X V I I I V Í S I N D A R Á Ð S T E F N A H Í F Y L G I R I T 9 1 LÆKNAblaðið/Fylgirit 91 2017/103 81 for layer-by-layer modification of PP and PLA nonwovens. The bacterici- dal effect of the three modified nonwovens towards S. aureus, expressed in terms of percentage reduction of the viable bacterial cells show that PP-1 showed a reduction of upto ~60% after 4.5 h in comparison to the growth control. On the other hand, PP-2 and PLA were capable of showing 100% reduction in the bacterial cells at time intervals of 2 h and 3 h respectively and this effect was maintained up to the end of 24 h. Conclusion: The deposition of TMC layer contributes antibacterial properties to modified polypropylene and polylactide materials which can be used for medical applications. V 64 Aggregation of native β-cyclodextrin (βCD) and HP-β- cyclodextrin (HPβCD): determination of critical aggregation concentration by permeation André Sá Couto, Ryzhakov Alexey, Þorsteinn Loftsson Faculty of Pharmacy University Iceland ars70@hi.is Introduction: Purpose of the present work was to investigate formation of aggregates in aqueous βCD and HPβCD solutions using CD permeation through semi-permeable cellophane membranes. Another goal was to calculate the lowest CD concentration that initiates the aggregation process (i.e. the critical aggregation concentration [cac]). Methods and data: Aqueous βCD and HPβCD solutions of vari- ous concentrations were prepared through sonication (60°C, 60 min). All concentrations were determined by UHPLC validated methods. Permeation studies were carried out in unjacketed Franz diffusion cells using semipermeable membranes with molecular-weight-cutoff (MWCO) of 3.5-5 and 8-10kDa. Results: Regarding to the βCD permeation studies a negative deviation from the theoretical flux curve was observed for the MWCO 3.5-5 kDa membrane but close to linear relationship was observed for the MWCO 8-10kDa membrane. Similar results were obtained for HPβCD where the MWCO 3.5-5 kDa membrane indicated HPβCD aggregation. From the intersection of the linear portions of the plots at concentrations above and below the inflections points it was possible to determine CAC for both CDs. The calculated CAC for βCD was approximately 1.1% and for HPβCD approximately 15%. Conclusions: The analysis of permeation results for both CD clearly indicates that the aggregates are 5-10kDa as they seem to permeate freely through the 8-10kDa pore size membrane (linear flux) but not through the 3.5-5kDa membrane. The aggregation and aggregate size appeared to increase with increasing CD concentration. One can conclude that HPβCD (CAC 15% w/v) has less tendency to form aggregates than the native βCD (CAC 1.1% w/v). V 65 Interaction of 2-hydroxypropyl-β-cyclodextrin (HPβCD) with parabens: influence in the aggregation process André Sá Couto, Ryzhakov Alexey, Þorsteinn Loftsson Faculty of Pharmacy University Iceland ars70@hi.is Purpose: Purpose of the present work was to investigate the influence of parabens on HPβCD aggregation by permeation and determine their effect on the critical aggregation concentration (cac) of HPβCD. Methods: Binary systems of HPβCD and parabens (i.e. methyl-, ethyl-, propyl- or butylparaben) of various concentrations were prepared in aqueous solutions. Permeation studies were carried out in unjacketed Franz diffusion cells using semipermeable membranes with molecular- -weight-cutoff (MWCO) of 3.5-5 kDa. Results: Analysis of pure aqueous HPβCD solutions showed negati- ve deviation from linearity at elevated HPβCD concentrations and cac of approximately 15% w/v. HPβCD solutions containing methyl- and ethylparaben gave similar HPβCD flux profiles (similar slopes) as pure HPβCD solution showing that these two parabens have negligible effect on the cac of HPβCD (cac 14-15%). In contrast, propyl- and butylparaben decreased the HPβCD flux indicating that these parabens have signi- ficant effect on HPβCD cac (≈12%). Regarding the cac of the parabens, methylparaben gives a linear flux-paraben concentration profile (cac cannot be observed in the study range) while the remaining parabens display a negative deviation from linearity (increased with the increasing length of the alkyl chain). Conclusion: As previously described parabens can self-aggregate and aggregation increased with increasing alkyl chain length (MP < EP < PP < BP). One can also conclude that methyl- and ethylparaben do not influence HPβCD flux profile (similar cac) while propyl- and butylparaben increa- sed HPβCD aggregation. HPβCD (cac ≈15% w/v) had higher tendency to form aggregates in presence of propyl- and butylparaben (cac ≈ 12% w/v). V 66 Transdermal numerical modelling from silicone matrix systems Bergþóra S. Snorradóttir1, Fjóla Jónsdóttir2, Sven Th. Sigurðsson2, Már Másson1 1Faculty of Pharmaceutical Science, University of Iceland, 2Faculty of Industrial Engineering, Mecha, University of Iceland bss@hi.is Introduction: Matrix type formulations are common types of delivery systems used for transdermal delivery. Modelling was used to find para- meter values for the matrix systems, based on release studies, and for the membranes by an investigation of trans-membrane delivery from donor solutions. Methods and data: Transdermal drug release, in vitro studies from donor solutions and silicone matrix systems were conducted with vertical Franz diffusion cells. A numerical model was constructed. The model was transi- ent and did not require pseudo-steady state approximation. It was vali- dated against experimental data for drug release from silicone matrices. Results: The model was transient and could therefore be used to pred- ict lag-times in addition to the drug flux for trans-dermal delivery. The donor solution drug release considered conditions where there were no diffusion limitations, contrary to the cases of drug incorporated silicone matrix systems. Good fit to experimental data was obtained. Conclusions: The modelling approach was illustrated by allowing the possibility of a donor solution. The results indicated that while the dissolution in the case of ibuprofen is close to being instantaneous, this is not so in the case of diclofenac. The experiments and the numerical model outlined in this study could also be adjusted to more general formulations. V 67 Inclusion complex formation of p-hydroxybenzoic acid esters and ϒ-Cyclodextrin Phennapha Saokham1, Þorsteinn Loftsson2 1Faculty of Pharmaceutical Sciences, University of Iceland, 2University of Iceland phs3@hi.is Introduction: The usage of parabens in aqueous media has been hamper-

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