An Analytical Target Profile for the Development of an In Vitro Release Test Method and Apparatus Selection in the Case of Semisolid Topical Formulations.

This study focuses on how to define an Analytical Target Profile (ATP) which is intended for use in practice and on facilitating the selection of in vitro release test (IVRT) technology for diclofenac sodium topical hydrogel and cream. The implementation involves incorporating the new draft guidelines of the International Council for Harmonisation (ICH Q14) and USP (United States Pharmacopeia) Chapter 1220. Four IVRT apparatuses were compared (USP Apparatus II with immersion cell, USP Apparatus IV with semisolid adapter, static vertical diffusion cell, and a new, in-house-developed flow-through diffusion cell) with the help of the ATP. Performance characteristics such as accuracy, precision, cumulative amount released at the end of the IVRT experiment, and robustness were investigated. We found that the best apparatus for developing IVRT quality control (QC) tests in both cases was USP II with an immersion cell. All four different IVRT apparatuses were compared with each other and with the data found in the literature.

Foams Set a New Pace for the Release of Diclofenac Sodium.

Medicated foams have emerged as promising alternatives to traditional carrier systems in pharmaceutical research. Their rapid and convenient application allows for effective treatment of extensive or hirsute areas, as well as sensitive or inflamed skin surfaces. Foams possess excellent spreading capabilities on the skin, ensuring immediate drug absorption without the need for intense rubbing. Our research focuses on the comparison of physicochemical and biopharmaceutical properties of three drug delivery systems: foam, the foam bulk liquid, and a conventional hydrogel. During the development of the composition, widely used diclofenac sodium was employed. The safety of the formulae was confirmed through an in vitro cytotoxicity assay. Subsequently, the closed Franz diffusion cell was used to determine drug release and permeation in vitro. Ex vivo Raman spectroscopy was employed to investigate the presence of diclofenac sodium in various skin layers. The obtained results of the foam were compared to the bulk liquid and to a conventional hydrogel. In terms of drug release, the foam showed a rapid release, with 80% of diclofenac released within 30 min. In summary, the investigated foam holds promising potential as an alternative to traditional dermal carrier systems, offering faster drug release and permeation.

Guar gum as a microbially degradable component for an oral colon delivery system based on a combination strategy: formulation and in vitro evaluation.

Oral colon delivery has widely been pursued exploiting naturally occurring polysaccharides degraded by the resident microbiota. However, their hydrophilicity may hinder the targeting performance. The aim of the present study was to manufacture and evaluate a double-coated delivery system leveraging intestinal microbiota, pH, and transit time for reliable colonic release. This system comprised a tablet core, a hydroxypropyl methylcellulose (HPMC) inner layer and an outer coating based on Eudragit® S and guar gum. The tablets were loaded with paracetamol, selected as a tracer drug because of the well-known analytical profile and lack of major effects on bacterial viability. The HPMC and Eudragit® S layers were applied by film-coating. Tested for in vitro release, the double-coated systems showed gastroresistance in 0.1 N HCl followed by lag phases of consistent duration in phosphate buffer pH 7.4, imparted by the HPMC layer and synergistically extended by the Eudragit® S/guar gum one. In simulated colonic fluid with fecal bacteria from an inflammatory bowel disease patient, release was faster than in the presence of ß-mannanase and in control culture medium. The bacteria-containing fluid was obtained by an experimental procedure making multiple tests possible from a single sampling and processing run. Thus, the study conducted proved the feasibility of the delivery system and ability of guar gum to trigger release in the presence of colon bacteria without impairing the barrier properties of the coating. Finally, it allowed an advantageous simulated colonic fluid preparation procedure to be set up, reducing the time, costs, and complexity of testing and enhancing replicability.

Impact of Apparatus and Adapter on In vitro Drug Release of Ophthalmic Semisolid Drug Products.

PURPOSE: In vitro release testing (IVRT) is a widely used tool for evaluating the quality and performance of drug products. However, standardized sample adaptors or drug release apparatus setups for IVRT studies are still lacking for ophthalmic ointments. The aim of this study was to provide a better understanding of the impact of apparatus and sample adaptor setups on IVRT of ophthalmic ointments. METHODS: Dexamethasone (DEX), a steroidal ingredient commonly used in ophthalmic drug products, was selected as a model drug. Ointments were prepared by mixing DEX in white petrolatum using a high shear mixer. A novel two-sided adapter was developed to increase the drug release surface area. DEX ointment was placed in one-sided or two-sided release adaptors coupled with 1.2 µm polyethersulfone membrane, and the drug release was studied in different USP apparatuses (I, II, and IV). RESULTS: The sample adaptor setups had a minimal impact on cumulative drug release amount per area or release rate while USP IV apparatus with agitated flow enhanced drug release rates. The USP apparatus I with a two-sided semisolid adapter, which uses membranes on both sides, showed dramatically higher cumulative drug release and discriminative release profiles when evaluating ophthalmic formulations. CONCLUSIONS: USP apparatuses and sample adaptors are critical considerations for IVRT. Two-sided semisolid adapter provides higher cumulative release, facilitating the discrimination between low drug content ophthalmic ointment formulations with good sensitivity and repeatability without affecting the drug release rate.

Solid-in-oil nanodispersion as a novel topical transdermal delivery to enhance stability and skin permeation and retention of hydrophilic drugs l-ascorbic acid.

l-ascorbic acid （Vitamin C, VC） is the most abundant antioxidant in human skin. But its poor penetration into the skin and unstability limit the application. The aim of the study was to promote the topical skin permeation and retention of VC, increase the stability as well as effectiveness by a novel solid in oil nanodispersion. In the nanodispersions system, nano-sized particles of hydrophilic molecules are dispersed in an oil vehicle with the assistance of hydrophobic surfactants. The optimized formula composed of O170 and S1570 (12.5:1, w/w) showed high EE% of 98% and good stability. FTIR analysis confirmed that there may be hydrogen bond between VC and surfactants. The results of DSC, and XRD revealed that the drug was successfully encapsulated in the surfactants, which maintained the stability of drug. By analyzing and fitting the release data in vitro, the drug release mechanism of SONDs was predicted as a multi-dynamic model. Skin permeation of VC was improved 3.43-fold for SONDs compared with VC aqueous solution, highlighting that the lipophilicity and nano size of the carrier more easily penetrated into the skin. Finally, the photoaging study revealed that topical application of VC-SONDs provided the highest skin protection compared UV and VC aqueous solution treated group which was evident by the normal thick epidermal morphology, no obvious melanocytes and the densely arranged dermal elastic fibers. These results demonstrated that the solid-in-oil nanodispersions may be a potential transdermal delivery system for hydrophilic bioactive ingredients.

Novel modified vertical diffusion cell for testing of in vitro drug release (IVRT) of topical patches.

The vertical diffusion cell is an in vitro laboratory device for the study of drug release and permeation of semi-solid topical formulations and topical patches. Both static and dynamic versions of the diffusion cell are used in practice, the operation of which can be automated. The device is available at a reasonable cost for smaller, mainly transdermal patches, the amount of sampling fluid is replenished at the same time as the sample, in the same amount as the amount sampled without automation of the system, and simultaneous replenishment of acceptor fluid by hydrostatic pressure helps keeping the acceptor chamber bubble-free.

Ethosomes and Transethosomes as Cutaneous Delivery Systems for Quercetin: A Preliminary Study on Melanoma Cells.

The present study is aimed to design ethosomes and transethosomes for topical administration of quercetin. To overcome quercetin low bioavailability, scarce solubility and poor permeability that hamper its pharmaceutical use, the drug was loaded in ethosomes and transethosomes based on different concentrations of phosphatidylcholine. Vesicle morphology was studied by cryogenic transmission electron microscopy, while size distribution and quercetin entrapment capacity were evaluated up to 3 months, respectively, by photon correlation spectroscopy and high-performance liquid chromatography. The antioxidant property was studied by photochemiluminescence test. Quercetin release and permeation was investigated in vitro, using Franz cells associated to different membranes. In vitro assays were conducted on human keratinocytes and melanoma cells to study the behavior of quercetin-loaded nano-vesicular forms with respect to cell migration and proliferation. The results evidenced that both phosphatidylcholine concentration and quercetin affected the vesicle size. Quercetin entrapment capacity, antioxidant activity and size stability were controlled using transethosomes produced by the highest amount of phosphatidylcholine. In vitro permeation studies revealed an enhancement of quercetin permeation in the case of transethosomes with respect to ethosomes. Notably, scratch wound and migration assays suggested the potential of quercetin loaded-transethosomes as adjuvant strategy for skin conditions.

Analytical Quality by Design (AQbD) Approach to the Development of In Vitro Release Test for Topical Hydrogel.

The aim of our study was to adapt the analytical quality by design (AQbD) approach to design an effective in vitro release test method using USP apparatus IV with a semi-solid adapter (SSA) for diclofenac sodium hydrogel. The analytical target profile (ATP) of the in vitro release test and ultra-high-performance liquid chromatography were defined; the critical method attributes (CMAs) (min. 70% of the drug should be released during the test, six time points should be obtained in the linear portion of the drug release profile, and the relative standard deviation of the released drug should not be over 10%) were selected. An initial risk assessment was carried out, in which the CMAs (ionic strength, the pH of the media, membrane type, the rate of flow, the volume of the SSA (sample amount), the individual flow rate of cells, drug concentration %, and the composition of the product) were identified. With the results, it was possible to determine the high-risk parameters of the in vitro drug release studies performed with the USP apparatus IV with SSA, which were the pH of the medium and the sample weight of the product. Focusing on these parameters, we developed a test protocol for our hydrogel system.

Skin Pharmacokinetics of Transdermal Scopolamine: Measurements and Modeling.

Prediction of skin absorption and local bioavailability from topical formulations remains a difficult task. An important challenge in forecasting topical bioavailability is the limited information available about local and systemic drug concentrations post application of topical drug products. Commercially available transdermal patches, such as Scopoderm (Novartis Consumer Health UK), offer an opportunity to test these experimental approaches as systemic pharmacokinetic data are available with which to validate a predictive model. The long-term research aim, therefore, is to develop a physiologically based pharmacokinetic model (PBPK) to predict the dermal absorption and disposition of actives included in complex dermatological products. This work explored whether in vitro release and skin permeation tests (IVRT and IVPT, respectively), and in vitro and in vivo stratum corneum (SC) and viable tissue (VT) sampling data, can provide a satisfactory description of drug "input rate" into the skin and subsequently into the systemic circulation. In vitro release and skin permeation results for scopolamine were consistent with the previously reported performance of the commercial patch investigated. New skin sampling data on the dermatopharmacokinetics (DPK) of scopolamine also accurately reflected the rapid delivery of a "priming" dose from the patch adhesive, superimposed on a slower, rate-controlled input from the drug reservoir. The scopolamine concentration versus time profiles in SC and VT skin compartments, in vitro and in vivo, taken together with IVRT release and IVPT penetration kinetics, reflect the input rate and drug delivery specifications of the Scopoderm transdermal patch and reveal the importance of skin binding with respect to local drug disposition. Further data analysis and skin PK modeling are indicated to further refine and develop the approach outlined.

Identification of critical formulation parameters affecting the in vitro release, permeation, and rheological properties of the acyclovir topical cream.

To understand effects of formulation variables on the critical quality attributes (CQA) of acyclovir topical cream, this study investigated effects of propylene glycol (PG), poloxamer, and sodium lauryl sulfate (SLS) concentrations, acyclovir particle size, and formulation pH of the acyclovir cream. Fifteen formulations were prepared and characterized for rheological properties, particle size distribution, drug release and in vitro skin permeation. Drug distribution between various phases of the cream was determined. The concentration of soluble acyclovir in the aqueous phase was determined as a surrogate of the equilibrium with other acyclovir species in the cream. The interaction among effects of the formulation variables on the amount of acyclovir retained by skin was also evaluated. The results showed that PG significantly (p < 0.05) increased the yield stress, viscosity, drug concentration in the aqueous phase, and drug release. The PG and SLS significantly (p < 0.05) increased acyclovir retention by skin samples. Particle size of acyclovir inversely affected the drug release. This study revealed that the employed concentrations of PG and SLS and particle size of the dispersed acyclovir are critical formulation variables that should be carefully controlled when developing acyclovir topical creams with desired performance characteristics.

Novel In Vitro Investigational Methods for Modeling Skin Permeation: Skin PAMPA, Raman Mapping.

The human skin is marked as a standard by the regulatory agencies in the permeation study of dermal formulations. Artificial membranes can substitute human skin to some extent. Academicians and pharmaceutical corporations are focusing their efforts on developing standardized protocols and safe, reliable options to substitute human skin for carrying out permeability studies. Our research aim was to study the applicability of new techniques in the case of different types of dermal formulations. The skin parallel artificial membrane permeability assay (PAMPA) method and Raman mapping were compared to the gold-standard Franz cell method. A hydrogel and two types of creams were investigated as the most generally used dermal preparations. The values of the diffused drug were closer to each other in PAMPA and Franz cell measurement. The diffused amount of drug showed the same order for the different formulations. These results correlate well with the results of Raman mapping. Our conclusions suggest that all early screening examinations can be performed with model tools such as skin PAMPA supplemented with methods like Raman mapping as a semi-quantitative method.

Revisiting in vitro release test for topical gel formulations: The effect of osmotic pressure explored for better bio-relevance.

Release test methods for topical dosage forms including pharmacopeial tests require a large volume of release media, with limited application for high throughput screening. In the present study, we evaluated Transwell assay to miniaturize the release test method for optimization of thermoreversible topical gel formulations. We also explored the osmotic effect on the in vitro release rates from gel formulations to understand the bio-relevance of release media. An extreme vertices type of mixture design in Minitab®16 generated eleven formulations composed of poloxamer 407, poloxamer 188, and phosphate buffered saline (PBS). A quadratic equation adequately described the composition dependence of gelation temperature. Epidermal growth factor (EGF) and trypan blue were used as model drugs for proteins and small molecules, respectively. Cumulative release in PBS containing 30% sucrose exhibited linear correlation with respect to the gel compositions, while PBS without sucrose did not differentiate various compositions. Higher release rates in PBS than in sucrose media are attributable to the osmotic water flow from PBS into the donor phase, and subsequent increase in diffusivity. The time course of in vivo near-infrared fluorescence imaging of topical EGF gels on the wound sites were consistent with the in vitro release profiles measured with PBS as the release media. To the best of our knowledge, this is the first study to propose a release test method suitable for high throughput screening of topical formulations with emphasis on the osmotic pressure effect. Bio-relevant release media composition for a topical formulation would vary depending on its clinical application because the osmotic water flow through the normal skin would be negligible compared to compromised skin.

Bioequivalence Methodologies for Topical Drug Products: In Vitro and Ex Vivo Studies with a Corticosteroid and an Anti-Fungal Drug.

OBJECTIVE: To examine whether in vitro and ex vivo measurements of topical drug product performance correlate with in vivo outcomes, such that more efficient experimental approaches can be reliably and reproducibly used to establish (in)equivalence between formulations for skin application. MATERIALS AND METHODS: In vitro drug release through artificial membranes, and drug penetration into porcine skin ex vivo, were compared with published human in vivo studies. Two betamethasone valerate (BMV) formulations, and three marketed econazole nitrate (EN) creams were assessed. RESULTS: For BMV, the stratum corneum (SC) uptake of drug in 6 h closely matched data observed in vivo in humans, and distinguished between inequivalent formulations. SC uptake of EN from the 3 creams mirrored the in vivo equivalence in man (both clinically and via similar tape-stripping experiments). However, EN clearance from SC ex vivo did not parallel that in vivo, presumably due to the absence of a functioning microcirculation. In vitro release of BMV from the different formulations did not overlap with either ex vivo or in vivo tape-stripping data whereas, for EN, a good correlation was observed. No measurable permeation of either BMV or EN was detected in a 6-h in vitro skin penetration experiment. CONCLUSIONS: In vitro and ex vivo methods for topical bioequivalence determination can show correlation with in vivo outcomes. However, these surrogates have understandable limitations. A "one-size-fits-all" approach for topical bioequivalence evaluation may not always be successful, therefore, and the judicious use of complementary methods may prove a more effective and reliable strategy.

In vitro release of diclofenac diethylamine from gels: evaluation of generic semisolid drug products in Brazil

In order for the pharmacological action of a topical dermal drug product to occur, the drug must first be released from the vehicle to be available to penetrate the skin layers and reach the site of action. Drug release is mainly dependent on the characteristics of the formulation. Currently, to register a generic or a similar drug product in Brazil performance testing of topical drug products for local action is not required. In this context, this aim of this study was to evaluate the in vitro release of commercial diclofenac diethylamine gel products available on the Brazilian pharmaceutical market, using the vertical diffusion cell method. Factors which may influence the test, such as the type of membrane used, and the effect of the formulation characteristics on the diffusion rate were evaluated. Brazilian legislation currently allows generic drug products to contain excipients other than the reference drug, which may affect the drug release from the vehicle. Only one of the four generic drug products tested could be considered equivalent to the reference Cataflam Emulgel®. The cellulose acetate and polyethersulfone membranes tested were found to be interchangeable in the in vitro release studies carried out on this product.

Para exercer ação farmacológica, medicamentos tópicos de aplicação cutânea precisam, primeiramente, liberar o fármaco do veículo, para que desta forma ele se torne disponível para penetração nas camadas da pele, até atingir seu local de ação. A liberação do fármaco do veículo depende principalmente das características da formulação. Até a presente data, para registrar um medicamento genérico ou similar no Brasil não se exigem testes de desempenho para produtos tópicos de ação local. O presente trabalho teve como objetivo avaliar a liberação in vitro de especialidades farmacêuticas de diclofenaco dietilamônio gel do mercado farmacêutico brasileiro, usando o sistema de célula de difusão vertical. Avaliaram-se fatores que influenciam o teste como o tipo de membrana usada nos ensaios de liberação e características da formulação que impactam a velocidade de difusão. A legislação vigente no País permite que medicamentos genéricos contenham excipientes diferentes do medicamento referência. Esta diferença afetou a liberação do fármaco do veículo. Dos quatro medicamentos genéricos testados apenas um seria considerado equivalente ao medicamento referência Cataflam Emulgel®. As membranas de acetato de celulose e polietersulfona testadas apresentaram-se intercambiáveis nos estudos de liberação desse produto.

Emulsões O/A contendo Cetoconazol 2,0%: avaliação da estabilidade acelerada e estudos de liberação in vitro / O/W Emulsion Containing 2.0% Ketoconazole: Accelerated Stability Test and in vitro Release

Os objetivos do estudo foram desenvolver e avaliar a estabilidade físico-química de emulsões O/A contendo cetoconazol a 2,0% e determinar seu perfil de liberação in vitro. As formulações foram preparadas com bases auto-emulsionáveis com diferentes características químicas. A estabilidade do sistema foi avaliada de acordo com o Guia para Realização de Testes de Estabilidade em Produtos Farmacêuticos, utilizando diferentes temperaturas (4ºC, 37ºC e 45ºC) por um período de tempo de três meses. Os parâmetros avaliados durante o ensaio foram: as características organolépticas,o pH, o comportamento reológico e a concentração do ativo. A emulsão considerada estável foi submetida ao ensaio de liberação in vitro utilizando célula de difusão de Franz. A quantificação do cetoconazol na formulação e na solução receptora foi realizada por método espectrofotométrico no ultravioleta a 244 nm. Dentre as formulações testadas, somente aquela preparada com álcool cetoestearílico e estearato de polietilenoglicol (PEG20) manteve suas características físico-químicas estáveis durante o teste. O estudo de liberação in vitro demonstrou que o fármaco foi liberado do sistema gradualmente no decorrer do tempo, apresentando uma cinética pseudo zero ordem.

The goal of this work was to develop and assess the physicochemical stability of O/W emulsions containing 2.0% ketoconazole and to determine their in vitro release profile. These formulations were prepared with self-emulsifying bases that differed in their chemical characteristics. The stability of the system was assessed, as recommended in the Guide to Drug Product Stability Tests, over 3 months at 3 different temperatures (4ºC, 37ºC and 45ºC). The characteristics assessed during the test were the organoleptic properties, pH, rheological behavior and drug concentration. The most stable emulsion was subjected to an in vitro release test in a Franz diffusion cell system. The ketoconazole in both the formulation and receptor phase was determined by UV spectrophotometry at 244 nm. The O/W emulsion prepared with cetearyl alcohol and polyethylene glycol (PEG20) stearate was the only one that maintained its physicochemical characteristics throughout the test. The in vitro release test demonstrated that the drug was released gradually, exhibiting pseudo zero-order kinetics.