ABSTRACT
The benzopyran HP1, a compound isolated from Hypericum polyanthemum, has demonstrated significant opioid-mediated antinociceptive activity after its oral administration. Despite the pharmacological potential, the poor aqueous solubility limits the oral absorption of this compound. For this reason, HP1 has been alternatively incorporated in lipid-based drug delivery systems. Given that nanoemulsions showed higher antinociceptive action than the free compound in a previous report, in this study, the main objective was to investigate the intestinal transport mechanisms of this system. The Ussing chamber model and rat jejunum were selected for this purpose. The apparent permeability coefficient of HP1 increased approximately 5.3 times after its incorporation in nanoemulsions. Considering that the absorptive transport of HP1 was significantly higher than the secretory transport, the participation of active transporters was suggested. The amount of HP1 in the acceptor chamber was reduced during permeability assays performed at 4⯰C, supporting the hypothesis that active transporters are involved in the intestinal transport of this compound. The amount of free fatty acids released from nanoemulsion was approximately 60% after 90â¯min, demonstrating that part of this system is disassembled before absorption. Nanoemulsion constituents would be able to form new structures with biological constituents, leading to a rapid solubilization of HP1. A mucoadhesion rate of 50% was achieved by nanoemulsion after 30â¯min, which would also contribute to explain the higher absorption of this system. The particle size of the nanoemulsion is also compatible with endocytosis-mediated transport. Taken together, these results suggest that nanoemulsions containing HP1 could be efficiently delivered to humans considering that different absorption mechanisms are exploited.
Subject(s)
Benzopyrans/administration & dosage , Intestinal Absorption , Jejunum/metabolism , Nanostructures/administration & dosage , Adhesiveness , Animals , Emulsions , In Vitro Techniques , Male , Permeability , Rats, WistarABSTRACT
Recently, many efforts are taken to identify the intestinal uptake and efflux transporters since they are responsible for the absorption of many drugs as their interactions. Norfloxacin (NFX) is a fluoroquinolone that presents low solubility and low permeability, and as a consequence, low bioavailability. In this context, the aim of this study is evaluate for the first time the intestinal permeability mechanisms of NFX by Ussing chamber model. The low permeation of NFX at low temperature, where the efflux pumps are not active, reveals that NFX permeation is transporter-dependent. The permeation study at different level of intestine demonstrated that NFX passage is in the decrescent order: ileumâ¯>â¯jejunumâ¯>â¯duodenumâ¯>â¯colon, probably attributed to transporters that are expressed differently along the intestinal tract. NFX intestinal flow was evaluated in the presence of many inhibitors and substrates to identify the uptake and efflux transporters implicate in NFX permeability mechanism. It could be observed that BCRP and MRPs are involved in the NFX efflux and PEPT1, PMAT and OCT in the NFX uptake transport. Furthermore, this work revealed that NFX has itself an affinity for OCTN and OATP, demonstrating that NFX could inhibit these transporters and influence the absorption of other drugs. The updated description of NFX intestinal permeability factors could contribute to the development of rational pharmaceutical formulations that could circumvent the efflux problems and consequently improve NFX biopharmaceutical properties and avoid drug-drug interactions.
Subject(s)
Anti-Bacterial Agents/metabolism , Intestinal Absorption , Intestinal Mucosa/metabolism , Membrane Transport Proteins/metabolism , Norfloxacin/metabolism , Animals , Biological Transport , Male , Rats, WistarABSTRACT
Nanosponges are a novel class of hyperbranched cyclodextrin-based nanostructures that exhibits remarkable potential as a drug host system for the improvement in biopharmaceutical properties. This work aims the development of cyclodextrin-based nanosponge of norfloxacin to improve its physicochemical characteristics. ß-cyclodextrin was used as base and diphenyl carbonate as crosslinker agent at different proportions to produce nanosponges that were evaluated by in vitro and in vivo techniques. The proportion cyclodextrin:crosslinker 1:2â¯M/M was chosen due to its higher encapsulation efficiency (80%), revealing an average diameter size of 40â¯nm with zeta potential of -19â¯mV. Norfloxacin-loaded nanosponges exhibited higher passage of norfloxacin in comparison to norfloxacin drug alone by Ussing chamber method. The nanosponge formulation also revealed a mucoadhesive property that could increase norfloxacin absorption thus improving its antibiotic activity in an in vivo sepsis model. Therefore, nanosponges may be suitable carrier of norfloxacin to maximize and facilitate oral absorption.
Subject(s)
Anti-Bacterial Agents/administration & dosage , Cyclodextrins/chemistry , Drug Carriers/chemistry , Intestinal Absorption , Nanostructures/chemistry , Norfloxacin/administration & dosage , Animals , Anti-Bacterial Agents/pharmacokinetics , Drug Liberation , Female , Male , Norfloxacin/pharmacokinetics , Rats , Rats, WistarABSTRACT
ABSTRACT Hypericum species, Hypericaceae, are recognized as a source of therapeutical agents. Purified fractions and isolated compounds have been shown antimicrobial activity. As the indiscriminate use of antifungals and the increase of infections caused by emerging species are leading to the search of new alternative treatments, the aim of this study was to continue the study with Hypericum carinatum Griseb. lipophilic fraction, rich in phloroglucinol derivatives, investigating the effect of its association with fluconazole against emerging yeasts (Candida krusei, C. famata, C. parapsilosis and Cryptococcus neoformans). The synergistic activity between H. carinatum lipophilic fraction and fluconazole was assessed by two methodologies for multiple dose–response analysis: checkerboard and isobologram. Regarding synergistic experiments, the effect of the association was higher than the effect of fluconazole alone against Candida krusei and C. famata isolates (MIC fluconazole decreased about eight and four folds, respectively), suggesting that, somehow, H. carinatum lipophilic fraction compounds are facilitating the action of this drug. On the other hand, when tested against Cryptococcus neoformans and C. parapsilosis, fluconazole showed better results than the association. Thus, against Candida krusei and C. famata, the lipophilic fraction of H. carinatum was able to reduce the MIC values of fluconazole and could be considered as a potential alternative to be used against emerging yeast species.
ABSTRACT
Three dimeric acylphloroglucinols, austrobrasilol A, austrobrasilol B and isoaustrobrasilol B were isolated from the flowers of Hypericum austrobrasiliense (Hypericaceae, section Trigynobrathys). Their structures were elucidated using mass spectrometry and NMR experiments (1D and 2D), and by comparison with previously reported data for other dimeric acylphloroglucinols isolated from Hypericum and Elaphoglossum genera. The three compounds were orally administered in mice at equimolar doses to uliginosin B (15mg/kg, p.o.) displaying antinociceptive activity in the hot-plate test. The compounds did not induce motor impairment in the rotarod apparatus.