An antibiotic susceptibility testing device of gram-negative bacteria, as well as a corresponding method, are discussed. The device has a temperature control unit (including a constant temperature chamber) and a contactless conductivity-based measurement system. Disposable glassy or PVC tubes are used as test vessels for AST. In the performance of AST assay, appropriate kind of liquid medium containing identical amount of target bacterial cells and target antibiotics at different concentrations are loaded into test tubes, following by incubation in the device at a setup temperature. The bacterial growth profile is monitored by collecting the differential values (ΔC) of conductivity of liquid medium, which depend on the proliferation of viable cells. Outcome of ΔC indicates whether the target bacterial cells are completely inhibited by the test antibiotic or not, enabling the user to judge the value of the minimal inhibitory concentration (MIC) simply.

An antibiotic susceptibility testing device of gram-negative bacteria, as well as a corresponding method, are discussed. The device has a temperature control unit (including a constant temperature chamber) and a contactless conductivity-based measurement system. Disposable glassy or PVC tubes are used as test vessels for AST. In the performance of AST assay, appropriate kind of liquid medium containing identical amount of target bacterial cells and target antibiotics at different concentrations are loaded into test tubes, following by incubation in the device at a setup temperature. The bacterial growth profile is monitored by collecting the differential values (ΔC) of conductivity of liquid medium, which depend on the proliferation of viable cells. Outcome of ΔC indicates whether the target bacterial cells are completely inhibited by the test antibiotic or not, enabling the user to judge the value of the minimal inhibitory concentration (MIC) simply.

Disclosed are methods of identifying pathogens and determining their antimicrobial susceptibility. The methods comprise detecting biomarkers in a test sample, locating the sample in a phylogenetic tree based on biomarker information, obtaining drug susceptibility prediction rules based on the phylogenetic tree positioning of the sample, and determining the drug susceptibility of a pathogen according to the prediction rules. Further disclosed are an application of the phylogenetic tree in the preparation of pathogen identification and/or drug susceptibility diagnostic product, and a pathogen identification and drug susceptibility diagnostic kit.

Disclosed are methods of identifying pathogens and determining their antimicrobial susceptibility. The methods comprise detecting biomarkers in a test sample, locating the sample in a phylogenetic tree based on biomarker information, obtaining drug susceptibility prediction rules based on the phylogenetic tree positioning of the sample, and determining the drug susceptibility of a pathogen according to the prediction rules. Further disclosed are an application of the phylogenetic tree in the preparation of pathogen identification and/or drug susceptibility diagnostic product, and a pathogen identification and drug susceptibility diagnostic kit.

A method for assessing an assessment target according to an embodiment includes: a step of acquiring statistical information based on at least one color feature quantity with respect to each of a plurality of assessment regions in a plate image corresponding to an image of an assessment plate that holds an assessment target in a plurality of wells provided in the plate; and a step of determining a color of the plurality of assessment regions by using the statistical information. The assessment target includes a tester, the plurality of wells include a test substance well holding the assessment target that further includes a test substance, the plate image includes a plurality of well images corresponding to the plurality of wells, and each of the plurality of assessment regions includes at least one well image corresponding to at least one of the wells.

An apparatus for in-situ monitoring and measuring of general corrosion and localized microbiologically influenced corrosion (MIC) in a simulated environment is provided. The apparatus includes a chamber containing an electrolyte solution and a microbe specimen. The chamber includes a pair of electrical resistance (ER) probes that measure a current flowing through the electrolyte solution and a general corrosion rate on the surface of the ER probes. The chamber also includes a pair of electrochemical noise (EN) probes. The EN probes are aligned to face one another such that the EN probes measure a localized corrosion rate on the surface of the EN probes and measure the influence of gravity on MIC. The apparatus measures the general and localized corrosion rates simultaneously without polarizing the surface of the ER and EN probes.

An apparatus for in-situ monitoring and measuring of general corrosion and localized microbiologically influenced corrosion (MIC) in a simulated environment is provided. The apparatus includes a chamber containing an electrolyte solution and a microbe specimen. The chamber includes a pair of electrical resistance (ER) probes that measure a current flowing through the electrolyte solution and a general corrosion rate on the surface of the ER probes. The chamber also includes a pair of electrochemical noise (EN) probes. The EN probes are aligned to face one another such that the EN probes measure a localized corrosion rate on the surface of the EN probes and measure the influence of gravity on MIC. The apparatus measures the general and localized corrosion rates simultaneously without polarizing the surface of the ER and EN probes.

A method of spectrometric analysis comprises obtaining one or more sample spectra for an aerosol, smoke or vapour sample. The one or more sample spectra are subjected to pre-processing and then multivariate and/or library based analysis so as to classify the aerosol, smoke or vapour sample. The results of the analysis are used for various surgical or non-surgical applications.

A method of spectrometric analysis comprises obtaining one or more sample spectra for an aerosol, smoke or vapour sample. The one or more sample spectra are subjected to pre-processing and then multivariate and/or library based analysis so as to classify the aerosol, smoke or vapour sample. The results of the analysis are used for various surgical or non-surgical applications.

A method for detecting and characterizing a microorganism in a clinical sample includes introducing a clinical sample to a first culture vessel containing the culture medium; removing a test aliquot; separating DNA from the test aliquot; and performing nucleic acid tests on the DNA to identify the microorganism and to detect the presence or absence of one or more genetic antimicrobial resistance markers in the microorganism. If a microorganism is identified, an antimicrobial susceptibility test is performed wherein microbial growth in the antimicrobial susceptibility test is monitored by accessing growth or markers for growth and wherein the type and concentration of antimicrobial agents used in the antimicrobial susceptibility test is determined by the identity of the microorganism and the antimicrobial resistance markers detected. A device for performing the method is also provided.