A microtube assembly includes a column container, a sealing cap and a collecting tube. The column container includes a column body having a first protruding structure, and the one end of the column body has an opening and a first outer thread. The sealing cap has an inner thread matching up with the first outer thread, and the sealing cap is sealed the opening of the column container by the inner thread screwed on the first outer thread of the column body. The collecting tube includes a collecting tube body having a containing space and a matching structure corresponding to the first protruding structure. The containing space is configured for containing the column container. The matching structure leans against the first protruding structure when the sealing cap seals the column container.

The present invention relates to a pillar structure for a biochip, the pillar structure including: a substrate portion which has a plate-shaped structure; multiple pillar portions which protrude from one surface of the substrate portion and each of which has an end portion on which a sample is disposed; and smooth surface forming portions which are formed on the other surface of the substrate portion that defines the plate-shaped structure together with the one surface of the substrate portion, the smooth surface forming portions forming smooth surfaces each having a relatively concave groove shape at a portion corresponding to a circumferential surface of each of the pillar portions.

A particle separating and measuring device includes a first flow path device having a post-separation flow outlet to allow discharge of a first fluid containing target particles to be separated, and a second flow path device receiving the first flow path device and having a first flow inlet to receive the first fluid. The first flow path device having a lower surface having the post-separation flow outlet is on the second flow path device having an upper surface having the first flow inlet in a first region, with the post-separation flow outlet facing and connecting to the first flow inlet. A connection flow path vertically extends from an opening of the first flow inlet to a first flow path, and narrows from the opening of the first flow inlet toward the first flow path.

A particle separating and measuring device includes a first flow path device having a post-separation flow outlet to allow discharge of a first fluid containing target particles to be separated, and a second flow path device receiving the first flow path device and having a first flow inlet to receive the first fluid. The first flow path device having a lower surface with the post-separation flow outlet is on the second flow path device having an upper surface with the first flow inlet in a first region. The post-separation flow outlet faces and connects to the first flow inlet. The first flow inlet has an opening larger than an opening of the post-separation flow outlet. The opening of the post-separation flow outlet connects to the opening of the first flow inlet at a peripheral portion of the opening of the first flow inlet.

The present disclosure is drawn to microfluidic devices. The microfluidic device includes a substrate, an optically translucent lid, an adhesive securing the substrate to the lid, and an optical barrier material between the substrate and the optically translucent lid.

The present invention provides for a novel series of accessories for Raman and/or luminescence spectral acquisitions for many different applications and methods for making such accessories. The invention further provides sample holders that enhance sample handling ability and sample sensitivity, reduce fluorescence and Raman background, as well as sample size and consumption, and thereby improve resulting spectral analyses.

An acoustic analyzer system is provided that includes an acoustic analyzer having a reusable glass flow cell positioned within the acoustic analyzer. A disposable card body may be inserted into the acoustic analyzer and deliver sample fluid to the glass flow cell so that acoustic-wave assisted measurements may be performed on the sample fluid. The disposable card body may also deliver wash fluid to the glass flow cell, and receive waste sample fluid and waste wash fluid from the glass flow cell to prepare the glass flow cell for subsequent sample fluids. Numerous other embodiments are provided.

The present disclosure describes systems and methods for versatile acoustic tweezer trapping and transport configurations. Examples can use ultrasound for contact-free, biocompatible, and precise manipulation of particles from millimeter to sub-micrometer scale along a narrow and complex path. Examples include spatially complex particle trapping and manipulation inside a boundary-free chamber using a single pair of sources and a shadow waveguide. The shadow waveguide structure can be disposed just outside a microfluidic chamber to guide and control the acoustic wave fields inside the chamber. The shadow waveguide can create a tightly confined, spatially complex acoustic field inside the chamber without an interior structure that could interfere with net flow or transport.

The use of DNA or other charged biomolecules for data storage can include the use of devices to manipulate the biomolecules in solution, e.g., to store and later to selectively read out selected samples of stored biomolecules. Systems and methods provided herein facilitate the electrical manipulation of DNA or other charged biomolecules for data storage or other applications by applying voltages to sets of electrodes arranged along the length of channels of microfluidic devices. The magnitudes and signs of the applied voltages can be controlled to collect DNA into a channel, to retain the collected DNA in the channel for later use, and then to expel the DNA from the channel for readout (e.g., by a pore sequencer integrated into the same microfluidic device as the channel). Such storage channels can have rectangular cross-sections or otherwise include electrodes having substantially planar geometry.

The present invention relates to a suction device (1) to be used together with a pipette, in particular a Pasteur pipette. The suction device comprises a base element (2) with the bore (2a) for the insertion of a pipette (5), and a body connected to the base element, wherein the interior of the body is hollow, wherein at least the body is made of a flexible material, so that the inner volume of the body (3) is variable. Herein, the base element is formed in a polygonal or elliptic shape, so that the shape of the base element is not round and hence prevents a rolling of the suction device over a lab bench or the like.