439 research outputs found
Colloidal microgels - untapped potential?
Colloidal microgels are discrete cross-linked polymeric nanoparticles that may be prepared from a range of different monomer types. These monomers may confer dispersion sensitivity to a wide range of stimuli including temperature, pH, salinity and the addition of co-solvents. Microgels are spherical and are typically in the size range from 50 nm up to 1000 nm. They are prepared by a polymerization of a monomer or monomers in the presence of a crossliner
A review of hot-melt extrusion: process technology to pharmaceutical products [Review article]
Over the last three decades industrial adaptability has allowed hot-melt extrusion (HME) to gain wide acceptance and has already established its place in the broad spectrum of manufacturing operations and pharmaceutical research developments. HME has already been demonstrated as a robust, novel technique to make solid dispersions in order to provide time controlled, modified, extended, and targeted drug delivery resulting in improved bioavailability as well as taste masking of bitter active pharmaceutical ingredients (APIs). This paper reviews the innumerable benefits of HME, based on a holistic perspective of the equipment, processing technologies to the materials, novel formulation design and developments, and its varied applications in oral drug delivery systems
A quality by design (QbD) twin—screw extrusion wet granulation approach for processing water insoluble drugs
In this study, a Quality by Design (QbD) approach was used to identify the effect of formulation parameters in a twin screw wet extrusion granulation process for the manufacturing of ibuprofen (IBU) granules with increased dissolution rates. A fractional factorial Design of Experiment (DoE) was used to investigate the effect of the excipient composition, binder amount and liquid to solid (L/S) ratio (independent variables) on drug dissolution rates, median particle size diameter and specific surface area (dependent variables). The intra-granular addition of the binder in inorganic/polymer blends processed with ethanol as granulating liquids facilitated the formation of granules at various particle sizes. DoE regression analysis showed that all formulation parameters affect the dependent variables significantly. The enhanced dissolution rates were attributed not only to the IBU particle size reduction and adsorption in the porous inorganic network but also to the high specific surface area of the produced granules. Dynamic vapour sorption showed increased water absorption for granules with small particle size distribution and high specific surface area
Concurrent analysis: validation of the domains within the birth satisfaction scale
Background and aim: measuring women’s satisfaction with their birth experience has been problematic. Recently, an attempt has been made to capture birth satisfaction’s generalised meaning and incorporate it into an evidenced-based tool. Standard procedures for validation have limitations. Qualitative techniques such as domain analysis offer an alternative and assist in better understanding the importance of each item. This article examines the parsimony of the Birth Satisfaction Scale (BSS), which is a 30-item questionnaire designed to measure satisfaction with childbirth, with women’s actual experience of childbirth. Methods: primary free text data collected from 207 women who originally tested the BSS was concurrently analysed with first-hand accounts of birth satisfaction collected from 19 qualitative papers. Results: the domain analysis confirmed three explanatory items within the BSS: ‘being in control’, ‘things going as planned’, and ‘being supported’. Conclusions: the BSS accounts for all the analysed data, suggesting it is a robust measure of satisfaction in childbirth. Strengths and limitations of the method are discussed, as are implications for practice. With further development, the instrument could be used to establish correlates with other psychometric measures, i.e. self-efficacy, anxiety, depression, locus of control and bonding; and evaluate models or care systems as a standalone instrument, or as a screening test prior to detailed qualitative work
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Controlled release of microencapsulated docosahexaenoic acid (DHA) by spray–drying processing
The omega-3-fatty acid, docosahexaenoic acid (DHA) 22:6 n-3, is an important food component for the visual and brain development of infants. In this study two approaches have been explored for the encapsulation of DHA in the pH dependant polymer hydroxyl-propyl-methyl-cellulose-acetate-succinate (HPMCAS). In the first approach Direct Spray Drying (DSD) was implemented for the microencapsulation of DHA/HPMCAS organic solutions, whilst in the second approach solid lipid nanoparticle (SLN) dispersions of DHA, were first produced by high-pressure homogenization, prior to being spray dried in HPMCAS aqueous solutions. The DSD approach resulted in significantly higher quantities of DHA being encapsulated, at 2.09 g/100 g compared to 0.60 g/100 g in the spray-dried SLNs. The DHA stability increased with the direct spray-drying approach. Release studies of DHA in the direct sprayed dried samples revealed a lag time for 2 h in acidic media followed by rapid release in phosphate buffer (pH 6.8)
The Hot Galactic Corona and the Soft X-ray Background
I characterize the global distribution of the 3/4 keV band background with a
simple model of the hot Galactic corona, plus an isotropic extragalactic
background. The corona is assumed to be approximately polytropic (index = 5/3)
and hydrostatic in the gravitational potential of the Galaxy. The model
accounts for X-ray absorption, and is constrained iteratively with the ROSAT
all-sky X-ray survey data. Regions where the data deviate significantly from
the model represent predominantly the Galactic disk and individual nearby hot
superbubbles. The global distribution of the background, outside these regions,
is well characterized by the model; the 1 sigma relative dispersion of the data
from the model is about 15%. The electron density and temperature of the corona
near the Sun are about 1.1 x 10^{-3} cm^{-3} and about 1.7 x 10^6 K. The same
model also explains well the 1.5 keV band background. The model prediction in
the 1/4 keV band, though largely uncertain, qualitatively shows large intensity
and spectral variations of the corona contribution across the sky.Comment: An invited talk at IAU Colloquium No. 166: The Local Bubble and
Beyond. 10 pages (including b/w figures). Color versions of Figs. 1 and 4 are
provided separately and may also be found at
www.astro.nwu.edu/astro/wqd/paper/hal
The development of a novel smart material based on colloidal microgels and cotton
Colloidal microgels are often described as “smart” due to their ability to undergo quite dramatic conformational changes in response to a change in their environmental conditions (e.g. temperature, pH). A range of novel smart materials were developed by the incorporation of colloidal microgels into cotton fabric. A series of microgels have been prepared by a surfactant free emulsion polymerization based on N-isopropylacrylamide (NIPAM) monomer. Poly(NIPAM) is a thermosensitive polymer which undergoes a conformational transition close to the human skin temperature. Poly(NIPAM) was co-polymerized acrylic acid (AA), to prepare pH/temperature-sensitive microgels. Microgel particles were characterized by scanning electron microscopy (SEM), attenuated total reflectance fourier transform infrared (ATR-FTIR) spectroscopy, and dynamic light scattering (DLS).
This research aims at coupling microgel particles onto cotton fibers and comparing between different attachment techniques. The coupling reactions between microgels and cotton cellulose are only feasible if they both have appropriate functionalities. For microgels, this was achieved by using different initiators which introduce different functional groups on the particle surface and different surface charges. Cotton samples were successfully modified by carboxymethylation, periodate oxidation, grafting of 1,2,3,4-butanetetracarboxylic acid, and chloroacetylation in order to target possible reactions with the terminal functional groups of the microgel particles. Microgels were attached to the cotton fabrics using different methods and the bonds formed were determined by ATR-FTIR spectroscopy and SEM. The reaction yields were quantified gravimetrically and the maximum weight increase of cotton samples due to the attached microgels was around 24% (w/w)
Implications of the SPEAR FUV Maps on Our Understanding of the ISM
The distribution of a low-density transition temperature (10^4.5 - 10^5.5 K)
gas in the interstellar medium conveys the character and evolution of diffuse
matter in the Galaxy. This difficult to observe component of the ISM emits
mainly in the far-ultraviolet (FUV) (912-1800 {\AA}) band. We describe spectral
maps of FUV emission lines from the highly ionized species CIV and OVI likely
to be the dominant cooling mechanisms of transition temperature gas in the ISM.
The maps were obtained using an orbital spectrometer, SPEAR, that was launched
in 2003 and has observed the FUV sky with a spectral resolution of \sim 550 and
an angular resolution of 10'. We compare distribution of flux in these maps
with three basic models of the distribution of transition temperature gas. We
find that the median distribution of CIV and OVI emission is consistent with
the spatial distribution and line ratios expected from a McKee-Ostriker (MO)
type model of evaporative interfaces. However, the intensities are a factor of
three higher than would be expected at the MO preferred parameters. Some high
intensity regions are clearly associated with supernova remnants and
superbubble structures. Others may indicate regions where gas is cooling
through the transition temperature.Comment: 6 pages, 2 figures, presented at "The Local Bubble and Beyond II,"
April 200
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Formation of a bile salt-drug hydrogel to predict human intestinal absorption
The unique character of bile salts to self-assemble into hydrogels in the presence of halide salts was exploited in this work to facilitate the prediction of human intestinal absorption (%HIA) for a set of 25 compounds. This was achieved by firstly incorporating each compound separately within the process of gel formation to create a series of gel-drug membranes. Scanning Electron Microscopy (SEM) analysis of the freeze-dried samples of the blank bile salt hydrogels and drug loaded bile salt hydrogels indicated a unique microstructure made of a network of intertwined fibrils. Drug-loaded sodium deoxycholate (NaDC) hydrogels were then utilised as the donor phase to study permeability using flow-through and static diffusion cells. The resulting values of the release-permeability coefficient (Kp) were then analysed, along with other molecular descriptors, for the prediction of human intestinal absorption (%HIA) using multiple linear regression (MLR). Overall, when comparing predicted values (using the systems presented in this study) with known literature values, it can be seen that both methods (i.e. using static and flow through cells) had good predictability with R2PRED. values of 79.8 % and 79.7 % respectively. This study therefore proposes a novel, accurate and precise way to predict human intestinal absorption for compounds of pharmaceutical interest using a simple in vitro permeation system. It is important to develop alternatives to the current methods used in prediction of HIA which are expensive and time consuming or include the use of animals. Therefore, the proposed method in this study being economic and time saving provides superiority over these current methods and suggests the possibility of its use as an alternate to such methods for prediction of HIA
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