Dialysis hypotension: a hemodynamic analysis

Reducing symptoms during hemodialysis by continuously monitoring the hematocrit

Previous studies have demonstrated that patients on hemodialysis develop intradialytic symptoms when the blood volume decreases to a critical level. Using a continuous monitor (CRIT-LINE; In-Line Diagnostics, Riverdale, UT) to determine the instantaneous hematocrit and blood volume, we observed that certain intradialytic symptoms occurred at a patient-specific hematocrit. In the present study, we exploited this hematocrit threshold concept to decrease the occurrence of lightheadedness, cramping, and nausea, regardless of blood pressure changes. In the first phase of the study, hematocrit threshold was established in six hypotension-prone patients. Five patients entered into the second phase in which ultrafiltration rates were increased 25 percent above prescribed values at the beginning of the experimental sessions. Subsequently during the experimental sessions, ultrafiltration rates were manipulated to maintain the instantaneous hematocrit value 2 units below the established hematocrit threshold. Sessions without ultrafiltration rate adjustments based on hematocrit served as controls. There were no differences between experimental (n = 27) and control (n = 28) sessions with respect to treatment time (230 minutes v 229 minutes), fluid volume removed (3,351 mL v 3,383 mL), and maximum percentage change in systemic blood pressure (-26 percent v -24 percent). However, there were less symptoms during the experimental sessions (26 percent v 57 percent; P = 0.038). These data suggest that a twofold reduction in intradialytic symptoms can be achieved using continuous hematocrit monitoring without altering treatment times or volume removed in hypotension-prone patients.

Calcium free hemodialysis: experience in the treatment of 33 patients with severe hypercalcemia

OBJECTIVE

To assess the efficacy, adverse effects and relevance of calcium-free hemodialysis (CFHD) in the treatment of major hypercalcemia.

DESIGN

Retrospective chart review.

SETTING

Medical ICU.

PATIENTS

All patients admitted over a 9-year period for hypercalcemia requiring urgent treatment and who underwent hemodialysis.

INTERVENTIONS

CFHD with an acetate dialysate.

MAIN RESULTS

Thirty-three patients with severe hypercalcemia from various etiologies received CFHD. Marked and rapid decrease of serum total calcium was obtained during all sessions (mean decrease: 1.71 +/- 0.54 mmol/l). Calcium rebound within 24 h after CFHD was observed in all evaluable cases (1 +/- 0.45 mmol/l; mean delay 13.7 +/- 5.8 h). Adverse cardiovascular effects occurred in 17 of 48 sessions (35%) and in 13 of 30 evaluable patients (43%).

CONCLUSIONS

Adverse effects are frequent during CFHD. After correction of hypovolemia, its use should be restricted to patients with severe clinical symptoms or advanced renal impairment.

Ultrafiltration and backfiltration during hemodialysis

Ultrafiltration is the pressure-driven process by which hemodialysis removes excess fluid from renal failure patients. Despite substantial improvements in hemodialysis technology, three significant problems related to ultrafiltration remain: ultrafiltration volume control, ultrafiltration rate control, and backfiltration. Ultrafiltration volume control is complicated by the effects of plasma protein adsorption, hematocrit, and coagulation parameters on membrane performance. Furthermore, previously developed equations relating the ultrafiltration rate and the transmembrane pressure are not applicable to high-flux dialyzers, high blood flow rates, and erythropoietin therapy. Regulation of the ultrafiltration rate to avoid hypotension, cramps and other intradialytic complications is complicated by inaccurate estimates of dry weight and patient-to-patient differences in vascular refilling rates. Continuous monitoring of circulating blood volume during hemodialysis may enable a better understanding of the role of blood volume in triggering intradialytic symptoms and allow determination of optimal ultrafiltration rate profiles for hemodialysis. Backfiltration can occur as a direct result of ultrafiltration control and results in transport of bacterial products from dialysate to blood. By examining these problems from an engineering perspective, the authors hope to clarify what can and cannot be prevented by understanding and manipulating the fluid dynamics of ultrafiltration.

Effect of dialysate temperature on central hemodynamics and urea kinetics

Use of cool dialysate is associated with increased intradialytic blood pressure, but the hemodynamic mechanism is unknown. Whether changes in dialysate temperature affect muscle blood flow, which may the alter the degree of urea compartmentalization, also is unknown. We measured hemodynamics and blood and dialysate-side urea kinetic indices in nine hemodialysis patients during two cool (35.0 degrees C) versus two warm (37.5 degrees C) dialysate treatments. The % change in mean arterial pressure was different when using the cool (+6.5 +/- 9.7 mm Hg) versus the warm (-13.4 +/- 3.6) dialysate (P < 0.01), despite comparable amounts of fluid removal. Percent changes in cardiac output were similar with the two dialysates, and thus the blood pressure effect was due primarily to changes in total peripheral resistance (% delta TPR, cool +26 +/- 13.6, warm +8.6 +/- 14.5; P < 0.02). During cool dialysate use tympanic membrane temperature changed by -0.51 +/- 0.23 degree C, whereas body temperature increased by 0.52 +/- 0.14 degree C during use of warm dialysate. Measured urea recovery normalized to the predialysis urea nitrogen concentration was similar with the two treatments: cool 31.3 +/- 0.039 liter-1; warm 29.7 +/- 0.021; P = NS. In a second study, post-dialysis urea rebound values from 15 seconds to 30 minutes, expressed as the percent of the post-dialysis SUN, were similar after the two treatments: cool 11.79 +/- 1.4; warm 12.21 +/- 2.27, P = NS.(ABSTRACT TRUNCATED AT 250 WORDS)

Renal replacement therapies in the elderly: Part 1. Hemodialysis and chronic peritoneal dialysis

Recent demographic data from the United States and Europe demonstrate that the dialysis population is growing progressively older. In the United States the median age at onset of end-stage renal disease (ESRD) had reached 61 years in 1990, and the fraction of ESRD patients older than 65 years will approach 60% by the year 2000. The primary treatment of geriatric ESRD is center hemodialysis (82% of elderly patients). Chronic peritoneal dialysis in this age group is limited in the United States to less than 10%. Only 2.7% of elderly patients have a functioning transplant. Despite their complex medical and psychosocial conditions, survival and rehabilitation are acceptable in the elderly dialysis patient and these patients tend to be more complaint. Five-year dialysis patient survival rates in the United States are 19% and 10%, respectively, for the 65 to 74 and 75 to 84 age groups compared with 32% and 19%, respectively, for the same age groups in Europe. Five-year survival, particularly in the elderly, is even higher in Japan. Several factors favor the delivery of low doses of hemodialysis in the elderly and discontinuing dialysis is more common in the elderly. Continuous ambulatory peritoneal dialysis is a satisfactory alternative treatment modality for geriatric ESRD. Most studies confirm that survival of elderly patients on continuous ambulatory peritoneal dialysis and hemodialysis is similar. The 1991 United States Renal Data System report showing higher mortality among diabetic continuous ambulatory peritoneal dialysis patients than among hemodialysis patients may reflect selection of such patients, who may have more co-morbid conditions. In special cases, continuous cyclic peritoneal dialysis can be an alternative treatment for elderly ESRD patients.

Effects of cooler temperature dialysate on hemodynamic stability in "problem" dialysis patients

Symptomatic hypotension is a common and disabling complication of hemodialysis treatments. The incidence of symptomatic hypotensive episodes is particularly high in patients who have normal or low blood pressure at the initiation of dialysis and in patients who have large interdialytic weight gains. The aim of this study was to determine whether cooling the dialysate temperature from 37 degrees C to 35 degrees C improved tolerance to dialysis in a group of 12 of these "problem" patients. A double-blinded protocol was performed in six hypotension-prone and six large weight gainers who were subjected to two identical hemodialyses except for the dialysate temperature of 37 degrees C or 35 degrees C. Changes in biochemical parameters and weight were comparable during the two maneuvers. Recumbent blood pressure declined significantly (P < 0.01) during 37 degrees C dialysis but not 35 degrees C dialysis; blood pressure was significantly lower at 1, 2, and 3 hours of 37 degrees C dialysis compared to 35 degrees C dialysis (P < 0.05). Further, both supine and upright blood pressure was significantly lower following 37 degrees C dialysis (P < 0.02). This lower blood pressure was present in both subgroups of patients. All 18 episodes of symptomatic hypotension noted during the study occurred during 37 degrees C dialysis. A significantly greater increase in peripheral vascular resistance (calf blood flow was measured directly by venous occlusion plethysmography) occurred upon exposure to the 35 degrees C dialysate in both subgroups of patients (P < 0.01); supine and upright post-dialysis plasma norepinephrine values were also significantly greater (P < 0.001) after 35 degrees dialysis.(ABSTRACT TRUNCATED AT 250 WORDS)

Nature and rate of vascular refilling during hemodialysis and ultrafiltration

The change of blood volume, of blood and plasma density (rho b, rho p) following a short ultrafiltration pulse (duration: 20 min; mean rate -35 ml/min) within the first hour of hemodialysis was analyzed in 13 hemodynamically stable patients (30 single measurements). Protein concentration of refilling volume (7 g/liter) was calculated from its density (1009.25 +/- 3.7 kg/m3, at 20 degrees C) and from the linear relationship between plasma density and protein concentration (cp) of uremic plasma samples (rho p = 1007.46 + 0.2422 x cp). The filtration coefficient (Lp,calc) determined from a relation derived from Starling's hypothesis was 5.6 +/- 1.4 ml/(min.mm Hg.50 kg lean body mass); N = 13, mean +/- SD, minimum 3.2, maximum 8.0. A model describing the dynamics of blood and plasma volume was developed. It was fit to on-line measurements of relative blood volume changes by variation of the filtration coefficient and of initial blood volume (Lp,fit, Vb,fit). The linear regression between Vb,fit and blood volume determined from anthropometry (Vb,calc) was highly significant (r = 0.79, N = 30, P < 0.001). Compared to Vb,calc, Vb,fit was typically increased by 21 +/- 11%, reflecting a fluid overload at the beginning of the treatment. Lp,fit was not different from Lp,calc. Lp,fit significantly increased with blood volume excess. Due to the small but definite protein content of refilling volume, the model accounts for increased blood volume recovery and occasional overshoot of blood and plasma volumes following ultrafiltration.

Role of the venous system in hemodynamics during ultrafiltration and bicarbonate dialysis

A reduced venous compliance (VC) and inadequate venoconstriction may impair hemodynamics during hemodialysis, the first by impairing plasma volume preservation and by inducing a steep fall in central venous pressure (CVP) during minor plasma volume loss, the second by inadequate mobilization of hemodynamically inactive blood volume. For the protocol A, the relation between VC, the fall in plasma volume and the decline in central venous pressure (CVP) was assessed in 12 hemodialysis (HD) patients, aged 40 to 74 years, during isolated ultrafiltration (UF). The patients were ultrafiltrated for one hour at an UF rate of 1 to 1.5 liter/hr. VC was measured by strain gauge plethysmography with direct i.v. pressure measurements. CVP was assessed directly via a subclavian catheter. PVP was measured using the serial hematocrit method. VC correlated inversely with the fall in plasma volume (r = -0.66; P less than 0.025) and with the fall in CVP (corrected for UF volume) (r = -0.62; P less than 0.025). In the protocol B, the constriction of veins and resistance vessels was assessed sequentially during isolated UF and during UF combined with bicarbonate HD (UF + HD) by measuring the change in venous tone (VT) and vascular resistance (FVR) of the forearm. Twelve HD patients were studied (age 30 to 64 years). VT and FVR were measured using strain gauge plethysmography. The UF rate was equal during isolated UF and UF + HD (1 liter/hr). In six patients, the measurements were started with isolated UF and in six patients with UF + HD.(ABSTRACT TRUNCATED AT 250 WORDS)

Hypertension is not adequately controlled in hemodialysis patients

To examine the adequacy of hypertension control, we monitored the blood pressure (BP) of 53 hemodialysis patients who received treatment for hypertension. BP measurement using an ambulatory BP monitor began 1 hour before dialysis and continued every 30 to 60 minutes for 48 hours until the next dialysis. Diet, medications including antihypertensive drugs, and hemodialysis prescription were not changed during this study. Each patient had a mean of 68 BP measurements during the monitoring period. Mean (+/- SD) systolic and diastolic BP levels of all patients over 48 hours were 158.6 +/- 22.7 mm Hg and 88.7 +/- 16.6 mm Hg, respectively, without diurnal variations. In these, BP loads (the percentage of systolic BP exceeding 150 mm Hg and diastolic BP exceeding 90 mm Hg) were 58.4% and 39.4%, respectively, suggesting that hypertension was inadequately controlled for more than half of the study period. Eight patients (15%) maintained BP within normal ranges at all times. All patients lost weight (2.9 +/- 0.9 kg) at the end of dialysis by ultrafiltration. However, only 27 patients (51%) had a greater than 5% decrease in mean arterial BP post-dialysis, which returned to predialysis levels within 12 to 24 hours. Reduction of BP postdialysis was significantly more common among black patients (72%) than white patients (30%) (P less than 0.01). However, there was no difference in age, cause of kidney disease, amount of ultrafiltration, and BP loads between those whose BP decreased and those whose did not. BP monitoring was repeated in eight patients, 2 to 3 months after adjustment of their antihypertensive regimens.(ABSTRACT TRUNCATED AT 250 WORDS)

Improved left ventricular contractility with cool temperature hemodialysis

Cool temperature dialysis (CTD) has been shown to sharply decrease the frequency of intradialytic hemodialysis hypotension, but the mechanism of this hemodynamic protection is unknown. Therefore, we performed two-dimensional echocardiographic studies of left ventricular contractility in six stable hemodialysis patients before and after hemodialysis at 37 degrees C (RTD) and 35 degrees C (CTD). Left ventricular function was assessed by plotting the rate-corrected velocity of circumferential fiber shortening (Vcfc) against end-systolic wall stress (sigma es) at four different levels of afterload. Linear regression was used to calculate Vcfc at a common afterload of 50 g/cm2. Changes in weight and dialysis parameters were similar following RTD and CTD. Mean arterial pressure and heart rate did not change significantly following RTD or CTD. The Vcfc - sigma es relation was shifted upward in each patient after CTD, indicating increased contractility as compared to RTD or pre-dialysis baseline. Pre-dialysis Vcfc at an afterload of 50 g/cm2 was similar during RTD and CTD (0.94 +/- 0.24 circ/sec vs. 0.92 +/- 0.22 circ/sec). Postdialysis Vcfc at an afterload of 50 g/cm2 was significantly higher for CTD than for RTD (1.13 +/- 0.29 circ/sec vs. 0.98 +/- 0.30 circ/sec, P = 0.0004). Thus, cool temperature dialysis increases left ventricular contractility in hemodialysis patients, which may be a potential mechanism whereby hemodynamic tolerance to the dialysis procedure is improved.