Successful challenges using native E. coli asparaginase after hypersensitivity reactions to PEGylated E. coli asparaginase.

PURPOSE: Asparaginase is an essential component of pediatric acute lymphoblastic leukemia (ALL) therapy. However, asparaginase-induced hypersensitivity reactions can compromise its efficacy either by directly influencing the pharmacokinetics of asparaginase or by leading to a discontinuation of asparaginase treatment. Here, we report successful challenges using native Escherichia coli asparaginase after previous hypersensitivity reactions to both PEGylated E. coli asparaginase and Erwinia asparaginase. PATIENTS AND METHODS: The two patients included in this case report were diagnosed with B-precursor ALL at St. Jude Children's Research Hospital and were treated with a common regimen. Both patients developed hypersensitivity reactions to PEGylated E. coli asparaginase and Erwinia asparaginase early in treatment, and they were challenged with native E. coli asparaginase. Serum samples were collected for estimating the pharmacokinetic parameters of each patient during native E. coli asparaginase therapy. RESULTS: Challenges with native E. coli asparaginase were successful, and asparaginase serum concentrations above therapeutic levels were attained in both patients. CONCLUSIONS: These two cases suggest that some patients can be given native E. coli asparaginase after hypersensitivity reactions to PEGylated asparaginase and achieve therapeutic concentrations of the drug in serum.

Comparison of native E. coli and PEG asparaginase pharmacokinetics and pharmacodynamics in pediatric acute lymphoblastic leukemia.

Asparaginase (ASP) is used routinely in frontline clinical trials for the treatment of childhood acute lymphoblastic leukemia (ALL). The goals of this study were to assess the pharmacokinetics and pharmacodynamics of ASP and to mathematically model the dynamics between ASP and asparagine (ASN) in relapsed ALL. Forty children were randomized to receive either native or polyethylene glycolated (PEG) Escherichia coli ASP during reinduction therapy. Serial plasma ASP and ASN, cerebrospinal fluid (CSF) ASN, and serum anti-ASP antibody samples were collected. The ASP clearance was higher (P = 0.001) for native vs. PEG ASP. Patients with antibodies to PEG ASP had faster PEG ASP clearance (P = 0.004) than did antibody-negative patients. Patients who were positive for antibodies had higher CSF ASN concentrations than did those who were negative (P = 0.04). The modeling suggests that by modifying dosages, comparable ASN depletion is achievable with both preparations. At relapse, there were significant pharmacokinetic and pharmacodynamic differences attributable to ASP preparation and antibody status.

Deoxythioguanosine triphosphate impairs HIV replication: a new mechanism for an old drug.

Inhibition of HIV-1 reverse transcriptase (RT) and HIV protease are effective mechanisms for anti-retroviral agents, and the combined use of mechanistically different medications has markedly improved the treatment of HIV infected patients. The active metabolite of mercaptopurine and thioguanine (TG), deoxythioguanosine triphosphate, was shown to be incorporated into DNA by the polymerase function of HIV-1 RT and then to abrogate RNA cleavage by HIV-1 RNaseH. Treatment of human lymphocyte cultures with thioguanine produced substantial inhibition of HIV replication (IC(50)=0.035 microM, IC(95)=15.4 microM), with minimal toxicity to host lymphocytes (<10% at 15.4 microM TG, P<0.000005). Furthermore, low concentrations of TG and zidovudine were synergistic in inhibiting HIV replication in human lymphocytes (synergy volume=19 microM(2)%), without additive cytotoxicity to host lymphocytes. Thus, thiopurines are novel anti-retroviral agents that alter the DNA-RNA substrates for HIV RNaseH, thereby abrogating early stages of HIV replication.