The present disclosure relates to a sensor cap for an optochemical sensor for determining or monitoring at least one analyte present in a medium having a substantially cylindrical plug-in component and a sleeve-shaped outer component. The plug-in component has an optical component with a convex-shaped surface region for optimal flow, and the optical component at least partially consists of a material transparent to measuring radiation. On the surface region of the optical component is an analyte-sensitive matrix having at least one functional layer. The plug-in component and the sleeve-shaped component are designed such that the connecting region coming into contact with the medium is between the plug-in component and the sleeve-shaped outer component in the edge region of the optical component or is at a radial distance from the edge region of the optical component, and is sealed, without a gap, facing the medium.

The present invention relates to a system for measuring the hemoglobin concentration in whole blood, wherein the system comprises: a light-radiating unit including a light source that emits two types of incident light having different wavelengths; a diffusion unit which diffuses the incident light emitted by the light-radiating unit; a cuvette-holding unit which is formed so as to hold a cuvette including a blood sample; a detection unit which detects each absorbance of the two types of incident light having different wavelengths; a processing unit which determines the hemoglobin concentration in the blood by processing the measured absorbance result; and a control unit which regulates the two types of incident light having different wavelengths in order to repeatedly/sequentially radiate same. Although the system for measuring hemoglobin in whole blood of the present invention uses a small amount of whole blood, it is possible to measure the total hemoglobin concentration in an accurate and reliable manner. The system of the present invention aligns the paths of two types of incident light having different wavelengths passing through a microcuvette by using a diffuser plate so as to easily align a light source and increase the reliability of the results. Also, the system of the present invention uses two wavelengths so as to rapidly and accurately measure the total amount of hemoglobin, including oxidized and reduced hemoglobin.

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.

Embodiments as disclosed herein may provide a sensor system including a container, such as a bag, having a port assembly integrated therewith. The port assembly includes an optically transparent window and be configured such that a sensor may be mechanically attached to the port assembly to interface with the optical window. The sensor may include an index of refraction (IoR) sensor that measures the chemical concentration of a liquid inside the container based on a refractive index.

The present invention relates to a system for conducting the identification and quantification of micro-organisms, e.g., bacteria in biological samples. More particularly, the invention relates to a system comprising a disposable cartridge and an optical cup or cuvette having a tapered surface; wherein the walls are angled to allow for better coating and better striations of the light, an optics system including an optical reader and a thermal controller; an optical analyzer; a cooling system; and an improved spectrometer. The system may utilize the disposable cartridge in the sample processor and the optical cup or cuvette in the optical analyzer.

Apparatus and methods are described for determining a property of a bodily sample, using a microscope and optical-density-measurement apparatus. A sample carrier includes a microscopy sample chamber configured to receive a first portion of the sample and to facilitate imaging of the first portion of the sample by the microscope, and an optical-density-measurement chamber configured to receive a second portion of the sample, and to facilitate optical density measurements being performed by the optical-density-measurement apparatus upon the second portion of the sample. The sample carrier includes an upper surface and a lower surface. At least one of the upper surface and the lower surface of the sample carrier is defined by a glass sheet, and the other surface is defined by a molded component. Other applications are also described.

The present invention relates to a system for conducting the identification and quantification of micro-organisms, e.g., bacteria in biological samples. More particularly, the invention relates to a system comprising a disposable cartridge and an optical cup or cuvette having a tapered surface; wherein the walls are angled to allow for better coating and better striations of the light, an optics system including an optical reader and a thermal controller; an optical analyzer; a cooling system; and an improved spectrometer. The system may utilize the disposable cartridge in the sample processor and the optical cup or cuvette in the optical analyzer.

The invention relates to a modular absorption measuring system (1) for fluid media comprising a detection module (2) and a sample module (3), which comprises a sample chamber (14). The detection module (2) comprises a detection system (5), which also comprises an electromagnetic radiation source (8) and a quantum detector (9). The radiation source (8) is designed for supplying light in the direction of the sample chamber (14) and the quantum detector (9) is designed for receiving light from the sample chamber (14). The electromagnetic radiation source (8) is designed as an electroluminescence component and the detection module (2) and the sample module (3) are also designed to be arranged on top of one another.

A diagnostic system for analyzing an analyte is described. In an embodiment the diagnostic system includes a fluidic single-use disposable and a base cooperatively coupleable thereto. In an embodiment, the fluidic single-use disposable comprises a sample processing subcomponent configured to receive a sample and emit signal light if the sample comprises an analyte; a fluidic single-use disposable housing encompassing the sample processing subcomponent, the fluidic single-use disposable housing comprising: a first major side; and a fluidic single-use disposable viewing window disposed in the first major side and positioned to allow light emitted from the sample processing subcomponent to pass through the fluidic single-use disposable viewing window. In an embodiment, the base comprises a base housing comprising: a first major side shaped to cooperatively couple with the first major side of the fluidic single-use disposable housing.