Evidence for an independent role of metabolic acidosis on nutritional status in haemodialysis patients

BACKGROUND: Malnutrition in haemodialysis (HD) patients has been referred to underdialysis with low protein intake, and to acidosis. However, the separate effects of underdialysis and acidosis on nutrition have not been clearly demonstrated. To evaluate the role of the dialysis dose and of metabolic acidosis on nutrition, we measured the predialysis serum HCO3, pH, serum albumin, PCRn, Kt/V, and BMI in 81 uraemic patients on maintenance bicarbonate HD for 93+/-80 months. Patients with chronic liver diseases, malignancies, and cachexia were excluded. RESULTS: Mean age was 59+/-17 years, Kt/V was 1.29+/-0.21, PCRn 1.06+/-0.22 g/kg/day, serum albumin 4.07+/-0.28 g/dl, BMI 23+/-4 kg/m2, HCO3 21.1+/-1.9 mmol/l, pH 7.36+/-0.04. Serum albumin showed a significant direct correlation with: PCRn (P=0.001), HCO3 (P=0.001), pH (P=0.002), but no correlation with Kt/V and BMI. Serum HCO3 correlated inversely with PCRn (P=0.027). Multiple regression analysis confirmed the significant role of serum bicarbonate and age, but not of Kt/V, on serum albumin concentrations. The role of PCRn appeared to be marginal compared to serum bicarbonate in determining serum albumin levels. Dividing patients into two groups, serum albumin was 3.96+/-0.22 g/dl with HCO3 < or = 20 mmol/l and 4.18+/-0.31 g/dl in those with serum HCO3 > or = 23 mmol/l (P=0.002). PCRn in the same groups was respectively 1.14+/-0.24 g/kg/day and 1.01+/-0.23 g/kg/day (P=0.03). Most importantly, serum albumin levels did not appear to be affected by the dialysis dose, with Kt/V ranging from 0.90 to 1.88. CONCLUSIONS: In HD patients with adequate Kt/V, metabolic acidosis exerts a detrimental effect on serum albumin concentrations partially independently of the protein intake, as evaluated by PCRn. In the presence of moderate to severe metabolic acidosis, PCRn does not reflect the real dietary protein intake of the patients, probably as a result of increased catabolism of endogenous proteins. For this reason PCRn should be considered with caution as an estimate of the dietary protein intake in HD patients in the presence of metabolic acidosis.     

Predictive value of dialysis adequacy and nutritional indices for mortality and morbidity in CAPD and HD patients. A longitudinal study

BACKGROUND: The effects of dialysis inadequacy on patient survival and nutritional status and that of malnutrition on survival have not been clearly assessed. Studies comparing dose/mortality and morbidity curves on continuous ambulatory peritoneal dialysis (CAPD) and on haemodialysis (HD) are also needed, to assess adequate treatment on CAPD. METHODS: We have evaluated the effects of age, 13 pretreatment risk factors, serum albumin, transferrin, normalized protein catabolic rate, Kt/V, normalized weekly creatinine clearance, residual renal function and subjective global assessment of nutritional status on survival and morbidity, in a 3-year prospective study of 68 CAPD and 34 HD patients. RESULTS: Survivals did not differ for CAPD and HD patients. In the Cox hazard regression model, age, peripheral vasculopathy, serum albumin < 3.5 g/dl and Kt/V < 1.0/treatment on HD and < 1.7/week on CAPD were independent factors negatively affecting survival. On the contrary, adjusted survivals were not affected by gender, modality, other comorbid factors, normalized protein catabolic rate, or subjective global assessment of nutritional status. Persistence of residual renal function significantly improved survival. Observed and adjusted survival did not significantly differ for CAPD and HD patients with either low (HD, < 1.0/treatment; CAPD, < 1.7/week) or high ( > or = 1.0 and > or = 1.7) Kt/V. On HD, adjusted survivals were similar for 1.0 < or = Kt/V < 1.2 or > or = 1.2. On CAPD, Kt/V > or = 1.96/week was associated with definitely better survival, with only one death/23 patients versus 19/45, with Kt/V < or = 1.96. Survival was not different for 1.96 < or = Kt/V < 2.03 and > or = 2.03. Normalized weekly creatinine clearance and wKt/V were positively related on CAPD (r 0.39, P < 0.01) and wKt/V = 1.96 corresponded to 58 litres of normalized weekly creatinine clearance. CONCLUSIONS: Indices of adequacy were predictors of mortality and morbidity, both on CAPD and HD, whereas normalized protein catabolic rate and subjective global assessment of nutritional status were not. Serum albumin did not decrease during dialysis; hence its predictive effect for survival is due to the predialysis condition and not to dialysis-induced malnutrition.     

Interdialytic weight gain and nutritional parameters in chronic hemodialysis patients

The extent of interdialytic weight gain (IDWG) in chronic hemodialysis patients is usually attributed to the level of compliance with fluid restriction. However, in view of the substantial water content of food (and caloric content of beverages), IDWG also may be a function of calorie and protein intake and may reflect the nutritional state of patients. To investigate this theory, the relationship between 2-day IDWG and body weight, normalized protein catabolic rate (nPCR), serum albumin, and delivered Kt/V urea was assessed in a prospective, randomized study of 860 chronic hemodialysis patients in 56 dialysis units. Compared with patients having < 2 kg IDWG (n = 378), patients with > 3 kg IDWG (n = 138) weighed more (dry weight, 76.8 v 61.7 kg), had higher nPCR (1.15 v 0.96 g/kg/d), and had higher serum albumin levels (3.96 vs 3.79 g/dL) (all P < 0.001) but did not have different levels of Kt/V (1.04 v 1.06). When IDWG was assessed as a function of dry weight, patients with IDWG > 4.5% of dry weight (n = 151) had higher nPCR (1.17 v 0.94 g/kg/d) but weighed less (60.1 v 70.0 kg) and had a higher Kt/V (1.14 v 1.01) than patients with IDWG < 3% of dry weight (n = 355) (all P < 0.001). Artifactual association between IDWG and nPCR attributable to an accentuated two-pool effect from differing ultrafiltration requirements was unlikely as assessed by the relationship between modeled Kt/V and prescribed Kt/V determined using an anthropometric urea volume.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hydrogen peroxide induces protection against lethal effects of cumene hydroperoxide in Escherichia coli cells: an Ahp dependent and OxyR independent system?

Despite a large body of evidence showing the beneficial effects of successful treatment of anemia with recombinant human erythropoietin (EPO) in patients with end-stage renal disease, controversy remains as to whether EPO treatment of anemia can improve the nutritional status in patients on maintenance hemodialysis. This prompted us to conduct a prospective study in 41 hemodialysis patients with basal hemoglobin less than 9 g/dl. The dose of EPO was increased for 12 weeks to achieve the target hemoglobin concentration of 10 g/dl and then titrated in the following 12 weeks to maintain the target value. Nutritional status was assessed at baseline and after 6 months of follow-up, using the global protein-calorie malnutrition (PCM) index proposed by Bilbrey and Cohen. A low global PCM score indicates better nutrition. The results showed that hemoglobin values significantly increased from 8.7 +/- 0.8 g/dl at baseline to 10.7 +/- 0.5 g/dl in the 6th month (p < 0.001). No significant changes were observed in the normalized protein catabolic rate and Kt/V during the study period. Global PCM scores improved from 30.0 +/- 7.5 to 23.6 +/- 3.1 (p < 0.001) and paralleled the correction of anemia by EPO treatment. The data were consistent with a major improvement in the nutritional markers of relative body weight, triceps skinfold, midarm circumference, midarm muscle circumference, serum albumin, serum transferrin and total lymphocyte count in the 6th month as compared to baseline. The percentages of mild and moderate-severe PCM at baseline were 32 and 58%, respectively. These percentages were significantly reduced during the 6th month to 20 and 30%, respectively (p = 0.0004). In summary, correction of renal anemia with EPO improves the nutritional status in hemodialysis patients. A postulated mechanism is that EPO may exhibit anabolic effects, with a better utilization of ingested protein.     

Cesarean section rates: effects of participation in a performance measurement project

BACKGROUND: According to previous studies, postdialysis urea rebound (PDUR) is achieved within 30-90 min, leading to an overestimation of Kt/V of between 15 and 40% in 3- to 5-hour dialysis. The purpose of the study was to assess the impact of PDUR on the urea reduction ratio (URR), Kt/V and normal protein catabolic rate (nPCR) with long 8-hour slow hemodialysis. METHODS: This study was performed in 18 patients (13 males/5 females), 62.5 +/- 11.7 years of age, hemodialyzed for 3-265 months. Initial nephropathies were: 3 diabetes; 2 polycystic kidney disease; 3 interstitial nephritis; 2 nephrosclerosis; 3 chronic glomerulonephritis, and 5 undetermined. Residual renal function was negligible. The dialysis sessions were performed using 1- to 1.8-m2 cellulosic dialyzers during 8 h, 3 times a week. Blood flow was 220 ml/min, dialysate flow 500 ml/min, acetate or bicarbonate buffer was used. Serial measurements of the urea concentration were obtained before dialysis, immediately after dialysis (low flow at t = 0), and at 5, 10, 20, 30, 40, 60, 90 and 120 min, and before the next session. The low-flow method was used to evaluate the access recirculation, second-generation Daugirdas formulas for Kt/V, and Watson formulas for total body water volume estimation. The difference between the expected urea generation (UG) and urea measured after dialysis (global PDUR) defines net PDUR (n-PDUR). RESULTS: The n-PDUR usually became stable after 58 +/- 25 (30-90) min. Its mean value was 17 +/- 10% of the 30-second low-flow postdialysis urea (3.9 +/- 2 mmol/l). This small postdialysis urea value and the importance of UG in comparison with shorter dialysis justify the use of n-PDUR. Ignoring n-PDUR would lead to a significant 4% overestimation (p < 0.001) of the URR (79 +/- 7 vs. 76 +/- 8%), 12% of Kt/V (1.9 +/- 0.4 to 1.7 +/- 0.38) and 4% of the nPCR (1.1 +/- 0.3 to 1.05 +/- 0.3). n-PDUR correlated negatively with postdialysis urea (r = 0.45 p = 0.05), positively with URR (r = 0.31 p = 0.01) and Kt/V (r = 0.3 p = 0.03) but not with K, and negatively with the urea distribution volume (r = 0.33 p = 0.05). Mean total recirculation, ultrafiltration rate, predialysis urea levels and urea clearance did not correlate with n-PDUR. CONCLUSION: We found a significant PDUR in long-slow hemodialysis after a mean of 1 h after dialysis. This PDUR has a less important impact upon dialysis delivery estimation than short 3- to 5-hour hemodialysis, especially for the lower Kt/V or URR ranges. This is explained by the low-flux, high-efficiency, and long-term dialysis. Its inter-individual variability incites us to calculate PDUR on an individual basis.     

Daily home haemodialysis in The Netherlands: effects on metabolic control, haemodynamics, and quality of life

BACKGROUND: More frequent dialysis has been claimed to improve clinical outcome and quality of life. METHODS: Clinical status was optimized in 13 haemodialysis patients during a run-in period of 2 months with three dialysis sessions a week. Thereafter, daily home haemodialysis (DHHD, 6 sessions per week) was initiated. The total weekly dialysis dose (Kt/V) was kept constant. RESULTS: Weekly Kt/V was 3.2+/-0.13 (M+/-SEM) before, and 3.2+/-0.15 after 6 months of DHHD (NS), time-averaged concentration of urea (TACu) was 21.2+/-1.6 mmol/l and 20.1+/-0.9 mmol/l (NS). Urea reduction was 0.56+/-0.05 before DHHD, and 0.41+/-0.06 during DHHD (P<0.0001). Serum K remained unchanged, but significantly less exchange resins were used (P<0.02). Also, the dose of phosphate-binding agents could be decreased. Values for Na, K, Cl, bicarbonate, Ca, PTH, albumin, and Hb remained unchanged. Iron deficiency developed in some patients. Twenty-four-hour blood pressure monitoring showed a decrease of systolic blood pressure (141.1+/-17.2 mmHg before, and 130.9+/-19.2 mmHg during DHHD, P<0.001). Diastolic blood pressure remained constant (82.8+/-7.2 and 76.9+/-10.1 mmHg, NS). Mean arterial pressure decreased from 102.2+/-9.5 to 94.9+/-1.4 mmHg (P<0.02). Blood pressure decreased mainly in previously hypertensive patients. Mean target weight increased 0.8 kg. The amount of antihypertensive drugs used decreased from 1.88+/-0.35 to 0.75+/-0.17 (P<0.005, n=7). Dialysis sessions were much more stable, also in patients with cardiac insufficiency. Quality of life questionnaires (Rand 36, Nottingham Health Profile, Uraemic Symptoms Profile) showed a significant improvement of physical condition and fewer uraemic symptoms. CONCLUSION: DHHD compared to conventional thrice-weekly haemodialysis with similar weekly Kt/V results in an improved haemodynamic control and quality of life, but has lesser impact on metabolic regulation.     

Chronic renal replacement therapy in children: which index is best for adequacy?

BACKGROUND: The dialysis dose, Kt/V, and Solute Removal Index (SRI) have been proposed as tools to measure and compare adequacy of different renal replacement therapies in adults. The aim of our study was to elucidate whether the Kt/V and SRI could be appropriate parameters to compare different treatments and define adequacy targets in children. METHODS: Twenty-two pediatric chronic dialysis patients (2 to 17 years) were prospectively studied. Six patients were on continuous ambulatory peritoneal dialysis (CAPD), 7 patients were on automatic nightly peritoneal dialysis (ANPD), and 9 were on hemodialysis (HD). Patients had no peritonitis and were not hospitalized during the previous two months and, as proved by growth and subjective well being, were in steady state condition at the initiation of the protocol. As a consequence, the treatment delivered was assumed to be adequate and the prospective analysis was carried out within one month. Urea levels in dialysate, plasma and urine were measured to determine urea kinetics and measure adequacy parameters. RESULTS: Instantaneous urea clearance was much higher when hemodialysis was used (124.67 +/- 32.04 ml/min) compared to CAPD (2.79 +/- 0.29 ml/min) and ANPD (6.60 +/- 1.42 ml/min), as expected. The Urea dialytic clearance per week was greater in HD (67320 +/- 17299 ml) than in CAPD(28144 +/- 2895 ml) and ANPD (29910 +/- 4234 ml). Residual renal function contributed to the overall weekly clearance by 47% in CAPD, while it was only by 19% in HD and 26% in ANPD. The overall weekly clearance was therefore 79,842 ml/week in HD, 53,340 ml/week in CAPD and 41,012 ml/week in ANPD. Weekly dialytic Kt/V results were much higher in HD (3.75) than in CAPD (1.78) and ANPD (2.37). To these values, the renal Kt/V was added, reaching the values of overall (dialytic + renal) weekly Kt/V of 4.53 in HD, 3.41 in CAPD and 3.41 in ANPD. Although higher Kt/V values were observed in HD, when the SRI % was considered, HD appeared to be less efficient compared with the other two techniques. Since postdialytic rebound in HD patients averaged 22.5%, we may speculate that hemodialysis in children is less efficient than continuous or daily peritoneal dialysis because of a remarkable cardipulmonary recirculation and solute sequestration. CONCLUSION: In the global evaluation, dialysis SRI% appears to be more reliable as an index of adequacy compared to Kt/V in children. At least an integration between the two indices is strongly recommended.     

Impaired delivery of hemodialysis prescriptions: an analysis of causes and an approach to evaluation

Serial kinetic modeling is commonly used in hemodialysis to assess the adequacy of dialysis. A variety of problems lead to declining Kt/V in previously stable patients. These include noncompliance, vascular access recirculation, and dialyzer dysfunction. The purpose of this study was to find the relative frequencies of these problems in a group of patients undergoing routine hemodialysis. Simultaneous urea kinetic modeling and access recirculation were tested during 3 consecutive months. The baseline Kt/V was defined as the average of each patient's Kt/V values obtained during the previous 4 mo. A clinically important fall in Kt/V was defined as a decline of > or =0.2 if the baseline Kt/V was > or =1.2, or a decline of > or =0.1 if the baseline Kt/V was <1.2. Ninety-three of 375 (25%) sessions met the criteria for a significant decline in urea kinetic modeling. The baseline Kt/V in this group was 1.33 +/- 0.20 (mean +/- SEM) and declined to 1.02 +/- 0.18 in the abnormal month (P < 0.05). In 42% of instances with a decline of Kt/V, reduced blood processing due to a lower blood flow or shorter time than prescribed was responsible. Recirculation of >12% was found in 25% of sessions with a decrease in Kt/V. These patients most often had access dysfunction or reversed needles. The remaining one-third of patients with decreases in Kt/V had no problem identified, and subsequent monthly kinetic modeling results returned to baseline. These results suggest that analysis of falling urea kinetic modeling results should include a careful review of the dialysis record for reductions in prescribed time or blood flow rates followed by vascular access testing. If these evaluations are unrevealing, urea kinetic modeling results usually return to baseline in the next month.     

Long-term experience with an ultrapure individual dialysis fluid with a batch type machine

BACKGROUND: This paper discusses long-term experience with a specific type of dialysis equipment which has been used more than 15 years without variation. The system was designed to allow easy individualization of dialysis fluid composition and to deliver dialysate of the highest hygienic quality. METHODS: Data from 399 patients covering the period from 1971 onwards were analysed retrospectively. Survival probabilities were estimated by the Kaplan-Meier method and the median number of days in hospital was calculated. Additional data collected from patient subgroups included serum albumin level, erythropoietin requirement and antihypertensive treatments. Kt/V and PCR from one subgroup were computed using the formulae of Daugirdas and Depner. RESULTS: The estimated survival probability after 5 years for all patients was 59.1% (95% CI: 52.6-65.6%). The main risk factors from the available covariables were age and IDDM. The cumulative incidence of carpal tunnel syndrome after 10 years of dialysis was estimated as 7% (95% CI: 0-14%). Data from the subgroups revealed that 82% of the patients had serum albumin levels >4.0 g/dl, 65% of the patients received no antihypertensive drugs and 39% received erythropoietin (37 +/- 28 units/kg bw/week) to correct dialysis anaemia (haemoglobin level = 98 +/- 8 g/l). Average Kt/V was 1.21 +/- 0.17, PCR was 1.10 +/- 0.22 g/kg/day. CONCLUSIONS: The setup described permits individualized therapy of high quality. The high serum albumin values and our very low incidence of carpal tunnel syndrome underline the importance of water and dialysate quality.     

Dialysis adequacy and nutrition determine prognosis in continuous ambulatory peritoneal dialysis patients

Peritoneal membrane function was assessed in patients undergoing continuous ambulatory peritoneal dialysis (CAPD) using parameters derived from urea kinetic modeling and the peritoneal equilibration test (PET). Their relationships with other nutritional markers and overall morbidity were determined. Data regarding the patients' nutritional status as determined by total body nitrogen (TBN) measurements, hospital admissions, and infectious complications within the last 12 months were reviewed. Total dialysate clearance (Kt/V) delivered was highly dependent on residual renal function (P < 0.0001). Kt/V derived from peritoneal clearance diminished with increasing age (P < 0.05). A higher delivered total Kt/V was associated with higher normalized protein catabolic rates (P < 0.002), which in turn were associated with improved TBN (P < 0.05). Hospital admissions decreased with improved normalized protein catabolic rates (P < 0.05), and higher serum albumin and total protein levels (P < 0.01 and P < 0.002, respectively). Infectious complications correlated positively with time on dialysis (P < 0.01), and correlated negatively with TBN measurements (P = 0.05). No correlations were found between infectious complications and serum albumin level or peritoneal protein loss. However, the total duration of hospitalization was shortened with higher serum albumin and total protein levels (P < 0.0001 and P < 0.002, respectively). Although Kt/V determinations did not correlate with clearances determined by the PET, the PET-determined creatinine transport rate correlated with TBN (P < 0.05) but not with infectious complications. In conclusion, nutritional parameters correlate with outcome on continuous ambulatory peritoneal dialysis. An integral relationship exists between nutritional status and dialysis delivery, which is best assessed by urea kinetic modeling.     

On-line assessment of delivered dialysis dose

BACKGROUND: The adequacy of the delivered dialysis dose is essential to prevent patient morbidity and mortality. The determination of effective ionic dialysance (D) is easy, non-invasive and inexpensive, and its use instead of effective urea clearance (K) in kinetically determining apparent" urea distribution volume (Vt) is likely to lead to a correct Kt/V, even though the Vt value may be incorrect. The aim of this study was to test the possibility of using the measurement of D to monitor Kt/V on-line during each dialysis treatment. METHODS: Forty-four patients were dialyzed using a monitor equipped with specially designed "Diascan Module" (COT; Hospal) that measures effective D by means of a single conductivity probe. Vt was calculated according to the SPVV three BUN method urea kinetic model using D instead of K values. One month later, Kt/V was calculated as Dt/V, using actual D and T values and the predetermined Vt values updated for the current final body wt. Both the Dt/V and Kt/V determined according to the Smye and Daugirdas methods were compared with the Kt/V determined using the SPVV kinetic model (Kt/Veq) RESULTS: The Kt/V values calculated using ionic dialysance and predetermined Vt were approximately equivalent to those of Kt/Veq (1.14 +/- 0.16 vs. 1.14 +/- 0.17, mean difference 0.00 +/- 0.07), as were those determined according to the Smye and Daugirdas methods (1.10 +/- 0.18 and 1.13 +/- 0.17, mean difference -0.03 +/- 0.06 and 0.01 +/- 0.06, respectively). CONCLUSION: Once Vt has been determined, the evaluation of ionic dialysance in stable patients makes it possible to calculate the Kt/V accurately at each dialysis session without blood or dialysate sampling, and at no additional cost.     

Assessment of dialysis adequacy using the dialysate urea monitor: preliminary experience of the dialysate urea monitor

Numerous studies have identified a strong linkage between the delivered dialysis dose (Kt/V) and the survival of hemodialysis (HD) patients. However, the current method used to calculate Kt/V requires multiple blood samples and the process is complex and time consuming. We evaluate the performance of a recently developed on-line monitor (Biostat 1000 dialysate urea monitor, Baxter) that measures the urea concentration in the effluent dialysate and displays Kt/V and nPCR immediately after hemodialysis. To verify the performance of the urea monitor, we selected 21 hemodialysis patients, calculated their Kt/V and nPCR values from blood samples obtained during each hemodialysis, and compared the results with data obtained using the urea monitor. The Kt/V and nPCR values calculated by the urea monitor were both significantly correlated with those obtained using blood samples (R = 0.804, p < 0.001 in Kt/V and R = 0.749, p < 0.001 in nPCR). Our results suggest that the urea monitor may be used for on-line assessment of dialysis adequacy and obviates the need for blood sampling.     

Fluid dynamics of gingival tissues

Determining adequacy of dialysis has remained a problem for the nephrologist despite the results of the National Cooperative Dialysis Study published more than 20 years ago. Urea Kinetics Modelling (UKM) which requires computer data entry is time-consuming for the dialysis staff but is the only method that has been rigorously studied. Furthermore, it is unclear today what value of Kt/V represents ideal dialysis; the technique is subject to a number of errors associated with estimation of dialyser clearance (K) and volume of distribution of urea (V) but it is useful for calculating protein catabolic rate (PCR). Methods that use urea reduction ratios (URR) is widely used because it is simpler but not always accurate and suffer from an inability to calculate PCR. Direct dialysis quantification (DDQ) can overcome a number of these problems but it is too cumbersome for routine use. Simpler methods to determine dialysateside kinetics have the advantage of solving a number of these problems and also facilitate the calculation of PCR to determine the patient's nutritional state. In our study we have demonstrated that by taking two dialysate samples at the beginning and at the end of dialysis (2-DSM), it is possible to determine total urea removal (TUR) which is equivalent to DDQ. By taking blood samples after dialysis and before the next dialysis, it is possible to calculate the total urea generated (TUG). The ratio of TUR/TUG will provide an index of dialysis which places emphasis on removal of solute that has accumulated in the inter-dialytic interval thus re-establishing a state of equilibrium. We refer to this index as the Mass Balance Index (MBI). The MBI is also useful in helping to identify those patients whose PCR is inadequate since the mean MBI for patients with an nPCR <0.8 was 0.93 +/- 0.03 vs 1.08 +/- 0.02 in those with a PCR >0.8. In these two groups of patients the Kt/V was not significantly different, 1.49 +/- 0.07 vs 1.53 +/- 0.06, p -0.64. We suggest that the emphasis for adequacy of dialysis should shift away from Kt/V to maintaining a state of equilibrium by removing the solutes that accumulate between dialysis and by identifying those patients with an inadequate PCR.     

Pathology of preinvasive and excellent prognosis breast cancer

BACKGROUND: Erythropoietin (EPO) therapy is a common and effective treatment for the correction of anemia in patients with end-stage renal disease. Simultaneous treatment with angiotensin-converting enzyme (ACE) inhibitors for the control of hypertension and/or heart failure is often necessary. Recent reports in the literature have raised concern about a potential interaction between these drugs, with a resultant decreased EPO efficacy. METHODS: To investigate whether this interaction occurs in chronic dialysis patients, we retrospectively reviewed the records of 175 patients receiving chronic dialysis. All study patients were treated with EPO for at least 3 months, and had normal iron indices. Patients were treated with ACE inhibitors for at least 3 months, at a constant daily dose for at least 1 month (group 1, n = 32), or did not receive ACE inhibitors (group 2, n = 143). Patients with infections or overt iron deficiency were excluded. Total weekly EPO doses and hematocrit (Hct)/hemoglobin (Hgb) values in the two groups were compared. Variables known to affect response to EPO were compared, including ferritin, transferrin saturation, dialysis dose and serum aluminum. RESULTS: Total weekly EPO dose was 17,358 +/- 6,871 units in group 1 and 17,612 +/- 7,744 units in group 2 (p = 0.854). The achieved Hct was 32.1 +/- 4.4% (group 1) and 30.5 +/- 4.0% (group 2) (p = 0.079). Similarly, Hgb, ferritin, transferrin saturation, Kt/V, and serum aluminum were not different. The dose or duration of ACE inhibitor therapy did not affect Hgb or Hct. Thus, ACE inhibitor therapy does not appear to affect response to EPO in chronic dialysis patients.     

Low dialysate [K+] decreases efficiency of hemodialysis and increases urea rebound

In a previous study, it was reported that hemodialysis with dialysate [K+] (KD) of 1.0 or 2.0 mmol/L caused an increase in BP shortly after completion of treatment due to arteriolar constriction. With this background, it was hypothesized that a low KD might decrease dialysis efficiency by a similar mechanism. To evaluate this hypothesis, paired observations of two consecutive 3-h treatments, with KD of 1.0 or 3.0 mmol/L, were performed in 14 stable end-stage renal disease patients. A KD of 1.0 mmol/L resulted in lower values for both urea reduction ratio and Kt/V evaluated at completion of dialysis and 1 h thereafter. Values at equilibrium were urea reduction ratio 42+/-1% versus 47+/-2% (P < 0.02), Kt/V 0.65+/-0.03 versus 0.73+/-0.03 (P < 0.02) for KD 1.0 or 3.0 mmol/L, respectively. The mechanisms responsible for the observed differences in dialysis efficiency were examined using a urea kinetics model that predicts urea sequestration caused by impaired blood flow to urea-rich tissues. For this purpose, urea rebound and its effect on Kt/V (by means of deltaKt/V, calculated as equilibrated minus single pool value) with KD 1.0 and 3.0 mmol/L were assessed. Greater urea rebound, 12.8+/-1.6% versus 8.6+/-1.4% (P < 0.001), and larger deltaKt/V, 0.12+/-0.01 versus 0.10+/-0.02 (P < 0.02), were observed with KD 1.0 mmol/L compared with 3.0 mmol/L. The theoretical model accurately predicted the deltaKt/V observed with KD 1.0 mmol/L. It is concluded that a low KD decreases dialysis efficiency. This effect is likely caused by reduced blood perfusion to nonvisceral organs, largely skeletal muscle. Conversely, hemodialysis with KD 3.0 mmol/L facilitates tissue perfusion, minimizes urea trapping in poorly perfused areas, and improves the efficiency of this treatment modality.     

Administration to mouse of endotoxin from gram-negative bacteria leads to activation and apoptosis of T lymphocytes

The carbamylation reaction in vivo involves the nonenzymatic, covalent attachment of isocyanic acid, the spontaneous dissociation product of urea, to proteins. Carbamylated proteins have been proposed as markers of uremia and indicators of uremic control. However, the utility of measuring carbamylated proteins has not been investigated adequately. Therefore, this study was done to determine the relationship between the carbamylation of long-lived protein (hemoglobin) with that of short-lived proteins (plasma proteins) in hemodialyzed patients. Significantly higher carbamylated hemoglobin (CHb; 157 +/- 40 microg valine hydantoin/g Hb) and carbamylated protein (CTP; 0.117 +/- 0.011 absorbance/mg protein) concentrations were found in hemodialyzed patients (N = 13) as compared to normal individuals (N = 9, 53 +/- 20 microg valine hydantoin/g Hb and 0.08 +/- 0.01 absorbance/mg protein, respectively). A high correlation was found between CHb and CTP concentrations (r = 0.87, P < 0.0001), demonstrating a strong relationship between these two different half-lived proteins. A six-month longitudinal study of seven hemodialyzed patients showed that the between subject correlations were significant for CHb versus CTP as well as CHb versus pre-dialysis urea. Correlations were not significant for CTP versus pre-dialysis urea or Kt/V, nor CHb versus Kt/V. Carbamylated hemoglobin fluctuated the most over this time period (30.1% +/- 20.2%), pre-dialysis urea and CTP varied less (18.3% +/- 13.4% and 14.9% +/- 7.5%, respectively), and Kt/V varied the least (6.3% +/- 3.3%). Within subject correlations were not significant between any two tests. It is unclear whether the lack of correlations found is real or a function of the small sample size. However, these data do show that CHb and CTP are positively associated and reflect the degree of urea exposure in the blood, but their usefulness for patients on maintenance hemodialysis is not clear.     

Variance in male mating success and female choice for persuasive courtship displays

BACKGROUND: The aim of the study was to evaluate our clinical experience with the CarboMedics Heart Valve Prosthesis. METHODS: Nine hundred ninety-seven consecutive patients underwent mechanical valve implantation (aortic, 771; mitral, 169; double, 52; tricuspid, 5) with this prosthesis from September 1987 through December 1993. The mean age was 62.3+/-13.7 years (range, 0.4 to 84 years); 56.6% (564 patients) were men. Four hundred seventy patients (47.1%) underwent additional surgical procedures. Mean follow-up was 4.1+/-2.2 years (range, 0 to 8.3 years) with a total of 4,040 patient-years. RESULTS: Early mortality was 5.0% (50/997; aortic, 4.4%; mitral, 6.4%; double, 9.6%). Late mortality was 14.8% (140/947). Survival at 7 years was 75.9%+/-1.8% (aortic, 78.4%+/-2%; mitral, 70.7%+/-4.5%; double, 60.8%+/-7.4%). When matched for sex and age and compared with the normal Norwegian population, our patients had an increased standard mortality ratio in both men (1.9+/-0.4) and women (2.9+/-0.6). The linearized rate of major thromboembolism was 0.9% per patient-year, valve thrombosis 0.2% per patient-year, major bleeding event 0.6% per patient-year, paravalvular leak needing reoperation 0.5% per patient-year, prosthetic valve endocarditis 0.1% per patient-year, and of all reoperations 0.6% per patient-year. CONCLUSIONS: The CarboMedics Heart Valve Prosthesis has incidences of morbid events comparable with or better than reported for other mechanical valves.     

Protein intake does not depend on the dose of dialysis delivered--provided Kt/V is adequate

BACKGROUND: A link between malnutrition and the dialysis dose has been recently postulated on the basis of the direct relationship between Kt/V and nPCR and an increase in dialysis therapy has been also proposed in malnourished patients or when nPCR is less than 1 g/kg b.w., but the clinical meaning of such a relationship is unclear. DESIGN: Both dietary protein intake and nPCR were simultaneously determined in a selected population of 35 well-dialysed patients (Kt/V > 0.8) and were related to the delivered dialysis dose. RESULTS: No relationship was found between measured Kt/V (1.10 +/- 0.20) and dietary protein intake (PI, 0.98 +/- 0.20 g/kg) and similarly no relationship was evident between the dialysis dose and nPCR (0.99 +/- 0.20 g/kg). Although the mean nPCR value was similar to that of protein intake, nPCR exceeded protein intake when PI was less than 1 g/kg b.w. CONCLUSION: Our results demonstrate that if the dialysis dose is adequate, protein intake is a dialysis--independent or patient--dependent variable. They also show that at least 0.9 to 1.0 g protein per kg b.w are required to maintain nitrogen balance even in well-dialysed patients.     

Serum transferrin receptor concentration is not indicative of erythropoietic activity in chronic hemodialysis patients with poor response to recombinant human erythropoietin

BACKGROUND: Serum transferrin receptor (sTfR) is a transmembrane glycoprotein derived from erythroid precursors in the bone marrow. Its concentration provides a quantitative measure of total erythropoietic activity and an indication of functional iron deficiency. This study was conducted to investigate whether sTfR is a useful index of erythropoietic activity in chronic hemodialysis patients with poor response to maintenance recombinant human erythropoietin (rHuEPO) therapy. METHODS: Using an enzyme-linked immunosorbent assay, sTfR concentration was measured in 67 uremic patients who had been on hemodialysis for a mean of 42 months (3-242 months). rHuEPO was administered three times a week to keep the hematocrit above 30%. Hemoglobin, red blood cell indices, serum ferritin, serum total iron binding capacity and unsaturated iron binding capacity were determined. Of the 67 patients, 35 who responded favorably to rHuEPO with hematocrits above 30% were categorized as Group I and 32 who did not attain the target hematocrit were categorized as Group II. As a control group, 31 healthy subjects were also investigated. RESULTS: The serum iron, ferritin, transferrin iron saturation, dialysis efficiency and nutritional state were not different between groups of hemodialysis patients. The mean sTfR concentration was 2.1 +/- 0.6 micrograms/ml (range, 1.15-3.53 micrograms/ml) in Group I patients, compared with 1.9 +/- 0.9 micrograms/ml (range, 1.03-2.65 micrograms/ml) in Group II. The difference was not significant. In addition, the mean sTfR concentration of 1.8 +/- 0.4 micrograms/ml (range, 0.86-2.76 micrograms/ml) in the healthy controls was not significantly different from Groups I and II. CONCLUSIONS: sTfR concentration cannot be used to distinguish good from poor rHuEPO responders among chronic hemodialysis patients who have elevated serum ferritin (> 300 micrograms/l) and transferrin iron saturation (> 25%) during the course of maintenance rHuEPO therapy.