Biopharmaceutic study and in vivo efficacy of natural and derivatives flavanones formulations.

Aim: The development and characterization of nanostructured flavanone formulations (FF) of 1 extracted from Eysenhardtia platycarpa and 1a, 1b, 1c and 1d derivatives by structural modification of 1 as anti-inflammatory candidates for topical treatment of local inflammation. Materials & methods: The FF were physicochemical characterized and the behavior release, skin permeation and, in vivo anti-inflammatory efficacy in the rat model were studied. Results: The FF revealed sustained drug release and showed slow drug penetration in human skin. The FF reduced inflammation in comparison with the standard formulation. Conclusion: The FF could be effective systems for the delivery and controlled release of flavanones on the skin, and the chemical modification of lead molecule 1 improved the efficacy.

Carprofen Permeation Test through Porcine Ex Vivo Mucous Membranes and Ophthalmic Tissues for Tolerability Assessments: Validation and Histological Study.

Carprofen (CP), a non-steroidal anti-inflammatory drug (NSAID), is profusely used in veterinary medicine for its analgesic and anti-inflammatory activity. Some undesirable effects are associated with its systemic administration. Alternative local routes are especially useful to facilitate its administration in animals. The main aim of this paper is to validate the suitability of ex vivo permeation experiments of CP with porcine mucous membranes (buccal, sublingual and vaginal) and ophthalmic tissues (cornea, sclera and conjunctiva) intended to be representative of naïve in vivo conditions. Chromatographic analysis of CP in membrane-permeated samples and drug-retained have been validated following standard bioanalytical guidelines. Then, recovery levels of drugs in tissue samples were assessed with aqueous phosphate buffered saline (PBS) buffer to preserve the histological integrity. Finally, as a proof of concept, a series of CP permeation tests in vertical Franz diffusion cells has been performed to evaluate permeation flux and permeability constants in all tissues, followed by a histological study for critical evaluation. Furthermore, synthetic tissue retention-like samples were prepared to verify the value of this experimental study. Results show linear relationships with good determination coefficient (R2 > 0.998 and R2 > 0.999) in the range of 0.78 to 6.25 mg/mL and 3.125 mg/mL to 100 mg/mL, respectively. Low limits of quantification around 0.40 µg/mL were allowed to follow permeation levels until a minimum of 0.40% of the locally-applied dose. This method showed a good accuracy and precision with values lower than 2%. After the recovery technique, reproducible values below 30% were achieved in all tissues, suggesting it is a non-damaging method with low efficiency that requires the use of further solvents to enhance the extraction percentages. After permeation and histology tests, no relevant peak interferences were detected, and no cell or tissue damage was found in any tissue. In conclusion, results demonstrate the suitability of this test to quantify the distribution of CP with good histological tolerability.

Ex Vivo Permeation of Carprofen Vehiculated by PLGA Nanoparticles through Porcine Mucous Membranes and Ophthalmic Tissues.

(1) Background: Carprofen (CP), 2-(6-chlorocarbazole) propionic acid, is used as an anti-inflammatory, analgesic and anti-pyretic agent and it belongs to the family of non-steroidal anti-inflammatory drugs (NSAIDs). CP has some adverse reactions in systemic administration; for this reason, topical administration with CP nanoparticles (CP-NPs) can be an optimal alternative. The main objective of this work is the investigation of ex vivo permeation of CP through different types of porcine mucous membranes (buccal, sublingual and vaginal) and ophthalmic tissues (cornea, sclera and conjunctiva) to compare the influence of CP-NPs formulation over a CP solution (CP-Solution). (2) Methods: The ex vivo permeation profiles were evaluated using Franz diffusion cells. Furthermore, in vivo studies were performed to verify that the formulations did not affect the cell structure and to establish the amount retained (Qr) in the tissues. (3) Results: Permeation of CP-NPs is more effective in terms of drug retention in almost all tissues (with the exception of sclera and sublingual). In vivo studies show that neither of the two formulations affects tissue structure, so both formulations are safe. (4) Conclusions: It was concluded that CP-NPs may be a useful tool for the topical treatment of local inflammation in veterinary and human medicine.

Biopharmaceutical Development of a Bifonazole Multiple Emulsion for Enhanced Epidermal Delivery.

Efficient topical delivery of imidazolic antifungals faces the challenge of overcoming its limited water solubility and its required long-lasting duration of treatments. In this paper, a hydrophilic multiple emulsion (ME) of Bifonazole (BFZ) is shown to maximize its skin retention, minimize its skin permeation, and maintain an acceptable level of being harmless in vivo. The formulations were pharmaceutically characterized and application properties were assessed based on viscosity measurements. Non-Newtonian pseudoplastic shear thinning with apparent thixotropy was observed, facilitating the formulation retention over the skin. The in vitro release profile with vertical diffusion cells showed a predominant square-root release kinetic suggesting an infinite dose depletion from the formulation. Ex vivo human skin permeation and penetration was additionally evaluated. Respective skin permeation was lower than values obtained with a commercial O/W formulation. The combination of amphoteric and non-ionic surfactants increased the bifonazole epidermal accumulation by a factor of twenty. This fact makes the possibility of increasing its current 24 h administration frequency more likely. Eventual alterations of skin integrity caused by the formulations were examined with epidermal histological analysis and in vivo preclinical measurements of skin elasticity and water retrograde permeation. Histological analysis demonstrated that the multiple emulsions were harmless. Additionally, modifications of in vivo skin integrity descriptors were considered as negligible.

Clotrimazole multiple W/O/W emulsion as anticandidal agent: Characterization and evaluation on skin and mucosae.

Clotrimazole (CLT) was formulated in a multiple W/O/W emulsion (ME) with the aim of evaluating its potential as topical anticandidal agent and comparing with marketed products. A previously evaluated CLT-ME was selected and physicochemically characterized. The in vitro release behavior and the ex vivo permeation profiles were assessed using Franz diffusion cells using three different types of biological membranes: human skin and porcine buccal, sublingual and vaginal mucosae. The antifungal activity against Candida strains was also tested. Results showed CLT-MEs sizes of 29.206 and 47.678 µm with skin compatible pH values of 6.47 and 6.42 exhibiting high zeta potential values of -55.13 and -55.59 mV with dependence on the pH variation. The physicochemical stability was kept for a period of 180 days of storage at room temperature. CLT-MEs exhibited pseudoplastic behavior with hysteresis areas and viscosities of 286 and 331 mPa⋅s showing higher spreadability properties than commercial counterparts. An improved CLT release pattern was supplied by the ME system following a hyperbolic model. Likewise, ME system gave higher skin permeation flux of CLT than commercial reference. CLT amounts retained in the skin and mucosae were also higher than commercial references, which coupled with the higher antimycotic efficacy make CLT-MEs a great tool for clinical investigation of topical candidiasis treatments.

Skin permeation of econazole nitrate formulated in an enhanced hydrophilic multiple emulsion.

Local delivery of imidazolic antifungals is limited by its extreme lipophilicity. Multiple emulsions (ME) are a potential vehicle to enhance the delivery of econazole nitrate (ECN), an antifungal targeted to deep-seated epidermal yeast infections. An 1% ECN hydrophilic ME was compared with a commercial formulation in terms of rheology, droplet size and in vitro antifungal activity against Candida species. Comparative in vitro drug release, human skin permeation and drug retention were investigated using vertical diffusion cells. Rheology demonstrated a pseudoplastic shear thinning with thixotropy facilitating skin residence. No significant aggregation or droplet size variations were observed during a 6-month stability storage. Both formulations exhibited similar release levels achieving asymptotic values in 5 h. ECN skin permeation levels from the multiple emulsion resulted to be significantly higher than those of the commercial formulation, attributable to differences in formulation polarity and excipients composition. Conversely, similar drug accumulation levels in skin were obtained (40-130 ppm). These concentrations resulted to be comparable with obtained MIC values (2-78 ppm), confirming the in vitro antimicrobial efficacy of both formulations. A similar skin retention and a higher permeation rate over the existing formulations is considered an improved approach to target the drug to deep epidermis.

About the equivalence between different batches of a glycopeptide drug.

CONTEXT: Teicoplanin is a glycopeptide antibiotic consisting of a combination of different active components. Clinical equivalence between different batches of this drug is not guaranteed by the present pharmacopeial specification of chemical composition based on an HPLC chromatogram. OBJECTIVE: To test a modification of this specification and to evaluate independent compositions recently published in the literature. MATERIALS AND METHODS: The expectable area under the plasma curve of each batch has been estimated based on its chemical composition as described in a former paper. Batch-comparisons are based on ratios between the area of the test batch and the area of a reference. RESULTS AND DISCUSSION: The modification of this specification recently proposed by the European Medicines Agency (EMA) has been tested confirming its goodness. A new acceptance range of AUC variation, rounding -10% to +15%, has been obtained. It is narrower than the current interval of the pharmacopeial specification. Concerning the generic batches that have been studied, the majority of differences with the reference is lower than ±10%. Variations in the compositions of the reference product have been observed to influence the results and a control criteria are proposed. CONCLUSION: The variability of the pharmacokinetic performance of teicoplanin can be better controlled with this new proposal of composition specification given by EMA.

Composition specification of teicoplanin based on its estimated relative bioavailability.

CONTEXT: Teicoplanin is a fermentative antibiotic consisting of several active components that contribute similarly to the antibacterial activity, but exhibit different pharmacokinetic properties. Differences in systemic exposure between batches of teicoplanin are possible within pharmacopeial specifications as the proportion of subcomponents may vary from batch to batch. OBJECTIVE: The aim of this paper is to study the possible modification of the present pharmacopeial specification for teicoplanin composition to ensure an a priori pharmacokinetic equivalence between all pharmacopoeial-compliant batches. METHODS: The expectable whole Area Under the Curve (AUC) of plasma levels of teicoplanin was predicted for different experimental batches and also for the theoretical extreme batches within pharmacopeial specifications. Calculations were done based on the AUC of each teicoplanin active subcomponent. Subsequently, the equivalence between a generic teicoplanin and a reference drug product was investigated by means of the ratio of AUCs. RESULTS: Batches under study, complying with current pharmacopoeial specifications, showed a maximum predicted difference in AUC slightly larger than 40%. The observed variability in teicoplanin compositions surpasses the conventional ±5% specification used for drugs obtained by chemical synthesis, but no 5% differences have been observed for any of the AUC means of the reference product when compared with the whole pooled data. DISCUSSION AND CONCLUSION: Alternative specifications of actives composition can be defined to ensure that all batches complying with the pharmacopoeia are inside ±10% interval between them.

Relevance of equivalence assessment of topical products based on the dermatopharmacokinetics approach.

Common procedures to test bioequivalence of oral products, measuring the rate and extent of the obtained plasma levels, do not apply to drug products for topical use, which provide limited systemic absorption. Nowadays, clinical trials are still the goldenrule for the development of a generic topical product but, unfortunately, not many techniques are helpful for the specific investigation of in vivo topical absorption. Additionally, during early stages of pharmaceutical development, experimental procedures for demonstrating the quality by design of topical formulations are lacking. In some cases, the dermatopharmacokinetic characterization in healthy volunteers of the topical drug penetration by skin stripping has resulted to be a promising option. Recently, some authors have focused special efforts to enlighten all the capabilities of this approach. This short review tries to describe and discuss some aspects under optimization of dermatopharmacokinetics as is the influence of the formulation on drug performance, the parameter calculation and the experimental procedure for minimizing variability. All those aspects are nowadays in continuous improvement trying to define the place of dermatopharmacokinetics as a putative technique for avoiding clinical trials in topical generics development.