malfunctioning of the venous access. Rinsing of the adsorber with saline, administration of a heparin bolus and increase of the citrate admixture as well as a rinse and/or repositioning of the venous access are helpful measures. If these basic rules are followed, DALI LDL-apheresis is a safe, efficient, rapid and user-friendly LDL-apheresis procedure as evidenced by more than 80,000 DALI sessions successfully performed to date.

Efficacy and Safety of DALI-LDL-Apheresis in Two Patients Treated with the Angiotensin II-Receptor 1 Antagonist Losartan

Direct adsorption of lipids (DALI) is the first low-density lipoprotein (LDL)-apheresis technique capable of adsorbing LDL and lipoprotein (a) directly from whole blood. The adsorber consists of negatively charged polyacrylate ligands linked to a Eupergit matrix. Negatively charged ligands give rise to activation of bradykinin, which is rapidly degraded by the angiotensin converting enzyme (ACE). Thus, angiotensin converting enzyme inhibitors are contraindicated in DALI-LDL-apheresis. This is the first paper to describe the efficacy and safety of DALI-LDL-apheresis in patients treated with 50 mg of the angiotensin II-receptor 1 antagonist (ARA) losartan. Two hypercholesterolemic patients were treated for 79 patient months with weekly or biweekly DALI sessions (N = 221 sessions). Approximately 1.4 patient blood volumes were treated per session. Acute reductions of LDL-cholesterol (63%) and lipoprotein (a) (62%) exceeded 60% and laboratory safety parameters remained in the apheresis typical range. Mean bradykinin plasma levels peaked in the efferent line post-adsorber at 1000 mL of treated blood volume; 467 fmol/mL (N = 6 sessions) in the ARA-treated patients and 671 fmol/mL (N = 9 sessions) in a control group of three DALI patients without ARA medication (P = 0.69, n.s.). Clinically, the DALI sessions for the ARA-treated patients were completely uneventful and blood pressure was not significantly different in the two groups. In summary, according to this retrospective pilot study, DALI-LDL-apheresis was shown for the first time to be safe and effective in patients on ARA medication.

In face of the increasing efficacy of lipid-lowering therapy, is there still a place for LDL-apheresis?

Based on a large body of evidence, high LDL-cholesterol concentrations in blood is a key factor of coronary heart disease (CHD). Overall, the observational studies show a curvilinear relationship between blood cholesterol level and coronary heart disease risk. Even more relevant are the randomised trials, firmly establishing that within just a few years a cholesterol-lowering therapy confers a dramatic effect on cardiovascular morbidity and mortality. More recent studies indicate that there is a greater risk reduction in those subjects achieving lower low-density lipoprotein cholesterol (LDL-C) levels--i.e. lower is better. While this favours aggressive therapy, it is nevertheless imperative to precise patients selection for every therapy that entails a major commitment for the patient and medical community. Therefore, well-defined criteria for use of LDL-apheresis have yet to be established in the light of the expanding therapeutic armamentarium. Based on the current knowledge of the impact of statin therapy and anticipating that new options will further optimize the management of dyslipidemia in high-risk patients, we propose a reliable assessment of the effects of LDL-apheresis.

The Efficacy and Safety of the New Heparin-induced Extracorporeal Low-density Lipoprotein Precipitation System (Plasmat Futura) in Comparison with the Currently used System (Plasmat Secura)

The aim of the present study was to examine whether the recently introduced heparin-mediated extra-corporeal low-density lipoprotein precipitation (HELP) apheresis system Plasmat Futura (since 2001) was comparable to Plasmat Secura system, used to date, in its efficiency to remove atherogenic components, its ease of handling and operating as well as clinical safety and patient compliance. Coronary heart disease (CHD) patients (N = 21) were first treated with Plasmat Secura system and 13 of them were then randomly switched over to the upgraded Plasmat Futura system. Eight patients remained on Secura system. All together, 40 Futura treatments and 40 Secura treatments were performed. Blood samples were collected immediately before and after each apheresis therapy. Our data showed no significant differences in the reduction of plasma low-density lipoprotein, lipoprotein (a) and fibrinogen by Plasmat Futura and Secura system (P > 0.05). However, the major advantages of Plasmat Futura system are the ready-to-use sterile dialysis solutions instead of reverse osmosis device in Plasmat Secura, which ensures flexibility and lower risk of cross infections. Long-term tolerance and safety parameters showed no significant difference (P > 0.05). On the basis of our studies. Plasmat Futura system is easy to use, shows no adverse events and is comparable to Plasmat Secura in its capacity to remove proatherogenic plasma factors.

Efficacy and safety of DALI LDL-apheresis at high blood flow rates: A prospective multicenter study

Direct adsorption of lipids (DALI) is the first LDL-apheresis method compatible with whole blood. Usually, the blood flow rate is adjusted at 60-80 ml/min, which results in session times of about 2 hr. The present study was performed to test the safety and efficacy of low-density lipoprotein cholesterol (LDL-C) and lipoprotein (a) [Lp(a)] removal by DALI at high blood flow rates in order to reduce treatment time. Thirteen chronic DALI patients in seven centers suffering from hypercholesterolemia (LDL-C 162 +/- 42 mg/dl at baseline) and coronary artery disease were treated on a weekly or biweekly basis by DALI apheresis. The blood flow rate QB was held constant for at least two sessions, respectively, and was increased from 60 to 80, 120, 160, 200, and 240 ml/min. All patients had pre-existing av-fistulas. The anticoagulation was performed by a heparin bolus plus ACD-A at a ratio of citrate:blood ranging from 1:20 to 1:90. Clinically, the sessions were well tolerated and only 26/201 sessions (12%) of the treatments were fraught with minor adverse events. Acute LDL-C reductions (derived from LDL-C levels determined by lipoprotein electrophoresis) averaged 72/66/60/53/50/48% for QB=60/80/120/160/200/240 ml/min. Lp(a) reductions were 68/67/62/60/58/56%, whereas HDL-C losses were < or =10%. Routine blood chemistries and blood cell counts remained in the normal range. Treatment times averaged 142/83/45 min at Qb=60/120/240 ml/min. On average, DALI LDL-apheresis could be performed safely and effectively at high blood flow rates up to at least 120 ml/min in patients with good blood access, which significantly reduced treatment time from 142 to 83 min (-42%).

Direct adsorption of low-density lipoprotein and lipoprotein(a) from whole blood: results of the first clinical long-term multicenter study using DALI apheresis

Direct adsorption of lipoproteins (DALI) is the first low-density lipoprotein (LDL)-apheresis technique by which atherogenic LDL and lipoprotein(a) (Lp(a)) can be selectively removed from whole blood without plasma separation. The present study was performed to evaluate the efficacy, selectivity and safety of long-term DALI apheresis. Sixty-three hypercholesterolemic coronary patients were treated by weekly DALI sessions. Initial LDL-cholesterol (C) plasma levels averaged 238 +/- 87 mg/dl (range 130-681 mg/dl). On average, 34 sessions (1-45) were performed processing 1.5 patient blood volumes. The primary aim was to acutely reduce LDL-C by >or=60% per session. To this end, three different adsorber sizes could be employed, i.e., DALI 500, 750, and 1000, which were used in 4, 73, and 23% of the 2156 sessions, respectively. On average, 7387 ml of blood were processed in 116 min per session. This resulted in the following mean acute changes: LDL-C 198 --> 63 mg/dl (-69%), Lp(a) 86 --> 32 mg/dl (-64%), triglycerides 185 --> 136 mg/dl (-27%). HDL-C (-11%) and fibrinogen (-15%) were not significantly influenced. The mean long-term reduction of LDL-C was 42% compared to baseline while HDL-C slightly increased in the long run (+4%). The selectivity of LDL removal was good as recoveries of albumin, immunoglobulins, and other proteins exceeded 85%. Ninety-five percent of 2156 sessions were completely uneventful. The most frequent adverse effects were hypotension (1.2% of sessions) and paresthesia (1.1%), which were probably due to citrate anticoagulation. Access problems had to be overcome in 1.5%, adsorber and hardware problems in 0.5% of the sessions. In this multicenter long-term study, DALI apheresis proved to be an efficient, safe, and easy procedure for extracorporeal LDL and Lp(a) elimination.

Polyacrylamide gel as an acoustic coupling medium for focused ultrasound therapy

A hydrogel acoustic coupling medium was investigated as a practical alternative to water for clinical applications of focused ultrasound (US) therapy. Material characterization and functional testing of polyacrylamide gel couplers were performed. Acoustic, bulk and thermal properties were measured. Conical couplers were designed and fabricated to fit a 3.5-MHz, spherically concave transducer for functional tests, including Schlieren imaging, power efficiency measurements and in vivo hemostasis experiments. Polyacrylamide was shown to have favorable acoustic properties that varied linearly with acrylamide concentration from 10% to 20% weight in volume. Attenuation coefficient, sound speed and impedance ranged from 0.08 to 0.14 dB/cm at 1 MHz, 1546 to 1595 m/s and 1.58 to 1.68 Mrayl, respectively. An intraoperative in vivo hemostasis experiment in a sheep model demonstrated that the gel-coupled transducer was capable of inducing hemostasis in actively bleeding splenic and hepatic incisions. The results of this study show that polyacrylamide may be a promising coupling material for focused US therapy.

Indication of low-density lipoprotein apheresis in severe hypercholesterolemia and its atherosclerotic vascular complications: dextran sulfate cellulose low-density lipoprotein apheresis

Homozygous familial hypercholesterolemia (FH) and heterozygous FH, with or without elevation of Lp(a), or isolated massive elevation of Lp(a) with clinically relevant coronary heart disease are indications for low-density lipoprotein (LDL) apheresis, as long as maximal conventional lipid lowering drug therapy does not lead to a LDL cholesterol level below 100 mg/dL. Reduction of lipoproteins and Lp(a), of oxidation of LDL, improvement of disturbed vasomotion, the procoagulatory state and disturbed hemorheology associated with atherosclerosis, as well as the stabilization of plaques and the decrease of cytokines and adhesion molecules have been induced by apheresis and are thought to favorably influence regression of artherosclerosis. Several intervention studies point in this direction.

Clinical effects of direct adsorption of lipoprotein apheresis: beyond cholesterol reduction

Direct adsorption of lipoproteins (DALI) from whole blood is the first LDL hemoperfusion technique for extracorporeal LDL and Lp(a) elimination without initial plasma separation. Thus, this technique is characterized by high user-friendliness. In a long-term multicenter study, LDL and lipoprotein (a) (Lp(a)) reductions were 69% and 64%, respectively, per session. Adverse effects were rare, as 95% of the sessions were uneventful. Biocompatibility studies showed only minor blood-adsorber interactions for most parameters; however, there was a significant bradykinin generation. After a single session, significant reductions of plasma viscosity, erythrocyte aggregation and adhesion molecules were documented. A retrospective analysis of 18 chronic DALI patients revealed that in the majority of patients, symptoms like angina and dyspnea as well as their general status and subjective well-being improved significantly. Moreover, the objective cardiovascular event rate (MACE) decreased from a total of 26 in the 3-year period prior to DALI to 6 during a mean follow-up of 3.8 years during chronic DALI therapy. Thus, the average event rate of 0.48 per patient year at baseline could be significantly reduced to 0.09 (P < 0.004) by DALI. This impressive improvement of symptoms and coronary events can hypothetically be related to the improvement of hemorheology and the transformation of unstable into stable plaques by DALI LDL apheresis.

Modified DALI LDL-apheresis using trisodium citrate anticoagulation plus bicarbonate or lactate-buffered hemofiltration substitution fluids as primers

BACKGROUND

DALI (direct adsorption of lipids) is the first LDL-apheresis technique able to adsorb low-density lipoprotein (LDL) and lipoproteina) directly from whole blood. In the standard procedure, acid citrate dextrose (ACD-A) is used as anticoagulation and the adsorber is rinsed with a specially manufactured priming solution (PS). Using neutral trisodium citrate (TSC) instead of ACD-A might improve the acid-base homeostasis during DALI apheresis; moreover, applying wholesale hemofiltration solutions instead of the special PS might avoid the use of two separate solutions for both priming before and reinfusion after the treatment, thus simplifiying the procedure.

AIM

The present study was performed to test the effect of neutral (TSC) anticoagulation and of two different commercially available hemofiltration (HF) priming solutions on the efficacy and biocompatibility of DALI apheresis.

MATERIALS AND METHODS

Five hypercholesterolemic chronic DALI patients were treated prospectively, on a weekly or biweekly basis, 3 times each by standard DALI-apheresis (A). by DALI using 4% TSC and bicarbonate-buffered HF BIC35-210 priming (B). as well as by DALI using 4% TSC and lactate-buffered HF 23 priming (C). After the sessions, the extracorporeal circuit (ECC) was rinsed with saline in study arm A and with the corresponding HF solutions in study arms B and C, respectively.

RESULTS

Acute LDL-cholesterol reductions in the study arms A/B/C averaged 64/64/63%, for Lp(a) 62/64/62%, respectively (n=15). Clinically, all sessions were essentially uneventful and no clots were observed in the ECC. No major differences were found between the 3 study arms with respect to biocompatibility (elastase, C3a, thrombin-antithrombin, beta-thromboglobulin, bradykinin).

CONCLUSION

DALI apheresis using TSC anticoagulation and HF solutions for both priming and reinfusion proved to be as safe and effective as the standard DALI apheresis. These modifications, however, further simplify the procedure.

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.

In vitro evaluation of dextran sulfate cellulose beads for whole blood infusion low-density lipoprotein-hemoperfusion

We describe results from a feasibility study of a newly developed low-density lipoprotein (LDL) adsorbent designed for use in whole-blood infusion LDL-hemoperfusion. The adsorbent has almost the same chemical structure as the Liposorber adsorbent (dextran sulfate cellulose beads) but has a larger particle size. In whole-blood perfusion tests, the adsorbent adsorbed atherogenic LDL cholesterol directly from whole blood but left concentrations of high-density lipoprotein cholesterol largely unchanged. In whole-blood perfusion tests using fresh human donor blood or bovine blood anticoagulated with acid citrate dextrose solution or sodium citrate, the adsorbent showed minimal side effects in terms of blood cell activation, complement activation, and blood cell loss, suggesting that it has excellent blood compatibility. In addition, the adsorbent showed mechanical stability and absence of hemolysis. In conclusion, the new adsorbent showed the appropriate characteristics for an LDL adsorbent column for use in whole-blood infusion LDL-hemoperfusion.

Effects of direct adsorption of lipoproteins apheresis on lipoproteins, low-density lipoprotein subtypes, and hemorheology in hypercholesterolemic patients with coronary artery disease

Direct adsorption of lipoproteins (DALI) apheresis has been shown to reduce effectively low-density lipoprotein (LDL) cholesterol and lipoprotein (a) concentrations. However, the effects on nontraditional risk indicators such as hemorheology and LDL subtypes have not been investigated so far. Five patients (2 women, 3 men, age 53 +/- 8 years) with coronary artery disease and severe LDL hypercholesterolemia regularly treated with other LDL apheresis devices entered the study and were then treated with DALI for the first time. Hemorheological and lipoprotein parameters were measured before and immediately after the initial DALI apheresis as well as before the fourth DALI apheresis. Compared to baseline (before the first DALI apheresis), the following parameters were significantly improved (p < 0.05) after the first DALI apheresis: LDL cholesterol (69 +/- 28 versus 208 +/- 82 mg/dl) and cholesterol in each LDL subfraction as well as plasma viscosity (1.23 +/- 0.04 versus 1.37 +/- 0.06 mPa), C-reactive protein, native blood viscosity, red cell aggregation, and red cell deformability. When parameters before the fourth DALI apheresis were compared to baseline, LDL cholesterol was still lower, and red cell deformability was still improved while cholesterol in each subfraction showed a statistical trend to lower concentrations (0.08 < p < 0.14). In conclusion, DALI apheresis not only reduces LDL cholesterol but also induced a significant reduction of cholesterol in all LDL subfractions and improved various hemorheological parameters.

High-efficiency DALI apheresis using 1,250 ml adsorbers in a hypercholesterolemic obese patient: a case report

Direct adsorption of lipoproteins (DALI) apheresis is the first method for direct adsorption of lipoproteins from whole blood and is therefore an easy and rapid procedure. The majority of patients reaches >60% acute low-density lipoprotein cholesterol (LDL-C) reduction using either the DALI 750 or 1000 configuration. However, in patients with extremely high LDL-C levels or very large blood volumes, these configurations may lead to suboptimal results. The current study was performed to test the safety and efficacy of DALI 1250. In a severely obese patient (185 cm, 133 kg, blood volume 7.2 L, LDL-C 239 mg/dl), 11 L of blood (1.53-fold patient blood volume) was processed at a flow rate of 80 ml/min in 2.5 h; a combined heparin-plus-citrate anticoagulation regimen was used. Commercially available DALI 1250 and DALI hardware and disposables were manufactured by Fresenius HemoCare Adsorber Technology, St. Wendel, Germany. Twenty weekly sessions were performed. Clinically and technically, the apheresis sessions were completely uneventful. As compared to DALI 1000 (n = 4 sessions), the reduction rates by DALI 1250 (n = 20) improved for LDL-C (from 52% to 66%), lipoprotein (a) (Lp[a]) (53% vs. 66%), and fibrinogen (11% vs. 16%). There was a slight increase in high-density lipoprotein cholesterol (HDL-C) loss (20% vs. 24%). Moreover, the absolute amount of LDL-C removed per session increased from 5.06 g to 5.94 g. Laboratory safety parameters remained within the normal range, the anticoagulation was well controlled, and the pressure gradients over the adsorber remained constant. In this case report, DALI 1250 was perfectly safe and significantly increased the efficacy of LDL-C and Lp(a) elimination compared to standard DALI. Thus, this high-efficiency version of DALI may be used in patients with extremely high LDL-C levels and/or large blood volumes.

Improvement of hemorheology by DALI apheresis: acute effects on plasma viscosity and erythrocyte aggregation in hypercholesterolemic patients

Plasma viscosity (PV) and erythrocyte aggregation (EA) are determinants of microcirculation, especially under the compromised hemodynamic conditions resulting from atherosclerosis. Direct adsorption of lipoproteins (DALI) apheresis is the first method for direct adsorption of lipoproteins; it drastically reduces low-density lipoprotein (LDL)-cholesterol and lipoprotein (a) (Lp[a]), and may therefore improve PV and EA. The current study was performed to test the effect of DALI on hemorheology. Six hypercholesterolemic patients who had been on regular LDL apheresis for at least several months were treated on a weekly or biweekly basis, on average 5 times each by DALI. Before and after each session, PV was measured by a capillary tube plasma viscosimeter and EA by rotational aggregometry. Single DALI sessions (n = 31) acutely decreased PV from 1.18 +/- 0.04 to 1.06 +/- 0.3 mPa (-10%) while EA improved from 22.8 +/- 4.4 to 13.3 +/- 4.5 (arbitrary units) (-42%). LDL-cholesterol, Lp(a), and very-low-density lipoprotein (VLDL)-cholesterol were effectively reduced while the decrease of triglycerides and fibrinogen was only moderate. DALI apheresis exerted an acute positive effect on blood hemorheology which may have beneficial effects on microcirculation. This hypothesis is in accordance with the clinical observation that in some patients, improvement of angina and/or exercise tolerance can be observed after only a few DALI sessions where changes of coronary stenoses cannot be expected yet.

DALI low-density lipoprotein apheresis in homozygous and heterozygous familial hypercholesterolemic patients using low-dose citrate anticoagulation

The purpose of this study was to clarify the efficacy and safety of direct adsorption of lipoprotein low-density lipoprotein apheresis (DALI LDL apheresis) in patients with severe homozygous and heterozygous familial hypercholesterolemia who showed minor adverse effects during treatment with the usual DALI configuration (AC 1:20) through the use of a new system with low-dose citrate anticoagulation (AC 1:40) developed in order to minimize citrate-related adverse effects. Serum total cholesterol and LDL-cholesterol (LDL-C) showed a decrease of 57% to 61%, and 62% to 67%, respectively, in the 2 patients. Serum lipoprotein (a) (Lp[a]) was higher in the homozygous patient (Patient 1: MD) and within the normal range in the heterozygous patient (Patient 2: ES). In the former, Lp(a) was reduced by 52%. Serum high-density lipoprotein cholesterol (HDL-C) showed a statistically insignificant acute reduction: 15% to 19%. The observed reduction is mainly related to the well-known effect of hemodilution. The cardiovascular risk (total cholesterol/HDL-C) was reduced in both patients (46% to 54%) as expected. Serum triglycerides were reduced by 33% to 49%. The mean blood volume processed per session was 7,600 ml. Fifteen treatments for each patient have successfully been completed without the appearance of any clinically significant subjective and objective symptoms related to treatment with the new system.

Direct adsorption of lipoproteins from whole blood by DALI apheresis: technique and effects

Low-density lipoprotein (LDL) apheresis can drastically reduce atherogenic lipoproteins in coronary patients in whom LDL and lipoprotein (a) (Lp[a]) cannot be sufficiently reduced by conservative therapy. LDL and Lp(a) adsorption by polyacrylate/polyacrylamide (DALI) is the simplest procedure for clinical LDL apheresis to date. DALI was first applied in patients in 1994 and introduced into clinical routine in 1996. It is the first LDL-hemoperfusion system, i.e., it adsorbs LDL and Lp(a) directly from whole blood. This markedly simplifies the extracorporeal circuit, the handling of the system, and reduces significantly staff time and, especially at higher blood flow rates, treatment time. Its features are high selectivity and capacity of lipoprotein removal (maximum about 8 g low-density lipoprotein cholesterol per session). Using citrate anticoagulation, good biocompatibility is evidenced by the lack of cell losses, hemolysis, thrombotic events, and complement activation. Some clotting factors of the intrinsic system are also adsorbed. There is significant bradykinin activation that, however, does not cause problems in most patients if angiotensin converting enzyme inhibitor medication is avoided. In a first long-term study, 93% of sessions were uneventful. Major side effects were citrate-induced paresthesias (1.3%) and hypotension (0.8%). To date, more than 25,000 DALI sessions have been performed all over the world.

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.

Effect of low-dose citrate anticoagulation on the clinical safety and efficacy of direct adsorption of lipoproteins (DALI apheresis) in hypercholesterolemic patients: a prospective controlled clinical trial

Direct adsorption of lipoproteins (DALI) is the first lipid apheresis system compatible with whole blood with the advantage of a very simple procedure. A mixture of heparin plus citrate (ACD-A) is used for the anticoagulation regimen (AR). A clinical, prospective, controlled crossover study was performed to test the safety and efficacy of low-dose citrate (LDC) anticoagulation in DALI. Five chronic DALI patients suffering from coronary heart disease and hypercholesterolemia underwent 3 DALI sessions each using the LDC anticoagulation regimen (60 IU heparin/kg body weight as initial bolus; 1:40 ACD-A: blood as perfusion). This was compared to 3 sessions per patient with the standard AR (bolus of 20 IU heparin/kg, 1:20 ACD-A as perfusion). Patient blood volumes (1.6; average of 7,040 ml) were treated with 750 ml adsorber gel per session at a blood flow rate of 60 ml/min. Mean LDL and Lp(a) reductions exceeded 60% with both AR. No clinical side effects were observed. Both AR controlled the coagulation well as evidenced by a sufficient prolongation of the partial prothrombin time (PTT) and activated clotting time as well as low thrombin-antithrombin (TAT) formation. Biocompatibility parameters exhibited favorable results (low activation of complement and cells, and only slight formation of C3a, C5a, beta-thromboglobulin, elastase, and TNF-alpha). The asymptomatic bradykinin generation was comparable in both study arms. LDC optimized the ionized calcium levels and pH in the efferent blood postadsorber. LDC anticoagulation was safe and effective, and may further improve the tolerance of DALI apheresis in hypercholesterolemic patients.