An apparatus for determining the mean corpuscular haemoglobin concentration (MCHC) in a whole blood sample includes a sample holder including an elongate sample chamber having an open end and a closed end. A holding member is adapted to receive and retain the sample holder. The holding member rotates may rotate about an axis of rotation. When the sample holder is received and retained by the holding member the sample chamber is substantially perpendicular to the axis of rotation. First and second light sources are positioned on one side of the sample holder and are configured to emit light in respective different frequencies. At least one light sensor is positioned on a second side of the sample holder, opposite from the first side, so that light from the light source may pass through the sample chamber, in at least one rotational position of the sample holder, and impinge on the light sensor.

Described herein are various embodiments directed to rotor devices, systems, and kits. Embodiments of rotors disclosed herein may be used to characterize one or more analytes of a fluid. An apparatus may include a first layer being substantially transparent. A second layer may be coupled to the first layer to collectively define a set of wells. The second layer may define a channel, and the second layer may be substantially absorbent to infrared radiation. A third layer may be coupled to the second layer. The third layer may define an opening configured to receive a fluid. The third layer may be substantially transparent. The channel may establish a fluid communication path between the opening and the set of wells.

Described herein are various embodiments directed to rotor devices, methods, and systems. Embodiments of rotors disclosed herein may be used to characterize one or more analytes of a fluid. A method may include bonding a first layer and a second layer using two-shot injection molding. The first layer coupled to the second layer may collectively define a set of wells. The first layer may be substantially transparent. The second layer may define a channel. The second layer may be substantially absorbent to infrared radiation. A third layer may be bonded to the second layer using infrared radiation. The third layer may define an opening configured to receive a fluid. The third layer may be substantially transparent. The channel may establish a fluid communication path between the opening and the set of wells.

Provided are methods and apparatuses for controlling a position of a target point on a processing result relative to a focus point of a focusing sensor system for determining properties of the processing result. The method includes the steps of determining an initial focus point of the focusing sensor system, controlling rotation of the cartridge and disc, checking whether the initial focus point of the focusing sensor system corresponds to the target point on the processing result, comparing (x, y) target positions in captured images with the initial focus point of the focusing sensor system, adjusting rotation of the cartridge and disc such that the focus point of the focusing sensor system corresponds to the target point on the processing result, and detecting and examining signals received from the focusing sensor system for determining properties of the processing result.

Provided are methods and apparatuses for controlling a position of a target point on a processing result relative to a focus point of a focusing sensor system for determining properties of the processing result. The method includes the steps of determining an initial focus point of the focusing sensor system, controlling rotation of the cartridge and disc, checking whether the initial focus point of the focusing sensor system corresponds to the target point on the processing result, comparing (x, y) target positions in captured images with the initial focus point of the focusing sensor system, adjusting rotation of the cartridge and disc such that the focus point of the focusing sensor system corresponds to the target point on the processing result, and detecting and examining signals received from the focusing sensor system for determining properties of the processing result.

A method for measuring a concentration of molecules, characterized in that the method measures the concentration of molecules dissolved in a continuous phase of a colloid and includes obtaining a test sample by mixing a number of molecules with a volume of colloid, obtaining a control sample by mixing a number of molecules with a volume of a composition comprising a particle-free solution extracted from a fraction of the continuous phase of same colloid used in the obtaining the test sample, so that a value of the concentration of molecules in the mixture is equal to the value of the concentration of molecules in the test sample obtained in the obtaining the test sample, and submitting the test and the control samples obtained in the obtaining the test sample and obtaining the control sample to a process in order to concentrate the particles of the test sample.

A method for measuring a concentration of molecules, characterized in that the method measures the concentration of molecules dissolved in a continuous phase of a colloid and includes obtaining a test sample by mixing a number of molecules with a volume of colloid, obtaining a control sample by mixing a number of molecules with a volume of a composition comprising a particle-free solution extracted from a fraction of the continuous phase of same colloid used in the obtaining the test sample, so that a value of the concentration of molecules in the mixture is equal to the value of the concentration of molecules in the test sample obtained in the obtaining the test sample, and submitting the test and the control samples obtained in the obtaining the test sample and obtaining the control sample to a process in order to concentrate the particles of the test sample.

A biochemical analyzer is disclosed. The biochemical analyzer includes a detection disc sample feeding device, a detection disc device, an optical path detection device, and a temperature control device. The detection disc device includes a rotatable detection disc. The detection disc has a plurality of partitions, and each partition is correspondingly equipped with one chip to be detected. The detection disc is further provided with an optical limiting slot, and the optical limiting slot cooperates with a first limiting optocoupler located on a side face of the detection disc to monitor the number of rotations of the detection disc. Each partition of the detection disc may be equipped with one chip to be detected, and multiple chips can be detected in one operation by using the rotatable detection disc.

A microfluidic centrifuge is provided that includes a microfluidic disc having a pair of through holes that include a first through hole and a second through hole, where the pair of through holes are disposed symmetric and proximal to a central axis of the microfluidics disc, where the microfluidics disc includes a sealable input port and a sealable output port, where the sealable input port and the sealable output port are connected by a microfluidics channel, and a pair of tethers disposed through the pair of through holes that are disposed to twist about each other for unwinding where the tether unwinding is disposed to interact with the through holes, where the microfluidics disc rotates about the central axis.

A sample analysis device includes: a motor to rotate a sample analysis substrate with a sample introduced thereon around a rotation axis of the sample analysis substrate; a drive circuit to drive the motor; a photodetector to measure a number of photons associated with a luminescence from the sample being transmitted through a window of a measurement chamber of the sample analysis substrate; and a control circuit to calculate a measurement value of the luminescence of the sample by using a number of photons measured by the photodetector while the motor rotates the sample analysis substrate.