Adaptive responses during anemia and its correction in lambs.

There is limited information available on which to base decisions regarding red blood cell (RBC) transfusion treatment in anemic newborn infants. Using a conscious newborn lamb model of progressive anemia, we sought to identify accessible metabolic and cardiovascular measures of hypoxia that might provide guidance in the management of anemic infants. We hypothesized that severe phlebotomy-induced isovolemic anemia and its reversal after RBC transfusion result in a defined pattern of adaptive responses. Anemia was produced over 2 days by serial phlebotomy (with plasma replacement) to Hb levels of 30-40 g/l. During the ensuing 2 days, Hb was restored to pretransfusion baseline levels by repeated RBC transfusion. Area-under-the-curve methodology was utilized for defining the Hb level at which individual study variables demonstrated significant change. Significant reciprocal changes (P < 0.05) of equivalent magnitude were observed during the phlebotomy and transfusion phases for cardiac output, plasma erythropoietin (Epo) concentration, oxygen extraction ratio, oxygen delivery, venous oxygen saturation, and blood lactate concentration. No significant change was observed in resting oxygen consumption. Cardiac output and plasma Epo concentration increased at Hb levels <75 g/l, oxygen delivery and oxygen extraction ratio decreased at Hb levels <60 g/l, and venous oxygen saturation decreased and blood lactate concentration increased at Hb levels <55 g/l. We speculate that plasma Epo and blood lactate concentrations may be useful measures of clinically significant anemia in infants and may indicate when an infant might benefit from a RBC transfusion.

Erythropoietin pharmacokinetics in premature infants: developmental, nonlinearity, and treatment effects.

Erythropoietin (EPO) pharmacokinetic studies were performed in premature infants (birth weight < 1.25 kg) and normal adults. Infants were divided into two subgroups on the basis of whether they received chronic treatment with recombinant human EPO (rhEPO; 500 IU.kg-1.wk-1 for 6 wk) beginning at 2-4 wk of life. Ten adults and seven rhEPO-treated infants underwent intravenous pharmacokinetic studies at escalating rhEPO doses: 10, 100, and 500 IU/kg. To test for pharmacokinetic developmental and treatment effects, an equal number of non-EPO- and EPO-treated infants were studied with 100 IU/kg on the last day of treatment. Compared with adults, very low birth weight infants demonstrated significantly greater plasma clearance and distribution volume and significantly shorter fractional elimination times (FET) and mean residence time (MRT) at all three rhEPO doses. Both infants and adults demonstrated nonlinear EPO elimination, i.e., increasing rhEPO dosing was associated with decreasing plasma clearance and increasing FET and MRT. In the absence of rhEPO treatment there were no pharmacokinetic differences between the two subgroups of infants studied 6 wk apart. In contrast, the rhEPO-treated infant subgroup demonstrated a significant increase in clearance and a decrease in FET and MRT following 6 wk of treatment. Enhancement of rhEPO efficacy in the prevention and treatment of anemia in premature infants may require higher doses administered in a progressively increasing fashion.

Kinetic evaluation of nonlinear drug elimination by a disposition decomposition analysis. Application to the analysis of the nonlinear elimination kinetics of erythropoietin in adult humans.

The disposition-decomposition analysis (DDA) methodology enables isolation of the overall elimination and distribution effects in pharmacokinetics and facilitates analysis which focuses on drug elimination kinetics and does not require a specific structured modeling of drug distribution processes. A computer algorithm enables a curve fitting and a kinetic estimation by integration of the convolution type integrodifferential equation in the DDA. The approach is demonstrated in an analysis of the nonlinear disposition kinetics of erythropoietin (Epo) in 10 healthy, adult human subjects who each received 10, 100, and 500 U/kg i.v. bolus doses of Epo. The nonlinearity is analyzed according to a Michaelis-Menten type nonlinear elimination function, considering simultaneous fitting to the data from all three doses in each subject. The simultaneous fittings produced estimates of the Michaelis-Menten parameters (mean, % cv) Vm (901 mU/mL/h, 19.4%) and km (4814 mU/mL, 24.6%). A linear clearance parameter is defined as the asymptotic clearance value approached when the drug level decreases toward zero. The degree of nonlinearity reached from various dosings was quantified in terms of a clearance ratio which is defined as the ratio between the linear clearance and the clearance estimated for the maximum drug concentration encountered at the given dose level. The subjects showed very little nonlinearity at the 10 U/kg dosing with a mean clearance ratio of 1.07 (2.1% CV) A statistically significant increase in the degree of nonlinearity was observed in the Epo elimination kinetics as the dosing level was increased to 100 and 500 U/kg, reaching clearance ratios of 1.66 (14% CV) and 4.33 (27% CV), respectively. A zero value for the global elimination rate parameter in all 30 dosings indicates that Epo's elimination is entirely accounted for by nonlinear pathway(s).

Antecedents of nursing school attrition: attitudinal dimensions.

In an attempt to identify attitudinal orientations that might be used as indicators of attrition, demographic, academic performance, and attitudinal data on 261 students enrolled in the Woodruff School of Nursing at Emory University, Atlanta, between 1968 and 1972, were studied. Traditional measures of scholastic aptitude were not found to be good indicators. The higher the father's educational attainment, the more likely attrition was to occur. The higher the mother's occupational status, the less likely attrition was to occur. Attitudinal measures used in the study seemed to have little direct impact on attrition.

Distributions of interstitial cells of Cajal in stomach and colon of cat, dog, ferret, opossum, rat, guinea pig and rabbit.

Electrical slow waves vary in prominence from one location to another in stomach and colon. If interstitial cells of Cajal are involved in generation of the slow waves, they might be more abundant in regions where slow waves are prominent than in regions where slow waves are small or absent. We calculated the density of distribution of interstitial cells of Cajal in colon and stomach of cat, dog, ferret, guinea pig, opossum, rabbit, and rat, using the zinc iodide-osmic acid reaction for light microscopy. The cells in the stomach were concentrated in the myenteric plexus and in the circular muscle layer. Along the greater curvature, cells were relatively sparse in the fundus, more frequent in the corpus and densest in the antrum. Along the lesser curvature, they were denser distally than proximally in all species except guinea pig. In the colon most cells lay with an axonal network at the circular muscle-submucosal interface. The axons were sparse in the cecum but uniformly conspicuous from the ileocolonic junction to the internal and sphincter. The density of the interstitial cells of Cajal in cat, dog, opossum, and rabbit rose from a relatively low level in the cecum to a maximum in the mid-colon, declining toward the rectum. In guinea pig, rat, and ferret, the levels throughout the most proximal colon were high. Since gastric slow waves are absent from the fundus, diminutive in the body, and prominent in the antrum, the density of interstitial cells of Cajal in the stomach roughly parallels the prominence of slow waves. Colonic slow waves are most prominent in the right colon and mid-colon, and so the density distribution of interstitial cells of Cajal in the colon also roughly parallels the prominence of slow waves.

A comparison of nonlinear pharmacokinetics of erythropoietin in sheep and humans.

The primary mechanism of erythropoietin's (EPO) in vivo elimination and the tissue, or tissues, responsible are unknown. Previous studies indicating that EPO pharmacokinetic (PK) behaviour is nonlinear suggest that EPO elimination takes place by a saturable mechanism. A versatile PK system analysis, the Disposition Decomposition Analysis (DDA), capable of quantification of the Michaelis-Menten parameters, V(m) and k(m) was used to analyze and compare EPO's PK behaviour in newborn sheep and preterm infants. Lambs and infants both demonstrated nonlinear PK behaviour appropriately analyzed with DDA. Compared to preterm infants, lambs had significantly greater (p<0.05) elimination capacity as determined by the V(m) (2789+/-525 versus 1767+/-250 mU/mL per h (mean+/-S.E.), respectively), and larger extrapolated linear clearances (116+/-19.1 versus 21.3+/-1.75 mL/kg per h, respectively) (p<0.01). Lambs also demonstrated significantly larger (p<0.01) degrees of nonlinearity as judged by smaller mean k(m) values (2142+/-258 versus 6796+/-1.007 mU/mL, respectively). Of note, although the DDA does not distinguish what the mechanism of EPO elimination is, enzymatic degradation and receptor-mediated cellular internalization are two possibilities. The in vivo DDA-derived k(m) values were similar to reported in vitro binding affinity k(d) data for erythroid progenitors and cell lines having EPO-R's, i.e. 240-2400 mU/mL. The present study's demonstration that EPO's nonlinear PK behaviour in both sheep and humans can be analyzed by the DDA methodology indicates that the sheep model may be used in invasive studies needed to further characterize the mechanism of EPO elimination.

In vivo 125I-erythropoietin pharmacokinetics are unchanged after anesthesia, nephrectomy and hepatectomy in sheep.

Knowledge regarding the in vivo metabolic fate of the glycoprotein erythropoietin (EPO) is incomplete. To determine whether EPO pharmacokinetics are perturbed by ablation of the kidneys or liver or by anesthesia, EPO pharmacokinetic parameters were determined in adult sheep. Animals were studied in a paired manner, with and without deep barbiturate anesthesia and before and immediately after nephrectomy or hepatectomy accompanied by deep barbiturate anesthesia. Hepatectomy was accomplished with the liver left in situ, by occlusion of the arterial hepatic blood supply and diversion of portal venous flow to the jugular vein. After i.v. administration of tracer amounts of 125I-labeled recombinant human EPO, multiple blood samples were taken over 6 to 7 hr and analyzed for EPO immunoprecipitable radioactivity. EPO pharmacokinetic parameters were derived using a noncompartmental system analysis applied to the data on EPO immunoprecipitable radioactivity. No significant differences were detected for plasma clearance, distribution volume, mean residence time and alpha and beta half-lives examined under each of the three paired study conditions. Contrary to speculation by others, results of the present study make it highly unlikely that removal of the terminal sialic acid moieties of EPO contributes significantly to the metabolism of EPO. Because removal of the liver and kidney had no effect on EPO elimination, the metabolic degradation of EPO occurs in a tissue compartment that is yet to be defined. We speculate that the bone marrow is the most likely tissue with primary responsibility for the metabolism of EPO.

Direct relationship of fetal carboxyhemoglobin with hemolysis in alloimmunized pregnancies.

Because carbon monoxide (CO) is a byproduct of heme degradation and because placental diffusing capacity of CO is limited, we hypothesized that the concentration of CO transported in fetal blood as carboxyhemoglobin (HbCO) would correlate with the severity of fetal hemolytic disease. Fetal blood was obtained by cordocentesis and HbCO was measured by gas chromatography. The two primary study groups included control fetuses (n = 26) and fetuses of Coombs-positive mothers before in utero transfusion (n = 15). Compared with controls, fetuses with hemolytic disease had higher HbCO levels (0.0111 +/- 0.0014 versus 0.0159 +/- 0.0072 fraction of total Hb, mean +/- SD, p < 0.002). In contrast, HbCO levels in simultaneously sampled maternal blood samples were not different in the control and alloimmune groups [0.0110 +/- 0.0025 (n = 20) versus 0.0115 +/- 0.0021 (n = 11)]. There was a significant inverse correlation observed between fetal HbCO and Hb concentrations in the group with hemolytic disease (r = -0.73, p < 0.002) but not in controls. In fetuses with hemolytic disease, HbCO and bilirubin were highly correlated (r = 0.88, p < 0.0001). Data from four anemic fetuses who were Coombs negative, three of whom had no evidence of hemolysis, indicated normal HbCO and normal plasma bilirubin levels. A fourth fetus with anemia had viral sepsis and elevated HbCO and plasma bilirubin levels. We conclude that elevated HbCO levels detected in fetuses of nonsmoking mothers with erythrocyte alloimmunization are likely the result of accelerated hemolysis.

Effect of chronic erythropoietin administration on plasma iron in newborn lambs.

Erythropoietin, the primary stimulator of erythropoiesis, represents an important potential therapy for the anemia of prematurity. Enhancement of the therapeutic benefit of recombinant human erythropoietin (rhEp) in very-low-birth-weight infants will require a better understanding of rhEp's pharmacodynamic effects including its interaction with iron in stimulating erythropoiesis. The purpose of this study was to determine the effects of chronic rhEp administration on plasma iron levels and hematopoiesis using a twin lamb model. Nine pairs of twin lambs in which one twin was randomized to receive rhEp, and the other saline, were studied during a 1-week baseline and a subsequent 4- to 5-week treatment period. The effects of therapy on plasma iron levels and erythropoiesis were measured by integrating the areas under the concentration-time curves (AUC) of the study variables. During the rhEp treatment period, significantly greater negative daily AUCs were observed in the rhEp-treated lambs for plasma iron concentration (p = 0.0008), while significantly greater positive daily AUCs were observed for hemoglobin concentration (p = 0.04) and reticulocyte count (p = 0.02). In the rhEp-treated group, pretreatment iron concentrations were directly associated with the magnitude of the iron response during treatment such that the greater the pretreatment iron, the greater the daily AUC below the plasma iron concentration-time plot (r = -0.66, p = 0.05). For the placebo-treated group, this association tended toward, but did not achieve, statistical significance (r = -0.52, p = n.s.). These observations suggest that treatment of rapidly growing newborn lambs with rhEp results in increased iron utilization due to increased erythropoiesis and depends on iron status at the initiation of rhEp treatment. Use of the term neonatal lamb model offers advantages over studies in human infants for more detailed or invasive examinations of the interaction of iron and rhEp treatment.