Early high-dose recombinant erythropoietin is well tolerated by extremely low birth weight infants, causing no excess morbidity or mortality. Recombinant erythropoietin dosages of 1000 and 2500 U/kg achieved neuroprotective serum levels.
OBJECTIVE: To determine the safety and pharmacokinetics of erythropoietin (Epo) given in conjunction with hypothermia for hypoxic-ischemic encephalopathy (HIE). We hypothesized that high dose Epo would produce plasma concentrations that are neuroprotective in animal studies (ie, maximum concentration = 6000–10 000 U/L; area under the curve = 117 000–140 000 U*h/L). METHODS: In this multicenter, open-label, dose-escalation, phase I study, we enrolled 24 newborns undergoing hypothermia for HIE. All patients had decreased consciousness and acidosis (pH < 7.00 or base deficit ≥ 12), 10-minute Apgar score ≤ 5, or ongoing resuscitation at 10 minutes. Patients received 1 of 4 Epo doses intravenously: 250 (N = 3), 500 (N = 6), 1000 (N = 7), or 2500 U/kg per dose (N = 8). We gave up to 6 doses every 48 hours starting at <24 hours of age and performed pharmacokinetic and safety analyses. RESULTS: Patients received mean 4.8 ± 1.2 Epo doses. Although Epo followed nonlinear pharmacokinetics, excessive accumulation did not occur during multiple dosing. At 500, 1000, and 2500 U/kg Epo, half-life was 7.2, 15.0, and 18.7 hours; maximum concentration was 7046, 13 780, and 33 316 U/L, and total Epo exposure (area under the curve) was 50 306, 131 054, and 328 002 U*h/L, respectively. Drug clearance at a given dose was slower than reported in uncooled preterm infants. No deaths or serious adverse effects were seen. CONCLUSIONS: Epo 1000 U/kg per dose intravenously given in conjunction with hypothermia is well tolerated and produces plasma concentrations that are neuroprotective in animals. A large efficacy trial is needed to determine whether Epo add-on therapy further improves outcome in infants undergoing hypothermia for HIE.
Aminoglycoside pharmacokinetics were determined in 30 normal weight patients and 30 morbidly obese patients (greater than 90% overweight). All had normal renal function and a gram-negative infection (documented by cultures, fever and elevated white blood cell counts) which was treated only with aminoglycoside antibiotics. The normal weight and morbidly obese patients were matched with respect to the following criterion: age, sex, ideal body weight (IBW), serum creatinine, site of infection, and type of aminoglycoside antibiotic (gentamicin, tobramycin, or amikacin). The results were similar for all 3 drugs. Average half-life was 2 h for both the morbidly obese and normal weight patients. The mean volumes of distribution and clearances were significantly larger in the morbidly obese (23.3 l and 135.8 ml/min for gentamicin, 29.9 l and 162.4 ml/min for tobramycin, and 26.8 l and 157.3 ml/min for amikacin) than in normal weight patients (17.0 l and 95.9 ml/min for gentamicin, 18.3 l and 101.3 ml/min for tobramycin, and 18.6 l and 99.2 ml/min for amikacin). As a result of altered aminoglycoside pharmacokinetics, morbidly obese patients required significantly larger mean doses (540 mg/d for gentamicin, 690 mg/d for tobramycin and 1970 mg/d for amikacin) when compared to the normal weight patients (380 mg/d, 420 mg/d and 1420 mg/d, respectively; p less than 0.005) in order to achieve comparable serum concentrations.
Background: Up to 65% of untreated infants suffering from moderate to severe hypoxic-ischemic encephalopathy (HIE) are at risk of death or major disability. Therapeutic hypothermia (HT) reduces this risk to approximately 50% (number needed to treat: 7-9). Erythropoietin (Epo) is a neuroprotective treatment that is promising as an adjunctive therapy to decrease HIE-induced injury because Epo decreases apoptosis, inflammation, and oxidative injury and promotes glial cell survival and angiogenesis. We hypothesized that HT and concurrent Epo will be safe and effective, improve survival, and reduce moderate-severe cerebral palsy (CP) in a term nonhuman primate model of perinatal asphyxia. Methodology: Thirty-five Macacanemestrina were delivered after 15-18 min of umbilical cord occlusion (UCO) and randomized to saline (n = 14), HT only (n = 9), or HT+Epo (n = 12). There were 12 unasphyxiated controls. Epo (3,500 U/kg × 1 dose followed by 3 doses of 2,500 U/kg, or Epo 1,000 U/kg/day × 4 doses) was given on days 1, 2, 3, and 7. Timed blood samples were collected to measure plasma Epo concentrations. Animals underwent MRI/MRS and diffusion tensor imaging (DTI) at <72 h of age and again at 9 months. A battery of weekly developmental assessments was performed. Results: UCO resulted in death or moderate-severe CP in 43% of saline-, 44% of HT-, and 0% of HT+Epo-treated animals. Compared to non-UCO control animals, UCO animals exhibit poor weight gain, behavioral impairment, poor cerebellar growth, and abnormal brain DTI. Compared to UCO saline, UCO HT+Epo improved motor and cognitive responses, cerebellar growth, and DTI measures and produced a death/disability relative risk reduction of 0.911 (95% CI -0.429 to 0.994), an absolute risk reduction of 0.395 (95% CI 0.072-0.635), and a number needed to treat of 2 (95% CI 2-14). The effects of HT+Epo on DTI included an improved mode of anisotropy, fractional anisotropy, relative anisotropy, and volume ratio as compared to UCO saline-treated infants. No adverse drug reactions were noted in animals receiving Epo, and there were no hematology, liver, or kidney laboratory effects. Conclusions/Significance: HT+Epo treatment improved outcomes in nonhuman primates exposed to UCO. Adjunctive use of Epo combined with HT may improve the outcomes of term human infants with HIE, and clinical trials are warranted.
Recombinant human erythropoietin (rEpo) is neuroprotective in neonatal models of brain injury. Pharmacokinetic data regarding the penetration of circulating rEpo into brain tissue is needed to optimize neuroprotective strategies. We sought to determine the pharmacokinetics of rEpo given intraperitoneally or subcutaneously in plasma and brain. We hypothesized that 1) exogenous rEpo would penetrate the blood-brain barrier (BBB), 2) brain and plasma Epo would correlate, and 3) brain injury would enhance rEpo penetration. Two hundred and eighty-four 7-d-old control, sham, or brain-injured rats were treated with i.p. or s.c. rEpo (0, 250, 2500, or 5000 U/kg) and killed at scheduled intervals. Plasma and brain tissue were collected. Epo concentrations were measured by ELISA. Intraperitoneal injection yielded a faster and greater peak concentration of plasma rEpo (Tmax 3 h, Cmax 10,016 Ϯ 685 mU/mL) than s.c. injection (Tmax 9 h, Cmax 6224 Ϯ 753 mU/mL). Endogenous brain Epo was below detection even after hypoxia exposure. Systemic rEpo crossed the BBB in a dose-dependent manner, peaked in brain at 10 h, and was increased after brain injury. We conclude that highdose rEpo is detectable in brain for Ͼ20 h after a single systemic injection. These pharmacokinetic data are valuable for planning of rEpo neuroprotection experiments.
Doses required to achieve desired vancomycin concentrations are similar in morbidly obese and normal weight patients when TBW is used as a dosing weight for the obese (approximately 30 mg x kg(-1) x d(-1)). Shorter dosage intervals may be needed when dosing morbidly obese patients so that steady-state trough concentrations remain above 5 microg x ml(-1) in this population. Because of the large amount of variation in required doses, vancomycin serum concentrations should be obtained in morbidly obese patients to ensure that adequate doses are being administered. Dosage requirements for morbidly obese patients with renal dysfunction require further study.
In an uncontrolled study, vancomycin pharmacokinetics were determined in four normal (total body weight [TBW], 65.9 to 89.1 kg) and six morbidly obese (TBW, 111.4 to 226.4 kg) subjects. The morbidly obese subjects were investigated 3 to 4 h after gastric bypass surgery. Mean terminal half-lives, volumes of distribution, and total body clearances for the normal controls and the morbidly obese subjects were 4.8 h, 0.39 liter/kg, and 1.085 ml/min per kg versus 3.2 h, 0.26 liter/kg TBW, and 1.112 ml/min per kg TBW. The mean terminal half-life and volume of distribution values were significantly different between the two groups. Strong correlations were found between TBW and both volume of distribution (correlation coefficient, 0.943) and total body clearance (correlation coefficient, 0.981). These results implied that TBW should be used to calculate vancomycin doses for morbidly obese patients. This was supported by the finding that there was no significant difference in the daily dose (in milligrams per kilogram per day) required to produce an average steady-state concentration of 15 ,ug/ml in the two groups (23.4 ± 1.5 mg/kg per day for normal weight subjects and 24.0 ± 3.4 mg/kg per day TBW for the postsurgery morbidly obese subjects). Therefore, the morbidly obese required higher total doses (in milligrams per day) than did normal weight subjects to achieve the same mean steady-state concentrations. In addition, normal weight and morbidly obese subjects had similar volumes of the central compartment (7.7 and 6.4 liters, respectively). To avoid high transient peak concentrations which could occur when obese patients are given larger total doses (in milligrams per day), maintenance doses may be given at more frequent intervals. The shorter mean terminal half-lives observed in morbidly obese patients allows more frequent dosing without excessive accumulation.
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