Chip-based impedance measurement on single cells for monitoring sub-toxic effects on cell membranes.

There is a lack of methods suitable for generation of data about the dynamics of effects on cell membranes with a high sensitivity. Such methods are urgently needed to support the optimisation of interaction of substances, particles or materials with cell. The goal of this article is to use an improved microhole chip system to monitor the alterations of cells due to the interactions of polymer-DNA complexes. This should demonstrate exemplarily that subtoxic effect of biological relevant particles or substances at relevant concentrations can be monitored for several hours. By using a microhole cell chip and a microfluidic unit single cells can be electrically interfaced via microholes and the use of small electrodes with high impedances is not necessary. For separation and positioning of the cells onto the hole negative pressure is applied on the reverse side of the chip. Under cell culture conditions the cell starts to spread on the biocompatible insulating chip membrane resulting in a stable interface to an adherent growing cell. After the spreading process is finished, the polymer/polyplex solution is added and the impedance is measured with respect to time. To illustrate the cellular parameter which can affect the measured impedance a simple simulation based on the finite element method (FEM) is performed. It was shown for the first time that the impedance-based method predicated on the microhole chip can be used for biological relevant substances at relevant concentrations and that it is more sensitive than the well-established biological marker.

Photo-cross-linking between polymers derivatized with photoreactive ruthenium-1,4,5,8-tetraazaphenanthrene complexes and guanine-containing oligonucleotides.

We have shown previously that complexes containing 1,4,5,8-tetraazaphenanthrene (TAP) ligands are able to form photoadducts with the guanine bases of DNA and oligonucleotides. In this work, we have exploited this specific photoreaction for carrying out photo-cross-linkings between guanine-containing oligonucleotides (G-ODNs) and biodegradable polymers derivatized with the photoreactive Ru(II) compounds. The aim in the future is to use these polymer conjugates as vectorizing agents of the metallic compounds inside the cells. Thus, photooxidizing Ru(II) complexes such as [Ru(TAP)3]2+ and [Ru(TAP)2phen]2+ (phen = 1,10-phenanthroline) have been derivatized by an oxyamine function to attach them, via an oxime ether linkage, to a soluble 6 or 80 kDa poly-[N-(2-hydroxyethyl)-l-glutamine] polymer that contains pendent aldehyde groups. It is demonstrated that the resulting Ru-labeled polymers exhibit photophysical properties and a photochemistry that are comparable with those of the free, nonattached complexes. The photo-cross-linkings with the G-ODNs are clearly detected by gel electrophoresis with the 6 kDa Ru conjugates upon illumination.

Polyacetal and poly(ortho ester)-poly(ethylene glycol) graft copolymer thermogels: preparation, hydrolysis and FITC-BSA release studies.

Graft copolymers comprised of a polyacetal backbone with pendant poly(ethylene glycol) side-chains were prepared using a condensation reaction between a divinyl ethers, a diol and Fmoc-protected serinol, followed by deprotecting the amine and reacting the polyacetal with pendant amino groups with PEG-alpha-methoxy-omega-succimidylcarbonate. A series of materials having lower critical solution temperature (LCST) between 25 and 60 degrees C has been prepared. Since LCST is determined by the hydrophilic-hydrophobic balance, and this in turn is determined by the molecular weight of the polyacetal backbone, the molecular weight of the grafted PEG and the amount grafted, materials having a desired LCST could be readily prepared. Incorporating FITC-BSA at 1 wt.% into the thermogel resulted in sustained release over about 100 days at pH 7.4 and 40 days at pH 5.5 without a burst and by reasonably linear kinetics. Incorporating FITC-BSA at 5 wt.% into the thermogel significantly increased delivery time at pH 5.5 and decreased the difference in delivery rates between pH 5.5 and pH 7.4. FITC-BSA is released by a predominantly erosion-controlled process and FITC-BSA depletion coincides closely with total gel dissolution. More rapidly eroding thermogels were prepared by replacing the polyacetal backbone with a poly(ortho ester) backbone. Such gels completely dissolved between 3 and 6 days. It is hoped that intermediate erosion rates can be achieved by preparing backbones containing both acetal and ortho ester linkages. Such materials have been prepared and shown to have LCST values in the desired range, but no erosion, or drug release studies have as yet been completed.

Structure-activity relationships of poly(L-lysines): effects of pegylation and molecular shape on physicochemical and biological properties in gene delivery.

The influence of shape, molecular weight and pegylation of linear, grafted, dendritic and branched poly-L-lysines on their DNA delivery properties were investigated. DNA binding, condensation, complex size and morphology, cell uptake and transfection efficiency were determined. Most polylysines condense DNA, linear polymers being more efficient than most dendritic ones. At low molecular weights of PLL DNA binding and condensation were less efficient, particularly with dendrimers. Pegylation did not decrease DNA condensation of PLLs at less than 60% (fraction of M(w)) of PEG. Pegylation stabilized the complexes sterically, but did not protect them from interaction with polyanionic chondroitin sulfate. Cell uptake of polylysine/DNA complexes was high and pegylation increased the transfection efficacy. However, overall transfection level of polylysines is low possibly due to inadequate escape of the complexes from endosomes or poor release of DNA from the complexes. Physicochemical and biological structure-property relationships of poly-L-lysines were demonstrated, but no clear correlations between the tested physicochemical determinants (size of complexes, zeta-potentials, condensation of DNA and the shape of complexes) and biological activities were seen. Transfection activity may be ultimately determined by intracellular factors and/or still unknown features of DNA complexation with the carriers.