The pharmacokinetics of cefazolin (Table 1) in 11 neonates were studied by Deguchi et al.10 There was marked interindividual variability in the distribution volume (Vd). This parameter ranged from 0.21 to 0.37 L/kg. The unbound fraction of cefazolin in neonatal plasma ranged from 0.22 to 0.83. The Vd of cefazolin highly correlated (r = 0.936; p<0.001) with the unbound fraction of this drug.

Young and Mangum9 suggested administering 25 mg/kg cefazolin every 8 to 12 h according to the neonate's postmenstrual age and postnatal age. When the postmenstrual age is >45 weeks, the interval between doses should be six hours.

Regazzi et al11 studied the pharmacokinetics of cefoxitin in 15 neonates. Their reported kinetic parameters are summarized in Table 1. The half-life (t1/2) negatively correlated with postnatal age (r = -0.58; p<0.05). Young and Mangum9 suggested administering 25 to 33 mg/kg cefoxitin every 8 to 12 h according to the neonate's postmenstrual age and postnatal age. When the post-menstrual age is >45 weeks, the interval between doses should be six hours.

Renlund and Pettay12 studied the pharmacokinetics of cefuroxime in 104 neonates, and their reported kinetic parameters are summarized in Table 1. The serum concentration of cefuroxime decreased with body weight from 25.6±9.9 μg/ml (<1 kg body weight) to 19.5±6.8 μg/ml (>4 kg body weight) because of the increase in GFR with neonatal maturation. t1/2 showed similar behavior, decreasing from 5.6 h (2.83 kg body weight) to 4.0 h (3.83 kg body weight). Cefuroxime did not accumulate over a period of 8 days and was excreted in the urine by more than 70%.

The kinetic parameters of cefotaxime are summarized in Table 2. Kafetzis et al13 described treating infections with cefotaxime in 32 neonates. The pathogens that sustained the infection were Escherichia coli, Klebsiella species, Pseudomonas aeruginosa, Serratia marcescens Staphylococcus aureus, Staphylococcus epidermidis, and β-hemolytic streptococcus. All of the isolated pathogens were susceptible to cefotaxime. These authors clustered the pharmacokinetic parameters of cefotaxime into four groups according to the neonates' gestational age and postnatal age. With neonatal maturation, t1/2 decreased and Cl increased. For brevity, Table 2 shows the two extremes of the cohort. In five patients with meningitis who received 50 mg/kg cefotaxime twice daily, the concentration of the drug was simultaneously measured in the CSF and serum 1 to 2 h after cefotaxime administration. The CSF and serum concentrations (mean±SD) were 18.2±7.4 and 38.6±10.3μg/ml, respectively. The CSF-to-serum ratio was 45±0.12%.

McCracken et al14 compared the kinetic parameters of cefotaxime in two groups of neonates; the first had an average body weight of 1,103 g, and the second had an average body weight of 2,561 g (p<0.0001). Vd and t1/2 were greater in the former than the latter group, whereas Cl was greater in the latter group and AUC was not different in the two groups.

Cefotaxime is converted into desacetyl cefotaxime in the neonate, and the peak concentration of desacetyl cefotaxime is about one-tenth of that of cefotaxime.15–17 The t1/2 of desacetyl cefotaxime is 9.4 h in very low-body-weight neonates.18 After 50 mg/kg cefotaxime, 50 to 60% of the dose is excreted unchanged in the urine, and approximately 20% is excreted as desacetyl cefotaxime.18 The renal Cl of cefotaxime is quantitatively more important than its metabolic Cl. Gouyon et al15 observed that the t1/2 of cefotaxime was negatively correlated with gestational age (r = -0.8954; p<0.01) and body weight (r = -0.8500; p<0.01). In contrast, Cl was positively correlated with gestational age (r = 0.7280; p<0.02) and body weight (r = 0.8667; p<0.02). The AUC of cefotaxime was negatively correlated with gestational age (r = -0.7950; p<0.01), but it did not correlate with body weight.

One recent study examined cefotaxime in neonates undergoing extracorporeal membrane oxygenation (ECMO).19 Doses of 50 mg/kg of body weight twice a day (postnatal age <1 week), 50 mg/kg three times a day (postnatal age 1 to 4 weeks) or 37.5 mg/kg four times a day (postnatal age >4 weeks) were found to provide sufficient periods of supra-MIC concentrations to give adequate treatment of infants on ECMO.

Young and Mangum9 suggested intravenously administering 25 to 33 mg/kg of cefotaxime every 8 or 12 h according to the postmenstrual age. When the postmenstrual age is >45 weeks, the interval between doses should be six hours.

The pharmacokinetic parameters of ceftazidime are summarized in Table 2. The ceftazidime concentration was measured after intravenous administration to seven neonates and after intramuscular administration to 9 infants.20 Ceftazidime concentrations after intravenous injection declined biexponentially, and the postdistributive phase occurred 30 to 60 min after administration. The peak ceftazidime concentration was 109±19.9 (intravenously) and 53.0±22.4 (intramuscularly; p<0.05). The t1/2 of ceftazidime was 4.7±1.5 (intravenously) and 3.8±1.1 (intramuscularly; NS).

McCracken et al21 described the pharmacokinetics of ceftazidime in three groups of neonates with gestational ages of ≤32, 33-37, and ≥38 weeks. Cl increased with gestational age, whereas t1/2, AUC and the trough concentrations decreased with gestational age.

Blumer et al22 described ceftazidime's pharmacokinetics and penetration into CSF in ten children aged 12 to 540 days. Ceftazidime at 50 mg/kg was intravenously administered once per day. The t1/2 of ceftazidime was 1.8±0.8 h, which was 2- to 4-fold lower than that reported in neonates during the first week of life (see Table 2). The two youngest children, aged 12 and 23 days, had a t1/2 of 3.6 and 2.18 h, respectively. The Cl of ceftazidime varied by more than 300%; such a large variation makes it inappropriate to report the average Cl, so the data from Blumer et al22 are not shown in Table 2. In contrast, Vd showed little variation and ranged from 0.27 to 0.38 L/kg, with a mean±SD of 0.34±0.07 L/kg. The ceftazidime concentrations in the CSF and serum were 4.7±2.5 and 145±30.4 μg/ml, respectively. The CSF-to-serum concentration of ceftazidime was 3.5±1.8%. The ratio of CSF to serum ceftazidime concentration showed a time-dependent increase, suggesting that ceftazidime was eliminated more slowly from the CSF than from the vascular compartment. The MIC of the isolated pathogens ranged from 0.0156 μg/ml (Neisseria meningitidis) to 0.125 μg/ml (Haemophilus influenzae, Type B).

Prenatal exposure to indomethacin resulted in significantly lower GFR and ceftazidime Cl values.23 The Cl of ceftazidime was 0.46 ml/min/kg (n = 23) in neonates who were prenatally exposed to indomethacin and 0.68 ml/min/mg (No = 84) in infants who were not exposed to indomethacin (p<0.05). The Cl of ceftazidime increased with gestational age (r = 0.83; p<0.001), whereas t1/2 showed an opposite trend (r = -0.54; p<0.001).23 The positive relationship between the Cl of ceftazidime and the Cl of inulin (r = 0.73; p<0.001) indicated that glomular filtration had an important effect on the Cl of ceftazidime. The Cl of ceftazidime correlated with the reciprocal of the serum concentration of creatinine (r = 0.72; p<0.001), suggesting that this compound may interfere with the renal Cl of ceftazidime.

The ceftazidime Cl increased from days 3 to 10 of life24 (Table 2). Such increases are due to an increase in GFR. The inulin Cl was 0.72 (day 3) and 0.91 ml/min (day 10; p<0.05). The Cl of ceftazidime correlated with GFR (r = 0.81; p<0.001). This correlation indicates the important role of GFR in the clearance of ceftazidime. The Vd of ceftazidime decreased between days 3 and 10 of life. During the first week of life, there was a significant decrease in extracellular water. Ceftazidime is mainly distributed in the extracellular water component, and a decrease of extracellular water may cause a decrease in the Vd during this period. Postnatal exposure to indomethacin prevented the pharmacokinetic modification seen from days three to ten of life. This may be explained by renal function's dependence on postnatal changes in extracellular water24 and the GFR impairment associated with indomethacin use.

Once-daily versus twice-daily administration of ceftazidime was studied by van den Anker et al.25 After 25 mg/kg twice daily, the trough concentration of ceftazidime was 42.0±13.4 μg/ml, which was higher than the target value of 10 μg/ml. After once-daily dosing, the trough concentration was 13.1±4.7 μg/ml, higher than the target value of 10 μg/ml and higher than major neonatal pathogen MIC99 values such as those for Streptococcus agalactiae and Escherichia coli26,27 (MIC99 <0.25 μg/ml). Therefore, these authors suggested that once-daily 25 mg/kg ceftazidime is the appropriate therapeutic schedule for ceftazidime in the neonate. This administration schedule conflicts with the one suggested by Young and Mangum.9 They suggested administering 30 mg/kg of ceftazidime every 8 or 12 h according to the postmenstrual and postnatal age. When the postmenstrual age is ≥45 weeks, ceftazidime should be administered every eight hours.

Ceftriaxone is contraindicated in neonates because it displaces bilirubin from albumin binding sites, resulting in a higher free bilirubin serum concentration with subsequent accumulation of bilirubin in the tissues.5,6 Even more dangerous is ceftriaxone's interaction with calcium. This interaction precipitates calcium, which results in serious adverse effects.7,8

Nonetheless, the literature on ceftriaxone was reviewed to provide a comprehensive study of cephalosporin use. The kinetic parameters of ceftriaxone are summarized in Table 2. The MIC90 of ceftriaxone ranged between 0.06 and 2 μg/ml for Escherichia coli, Klebsiella species, Proteus species, Enterobacter species, and Staphylococcus aureus, whereas Enterococci and Listeria monocytogenes are resistant.28 Ceftriaxone reached CSF concentrations of 5.4 and 6.4 μg/ml after intravenous doses of 50 and 75 mg/kg, respectively, and the CSF-to-peak serum concentration was 2.2-2.3%.29 Sixty percent of ceftriaxone is eliminated by the kidneys, and Mulhall et al30 have described the pharmacokinetics of this drug in the neonate (Table 2).

McCracken et al31 stratified the kinetic parameters of ceftriaxone based on neonatal body weight. The longest t1/2, 7.7 to 8.4 h, was found in neonates weighing ≤1,500 g, compared with 5.2 to 7.4 h in those weighing >1,500 g. The shortest t1/2 (3.5 and 4.8 h) was found in two neonates aged 45 to 33 days, respectively. Vd ranged between 0.50 and 0.61 l/kg; the smaller value was found in larger and older infants. Of nine neonates who received multiple ceftriaxone doses of 50 mg/kg every 12 h, five showed evidence of drug accumulation in the plasma. The concentrations of ceftriazone increased from 20 to 208% (mean 82%) at 0.5 h and from 15 to 165% (mean 53%) at 6 h after dosing. The ceftriaxone concentration in randomly collected urine ranged from 113 to 3,350 μg/ml (median 618 μg/ml).

Young and Mangum9 suggested administering 50 mg/kg every 24 h. To treat meningitis, they suggested a 100-mg/kg loading dose and then 80 mg/kg once daily.

The kinetic parameters of cefoperazone are summarized in Table 2. Gestational age correlated with Cl (r = 0.67; p = 0.01) and with a constant rate of elimination32 (Ke; r = 0.57; p = 0.05), while t1/2 decreased with advancing gestational age33 (r = -0.81; p<0.001). Rosenfeld et al34 studied the pharmacokinetics of cefoperazone (50 mg/kg) in 25 infants with a postnatal age of 1 to 2 days. The neonates were divided into three groups according to their gestational age. These authors repeated the cefoperazone treatment in 14 neonates aged 5 to 7 days, and the kinetic parameters were similar to those obtained at a postnatal age of 1 to 2 days. The percentage of the cefoperazone dose excreted in the urine on days 1 and 2 after birth was highest in the most premature patients (55%) but was not statistically different from that of full-term infants (37%). In infants 5 to 7 days old, cefoperazone excretion decreased in the full-term neonates (27%) and was 55% in the most premature infants (p<0.03). These data suggest that cefoperazone is partially metabolized and that its rate of metabolism depends on neonatal maturation. In adults, 69% of cefoperazone administered orally is eliminated by hepatic routes.35

A study based on seven neonates with body weights ranging from 1,540 to 3,600 g determined that cefoperazone penetrates the CSF.34 The cefoperazone concentration (μg/ml) in the CSF and serum was 5.3±3.6 and 89±58, respectively. The CSF-to-serum ratio was 10.9±9.6% and ranged from 1.4 to 31.7%.

The kinetic parameters of ceftizoxime are summarized in Table 2. The pharmacokinetics of ceftizoxime were studied in 52 infants whose postnatal age ranged from 0.1 to 189 days.36 t1/2 diminished steadily as the postnatal aged increased, whereas Cl showed the opposite trend. In this study, Vd remained relatively constant37, and ceftizoxime was excreted essentially unchanged via the kidney.36

The kinetic parameters of cefepime are summarized in Table 3. The serum creatinine concentration was negatively correlated (r = -0.79) with cefepime Cl in neonates.38 The serum concentration of creatinine was a strong predictor of cefepim Cl.38 The relationship between cefepime Cl and gestational age was not significant. The maturation of the renal excretory function is an important dosing determinant for cephalosporins, including cefepime. In premature infants, renal function is impaired. Because cefepime is mainly excreted unchanged, the premature and term neonates clear cefepime more slowly than more mature infants. In neonates, the cefepime Cl value was approximately 40% of that of more mature infants, which results in a longer t1/2 and a higher trough concentration. Vd was greater in infants with less than 30 weeks of postconceptional life.38 This is consistent with the greater total body water content in the extremely premature neonate.

Reed et al39 described the pharmacokinetics of cefepime in 37 infants and children aged between 2 months and 16 years. The data were grouped by age; the youngest patients ranged between two and six months of age, and the pharmacokinetic parameters of cefepime in these patients are reported in Table 3. Ninety percent of cefepime was recovered in the urine during 24-h urine collection; thus, the elimination of cefepime is in large part via the kidneys. The data for cefepime reveal disposition parameters similar to those of third-generation cephalosporins, including linearity over a broad dose range (250-2,000 mg), limited disposition and Cl mainly by the kidneys.

Lima-Rogel et al40 compared their own results on the pharmacokinetics of cefepime in neonates with those of Capparelli et al38 and Reed et al.39 The kinetic parameters of cefepime measured by Lima-Rogel et al40 and those of Capparelli et al38 were obtained in infants with similar demographic data, and t1/2 and Cl were comparable in these two studies. Reed et al39 described the pharmacokinetics of cefepime in older infants and children. In this last study, t1/2 was one-half and Cl was double the values in the neonates.

Information on the penetration of cephalosporins in the CSF is limited. Table 4 summarizes the concentrations of cefotaxime, ceftazidime, ceftriaxone, cefoperazone, and cefepime in the CSF and serum and the CSF-to-serum ratio. Information on the penetration in the CSF is available only for these cephalosporins. A relevant CSF-to-serum ratio was observed for cefotaxime13 and it was 45±12%. Another relevant penetration rate in the CSF was observed for cefoperazone,34 which was 10.9±9.6%. This figure seems to be overestimated, as it ranged from 1.4% to 37.1%. The rate of penetration of cefepime in the CSF was variable. In two preterm infants, the CSF-to-serum ratio was 30% and 87%, whereas in 7 term infants, it ranged from 3.6% to 59%, with a mean±SD of 16.7±21.4%. Table 4 shows the data for all nine neonates.