Systems and methods for performing measurements of one or more materials are provided. One system is configured to transfer one or more materials to an imaging volume of a measurement device from one or more storage vessels. Another system is configured to image one or more materials in an imaging volume of a measurement device. An additional system is configured to substantially immobilize one or more materials in an imaging volume of a measurement device. A further system is configured to transfer one or more materials to an imaging volume of a measurement device from one or more storage vessels, to image the one or more materials in the imaging volume, to substantially immobilize the one or more materials in the imaging volume, or some combination thereof.

A cuvette carrier comprising: a plurality of walls defining a holding volume for a cuvette; a first and second transmissive region included in the plurality of walls; and a first optical polarizer arranged to polarize light passing through the first transmissive region.

The invention relates to a sample-holding element (20) for a liquid sample for the simultaneous analysis of three or more chemico-physical parameters of the liquid by means of an analysis device. The sample-holding element (20) has a sample-holding chamber (31), which can be filled with the liquid, wherein the sample-holding element (20) has at least three measurement points (24, 25, 26, 26N, 27) arranged adjacent to each other, which are distributed over the sample-holding chamber (31), wherein two of the measurement points (24, 25) are a photonic measurement point (24) and a refractive-index measurement point (25) and wherein the at least one further measurement point is selected from the group comprising at least a pH measurement point (26), a conductivity measurement point (27) and a germ measurement point. The sample-holding element (20) is a planar element (20) that is double-walled at least in some sections and that has plates (30, 30), which are arranged on each other in a plane-parallel manner and are connected to each other at the edges thereof at least in some sections, wherein the sample-holding chamber (31) is formed as a planar gap between the plates (30, 30) and the distance between the plates (30, 30) is just so large that the liquid sample can be subjected to the capillary effect between the double walls (30, 30). The measurement point (25) for measuring the refractive index has a refraction structure (25, 25) on one of the plates (30, 30) in a region predefined therefor. The invention further relates to an analysis device set having the sample-holding element (20) and having an analysis apparatus (1) and to a method for the simultaneous analysis of three or more chemico-physical parameters of the liquid.

A spectrometer apparatus (1) is provided for measuring spectra of a liquid sample, such as a beverage such as wine. The apparatus (1) comprises an integrating cavity (3) comprising a reflective inner wall or walls (5), configured to receive a cuvette (7) containing the liquid sample within the integrating cavity (5). A combination of light inlet ports P1, P2 and light outlet ports P3, P4 are provided to receive light from at least one light source (9) and to deliver light to a spectrometer (11). A light path adjuster (13, 13B) is configured to selectively adjust a light path through the integrating cavity (5) such that at least two distinct light paths are provided; wherein when the light path adjuster (13, 13B) is in a first configuration, the apparatus (1) is in a transmission mode in which light from the light source follows a first light path (15) from the or one of the light inlet port(s) to the liquid sample such that the light from the light source irradiates the liquid sample directly before the light transmitted by the sample is transmitted through the or one of the light outlet port(s) and received by the spectrometer (11) for wavelength analysis of the light to provide an extinction spectrum of the liquid sample; and when the light path adjuster (13, 13B) is in a second configuration, the apparatus is in a diffusely reflecting mode in which light from the light source follows a second light path (17) from the or one of the inlet port(s) into the integrating cavity, is incident onto the reflective inner wall or walls of the integrating cavity and is diffusely reflected within the integrating cavity, such that the light from the light source irradiates the liquid sample before being transmitted through the or one of the light outlet port(s) and received by the spectrometer (11) for wavelength analysis of the light to provide an absorbance spectrum of the liquid sample contained in the liquid sample.

A system includes a cuvette including a cuvette body forming a substantially planar exterior surface and having a sensor window defined within the substantially planar exterior surface. The cuvette further includes a probe retention structure extending from the cuvette body. The system includes a probe with a probe body and a protrusion that is removably coupled to the probe retention structure.

A system includes a cuvette (200) including a cuvette body (202) forming a substantially planar exterior surface and having a sensor window (204) defined within the substantially planar exterior surface. The cuvette further includes a probe retention structure (236, 238, 204) extending from the cuvette body. The system includes a probe (402) with a probe body (404) and a protrusion (410) that is removably coupled to the probe retention structure.

A transmissive sampling module is provided, which is adapted to a spectrometer main body. The transmissive sampling module includes a light source assembly and a support base. The light source assembly is directly connected to the support base. The support base includes a tube body and at least one fixing member. The tube body surrounds an accommodating groove, and an extending direction of the tube body is not parallel to an optical path of the light source assembly, and the tube body includes a transparent portion, and the optical path of the light source assembly passes through the transparent portion and the accommodating groove. The at least one fixing member is disposed on the tube body and is adjustably protruded out of an inner surface of the tube body. A transmissive spectrometer is also provided.

Provided is a microscope including: a chamber storing a solution in which a cuvette accommodating a solution together with a sample is immersed and that has an index of refraction identical to that of the solution; an immersion objective lens being placed outside the chamber and collecting light from the sample; a camera acquiring an image of the light collected by the lens; a targeting section moving the lens in a direction along a detection light axis thereof; and a movable stage supporting the cuvette in the chamber so as to be movable in at least a direction along the detection light axis. Each of the cuvette and the chamber has a transparent section that can transmit light coming from the sample. The lens is placed so as to face the transparent section of the cuvette with the transparent section of the chamber interposed therebetween.

The present invention relates to a biosensor. The biosensor according to an embodiment of the present invention comprises: a substrate (11) having a predetermined length; a sensing unit (10) having a thin film layer (13) formed by dispersing and arranging conductive nanoparticles or nanostructures (14) on at least one of the both sides of the substrate (11) to cause an LSPR phenomenon and being immersed in a target sample (3) to bind a target analyte in the target sample (3) to the thin film layer (13); and a gripping unit (20) connected to one end of the substrate (11) and gripped by a user.

The disclosed technology relates to a biosensor and an analysis method using the same. The biosensor includes a sensing unit and a gripping unit. The sensing unit includes a substrate having a thin film layer formed on one or more surfaces thereof, wherein the thin film layer comprises conductive nanoparticles or nanostructures that are configured such that localized surface plasmon resonance (LSPR) is induced in response to light incident thereon. When immersed in a target sample containing a target analyte, the thin film layer is configured to bind thereon the target analyte. The gripping unit connected to one end of the substrate and configured to be gripped by a user.