Susan A. Barker

An investigation into the mechanisms of self-emulsification using particle size analysis and low frequency dielectric spectroscopy

Abstract A series of mixtures comprising Imwitor 742 and Tween 80 have been prepared and their self-emulsifying properties studied using a method of visual examination. The particle size distributions of emulsions prepared from these mixtures at 25°C, 37°C in water and 37°C in 0.1 M HCl have been measured. A marked decrease in mean particle size was observed for 30 and 40% Imwitor 742/Tween 80 mixtures at 25°C with a decrease in particle size also being noted for the majority of Imwitor 742/Tween 80 compositions at higher temperatures. Low frequency dielectric spectroscopy was performed on the pure components and on binary systems to which water had been added to make 50% v/v mixtures. Evidence was shown for the formation of liquid crystalline phases at concentrations corresponding to those shown to be efficient self-emulsifying systems. The study therefore suggests that self-emulsification may be associated with liquid crystal formation and that low frequency dielectric spectroscopy may be of considerable use in understanding the factors leading to self-emulsification.

Plasticization of zein: a thermomechanical, FTIR, and dielectric study.

Zein, the main seed storage protein of maize, has been widely studied as a possible source of material for the production of biodegradable plastic films. Plasticization of zein is critical to make functional films. While there have been a number of publications which report the behavior of systems with a wide variety of plasticizers, there have been few which attempt to examine the interactions of protein and plasticizer at the molecular level. In this paper, we report on the plasticizing effects of water, glycerol, and 2-mercaptoethanol, which were examined by a combination of spectroscopy (FTIR and dielectric) and thermomechanical methods. The results suggest that both water and glycerol are adsorbed onto the protein and form hydrogen bonds with the amide groups. The plasticizer then builds up in patches on the protein surface. 2-Mercaptoethanol only exhibited a weak plasticizing effect due probably to disulfide bond breaking.

The effect of composition and gastric conditions on the self-emulsification process of ibuprofen-loaded self-emulsifying drug delivery systems: A microscopic and dynamic gastric model study

ABSTRACTPurposeTo investigate the physical processes involved in the emulsification of self-emulsifying drug delivery systems (SEDDSs) and the use of the Dynamic Gastric Model (DGM) as a characterisation tool.MethodsSEDDSs based on soybean oil, Tween 80, Span 80 and ibuprofen were prepared and their equilibrium phase diagrams established. The emulsification behaviour in a range of media was studied using polarised light microscopy and particle sizing. The behaviour of the SEDDSs in the DGM and conventional testing equipment was assessed.ResultsA range of liquid crystalline mesophases was observed, enhanced in the presence of the drug. Polarised light microscopy showed different emulsification processes in the presence and absence of the drug, which was also manifest in different droplet sizes. The droplet size distribution varied between the DGM and the USP II dissolution apparatus.ConclusionsThe model SEDDS displays complex liquid crystalline behaviour which may be intimately involved in the emulsification process, which in turn may alter particle size on emulsification, although there remains a question as to the in vivo significance of this effect. Furthermore, we demonstrate that the DGM represents a very promising new method of assessing the biological fate of SEDDSs.

Enhanced Oral Bioavailability and Intestinal Lymphatic Transport of a Hydrophilic Drug Using Liposomes

ABSTRACT A liposome system was evaluated for oral delivery of a poorly bioavailable hydrophilic drug. The system was prepared from proliposome, which consisted of negatively charged phosphatidylcholine, whereas cefotaxime was chosen as the model drug. An in vivo study was carried out on nine rats according to a three-way crossover design to compare the oral bioavailability of cefotaxime from the liposomal formulation with that of an aqueous drug solution and a physical mixture of cefotaxime with blank liposomes. The results indicated that the extent of bioavailability of cefotaxime was increased approximately 2.7 and 2.3 times compared with that of the aqueous solution and the physical mixture, respectively. In a separate study, simultaneous determination of cefotaxime in intestinal lymph (collected from the mesenteric lymph duct) and in plasma (collected from the tail vein) revealed that its concentration was consistently higher in the lymph than in the plasma when administered via the liposomal formulation, whereas the reverse was observed with the aqueous solution. Thus, the results indicated that the liposomes system has the potential of increasing the oral bioavailability of poorly bioavailable hydrophilic drugs and also promote their lymphatic transport in the intestinal lymph.

A study on maize proteins as a potential new tablet excipient

This investigation has examined the use of zein proteins from maize as the major component in oral controlled-release tablets, such formulations often being required to improve patient compliance. Tablets containing ground zein proteins, calcium hydrogen orthophosphate, polyvinyl pyrrolidone, theophylline and magnesium stearate were produced by wet granulation and compression on a single station tablet press and were compared to directly compressed tablets based on zein proteins, calcium hydrogen orthophosphate and theophylline. Non invasive techniques such as Fourier Transform infrared spectroscopy and Fourier Transform Raman spectroscopy were employed to investigate any changes in the secondary structure of zein proteins during tablet production. Random coils, alpha helices and beta sheets predominated and their relative content remained unaffected during grinding, wet granulation and compression, indicating that formulations based on zeins will be robust, i.e. insensitive to minor changes in the production conditions. Drug release from the tablets was studied using a standard pharmacopoeial dissolution test. Dissolution profiles in water, 0.1M HCl (pH=1) and phosphate buffer (pH=6.8) show that only a limited amount of theophylline was released after 4.5h, suggesting that zein proteins could act as a potential vehicle for oral controlled drug release. Analysis of the theophylline release profiles using the Peppas and Sahlin model reveals that diffusion and polymer relaxation occurred in acidic (pH=1) and buffered (pH=6.8) conditions for wet granulated tablets, whereas diffusion was predominant in directly compressed tablets. In conclusion, the present study has shown that zeins can be successfully used as a pharmaceutical excipient, and in particular as a matrix in monolithic controlled release tablets.

An investigation into the use of stepwise isothermal high sensitivity DSC as a means of detecting drug-excipient incompatibility

The use of stepwise isothermal high sensitivity differential scanning calorimetry (HSDSC) as a novel means of detecting excipient incompatibility is described using aspirin mixes with magnesium stearate and stearic acid as model systems. Aspirin, magnesium stearate and stearic acid alone and as mixes were studied in scanning mode using conventional DSC and were then subjected to a stepwise heating programme using HSDSC, whereby the samples were heated to temperatures between 45 and 70 degrees C and held for 1 h, during which the heat flow to or from the sample was measured. The data indicated that while no thermal events were detected for the individual components or mixes with stearic acid other than melting of stearic acid, 50% w/w mixes of magnesium stearate showed a marked endothermic response at temperatures above 55 degrees C. The data were fitted to an adaptation of an existing kinetic model for the degradation process and a reasonable correlation found. Mixes of the drug with the two excipients were then studied at 60 degrees C over 6 h at concentrations between 1 and 50% w/w. Incompatibilities with magnesium stearate concentrations as low as 1% w/w could be detected using this approach. Compacts of magnesium stearate and aspirin were also studied, with considerably more pronounced thermal events taking place compared to the powder mixes. It is concluded from these studies that while the study has highlighted certain limitations of the approach, stepwise isothermal DSC represents a potentially highly useful means of detecting excipient incompatibilities.

Characterization and quantification of amorphous material in milled and spray-dried salbutamol sulfate: a comparison of thermal, spectroscopic, and water vapor sorption approaches.

A study has been undertaken using a range of established and novel approaches to examine the effects of milling on the structure and crystallization behavior of salbutamol sulfate. A combination of modulated temperature differential scanning calorimetry, attenuated total reflectance Fourier-transform infrared spectroscopy, powder X-ray diffraction, and gravimetric vapor sorption analysis have been employed, with a particular view to examining the validity of using spray-dried material as a comparator. Although the expected increase in amorphization with milling time was observed, several unexpected observations were made including an apparently anomalous relationship between glass transition temperature and water content; this was used as the basis for the development of a novel method of quantifying amorphous content. Reasonable agreement was found between the data obtained from the spectroscopic and thermal methods, particularly those latter approaches that do not rely on recrystallization for quantification. The activation energy for the onset process was determined and found to be similar for all materials studied. The study has indicated that when using spray-dried material as a standard, the associated limitations must be appreciated, particularly in terms of the assumption of comparability of the recrystallization process between materials that is embedded in many quantification techniques.

Simple liquid chromatographic method for the determination of cefotaxime in human and rat plasma.

A high-performance liquid chromatographic method with ultraviolet (UV) detection was developed for measuring cefotaxime in rat and human plasma. The method used direct injection of the plasma supernatant after deproteinization with 70% perchloric acid. Degradation of cefotaxime in acidic medium was retarded by adding phosphate buffer before centrifuging the sample. The mobile phase was 0.05 M aqueous ammonium acetate-acetonitrile-tetrahydrofuran (87:11:2, v/v) adjusted to pH 5.5. Analysis was run at a flow-rate of 1.0 ml/min, and a detection wavelength of 254 nm was used. The method has a quantification limit of 0.20 microgram/ml. The within- and between-day coefficients of variation and accuracy values were less than 8% and +/-3%, respectively, while the recovery values were greater than 87% over the concentration range tested (0.20-50 microgram/ml). The speed, sensitivity, specificity and reproducibility of this method make it particularly suitable for the routine determination of cefotaxime in human plasma. Moreover, only a relatively small sample plasma volume (100 microliter) is required, allowing this method to be applied to samples taken from neonates.

Further investigations into the use of high sensitivity differential scanning calorimetry as a means of predicting drug-excipient interactions

The early prediction of drug-excipient incompatibility is vital in the pharmaceutical industry to avoid costly material wastage and time delays. We report here on the use of high sensitivity differential scanning calorimetry (HSDSC) to examine the compatibility between an experimental drug (Drug A) and common pharmaceutical excipients. Short-term HSDSC experiments (up to 25h) indicated that Drug A was stable in the presence of moisture and was compatible with both lactose monohydrate and magnesium stearate in the dry state, but showed degradation in the presence of magnesium stearate and water in combination. These results agreed with conventional stability studies, in which extensive degradation was observed in the Drug A-magnesium stearate system after storage at 40 degrees C/75% RH for 4 weeks but not under other conditions. These results indicate that HSDSC may be used to examine the compatibility of experimental drugs with conventional excipients and, in particular, illustrate the importance of incorporating humidity as an experimental variable in order to fully establish the stability profile of the material under test.

Development of fully amorphous dispersions of a low Tg drug via co-spray drying with hydrophilic polymers

The aim of the study was to prepare molecular dispersions of a physically highly unstable amorphous drug, paracetamol (acetaminophen with a T(g) of ca. 25°C) via co-spray drying with a variety of polymers. Solid dispersions at a range of drug loadings (10-90%w/w) using hydroxypropyl methylcellulose/acetate succinate (HPMC/HPMC AS), polyvinylpyrrolidone (PVP) and copovidone were produced and characterised by modulated temperature differential scanning calorimetry (MTDSC), thermogravimetric analysis (TGA), X-ray powder diffraction (XRPD), Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM). PVP-based polymers showed a greater tendency than the HPMC-based group to generate temperature-stable dispersions. In particular, copovidone (Plasdone® S-630) was found to be the most effective of the polymers studied and could formulate molecular dispersions at drug loadings up to and including 40%w/w. However, no evidence for direct drug-polymer interactions was found for such systems as a possible stabilising mechanism. The expected relationship of a higher T(g) of the polymer leading to greater stabilisation was not observed, while there was an inverse relationship between viscosity grade and amorphous phase generation. The study has therefore shown that temperature-stable amorphous dispersions of a low T(g) drug may be prepared by co-spray drying, particularly using PVP-based polymers.