Abstract: Disclosed are a method and a device for feeding and/or discharging fluids in microreactor arrays through one or several fluid ducts that extend into each individual microreactor and can be individually controlled and regulated, in order to control, regulate, influence, and/or verify processes. The fed or discharged amounts of fluid are introduced into or discharged from the volume of the reaction liquid during a continuous shaking process and are evenly mixed as a result of the shaking process. The continuous shaking process causes sufficient mass transfer and thorough mixing of the reaction partners or fluids while the reaction is not limited or restricted by the mass transfer conditions.

Abstract: Disclosed are a method and a device for feeding and/or discharging fluids in microreactor arrays through one or several fluid ducts that extend into each individual microreactor and can be individually controlled and regulated, in order to control, regulate, influence, and/or verify processes. The fed or discharged amounts of fluid are introduced into or discharged from the volume of the reaction liquid during a continuous shaking process and are evenly mixed as a result of the shaking process. The continuous shaking process causes sufficient mass transfer and thorough mixing of the reaction partners or fluids while the reaction is not limited or restricted by the mass transfer conditions.

Abstract: The invention relates to a device for detecting physiological measured variables within the body, comprising a catheter which has a tip supporting a sensor and which can be introduced into a blood vessel, the catheter (1) being connected to a transponder unit (2) for wireless transmission of at least one measured variable to an external reading station which is arranged outside the blood vessel (4) after insertion of the catheter (1) into said blood vessel (4), the catheter (1) and the transponder (2) being sealed in a leaktight manner. The invention also relates to a sluice/sleeve for coaxial arrangement on an element for insertion into a blood vessel, in particular a needle and/or a catheter, the sluice/sleeve (6,10,11) being able to be divided at least once in the longitudinal direction.

Abstract: The invention relates to a device for measuring physical quantities in the eye, especially for measuring the intraocular pressure. The inventive device comprises a foldable telemetry system containing a coil (1) which is flatly arranged on a foldable support. Said coil is completely embedded in the biocompatible implant material together with an electronic mobile (4) that contains the electronic of the telemetry system.

Abstract: A device for measuring intraocular pressure includes a remote measuring device that can be implanted in the eye and that contains a pressure sensor, a device that can convert the sensor signals into information that can be transmitted without wires, and a transmitter. The device also includes a receiving device located outside the eye which receives the information transmitted by the transmitter and which is connected to an evaluation device in which the received information is converted into data on the intraocular pressure for recording.

Abstract: The invention relates to an electrochemical sensor with interdigital micro-electrodes (1) with structure widths in the sub-.mu.m range. With a twin or multi-pair array of the interdigital micro-electrodes on a substrate (8), the electrochemical detection of molecules with high sensitivity is made possible and further uses for the detection of chemical reaction cycles are made available. The electrodes may be arranged in a micro-channel applied to the substrate having a constant small volume of a few nanoliters. The electrochemical sensor of the invention is suitable for the multiple measurement of the same species of molecule or as a multi-sensitive sensor in chemical analysis and process control in various fields such as biotechnology, environmental protection or health.

Abstract: An apparatus for measuring mechanical forces and force actions by means of body, a restoring element and a movable mass, with elements for limiting the deflections of the movable mass. The movable mass is deflected against the resistance of the restoring element under the influence of a mechanical force which, with the aid of sensors, is converted into electrical signals. The elements for limiting deflection include at least two parallel tongues fixed respectively to the restoring element and to the movable mass, and a bridge element fixed at right angles to one of the tongues, at least partly overlapping the other of the tongues.

Abstract: Methods for producing beam shaping diaphragms for lithographic devices in which a silicon layer is epitaxially deposited on a semiconductor body and the epitaxial layer is formed in the central region as a self-supporting membrane and is formed with preferably straight line-shaped quadratic recesses which have perpendicular limiting surfaces. Photolithographic processes and galvanic second-casting techniques may be used in the process for producing the beam-shaping diaphragm. The beam-shaping diaphragm can also be produced in lightly doped epitaxial layers by using electro-chemical etching methods.

Abstract: A method for manufacturing a control plate for a lithographic device. The control plate manufactured with a method of the present invention is essentially composed of a semiconductor substrate having an opening for the passage of particle probes emanating from a multi-beam source and of a corresponding plurality of deflection elements that are connected via bond pads and connecting lines to the electronics of the lithographic device that generates control signals. Lithographic methods and voltaic shaping techniques are utilized for the manufacture of the deflection elements located on the semiconductor substrate which is coated with a dielectric.