Pharmacodynamics of Voriconazole for Invasive Pulmonary Scedosporiosis.

Scedosporium apiospermum is a medically important fungal pathogen that causes a wide range of infections in humans. There are relatively few antifungal agents that are active against Scedosporium spp. Little is known about the pharmacodynamics of voriconazole against Scedosporium Both static and dynamic in vitro models of invasive scedosporiosis were developed. Monoclonal antibodies that target a soluble cell wall antigen secreted by Scedosporium apiospermum were used to describe the pharmacodynamics of voriconazole. Mathematical pharmacokinetic-pharmacodynamic models were fitted to the data to estimate the drug exposure required to suppress the release of fungal antigen. The experimental results were bridged to humans using Monte Carlo simulation. All 3 strains of S. apiospermum tested invaded through the cellular bilayer of the in vitro models and liberated antigen. There was a concentration-dependent decline in the amount of antigen, with near maximal antifungal activity against all 3 strains being achieved with voriconazole at 10 mg/liter. Similarly, there was a drug exposure-dependent decline in the amount of circulating antigen in the dynamic model and complete suppression of antigen, with an area under the concentration-time curve (AUC) of approximately 80 mg · h/liter. A regression of the AUC/MIC versus the area under the antigen-time curve showed that a near maximal effect was obtained with an AUC/MIC of approximately 100. Monte Carlo simulation suggested that only isolates with an MIC of 0.5 mg/liter enabled pharmacodynamic targets to be achieved with a standard regimen of voriconazole. Isolates with higher MICs may need drug exposure targets higher than those currently recommended for other fungi.

Pharmacodynamics of the Novel Antifungal Agent F901318 for Acute Sinopulmonary Aspergillosis Caused by Aspergillus flavus.

Background: Aspergillus flavus is one of the most common agents of invasive aspergillosis and is associated with high mortality. The orotomides are a new class of antifungal agents with a novel mechanism of action. An understanding of the pharmacodynamics (PD) of the lead compound F901318 is required to plan safe and effective regimens for clinical use. Methods: The pharmacokinetics (PK) and PD of F901318 were evaluated by developing new in vitro and in vivo models of invasive fungal sinusitis. Galactomannan was used as a pharmacodynamic endpoint in all models. Mathematical PK-PD models were used to describe dose-exposure-response relationships. Results: F901318 minimum inhibitory concentrations (MICs) ranged from 0.015 to 0.06 mg/L. F901318 induced a concentration-dependent decline in galactomannan. In the in vitro model, a minimum concentration:MIC of 10 resulted in suppression of galactomannan; however, values of approximately 10 and 9-19 when assessed by survival of mice or the decline in galactomannan, respectively, were equivalent or exceeded the effect induced by posaconazole. There was histological clearance of lung tissue that was consistent with the effects of F901318 on galactomannan. Conclusions: F901318 is a potential new agent for the treatment of invasive infections caused by A flavus with PDs that are comparable with other first-line triazole agents.

Triazole Resistance Is Still Not Emerging in Aspergillus fumigatus Isolates Causing Invasive Aspergillosis in Brazilian Patients.

Aspergillus fumigatus azole resistance has emerged as a global health problem. We evaluated the in vitro antifungal susceptibility of 221 clinical A. fumigatus isolates according to CLSI guidelines. Sixty-one isolates exhibiting MICs at the epidemiological cutoff value (ECV) for itraconazole or above the ECV for any triazole were checked for CYP51A mutations. No mutations were documented, even for the isolates (1.8%) with high voriconazole MICs, indicating that triazoles may be used safely to treat aspergillosis in Brazil.