Optical tomography arrangements are disclosed for performing optical tomography on the transparent or translucent contents of individual microplate wells comprising a light emitting array having a plurality of light emitting elements, a sample module, and a light sensing array including a plurality of light sensing elements, wherein the light sensing array is configured to sense light emitted from the light emitting array which has passed through the sample module. The light emitting elements can comprise light emitting diodes (LEDs), organic light emitting diodes (OLEDs), organic light emitting transistors (OLETs), and/or other optoelectronic devices. The light sensing array can comprise organic light sensing devices, photodiodes, phototransistors, CMOS photodetectors, or charge-coupled devices (CCDs). The light emitting array can be flat or curved, and the light sensing array can be flat or curved. The collection of measurement values can be overspecified, and a generalized inverse operation can provide solutions rendering computational tomography data.

Fluorescence-based sensors having favourably low detection limits and high sensitivity are disclosed. The sensors comprise one or more solution processable colour filters that are used together with organic LEDs and photodiodes. The colour filters are used to narrow the wavelength range of the OLED emission and/or to reject any light from reaching the photodiode which is not from analyte fluorescence, thereby enhancing the device sensitivity.

An assay device for the quantitative determination of the concentration of at least one analyte in a liquid sample comprises a planar emitter (2), a planar detector (3), a lateral flow membrane (4) interposed between the emitter (2) and the detector (3), a conjugate pad (5) in fluid communication with a proximal end of the lateral flow membrane (4), the conjugate pad (5) comprising optically detectable tagging particles bound to a first assay component, a sample pad (6) in fluid communication with the conjugate pad (5) and arranged to receive the liquid sample, and a wicking pad (7) in fluid communication with a distal end of the lateral flow membrane (4). The lateral flow membrane (4) is formed from a light transmissive material and is capable of transporting fluid from the conjugate pad (5) to the wicking pad (7) by capillary action. The lateral flow membrane (4) comprises at least one test region (8, 12) comprising an immobilised second assay component for retaining the tagging particles in the test region (8, 12) in dependence on the binding between the analyte, the first assay component and the second assay component in order to generate a concentration of tagging particles in the test region (8, 12) that is indicative of the concentration of the analyte in the liquid sample. The emitter (2) comprises an emission layer (9, 16) of an organic electroluminescent material and the emission layer (9, 16) is aligned with the test region (8, 12) of the lateral flow membrane 4, whereby the emitter (2) is capable of illuminating the test region (8, 12). The detector (3) comprises an absorption layer (10, 15) of an organic photovoltaic material and the absorption layer (10, 15) is aligned with the test region (8, 12) of the lateral flow membrane 4, whereby the detector (3) is capable of detecting light from the test region (8, 12).

A cylindrical optical tomography system includes a light emitting array having a plurality of light emitting elements, a cylindrical sample holding element, and a light sensing array including a plurality of light sensing elements, wherein the light sensing array is configured to sense light emitted from the light emitting array which has passed through the sample holding module.

An imaging element for analysis of a sample includes an electrode adapted to receive the sample, a light-emitting element, disposed opposite the electrode, and separated from the electrode by an insulating protective layer, a voltage-controlled current source configured to supply current to the light-emitting element and comprising a control electrode electrically connected to the electrode, so that said light-emitting element generates a light wave in response to a voltage coming from the sample.

A sensor device configured to be attached to a drug delivery device and configured to illuminate the drug delivery device when attached, the sensor device having an OLED having a transparent first electrode, a transparent second electrode and a central layer disposed between the first and second electrodes, the central layer comprising at least one organic layer, the at least one organic layer configured to emit light through the transparent first electrode, and an optical sensor arranged to receive light reflected from a surface of the drug delivery device, wherein the central layer of the OLED has a region without the at least one organic layer and wherein the optical sensor is arranged, when the sensor device is attached to the drug delivery device, to view a predetermined area of the surface of the drug delivery device through the region without the at least one organic layer.

A cylindrical optical tomography system includes a light emitting array having a plurality of light emitting elements, a cylindrical sample holding element, and a light sensing array including a plurality of light sensing elements, wherein the light sensing array is configured to sense light emitted from the light emitting array which has passed through the sample holding module.

An optical instrument monitors PCR replication of DNA in a reaction apparatus having a temperature cycled block with vials of reaction ingredients including dye that fluoresces in presence of double-stranded DNA. A beam splitter passes an excitation beam to the vials to fluoresce the dye. An emission beam from the dye is passed by the beam splitter to a CCD detector from which a processor computes DNA concentration. A reference strip with a plurality of reference emitters emit reference beams of different intensity, from which the processor selects an optimum emitter for compensating for drift. Exposure time is automatically adjusted for keeping within optimum dynamic ranges of the CCD and processor. A module of the beam splitter and associated optical filters is associated with selected dye, and is replaceable for different dyes.

A sensor device configured to be attached to a drug delivery device and configured to illuminate the drug delivery device when attached, the sensor device having an OLED having a transparent first electrode, a transparent second electrode and a central layer disposed between the first and second electrodes, the central layer comprising at least one organic layer, the at least one organic layer configured to emit light through the transparent first electrode, and an optical sensor arranged to receive light reflected from a surface of the drug delivery device, wherein the central layer of the OLED has a region without the at least one organic layer and wherein the optical sensor is arranged, when the sensor device is attached to the drug delivery device, to view a predetermined area of the surface of the drug delivery device through the region without the at least one organic layer.

An optical tomography system including a light emitting array having one or more light emitting diodes (LEDs), a sample holding module and a light sensing array comprising one or more light emitting diodes (LEDs), wherein the light sensing array is configured to sense light emitted from the light emitting array, which has passed through the sample holding module.