Screening and verification of CYP3A4 inhibitors from Bushen-Yizhi formula to enhance the bioavailability of osthole in rat plasma.

ETHNOPHARMACOLOGICAL RELEVANCE: With the features of multiple-components and targets as well as multifunction, traditional Chinese medicine (TCM) has been widely used in the prevention and treatment of various diseases for a long time. During the application of TCM, the researches about bioavailability enhancement of the bioactive constituents in formula are flourishing. Bushen-Yizhi formula (BSYZ), a TCM prescription with osthole (OST) as one of the main bioactive ingredients, have been widely used to treat kidney deficiency, mental retardation and Alzheimer's disease. However, the underlying biological mechanism and compound-enzyme interaction mediated bioavailability enhancement of OST are still not clearly illuminated. AIM OF THE STUDY: The aim of this study is to explore the material basis and molecular mechanism from BSYZ in the bioavailability enhancement of OST. Screening the potential CYP3A4 inhibitors using theoretical prediction and then verifying them in vitro, and pharmacokinetics study of OST in rat plasma under co-administrated of screened CYP3A4 inhibitors and BSYZ were also scarcely reported. MATERIALS AND METHODS: Screening of CYP3A4 inhibitors from BSYZ was performed with molecular docking simulation from systems pharmacology database. The screened compounds were verified by using P450-Glo Screening Systems. A multiple reaction monitoring (MRM) mass spectrometry method was established for OST quantification. Male Sprague-Dawley rats divided into four groups and six rats in each group were employed in the pharmacokinetics study of OST. The administrated conditions were group I, OST (20 mg/kg); group II, BSYZ (containing OST 1 mg/mL, at the dose of 20 mg/kg OST in BSYZ); group III, co-administration of ketoconazole (Ket, 75 mg/kg) and OST (20 mg/kg); group IV, co-administration of CYP3A4 inhibitor (10 mg/kg) and OST (20 mg/kg). They were determined by using HPLC-MS/MS (MRM) and statistical analysis was performed using student's t-test with p < 0.05 as the level of significance. RESULTS: 21 potential CYP3A4 inhibitors were screened from BSYZ compounds library. From the results of verification in vitro, we found 4 compounds with better CYP3A4 inhibition efficiency including Oleic acid, 1,2,3,4,6-O-Pentagalloylglucose, Rutin, and Schisantherin B. Under further verification, Schisantherin B exhibited the best inhibitory effect on CYP3A4 (IC50 = 0.339 µM), and even better than the clinically used drug (Ket) at the concentration of 5 µM. In the study of pharmacokinetics, the area under the curve (AUC, ng/L*h) of OST after oral administration of BSYZ, Ket and Schisantherin B (2196.23 ± 581.33, 462.90 ± 92.30 and 1053.03 ± 263.62, respectively) were significantly higher than that of pure OST treatment (227.89 ± 107.90, p < 0.01). CONCLUSIONS: Schisantherin B, a profoundly effective CYP3A4 inhibitor screened from BSYZ antagonized the metabolism of CYP3A4 on OST via activity inhibition, therefore significantly enhanced the bioavailability of OST in rat plasma. The results of this study will be helpful to explain the rationality of the compatibility in TCM formula, and also to develop new TCM formula with more reasonable drug compatibility.

In Vitro-In Vivo Correlation in Cocrystal Dissolution: Consideration of Drug Release Profiles Based on Coformer Dissolution and Absorption Behavior.

This study assessed the in vitro-in vivo correlation in cocrystal dissolution based on the coformer behavior. 4-Aminobenzoic acid (4ABA) was used as a coformer. Cocrystals of poorly water-soluble drugs with 4ABA, ketoconazole cocrystal (KTZ-4ABA), posaconazole cocrystal (PSZ-4ABA), and itraconazole cocrystal (ITZ-4ABA) were used. These three cocrystals generated supersaturated solutions in fasted state simulated intestinal fluid (FaSSIF) in a small-scale, 8 mL dissolution vessel. The time profile of the dissolved amount of 4ABA, an indicator of cocrystal dissolution, was significantly different among the three cocrystals. Under the conditions utilized, half of the KTZ-4ABA cocrystal solid rapidly dissolved within 5 min and the dissolved amount (% of applied amount) of KTZ and 4ABA was the same. Then, even though the residual solid cocrystal gradually dissolved, KTZ precipitated with time. The PSZ-4ABA cocrystal dissolved in a linear fashion with time but the dissolved concentration of PSZ reached a plateau in the supersaturated state and was maintained for at least 2 h. The dissolution rate of ITZ-4ABA was very slow compared to those of the other cocrystals, but a similar tendency was observed between cocrystal dissolution and the dissolved amount of ITZ. The rank order of the cocrystal dissolution rate based on the conformer concentration was KTZ-4ABA > PSZ-4ABA > ITZ-4ABA. Furthermore, cocrystallization of the three drugs with 4ABA significantly enhanced the oral drug absorption in rats. The rank order of the in vivo cocrystal dissolution rate by a deconvolution analysis with the plasma concentration-time profile of 4ABA was KTZ-4ABA > PSZ-4ABA > ITZ-4ABA, which corresponded well with the in vitro dissolution profiles of the cocrystals. These results indicate that analysis of cocrystal dissolution based on the coformer behavior may be useful to evaluate the in vitro and in vivo cocrystal dissolution.

Development and evaluation of a biorelevant medium simulating porcine gastrointestinal fluids.

Simulated human intestinal media, have proved to be a useful biopharmaceutics tool as a dissolution media for predicting in vivo dissolution and pharmacokinetic profile in humans. During drug product development preclinical animal models are also required to assess drug product performance, and there is a need to develop species specific intestinal media to similarly predict in vivo pharmacokinetic profiles in each preclinical model. Pigs, are increasingly being used in preclinical drug development, however to date there is a lack of quantitative information about the composition of porcine gastrointestinal (GI) fluids. As a result, a porcine biorelevant medium has not yet been developed, which is essential to improve interpretation and forecast of preclinical results using biorelevant in vitro dissolution studies. GI fluid samples, were collected from landrace pigs, and characterized. Fasted State Simulated Intestinal Fluid of pigs (FaSSIFp) was developed based on the physiological composition of the GI fluids in terms of pH, buffer capacity, osmolality, surface tension, as well as the bile salt, phospholipid and free fatty acid content. This study demonstrated that FaSSIFp was superior at predicting the solubility of the six model drugs in porcine intestinal fluids (PIF). A markedly high correlation (r2 0.98) was observed between the solubility obtained in PIF and FaSSIFp, whereas poor correlation (r2 0.12) was found for the solubility of the model drugs between human FaSSIF and PIF. This confirms that species specific biorelevant intestinal media are crucial to provide more accurate predictions of pharmacokinetic studies in preclinical models. Additionally, the availability of a species specific intestinal medium offers the potential to improve in vitro-in silico approaches to predict in vivo absorption and to reduce the overall number of animals needed in oral drug product development testing.

Formulation evaluation of ketoconazole microemulsion-loaded hydrogel with nigella oil as a penetration enhancer.

BACKGROUND: Onychomycosis is an opportunistic fungal infection often infecting people with compromised immune system. Currently available treatment interventions such as physical, surgical, and chemical-based approaches are successful in treating the condition, however, are painful and nonpatient complaint. Moreover, dermal creams with antifungal agents do not penetrate nail plate as required; hence, there is a necessity of developing a novel formulation with enhanced penetration. AIMS: The aim of the present research work was to develop ketoconazole microemulsion-loaded hydrogel formulation containing nigella oil as permeation enhancer for the treatment of onychomycosis. METHODS: Screening of oils, surfactants, and cosurfactants were done based on solubility studies followed by the construction of pseudo-ternary phase diagrams with 2% ketoconazole. The microemulsion was characterized for globule size, zeta potential, viscosity, and thermodynamic stability. Ex-vivo studies were carried out using Franz diffusion cells using porcine skin membrane. The antifungal activity of microemulsion-loaded hydrogel was evaluated using cup plate method using Candida albicans and Aspergillus niger. RESULTS: The optimized microemulsion had a composition of 54.97% Capryol:Nigella (2:1), 36.07% Transcutol:Propylene glycol (2:1), and 7.13% water and was later incorporated into polymeric gel base. The microemulsion-loaded hydrogel exhibited a 10 hours sustained release profile as compared to the marketed cream and an enhanced activity against marketed ketoconazole cream and compared with marketed ketoconazole formulation. CONCLUSION: The thermodynamic stability, sustained drug release with greater permeation, and enhanced activity due to the presence of nigella oil in microemulsion-loaded hydrogel warrant its application as an excellent vehicle for treating fungal infections.

Antileishmanial Efficacy and Pharmacokinetics of DB766-Azole Combinations.

Given the limitations of current antileishmanial drugs and the utility of oral combination therapy for other infections, developing an oral combination against visceral leishmaniasis should be a high priority. In vitro combination studies with DB766 and antifungal azoles against intracellular Leishmania donovani showed that posaconazole and ketoconazole, but not fluconazole, enhanced DB766 potency. Pharmacokinetic analysis of DB766-azole combinations in uninfected Swiss Webster mice revealed that DB766 exposure was increased by higher posaconazole and ketoconazole doses, while DB766 decreased ketoconazole exposure. In L. donovani-infected BALB/c mice, DB766-posaconazole combinations given orally for 5 days were more effective than DB766 or posaconazole alone. For example, 81% ± 1% (means ± standard errors) inhibition of liver parasite burden was observed for 37.5 mg/kg of body weight DB766 plus 15 mg/kg posaconazole, while 37.5 mg/kg DB766 and 15 mg/kg posaconazole administered as monotherapy gave 40% ± 5% and 21% ± 3% inhibition, respectively. Combination index (CI) analysis indicated that synergy or moderate synergy was observed in six of nine combined dose groups, while the other three were nearly additive. Liver concentrations of DB766 and posaconazole increased in almost all combination groups compared to monotherapy groups, although many increases were not statistically significant. For DB766-ketoconazole combinations evaluated in this model, two were antagonistic, one displayed synergy, and one was nearly additive. These data indicate that the efficacy of DB766-posaconazole and DB766-ketoconazole combinations in vivo is influenced in part by the pharmacokinetics of the combination, and that the former combination deserves further consideration in developing new treatment strategies against visceral leishmaniasis.

Best practices for the use of itraconazole as a replacement for ketoconazole in drug-drug interaction studies.

Ketoconazole has been widely used as a strong cytochrome P450 (CYP) 3A (CYP3A) inhibitor in drug-drug interaction (DDI) studies. However, the US Food and Drug Administration has recommended limiting the use of ketoconazole to cases in which no alternative therapies exist, and the European Medicines Agency has recommended the suspension of its marketing authorizations because of the potential for serious safety concerns. In this review, the Innovation and Quality in Pharmaceutical Development's Clinical Pharmacology Leadership Group (CPLG) provides a compelling rationale for the use of itraconazole as a replacement for ketoconazole in clinical DDI studies and provides recommendations on the best practices for the use of itraconazole in such studies. Various factors considered in the recommendations include the choice of itraconazole dosage form, administration in the fasted or fed state, the dose and duration of itraconazole administration, the timing of substrate and itraconazole coadministration, and measurement of itraconazole and metabolite plasma concentrations, among others. The CPLG's recommendations are based on careful review of available literature and internal industry experiences.

Drug-drug interactions between ketoconazole and berberine in rats: pharmacokinetic effects benefit pharmacodynamic synergism.

Ketoconazole (KTZ), a clinical antifungal agent, is a known inhibitor of CYP3A and permeability glycoprotein (P-gp). Berberine (BBR), a natural plant-derived product used for gastroenteritis, is a substrate of P-gp. Recently, a synergistic antifungal effect of KTZ combined with BBR has been revealed. In this study, we performed both in vivo and in vitro experiments to explore whether pharmacokinetic interactions between KTZ and BBR would benefit their pharmacodynamic synergism. After oral co-administration of 10 mg/kg KTZ with 60 mg/kg BBR, the average area under the curve (AUC) and the maximum concentration (C(max) ) for KTZ increased to 215% and 449% (p < 0.05), respectively, in male rats and 157% and 172% (p < 0.05), respectively, in female rats, compared with those administered KTZ alone. Area under the curve and C(max) for BBR increased to 173% and 142%, respectively, compared with those administered BBR alone. After intravenous co-administration of 0.5 mg/kg KTZ and 0.8 mg/kg BBR, the pharmacokinetic properties of KTZ remained the same, but AUC of BBR increased to 254% (p < 0.05) compared with those administered BBR alone. In rat liver microsomes, inhibitory concentration (IC)(50) of BBR inhibiting KTZ depletion was determined to be 103 µm. These resulting pharmacokinetic interactions may benefit their pharmacodynamic synergism to a certain extent.

Development of an in vivo rat screen model to predict pharmacokinetic interactions of CYP3A4 substrates.

With the advent of polytherapy, drug interactions have become a common clinical problem. Although in vitro data are routinely used for the prediction of drug interactions, in vitro systems are not dynamic and sometimes fail to predict drug interactions. We sought to use the rat as an in vivo screening model to predict pharmacokinetic interactions with ketoconazole. The pharmacokinetic studies were conducted following an oral dose of CYP3A substrates and an optimized oral regimen of ketoconazole. In vitro reaction phenotyping was conducted using individual human and rat cDNA-expressed CYP enzymes and human or rat liver microsomes in the presence of ketoconazole. The in vitro experiments indicated that the test compounds were largely metabolized by CYP3A in both human and rat. The compounds could be rank-ordered with respect to the increase in C(max) and area under the curve (AUC) values relative to midazolam in the presence of ketoconazole. The degree of pharmacokinetic interaction with ketoconazole was dependent, in part, upon their in vitro metabolism in the presence of rat CYP3A1/3A2 and in rat and human microsomes, co-incubated with ketoconazole, and on their fraction metabolized (f(m)) in the rat relative to other disposition pathways. Based on the rank-order of interaction, the compounds could be prioritized for further preclinical development.

The advantages of the Ussing chamber in drug absorption studies.

By adding high concentrations of test drugs to an Ussing chamber with rat jejunum, we established a system that yields very high correlations between the rat absorption percentage and the membrane permeability, and that can accurately predict the absorption percentage for rats. An advantage of this technique is that, unlike the results obtained using Caco-2, the slope of the absorption/membrane-permeability curve is gentle, which facilitates a more exact prediction of the absorption percentage. In addition, the results obtained with this technique demonstrated that it could be used to evaluate the absorption percentage of drugs with an affinity for P-glycoprotein (P-gp), which cannot be assessed using Caco-2. This method also allows for cassette screening, which would facilitate evaluation of the contribution of P-gp to absorption in the small intestine. Cassette screening showed that absorption of fexofenadine was unaffected by combination with the P-gp substrate ketoconazole. Consistent with this finding, in vivo studies showed that ketoconazole did not affect the Fa Fg for fexofenadine, a pharmacokinetic parameter that reflects absorption and bioavailability in the small intestine. This confirms the usefulness of the Ussing chamber for cassette screening and also suggests that intestinal P-gp has a minimal contribution to drug absorption.

Development of an in vivo preclinical screen model to estimate absorption and first-pass hepatic extraction of xenobiotics. II. Use of ketoconazole to identify P-glycoprotein/CYP3A-limited bioavailability in the monkey.

The effect of P-glycoprotein (Pgp) and/or CYP3A on the disposition of xenobiotics has been extensively investigated and is often of interest during drug discovery lead optimization. We have previously described a monkey pharmacokinetic screen to rapidly estimate absorption and first-pass extraction. In the present work, this monkey screen has been expanded to include an assessment of Pgp/CYP3A effects on absorption and first-pass extraction, using ketoconazole as a prototypic dual Pgp/CYP3A inhibitor. To generate a ketoconazole dosing regimen, the pharmacokinetics of ketoconazole were first determined in the monkey and were found to be consistent with that previously described in the rat, dog, and human. Dose-ranging experiments demonstrated that a single 10-mg/kg intraduodenal ketoconazole dose would provide an appropriate exposure; this dose was used throughout subsequent interaction experiments. Next, erythromycin and propranolol were explored as positive and negative control substrates for Pgp/CYP3A interactions, respectively. As anticipated, ketoconazole produced no change in the absorption or first-pass extraction of propranolol but resulted in a substantial increase in absorption and decrease in first-pass extraction of erythromycin. Finally, this ketoconazole-based monkey screen was deployed in a drug discovery setting, and examples of such use are presented. These experiments have allowed a more complete characterization of ketoconazole as a prototypic dual Pgp/CYP3A inhibitor and its use as a tool in a preclinical setting and further demonstrate the use of the monkey to investigate the role of Pgp/CYP3A in limiting the oral bioavailability of new drug candidates.

Peppermint oil enhances cyclosporine oral bioavailability in rats: comparison with D-alpha-tocopheryl poly(ethylene glycol 1000) succinate (TPGS) and ketoconazole.

Peppermint oil inhibits cyclosporine metabolism in vitro. The current work compared the effects of peppermint oil, ketoconazole, and D-alpha-tocopheryl poly(ethylene glycol 1000) succinate (TPGS) on cyclosporine oral bioavailability. Male Sprague-Dawley rats were administered cyclosporine (25 mg/kg) as the Sandimmune formulation. Peppermint oil (100 mg/kg) tripled the mean cyclosporine maximum concentration (C(max)) from 0.60 to 1.6 microg/mL and increased the area under the concentration versus time curve (AUC(0-infinity)) from 8.3 to 24.3 microg x h/mL. The median time to reach C(max) (t(max)) was increased from 2 to 6 h. Terminal half-life (10 h) and mean residence time (MRT; 15 h) were unaffected. Coadministration of TPGS (50 mg/kg) with cyclosporine in a saline vehicle doubled cyclosporine C(max) from 1.3 to 2.9 microg/mL and increased AUC(0-infinity) from 28.5 to 59.7 microg x h/mL. The t(max) was unchanged (3 h). Terminal half-life and MRT were increased by 44% (15.4 versus 10.7 h) and 24% (19.9 versus 16.0 h), respectively. Cyclosporine pharmacokinetics were not altered when corn oil was used instead of saline as a gavage vehicle, however the TPGS effect was abolished. Ketoconazole (10 and 20 mg/kg) had no effect on cyclosporine absorption. The lack of a significant ketoconazole effect may reflect poor metabolism of cyclosporine in rat intestinal tissue and suggests that inhibition of cytochrome P450 3A is not the only means by which peppermint oil enhances cyclosporine oral bioavailability.

Pruebas de sensibilidad in vitro para levaduras: evaluación de un micrométodo / In vitro susceptibility tests for yeasts: evaluation of a micromethod

Se evaluó un micrométodo para la realización de pruebas de sensibilidad de levaduras frente a antifúngicos, basado en el macrométodo en medio líquido estandarizado por el National Committee for Clinical Laboratory Standards (NCCLS) Subcommittee on Antifungal Susceptibility Testing. En este trabajo se compararon ambos métodos utilizando 6 cepas de referencia de diferente sensibilidad a los siguientes antifúngicos, anfotericina B (AMB), flucitosina (5FC), fluconazol (FCZ), itraconazol (ITZ), ketoconazol (KTZ) y miconazol (MCZ). Se observaron variaciones de sólo 1 ó 2 diluciones entre los resultados de las concentraciones inhibitorias mínimas (CIM) obtenidas con las dos técnicas. Asimismo, se compararon las lecturas visuales de CIM por micrométodo con las mediciones turbidimétricas del crecimiento en distintas concentraciones de antifúngicos frente a 47 aislamientos de Candida albicans. Existió una correlación significativa (p<0.001) entre CIM visual y la inhibición del 80 por ciento de crecimiento determinada por turbidimetría con AMB, 5FC, FCZ, ITZ y MCZ; en cambio no hubo correlación alguna para KTZ (p=1.00)

Pruebas de sensibilidad in vitro para levaduras: evaluación de un micrométodo / In vitro susceptibility tests for yeasts: evaluation of a micromethod

Se evaluó un micrométodo para la realización de pruebas de sensibilidad de levaduras frente a antifúngicos, basado en el macrométodo en medio líquido estandarizado por el National Committee for Clinical Laboratory Standards (NCCLS) Subcommittee on Antifungal Susceptibility Testing. En este trabajo se compararon ambos métodos utilizando 6 cepas de referencia de diferente sensibilidad a los siguientes antifúngicos, anfotericina B (AMB), flucitosina (5FC), fluconazol (FCZ), itraconazol (ITZ), ketoconazol (KTZ) y miconazol (MCZ). Se observaron variaciones de sólo 1 ó 2 diluciones entre los resultados de las concentraciones inhibitorias mínimas (CIM) obtenidas con las dos técnicas. Asimismo, se compararon las lecturas visuales de CIM por micrométodo con las mediciones turbidimétricas del crecimiento en distintas concentraciones de antifúngicos frente a 47 aislamientos de Candida albicans. Existió una correlación significativa (p<0.001) entre CIM visual y la inhibición del 80 por ciento de crecimiento determinada por turbidimetría con AMB, 5FC, FCZ, ITZ y MCZ; en cambio no hubo correlación alguna para KTZ (p=1.00) (AU)

Tissue distribution and antifungal effect of liposomal itraconazole in experimental cryptococcosis and pulmonary aspergillosis.

We studied the tissue distribution and in vivo antifungal effect of itraconazole, incorporated into pure dipalmitoylphosphatidylcholine (DPPC) multilamellar liposomes and administered intravenously. Eighty percent of the itraconazole was associated with DPPC. Drug levels in lung, brain, and liver, obtained after intravenous administration of tritiated itraconazole, were higher when the drug was administered intravenously as liposomal than when it was dissolved in cyclodextrin. Administration of the liposomal formulation also led to higher and sustained levels of intact itraconazole in serum. Efficacy was assessed in DBA/2 mice infected intravenously with 3 x 10(6) Cryptococcus neoformans, an inoculum responsible for early fatal pneumonia, or 3 x 10(5) C. neoformans, leading to delayed meningitis. In pneumonia, 20 mg/kg of liposomal itraconazole was more effective on survival than the same dose given intravenously in cyclodextrin or twice the dose administered orally dissolved in polyethylene glycol 200. In meningitis, liposomal itraconazole was also more efficient than the drug dissolved in cyclodextrin. These results were confirmed by colony counts in the brain and lung of infected mice. In immunosuppressed OF1 mice infected after inhalation of Aspergillus fumigatus spores, liposomal itraconazole (20 mg/kg x 3) was the only effective treatment. We conclude that intravenous liposomal delivery of itraconazole enhances both concentrations in infected tissues and the in vivo efficacy of the drug. Such passive targeting of antifungal agents other than amphotericin B might be helpful in the treatment of severe systemic mycoses, especially in the case of lung or brain involvement.

Itraconazole therapy for nonmeningeal coccidioidomycosis: clinical and laboratory observations.

Itraconazole, a new oral triazole antifungal agent, was administered in 75 courses to patients with chronic coccidioidomycosis at dosages of 50 to 400 mg/day for a median duration of 10 months. Assessment of efficacy was made with a standardized scoring system. Responses were seen in 42 of 58 assessable courses (72%). Nonresponse occurred exclusively in patients who had failed previous therapy and was most common in pulmonary disease. Toxicity was minimal at the doses studied. Pharmacokinetic analysis of itraconazole in serum at steady state showed negligible circadian variation; differences in serum concentrations among patients were large. Clinical isolates of Coccidioides immitis showed uniform in vitro susceptibility to itraconazole. Itraconazole shows impressive activity in this series of patients with refractory coccidioidomycosis. Further evaluation of itraconazole in this and in other systemic mycoses is in order.

The pharmacokinetics of BAY R3783 and its efficacy in the treatment of experimental cryptococcal meningitis.

We studied the pharmacokinetics and efficacy of BAY R3783, a new antifungal azole compound, in rabbits and compared it with fluconazole and itraconazole. BAY R3783 has at least two active metabolites, BAY U3624 and BAY U3625. We measured serum concentrations of all three compounds; the peak serum level for the parent compound was approximately two hours post dose. BAY R3783 and its metabolites also crossed the blood-CSF barrier; the mean CSF level of BAY R3783 was 30.5% of simultaneous serum levels. The in-vivo activity of the azoles was compared in a model of cryptococcal meningitis in immunosuppressed rabbits. BAY R3783, fluconazole and itraconazole all reduced yeast counts in the CSF with equal efficacy over ten days of therapy at 100 mg/day. In this model, BAY R3783 was effective in the treatment of cryptococcal meningitis.

Treatment of invasive aspergillosis with itraconazole.

PURPOSE: Invasive aspergillosis in the immunocompromised host is one of the most difficult therapeutic problems. Itraconazole, a new oral triazole, is inhibitory as well as fungicidal against Aspergillus species in vitro. It is active against Aspergillus infections in animal models. We present our experience with itraconazole therapy of 21 patients with aspergillosis. PATIENTS AND METHODS: Eighteen of the 21 patients received 400 mg of itraconazole orally per day; the other three received 100 to 200 mg daily. Serum concentrations of itraconazole were measured and susceptibility testing was performed according to previously described methods. RESULTS: Of 15 evaluable patients, responses were produced in 12. Four of five with invasive pulmonary disease, two of two with skeletal disease, one of two with pleural disease, one of one with pericardial, sinus, mastoid, or hepatosplenic aspergillosis, and one of one with onychomycosis responded. One patient with carotid artery disease did not show a response, although results of cultures were negative at autopsy. One responder with joint disease had a possible relapse three months after completing 12 months of therapy. Ten of these patients were immunocompromised (including four with neutropenia and two renal transplant recipients) and eight of these responded. Side effects with itraconazole, in contrast to previously available therapy, were rare. CONCLUSION: This experience suggests itraconazole may be an important advance in the therapy of aspergillosis.

Role of animal and human pharmacology in antifungal drug design.

Since the late sixties, several new antifungal drugs have become available. Initially, they were all intended for topical use, and, consequently, animal and human pharmacology always primarily aimed at confirming therapeutic efficacy. With the new tendency for the development of orally active antifungal drugs, human and animal pharmacology have significantly gained in importance. Indeed, not only is it now necessary to demonstrate the presence of adequate antifungal concentrations at the site of infection, but the systemic availability of the antifungal drug also necessitates an in-depth study of the effects of the drug on the function of several organs. As a result, human and animal pharmacology have become the cornerstones in the selection of orally active antifungal drugs. The development of ketoconazole has been an example of the need for optimized pharmacological screening. The choice of itraconazole--with its improved tissue affinity, its lower therapeutic dose requirements, and its increased selectivity for fungal cytochrome P-450--demonstrates very well that the use of animal and human pharmacology helps in the design of an antifungal drug with as much effect as possible on the fungus and as little effect as possible on the host.