RESUMEN
Powder flow is a critical attribute of pharmaceutical blends to ensure tablet weight uniformity and production of tablets with consistent and reproducible properties. This study aims at characterizing different powder blends with a number of different rheologic techniques, in order to understand how particles' attributes and interaction between components within the formulation generate different responses when analysed by different rheological tests. Furthermore, this study intends on reducing the number of tests in early development phases, by selecting the ones that provide the best information about the flowability attributes of the pharmaceutical blends. This work considered two cohesive powders - spray-dried hydroxypropyl cellulose (SD HPMC) and micronized indomethacin (IND) - formulated with other four commonly used excipients [(lactose monohydrated (LAC), microcrystalline cellulose (MCC), magnesium stearate (MgSt) and colloidal silica (CS)]. The experimental results showed that powder flowability may be affected by materials particles' size, bulk density, morphology, and interactions with lubricant. In detail, parameters, such as angle of repose (AoR), compressibility percentage (CPS), and flow function coefficient (ffc) have shown to be highly affected by the particle size of the materials present in the blends. On the other hand, the Specific Energy (SE) and the effective angle of internal friction (φe) showed to be more related with particle morphology and materials interaction with the lubricant. Since both ffc and φe parameters are generated from the yield locus test, data suggest that a number of different powder flow features may be understood only by applying this test, avoiding redundant powder flow characterization, as well as extensive time and material spent in early development formulation stages.
Asunto(s)
Excipientes , Lubricantes , Polvos/química , Excipientes/química , Reología/métodos , Comprimidos/química , Tamaño de la PartículaRESUMEN
Biopharmaceutics Classification System (BCS) class II and IV drugs may be formulated as supersaturating drug delivery systems (e.g., amorphous solid dispersions [ASDs]) that can generate a supersaturated drug solution during gastrointestinal (GI) transit. The mechanisms that contribute to increased bioavailability are generally attributed to the increased solubility of the amorphous form, but another mechanism with significant contributions to the improved bioavailability have been recently identified. This mechanism consists on the formation of colloidal species and may further improve the bioavailability several fold beyond that of the amorphous drug alone. These colloidal species occur when the concentration of drug generated in solution exceeds the amorphous solubility during dissolution, resulting in a liquid-liquid phase separation (LLPS). For the appearance of LLPS, the crystallization kinetics needs to be slow relatively to the dissolution process. This work intended to implement an analytical methodology to understand the ability of a drug to form colloidal species in a biorelevant dissolution media. This screening tool was therefore focused on following the colloidal formation and crystallization kinetics of itraconazole (ITZ; model drug from BSC class II) in the presence of hydroxypropyl methylcellulose (HPMC-AS L and HPMC-AS M, which are HPMC-AS with varying ratios of succinoyl:acetyl groups), using a laser diffraction-based methodology. The ability of ITZ to form colloids by a solvent-shift approach was compared with the actual colloidal formation of ITZ amorphous solid dispersions produced by spray-drying. Results indicate that regardless of the used methodology, colloids of ITZ can be detected and monitored. The extension of colloid generation showed to be correlated with the ASD disintegration/dissolution rate, i.e, polymers with faster wettability kinetics led to faster ASD disintegration and colloidal formation. As conclusion, this study showed that laser diffraction could give complementary information about colloidal formation and ASD dissolution profile, showing to be an excellent screening strategy to be applied in the early stage development of amorphous solid dispersions.
Asunto(s)
Rayos Láser , Polímeros , Cristalización , Derivados de la Hipromelosa , SolubilidadRESUMEN
The potential of polyethyleneglycol (PEG), polyvinylpyrrolidone (PVP), and hydroxypropylcellulose (HPC) to inhibit the hydration of olanzapine (OLZ) in aqueous environments was assessed. OLZ Form I (OLZ) suspended in water (A) or in aqueous polymer solutions (2%, 0.2%, 0.02%, and 0.002%) (PEG 6000 [B], PEG 40,000 [C], HPC LF [D], or PVP K30 [E]). Filtered samples were analyzed by different techniques (X-ray powder diffraction, Fourier transform infrared spectroscopy, differential scanning calorimetry, 1H-nuclear magnetic resonance spectroscopy). OLZ hydration showed to be faster in water than in PEG solutions, regardless of the polymer molecular weight. OLZ in D and E suspensions remained anhydrous at concentrations of 2%-0.02%. The NMR measurements revealed that all of these polymers were able to establish hydrogen bonds with the OLZ molecule and increased its saturation solubility, but only D and E showed to increase the wettability of the OLZ particles due to binding of these polymers to the surface of hydrate nuclei/first crystals OLZ crystals. This study provided an insight into the mechanisms of OLZ hydrate protection by polymers. It confirmed the advantage of using PVP K30 or HPC LF in wet granulation in concentrations as low as 0.02% to prevent formation of OLZ hydrates, due to the combined effect of H-bond ability and the strong bonding of these polymers to the surface of the crystals.
Asunto(s)
Antieméticos/química , Benzodiazepinas/química , Celulosa/análogos & derivados , Excipientes/química , Polietilenglicoles/química , Povidona/química , Agua/química , Rastreo Diferencial de Calorimetría , Celulosa/química , Cristalización , Estabilidad de Medicamentos , Espectroscopía de Resonancia Magnética , Olanzapina , Solubilidad , Espectroscopía Infrarroja por Transformada de FourierRESUMEN
The study aims to elucidate the transformations of anhydrous olanzapine Form I (OLZ FI) into the hydrate forms, when stored at a high relative humidity or suspended in an aqueous media, in the presence of polymers. OLZ FI and physical mixtures (3:1 and 1:1, as powders or compacts) of olanzapine with polyethylene glycol (PEG-6000), polyvinylpyrrolidone (PVP K25) and hydroxypropylcellulose (HPC-LF) were stored (75%RH/25°C, 75%RH/40°C and 93%RH/25°C) for 28days. OLZ FI and the physical mixtures were also suspended in water under stirring (200rpm/60min). Samples were collected at different time points and vacuum filtered. OLZ FI showed to hydrate at 75%RH/25°C when stored in the presence of HPC and PEG. At 93%RH all polymers affected the kinetics of hydration of OLZ FI with PVP as the only polymer with the ability to minimize the formation of the hydrate. When olanzapine was suspended in water with HPC and PVP the formation of the hydrate was inhibited. Compaction of the powders before storage led to an increase of the hydrate conversion rate of olanzapine on the first week of storage, due to a partial amorphisation of olanzapine present at the tablet surface. When stored at high humidity environments OLZ FI converted into dihydrate D and, when exposed to aqueous environments in the presence of different polymers converted into dihydrates B and E. From an industrial point of view, this study highlighted the importance of the excipient's choice for OLZ formulations, so that a final OLZ medicine can have a consistent quality and performance throughout the entire medicine's shelf life.
Asunto(s)
Antipsicóticos/química , Benzodiazepinas/química , Polímeros/química , Estabilidad de Medicamentos , Humedad/efectos adversos , Olanzapina , Difracción de Rayos XRESUMEN
The focus of this study was the understanding of the hydrate transformations of anhydrous olanzapine Forms I and II (the most common polymorphs) upon exposure to different moisture conditions (11, 53, 75, 93% RH) and direct contact with water (e.g. aqueous slurry) and the impact of hydration on the aqueous dissolution rates of the polymorphs. The kinetics of reversible transformations (anhydrate-hydrate phases) and the identification of polymorphs were evaluated by differential scanning calorimetry, thermogravimetry, infrared (DRIFT) and X-ray powder diffraction. The results showed that anhydrous Forms I and II have undergone water vapor phase induced transformations at 93% and 75% RH, respectively. At 93% RH Forms I and II showed to hydrate into dihydrates D and B, respectively, the latter with a higher hydration rate. The conversion of Form I into the dihydrate D showed to affect the dissolution rate of olanzapine (f2<50). As slurries both forms showed to hydrate into a mixture of two different Forms - dihydrate B and higher hydrate. The study provided an understanding of the conversion pathways of the different forms when they were exposed to humid air or aqueous environments, resembling the transformations that might occur during processing, storage or during the persecution of dissolution tests to assess the quality of dosage forms delivering olanzapine.