Concentrations of idoxuridine in serum, urine, and cerebrospinal fluid of patients with suspected diagnoses of Herpesvirus hominis encephalitis.

A reproducible microbiologic assay of microgram quantities of idoxuridine (IDU) in serum, urine, or cerebrospinal fluid is presented. The antiviral assay is not interfered with by type-specific antibody or interferon. During slow intravenous infusions of idox-uridine (4 mg/min) in patients with suspected diagnoses of Herpesvirus hominis encephalitis, the rate of inactivation and/or removal of drug exceeded its administration. During several rapid infusions of idoxuridine (50 mg/min) significant quantities of the drug were found in serum, urine, and cerebrospinal fluid. Idoxuridine is not significantly bound to serum proteins and is not deiodinated in fresh serum or urine in vitro to inactive products (iodouracil, uracil, iodide). It is rapidly excreted into the urine. Inactivation of IDU occurs in tissues. This antiviral assay of IDU in body fluids should be applicable to other viruses and potential antiviral agents. Minimal inhibitory concentrations of IDU for fresh isolates of Herpesvirus hominis (type 1 or 2) were determined. Type 1 herpesviruses' microplaques in baby hamster kidney cell (BHK 21) tissue cultures were sensitive to 2.5-10 mug/0.4 ml. Type 2 macroplaques required 25-50 mug/0.4 ml. This latter characteristic may be an additional biologic marker which may be useful in suggesting type-specificity of herpesvirus isolates.

Pharmacokinetics and metabolism of E-5-(2-[131I]iodovinyl)-2'-deoxyuridine in dogs.

E-5-(2-Iodovinyl)-2'-deoxyuridine (IVdU) is a potent inhibitor of herpes simplex virus type 1 replication in vitro. The selective antiviral activity of IVdU is due to preferential phosphorylation by the herpes simplex virus type 1-encoded thymidine kinase. This selective sequesteration provided the rationale for the development of radioiodinated IVdU as a potential radiopharmaceutical compound for use in noninvasive diagnosis of herpes simplex virus encephalitis. We studied the pharmacokinetics and the in vivo metabolism of [131I]IVdU in dogs. The radioactive components in plasma were characterized and quantitated by radio high-pressure liquid chromatography. During incubation with dog blood, [131I]IVdU was metabolized to the corresponding base (E)-5-(2-iodovinyl)uracil. 131I-labeled (E)-5-(2-iodovinyl)uracil accounted for 73% of the total radioactivity present in plasma after 2 h of incubation, suggesting that phosphorolysis of the nucleoside is the major degradation pathway of IVdU in blood. The in vivo studies showed that there was an initial rapid clearance of the tracer from blood, followed by a second very slow clearance phase. Evaluation of the renal excretion of the radiotracer showed that only 8% of the injected dose was excreted by kidneys over an 8-h period. IVdU was rapidly metabolized to three radioactive compounds. Two of these metabolites, the base (E)-5-(2-iodovinyl)uracil and iodide, were characterized. The radioactivity associated with these metabolites was responsible for the slow clearance phase. Our results suggest that the development of [131I]IVdU as a radiopharmaceutical compound will require measures to prevent its rapid degradation in vivo.