The present disclosure describes an apparatus and method of improving temperature uniformity and suppressing well plate warping. In an embodiment, the apparatus includes a barrier configured to be positioned above at least one well configured to contain a liquid sample, where a vessel includes the at least one well, where the vessel is transparent and is configured to be placed within a measurement chamber, where a light measurement apparatus includes the measurement chamber, where the light measurement apparatus is configured to measure light scattered from the liquid sample, where the barrier is configured to seal the at least one well from the measurement chamber, and a weighted lid configured to press a bottom surface of the vessel against a well plate retainer of the measurement chamber, thereby spreading heat among the at least one well and preventing the vessel from warping.

A closure and a container assembly are disclosed. The closure includes a first visual identifier and a second visual identifier, wherein the second visual identifier is different from the first visual identifier. The first visual identifier may be a first color, and the second visual identifier may be a second color. At least one of the first and/or second visual identifier may include a fluorescent compound having a characteristic fluorescent spectra. The first visual identifier and the second visual identifier may be provided on the annular skirt of the closure. The fluorescent compound may be provided on at least one of the closure and the container assembly and can be used to facilitate automated visualization of the fluorescent compound under fluorescence excitation light.

Enclosures and corresponding magnetic joints. An apparatus includes an enclosure. The enclosure includes a magnetic panel joint formed by: an alignment bore disposed in one of the first end face and the second end face, an alignment dowel disposed in the other of the first end face and the second end face, a face magnet disposed in one of the first end face and the second end face, a face ferromagnetic segment disposed in the other of the first end face and the second end face, and a shield that extends from the second panel and is received in the first pocket, when the first panel and the second panel are removably secured to one another.

Methods and apparatus for long read, label-free, optical nanopore long chain molecule sequencing. In general, the present disclosure describes a novel sequencing technology based on the integration of nanochannels to deliver single long-chain molecules with widely spaced (>wavelength), ˜1-nm aperture “tortuous” nanopores that slow translocation sufficiently to provide massively parallel, single base resolution using optical techniques. A novel, directed self-assembly nanofabrication scheme using simple colloidal nanoparticles is used to form the nanopore arrays atop nanochannels that unfold the long chain molecules. At the surface of the nanoparticle array, strongly localized electromagnetic fields in engineered plasmonic/polaritonic structures allow for single base resolution using optical techniques.

Disclosed is a device for packaging balls for reaction vessels for an analysis appliance, including: a body including at least one opening and used to house balls, a closing member, that can be moved relative to the body between a closed position in which the closing member closes the opening of the body, and an open position in which the opening of the body is open so as to allow the balls to be dispensed from the body.

A sensor device for use in sensing a change in a concentration of micro-organisms, comprises a waveguide interferometer having a sensing arm and a reference arm, a microfluidic channel for a fluid containing the micro-organisms, and a trapping arrangement in the microfluidic channel for physically trapping the micro-organisms when the fluid flows along the microfluidic channel so as to concentrate the micro-organisms in a sensing region of the microfluidic channel. The sensing arm is configured to guide sensing light, the reference arm is configured to guide reference light, and the waveguide interferometer is configured to interfere the sensing light with the reference light. The waveguide interferometer and the microfluidic channel are configured to allow the sensing light to interact with the fluid and the micro-organisms in the sensing region of the microfluidic channel.

A microfluidic device includes a lower casing and an upper casing covering the lower casing. The lower casing includes a lower base wall having a top surface and a plurality of spaced-apart columns that protrude upwards from the top surface. The upper casing includes an upper base wall. A first gap between the upper base wall and a column top surface of each of the columns is large enough to permit passage of large biological particles of a liquid sample, and a second gap between any two adjacent ones of the columns is not large enough to permit passage of the large biological particles and is large enough to permit passage of small biological particles of the liquid sample.

A test device is provided that can comprise: a housing accommodating a chromatography support, wherein the housing comprises: a supporting part that supports a container accommodating a liquid used for chromatography. A method is provided for performing chromatography using the test device.

An apparatus suitable for handling biological material, for directly introducing or removing material to, or from, a container, comprising a body comprising at least one resealable port; a cover comprising an aperture and wherein the cover is disposed over an upper side of the body, and wherein the cover is moveable such that an aperture of the cover is configured to expose at least part of the resealable port.

A fully automatic inductive sample-collecting bucket capable of storing sample information includes a bucket, and a bucket cover snap-fitted to an upper end of the bucket. A bucket cover cavity is formed in the bucket cover. A locking mechanism, and a control mechanism for driving the locking mechanism to act are integrated in the bucket cover cavity. An integrated circuit (IC) card inductive control assembly is integrated in the bucket cover. The bucket is provided with a radio frequency identification (RFID) chip. The IC card inductive control assembly is configured to identify IC card unlocking information of an external grip for cover opening work and to drive the control mechanism to work to control an action of the locking mechanism. The sample-collecting bucket integrates an RFID card capable of carrying sample coding information, and can realize the automatic cover-sealing and cover-opening function under the identification and control of the controller.