Abstract: Incubation system and method for automated cell culture and/or testing. An exemplary incubation system may comprise a housing forming a chamber. A rack may define storage positions to support an array of sample holders inside the chamber. A detection robot may be configured to capture one or more images of cells contained by one or more wells of each sample holder while the sample holder remains at one of the storage positions of the rack. A fluid handling station may be configured to add fluid to, and/or remove fluid from, one or more wells of each of the sample holders inside the housing. At least one plate robot may be configured to move sample holders between the rack and the fluid handling station. A computer may control operation of the detection robot, the fluid handling station, and the at least one plate robot.

Abstract: In an optical-based sample analysis, for example fluorescence-based or absorbance-based measurement, a selection is made between a first excitation light path and a second excitation light path. The first excitation light path directs excitation light from a light source, through an excitation monochromator, through an excitation filter, and to a sample. The second excitation light path directs excitation light from the light source, through the excitation filter, and to the sample while bypassing the excitation monochromator. Excitation light generated by the light source is transmitted along either the first excitation light path or the second excitation light path in accordance with the selection made, thereby irradiating the sample. In response the sample produces emission light (transmitted light in the case of absorbance measurements), which is transmitted to and measured by a light detector.

Abstract: In an optical-based sample analysis, for example fluorescence-based or absorbance-based measurement, a selection is made between a first excitation light path and a second excitation light path. The first excitation light path directs excitation light from a light source, through an excitation monochromator, through an excitation filter, and to a sample. The second excitation light path directs excitation light from the light source, through the excitation filter, and to the sample while bypassing the excitation monochromator. Excitation light generated by the light source is transmitted along either the first excitation light path or the second excitation light path in accordance with the selection made, thereby irradiating the sample. In response the sample produces emission light (transmitted light in the case of absorbance measurements), which is transmitted to and measured by a light detector.

Abstract: In a sample analyzing apparatus, an injector assembly injects a reagent onto a sample, and luminescent light from the sample is transmitted to a detector. The assembly may be movable toward and away from the sample. The assembly may include one or more needles that communicate with one or more reservoirs supplying reagent or other liquids. The assembly may include a light guide for communicating with the detector. A cartridge may be provided in which the assembly, one or more reservoirs, and one or more pumps are disposed. The cartridge and/or the apparatus may be configured for enabling rinsing or priming to be done outside the apparatus. The cartridge and/or the apparatus may include one or more types of sensors configured for detecting, for example, the presence of liquid or bubbles in one or more locations of the apparatus and/or the cartridge.

Abstract: In a sample analyzing apparatus, an injector assembly injects a reagent onto a sample, and luminescent light from the sample is transmitted to a detector. The assembly may be movable toward and away from the sample. The assembly may include one or more needles that communicate with one or more reservoirs supplying reagent or other liquids. The assembly may include a light guide for communicating with the detector. A cartridge may be provided in which the assembly, one or more reservoirs, and one or more pumps are disposed. The cartridge and/or the apparatus may be configured for enabling rinsing or priming to be done outside the apparatus. The cartridge and/or the apparatus may include one or more types of sensors configured for detecting, for example, the presence of liquid or bubbles in one or more locations of the apparatus and/or the cartridge.

Abstract: Systems and methods for measuring a target in a sample, the target being capable of generating an emitted light in response to an excitation light. In an example system, an excitation light source generates the excitation light along an excitation optical path. An attenuation filter arrangement selectively adds an attenuation filter to the excitation optical path. The attenuation filter attenuates the excitation light by a corresponding attenuation factor. The excitation light exits the attenuation filter arrangement along the excitation optical path to illuminate the sample. A light energy detector receives the emitted light generated in response to the excitation light, and outputs a measured signal level corresponding to an emitted light level. If the light energy detector indicates an overflow, signal measurement is repeated with attenuation filters of increasing attenuation factors until the measured signal level does not overflow.

Abstract: A system is provided for performing filter-based and monochromator-based measurements. The system includes a light source and a plurality of detectors. An excitation monochromator outputs a selected wavelength component of the excitation light. Emitted light from a sample follows a selected emission optical path. An emission monochromator outputs a selected wavelength component of the emitted light when part of the selected path. An interface cartridge includes emission light ports positioned to direct the emitted light from the sample along a corresponding optical path. The interface cartridge aligns a selected optical path with the main measurement optical axis. A movable sliding switch mechanism provides optical channels corresponding to positions on the sliding switch mechanism to complete a selected emission optical path. The position on the sliding switch mechanism is selected by moving the sliding switch mechanism to align the optical channel for the position with the main measurement optical axis.

Abstract: A cartridge and cartridge system for use in an apparatus for analyzing a sample are provided. The system has a plurality of cartridges for different applications for a multimode instrument. The cartridges are removably engaged with a cartridge support of the apparatus in a “plug-in” format such that one cartridge may be removed from the apparatus and another cartridge may be easily installed. The cartridge support includes a plurality of cartridge positions that receive cartridges concurrently. One of the cartridges may be a luminescence cartridge that includes an integrated detector that is movable toward and away from a sample carrier of the apparatus, and thus toward and away from a sample located at the sample carrier.

Abstract: Systems and methods for measuring a light intensity. An example photodetector measurement circuit comprises a photodetector that receives a light and generates a photodetector current indicative of the light intensity. The measurement circuit includes a first integrator coupled along a first signal path to the photodetector to generate a first voltage signal at a first integrator output indicative of an integral of the photodetector current level. A second integrator is configured to generate a second voltage signal at a second integrator output indicative of an integral of the photodetector current level. A differential amplifier receives the first voltage signal and the second voltage signal and generates a third output signal at a differential amplifier output indicative of a difference between the first voltage signal and the second voltage signal. The differential amplifier outputs the third voltage signal to an analog-to-digital conversion function (“ADC function”) input.

Abstract: Systems and methods for measuring a light intensity. An example photodetector measurement circuit comprises a photodetector that receives a light and generates a photodetector current indicative of the light intensity. The measurement circuit includes a first integrator coupled along a first signal path to the photodetector to generate a first voltage signal at a first integrator output indicative of an integral of the photodetector current level. A second integrator is configured to generate a second voltage signal at a second integrator output indicative of an integral of the photodetector current level. A differential amplifier receives the first voltage signal and the second voltage signal and generates a third output signal at a differential amplifier output indicative of a difference between the first voltage signal and the second voltage signal. The differential amplifier outputs the third voltage signal to an analog-to-digital conversion function (“ADC function”) input.

Abstract: A system is provided for performing filter-based and monochromator-based measurements. The system includes a light source and a plurality of detectors. An excitation monochromator outputs a selected wavelength component of the excitation light. Emitted light from a sample follows a selected emission optical path. An emission monochromator outputs a selected wavelength component of the emitted light when part of the selected path. An interface cartridge includes emission light ports positioned to direct the emitted light from the sample along a corresponding optical path. The interface cartridge aligns a selected optical path with the main measurement optical axis. A movable sliding switch mechanism provides optical channels corresponding to positions on the sliding switch mechanism to complete a selected emission optical path. The position on the sliding switch mechanism is selected by moving the sliding switch mechanism to align the optical channel for the position with the main measurement optical axis.

Abstract: A cartridge and cartridge system for use in an apparatus for analyzing a sample are provided. The system has a plurality of cartridges for different applications for a multimode instrument. The cartridges are removably engaged with a cartridge support in a “plug-in” format such that one cartridge may be removed from the apparatus and another cartridge may be easily installed. The cartridge support includes a plurality of cartridge positions that receive cartridges concurrently. One of the cartridges is a wavelength-tunable cartridge in which different light sources, excitation filters, and/or emission filters may be selected. Tuning is further accomplished by tilting the excitation or emission filters at desired angles relative to a beam of exciting light or emitted light.

Abstract: A cartridge and cartridge system for use in an apparatus for analyzing a sample are provided. The system has a plurality of cartridges for different applications for a multimode instrument. The cartridges are removably engaged with a cartridge support of the apparatus in a “plug-in” format such that one cartridge may be removed from the apparatus and another cartridge may be easily installed. The cartridge support includes a plurality of cartridge positions that receive cartridges concurrently. One of the cartridges may be a luminescence cartridge that includes an integrated detector that is movable toward and away from a sample carrier of the apparatus, and thus toward and away from a sample located at the sample carrier.

Abstract: A cartridge and cartridge system for use in an apparatus for analyzing a sample are provided. The cartridge has one or more light sources and/or optical systems and other components that are specific for a certain type of application such as fluorescence, absorbance, or luminescence. The light source, optical systems, and other components for a specific application are housed in a single cartridge. The system has a plurality of cartridges for different applications for a multimode instrument. The cartridges are removably engaged with the apparatus in a “plug-in” format such that one cartridge may be removed from the apparatus and another cartridge may be easily installed.