Abstract: A method and a device are used for carrying out measurements on cells located in a liquid environment. Each cell is positioned with an underside of its membrane on a surface having a channel running through it. A negative pressure is established to aspirate the cells. Each cell is electrically scanned via at least one electrode which is spaced apart from the cell. The negative pressure is preferably established in a pulse-like manner to rupture the membrane in such a way that the cell interior enclosed by the membrane is connected to the channel.

Abstract: A device is disclosed for electrophysiological studies on biological material. The device comprises a support on which an array of measurement electrodes is arranged. A vessel is provided having a cavity for the biological material and an appropriate culture medium. The vessel is arranged on the support around the measurement electrodes in such a way that the latter are in electrical contact with the cavity. By means of a counter electrode, which is permanently arranged in the cavity, electrical signals can be measured between the measurement electrodes and the counter electrode.

Abstract: A retina implant to be implanted into an eye having an eye ball with an exterior and an interior, a sclera, a lens, and a retina is disclosed. The implant comprises a chip adapted to be implanted into the interior of the eye in contact with the retina. The chip, when in an implanted condition, has a plurality of pixel elements on a side thereof facing the lens for receiving an image projected onto the retina. The chip, further, comprises a plurality of electrodes for stimulating retina cells. The electrodes are located on the side of the chip having the pixel elements thereon, such that the chip is adapted to be implanted into a subretinal space of the eye. The implant, further, comprises a receiver coil for inductively coupling thereinto electromagnetic energy. The receiver coil is coupled to a means for converting an alternating voltage induced into the receiver coil in a direct voltage suited for supplying the chip.

Abstract: A retina implant, comprises a surface and a plurality of pixel elements disposed on the surface for receiving and converting incoming light energy into electric energy. At least one amplifier is provided in the implant, and a plurality of stimulation electrodes supplied via the at least one amplifier as a function of signals received by the pixel elements. At least one light-sensitive reference element is coupled with the at least one amplifier for controlling amplification thereof as a function of light energy impinging on the at least one reference element.

Abstract: A microelement device has a plurality of microelements, which may be configured as microelectrodes, arranged on a substrate and adapted for making contact to cells present in a liquid environment. The cells are guided onto the microelectrodes, are isolated or are mechanically attracted to the microelectrodes. A negative-pressure force or a hydrodynamic force may be applied on the cells. Also described are a method for making contact to the cells, and a method for manufacturing the microelement device is disclosed.

Abstract: An optically controllable microelectrode array for stimulating cells within a tissue is disclosed. The array comprises a substrate having a surface. The substrate is adapted to be placed on the tissue with the surface adjoining the cells. The substrate further comprises a plurality of electrodes on the surface in contact with the cells for stimulating the cells. The electrodes are dimensioned such that a first surface area on the electrodes in contact with the cells is essentially smaller than a second surface area on the cells in which the cells may be contacted by the electrodes. An electrical stimulus is exerted from the electrodes to the cells under the control of light impinging on the tissue.

Abstract: A microelement device has a plurality of microelements, which may be configured as microelectrodes, arranged on a substrate and adapted for making contact to cells present in a liquid environment. The cells are guided onto the microelectrodes, are isolated or are mechanically attracted to the microelectrodes. A negative-pressure force or a hydrodynamic force may be applied on the cells. Also described are a method for making contact to the cells, and a method for manufacturing the microelement device is disclosed.

Abstract: A retina implant has a substrate with a surface for applying same to a retina. The substrate comprises electrodes for stimulating cells within the retina. The electrodes are provided on the surface and are exposed to visible light impinging on the retina such that stimuli are exerted on the cells by the electrodes. The implant, further, comprises a photovoltaic layer responsive to non-visible light. The stimuli are locally switched utilizing a voltage generated by the photovoltaic layer.

Abstract: The invention concerns an “in situ” ion-etching device for local thinning of a sample in a transmission electron microscope (1) with simultaneous electron microscopic observation. Towards this end, an ion beam device (2) is arranged in such a way that the finest possible ion probe is produced at the sample location and can be scanned over the sample surface. The ion beam (16) and sample (10) thereby enclose the flattest possible angle. To compensate for the magnetic field of the objective lens (5), the ion beam (16) is defected along a curved path onto the sample (10). In a preferred embodiment, an electrostatic cylinder capacitor sector field effects double focusing. The ion probe can be positioned, via the scanned ion image, onto a selected region of the sample by the secondary electrons (22) released from the sample (10). The sample location can be observed during the ion thinning process in electron transmission or electron diffraction.

Abstract: The invention concerns a microelectrode arrangement for leaking, with local resolution, electrical cell potentials, or for electrical stimulation of networks of biological cells such as for example cell cultures, tissue slices "in vitro" or biological tissue "in vivo". In order to attain high local resolution and high temporal resolution, the invention suggests that, as microelectrodes (M.sub.1 to M.sub.n), in each instance a contacting electrode (K.sub.1 to K.sub.n) be placed above a pad electrode (A.sub.1 to A.sub.n) onto a substrate (S); with light-sensitive elements, preferably in the shape of a continuous layer (P) arranged between the said contacting electrodes and the pad electrodes. By illuminating the light-sensitive layer (P) in the region of individual microelectrodes (M.sub.1 to M.sub.n), these microelectrodes are selected. Selection is preferably by the transmitted-light process through the substrate (S). In this case, substrate (S) and pad electrodes (A.sub.1 to A.sub.n) must be translucent.

Abstract: A biocompatible composite material and a method for its production are provided, wherein the composite material is made of a plastic matrix having a felt of collagen fibers contained therein, wherein the collagen fibers project out of a surface of the composite material, wherein the composite material is produced by a process involving:a) providing a collagen fiber felt wherein the collagen fibers have a structure of native collagen;b) impregnating the collagen fiber felt with one or more polymerizable monomers,c) partially curing the one or more polymerizable monomers to provide a polymer containing unpolymerized monomers, shortchain oligomers or both therein;d) removing the unpolymerized monomers and shortchain oligomers from the surface of the composite material to expose the collagen fiber felt on the surface,wherein the composite material is useful for the production of implants, especially dental implants and the implants can be colonized with human cells prior to implantation.