Biocompatibility study based on differential sequestration kinetics of CD14+CD16+ blood monocyte subsets with different dialyzers

The immune defect in hemodialysis (HD) patients is associated with a monocyte dysfunction, including an increase in the production of proinflammatory cytokines. Blood membrane contact leads to an increase in cellular activation and sequestration into the capillary bed of the lung. The influence of the sequestration on the number of mature monocytes was studied by analyzing the fate of monocytes, particularly, the CD14+CD16+ subpopulation, during HD treatment. In thirty stable HD patients, the distinct cell populations were determined by differential blood counts and flow cytometry. Patients with diabetes or systemic vasculitis, those showing evidence of infectious complications or malignancy, or those taking immunosuppressive medications were excluded from the study. Cells from this study population were analyzed before the start, 30 min thereafter, and at the end of HD treatment, each time using a different dialyzer: hemophan, methylmethacrylate (PMMA), triacetate membrane, cuprophane/vitamin E, acrylonitrile, and sodium methallylsulfonate polymer (AN69). The CD14+CD16+ subset decreased at 30 min and remained suppressed for the course of dialysis. To examine whether currently used biocompatible membranes differ in their effect on the sequestration of monocyte subpopulations, temporal monocytic changes were comparatively analyzed during HD with a different dialyzer. The drop in the first 30 min until the end of HD treatment was significant (p<0.05), very uniform, and sharp in all patients, and was independent upon membrane type. The CD14+CD16+ monocyte subpopulation showed increased and longer margination from the blood circulation during HD. Given the fact that CD14+CD16+ monocytes represent a sensitive marker for inflammation or cellular activation, the depletion of these cells may offer an easily accessible parameter that is more sensitive than complement activation for biocompatibility studies on forthcoming, improved dialyzer membranes.     

Changes in the beta 2-microglobulin level during hemodialysis

The authors studied changes of the beta 2-microglobulin level during hemodialysis with dialyzers AIP-02-02 (cuprophane membrane), E2 (cuprophane membrane), AIP-03-02 (polysulfone membrane), F60 (polysulfone membrane), and hemodiafiltration with dialyzer F60. The following data were obtained. The beta 2-microglobulin level in patients undergoing hemodialysis is approximately 20 times the normal level. No essential fluctuations of the level of this protein occurs during hemodialysis and hemodiafiltration. The cuprophane membrane does not cause increase of beta 2-microglobulin generation during hemodialysis. Standard hemodialysis with the cuprophane membrane and the highly-permeable polysulfone membrane does not lead to decrease of the beta 2-microglobulin level. Hemodiafiltration with the highly-permeable polysulfone membrane is an effective method for the elimination of this protein.     

Evaluation of phagocytic cell function in an ex vivo model of hemodialysis

An ex vivo model of hemodialysis was used to evaluate the effect of dialysis membranes on phagocytic cell function. Blood was withdrawn continuously from healthy, non-uremic donors, heparinized, and pumped, single pass, through membrane modules under conditions which simulated normal dialysis conditions. The membrane modules contained membranes of cellulose, DEAE-substituted cellulose, or polysulfone. Blood was obtained from the module outlets for determination of complement activation, phagocyte elastase release, zymosan-induced phagocyte chemiluminescence, and monocyte interleukin-1 production. Significantly less complement activation occurred with the polysulfone and DEAE-substituted cellulose membranes than with cellulose membranes. Normal monocyte interleukin-1 production was not stimulated by any of the membranes used. In contrast, the cellulosic, but not the polysulfone, membranes primed the oxidative burst of the phagocytes and caused them to release elastase. DEAE-substituted cellulose had a lesser effect on elastase release than did cellulose and elastase release correlated significantly with the degree of complement activation. However, the correlation between complement activation and priming of phagocyte oxidative burst was weak, suggesting that membranes affect phagocyte oxidative metabolism through more than one mechanism. We conclude that some dialysis membranes stimulate the bacteriacidal functions of normal phagocytic cells, in part through complement-dependent mechanisms.     

Biocompatibility Study Based on Differential Sequestration Kinetics of CD14+CD16+ Blood Monocyte Subsets with Different Dialyzers

The immune defect in hemodialysis (HD) patients is associated with a monocyte dysfunction, including an increase in the production of proinflammatory cytokines. Blood membrane contact leads to an increase in cellular activation and sequestration into the capillary bed of the lung. The influence of the sequestration on the number of mature monocytes was studied by analyzing the fate of monocytes, particularly, the CD14+CD16+ subpopulation, during HD treatment.

In thirty stable HD patients, the distinct cell populations were determined by differential blood counts and flow cytometry. Patients with diabetes or systemic vasculitis, those showing evidence of infectious complications or malignancy, or those taking immunosuppressive medications were excluded from the study. Cells from this study population were analyzed before the start, 30 min thereafter, and at the end of HD treatment, each time using a different dialyzer: hemophan, methylmethacrylate (PMMA), triacetate membrane, cuprophane/vitamin E, acrylonitrile, and sodium methallylsulfonate polymer (AN69).

The CD14+CD16+ subset decreased at 30 min and remained suppressed for the course of dialysis. To examine whether currently used biocompatible membranes differ in their effect on the sequestration of monocyte subpopulations, temporal monocytic changes were comparatively analyzed during HD with a different dialyzer. The drop in the first 30 min until the end of HD treatment was significant (p<0.05), very uniform, and sharp in all patients, and was independent upon membrane type.

The CD14+CD16+ monocyte subpopulation showed increased and longer margination from the blood circulation during HD. Given the fact that CD14+CD16+ monocytes represent a sensitive marker for inflammation or cellular activation, the depletion of these cells may offer an easily accessible parameter that is more sensitive than complement activation for biocompatibility studies on forthcoming, improved dialyzer membranes.     

Evolution of serum prealbumin following hemodialysis: effect of different dialysis membranes.

The effects of hemodialysis on the levels of serum prealbumin (pA) were studied on a crossover basis in 17 uncomplicated patients. Bicarbonate dialysate was used exclusively, and two different membranes, cuprophane and polysulfone, were compared. We aimed to prove the induction of an acute-phase response during the procedure. Serum pA, corrected for hemoconcentration, decreased significantly 24 h after the start of cuprophane hemodialysis and returned to the initial value within 48 h. No such change was observed using polysulfone membranes. These results were seemingly correlated with the effects of the membranes on complement activation. It is concluded that cuprophane hemodialysis is indeed associated with an acute-phase response, probably due to interleukin-1 release during the treatment, and that the membrane composition has some role in inducing it. Thus, serum pA analysis may prove useful as an indicator of the biocompatibility of the dialysis procedure.     

Comparison of blood biocompatibility during haemodialysis with cuprophane and polyacrylonitrile membranes

Clotting within the dialyser is one of the most significant clinical parameters of biocompatibility. A study was designed to evaluate the biocompatibility of two different dialysis membranes (cuprophane and polyacrylonitrile) during therapy with conventional heparin. Transient leukopenia during cuprophane but not during polyacrylonitrile haemodialysis was observed, and elastase release using polyacryonitrile membranes was reduced (P less than 0.001). An elevation in F VIII:C activity during cuprophane haemodialysis has to be taken as an indication of endothelial disturbances. There was a significant (P less than 0.001) platelet activation (beta-thromboglobulin) and combined thrombin/plasmin generation using cuprophane membranes. This new synthetic polyacrylonitrile membrane inactivates the clotting in an extracorporeal system to a sufficient degree and allows a reduction in dosages of heparin. Platelet activation, platelet turnover, disturbances of endothelium, fibrinolysis activation, and granulocyte activation are reproducible parameters of a described interaction model. They also permit a comparison of different haemodialysis membranes.     

Dialyzer membrane type and reuse practice influence polymorphonuclear leukocyte function in hemodialysis patients

BACKGROUND: Polymorphonuclear leukocyte (PMNL) production of reactive oxygen species (ROS) has been linked to hemodialysis (HD) associated morbidity. The effect of dialyzer membrane type and reuse on PMNL function has not been clearly defined. METHODS: The present report is a cross-sectional study undertaken in a cohort of patients undergoing regular HD, at enrollment into the Hemodialysis (HEMO) Study, to study the association between patient and dialysis-related factors and PMNL function. PMNL function was assessed by measuring PMA- and N-formyl methionyl-leucyl-phenylalanine (fMLP) -induced respiratory burst, and phagocytic activity toward Staphylococcus aureus. RESULTS: PMNL from patients dialyzed with polysulphone (PS) or cuprophane (CU) membranes showed higher PMA-induced respiratory burst activity compared with those exposed to substituted cellulose (cellulose acetate, cellulose triacetate, CA/CT) membranes, regardless of dialyzer reuse. The use of bleach as a cleansing agent during reuse was associated with higher PMA-induced PMNL superoxide production, as was the use of renalin when compared to aldehydes. In a subgroup of patients using PS dialyzers, reuse itself was associated with higher fMLP-induced superoxide production. The type of bleach-germicide combination during reuse showed that use of renalin as a germicide was also associated with higher PMNL phagocytosis index. The number of years on HD correlated inversely with PMA-induced PMNL superoxide response. Weaker PMNL response to fMLP was associated with greater comorbidity and poor functional status as quantified by Index of Coexisting Diseases (ICED) and Karnofsky scores, respectively. CONCLUSION: Our results indicate that dialyzer membrane type and the reuse process influence the oxidative response of PMNL among HD patients. The implications of these observations on clinical morbidity need to be further evaluated in prospective studies.     

Impact of dialyzer membrane on apoptosis and function of polymorphonuclear cells and cytokine synthesis by peripheral blood mononuclear cells in hemodialysis patients

Abstract:  In an in vivo crossover trial, we compared a cellulosic with a synthetic dialyzer with respect to polymorphonuclear cells (PMN) function and apoptosis, cytokine serum levels and synthesis by peripheral blood mononuclear cells (PBMC), and complement activation. Twenty hemodialysis (HD) patients were assigned in alternate order to HD with cellulose acetate (CA) or polysulfone (PS) dialyzer. After 2 weeks, patients were crossed over to the second dialyzer and treated for another 2 weeks. Apoptosis was assessed by flow cytometry in freshly isolated PMN. Phagocytosis and production of peroxide by PMN were studied by flow cytometry in whole blood. PBMC were isolated from blood samples and incubated for 24 h with or without lipopolysaccharide (LPS). There was no impact of dialyzer biocompatibility on PMN apoptosis and function, cytokine synthesis by PBMC or on their serum levels, serum levels of C3a, and terminal complement complex (TCC). Nevertheless, after HD, serum levels of complement correlated negatively with PMN phagocytosis and peroxide production, and positively with PMN apoptosis and cytokine production by PBMC. Although the results did not show a dialyzer advantage on the immunologic parameters, complement activation may have modulated cell function and apoptosis after HD.     

Role of complement and platelet-activating factor in the stimulation of phagocytosis and reactive oxygen species production during haemodialysis.

BACKGROUND: Neutrophil phagocytic functions have been studied extensively in haemodialysis (HD) patients; however, results are contradictory and the mechanisms that modulate phagocytosis and oxidative burst during dialysis are not completely understood. METHODS: The present study investigated neutrophil functions in a selected population of patients before and during clinical dialysis with cuprophane, and polyacrylonitrile (AN69) membranes. We measured phagocytosis of Escherichia coli and intracellular hydrogen peroxide (H2O2) production by flow cytometry in whole blood. RESULTS: Before dialysis, neutrophils from HD patients showed normal phagocytic capability and H2O2 formation. Phagocytosis of FITC-E. coli was significantly stimulated in cuprophane but not AN69-treated patients. Spontaneous and stimulated H2O2 production was enhanced with both cuprophane and AN69 membranes. We then investigated in vitro the role of complement and platelet-activating factor (PAF) in the activation of neutrophils. Incubation of whole blood with C5a increased phagocytosis but not H2O2 production. On the contrary, the addition of synthetic PAF showed a markedly stimulated H2O2 production without increase in phagocytosis. Moreover, during dialysis with formaldehyde-reused cuprophane, complement activation was abolished and phagocytosis was no longer enhanced, while the stimulation of H2O2 production persisted. In addition, we also excluded a particular role of the membrane itself in the activation of neutrophils. CONCLUSION: We demonstrated that in a selected population of HD patients, neutrophils exhibit normal phagocytic capability and normal intracellular H2O2 production. During dialysis, the stimulation of phagocytosis observed with cuprophane is complement dependent, whereas the enhanced H2O2 production observed with both cuprophane and AN69 membranes might be related to PAF production.     

Dialysis filter type determines the acute effect of haemodialysis on endothelial function and oxidative stress.

BACKGROUND: Endothelial function of large arteries is impaired in chronic haemodialysis patients and oxidative stress due to the dialysis procedure has been suggested as a causal factor. However, it is not clear whether different types of dialysis membranes affect endothelial function differently. Therefore we determined endothelium-dependent, flow-mediated dilatation (FMD) of the brachial artery as well as markers of oxidative stress immediately before and after haemodialysis (HD) with either a cellulosic cuprophane or a synthetic polysulphone dialyser in a blinded, randomized, cross-over study. METHODS: Twelve haemodialysis patients (age 55+/-3 years, time on dialysis 20+/-2 months, mean fluid change -1782+/-21 ml, systolic/diastolic blood pressure 139/75 mmHg) were included. Using a multi-gate-pulsed Doppler system (echo-tracking device) brachial artery FMD and nitroglycerine-induced, endothelium-independent vasodilatation (NMD) were measured. Patients were randomized to HD with either a polysulphone or a cuprophane membrane and were crossed over to the other filter. Investigators were blinded to the type of membrane used. Serum concentrations of oxidized LDL (oxLDL) and alpha-tocopherol as markers of oxidative stress were measured before and after each dialysis session. RESULTS: Data are given as mean+/-SEM. Treatment with polysulphone filter HD did not significantly affect FMD (baseline 9.3+/-2.0% vs after HD 9.6+/-1.8%). After dialysis with a cuprophane membrane FMD decreased from 9.4+/-2.1 to 7.4+/-1.8% (P<0.05). NMD was not significantly affected by HD irrespective of the membrane material used. Serum levels of oxLDL were not changed by either treatment; however, alpha-tocopherol concentrations fell significantly after dialysis with the cuprophane filter (baseline 18.0+/-2.3 after HD 16.6+/-1.3 micro g/ml, P<0.05), while alpha-tocopherol levels remained unchanged when the polysulphone membrane was used. CONCLUSIONS: The type of dialysis filter membrane determines the acute effect of haemodialysis on arterial endothelial function. Differences in biocompatibility and oxidative stress may account for the observed differential effects, since the decrease of FMD after dialysis with a cellulosic cuprophane membrane-but not with a synthetic polysulphone membrane-was associated with a reduction in serum vitamin E.     

High-flux dialysis lowers plasma leptin concentration in chronic dialysis patients

Leptin is a protein produced by fat cells and involved in body weight regulation. Plasma leptin is significantly higher in some hemodialysis (HD) patients than in normal controls. We examined the influence of dialyzer membrane biocompatibility and flux on elevated plasma leptin concentrations in hemodialysis patients. Employing a crossover design, leptin and tumor necrosis factor-alpha (TNF-alpha) levels were serially determined in eight chronic dialysis patients. Patients were dialyzed sequentially on low-flux cellulosic (TAF) dialyzers, low-flux (F8) polysulfone, high-flux (F80B) polysulfone, then low-flux polysulfone and cellulosic dialyzers again. Mean leptin concentrations were similar when low-flux polysulfone or cellulosic dialyzers were employed (141.9+/-24.2 microg/L versus 137.8+/-18.4 microg/L, respectively (P=NS). In contrast, leptin fell significantly on the high-flux polysulfone dialyzer (99.4+/-16.2 microg/L) compared with cellulosic (P < 0.005), and low-flux polysulfone dialyzers (P < 0.02). Leptin clearance by the high-flux polysulfone dialyzer was significantly higher than the low-flux dialyzers (50.4+/-21.5 v -9.6+/-10.3 mL/min; P=0.043), but did not account fully for the 30% decline in plasma leptin during the high-flux arm of the study. Concentrations of TNF-alpha were lower when high-flux polysulfone dialyzers were employed, but there was no correlation of individual TNF-alpha levels with leptin concentrations. High-flux dialysis lowers plasma leptin concentrations an average of 30%, but biocompatibility does not influence leptin levels. The decrease in plasma leptin on high-flux dialysis cannot be explained solely by enhanced clearance.     

Soluble adhesion molecules in children and young adults on chronic hemodialysis

Children on chronic hemodialysis (HD) present with impaired immunity that may result from disturbances in leukocyte migration, caused by changes in expression of adhesion molecules on endothelium and immunocompetent cells. However, it is still not clear whether the type of dialyzer or a single dialysis session influences the concentrations of soluble adhesion molecules in these patients. We evaluated by ELISA serum levels of soluble (s) VCAM-1, ICAM-1, L-selectin, and P-selectin in 22 patients on cuprophane HD (CU), 8 on polysulfone HD (PS), 10 on vitamin E-modified cellulose HD (VE), and 15 controls. In all HD patients, sVCAM-1 levels were elevated compared with controls and were higher in CU than in VE. The sICAM-1 concentrations were increased in VE compared with controls, but remained unchanged in CU and PS. The sL-selectin levels were reduced in all HD patients. The mean values of sP-selectin were comparable in CU, PS, and controls. The lowest levels were observed in VE. In CU patients, sVCAM-1, sICAM-1, and sP-selectin concentrations rose after HD. A single PS session had no impact on adhesion molecules, whereas a VE session increased the level of sVCAM-1. The type of dialysis membrane may change the profile of adhesion molecule concentrations, thus influencing the immune system of a child on HD. The increase in levels of adhesion molecules in the course of a single HD session, which was pronounced in CU and VE patients, suggests poor biocompatibility of these dialyzers.     

Use of a polysulfone hemodialysis membrane may prevent recurrent posterior reversible encephalopathy syndrome in a patient undergoing hemodialysis

A 71-year-old woman underwent hemodialysis (HD) treatment for chronic kidney disease. During HD, she developed headache, abnormalities in visual perception, and generalized convulsion. Brain magnetic resonance imaging (MRI) showed T2-hyperintensity lesions in the posterior lobe, and an electroencephalogram showed slow waves in all areas. Twenty days later, the T2-hyperintensity lesions had vanished. Furthermore, perfusion computed tomography (CT) and single-photon emission CT with N-isopropyl[¹²³I]-p-iodoamphetamine (IMP-SPECT) showed no significant abnormalities. The patient was diagnosed with posterior reversible encephalopathy syndrome (PRES) because she displayed typical clinical symptoms and MRI findings. Although several antihypertensive and antiseizure medications were administered, the patient experienced recurrent PRES. Therefore, we used a polysulfone dialyzer to reduce the oxidative stress and inflammation while preserving vascular endothelial function. After use of a polysulfone dialyzer membrane, the patient had no PRES episodes during the clinical course. This is the first study to demonstrate that use of a polysulfone dialyzer membrane instead of a cellulose membrane may prevent recurrent PRES.     

Impact of dialyzer membrane selection on cellular responses in acute renal failure: a crossover study

BACKGROUND: When acute renal failure (ARF) is severe enough to require dialysis, in-hospital mortality rates approach 60%. These alarming figures have been ascribed in part to advanced age and the high prevalence of comorbid conditions. In the past several years, a number of attempts have been made to investigate the impact of dialyzer membrane type on clinical outcomes. Unfortunately, to date, clinical studies addressing this question have reported conflicting results. METHODS: This crossover study examined the effect of dialyzer membrane type on cytokine synthesis by peripheral blood mononuclear cells (PBMCs), superoxide release by neutrophils, and apoptosis or programmed cell death of neutrophils in 24 patients with ARF requiring intermittent hemodialysis. The patients were assigned in an alternate order to a low-flux cellulose acetate (CA) or polysulfone (PS) dialyzer. After three consecutive dialysis sessions, patients were crossed over to the second dialyzer for three additional treatments. These cellular responses were measured upon dialyzer assignment and at the third and sixth dialysis session in relationship to the dialyzer type. RESULTS: The results of the study showed no impact of dialyzer biocompatibility on synthesis of tumor necrosis factor-alpha (TNF-alpha) or interleukin 10 (IL-10) by PBMCs, superoxide release by neutrophils, or neutrophil apoptosis. This held true regardless of the initial dialyzer assignment. Furthermore, there was no correlation between dialysis adequacy (measured by single-pool Kt/V) and postdialysis cellular responses. CONCLUSIONS: In summary, this study refines the question of biocompatibility by comparing a substituted cellulose rather than unsubstituted cellulose dialyzer to a PS dialyzer in the setting of ARF. The results failed to demonstrate a dialyzer advantage on the selected cellular responses.     

Effect of dialysis membranes on lipoprotein profile of serum in haemodialysed patients

The subjects of the studies were 31 haemodialysed (HD) patients with chronic renal insufficiency (CRI). In this group of patients the lipoprotein profile was determined and 8 patients were selected for further studies. During the study the patients were treated with cuprophane membranes for 6 months. For the next 6 months the same patients were treated using polysulfone dialysers, and for further 6 months HD with polysulfone dialysers was continued. Patients' sera were tested after every 6 months of treatment. The Δ values were calculated as 6-month HD with polysulfone minus 6-month HD with cuprophane (ΔI) and 12-month HD with polysulfone minus 6-month HD with polysulfone (ΔII). We concluded that after long-term HD with low flux polysulfone treatment the lipoprotein profiles improved, but the mechanism of the process is not clear.     

Removal of silicon,aluminum and beta2-Microglobulin in chronic haemodialysis patients

One hundred outpatients on chronic haemodialysis with polymethylmethacrylate (PMMA) membrane dialyzer were randomly chosen. A control group of 100 likewise randomly chosen outpatients were treated with cuprophane membrane dialyzer. In both groups the treatments lasted for one year. Comparison of the test results revealed that Si, Al and β₂M.G levels could be reduced in patients on chronic HD with PMMA.     

Oxidative stress in hemodialysis: Causative mechanisms,clinical implications,and possible therapeutic interventions

Oxidative stress (OS) is the result of prooxidant molecules overwhelming the antioxidant defense mechanisms. Hemodialysis (HD) constitutes a state of elevated inflammation and OS, due to loss of antioxidants during dialysis and activation of white blood cells triggering production of reactive oxygen species. Dialysis vintage, dialysis methods, and type and condition of vascular access, biocompatibility of dialyzer membrane and dialysate, iron administration, and anemia all can play a role in aggravating OS, which in turn has been associated with increased morbidity and mortality. Oral or intravenous administration of antioxidants may detoxify the oxidative molecules and at least in part repair OS‐mediated tissue damage. Lifestyle interventions and optimization of a highly biocompatible HD procedure might ameliorate OS development in dialysis.     

The effect of hemodialysis on lipid peroxidation

With regard to the variance in the levels of lipid peroxidation products (malonic dialdehyde and diene conjugates) the authors studied the impact of hemodialysis on lipid peroxidation. Transitory activation of lipid peroxidation with a subsequent decrease in the levels of lipid peroxidation products that were lower than initial ones were noted at the initial stages of hemodialysis performed with the use of a DEP-02-02 dialyzer (with a cuprophane membrane). The comparison of the input and output levels of lipid peroxidation products failed to demonstrate any generation of lipid peroxidation products inside the dialyzer. The systemic character of the activation effect in the onset of dialysis was established. It was proved that the effect did not depend on the material used for the membrane as there was no rise in the levels of lipid peroxidation products but a decrease in their concentration when the capillary dialyzers D1 and B2-100 were used. The study of the washings from the cuprophane membrane from the dialyzer DEP-02-02 demonstrated high levels of endotoxin which were several times higher than in those from the same membrane from the dialyzer D2. Endotoxin release into the circulation probably determined the transitory effect of the activation in the onset of the procedure performed with the dialyzer DEP-02-02. The authors discussed the possible origin of high initial levels of lipid peroxidation products observed in patients with terminal chronic renal failure who had undergone hemodialysis.     

Is dialysis membrane type responsible for increased circulating adhesion molecules during chronic hemodialysis?

BACKGROUND: Patients with chronic renal failure under maintenance hemodialysis (HD) present with numerous adverse effects including immunologic alterations. Serious abnormalities of neutrophil function have been reported to be associated with disturbed cell adhesiveness. These adhesion processes are mediated by cytokines and different adhesion molecules. PATIENTS AND METHODS: In this study, serum concentrations of the intercellular adhesion molecule ICAM-1, vascular cell adhesion molecule VCAM-1 and endothelial leukocyte adhesion molecule E-selectin were investigated during employment of different dialysis membranes (cuprophane: n = 23, cellulose: 8, polysulfone: 26, acrylonitrile: 7). These adhesion parameters from 64 patients before and after a hemodialysis session were investigated parallel to the serum levels of circulating cytokines and their inhibitors. RESULTS: Circulating ICAM-1 levels were not elevated in low-flux membranes and most of the high-flux HD membranes, except for one high-flux polysulfone membrane. cVCAM-1 levels were significantly elevated both in low- and high-flux dialysis membranes, whereas cE-selectin was not increased. cICAM-1 levels were not different before and after hemodialysis in the entire study group. In contrast, cVCAM-1 and cE-selectin levels increased significantly during HD in the entire study group (both p < 0.001). Serum levels did not correlate with the duration of end-stage renal failure and hemodialysis. Levels of circulating cytokine antagonists/inhibitors (Il-lra, Il-2R, TNFsRp55/75) were significantly increased in all patients before and after HD, whereas the serum concentrations of the corresponding circulating cytokines (I1-1beta, Il-1, TNF-alpha) were within normal ranges. CONCLUSION: Increased levels of cVCAM-1 which suggest an important role for immunological alterations in HD and cytokine-independent changes during HD sessions in all membranes without alterations of cICAM-1 in most membranes and unchanged cE-selectin indicate that processes such as uremia are responsible for these effects rather than membrane characteristics. The level of circulating adhesion molecules does not serve as an appropriate marker of membrane biocompatibility.     

Relative contribution of intrinsic lung dysfunction and hypoventilation to hypoxemia during hemodialysis

Two mechanisms have been proposed to explain hemodialysis (HD)-induced hypoxemia: reversible lung damage due to intrapulmonary leukostasis as a consequence of the contact of blood with the dialyzer membrane, or alveolar hypoventilation due to the loss of carbon dioxide through the dialyzer. To assess the role of these factors, seven chronically uremic patients were studied before and during 4-hr HD sessions using a cuprophane membrane and either acetate (AHD) or bicarbonate (BHD) dialysate. In AHD only we observed, by comparison with predialysis values, a significant hypoxemia, and a decrease of alveolar ventilation (VA), lung carbon dioxide output, and respiratory exchange ratio. In both the AHD hypoxemic group and BHD nonhypoxemic group, there was a similar decrease in lung carbon dioxide diffusing capacity (DLCO) and of white blood cells (WBC), and a positive correlation between arterial oxygen pressure and VA without modification of alveolo arterial PO2 difference, an argument against the existence of ventilation-perfusion or ventilation-diffusion mismatching. We conclude that, although WBC sequestration induced a lung damage evidenced by DLCO impairment, the key factor of hypoxemia observed in AHD was the hypoventilation.