Prediction of the redox behavior of electroactive molecules
enables
screening of a variety of compounds and can serve as a guideline in
the search for organic molecules for use as cathode materials in,
for example, Li ion batteries. In this study, we present a computational
strategy, based on density functional theory, to calculate redox potentials
and acid dissociation constants for a series of 16 isoindole-4,7-dione
(IID) derivatives. The calculations take all possible electron and
proton transfers into account, and the results were found to correlate
very well with electrochemical and spectroscopic measurements. The
possibility of polymerizing the IID derivatives was also assessed
computationally, as polymerization serves as a straightforward route
to immobilize the active material. Three of the considered IIDs (5,6-dicyano-2-methyl-isoindole-4,7-dione,
5,6-dihydroxy-2-methyl-isoindole-4,7-dione, and 2-methyl-5-(trifluoromethyl)-isoindole-4,7-dione)
are predicted to be particularly interesting for making polymers for
organic cathodes because these are calculated to have high redox potentials
and high specific capacities and to be readily polymerizable. The
presented strategy is general and can be applied in the prediction
of the electrochemical behavior of quinones as well as other systems
involving proton and electron transfers.
PostprintThis is the accepted version of a paper published in Journal of Pharmaceutical Sciences. This paper has been peer-reviewed but does not include the final publisher proof-corrections or journal pagination.Citation for the original published paper (version of record):Jämstorp, E., Strømme, M., Frenning, G. (2011) Modeling structure-function relationships for diffusive drug transport in inert porous geopolymer matrices.
Journal of Pharmaceutical
AbstractA unique structure-function relationship investigation of mechanically strong geopolymer drug delivery vehicles for sustained release of potent substances is presented. The effect of in-synthesis water content on geopolymer pore structure and diffusive drug transport is investigated. Scanning electron microscopy, N 2 gas adsorption, Hg intrusion porosimetry, compression strength test, drug permeation and release experiments are performed. Effective diffusion coefficients are measured and compared to corresponding theoretical values as derived from pore size distribution and connectivity via pore network modelling. By solely varying the in-synthesis water content, mesoporous and mechanically strong geopolymers with porosities of 8-45% are obtained. Effective diffusion coefficients of the model drugs Saccharin and Zolpidem are observed to span two orders of magnitude (~1.6-120×10 -8 cm 2 /s), comparing very well to theoretical estimations. The ability to predict drug permeation in and release from geopolymers, and materials alike, allows future formulations to be tailored on a structural and chemical level for specific applications, such as controlled drug delivery of highly potent substances.
Improving acid resistance, while maintaining the excellent mechanical stability is crucial in the development of a sustained and safe oral geopolymer dosage form for highly potent opioids. In the present work, commercially available Methacrylic acid-ethyl acrylate copolymer, Polyethylene-glycol (PEG) and Alginate polymer excipients were included in dissolved or powder form in geopolymer pellets to improve the release properties of Zolpidem, herein acting as a model drug for the highly potent opioid Fentanyl. Scanning electron microscopy, compression strength tests and drug release experiments, in gastric pH 1 and intestinal pH 6.8 conditions, were performed. The polymer excipients, with an exception for PEG, reduced the drug release rate in pH 1 due to their ability to keep the pellets in shape, in combination with the introduction of an insoluble excipient, and thereby maintain a barrier towards drug diffusion and release. Neither geopolymer compression strength nor the release in pH 6.8 was considerably impaired by the incorporation of the polymer excipients. The geopolymer/polymer composites combine high mechanical strength and good release properties under both gastric and intestinal pH conditions, and are therefore promising oral dosage forms for sustained release of highly potent opioids.
The aim of the present work was to evaluate alginate hydrogels in the form of spherical beads as carrier for antithrombotic drugs for future use in artificial grafts. The ionotropic gelation technique was employed to prepare beads from the L. hyperborea stipe of alginate with two different alginate concentrations and two different guluronic to manuronic acid ratios. The beads were loaded, via soaking, with three different types of low molecular weight model molecules representing drugs with antithrombotic action and their release characteristics were subsequently evaluated. The entire release process of the negatively charged model drugs under study (Salicylic acid and Hirudin), was found to be governed by diffusion, while additional electrostatic interactions between drug molecule and alginate matrix was indicated to influence the release rate of the analyzed positively charged drug molecule (Dipyridamole). It was found that the alginate hydrogel matrix imposed a decrease of the drug diffusion rate on the molecules under study as compared to the corresponding diffusion rates in water. All diffusion coefficients decreased slightly with increasing concentration of alginate and with increasing guluronic to manuronic acid ratio. The results show on the potential use of alginate gel beads when developing vehicles for release of low molecular weight antithrombotic drugs.
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