Your search keyword '"Saile, Volker"' showing total 7 results

1. Large-aperture two-dimensional x-ray refractive mosaic lenses.

Author

Nazmov V, Reznikova E, Mohr J, Saile V, Tajiri H, and Voigt A

Abstract

Lenses with high numerical aperture are required for images with very high spatial resolution, which is difficult to realize in the x-ray range because of low-refraction-index decrement and relatively high absorption of x-rays in the material. However, such an aperture can be realized by means of a mosaic lens, as shown in this work.

Published

2016

2. On the ANKA decision: a response to Braun's Just for us?

Author

Saile V

Abstract

KIT's Executive Board has decided to discontinue the operation of the synchrotron radiation facility ANKA within category LK-II (user facility) of the Helmholtz Association and continue operation in LK-I (research). The KIT Senate confirmed this decision. Some aspects of the background and the rationale leading to this change are explained.

Published

2015

3. Fabrication of cell container arrays with overlaid surface topographies.

Author

Truckenmüller R, Giselbrecht S, Escalante-Marun M, Groenendijk M, Papenburg B, Rivron N, Unadkat H, Saile V, Subramaniam V, van den Berg A, van Blitterswijk C, Wessling M, de Boer J, and Stamatialis D

Subjects

Animals, Cell Line, High-Throughput Screening Assays, Lactic Acid chemistry, Mice, Polyesters, Surface Properties, Polymers chemistry, Tissue Engineering methods

Abstract

This paper presents cell culture substrates in the form of microcontainer arrays with overlaid surface topographies, and a technology for their fabrication. The new fabrication technology is based on microscale thermoforming of thin polymer films whose surfaces are topographically prepatterned on a micro- or nanoscale. For microthermoforming, we apply a new process on the basis of temporary back moulding of polymer films and use the novel concept of a perforated-sheet-like mould. Thermal micro- or nanoimprinting is applied for prepatterning. The novel cell container arrays are fabricated from polylactic acid (PLA) films. The thin-walled microcontainer structures have the shape of a spherical calotte merging into a hexagonal shape at their upper circumferential edges. In the arrays, the cell containers are arranged densely packed in honeycomb fashion. The inner surfaces of the highly curved container walls are provided with various topographical micro- and nanopatterns. For a first validation of the microcontainer arrays as in vitro cell culture substrates, C2C12 mouse premyoblasts are cultured in containers with microgrooved surfaces and shown to align along the grooves in the three-dimensional film substrates. In future stem-cell-biological and tissue engineering applications, microcontainers fabricated using the proposed technology may act as geometrically defined artificial microenvironments or niches.

Published

2012

4. Closer to nature-bio-inspired patterns by transforming latent lithographic images.

Author

Giselbrecht S, Reinhardt M, Mappes T, Börner M, Gottwald E, van Blitterswijk C, Saile V, and Truckenmüller R

Subjects

Polymethyl Methacrylate chemistry, Surface Properties, Ultraviolet Rays, X-Rays, Biomimetics

Published

2011

5. Thermoforming of film-based biomedical microdevices.

Author

Truckenmüller R, Giselbrecht S, Rivron N, Gottwald E, Saile V, van den Berg A, Wessling M, and van Blitterswijk C

Subjects

Cell Culture Techniques, Hot Temperature, Microfluidic Analytical Techniques, Microtechnology, Tissue Engineering, Polymers chemistry

Abstract

For roughly ten years now, a new class of polymer micromoulding processes comes more and more into the focus both of the microtechnology and the biomedical engineering community. These processes can be subsumed under the term "microthermoforming". In microthermoforming, thin polymer films are heated to a softened, but still solid state and formed to thin-walled microdevices by three-dimensional stretching. The high material coherence during forming is in contrast to common polymer microreplication processes where the material is processed in a liquid or flowing state. It enables the preservation of premodifications of the film material. In this progress report, we review the still young state of the art of microthermoforming technology as well as its first applications. So far, the applications are mainly in the biomedical field. They benefit from the fact that thermoformed microdevices have unique properties resulting from their special, unusual morphology. The focus of this paper is on the impact of the new class of micromoulding processes and the processed film materials on the characteristics of the moulded microdevices and on their applications., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

6. Gold helix photonic metamaterial as broadband circular polarizer.

Author

Gansel JK, Thiel M, Rill MS, Decker M, Bade K, Saile V, von Freymann G, Linden S, and Wegener M

Abstract

We investigated propagation of light through a uniaxial photonic metamaterial composed of three-dimensional gold helices arranged on a two-dimensional square lattice. These nanostructures are fabricated via an approach based on direct laser writing into a positive-tone photoresist followed by electrochemical deposition of gold. For propagation of light along the helix axis, the structure blocks the circular polarization with the same handedness as the helices, whereas it transmits the other, for a frequency range exceeding one octave. The structure is scalable to other frequency ranges and can be used as a compact broadband circular polarizer.

Published

2009

7. Microfabrication of chip-sized scaffolds for three-dimensional cell cultivation.

Author

Giselbrecht S, Gottwald E, Truckenmueller R, Trautmann C, Welle A, Guber A, Saile V, Gietzelt T, and Weibezahn KF

Subjects

Cell Culture Techniques methods, Microchip Analytical Procedures methods, Microinjections, Polymers chemistry, Cell Culture Techniques instrumentation, Lab-On-A-Chip Devices, Microtechnology methods

Abstract

Using microfabrication technologies is a prerequisite to create scaffolds of reproducible geometry and constant quality for three-dimensional cell cultivation. These technologies offer a wide spectrum of advantages not only for manufacturing but also for different applications. The size and shape of formed cell clusters can be influenced by the exact and reproducible architecture of the microfabricated scaffold and, therefore, the diffusion path length of nutrients and gases can be controlled.1 This is unquestionably a useful tool to prevent apoptosis and necrosis of cells due to an insufficient nutrient and gas supply or removal of cellular metabolites. Our polymer chip, called CellChip, has the outer dimensions of 2 x 2 cm with a central microstructured area. This area is subdivided into an array of up to 1156 microcontainers with a typical dimension of 300 m edge length for the cubic design (cp- or cf-chip) or of 300 m diameter and depth for the round design (r-chip).2 So far, hot embossing or micro injection moulding (in combination with subsequent laborious machining of the parts) was used for the fabrication of the microstructured chips. Basically, micro injection moulding is one of the only polymer based replication techniques that, up to now, is capable for mass production of polymer microstructures.3 However, both techniques have certain unwanted limitations due to the processing of a viscous polymer melt with the generation of very thin walls or integrated through holes. In case of the CellChip, thin bottom layers are necessary to perforate the polymer and provide small pores of defined size to supply cells with culture medium e.g. by microfluidic perfusion of the containers. In order to overcome these limitations and to reduce the manufacturing costs we have developed a new microtechnical approach on the basis of a down-scaled thermoforming process. For the manufacturing of highly porous and thin walled polymer chips, we use a combination of heavy ion irradiation, microthermoforming and track etching. In this so called "SMART" process (Substrate Modification And Replication by Thermoforming) thin polymer films are irradiated with energetic heavy projectiles of several hundred MeV introducing so-called "latent tracks" Subsequently, the film in a rubber elastic state is formed into three dimensional parts without modifying or annealing the tracks. After the forming process, selective chemical etching finally converts the tracks into cylindrical pores of adjustable diameter.

Published

2008