Disclosed is a calibration curve creation method performed by an analyzer, the calibration curve creation method including: preparing a plurality of calibrators at different dilution rates by dispensing a calibrator in a container into one or more different containers; obtaining a plurality of measurement values by measuring each of the prepared plurality of calibrators; creating a calibration curve by use of the plurality of measurement values; selecting a first measurement value to be re-measured, among the plurality of measurement values used for the calibration curve; preparing another calibrator at a dilution rate corresponding to a calibrator from which the selected first measurement value is obtained; obtaining a second measurement value by measuring the prepared another calibrator; and creating a new calibration curve by replacing the first measurement value, among the plurality of measurement values, with the second measurement value.

Techniques for colorimetric based test strip analysis and reader system are provided. In one aspect, a method of test strip analysis includes: illuminating a test strip wetted with a sample with select spectrums of light, wherein the test strip includes test pads that are configured to change color in the presence of an analyte in the sample; obtaining at least one digital image of the test strip; and analyzing color intensity from the at least one digital image against calibration curves to determine an analyte concentration in the sample with correction for one or more interference substances in the sample that affect the color intensity. A calibration method and a reader device are also provided.

Apparatuses, methods, and software products for analyzing liquids dispensed from a chemical dispensing system. Beams of light having different wavelengths are passed through a liquid dispensed by the dispensing system. The intensity of each beam of light is measured after passing through the liquid. A transmission coefficient is determined by comparing the intensity of the beam of light to a calibration parameter obtained by passing the beam of light through an unadulterated diluent. The transmission coefficients for the beams of light are then compared to corresponding transmission coefficients obtained for one or more known reference solutions to determine one or more characteristics of the liquid being dispensed from the chemical dispensing system.

Disclosed herein is a method for improving the precision of a test result from an instrument with an optical system that detects a signal. The method comprises including in the instrument a normalization target disposed directly or indirectly in the optical path of the optical system. Also disclosed are instruments comprising a normalization target, and systems comprising such an instrument and a test device that receives a sample suspected of containing an analyte.

A method to correct signal light intensities measured by a detector of a detection unit in a laboratory instrument is presented. The detection unit comprises a light source, a sample plane comprising a sample holder configured to hold at least one sample vessel comprising a test sample to be illuminated, a reference light sensor, and the detector. Based on a basic light intensity of a newly manufactured light source and an initial light intensity measured by the reference light sensor the sensitivity of the reference light sensor can be determined. And signal light intensities measured by the detector can be corrected based on the determined sensitivity and subsequently measured reference light intensities of the reference light sensor in order to generate comparable test results.

Described are various embodiments of a dynamic Raman signal acquisition system, method and apparatus. In one embodiment, a Raman system comprises: an excitation light source operable at a designated irradiation power and for a designated acquisition time for each Raman data acquisition; a Raman probe operatively associated with said excitation light source to irradiate the biological tissue at said designated irradiation power and for said designated acquisition time, and capture an optical Raman response therefrom; a spectrometer operable to spectrally analyze said optical Raman response; and a controller in operative communication with said excitation light source and said spectrometer to automatically adjust at least one signal acquisition parameter.

One or more techniques and/or systems are provided for waste object detection. For example, a waste alert component is configured to emit ultraviolet light towards a waste detection zone, such as a bathroom floor or countertop. If a waste object, such as a paper towel or other object with a fluoresce property, exists within the waste detection zone, then the waste alert component may detect an increase in light due to the waste object fluorescing visible light in response to the ultraviolet light. If the increase in light intensity exceeds a detection threshold, then the waste alert component may provide a waste detection alert that the waste object exists within the waste detection zone (e.g., a message may be sent to a housekeeper that paper towel waste in on the bathroom countertop).

Techniques for colorimetric based test strip analysis and reader system are provided. In one aspect, a method of test strip analysis includes: illuminating a test strip wetted with a sample with select spectrums of light, wherein the test strip includes test pads that are configured to change color in the presence of an analyte in the sample; obtaining at least one digital image of the test strip; and analyzing color intensity from the at least one digital image against calibration curves to determine an analyte concentration in the sample with correction for one or more interference substances in the sample that affect the color intensity. A calibration method and a reader device are also provided.

Disclosed is a calibration curve creation method performed by an analyzer, the calibration curve creation method including: preparing a plurality of calibrators at different dilution rates by dispensing a calibrator in a container into one or more different containers; obtaining a plurality of measurement values by measuring each of the prepared plurality of calibrators; creating a calibration curve by use of the plurality of measurement values; selecting a first measurement value to be re-measured, among the plurality of measurement values used for the calibration curve; preparing another calibrator at a dilution rate corresponding to a calibrator from which the selected first measurement value is obtained; obtaining a second measurement value by measuring the prepared another calibrator; and creating a new calibration curve by replacing the first measurement value, among the plurality of measurement values, with the second measurement value.

The present invention relates to an optical system for triglyceride inspection partially integrated into a toilet seat and comprising a plurality of optical sensor modules and a controlling and processing module, wherein each said optical sensor module comprises a first light source, a second light source and an optical sensor. The optical sensor receives light signals generated by the first and second light sources respectively on the skin of the person (especially the skin of the thighs) to be tested and thereby generates a sensing signal of an adaptive calibration function. The sensing signal is then converted by the controlling and processing module into an inspection value of triglyceride, which is transmitted to a display unit. With the above optical system for triglyceride inspection, triglycerides can be inspected automatically without invasive blood sampling, making the system a convenient home health monitoring device.