Pharmacodynamics and pharmacokinetics of recombinant hirudin via four non-parenteral routes

One of recombinant hirudin variants, rHV2, a polypeptide used as an anticoagulant agent in clinic, was administered to anesthetized rats via intratracheal, buccal, nasal and rectal routes. Prolongation in clotting time and thrombin time was measured to calculate pharmacological bioavailability. Plasma concentration of rHV2 was determined using a chromogenic thrombin substrate assay and pharmacokinetic parameters were obtained on the basis of a non-compartmental model. Intravenous administration was also performed as the gold standard by which the other routes were compared. Difference in pharmacological bioavailability (P.A.), bioavailability (F) and absorption rate of rHV2 was found for the four non-parenteral routes. The rank order for both P.A. and F was intratracheal>nasal>buccal>rectal. Absorption was more rapid after both intratracheal and rectal administration (tmax approximately 20-40 min), compared with that after nasal and rectal administration. It is evident that the pulmonary route is preferable to other three routes for successful systemic delivery of rHV2.     

Pharmacodynamics and pharmacokinetics studies of phenoxazinium derivatives for antimalarial agent

In vivo antimalarial drug candidates screening test was carried out on a series of water-soluble 3,7-bis(dialkylamino)phenoxazin-5-ium derivatives. Among them, 3-(diethylamino)-7-(piperidin-1-yl)phenoxazin-5-ium chloride (SSJ-206) showing highest efficacy was chosen for further pharmcodynamics and pharmacokinetics study. It was supported from these data that the phenoxazinium salts, SSJ-206, would be one of hopeful candidates as an oral antimalarial drug.     

Pharmacodynamics and pharmacokinetics of dihydroergotamine (DHE) in conscious beagle dogs

Dihydroergotamine (DHE) elicits selective and longlasting venoconstrictor activity though the drug disappears rapidly from the blood. Changes in the diameter of the saphenous vein were determined in conscious beagle dogs and compared to plasma level-time curves of DHE and its metabolites. After both intravenous and oral administration of DHE the venoconstrictor response is of markedly longer duration than would be expected on the basis of the half life for elimination of DHE from blood. Furthermore, 3 out of 5 of the main metabolites of DHE elicited considerable constrictor effects when infused locally into the vein. It is suggested that the long duration of the DHE-induced venoconstriction is due to an extremely slow dissociation of the drug from its receptor sites on the venous smooth muscle cell and to the formation of active metabolites.     

Pharmacodynamics and pharmacokinetics of the insulin-mimetic agent vanadyl acetylacetonate in non-diabetic and diabetic rats

The objectives of this study were to evaluate the pharmacodynamics and pharmacokinetics of vanadyl acetylacetonate (VAC) in rats. Pharmacodynamic study was carried out using non-diabetic and diabetic rats by subcutaneous (s.c.) and intragastric (i.g.) administrations at single dose or multiple doses. Pharmacokinetic study was performed using non-diabetic rats. Results showed that VAC resulted in a significant decrease of plasma glucose levels in diabetic rats in all dosing levels, and nearly restored hyperglycemic values to normal values after s.c. injection at a single dose of 2, 4, and 8 mg vanadium (V)/kg, or after i.g. administration at multiple doses of 3 and 6 mg V/kg once daily for seven consecutive days, respectively. The VAC could be rapidly absorbed and T(max) values ranged from 0.9 +/- 0.3 h for s.c. injection to 3.0 +/- 0.9 h for i.g. administration. The average absolute bioavailabilities for i.g. administrations at a single dose of 3, 6, and 10 mg V/kg were 34.7%, 28.1%, and 22.8%, respectively. After i.g. administration at a single dose of 10 mg V/kg, the average elimination half-lives obtained from non-diabetic rats were very long ranging from 144.7 +/- 8.7 h in plasma to 657.3 +/- 34.8 h in femur tissue. In conclusion, VAC widely distributed in various tissues and accumulated more in the femur tissue. The time to reach maximal vanadium level after s.c. injection or i.g. administration was not coincident with the time to reach maximal hypoglycemic effect. The accumulated vanadium in bone, kidney or other tissues may gradually release and exert a longer action. In present dosing levels and administration routes, VAC was effective for lowering plasma glucose levels in diabetic rats and could reverse the higher triglyceride and cholesterol levels to the normal ranges. VAC did not influence the insulin levels in plasma and not cause obvious toxic signs like diarrhea.     

Azasteroids as antifungals

Azasteroids and derivatives thereof with antifungal potential are reviewed. Special emphasis is put on steroids with nitrogen as part of the steroidal framework, natural substances, and lines of development emerging from them.     

Chicory extracts from Cichorium intybus L. as potential antifungals

In this work extracts from roots of the common vegetable Cichorium intybus L., highly appreciated for its bitter taste, were studied to investigate their possible biological activity on fungi from a variety of ecological environments: some are parasites on plants (phytopathogens) or of animals and humans (zoophilic and anthropophilic dermatophytes), others live on the soil and only seldom parasitize animals (geophilic dermatophytes). The extracts were ineffective on geophilic species and on tested phytopathogens, with the exception of Pythium ultimum, whereas they inhibited the growth of zoophilic and anthropophilic dermatophytes, in particular Trichophyton tonsurans var. sulfureum, whose treatment caused morphological anomalies, here observed by scanning electron microscopy. This behaviour is discussed on the basis of the presence in the chicory extract of the two main sesquiterpene lactones, 8-deoxylactucin and 11β,13-dihydrolactucin.     

In-Silico Pharmacodynamics

Adverse effects are exhibited by most drugs in current clinical practice, the causes for which are often not known. In this post genomic era, bioinformatics has the potential to address several issues in understanding the mechanism of drug action and in designing improved drugs. This study describes the analysis of the possible pharmacodynamic behaviour of antihistamines blocking the histamine H(2) receptor (H(2)-antihistamines), by adopting the basic tenets of a systems biology approach. The different components that could form an appropriate sub-system are identified, thus providing a system landscape. Docking and analysis of the chosen antihistamines into each of these components resulted in identifying histamine N-methyl transferase (HNMT) as a potential unintended target for H(2)-antihistamines. Correlation with experimental data available from the literature indicates the inhibition of HNMT to be a possible cause for the adverse effects exhibited by these drugs. Implications for design of safer H(2)-antihistamines are discussed. The method reported here has the potential for application as a general strategy in understanding drug effects.     

Resistance to antifungals that target CYP51

Fungal diseases are an increasing global burden. Fungi are now recognised to kill more people annually than malaria, whilst in agriculture, fungi threaten crop yields and food security. Azole resistance, mediated by several mechanisms including point mutations in the target enzyme (CYP51), is increasing through selection pressure as a result of widespread use of triazole fungicides in agriculture and triazole antifungal drugs in the clinic. Mutations similar to those seen in clinical isolates as long ago as the 1990s in Candida albicans and later in Aspergillus fumigatus have been identified in agriculturally important fungal species and also wider combinations of point mutations. Recently, evidence that mutations originate in the field and now appear in clinical infections has been suggested. This situation is likely to increase in prevalence as triazole fungicide use continues to rise. Here, we review the progress made in understanding azole resistance found amongst clinically and agriculturally important fungal species focussing on resistance mechanisms associated with CYP51. Biochemical characterisation of wild-type and mutant CYP51 enzymes through ligand binding studies and azole IC₅₀ determinations is an important tool for understanding azole susceptibility and can be used in conjunction with microbiological methods (MIC₅₀ values), molecular biological studies (site-directed mutagenesis) and protein modelling studies to inform future antifungal development with increased specificity for the target enzyme over the host homologue.     

From natural products to clinically useful antifungals

In our search for natural products with a broad spectrum of antifungal activity as lead compounds for novel treatments for mycoses, we have isolated echinocandin-type lipopeptide FR901379 and lipopeptidolactone FR901469, as novel water-soluble antifungal agents that inhibit the synthesis of 1,3-beta-glucan, a key component of the fungal cell wall. Since the cell wall is a feature unique to fungi and is not present in nonfungal eukaryotic cells, inhibitors of the synthesis of fungal cell wall components such as 1,3-beta-glucan have potential for selective toxicity to fungi and not to the host. In this short review, we describe efforts directed at synthetic modification of FR901469 and FR901379 with the ultimate goal of identifying new entities with suitable profiles as development candidate compounds. The main thrust of our work to date has been replacement of the highly flexible lipophilic side chains of the natural products with a view to reducing the hemolytic potential associated with these compounds, and to enhance chemical stability and/or in vivo antifungal efficacy. As a result of these efforts, we recently discovered a novel analog, FK463 (micafungin). Micafungin is currently in phase III clinical trials worldwide as a parenteral agent for various mycoses, and a new drug application (NDA) was recently filed in Japan.     

Cell-penetrating peptides as antifungals towards Malassezia sympodialis

Aim: To determine whether different antimicrobial peptides (AMPs) and cell‐penetrating peptides (CPPs) are able to inhibit the growth of the commensal yeast Malassezia sympodialis, which can act as a trigger factor in different skin disorders, such as atopic eczema (AE), seborrhoeic eczema (SE) and dandruff. Methods and results: The antifungal activity of 21 different AMPs and CPPs was investigated by microdilution assay and plate counting to determine the number of colony forming units. Five CPPs and one AMP showed fungicidal activity at submicromolar concentrations. Importantly, no membrane damage on human keratinocytes was detected after peptide treatment. Conclusions: Several CPPs, while being nontoxic to mammalian cells, possess growth inhibitory activity on the very stringent yeast M. sympodialis. Significance and impact of study: Our findings that five CPPs and one AMP that are harmless towards mammalian cells act as antifungal agents against M. sympodialis opens up the possibility to use these in the treatment for AE, SE and dandruff. To our knowledge, this is the first time peptides have been identified as antifungal agents against M. sympodialis. Further studies to elucidate the mechanism are warranted.     

Molecular basis of resistance to azole antifungals

The increased incidence of invasive mycoses and the emerging problem of antifungal drug resistance has prompted investigations of the underlying molecular mechanisms, particularly for the azole compounds central to current therapy. The target site for the azoles is the ERG11 gene product, the cytochrome P450 lanosterol 14alpha-demethylase, which is part of the ergosterol biosynthetic pathway. The resulting ergosterol depletion renders fungal cells vulnerable to further membrane damage. Development of azole resistance in fungi may occur through increased levels of the cellular target, upregulation of genes controlling drug efflux, alterations in sterol synthesis and decreased affinity of azoles for the cellular target. Here, we review the adaptative changes in fungi, in particular Candida albicans, in response to inhibitors of ergosterol biosynthesis. The molecular mechanisms of azole resistance might help in devising more effective antifungal therapies.