Treatment of multiple myeloma with a combination of panobinostat and bortezomib at specified doses adjusted for safety.

The present disclosure relates to a method of assessing the effectiveness of a treatment with lanifibranor in a patient with a liver disease, the method comprising: a) in vitro measuring levels of a combination of biomarkers consisting of CK18M65, hyaluronic acid, fructosamine and ALT in a biological sample from the patient; b) assessing the effectiveness of the treatment with lanifibranor as a function of the levels measured in step a).

There is provided a method and materials pertaining to assays, for example immunoassays, for biomarkers in body fluids e.g. blood. Diagnostic or screening methods for infections, and methods of differentiating between infectious and non-infectious conditions in mammals, particularly equines, for monitoring response to anti-infective/antibiotic therapy are provided. A test fluid collection system adapted to permit dilution and analysis of the collected test fluid and an assay and device for monitoring exertional rhabdomyolysis in equines is also provided.

Disclosed herein are methods and compositions to predict a response of a subject to a nutrient modulation therapy. Restricting the uptake of at least one amino acid by cancer cells can be used to treat or delay cancer. In some embodiments, the nutrition modulation therapy is a dietary product that is substantially devoid of at least one amino acid.

The present invention concerns the field of diagnostics. Specifically, it relates to a method for assessing a subject with suspected infection comprising the steps of determining the amount of a first biomarker in a sample of the subject, said first biomarker being MR-proADM, determining the amount of a second biomarker in a sample of the subject, wherein said second biomarker is selected from the group consisting of: sFlt-1, GDF15 and ESM1, comparing the amounts of the biomarkers to references for said biomarkers and/or calculating a score for assessing the subject with suspected infection based on the amounts of the biomarkers, and assessing said subject based on the comparison and/or the calculation. The invention also relates to the use of a first biomarker being MR-proADM and a second biomarker selected from the group consisting of: sFlt-1, GDF15 and ESM1, or a detection agent specifically binding to said first biomarker and a detection agent specifically binding to said second biomarker for assessing a subject with suspected infection. Moreover, the invention further relates to a computer-implemented method for assessing a subject with suspected infection and a device and a kit for assessing a subject with suspected infection.

The present invention provides systems, devices, and methods for point-of-care and/or distributed testing services. The methods and devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device can be modified to allow for more flexible and robust use with the disclosed methods for a variety of medical, laboratory, and other applications. The systems, devices, and methods of the present invention can allow for effective use of samples by improved sample preparation and analysis.

A device is disclosed for conducting a non-invasive analysis of a bodily fluid to determine the presence and level of a certain constituent carried by the bodily fluid. An indicator formulation of the device changes color in response to exposure to the constituent to provide a visible indication of the presence and level of the constituent carried by the bodily fluid. A carrier substrate of the device is constructed of a material having voids providing a high void volume within the substrate. The device is made by applying a chromagen to the carrier substrate to create a chromagen-laden carrier member. Then, a selected reagent having a particular constituent-specific formulation is applied to the chromagen-laden member. The selected reagent then combines with the chromagen thereby establishing the indicator formulation within the carrier substrate in place for reception of a sample of the bodily fluid.

The present disclosure relates to acetaminophen protein adducts and methods of diagnosing acetaminophen toxicity using the acetaminophen protein adducts. The present disclosure provides acetaminophen (APAP)-protein adducts and methods of detecting acetaminophen-induced toxicity in a subject using APAP-protein adducts. One aspect of the present disclosure provides an APAP-protein adduct for diagnosing acetaminophen-induced toxicity. According to the present disclosure, the inventors have identified proteins that are modified by N-acetyl-pbenzoquinoneimine (NAPQI) in subjects with acetaminophen-induced toxicity. Non-limiting examples of proteins modified by NAPQI include betaine-homocysteine 5-methyltransferase 1, cytoplasmic aspartate aminotransferase, 1,4-alpha-glucan branching enzyme, formimidoyltransferase-cyclodeaminase, and dystrophin.

The present invention provides systems, devices, and methods for point-of-care and/or distributed testing services. The methods and devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device can be modified to allow for more flexible and robust use with the disclosed methods for a variety of medical, laboratory, and other applications. The systems, devices, and methods of the present invention can allow for effective use of samples by improved sample preparation and analysis.

A device is disclosed for conducting a non-invasive analysis of a bodily fluid to determine the presence and level of a certain constituent carried by the bodily fluid. An indicator formulation of the device changes color in response to exposure to the constituent to provide a visible indication of the presence and level of the constituent carried by the bodily fluid. A carrier substrate of the device is constructed of a material having voids providing a high void volume within the substrate. The device is made by applying a chromagen to the carrier substrate to create a chromagen-laden carrier member. Then, a selected reagent having a particular constituent-specific formulation is applied to the chromagen-laden member. The selected reagent then combines with the chromagen thereby establishing the indicator formulation within the carrier substrate in place for reception of a sample of the bodily fluid.