Pharmacokinetics of zidovudine phosphorylation in peripheral blood mononuclear cells from patients infected with human immunodeficiency virus

Pharmacokinetic individualisation of zidovudine therapy. Current state of pharmacokinetic-pharmacodynamic relationships

Zidovudine is the cornerstone of current antiretroviral treatment of human immunodeficiency virus (HIV) infection. Its use, however, frequently leads to adverse reactions, including myelosuppression. Zidovudine pharmacokinetics show large interindividual variation with indications of pharmacokinetic-pharmacodynamic relationships, but a clear therapeutic window has not yet been defined. Individualisation of zidovudine therapy with monitoring of drug concentrations might be desirable. This review considers (intracellular) monitoring of zidovudine and anabolites for individualisation of zidovudine therapy and the achievements in describing pharmacokinetic-pharmacodynamic relationships so far.

Long-term exposure to zidovudine affects in vitro and in vivo the efficiency of phosphorylation of thymidine kinase

The purpose of this study was to investigate the mechanism of acquired cellular resistance to AZT, a mechanism that has been described as a potential source of drug resistance in addition to viral mutations. To study this phenomenon the kinetics parameters of thymidine kinase (TK) activity have been defined in CEMazt, a cell line previously selected for resistance to AZT, in comparison with the parental AZT-sensitive CEM cells. The results revealed that the value of the maximum velocity (Vmax) of TK activity for deoxythymidine (dThd) phosphorylation is decreased in CEMazt as compared to the wild-type cell line (Vmax: CEM = 105.3 +/- 17.6 nmol/hr/mg of protein; CEMazt = 0.3 +/- 0.02 nmol/hr/mg of protein; p < 0.001). Furthermore, the enzyme affinity versus dThd is lower in CEMazt as compared to CEM (Km: CEM = 0.9 +/- 0.2 microM; CEMazt = 1.6 +/- 0.2 microM; p < 0.01). Consequently phosphorylation efficiency, expressed as the ratio between Vmax and Km, is also reduced in CEMazt (p < 0.001). To evaluate whether such a phenomenon may also occur in patients, ex vivo experiments were carried out by using PBMCs from HIV-infected patients, treated or not treated with AZT. The results (mean values from 10 patients for each group) indicate that a prolonged treatment (> 6 months) with AZT may modify the enzymatic kinetics of TK, leading to a significant reduction in the phosphorylation efficiency of the enzyme (4.07 +/- 1.7 in treated patients versus 13.5 +/- 1.7 in untreated patients; p < 0.001). These results indicate that AZT treatment can also induce a defect in TK activity in patients.

Zidovudine kinetics in the pregnant baboon

The devastating impact of human immunodeficiency virus (HIV) infection during pregnancy has made the pharmacologic evaluation of potentially therapeutic agents of high priority. The results presented here are the maternal pharmacokinetics from a series of experiments to delineate more clearly the complex maternal-fetal pharmacokinetics and the effects of AZT in the chronically instrumented maternal and fetal baboon during both steady state intravenous infusion and oral bolus dosage regimens. Two results of major clinical importance were found. First, during pregnancy, both the clearance and volume of distribution of AZT were increased. Plasma clearance in the pregnant animals was 51 +/- 10 ml/min/kg compared with 37 +/- 2 ml/min/kg in the nonpregnant animals, and steady state volume of distribution was 3.7 +/- 1.21/kg compared with 2.2 +/- 0.61/kg. Second, with continuous intravenous infusion plasma drug concentrations were easily maintained in the therapeutic range, whereas with oral administration plasma concentration fell below therapeutic levels within 2 h of the dose being given. Because maternal plasma concentrations are a major determinant of drug concentration achieved in the fetus, an understanding of drug kinetics in pregnancy is of vital importance when making recommendations regarding optimal drug therapy during pregnancy to maximize the beneficial effect--the prevention of HIV infection in children.

Human immunodeficiency virus replication in the presence of antiretroviral drugs: analogies to antineoplastic drug resistance

There are many analogies between antineoplastic therapy and antiviral therapy. For each there may be sanctuary sites in which the drug is ineffective because of decreased accumulation of the active form of the drug or increased competition by naturally occurring inhibitors. These sanctuaries may be restricted to anatomic or biochemical subsets of the population. A knowledge of these sanctuaries is essential to an understanding of the failure of therapy and for the design of more effective treatments. Eradication of these sanctuary sites may be important because they may be responsible for the viral replication or tumor cell division that continues to generate the diversity that drives clonal evolution. Ultimately, diversity as a consequence of the accumulation of mutations results in the selection of resistant viral or tumor cell variants and the failure of drug therapy. Maximizing therapy in an attempt to diminish the rate of generation of this diversity may result in better clinical outcomes, including a delay in the generation of variants with genetic drug resistance.

Pharmacokinetic optimisation of antiretroviral therapy in patients with HIV infection

More than 7 years after the introduction of zidovudine for treatment of HIV infection, little use has been made of the pharmacokinetic properties of this or any of the subsequently approved antiretroviral agents to optimise therapy. This is partly because of the limits of technologies developed to measure clinically relevant forms and concentrations of these drugs, and partly because the clinical community has been slow to recognise the potential benefits of pharmacokinetic optimisation of nucleoside analogue therapy in any disease. Nonetheless, for some of these agents, progress in understanding the relationship between pharmacokinetics and pharmacodynamics has been made. With zidovudine, for example, even though plasma concentrations have little clinical utility, evidence suggests that concentrations of active phosphorylated forms of zidovudine inside target cells are related to disease progression and toxicity. Furthermore, a decreased ability to phosphorylate zidovudine might be a prerequisite for the emergence of zidovudine-resistant HIV strains. Measurements of phosphorylated zidovudine inside cells similarly suggest that 100 mg of oral zidovudine every 8 hours approximates the optimal initial dosage regimen in asymptomatic patients. Increased plasma didanosine concentrations have been associated with several measures of clinical improvement in patients, and may be associated with an increased risk of toxicity as well. For zalcitabine and stavudine, however, the picture is much less clear. Their pharmacokinetic and pharmacodynamic relationships have not been studied in patients. Furthermore, there is insufficient data on the effects of age, gender, race and concurrent underlying conditions on the pharmacokinetics of all of these agents. Mounting evidence suggests that monitoring of these compounds could lead to individually optimised intervention strategies. Given the marginal benefits of therapy with these agents, their proven toxic effects and the lack of proven alternatives, it is critical that the clinical community strive to make the most effective use of these agents in the treatment of their patients.