Supplying a liquid to a detection chip including a housing having an opening portion and internally housing the liquid and including an elastic sheet covering the opening portion and having a penetrating portion providing communicating between the inside and the outside of the housing, specifically by inserting a liquid delivery nozzle to the housing via the penetrating portion and supplying the liquid into the housing in a state where the nozzle is in contact with the elastic sheet so as to close the penetrating portion. The penetrating portion is one of a hole and a notch. One of the maximum length of the opening of the hole and the maximum length of the notch is smaller than the outer diameter of the nozzle at a portion coming in contact with the elastic sheet when the nozzle is inserted to close the penetrating portion when a liquid is supplied into the housing.

A sample analysis substrate includes a substrate; a first holding chamber; a reaction chamber; a first flow path having a first opening and a second opening respectively connected with the first holding chamber and reaction chamber; a main chamber; a second flow path having a third opening and a fourth opening respectively connected with the reaction chamber and the main chamber; and a magnet accommodation chamber capable of accommodating a magnet. The first opening is located closer to a rotation shaft than the second opening. The second opening is located closer to the rotation shaft than the third opening. The magnet accommodation chamber is located at a position at which, in the case where the magnet is accommodated in the magnet accommodation chamber, the magnet captures magnetic particles in the main chamber. The sample analysis substrate is rotatable to transfer a liquid.

A sample analysis substrate includes a substrate; a first holding chamber; a reaction chamber; a first flow path having a first opening and a second opening respectively connected with the first holding chamber and reaction chamber; a main chamber; a second flow path having a third opening and a fourth opening respectively connected with the reaction chamber and the main chamber; and a magnet accommodation chamber capable of accommodating a magnet. The first opening is located closer to a rotation shaft than the second opening. The second opening is located closer to the rotation shaft than the third opening. The magnet accommodation chamber is located at a position at which, in the case where the magnet is accommodated in the magnet accommodation chamber, the magnet captures magnetic particles in the main chamber. The sample analysis substrate is rotatable to transfer a liquid.

An apparatus comprising: a sensor configured to sense ambient smell; and a processor configured, responsive to the sensor sensing the ambient smell, to determine smell impact based on the ambient smell, and to conduct at least one counter action based on the smell impact.

A liquid handling device has an accommodation part for accommodating a liquid, two or more flow paths each opening to a lower part of a side wall surface of the accommodation part, and a liquid movement suppression part that is disposed in the lower part of the side wall between the openings of two of the flow paths that are adjacent to each other and slows or stops the movement of the liquid along the corner formed by the lower surface of the accommodation part and the side wall surface.

Systems and methods for processing sensor data and self-calibration are provided. In some embodiments, systems and methods are provided which are capable of calibrating a continuous analyte sensor based on an initial sensitivity, and then continuously performing self-calibration without using, or with reduced use of, reference measurements. In certain embodiments, a sensitivity of the analyte sensor is determined by applying an estimative algorithm that is a function of certain parameters. Also described herein are systems and methods for determining a property of an analyte sensor using a stimulus signal. The sensor property can be used to compensate sensor data for sensitivity drift, or determine another property associated with the sensor, such as temperature, sensor membrane damage, moisture ingress in sensor electronics, and scaling factors.

The present invention addresses the problem of providing a fluid handling system that is capable of injecting a fluid into a desired chip or the like without using a large-scale device. In order to resolve the problem, this fluid handling system has a reservoir, a flow path chip, and a cap, one end of which is fitted to the internal opening of the reservoir and the other end of which is connected to an introduction port of the flow path chip, the cap having a through-hole that links the one end and the other end. In this fluid handling system, a protruding part provided to the flow path chip is fitted into the through-hole at the other end of the cap and restricts blocking of the through-hole when a fluid moves inside the through-hole of the cap.

A device for synthesising and studying compounds under controlled temperatures and pressures includes: a body delimiting a vacuum chamber including temperature-regulation means and vacuum-application means, and having one or more viewing windows enabling the inside of the chamber to be observed from the outside; temperature-regulation means that are intended for regulating the temperature inside the vacuum chamber; and vacuum-application means that are intended for regulating the pressure in the vacuum chamber; wherein it includes, inside the vacuum chamber, a sealed structure delimiting a sealed chamber having one or more viewing window facing said one or more windows in said body, and at least one pipe that is in fluid communication firstly with the inside of said sealed chamber and secondly with an outlet that is made in the body and provided in order to be connected to one or more sources of gas for synthesising said compound or sample.

A device for synthesising and studying compounds under controlled temperatures and pressures includes: a body delimiting a vacuum chamber including temperature-regulation means and vacuum-application means, and having one or more viewing windows enabling the inside of the chamber to be observed from the outside; temperature-regulation means that are intended for regulating the temperature inside the vacuum chamber; and vacuum-application means that are intended for regulating the pressure in the vacuum chamber; wherein it includes, inside the vacuum chamber, a sealed structure delimiting a sealed chamber having one or more viewing window facing said one or more windows in said body, and at least one pipe that is in fluid communication firstly with the inside of said sealed chamber and secondly with an outlet that is made in the body and provided in order to be connected to one or more sources of gas for synthesising said compound or sample.

An apparatus includes a chassis configured to move back and forth along multiple rails. The apparatus also includes electrical contacts configured to form electrical connections to the rails. The apparatus further includes a power converter/conditioner configured to receive power from the rails via the electrical contacts and to convert the power into a different form and/or condition the power. In addition, the apparatus includes one or more sensors configured to measure at least one characteristic of a material, where the one or more sensors are configured to operate using the power from the power converter/conditioner. The electrical contacts could touch the rails and receive the power directly from the rails. The electrical contacts could also touch rail contacts and receive the power indirectly from the rails via the rail contacts.