Relationship between pulmonary functions and hemodialysis induced leukopenia?

The leukointegrin alpha d/beta 2 (alpha d/CD18): specific changes in surface expression in patients on hemodialysis

Alpha d/CD18 is a newly discovered leukocyte adhesion molecule with sequence homology to CD11a, b and c of the beta 2 integrin family. Little is known about alpha d expression in vivo, particularly how it compares with the other beta 2 integrins. Previous studies have demonstrated that beta 2 integrin expression, particularly CD11b, is upregulated in vivo during hemodialysis (HD) with complement activating membranes. These changes may contribute to the immunologic abnormalities seen in HD patients. Given the well described changes of beta 2 integrins in these patients, we hypothesized that alpha d expression could also be altered by HD. Using flow cytometry with two specific antibodies to alpha d, alpha d expression in healthy adults (n = 16) was compared on macrophages (MO) > polymorphonuclear cells (PMNs) > lymphocytes (LY). Phorbol ester treatment of leukocytes in vitro significantly increased expression on MO and PMN, but not LY. Chronic HD patients at baseline (n = 15) had elevated (P < 0.05) alpha d mean channel fluorescence (MCF) on MOs, PMNs and LYs compared to normals. PMN alpha d MCF increased at 15 min into HD, but then returned to baseline levels at 180 min. Alpha d MCF for LYs decreased at 180 min, while MOs levels were unchanged. Alpha d expression is increased in chronic renal failure and further regulated by hemodialysis, but with unique characteristics compared to the other beta 2 integrins. Alpha d may be important in abnormal cell-cell contacts in renal failure.

Oxygen, arterial blood gases and ventilation are unchanged during dialysis in patients receiving pressure support ventilation

This study was undertaken to observe whether dialysis-induced alveolar hypoventilation and arterial hypoxaemia occur during bicarbonate haemodialysis in patients receiving partial mechanical support with pressure support ventilation. Nineteen patients admitted to the medical intensive care unit requiring mechanical ventilation and haemodialysis were enrolled. Arterial blood gas, white blood cell (WBC) count, minute ventilation, respiratory rate, breathing pattern and blood pressure were measured according to the following time schedule: pre-dialysis (time 0), and at 15, 30, 60, 120, 180, 240 min thereafter. Results showed that, with the use of cuprammonium dialyser, the WBC count dropped immediately and reached the nadir 15 min after haemodialysis. Thereafter, it recovered and overshot the pre-dialysis values until the end of dialysis. The bicarbonate dialysate indeed resulted in rapid and significant metabolic alkalosis. However, no decrease of PaO2 occurred throughout haemodialysis. The tidal volume, minute ventilation and breathing pattern remained stable during haemodialysis. We conclude that neither dialysis-induced alveolar hypoventilation nor arterial hypoxaemia developed during bicarbonate dialysis in patients mechanically ventilated with the pressure support ventilation.

Alterations in soluble intercellular adhesion molecule-1 and vascular cell adhesion molecule-1 in hemodialysis patients

Hemodialysis (HD) patients can develop acute reactions during treatment as well as increased long-term susceptibility to infections and malignancies. Abnormalities in leukocyte adhesion may contribute to these processes. Recently, serum levels of soluble adhesion molecules have been detected in circulating blood of normal subjects and in patients with chronic renal failure. We studied the effects of a single dialysis session with new cuprophane membrane on the soluble (s) form of intracellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1), two adhesion molecules with a variety of immunologic roles. Significant elevations in both sICAM-1 (523 +/- 61 v 304 +/- 45 [SEM] ng/mL, P < 0.05) and sVCAM-1 (2,055 +/- 270 v 1,189 +/- 149 ng/mL, P < 0.05) were observed in HD patients at baseline compared with controls. Both sICAM-1 and sVCAM-1 levels decreased after a 3-hour HD session (P < 0.001). Early in HD, sICAM-1 levels, though lower than predialysis, were elevated in the exit line of the dialyzer compared with entrance (339 +/- 64 v 259 +/- 53 ng/mL, P < 0.001), whereas sVCAM-1 was decreased on the exit line compared with entrance (639 +/- 90 v 932 +/- 92 ng/mL, P < 0.001). Because ICAM-1 and VCAM-1 are important for many leukocyte functions, alterations in serum levels of sICAM-1 and sVCAM-1 may play a role in the immunologic consequences of uremia and HD treatment.

Activated and regulatory T lymphocyte populations in chronic hemodialysis patients

T lymphocyte activation after leukocyte membrane interaction may play a role in immune dysfunction associated with hemodialysis (HD). Studies of T-lymphocyte activation markers in HD have yielded conflicting results, perhaps due to the use of a limited number of markers and different measurement techniques. We studied the lymphocyte activation markers CD25 (interleukin-2 receptor), CD38, CDw49b (VLA-2), CD71 (transferrin receptor), and HLA-DR, as well as the surface antigens CD3, CD4, CD7, and CD8 by two-color flow cytometry in 23 chronic HD patients before and after a single dialysis session; we also studied 30 normal controls. There was no increase in the percentage of activated T cells in the controls and in the patients pre- and post-HD. Conversely, the percentage of CD3+/CD71+ (transferrin receptor) cells was significantly decreased in the patients pre-HD compared with the controls (3.6% +/- 0.5% [mean +/- SEM] v 5.9% +/- 0.5%; P < 0.005). A single dialysis session did not alter the percentage of activated subsets, but led to significant depletion in the number (x 10(9)/L) of cells that were CD3+ (1.10 +/- 0.10 v 0.97 +/- 0.09; P < 0.05), CD7+ (1.0 +/- 0.09 v 0.85 +/- 0.08; P < 0.0001), and CD8+ (0.50 +/- 0.06 v 0.37 +/- 0.04; P < 0.001), but not CD4+ cells (0.73 +/- 0.08 v 0.69 +/- 0.07; P = NS). These data indicate that the chronic HD patients at baseline "predialysis" do not appear to have an increased percentage of circulating activated T lymphocyte subsets and that the CD3+/CD71+ subset is in fact decreased.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of uremia and its treatment on pulmonary function

Alterations in respiratory drive, mechanics, muscle function, and gas exchange are frequent if not invariable consequences of uremia. Pulmonary dysfunction may be the direct result of circulating uremic toxins or may result indirectly from volume overload, anemia, immune suppression, extraosseous calcification, malnutrition, electrolyte disorders, and/or acidbase imbalances. The pulmonary system is unique because it is affected by the disease and its treatment. Acetate hemodialysis reduces alveolar ventilation and PaO2 due to extrapulmonic CO2 unloading. Peritoneal dialysis increases alveolar ventilation and intraperitoneal pressure. The latter leads to an elevated and lengthened diaphragm, a reduced functional residual capacity, basilar atelectasis, possible hypoxemia, and altered respiratory muscle function. In patients on chronic peritoneal dialysis, adaptations may occur that limit the reductions in lung volumes, PaO2, and respiratory muscle strength that are often observed during acute peritoneal dialysis. This review details how uremia and dialysis interact to alter pulmonary function.

Hypoxemia during hemodialysis: a critical review of the facts

The literature describing the fall in PaO2 during dialysis is intensively and critically reviewed. This phenomenon is related to both the type of membrane used (cellulosic v noncellulosic membrane), and to the composition of the dialysate (acetate v bicarbonate). It appears that a ventilation/perfusion mismatch due to pulmonary leukostasis can, in part, explain hypoxemia in patients dialyzed with cellulosic membranes. This phenomenon is especially apparent in patients with preexisting pulmonary abnormalities. However, hypoventilation remains the major cause of hypoxemia. This hypoventilation is mainly due to CO2 consumption during acetate metabolism (acetate dialysis), or alkalinization of the blood (bicarbonate dialysis). The metabolic consequences of acetate metabolism, and of bicarbonate and CO2 losses through the dialyzer are critically analyzed. The cause for the increment in oxygen consumption during acetate dialysis is examined. Finally, the respective role of these combined factors are described and used to explain the changes in VCO2, VO2, respiratory quotient (RQ), and PaO2 reported in the literature during dialysis against acetate and/or bicarbonate.

Biocompatibility of haemodialysis membranes

Haemodialysis is widely used as a method of treatment for renal failure; it relies on diffusion across a semipermeable membrane. The exposure of blood to the membrane is associated with a rapid transient fall in white cells, activation of the complement system and a fall in arterial oxygenation. The interrelationship between these phenomena, their dependence on the type of membrane used and their clinical implications are reviewed and discussed.

On the kinetics of complement activation, leucopenia and granulocyte-elastase release induced by haemodialysis

In order to elucidate the kinetics of haemodialysis-induced activation of complement, leucopenia and release of granulocyte-elastase, 10 patients (three females and seven males; mean age 47.8 years) were extensively studied during a 4 h haemodialysis treatment and for the following 24 h, and further compared with a healthy control group. Prior to dialysis patients had normal leucocyte count, plasma elastase bound to alpha 1-proteinase inhibitor (E-alpha 1P1) and total haemolytic complement, whereas plasma C3d was higher and plasma C5a lower than in controls. Haemodialysis induced initial leucopenia and subsequent rebound phenomenon lasting 24 h post treatment. These alterations were due to almost selective changes in neutrophile count as monocyte and lymphocyte counts, apart from decrease in the first 30 min, were unchanged. Total haemolytic complement decreased initially during dialysis and rose at the end. Generation of C5a within the dialyser was evident by demonstration of high levels of this anaphylatoxin in dialyser effluent plasma; maximal values observed coincided with the nadir of leukopenia. Plasma C3d and E-alpha 1P1 both progressively rose during dialysis. After termination of extracorporeal circulation the disappearance rates (T/2) were approximately 6 h and 2.5 h respectively. Haemodialysis thus induces changes in the complement and leucocyte system resembling an acute inflammation, which out-lasts the treatment period.

Pulmonary gas exchange during hemodialysis and peritoneal dialysis: interaction between respiration and metabolism

This review concerns the alterations in pulmonary gas exchange during hemodialysis and peritoneal dialysis. The occurrence of hypoxemia during hemodialysis has led to numerous studies that now provide sufficient data to explain this complex phenomenon. The role of substrate metabolism during hemodialysis and peritoneal dialysis are explored as it relates to alterations in ventilation. Comparison to similar types of ventilatory changes occurring during total parenteral nutrition are discussed. The effect of peritoneal dialysis on pulmonary function is also described.

Blood--dialyzer interactions: hemodynamic manifestations in an animal model

A sheep model is described that reliably produces acute pulmonary hypertension after blood, previously in contact with a number of different dialysis membranes including Cuprophan, enters the animal's circulation. This hemodynamic manifestation is associated with myocardial ischemia and arrhythmias and coincides in time with neutropenia but precedes maximal hypoxemia. The resulting pulmonary vascular response occurs following both exposure of flowing blood to a dialyzer in an extracorporeal circuit and reinjection of blood previously in static contact with a number of different devices for varying periods of time. Increasing volumes (1-15 ml) previously in static contact (10 min) with regenerated cellulose, saponified cellulose ester, and Cuprophan (hollow fiber and sheet form) caused varying increments in mean pulmonary artery pressure. Contact with either polyacrylonitrile or cellulose acetate resulted in little response. This effect was magnified with all the surfaces, even polyacrylonitrile and cellulose acetate, by prolonging the duration of contact up to 30 min. The hemodynamic events that occurred with this model are similar to those reported in the clinical entity of "dialyzer hypersensitivity." This model may be of value in the quest for elucidation of the mechanisms involved in this syndrome.

Leukopenia, hypoxemia, and complement activation during a single hemoperfusion

White blood cell count, acid-base balance, PO2, and complement function in five uremic patients undergoing a single hemoperfusion employing activated charcoal coated with methacrylate were studied. After 20 min on hemoperfusion, a marked leukopenia [ranging from 6,080 +/- 526 to 3,740 +/- 1,124 (p less than 0.02)] and hypoxemia [ranging from 106 +/- 13.8 to 80.2 +/- 11.9 mm Hg (p less than 0.02)] were observed. At the same time, total hemolytic complement decreased from 135 +/- 15.7 to 123 +/- 14.7 U/ml (p less than 0.001) and alternative pathway activity from 38.1 +/- 5.1 to 33.1 +/- 6.7 U/ml (p less than 0.005). C3 and B cleavage fragments were detected in the samples tested, thus demonstrating the activation of the complement alternative pathway. After 60 min, the different parameters tended to increase but did not reach the baseline levels. A direct correlation between the degree of leukopenia and the reduction of PO2 throughout the hemoperfusion period was found. pH PCO2, and HCO-3 did not change throughout the hemoperfusion period. The results demonstrate that complement activation, leukopenia, and hypoxemia occur during hemoperfusion.

Leukopenia with different regenerated haemodialysis membranes

The white blood cell count (WBC) decreases during haemodialysis and it was investigated as a function of different dialysis membranes. Each of them was used four times, applying different sterilization methods. Twelve chronic haemodialysis patients were studied and dialysed with cuprophan and polyacrylonitrile (PAN) membranes. Cuprophan was studied by a dry sterilization method and after perchloric acid and formalin treatment. PAN was studied with dry sterilization and after perchloric acid. As it has been shown, cuprophan membranes cause significantly more marked neutropenia than PAN. No significant difference was seen in pO2, pH, pCO2 and bicarbonate between dialysers used four times. The results indicate differences in biocompatibility between cuprophan and PAN membranes, independent of the sterilization method employed.

Leukopenia, hypoxia, and complement function with different hemodialysis membranes

Complement activation during exposure of plasma to cuprophan has been postulated to cause leukopenia and hypoxia in hemodialysis patients. To determine if hypoxia is related to leukopenia and if complement activation leads to a depletion of functional complement components, we dialyzed four patients three times sequentially against each of four types of membranes: cuprophan, regenerated cellulose, cellulose acetate, and polyacrilonitrile. Within 20 min there was a marked leukopenia with cuprophan from 5541 +/- 376 to 1216 +/- 94 (P less than 0.001) and with regenerated cellulose from 5541 +/- 411 to 1533 +/- 203 (P less than 0.001). With cellulose acetate, the change from 5558 +/- 400 to 3783 +/- 341 (P less than 0.001) was less dramatic, and with polyacrilonitrile the fall from 5591 +/- 381 to 464 +/- 401 (P less than 0.02) was minimal. After 2 and 4 hours of dialysis, a rebound leukocytosis was seen with cuprophan, regenerated cellulose, and cellulose acetate, but not with polyacrilonitrile. Transient thrombocytopenia occurred with cuprophan and regenerated cellulose. In spite of the variable degree of leukopenia, all membranes induced a similar and significant hypoxia, which was progressive throughout dialysis, even during the rebound leukocytosis. After 4 hours, the mean PO2 ranged from 91 to 93 mm Hg with all membranes. Functional hemolytic titers of whole complement, C3, C5, and C4 were normal prior to hemodialysis and failed to decrease after 4 hours with any membrane. It is concluded that hemodialysis leukopenia is membrane-dependent and is not the cause of hypoxia. In addition, hemodialysis complement activation does not lead to functional complement depletion and is of no clinical significance.

Plasma levels and effects of sulfinpyrazone in patients requiring chronic hemodialysis

Sulfinpyrazone (Anturane), which inhibits platelet synthesis of prostaglandins and platelet release of serotonin, was given to patients with chronic renal failure requiring hemodialysis. Patients were mateched in double-blind fashion to receive either placebo or sulfinpyrazone at 200 mg orally three times a day. Peak plasma levels of sulfinpyrazone after the first 200-mg dose ranged from 6.7 to 11.4 micrograms/ml (mean : 8.7 micrograms/ml). The plasma concentration showed a monoexponential disappearance pattern with an apparent half-life of 4 hours. At steady state, sulfinpyrazone peak plasma levels were 10.7 to 30.1 micrograms/ml. Residual plasma levels 12 hours after a final dose while in steady state were 3.7 and 4.3 micrograms/ml. Sulfinpyrazone protected against falls of platelet counts normally encountered during hemodialysis. Sulfinpyrazone blocked the increased platelet aggregability and the platelet uptake and release of serotonin normally seen following dialysis. Sulfinpyrazone prevented the consumption of antithyrombin III which is normally seen with hemodialysis, without having changed the anticoagulant efficacy of heparin. Sulfinpyrazone can be given to patients with chronic renal failure. It prevents platelet consumption during hemodialysis and protects against the decrement of antithyrombin III normally seen during hemodialysis.

A study on hemodialysis leukopenia using various dialyzers

Hemodialysis leukopenia was studied using various dialyzers and membranes. We found that dialyzers with cellulosic membranes caused marked leukopenia, but in recently developed non cellulosic membranes, its occurrence was significantly less. Additionally, our results showed a newly developed cellulose acetate membrane to correlate well with the non cellulose membranes regarding leukopenia, in spite of it being a derivative of cellulose. The extent of white blood cell decrease seemed to correlate inversely with an increase in the ultrafiltration rate per membrane area of dialyzer. The relationship between leukopenia and hypoxemia was examined also. The results of this investigation are included, however, we feel that more research is necessary before any conclusions can be made.