Abstract: The invention relates to an optical sensor device (100) that comprises a plurality of objectives (152) for generating primary images of corresponding sensor regions (111). The primary images are then mapped with intermediate optics (153) onto a detector plane (154), particularly onto the sensitive plane of an image sensor.

Abstract: A biosensor system for the detection of particles includes a biosensor cartridge having a sensor surface. A biosensor magnet assembly is disposed on one side of the cartridge for generating a magnetic field effective at the cartridge and the sensor surface. The biosensor magnet assembly includes at least two magnetic sub-units separated by a gap. A first optical detection system detects the particles arranged at the same side of the cartridge as the magnet assembly. The magnet assembly and the first optical sensor are disposed such that the optical detection is accomplished through the gap of the magnet assembly.

Abstract: A medical imaging system for identifying a target structure (TS), e.g. a tumor, in a biological tissue. A hyperspectral camera system is used for imaging a surface area (A1) of the tissue (BT), e.g. with a limited spectral resolution, but enough to allow identification of suspicious areas where the target structure (TS) may be, e.g. such areas can be visually indicated on a display to the operator. A probe (PR), e.g. an optical surface probe, is used to provide probe measurement of a smaller surface area (A2) of the tissue, but with more information indicative of the target structure. The probe is selected to provide a higher specificity with respect to identification of the target structure than the hyperspectral camera (HSC). The hyperspectral processing algorithm (PP) is then calibrated based on probe measurement data performed within the suspicious areas, thus providing a calibrated hyperspectral processing algorithm resulting in images with an enhanced sensitivity to identify the target structure.

Abstract: The invention relates to a method for the detection of target components that comprise label particles, for example magnetic particles (1). The method includes (a) collecting the target components at a binding surface (12, 112, 512) of a carrier (11, 111, 211, 311, 411, 511); (b) directing an input light beam (L1, L1a, L1b) into the carrier such that it is totally internally reflected in an investigation region (13, 313a, 313b) at the binding surface (12, 112, 512); and (c) determining the amount of light of an output light beam (L2, L2a, L2b) that comprises at least some of the totally internally reflected light. Evanescent light generated during the total internal reflection is affected (absorbed, scattered) by target components and/or label particles (1) at the binding surface (12) and will therefore be missing in the output light beam (L2). This can be used to determine the amount of target components at the binding surface (12) from the amount of light in the output light beam (L2, L2a, L2b).

Abstract: The invention relates to a carrier with a binding surface at which target components that comprise label particles, for example magnetic particles, can collect and optionally bind to specific capture elements. An input light beam (L1) is transmitted into the carrier and totally internally reflected at the binding surface. The amount of light in the output light beam (L2) and optionally also of fluorescence light emitted by target components at the binding surface is then detected by a light detector. Evanescent light generated during the total internal reflection is affected (absorbed, scattered) by target components and/or label particles at the binding surface and will therefore be missing in the output light beam (L2). This can be used to determine the amount of target components at the binding surface from the amount of light in the output light beam (L2, L2a, L2b).

Abstract: A biosensor system for the detection of particles includes a biosensor cartridge having a sensor surface. A biosensor magnet assembly is disposed on one side of the cartridge for generating a magnetic field effective at the cartridge and the sensor surface. The biosensor magnet assembly includes at least two magnetic sub-units separated by a gap. A first optical detection system detects the particles arranged at the same side of the cartridge as the magnet assembly. The magnet assembly and the first optical sensor are disposed such that the optical detection is accomplished through the gap of the magnet assembly.

Abstract: The invention relates to a sensing system for sensing a substance in a fluid. The sensing system comprises a sensing site (132) at which the substance is to be sensed and a reference site (131). A signal generation unit generates a sensing signal by sensing the sensing site (132) and a reference signal by sensing the reference site (131). The reference signal is used for normalizing the sensing signal, wherein the sensing site (132) and the reference site (131) are arranged such that a drift variation of the normalized sensing signal is within a noise variation of the normalized sensing signal. This improves the accuracy of the normalized sensing signal.

Abstract: A biosensor system for the detection of particles includes a biosensor cartridge having a sensor surface. A biosensor magnet assembly is disposed on one side of the cartridge for generating a magnetic field effective at the cartridge and the sensor surface. The biosensor magnet assembly includes at least two magnetic sub-units separated by a gap. A first optical detection system detects the particles arranged at the same side of the cartridge as the magnet assembly. The magnet assembly and the first optical sensor are disposed such that the optical detection is accomplished through the gap of the magnet assembly.

Abstract: The invention relates to a sensor apparatus (100) and a method for detecting clusters with magnetic particles in a sample. The sample is provided in at least one sample chamber (114) of a substantially planar cartridge (110) that is exposed to a modulated magnetic field (Bxz, Byz) generated by a magnetic field generator (190). The sample chamber (114) is illuminated with excitation light (L0), and the resulting output light (Ls) is detected by a light detector (180). The magnetic field (Bxz, Byz) may particularly rotate, inducing a corresponding rotation of clusters which in turn induces a variation of the detection signal (S). According to a preferred embodiment, excitation light (L0) is focused onto blocking spots (173) behind the sample chamber (114), thus shielding the light detector (180) from direct illumination.

Abstract: The invention relates to an optical sensor device (100) that comprises a plurality of objectives (152) for generating primary images of corresponding sensor regions (111). The primary images are then mapped with intermediate optics (153) onto a detector plane (154), particularly onto the sensitive plane of an image sensor.

Abstract: The invention relates to a method and an optical device (150) in which a light beam (L) is coupled into a transparent component, for example into a foil (110). The incoupling is achieved by astigmatically focusing a light beam (L) onto an oblong entrance window (W) of the foil (110), wherein a focal line (Fx) of the light beam (L) is oriented along the axis (x) of extension of the entrance window (W). Preferably, a second focal line (Fy) of the light beam (L) is disposed inside the transparent component (110) below a region of interest (112).

Abstract: The invention relates to focusing optics (100) for a biosensor (10) which allow with simple means to accurately image an extended investigation region (13) onto a detector plane (P). To this end, the focusing optics (100) comprises at least two focusing lenslets (LL) that are arranged adjacent to each other such that they image an incident parallel light beam (L2) that is directed along a main optical axis (MOA) onto a common plane (P). The output light beam (L2) that is received by the focusing optics (100) may preferably originate from total internal reflection of a parallel input light beam (L1) at the investigation region (13) of a transparent carrier.

Abstract: A detection system combining an excitation radiation source providing excitation radiation to an analysis region of a sample within a substrate having a detection surface, a detector for detecting radiation collected from the analysis region comprising the detection surface of the sample resulting from the excitation, and a magnet arrangement beneath the analysis region of the sample, and stationary with respect to the excitation radiation source and light coupling arrangement, for attracting magnetic beads within the sample to the substrate surface. The detection radiation is collected from the detection surface of the substrate to give an enhanced surface specificity.

Abstract: A carrier and an apparatus for optical detection of a sample in a sample chamber includes en optical structure for refracting an input light beam into the adjacent sample chamber and for collecting an output light beam from light that originates in the sample chamber from the input light beam. The optical structure includes grooves in the surface of the carrier in which the Input light beam is transmitted Over a short distance through a sample. The optical structure can also be used for a wetting detection.

Abstract: The invention relates to a microelectronic sensor device for the examination of target particles (1) that are bound to binding sites (3) at the binding surface (12) of a carrier (11). In a preferred embodiment, an input light beam (L1) is transmitted into the carrier (11), where a frustrated total internal reflection (FTIR) takes place at the binding surface (12). The amount of light in a resulting output light beam (L2) is detected by a light detector (31) and provides information about the presence of target particles at the binding surface. Moreover, an actuation unit (50) induces movements of the bound target particles (1) by an interaction with a magnetic field (B) or an electric field, particularly with a given modulation frequency (COIn), such that by a demodulation of the detector signal (S) effects of the target particles can be distinguished from background.

Abstract: The invention relates to a sensor device (100) in which the spatial distribution of an input light (L1) emission from a light emitting area (121, 122) of a light source (120) can selectively be changed. The input light is propagated through an optical system (110) to produce some output light (L2). Changes of the input light are taken into account when the detected output light (L2) is evaluated. Thus it is for example possible to detect and/or eliminate optical disturbances occurring in the optical path outside an object region (3). The light source (120) may particularly comprise a plurality of a light emitting segments (121, 122) that can selectively be switched on or off.

Abstract: The invention relates to a cartridge (110) and an examination apparatus (100) for optical examinations of a sample. The cartridge (110) comprises a transparent bottom layer (113) that is of substantially uniform thickness and a top layer (111, 112) comprising a sample chamber (SC). The bottom layer and the top layer are preferably laminated onto each other, for example in a C roll-to-roll process. The bottom layer (113) is provided with structures like gratings (115) that allow the incoupling or outcoupling of light.

Abstract: The invention relates to a carrier (211) and an apparatus for optical manipulations of a sample in a sample chamber (2), wherein the carrier (211) comprises a contact surface (12) with a plurality of holes (52), particularly grooves (52). In a preferred embodiment, the holes (52) have two oppositely slanted opposing facets (53, 54) that include an angle (2a) of less than about (¾/¾)·140°, with ¾ and n2 being the refractive indices of the carrier and the sample, respectively. Moreover, a light source may be arranged such that it generates an input light beam (LI) which traverses at least two holes (52) before leaving the carrier (211) as an output light beam (L2). Due to the steepness of the facets (53, 54) and/or the multiple passages of the input light beam (LI) through holes (52) it is possible to interact with a sample in the holes in an efficient way and to minimize losses of light.

Abstract: The present invention provides an FTIR system comprising a first light source emitting light of a first wavelength, a sample volume with an adjacent sensor surface, a detector for detecting light reflected at said sensor surface. The sensor surface is illuminated by said first light source fulfilling the condition of total internal reflection and generating an evanescent field with a decay length within the sample volume. The system further comprises means for changing the decay length of the evanescent field and means for correlating the detected signals with the change of the decay length of the evanescent field.

Abstract: The invention relates to a substance determining apparatus for determining a substance within a fluid. Particles attach the substance and bind to a binding surface (30), wherein a sensing signal is generated depending on the bound particles. Binding events indicating a binding of a particle on the binding surface (30) are determined from the generated sensing signal, and the substance within the fluid is determined based on the determined binding events. During a procedure of determining a substance within a fluid, particles may bind to the binding surface and may leave the binding surface. Therefore, during this procedure a number of binding events can be determined being much larger than the number of bound particles. The determination of the substance within the fluid can therefore be based on a very large amount of data, thereby increasing the accuracy of determining the substance within the fluid.