Photoluminescence imaging of focused ion beam induced individual quantum dots.

We report on scanning microphotoluminescence measurements that spectrally and spatially resolve emission from individual InAs quantum dots that were induced by focused ion beam patterning. Multilayers of quantum dots were spaced 2 µm apart, with a minimum single dot emission line width of 160 µeV, indicating good optical quality for dots patterned using this technique. Mapping 16 array sites, at least 65% were occupied by optically active dots and the spectral inhomogeneity was within 30 meV.

Safety and pharmacokinetics of the antiorthopoxvirus compound ST-246 following repeat oral dosing in healthy adult subjects.

ST-246, a novel compound that inhibits egress of orthopoxvirus from infected cells, is being evaluated as a treatment for pathogenic orthopoxvirus infections in humans. This phase I, double-blind, randomized, placebo-controlled, escalating multiple-dose study was conducted to determine the safety, tolerability, and pharmacokinetics of ST-246 administered as a single daily oral dose of 250, 400, or 800 mg for 21 days to nonfasting healthy human volunteers. ST-246 appeared to be well tolerated, with no serious adverse events (AEs). Headache, for which one subject in the 800-mg group discontinued the study, was the most commonly reported AE in all treatment groups. The multiple-dose pharmacokinetics of ST-246 was well characterized. The day 21 mean elimination half-lives were calculated at 18.8, 19.8, and 20.7 h for each of the 250-, 400-, and 800-mg/day dose groups, respectively. Steady state was reached by day 6 (within 3 to 5 half-lives), saturable absorption was observed at the 800-mg dose level, and the fraction of parent drug excreted in the urine was very low. Based on these results, administration of 400 mg/day ST-246 can be expected to provide plasma concentrations above the efficacious concentration demonstrated in nonhuman primate models in earlier studies.

Single-dose safety and pharmacokinetics of ST-246, a novel orthopoxvirus egress inhibitor.

ST-246 is a novel, potent orthopoxvirus egress inhibitor that is being developed to treat pathogenic orthopoxvirus infections of humans. This phase I, double-blind, randomized, placebo-controlled single ascending dose study (first time with humans) was conducted to determine the safety, tolerability, and pharmacokinetics of ST-246 in healthy human volunteers. ST-246 was administered in single oral doses of 500, 1,000, and 2,000 mg to fasting healthy volunteers and 1,000 mg to nonfasting healthy volunteers. ST-246 was generally well tolerated with no serious adverse events, and no subject was withdrawn from the study due to ST-246. The most commonly reported drug-related adverse event was neutropenia, which was found, upon further analysis, not to be treatment related. ST-246 was readily absorbed following oral administration with mean times to maximum concentration from 2 h to 3 h. Absorption was greater in nonfasting volunteers than in fasting volunteers. Administration of ST-246 resulted in exposure levels predicted to be sufficient for inhibiting orthopoxvirus replication compared to exposure levels in nonhuman primates in which ST-246 protected animals from lethal orthopoxvirus infection.

In vitro and in vivo characterization of a potential universal placebo designed for use in vaginal microbicide clinical trials.

The development of vaginal microbicides for the prevention of sexual transmission of HIV is becoming an increasingly important strategy in the battle against the AIDS epidemic. Several first generation microbicide candidates are entering Phase III efficacy trials, and several other candidates are in earlier stages of clinical development. The capacity to make accurate clinical assessments of the safety and efficacy of microbicide formulations is critical. Since microbicide trials will rely on a blinded, randomized, placebo-controlled design, it is important to employ a placebo formulation that does not distort either safety or efficacy assessments. Efficacy of the microbicide would be underestimated if the placebo itself provided a degree of protection. Conversely, a placebo with epithelial toxicity that increased susceptibility would cause an overestimation of microbicide efficacy. To address these issues, a hydroxyethylcellulose (HEC) placebo formulation has been developed and has been adopted for use in clinical evaluations of investigational microbicides as a "universal" placebo. In this report, the chemical and physical properties of this formulation are described, as well as its in vitro and in vivo effects on safety and efficacy. The results show that this "universal" placebo has adequate physical properties, is sufficiently stable as a vaginal gel formulation, and is safe and sufficiently inactive for use in the clinical study of investigational microbicides.

Expression, purification, and characterization of recombinant cyanovirin-N for vaginal anti-HIV microbicide development.

Cyanovirin-N (CV-N) is a prokaryotic protein under development as a topical anti-HIV microbicide, an urgent and necessary approach to prevent HIV transmission in at-risk populations worldwide. We have expressed recombinant CV-N as inclusion bodies in the cytoplasm of Escherichia coli. A purification scheme has been developed that exploits the physicochemical properties of this protein, in particular its stability in a harsh inclusion body purification scheme. Under the conditions developed, this system yields 140 mg of highly purified CV-N per liter of high-density cell culture, which represents a 14-fold increase over the best recombinant CV-N yield reported to date. This purification scheme results in monomeric CV-N as analyzed by SDS-PAGE, isoelectric focusing, and reverse phase- and size exclusion-HPLC. This recombinantly expressed and refolded CV-N binds to gp120 with nanomolar affinity and retains its potent anti-HIV activities in cell-based assays. The expression and purification system described herein provides a better means for the mass production of CV-N for further microbicide development.