The disposition of the synthetic corticosteroids, dexamethasone and prednisolone, in CSF was evaluated following bolus intravenous (IV) and intrathecal (IT) injection in a nonhuman primate model. Steroid concentration in plasma and CSF was measured with a radioimmunoassay following celite column chromatography. The CSF to plasma ratios of dexamethasone and prednisolone following IV bolus administration were 0.15 +/- 0.02 and 0.08 +/- 0.03, respectively. Although peak levels of the two steroids in the CSF reached equally potent levels when administered systemically in equipotent doses, the half-life of prednisolone in the CSF was shorter. In addition, there was a significant difference in the plasma protein binding of the two steroids, which may account for the differences in their CSF pharmacokinetics. Dexamethasone was 70% protein bound over a wide concentration range, while the protein binding of prednisolone was concentration dependent, ranging from 60% at 10 mumol/L to 95% at 0.5 mumol/L and below. After the initial distribution phase in plasma, CSF concentrations of dexamethasone and prednisolone approximated free plasma concentrations, indicating that penetration into the CSF was limited primarily by protein binding. At the plasma concentrations achieved following oral administration of standard doses of prednisone in children, the prednisolone (the active metabolite) is greater than 90% protein bound. The proportionally higher free plasma levels of dexamethasone result in greater penetration into the CSF. These findings may explain the lower rates of meningeal leukemia observed in children receiving dexamethasone instead of prednisone for the treatment of acute lymphoblastic leukemia (ALL).
Methotrexate (MTX), a mainstay in the treatment of acute lymphoblastic leukemia, is associated with both hepatic and neurologic toxicity. Like a folate, MTX is metabolized to polyglutamated derivatives (MTXGlun) with long intracellular half-lives. These metabolites may contribute to MTX toxicity through a direct effect on cellular metabolism or indirectly through a perturbation of folate homeostasis. To better define the effects of chronic MTX treatment, tissue levels of MTX, MTXGlun, and folate were measured in three monkeys treated with weekly intramuscular MTX for 1 year. Greater than 80% of the total tissue MTX found was in the form of polyglutamated derivatives. Most of these derivatives were MTXGlu3-5 but Glu6-7 were easily detectable. Total tissue folates were measured in liver, kidney, brain and testis with MTX treated animals having a 90% loss of total folate in brain tissue. This is of special interest since inborn errors of folate metabolism are often associated with severe neurologic abnormalities.
The reported ability of amitriptyline to enhance the penetration of diffusion limited substances across the blood brain barrier was investigated. The CSF:plasma ratio of methotrexate in primates was not significantly altered by amitriptyline pretreatment. Nor was methotrexate plasma clearance altered.
The present study was designed to determine if the hepatic toxicity of chronic low-dose methotrexate could be circumvented by administering the drug systemically, avoiding high initial hepatic drug exposure resulting from absorption of an oral dose into the portal circulation. Hepatic concentrations of methotrexate were determined in rats following chronic administration of 1 mg/kg by either the intraperitoneal (absorbed via the portal circulation) or subcutaneous route. Plasma drug profiles of methotrexate administered by the two routes were similar. The mean (+/- S.D.) hepatic methotrexate concentration following intraperitoneal administration was 3.12 +/- .47 nmol/gm wet weight and following subcutaneous administration it was 2.68 +/- .52 (p = .06). Renal methotrexate concentrations in the 2 groups were 1.23 +/- .27 and 1.26 +/- .49 nmol/gm wet weight, respectively (p = .88). The results of this study suggest that that oral administration does not lead to greater accumulation of methotrexate in the liver compared to systemic administration.
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