Determination of physical emulsion stabilization mechanisms of wood hemicelluloses via rheological and interfacial characterization.

Materials manufacturing industries seek efficient, economic, and sustainable compounds for stabilizing dispersed systems such as emulsions. In this study, novel, abundant biobased hydrocolloids spruce galactoglucomannans (GGM) and birch glucuronoxylans (GX) were obtained from a forestry biorefining process and characterized as versatile stabilizers of rapeseed oil-in-water emulsions. For the first time, GGM and GX isolated by pressurized hot water extraction (PHWE) of spruce and birch saw meal, respectively, were studied in emulsions. The PHWE wood hemicelluloses-polysaccharides with relatively low molar mass-facilitated the formation of emulsions with small average droplet size and efficiently prevented droplet coalescence. GGM and GX lowered the surface tension of emulsions' oil-water interface and increased the viscosity of the continuous phase. However, viscosity of the wood hemicellulose-based systems was low compared to that of commercial polymeric stabilizers. GGM-stabilized emulsions with varying oil volume fractions were characterized in terms of their rheological properties, including large amplitude oscillation shear (LAOS) measurements, and compared to emulsions prepared with a classical small-molecular surfactant, Tween20. The physical emulsion stabilization mechanisms of GGM and GX are suggested as steric repulsion assisted by Pickering-type stabilization. Wood hemicelluloses have potential as highly promising future bioproducts for versatile industrial applications involving colloidal systems and soft materials.

In vitro trans-scleral iontophoresis of methylprednisolone hemisuccinate with short application time and high drug concentration.

Trans-scleral iontophoresis, i.e. the application of small electric current to enhance drug transport across sclera is an option for non-invasive delivery of corticosteroids to the posterior segment of the eye. In this paper, in vitro trans-scleral iontophoresis of methylprednisolone hemisuccinate was investigated using concentrated drug solutions and short application times to mimic the iontophoretic conditions of in vivo studies. The drug at the donor concentration of 45 mg/ml was delivered through isolated porcine sclera under passive and iontophoretic conditions (cathodal, 2.4 mA) for 2-15 min. In a second set of experiments, the drug was delivered for 5 min at current intensities of 0.9-7.2 mA. After donor removal, drug release was followed up to 24 h. The exposure of concentrated solutions to sclera for 2-15 min under passive conditions caused a notable accumulation of drug up to 0.8 mg/cm², the release of which was successively followed for 24 h. In cathodal iontophoresis, the amount of accumulated drug increased proportionally to the charge between 0.3 and 1.44 Coulomb. When the charge was increased to 2.16 Coulomb by increasing the application time or current intensity, no further enhancement was recorded. This behaviour can be ascribed to substantial drug adsorption on the scleral tissue, as demonstrated through streaming potential studies, with the consequent increase of the electroosmotic flow that opposes drug transport. The set up suggested here could help in defining the optimal conditions for in vivo studies with animal models and reducing the number of in vivo experiments.

The effect of thermostabilising mutations on the pressure stability of Trichoderma reesei GH11 xylanase.

We studied the pressure stability of disulphide bridge mutants of Trichoderma reesei XYNII at 500-5000 bar. The inactivation of XYNII and its mutants was strongest above 4000 bar. The pressure stability correlated with the thermostability order of the XYNII mutants, indicating that the stabilising mutations in protein regions important for thermostability also protect the enzyme at high pressure. In combination with high pressure, a mild heating had already inactivated the wild-type enzyme; the thermostabilising mutations largely counteracted this effect. At a low temperature, the mutations did not have any remarkable pressure stabilisation effect. Thus, thermal inactivation appeared to dominate over pressure inactivation at higher temperatures. Kinetic calculations indicated that pressure compressibility correlated with the thermostability of xylanase mutants.

Ion-exchange fibers and drugs: a novel device for the screening of iontophoretic systems.

The objective of this study was to theoretically model and experimentally measure the extent of drug release from ion-exchange fibers. The release was measured as a function of current density and NaCl concentration using a novel iontophoretic cell. The fibers tested contained weak carboxylate (-COOH) ion-exchange groups. The cationic model drugs tacrine and metoprolol were chosen on the basis of previous research, where tacrine had the lowest release rate and metoprolol the highest release rate. An in-house designed three compartment test cell was developed to test the suitability of drugs for iontophoretic drug delivery. In this cell, the anode and the drug containing ion-exchange fiber compartments were separated with a Nafion ion-selective membrane, while the fiber and the return electrode compartments were separated with a porous membrane. Tacrine proved to be a good drug candidate for this system as the release of the tacrine from the device was controllable with salt concentration and current density. Metoprolol release from the device was, however, not controllable.

Ion-exchange fibers and drugs: a transient study.

The objective of this study was to theoretically model and experimentally measure the kinetics and extent of drug release from different ion-exchange materials using an in-house-designed flow-cell. Ion-exchange fibers (staple fibers and fiber cloth) were compared with commercially available ion-exchange materials (resins and gels). The functional ion-exchange groups in all the materials were weak -COOH or strong -SO3H groups. The rate and extent of drug release from the fibers (staple fiber>fiber cloth) was much higher than that from the resin or the gel. An increase in the hydrophilicity of the model drugs resulted in markedly higher rates of drug release from the fibers (nadolol>metoprolol>propranolol>tacrine). Theoretical modelling of the kinetics of ion exchange provided satisfactory explanations for the experimental observations: firstly, a change in the equilibrium constant of the ion-exchange reaction depending on the drug and the ion-exchange material and, secondly, a decrease in the Peclet number (Pe) with decreasing flow-rate of the drug-releasing salt solution.

Effect of diffusion potential, osmosis and ion-exchange on transdermal drug delivery: theory and experiments.

Equations expressing the effect of the diffusion potential on the trace ion transfer across a porous charged membrane have been derived. These equations have been tested with experiments with human cadaver skin. The transfer of sotalol and salicylate was measured varying the salt (NaCl) concentration in the donor and receiver compartments. It appears that osmotic pressure and ion-exchange make a significant contribution to the flux enhancement by the diffusion potential.

Experimental verification of the mechanistic model for transdermal transport including iontophoresis.

An experimental verification of the previously introduced model for transdermal transport (Kontturi and Murtomäki, J. Control. Release, 41 (1996) 177) is presented. The model comprises two penetration routes: an aqueous and a lipoidal pathway. Lipophilicity of the drug determines which route the drug uses. Constant potential iontophoresis can be used to evaluate the relative proportions of the two competing pathways. beta-blockers sotalol, timolol and propranolol, whose water-octanol partition coefficients span three orders of magnitude, are used as model compounds. Experiments reinforce the predictions of the model in that iontophoresis enhances the flux of the most hydrophilic drug, sotalol, the most whereas the flux of the least hydrophilic drug, propranolol, is enhanced the least. The effect of electroosmosis has now been included in the model.

Electrochemical characterization of human skin by impedance spectroscopy: the effect of penetration enhancers.

The electrochemical properties of human cadaver skin were studied in a diffusion cell with impedance spectroscopy as a function of time in the absence and presence of penetration enhancers dodecyl N,N-dimethylamino acetate and Azone. An improved electrochemical model of skin is presented, and combining the novel model with modern fractal mathematics, the effect of enhancers on the surface of skin is demonstrated. The enhancers appeared to open new penetration routes and increase the ohmic resistance, capacitive properties, and fractal dimension of skin, which means a rougher or more heterogeneous surface.

Electrochemical determination of partition coefficients of drugs.

An electrochemical method for the determination of partition coefficients of drugs that can exist as ions in aqueous solutions is presented. The method involves cyclic voltammetry at the polarizable interface between two immiscible electrolyte solutions. Because n-octanol is an unsuitable solvent for electrochemical purposes, 1,2-dichloroethane, which has electronic properties similar to those of n-octanol, was used in the measurements. The values obtained could be correlated with the values for n-octanol-water partition taken from the literature by an approach based on the linear solvation relationship: log P1 = a log P2 + b; in this relationship, a and b are constants and P1 and P2 correspond to the two different organic and aqueous phase partition equilibria. Furthermore, aqueous diffusion coefficients of drugs were determined from voltammograms.