The Properties of HPMC:PEO Extended Release Hydrophilic Matrices and their Response to Ionic Environments.

Purpose: Investigate the extended release behaviour of compacts containing mixtures of hydrophilic HPMC and PEO in hydrating media of differing ionic strengths.

Methods: The extended release behaviour of various HPMC:PEO compacts was investigated using dissolution testing, confocal microscopy and magnetic resonance imaging, with respect to polymer ratio and ionic strength of the hydrating media.

Results: Increasing HPMC content gave longer extended release times, but a greater sensitivity to high ionic dissolution environments.

Use of the Dynamic Gastric Model as a tool for investigating fed and fasted sensitivities of low polymer content hydrophilic matrix formulations.

The Dynamic Gastric Model (DGM) is an in-vitro system which aims to closely replicate the complex mixing, dynamic biochemical release and emptying patterns of the human stomach. In this study, the DGM was used to understand how the polymer content of hydrophilic matrices influences drug release in fasted and fed dissolution environments. Matrices containing a soluble model drug (caffeine) and between 10 and 30% HPMC 2208 (METHOCEL(®) K4M CR) were studied in the DGM under simulated fasted and fed conditions.

The influence of polymer content on early gel-layer formation in HPMC matrices: The use of CLSM visualisation to identify the percolation threshold.

Percolation theory has been used for several years in the design of HPMC hydrophilic matrices. This theory predicts that a minimum threshold content of polymer is required to provide extended release of drug, and that matrices with a lower polymer content will exhibit more rapid drug release as a result of percolation pathways facilitating the faster penetration of the aqueous medium. At present, percolation thresholds in HPMC matrices have been estimated solely through the mathematical modelling of dissolution data.

The influence of substituted phenols on the sol:gel transition of hydroxypropyl methylcellulose (HPMC) aqueous solutions.

The influence of the physicochemical parameters of substituted aromatic molecules on the phase transition from sol to gel of hydroxypropyl methylcellulose (HPMC) has been investigated using a homologous series of substituted phenols. Using a turbimetric methodology, concentration dependent suppression of phase transition temperature of HPMC was observed for phenol and its derivatives, including methyl-, nitro- and chloro-substituted molecules. Although no strong direct relationship between single molecular physicochemical properties of the phenolic compounds (such as pKa, LogP and other molecular descriptors) and ΔCPT was found for the compounds tested, a successful prediction of behaviour could be obtained by using a combination of parameters.

Drug release from HPMC matrices in milk and fat-rich emulsions.

"Biorelevant" media for the fed stomach, including fat emulsions, are routinely used during in vitro testing of solid dosage forms. However, their complexity undoubtedly creates difficulties in identifying factors which affect drug release. Here, we show fats can directly influence drug release from hydroxypropyl methylcellulose (HPMC; Methocel K4M) matrices which are often subjected to biorelevant testing.

Solution interactions of diclofenac sodium and meclofenamic acid sodium with hydroxypropyl methylcellulose (HPMC).

Many pharmaceutical agents require formulation in order to facilitate their efficacious delivery. However, the interaction between the active species and the formulation additives has the potential to significantly influence the pharmocokinetics of the active. In this study, the solution interactions between hydroxypropyl methylcellulose (HPMC) with two non-steroidal anti-inflammatories - the sodium salts of diclofenac and meclofenamate - were investigated using tensiometric, rheological, NMR, neutron scattering and turbidimetric techniques.

Designing HPMC matrices with improved resistance to dissolved sugar.

High concentrations of dissolved sugars can accelerate in vitro drug release in certain hydroxypropyl methylcellulose (HPMC) matrices (Williams et al., 2009). This study investigated the potential for common formulation variables to modulate sucrose sensitivity, and explored if more resistant formulations could be designed.

The effect of sucrose and salts in combination on the drug release behaviour of an HPMC matrix.

Previous work has shown how high concentrations of sugars can accelerate drug release from hydroxypropyl methylcellulose (HPMC) matrices by suppressing polymer hydration. This study investigates the effects of combining sugar and salts, using sucrose, sodium chloride and trisodium citrate, soluble ingredients commonly found in foods. A factorial study showed that each solute suppressed HPMC solution sol-gel transition temperature (a sensitive measure of molecular hydration) independently, and their effects reflected their rank order in the Hofmeister series.

Elucidation of the internal physical and chemical microstructure of pharmaceutical granules using X-ray micro-computed tomography, Raman microscopy and infrared spectroscopy.

X-ray micro-computed tomography (XMCT) was used in conjunction with confocal Raman mapping to measure the intra-granular pore size, binder volumes and to provide spatial and chemical maps of internal granular components in α-lactose monohydrate granules formulated with different molecular weights of polyvinyl pyrrolidone (PVP). Infrared spectroscopy was used to understand the molecular association of binder domains. Granules were prepared by high-shear aqueous granulation from α-lactose monohydrate and PVP K29/32 or K90.

A liquid chromatography method for quantifying caffeine dissolution from pharmaceutical formulations into colloidal, fat-rich media.

A simple and rapid high-performance liquid-chromatography method is presented that permits quantification of caffeine in colloidal fat emulsions proposed as new 'biorelevant' dissolution media (Intralipid and various milks). Using a mobile phase of 0.1 M sodium acetate (pH 4.

The suitability of tris(hydroxylmethyl) aminomethane (THAM) as a buffering system for hydroxypropyl methylcellulose (HPMC) hydrophilic matrices containing a weak acid drug.

There are few studies of alkalising pH-modifiers in HPMC hydrophilic matrices. These agents may be incorporated to provide microenvironmental buffering and facilitate pH-independent release of weak acid drugs. This study compared tris(hydroxylmethyl) aminomethane (THAM, TRIS, tromethamine, trometamol) with sodium citrate as internal buffering agents for HPMC (4000 cps) 2208 and 2910 matrices containing felbinac, a weak acid drug which exhibits pH-dependent solubility.

The extended release properties of HPMC matrices in the presence of dietary sugars.

The mechanisms and structure-activity by which dissolved dietary sugars influence drug release from hydroxypropyl methylcellulose (Methocel K4M) matrices were investigated. Drug release was retarded at lower sugar concentrations, but above a critical solute concentration (S(CRIT)), there was marked acceleration of release. Studies of early gel layer formation suggested this resulted from sugar-induced suppression of HPMC particle swelling and coalescence, leading to gel structures with poorer diffusion-barrier properties and reduced resistance to physical erosion.

An investigation into the rheology of pharmaceutical inter-granular material bridges at high shear rates.

Purpose: This study was undertaken to investigate the rheological properties of inter-granular material bridges on the nano-scale when strained at high shear rates.

Materials And Methods: Atomic force microscopy (AFM) was used as a rheometer to measure the viscoelasticity of inter-granular material bridges for lactose:PVP K29/32 and lactose:PVP K90 granules, produced by wet granulation.

Results: The loss tangent (tan delta) and both the storage (G') and loss shear moduli (G'') of inter-granular material bridges were measured as a function of the probe-sample separation distance, oscillation frequency and relative humidity (RH).

Mechanisms of drug release in citrate buffered HPMC matrices.

Few studies report the effects of alkalizing buffers in HPMC matrices. These agents are incorporated to provide micro-environmental buffering, protection of acid-labile ingredients, or pH-independent release of weak acid drugs. In this study, the influence of sodium citrate on the release kinetics, gel layer formation, internal gel pH and drug release mechanism was investigated in HPMC 2910 and 2208 (Methocel E4M and K4M) matrices containing 10% felbinac 39% HPMC, dextrose and sodium citrate.

Pharmaceutical applications of confocal laser scanning microscopy: the physical characterisation of pharmaceutical systems.

The application of confocal laser scanning microscopy (CLSM) to the physicochemical characterisation of pharmaceutical systems is not as widespread as its application within the field of cell biology. However, methods have been developed to exploit the imaging capabilities of CLSM to study a wide range of pharmaceutical systems, including phase-separated polymers, colloidal systems, microspheres, pellets, tablets, film coatings, hydrophilic matrices, and chromatographic stationary phases. Additionally, methods to measure diffusion in gels, bioadhesives, and for monitoring microenvironmental pH change within dosage forms have been utilised.

Microstructural imaging of early gel layer formation in HPMC matrices.

A real-time confocal fluorescence imaging method has been developed which allows the critical early stages of gel layer formation in hydroxypropylmethylcellulose (HPMC) matrices to be examined. Congo Red, a fluorophore whose fluorescence is selectively intensified when bound to beta-D-glucopyranosyl sequences, has allowed mapping of hydrated polymer regions within the emerging gel layer, and revealed for the first time, the microstructural sequence of polymer hydration during development of the early gel layer. Liquid penetration and swelling can be examined in unprecedented detail.

Pharmaceutical applications of magnetic resonance imaging (MRI).

Magnetic resonance imaging (MRI) is a powerful imaging modality that provides internal images of materials and living organisms on a microscopic and macroscopic scale. It is non-invasive and non-destructive, and one of very few techniques that can observe internal events inside undisturbed specimens in situ. It is versatile, as a wide range of NMR modalities can be accessed, and 2D and 3D imaging can be undertaken.

Monitoring the thermal gelation of cellulose ethers in situ using attenuated total reflectance fourier transform infrared spectroscopy.

In this work attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopy was used to probe the thermal gelation behavior of aqueous solutions of hydroxypropyl methylcellulose (HPMC), specifically thermal gelation and accompanying precipitation. Cloud point measurements are usually evaluated through turbidity in dilute solutions but the method cannot readily be applied to more concentrated or highly viscous solutions. From the ATR-FTIR data, intensity changes of the nu(CO) band marked the onset of gelation and information about the temperature of gelation and the effect of the gel structure on the water hydrogen bonding network was elucidated.

Oesophageal bioadhesion of sodium alginate suspensions 2. Suspension behaviour on oesophageal mucosa.

Sodium alginate suspensions in a range of water miscible vehicles were investigated as novel bioadhesive liquids for targeting the oesophageal mucosa. Such a dosage form might be utilised to coat the oesophageal surface and provide a protective barrier against gastric reflux, or to deliver therapeutic agents site-specifically. Alginate suspensions swelled and formed an adherent viscous layer on contact with the mucosa.

Design and evaluation of an emulsion vehicle for paclitaxel. I. Physicochemical properties and plasma stability.

Purpose: The current formulation of paclitaxel contains ethanol and Cremophor EL and has been reported to cause serious adverse reactions. The purpose of the present work was to develop an improved emulsion vehicle for paclitaxel and to study the physicochemical properties of such a system.

Methods: Emulsions were prepared by either microfluidization or sonication method and the droplet size characterized by dynamic light scattering and light microscopy.

A concentric cylinder shear device for the study of stability in intravenous emulsions.

This paper introduces the use of a concentric cylinder shear device for studying the stability of intravenous emulsions under shear, and examines the relationship between shearing conditions and the emulsion droplet size and distribution, as characterised by laser diffraction and optical counting. Theoretically, the device generated flow in the Taylor region, but a linear relationship between the natural log mean droplet diameter and time, which was observed at all shear rates, suggested that coalescence kinetics could be treated in a manner analogous to laminar flow. An order of magnitude increase in coalescence rate was achieved within the shear rate range examined (2802-6164 s(-1)), yet irrespective of shear rate, the particle size distribution evolved a similar multi-peak pattern with common secondary peaks at 1.

Oesophageal bioadhesion of sodium alginate suspensions: particle swelling and mucosal retention.

This paper describes a prospective bioadhesive liquid dosage form designed to specifically adhere to the oesophageal mucosa. It contains a swelling polymer, sodium alginate, suspended in a water-miscible vehicle and is activated by dilution with saliva to form an adherent layer of polymer on the mucosal surface. The swelling of alginate particles and the bioadhesion of 40% (w/w) sodium alginate suspensions were investigated in a range of vehicles: glycerol, propylene glycol, PEG 200 and PEG 400.

Localised mapping of water movement and hydration inside a developing bioadhesive bond.

Few studies have investigated the internal processes involved in bioadhesive bond formation, particularly where mucus and hydrated polymer contribute jointly to bond structure. This paper reports the first study to spatially map the internal environment within a developing bioadhesive bond, utilising nuclear magnetic resonance (NMR) microscopy to measure localised water self-diffusion coefficients (SDC) and confocal laser scanning microscopy (CLSM) to estimate mucin concentration. In a model bioadhesive bond formed between an alginate matrix and mucin gel, characteristic profiles were observed in which fluorescence measurements showed a region of increasing mucin concentration in the mucus layer region adjacent to the matrix, corresponding closely with a zone of restricted water SDC in the diffusion profiles.

Investigating the coating-dependent release mechanism of a pulsatile capsule using NMR microscopy.

Chronopharmaceutical capsules, ethylcellulose-coated to prevent water ingress, exhibited clearly different release characteristics when coated by organic or aqueous processes. Organic-coated capsules produced a delayed pulse release, whereas aqueous-coated capsules exhibited less delayed and more erratic release behaviour. Nuclear magnetic resonance microscopy was used to elucidate the internal mechanisms underlying this behaviour by studying the routes of internal water transport and the timescale and sequence of events leading to the pulse.

Measurement and mapping of pH in hydrating pharmaceutical pellets using confocal laser scanning microscopy.

Purpose: pH modifiers are often used to promote drug solubility/ stability in dosage forms, but predicting the extent and duration of internal pH modification is difficult. Here, a noninvasive technique is developed for the spatial and temporal mapping of pH in a hydrated pharmaceutical pellet, within a pH range appropriate for microenvironmental pH control by weak acids.

Methods: Confocal dual excitation imaging (Ex 488/Ex 568) of pellets containing a single, soluble, pH-sensitive fluorophore with cross-validation from a pH microelectrode.