Influence of prenatal adrenaline infusion on arterial blood gases after caesarean delivery in the lamb.
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The efficacy of pulmonary gas exchange immediately after delivery is inversely related to the volume of liquid in the lung at birth, but aspiration of as much liquid as possible from the lung before Caesarean delivery fails to improve postnatal oxygenation (Pa,O2) to the level achieved after spontaneous term delivery. We hypothesised that the differing respiratory benefit of aspiration and vaginal delivery results from the differing volume of lung liquid remaining after aspiration (17 ml (kg body weight)-1) and labour (7 ml kg-1). We addressed this hypothesis by reducing lung liquid volume to an estimated 7 ml kg-1 by infusing adrenaline to seven fetal lambs at 140 days gestation (term is 147 days) before performing Caesarean delivery and obtaining postnatal blood gases for comparison with samples from lambs delivered vaginally. Infusion of adrenaline to fetuses caused a progressive decline in arterial O2 saturation (Sa, O2), pH and base excess, but no change in arterial partial pressure of O2 (Pa,O2) or CO2 (Pa,CO2). After birth, Pa,O2 rapidly rose to the same level in adrenaline-treated and vaginal-delivery groups. A severe acidosis occurred in the adrenaline-treated group and this appeared to be related to a higher Pa,CO2 and a transiently lower Sa, O2 in this group. We conclude that adrenaline infusion can enhance postnatal Pa,O2 levels in the newborn lamb, but this beneficial effect may be outweighed by the severe acidosis that develops after prolonged prenatal adrenaline treatment. (+info)
Chronic metabolic acidosis in azotemic rats on a high-phosphate diet halts the progression of renal disease.
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BACKGROUND: Hyperphosphatemia and metabolic acidosis are general features of advanced chronic renal failure (RF), and each may affect mineral metabolism. The goal of the present study was to evaluate the effect of chronic metabolic acidosis on the development of hyperparathyroidism and bone disease in normal and azotemic rats on a high-phosphate diet. Our assumption that the two groups of azotemic rats (acid-loaded vs. non-acid-loaded) would have the same degree of renal failure at the end of the study proved to be incorrect. METHODS: Four groups of rats receiving a high-phosphate (1.2%), normal-calcium (0.6%) diet for 30 days were studied: (1) normal (N); (2) normal + acid (N + Ac) in which 1.5% ammonium chloride (NH4Cl) was added to the drinking water to induce acidosis; (3) RF, 5/6 nephrectomized rats; and (4) RF + acid (RF + Ac) in which 0.75% NH4Cl was added to the drinking water of 5/6 nephrectomized rats to induce acidosis. RESULTS: At sacrifice, the arterial pH and serum bicarbonate were lowest in the RF + Ac group and were intermediate in the N + Ac group. Serum creatinine (0.76 +/- 0.08 vs. 1.15 +/- 0.08 mg/dL), blood urea nitrogen (52 +/- 8 vs. 86 +/- 13 mg/dL), parathyroid hormone (PTH; 180 +/- 50 vs. 484 +/- 51 pg/mL), and serum phosphate (7.46 +/- 0.60 vs. 12.87 +/- 1.4 mg/dL) values were less (P < 0.05), and serum calcium (9.00 +/- 0.28 vs. 7.75 +/- 0.28 mg/dL) values were greater (P < 0.05) in the RF + Ac group than in the RF group. The fractional excretion of phosphate (FEP) was greater (P < 0.05) in the two azotemic groups than in the two nonazotemic groups. In the azotemic groups, the FEP was similar even though PTH and serum phosphate values were less in the RF + Ac than in the RF group. NH4Cl-induced acidosis produced hypercalciuria in the N + Ac and RF + Ac groups. When acid-loaded (N + Ac and RF + Ac) and non-acid-loaded (N and RF) rats were combined as separate groups, serum phosphate and PTH values were less for a similarly elevated serum creatinine value in acid-loaded than in non-acid-loaded rats. Finally, the osteoblast surface was less in the N + Ac group than in the other groups. However, in the acid-loaded azotemic group (RF + Ac), the osteoblast surface was not reduced. CONCLUSIONS: The presence of chronic metabolic acidosis in 5/6 nephrectomized rats on a high-phosphate diet (1) protected against the progression of RF, (2) enhanced the renal clearance of phosphate, (3) resulted in a lesser degree of hyperparathyroidism, and (4) did not reduce the osteoblast surface. The combination of metabolic acidosis and phosphate loading may protect against the progression of RF and possibly bone disease because the harmful effects of acidosis and phosphate loading may be counterbalanced. (+info)
Potentiation of a voltage-gated proton current in acidosis-induced swelling of rat microglia.
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Microglia are equipped with a strong proton (H(+)) extrusion pathway, a voltage-gated H(+) channel, probably to compensate for the large amount of H(+) generated during phagocytosis; however, little is known about how this channel is regulated in pathological states. Because neural damage is often associated with intracellular and extracellular acidosis, we examined the regulatory mechanisms of the H(+) current of rat spinal microglia in acidic environments. More than 90% of round/amoeboid microglia expressed the H(+) current, which was characterized by slow activation kinetics, dependencies on both intracellular and extracellular pH, and blockage by Zn(2+). Extracellular lactoacidosis, pH 6.8, induced intracellular acidification and cell swelling. Cell swelling was also induced by intracellular dialysis with acidic pipette solutions, pH 5.5-6.8, at normal extracellular pH 7.3 in the presence of Na(+). The H(+) currents were increased in association with cell swelling as shown by shifts of the half-activation voltage to more negative potentials and by acceleration of the activation kinetics. The acidosis-induced cell swelling and the accompanying potentiation of the H(+) current required nonhydrolytic actions of intracellular ATP and were inhibited by agents affecting actin filaments (phalloidin and cytochalasin D). The H(+) current was also potentiated by swelling caused by hypotonic stress. These findings suggest that the H(+) channel of microglia can be potentiated via cell swelling induced by intracellular acidification. This potentiation might operate as a negative feedback mechanism to protect microglia from cytotoxic acidification and hence acidosis-induced swelling in pathological states of the CNS. (+info)
Effects of lactate-buffered and lactate-free dialysate in CAVHD patients with and without liver dysfunction.
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BACKGROUND: Continuous modalities of renal replacement deplete patients of bicarbonate, which is traditionally replaced indirectly by lactate in dialysate or replacement fluids. We have compared a new lactate-free dialysate (unbuffered dialysate with separate bicarbonate replacement of dialytic bicarbonate loss) with standard lactate-buffered dialysate in terms of acid-base control, lactate accumulation, and hemodynamic stability in patients undergoing continuous renal replacement therapy in an intensive care unit. METHODS: A nonrandomized crossover cohort study involving 54 patients with multi-organ failure (of whom 19 had significant hepatic dysfunction) was performed. All patients completed 24-hour continuous hemodiafiltration against both lactate-buffered and lactate-free dialysate. Arterial pH, blood gases, bicarbonate, and lactate, venous sodium, blood pressure, and inotrope requirements were measured before and at six hourly intervals during the first 24 hours of dialysis against each dialysate. RESULTS: Lactate-free dialysate provided more rapid control of acidosis than lactate buffered with less total administration of buffer than that given during the lactate-buffered period (total mmol bicarbonate vs. total mmol lactate + bicarbonate). Lactate accumulation was slight in both periods, but was higher during lactate-buffered continuous venovenous hemodiafiltration (CVVHD). The mean arterial pressure rose during lactate-free dialysis with decreased inotrope doses and fell during lactate-buffered dialysis with increased inotrope requirement. Results in patients with liver dysfunction were not significantly different from those without it. CONCLUSIONS: Over the time scale of 24 hours, lactate derived from continuous dialysis circuits is efficiently cleared from the blood of most patients with multi-organ failure, but with less effect on systemic acidosis than is produced by equivalent amounts of bicarbonate. (+info)
Role of pump prime in the etiology and pathogenesis of cardiopulmonary bypass-associated acidosis.
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BACKGROUND: The development of metabolic acidosis during cardiopulmonary bypass (CPB) is well recognized but poorly understood. The authors hypothesized that the delivery of pump prime fluids is primarily responsible for its development. Accordingly, acid-base changes induced by the establishment of CPB were studied using two types of priming fluid (Haemaccel, a polygeline solution, and Ringer's Injection vs. Plasmalyte 148) using quantitative biophysical methods. METHODS: A prospective, double-blind, randomized trial was conducted at a tertiary institution with 22 patients undergoing CPB for coronary artery bypass surgery. Sampling of arterial blood was performed at three time intervals: before CPB (t1), 2 min after initiation of CPB at full flows (t2), and at the end of the case (t3). Measurements of Na+, K+, Mg2+, Cl-, HCO3-, phosphate, Ca2+, albumin, lactate, and arterial blood gases at each collection point were performed. Results were analyzed in a quantitative manner. RESULTS: Immediately on delivery of pump prime fluids, all patients developed a metabolic acidosis (base excess: 0. 95 mEq/l (t1) to -3.65 mEq/l (t2) (P < 0.001) for Haemaccel-Ringer's and 1.17 mEq/l (t1) to -3.20 mEq/l (t2). The decrease in base excess was the same for both primes (-4.60 vs. -4.37; not significant). However, the mechanism of metabolic acidosis was different. With the Haemaccel-Ringer's prime, the metabolic acidosis was hyperchloremic (Delta Cl-, +9.50 mEq/l; confidence interval, 7.00-11.50). With Plasmalyte 148, the acidosis was induced by an increase in unmeasured anions, most probably acetate and gluconate. The resolution of these two processes was different because the excretion of chloride was slower than that of the unmeasured anions (Delta base excess from t1 to t3 = -1.60 for Haemaccel-Ringer's vs. +1.15 for Plasmalyte 148; P = 0.0062). CONCLUSIONS: Cardiopulmonary bypass-induced metabolic acidosis appears to be iatrogenic in nature and derived from the effect of pump prime fluid on acid-base balance. The extent of such acidosis and its duration varies according to the type of pump prime. (+info)
Acid-base changes caused by 5% albumin versus 6% hydroxyethyl starch solution in patients undergoing acute normovolemic hemodilution: a randomized prospective study.
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BACKGROUND: Preoperative acute normovolemic hemodilution (ANH) is an excellent model for evaluating the effects of different colloid solutions that are free of bicarbonate but have large chloride concentrations on acid-base equilibrium. METHODS: In 20 patients undergoing gynecologic surgery, ANH to a hematocrit of 22% was performed. Two groups of 10 patients each were randomly assigned to receive either 5% albumin or 6% hydroxyethyl starch solutions containing chloride concentrations of 150 and 154 mm, respectively, during ANH. Blood volume (double label measurement of plasma and red cell volumes), pH, Paco2, and serum concentrations of sodium, potassium, chloride, lactate, ionized calcium, phosphate, albumin, and total protein were measured before and 20 min after completion of ANH. Strong ion difference was calculated as serum sodium plus serum potassium minus serum chloride minus serum lactate. The amount of weak plasma acid was calculated using a computer program. RESULTS: After ANH, blood volume was well maintained in both groups. ANH caused slight metabolic acidosis with hyperchloremia and a concomitant decrease in strong ion difference. Plasma albumin concentration decreased after hemodilution with 6% hydroxyethyl starch solution and increased after hemodilution with 5% albumin solution. Despite a three-times larger decrease in strong ion difference after ANH with 6% hydroxyethyl starch solution, the decrease in pH was nearly the same in both groups. CONCLUSIONS: ANH with 5% albumin or 6% hydroxyethyl starch solutions led to metabolic acidosis. A dilution of extracellular bicarbonate or changes in strong ion difference and albumin concentration offer explanations for this type of acidosis. (+info)
Dilutional acidosis following hetastarch or albumin in healthy volunteers.
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BACKGROUND: The intent of this study was to evaluate the impact of the commonly used colloids-hetastarch and albumin-on in vivo acid-base balance. From this evaluation, a better understanding of the mechanism of dilutional acidosis was expected. METHODS: In a prospective, randomized fashion, 11 healthy volunteers were administered 15 ml/kg hetastarch solution, 6%, or 15 ml/kg albumin, 5%, intravenously over 30 min. Four weeks later, the study subjects were administered the other colloid. Arterial blood gas and electrolyte parameters were measured at baseline and at 30, 60, 90, 120, 210, and 300 min after colloid administration. Pre- and postlaboratory values were compared within groups using a paired t test and a Wilcoxon signed rank test and between groups using repeated-measures analysis of variance and a Wilcoxon rank sum test. RESULTS: Thirty min after infusion, subjects who were administered hetastarch showed statistically significant changes (P < 0.05) in base excess (from 2.5 +/- 0.9 mEq/l to 0.7 +/- 1.1 mEq/l), HCO3- concentration (from 27 +/- 1.0 mEq/l to 25 +/- 1.3 mEq/l), Cl- concentration (from 108 +/- 2 mEq/l to 112 +/- 2 mEq/l), albumin concentration (from 4.4 +/- 0.2 g/dl to 3.5 +/- 0.5 g/dl), and arterial carbon dioxide tension (Paco2; from 40.8 +/- 2.3 mmHg to 39. 2 +/- 3.2 mmHg), whereas only the albumin concentration (from 4.4 +/- 0.2 g/dl to 4.8 +/- 0.6 g/dl) changed significantly in the albumin-treated group. CONCLUSIONS: Decreases in base excess were observed for 210 min after hetastarch administration but not after albumin. The mechanism for this difference is discussed. (+info)
Acid-base correction and convective dialysis therapies.
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Whichever dialysis therapy is used, there is a similar need for correcting the acid base balance. The most important tool for this is the buffer in the dialysis fluid and, when using convective therapies, also in the substitution solution. The buffer source in all modern versions of these therapies should be bicarbonate. The more efficient the dialysis treatment in terms of small solute transport, the more rapid the uptake of buffer. Thus, optimally applied haemodiafiltration has the potential for the largest buffer gain. The target for acid-base correction in dialysis is to maintain patients within or as close to the physiological plasma bicarbonate range as possible. However, cross-sectional studies of acid base status among patients treated with contemporary forms of dialysis often show moderate acidosis. As metabolic acidosis has been found to be an important stimulus for protein catabolism in experimental studies, an association with nutritional problems has been sought in dialysis patients. This has revealed a negative correlation between plasma bicarbonate and nutritional parameters. Acidotic patients were found to have better nutritional status than patients with normalized acid-base balance. However, caution should be exercised when interpreting plasma bicarbonate levels, since acidosis may be a cause as well as an effect of excessive protein catabolism. Although available clinical data suggest that the catabolic effect of mild acidosis can be compensated by adequate nutrition and adequate dialysis, it should be desirable to aim for a normalized acid-base balance in combination with adequate nutritional intake and delivery of dialysis. (+info)