Your search keyword '"Winnie Edith Svendsen"' showing total 2 results

1. Fabrication of polyimide based microfluidic channels for biosensor devices.

Author

Azeem Zulfiqar, Andrea Pfreundt, Winnie Edith Svendsen, and Maria Dimaki

Subjects

*BIOSENSORS, *POLYIMIDES, *MICROFLUIDIC devices, *POINT-of-care testing, *BOND strengths, *BIOMEDICAL materials

Abstract

The ever-increasing complexity of the fabrication process of Point-of-care (POC) devices, due to high demand of functional versatility, compact size and ease-of-use, emphasizes the need of multifunctional materials that can be used to simplify this process. Polymers, currently in use for the fabrication of the often needed microfluidic channels, have limitations in terms of their physicochemical properties. Therefore, the use of a multipurpose biocompatible material with better resistance to the chemical, thermal and electrical environment, along with capability of forming closed channel microfluidics is inevitable. This paper demonstrates a novel technique of fabricating microfluidic devices using polyimide (PI) which fulfills the aforementioned properties criteria. A fabrication process to pattern microfluidic channels, using partially cured PI, has been developed by using a dry etching method. The etching parameters are optimized and compared to those used for fully cured PI. Moreover, the formation of closed microfluidic channel on wafer level by bonding two partially cured PI layers or a partially cured PI to glass with high bond strength has been demonstrated. The reproducibility in uniformity of PI is also compared to the most commonly used SU8 polymer, which is a near UV sensitive epoxy resin. The potential applications of PI processing are POC and biosensor devices integrated with microelectronics. [ABSTRACT FROM AUTHOR]

Published

2015

2. Qualitative Mapping of Structurally Different Dipeptide Nanotubes.

Author

Casper Hyttel Clausen, Jason Jensen, Jaime Castillo, Maria Dimaki, and Winnie Edith Svendsen

Subjects

*PEPTIDES, *NANOTUBES, *MOLECULAR self-assembly, *MICROSCOPY, *AROMATIC compounds, *PHENYLALANINE

Abstract

Biological self-assembled structures are receiving increasing focus within micro- and nanotechnology, for example, as sensing devices, due to the fact that they are cheap to produce and easy to functionalize. Therefore, methods for the characterization of these structures are much needed. In this paper, electrostatic force microscopy (EFM) was used to distinguish between hollow nanotubes formed by self-assembly by a simple aromatic dipeptide, l-phenylalanine, silver-filled peptide-based nanotubes, and silver wires placed on prefabricated SiO 2surfaces with a backgate. The investigation shows that it is possible to distinguish between these three types of structures using this method. Further, an agreement between the detected signal and the structure of the hollow peptide was demonstrated; however only qualitative agreement with the mathematical expressing of the tubes is shown. [ABSTRACT FROM AUTHOR]

Published

2008