Abstract: The present invention relates to a dispensing system (1) having at least two chambers (2,3) for a tissue adhesive system comprising at least two components, wherein first chamber (2) is designed as a hollow cylinder (H), which has a closed design on an end face (2a) and an open design on its opposite end face (2b) and second chamber (3) in a solid cylinder (V) is designed as an annular gap (4) and annular gap (4) extends from an end face (3a) facing hollow cylinder (H) to a mixing chamber (5) arranged on opposite end (3b) of solid cylinder (V) and hollow cylinder (H) is arranged on the side of its open end face (2b) in annular gap (4) of solid cylinder (V) so it can move in longitudinal direction (L), wherein at least one feed duct (6) is designed in solid cylinder (V), which extends on the inside of annular gap (4) from end face (3a) of solid cylinder (V) facing hollow cylinder (H) to mixing chamber (5), wherein a mixing tube (7) is provisioned in mixing chamber (5), which projects laterally from solid cylin

Abstract: It is described a low ohmic Through Wafer Interconnection (TWI) for electronic chips formed on a semiconductor substrate (600). The TWI comprises a first connection extending between a front surface and a back surface of the substrate (600). The first connection (610) comprises a through hole filled with a low ohmic material having a specific resistivity lower than poly silicon. The TWI further comprises a second connection (615) also extending between the front surface and the back surface. The second connection (615) is spatially separated from the first connection (610) by at least a portion of the semiconductor substrate (600). The front surface is provided with a integrated circuit arrangement (620) wherein the first connection (610) is electrically coupled to at least one node of the integrated circuit arrangement (620) without penetrating the integrated circuit arrangement (620). During processing the TWI the through hole may be filled first with a non-metallic material, e.g. poly silicon.

Abstract: In a disclosed imaging method, the instantaneous speed or data acquisition dwell times of a detector head is optimized as a function of position along a path of the detector head around a subject. The optimization is respective to an expected radioactive emission profile of a region of interest that is less than the entire subject. The detector head is traversed along the path using the optimized instantaneous speed or data acquisition dwell times. During the traversing, imaging data are acquired using the detector head. The acquired imaging data are reconstructed to generate a reconstructed image of at least the region of interest. A gamma camera configured to perform the foregoing imaging method is also disclosed.

Abstract: A grid (1) for selective transmission of electromagnetic radiation and a method for manufacturing such grid is proposed. Therein, the grid (1) comprises a structural element with walls (3) comprising a plurality of particles (19) of a radiation-absorbing material wherein the particles (19) are sintered together such that pores (21) are present between neighboring particles (19). The pores (21) are at least partially filled with a second solid material. The filling of the pores (21) can be done by inserting the second material in a liquid, preferably molten form into the pores. The second material can be itself radiation-absorbing as well and may help to both, increase the mechanical stability of the grid and to enhance the radiation-absorbing properties.

Abstract: The invention relates to semiconductor substrates and methods for producing such semiconductor substrates. In this connection, it is the object of the invention to provide semiconductor substrates which can be produced more cost-effectively and with which a high arrangement density as well as good electrical conductivity and closed surfaces can be achieved. In accordance with the invention, an electrically conductive connection is guided from its front side through the substrate up to the rear side. The electrically conductive connection is completely surrounded from the outside. The insulator is formed by an opening which is filled with material. The inner wall is provided with a dielectric coating and/or filled with an electrically insulating or conductive material. The electrically conductive connection is formed with a further opening which is filled with an electrically conductive material and is arranged in the interior of the insulator.

Abstract: In a disclosed imaging method, the instantaneous speed or data acquisition dwell times of a detector head is optimized as a function of position along a path of the detector head around a subject. The optimization is respective to an expected radioactive emission profile of a region of interest that is less than the entire subject. The detector head is traversed along the path using the optimized instantaneous speed or data acquisition dwell times. During the traversing, imaging data are acquired using the detector head. The acquired imaging data are reconstructed to generate a reconstructed image of at least the region of interest. A gamma camera configured to perform the foregoing imaging method is also disclosed.

Abstract: In a disclosed imaging method, the instantaneous speed or data acquisition dwell times of a detector head (14, 16) is optimized as a function of position along a path (P) of the detector head around a subject (S, SS, SXL). The optimization is respective to an expected radioactive emission profile (EPROI) of a region of interest (H, HS, HXL) that is less than the entire subject. The detector head is traversed along the path using the optimized instantaneous speed or data acquisition dwell times (40). During the traversing, imaging data are acquired using the detector head. The acquired imaging data are reconstructed to generate a reconstructed image of at least the region of interest. A gamma camera (10) configured to perform the foregoing imaging method is also disclosed.

Abstract: In order to provide a simple and reliable monitoring technique for a number of different parameters of a patient in a bed (2), a system (1) is provided, said system (1) comprising: at least one first sensor device (25) adapted to measure a first force component acting in a first direction (12), said first force component corresponding to a first parameter of the patient, at least one second sensor device (36) adapted to measure a second force component acting in a second direction (13, 14), said second force component corresponding to a second parameter of the patient, and a data device (16) adapted to acquire the measured data from the at least one first sensor device (25) and the at least one second sensor device (36) and to process those data in order to provide information about the number of parameters of the patient.

Abstract: A method and an apparatus for locally applying material to the surface of an anode of an X-ray source as well as a corresponding anode is presented. Anode material such as a repair material for filling a recess (121) in an X-ray emitting surface (115) is applied to the X-ray emitting surface of an anode (101). The location where such material is to be applied may be detected using a laser beam (133). The applied repair material including particles (41) of anode material such as tungsten, rhenium or molybdenum, is subsequently locally sintered using a high-energy laser beam (151). The sintered material may then be melted using a high-energy electron beam (163). Using such method, a damaged surface of an anode may be locally repaired. Alternatively, structures of different anode materials or of protrusions having different levels can be provided on the X-ray emitting surface (115) in order to selectively manipulate the X-ray emitting characteristics of the anode (101).

Abstract: A grid (1) for selective transmission of electromagnetic radiation and a method for manufacturing such grid is proposed. Therein, the grid (1) comprises a structural element with walls (3) comprising a plurality of particles (19) of a radiation-absorbing material wherein the particles (19) are sintered together such that pores (21) are present between neighbouring particles (19). The pores (21) are at least partially filled with a second solid material. The filling of the pores (21) can be done by inserting the second material in a liquid, preferably molten form into the pores. The second material can be itself radiation-absorbing as well and may help to both, increase the mechanical stability of the grid and to enhance the radiation-absorbing properties.

Abstract: The invention refers to a sensor arrangement for weight and/or movement sensing in a bed and uses thereof, to a bed and to a method of sensing weight and/or movement of a user in a bed. For the sensing of weight, activity and/or cardiopulmonary performance in a bed, force sensors (6) integrated between a bedframe (2) and a mattress frame (3) are used. The sensors are designed in a way that they can be positioned between the mattress frame and the bedframe without significantly enhancing the height of a mattress bearing surface. Thus, the integration into any bed with bedframe can be easily realized. The measurements do not require any user interaction or even direct contact between user and sensor.

Abstract: The invention relates to semiconductor substrates and methods for producing such semiconductor substrates. In this connection, it is the object of the invention to provide semiconductor substrates which can be produced more cost-effectively and with which a high arrangement density as well as good electrical conductivity and closed surfaces can be achieved. In accordance with the invention, an electrically conductive connection is guided from its front side through the substrate up to the rear side. The electrically conductive connection is completely surrounded from the outside. The insulator is formed by an opening which is filled with material. The inner wall is provided with a dielectric coating and/or filled with an electrically insulating or conductive material. The electrically conductive connection is formed with a further opening which is filled with an electrically conductive material and is arranged in the interior of the insulator.

Abstract: The present invention relates to a bed with an integrated sensor unit for a patient. Furthermore the invention relates to a method of providing a bed with a sensor unit for a patient. In order to provide a simple and reliable technique for monitoring patients a bed is suggested, comprising a bedframe (3) with at least a first and a second bedframe section (1, 2), said bedframe sections (1, 2) being connected to each other by means of at least one hinge (4), the bed further comprising a sensor unit (5, 5?), characterized in that the sensor unit (5, 5?) is connected with the pivot (9) of the hinge (4), and is adapted to measure the movement of a bedframe section (1, 2) in a direction (21) substantially perpendicular to the rotary axis (22) of the pivot (9).

Abstract: The present invention relates to a system (1) and method for obtaining cardiopulmonary and/or activity data of a patient (3) situated in a bed (2). In order to provide a simple and reliable technique for obtaining physiological data, in particular cardiopulmonary data and/or activity data, of a patient (3) situated in a bed (2), a method is suggested, comprising the steps of: providing a bed (2) with a bed structure (4) comprising at least one elastically deformable member (6), said member (69 being deformable by the patient (3) being situated in the bed (2); in case of deformation of said member (6), acquiring deformation data (25) of said member (6); and determining physiological data of said patient (3) using said deformation data (25).

Abstract: The present disclosure concerns a grid for selective transmission of electromagnetic radiation, particularly X-ray radiation, that has at least one structural element (2) that was built by means of selective laser sintering of an essentially radiation-opaque powder material, and it also discloses a method of manufacturing a grid for selective transmission of electromagnetic radiation that comprises the step of growing at least a structural element (2) by means of selective laser sintering from an essentially radiation-opaque powder material. Having a structural element that is built by selective laser sintering, the grid can be a highly complex 3D structure that is not achievable by molding or milling techniques. In one embodiment of the grid, the sintered structure engages through holes in metal sheets.

Abstract: In a disclosed imaging method, the instantaneous speed or data acquisition dwell times of a detector head (14, 16) is optimized as a function of position along a path (P) of the detector head around a subject (S, SS, SXL). The optimization is respective to an expected radioactive emission profile (EPROI) of a region of interest (H, HS, HXL) that is less than the entire subject. The detector head is traversed along the path using the optimized instantaneous speed or data acquisition dwell times (40). During the traversing, imaging data are acquired using the detector head. The acquired imaging data are reconstructed to generate a reconstructed image of at least the region of interest. A gamma camera (10) configured to perform the foregoing imaging method is also disclosed.

Abstract: In a lighting unit with a holder (21) and a body (22), the body (22) is pivotally hinged to the holder (21) for rotation around at least a first axis of rotation. The body (22) comprises a support (1) for a lamp (2), which support (1) is pivotally hinged to the body (22) for rotation around a second axis, where upon a rotational movement of the body (22) around the first axis of rotation, the support (1) rotates conversely around the second axis, so that the defined orientation of the lamp (2) in the environment is maintained.

Abstract: A Grid (1) for selective absorption of electromagnetic radiation (2, 3), as used e.g. in CT or NM imaging, comprises a block of a rigid foam material (4), where the foam material is essentially transparent to the electromagnetic radiation (2, 3), a first set of radiation absorbing lamellae (5), and a second set of radiation absorbing lamellae (6), the first and the second set of lamellae are arranged in the block of foam material so that a radiation transmission direction (T) is defined, the first set of lamellae and the second set of lamellae being arranged on top of each other with respect to the transmission direction (T). Such a grid arrangement is rigid due to the use of a carrier material, can be manufactured precisely and, furthermore, two-dimensional grids can be manufactured without the need to physically intersect the lamellae.

Abstract: The present invention allows on demand retrofit of a bed (2) with the sensing units (9) of a new monitoring system, which allows mechanical sensing of the presence of patients, movements of patients, breathing and heart rate.

Abstract: The invention relates to a device for the detection and/or transmission of radiation, particularly an X-ray detector 1, that consists of a carrier 10 on which an array of detector modules 20 is arranged. The carrier 10 comprises holes 11 through which a ball at the backside of the detector modules 20 can be inserted in order to fix the modules such that they can still rotate to a certain degree. Due to this freedom, the sensor modules 20 can align themselves during assembly.