An optical cell for performing light spectroscopy (including absorbance, fluorescence and scattering measurements) on a liquid sample in microfluidic devices is disclosed. The optical cell comprises an inlaid sheet having an opaque material inlaid in a clear material, and a sensing channel that crosses the clear material and the opaque material provides a fluidic path for the liquid sample and an optical path for probe light. Integral optical windows crossing a clear-opaque material interface permit light coupling into and out of the sensing channel, and thus light transmission through the sensing channel is almost entirely isolated from background light interference. A microfluidic chip comprising one or more optical cells is also disclosed. The optical cells may have different lengths of sensing channels, and may be optically and fluidly coupled. A method of manufacturing an optical cell in a microfluidic chip is also disclosed.

An on-chip optical absorption sensor for determining a concentration of a specimen in a sample, the optical absorption sensor comprising at least one light emitting device, configured to emit light in a first direction and a second direction being opposite the first direction; at least one sample holder configured to receive the sample, wherein the at least one sample holder is at least partially transparent for the emitted light, such that at least a portion of the light emitted in the first direction can propagate through at least a portion of the sample holder; at least one first light detector being arranged to detect at least partially the intensity I of the propagated light having propagated through the sample holder in the first direction; at least one second light detector being arranged to detect at least partially the intensity I of the light emitted in the second direction.

One example of a flow cell includes a base support and a multi-layer stack positioned over the base support. The multi-layer stack includes a resin layer positioned over the base support; and a hydrophobic layer positioned over the resin layer. A depression is defined in the multi-layer stack through the hydrophobic material and through a portion of the resin.

A microfluidic channel structure and a fabrication method thereof, a microfluidic detecting device and a detecting method thereof are disclosed. The microfluidic channel structure includes a support portion; a foundation portion, provided on the support portion and including a first foundation and a second foundation spaced apart from each other; and a channel defining portion, provided on a side of the foundation portion that is away from the support portion and including a first channel layer and a second channel layer, the first channel layer covering the first foundation and the second channel layer covering the second foundation have a gap therebtween to define a microfluidic channel; and the first channel layer and the second channel layer are made of a same material.

Methods are provided for the automated detection of micro-objects in a microfluidic device. In addition, methods are provided for repositioning micro-objects in a microfluidic device. In addition, methods are provided for separating micro-objects in a spatial region of the microfluidic device.

An on-chip optical absorption sensor for determining a concentration of a specimen in a sample, the optical absorption sensor comprising at least one light emitting device, configured to emit light in a first direction and a second direction being opposite the first direction; at least one sample holder configured to receive the sample, wherein the at least one sample holder is at least partially transparent for the emitted light, such that at least a portion of the light emitted in the first direction can propagate through at least a portion of the sample holder; at least one first light detector being arranged to detect at least partially the intensity I of the propagated light having propagated through the sample holder in the first direction; at least one second light detector being arranged to detect at least partially the intensity I of the light emitted in the second direction.

Methods are provided for the automated detection of micro-objects in a microfluidic device. In addition, methods are provided for repositioning micro-objects in a microfluidic device. In addition, methods are provided for separating micro-objects in a spatial region of the microfluidic device.

The present disclosure provides a microfluidic chip, including: first base substrate and a second base substrate opposite to each other; first electrode and second electrode between the first base substrate and the second base substrate and configured to control droplet to move between the first base substrate and the second base substrate according to voltages applied on the first electrode and the second electrode; light guide component configured to guide light propagating in the first base substrate to the droplet; shading component and detection component, shading component having light transmission regions spaced from each other, light transmission regions being configured to transmit light passing through the droplet to the detection component, wherein detection component is on second base substrate and is configured to obtain property of the droplet according to an intensity of the light passing through droplet and received from the light transmission regions.

The flow cell is composed of a cell block and a cell holder. The cell block is light transmittable and is provided with a plurality of cells communicated with each other and mutually different in optical path length and an inlet and an outlet communicated with the cell. The plurality of cells include a short optical path length cell having an optical path length of 100 m or less. The short optical path length cell is constituted by a groove formed on an inner joining surface of a plurality of laminated light transmitting substrates. The optical path length of the short optical path length cell is defined by a depth of the groove. The cell holder is configured to accommodate the cell block therein, and is provided with an incident window for allowing light to enter the cell block and an emission window for emitting the light transmitted through the cell block.