Your search keyword '"Koerten, H K"' showing total 3 results

1. Stable polyplexes based on arginine-containing oligopeptides for in vivo gene delivery.

Author

van Rossenberg, S. M. W., van Keulen, A. C. I., Drijfhout, J. -W., Vasto, S., Koerten, H. K., Spies, F., van't Noordende, J. M., van Berkel, Th. J. C., and Biessen, E. A. L.

Subjects

*PEPTIDES, *GENETIC transduction, *LYSINE, *ARGININE, *POLYMERIZATION, *GENE therapy

Abstract

In this study, we investigated to what extent the stability and transduction capacity of polyplexed DNA can be improved by optimizing the condensing peptide sequence. We have synthesized a small library of cationic peptides, at which the lysine/arginine ratio and the cation charge were varied. All peptides were able to compact DNA, at which polyplexes of short lysine-rich sequences were considerably larger than those of elongated or arginine-rich peptides (GM102 and GM202). In addition, the arginine-rich peptides GM102 and GM202 rendered the polyplexes resistant to plasma incubation or DNase I-mediated digestion. While all peptides were found to improve the transfection efficiency in HepG2 cells, only the GM102- and GM202-derived polyplexes could be specifically targeted to HepG2 cells by incorporation of a ligand-derivatized YKAK8WK peptide. We propose that GM102 and GM202 combine the advantage of small condensing peptides to give small-sized polyplexes with the superior stability of condensing polymers, which makes GM102 and GM202 excellent candidates for future in vivo gene therapy studies.Gene Therapy (2004) 11, 457-464. doi:10.1038/sj.gt.3302183 [ABSTRACT FROM AUTHOR]

Published

2004

2. Transport of Chitosan Microparticles for Mucosal Vaccine Delivery in a Human Intestinal M-cell Model.

Author

Van Der Lubben, I. M., Van Opdorp, F. A. C., Hengeveld, M. R., Onderwater, J. J. M., Koerten, H. K., Verhoef, J. C., Borchard, G., and Junginger, H. E.

Subjects

*CHITOSAN, *VACCINES, *ELECTRON microscopy, *INTESTINES, *CELLS

Abstract

Uptake of particulate antigen carrier systems by specialized M-cells of the gut-associated lymphoid tissue is still a limiting step in inducing efficient immune responses after oral vaccination. Although transport of soluble drugs over the epithelial barrier of the gut is extensively studied in vitro by using the Caco-2 cell model, this was for long time not possible for particles due to the absence of M-cells. By co-culturing Caco-2 cells with cultured human B-lymphocytes (Raji-cells), cells which are morphologically and functionally similar to M-cells can be induced. This human M-cells model makes it possible to study the uptake of microparticles for oral vaccine delivery. In this way, chitosan microparticles, which have demonstrated to target the Peyer's patches efficiently in vivo , could be tested in vitro . The development of this M-cells model facilitates the optimization of the microparticles in order to target them even more efficiently to the M-cells in the gut. In this study, the integrity of the human M-cell model was investigated by determining the transepithelial electrical resistance (TEER), 14 C-mannitol transport and morphology using scanning electron microscopy. The uptake of particles was investigated by measuring transport of both fluorescently labeled microspheres (Fluospheres ® ) and chitosan microparticles using flowcytometry. No discontinuities or abnormalities could be found in the co-culture. Scanning electron microscopy showed that morphologically different cells were present in the human M-cell model. Both commercially available Fluospheres ® (size 0.2 μm) and chitosan microparticles (size 1.7 μm) for oral vaccine delivery were transported at a significantly higher amount by the human M-cell model compared to the transport by the Caco-2 cell monoculture. Since chitosan microparticles were proven to be taken up by Peyer's patches in mice as well, this human M-cell model is able to predict the M-cell uptake of microparticles for oral vaccine delivery. This M-cell model is a new tool, which can be used to scan, develop and optimize microparticles for oral vaccine delivery. Since the M-cell uptake can now be studied in vitro , the targeting of these cells can be studied more efficiently and can now be done in cells from human origin. [ABSTRACT FROM AUTHOR]

Published

2002

3. Evidence of grass-pollen allergenic activity in the smaller micronic atmospheric aerosol fraction.

Author

Spieksma, F. Th. M., Kramps, J. A., Van Der Linden, A. C., Nikkels, Bep H., Plomp, A., Koerten, H. K., and Dijkman, J. H.

Subjects

*RESPIRATORY allergy, *POLLEN, *BLOOD plasma, *ALLERGIC rhinitis, *IMMUNE serums

Abstract

In June 1988, during the grass-pollen season in Leiden, The Netherlands, outdoor airborne paniculate matter was collected and separated into fractions according to aerodynamic sizes (≥10 µm, 4.9-10 µm, 2.7-4.9 µm, 1.3-2.7 µm, 0.6-1.3 µm, ≤0.6 µm), with a cascade impactor mounted on top of a high volume sampler. The different fractions were tested for the presence of grass-pollen allergenic activity using a RAST-inhibition assay: specific IgE-antibody-containing patient serum was applied on the particle-loaded impaction strips, and the serum was recovered by descending elution for further analysis in the RAST. Simultaneously., continuous measurements were made of the airborne grass-pollen concentration using a volumetric pollen trap. Sampling observations lasting 7-9 hr during a period with relatively high airborne grass-pollen concentrations showed reliably detectable amounts of grass-pollen allergen, not only in the first impaction stage where intact pollen were collected, but also in the lower stages collecting the smaller, paucimicronic and submicron atmospheric aerosol fraction. It is evident that this result has serious implications for the understanding of the bronchial symptoms frequently seen in hay fever patients on days with high pollen concentrations in the air. [ABSTRACT FROM AUTHOR]

Published

1990