This disclosure is directed to exemplary embodiments of systems, methods, techniques, processes, products and product components that can facilitate users making improved absorbance or fluorescence measurements in the field of spectroscopy with reduced (minimal) sample waste, and increased throughput, particularly in the study of biological sciences. A measuring system is provided having: a base unit with a means for locating a pipette tip; a pipette tip designed to interact with the base unit for purposes of accurate pipette tip positioning; at least one light supplying unit positioned to supply light to a liquid sample in the pipette tip and at least one light collecting unit positioned to collect light from a liquid sample in the pipette tip.

An optical measuring system measures polarization optical properties of a sample. The system includes (a) a light source that emits measuring light along an optical axis of an analysis beam path, (b) a polarization state generator, arranged downstream with respect to the light source in the analysis beam path which provides light with a defined polarization state, (c) a sample holder, arranged downstream with respect to the polarization state generator in the analysis beam path which accommodates the sample, (d) a polarization state analyzer, arranged downstream with respect to the sample holder in the analysis beam path which measures the polarization state of the measuring light after passing through the sample, and (e) a mechanical support structure, at which at least the polarization state generator, the sample holder and the polarization state analyzer are directly attached. Also described is a method for producing such an optical measuring system.

This disclosure is directed to exemplary embodiments of systems, methods, techniques, processes, products and product components that can facilitate users making improved absorbance or fluorescence measurements in the field of spectroscopy with reduced (minimal) sample waste, and increased throughput, particularly in the study of biological sciences. A measuring system is provided having: a base unit with a means for locating a pipette tip; a pipette tip designed to interact with the base unit for purposes of accurate pipette tip positioning; at least one light supplying unit positioned to supply light to a liquid sample in the pipette tip and at least one light collecting unit positioned to collect light from a liquid sample in the pipette tip.

The present disclosure concerns an apparatus (10) and method for reading out an optical chip (20). A light source (13) is arranged for emitting single mode source light (S1) from its emitter surface (A1) towards an optical input (21) of the optical chip (20). A light detector (14) is arranged for receiving measurement light (S2) impinging onto its receiver surface (A2) from an optical output (22) of the optical chip (20), and measuring said received measurement light (S2). The emitted source light (S1) is aligned to enter the optical input (21) of the optical chip (20) and the measurement light (S2) is aligned back onto the receiver surface (A2). The receiver surface (A2) is larger than the emitter surface (A1) for facilitating the overall alignment.

An ultrasonic transducer holder, which is an embodiment, has a detachable container for containing a liquid sample, and transmits an ultrasonic wave. The ultrasonic transducer holder includes an ultrasonic transducer that emits an ultrasonic wave, and a protective layer that is fixed to the ultrasonic transducer and transmits the ultrasonic wave to the container. The protective layer includes a first surface that is a surface to which the ultrasonic transducer is fixed, and a second surface that is a back surface of the first surface and is designed to fix the container via a contact medium.

The invention relates to an apparatus comprising: a measuring head (10) having a slot (18) for receiving a measurement cell (26) and means (28) for emitting electromagnetic radiation, and means (32, 36) for detecting radiation from said emission means (28) after it has passed through the measurement cell (26); means (16) for translatably driving and means (12, 14) for translatably guiding, allowing the substantially vertical longitudinal movement of the measurement head (10); at least two recesses (44) each intended for receiving a measurement cell (26) and arranged one above the other in a longitudinal direction, the recesses (44) as well as the driving means (16) and the guiding means (12, 14) being configured such that during the translational movement of the measurement head (10) along the nominal travel thereof each recess is placed inside the slot (18) of the measurement head (10).

This disclosure is directed to exemplary embodiments of systems, methods, techniques, processes, products and product components that can facilitate users making improved absorbance or fluorescence measurements in the field of spectroscopy with reduced (minimal) sample waste, and increased throughput, particularly in the study of biological sciences. A measuring system is provided having: a base unit with a means for locating a pipette tip; a pipette tip designed to interact with the base unit for purposes of accurate pipette tip positioning; at least one light supplying unit positioned to supply light to a liquid sample in the pipette tip and at least one light collecting unit positioned to collect light from a liquid sample in the pipette tip.

A device is for analyzing a heterogeneous sample (S). The device includes a measurement module having a reservoir configured to accommodate the sample (S), a first infrared spectroscopy subassembly and a second fluorescence spectroscopy subassembly. The first subassembly includes a diffusing optical element which is positioned so as to allow the implementation of reliable infrared spectroscopy measurements with a high precision without degrading the fluorescence spectroscopy measurements which take place on the same sample. The device includes a processing module connected to the measurement module by a communication network and a processor configured to analyze the data obtained by infrared spectroscopy and fluorescence spectroscopy.

An optical monitoring device includes: a heating stirrer configured to generate at least one of thermal energy and vibration energy; a jig disposed on the heating stirrer and configured to fix, relative to the optical monitoring device, at least one of a container and a conduit; a light source arranged to emit light toward the at least one of the container and the conduit; a camera arranged and configured to obtain an image of the at least one of the container and the conduit; and an adjuster configured to adjust at least one of a position and an orientation of at least one of the light source and the camera.

A spectrophotometric instrument (1) for the quantitative measurement of an optical property of an analyte in a sample cell (4). The spectrophotometric instrument (1) comprises an instrument housing (2a, 2b) for a source of electromagnetic radiation and a detector; an optical pot (3) for accommodating the sample cell (4) having a flexible restraining cradle (6).