The disclosed technology relates to chemical entities for the detection of wounds, e.g., chronic wounds or infected wounds, including compositions, substrates, kits, dressing materials, and articles, and systems containing such compounds. The disclosed technology further relates to methods of using these compositions, kits and systems in diagnostic assays, and in the diagnosis and/or detection of chronic or infected wounds based on enzymatic action on specific moieties and/or reaction sites. Additional disclosure relates to methods of characterizing wounds based on expression of a plurality of markers and using such information to treat, manage, and follow-up patients suffering from chronic or infected wounds.

The present invention identifies AKR1C1 as the first lipedema-associated gene. The invention provides methods for diagnosing or assessing an individual's susceptibility to lipedema by the analysis of the AKR1C1 gene or the expression levels of its product and related metabolites. Also provided are therapeutic methods for treating a patient or methods for prophylactically treating an individual susceptible to lipedema.

Methods of treating patients diagnosed with AML or MDS harboring mutant IDH-1 include detecting an IDH1 mutation and the therapeutic administration of an inhibitor of a mutant IDH-1 as a single agent, or in combination with azacitidine (AZA) or cytarabine.

Microbes expressing cholesterol oxidoreductase (COR) proteins, methods of engineering the microbes expressing COR proteins, compositions and methods of using the microbes are provided.

Provided is a compound having the structure: (SIG)-(SI-MOD).sub.m
where SIG is a signaling molecule, SI is a self-immolative structure bound to SIG such that SIG has a reduced signal relative to the signal of SIG without SI, MOD is a moiety bound to SI that is subject to modification by an activator, and m is an integer from 1 to about 10. When MOD is modified by an activator, SI is destabilized and self-cleaved from SIG such that SIG generates an increased signal. Also provided are methods of determining whether a sample, such as a cell, comprises an activator, such as a nitroreducase, using the compound. Further provided are methods of determining whether a mammalian cell is hypoxic using the compound where nitroreductase is the activator. A method of detecting a microorganism that comprises a nitroreductase using the compound where nitroreductase is the activator is also provided.

A CMOS-based chip having multiple sensing modalities that are able independently to detect multiple metabolites present in a sample. In particular, the chip provides multiple sensing modalities capable of performing detection within the same physical test volume, i.e. the chip can simultaneously detect a plurality of chemical reactions occurring in the test volume, where each chemical reaction yields a result that is independently detectable. The chip may comprise an optical sensor (e.g. photodiode) and a chemical sensor (e.g. pH sensor, embodied as an ISFET). With this technique, multiple metabolites may be measured in real time using a small scale point-of-care device.

Provided is a technique of predicting prognosis of skin cancer. A method for prognosis prediction of skin cancer includes: a step of obtaining a correlation amount correlated with an expression level of a glucose-6-phosphate dehydrogenase in a sample collected from a patient with the skin cancer; and a step of determining that the prognosis of the skin cancer is poorer when the correlation amount is large than that when the correlation amount is small.

Provided herein are methods of identifying a marker for a biological interaction, the method comprising: quantifying genome-wide RNA expression in cells; exposing the cells to a perturbagen for a period of time sufficient to induce the biological interaction in the cells, wherein the induced biological interaction comprises inducing changes in RNA expression in the cells that are exposed to the perturbagen; quantifying genome-wide nascent RNA expression in the cells that were exposed to the perturbagen; calculating a difference in the genome-wide nascent RNA expression between (i) the genome-wide RNA expression in the cells absent the perturbagen and (ii) the genome-wide nascent RNA expression in the cells that were exposed to the perturbagen; and identifying the marker using the calculated difference in the genome-wide nascent RNA expression.

Provided is a compound comprising the structure:

(SIG)-(SI-MOD).sub.m.

In this compound, SIG is a signaling molecule, SI is a self-immolative structure bound to SIG such that SIG has a reduced signal relative to the signal of SIG without SI, MOD is a moiety bound to SI that is subject to modification by an activator, and m is an integer from 1 to about 10. With this compound, when MOD is modified by an activator, SI is destabilized and self-cleaved from SIG such that SIG generates an increased signal. Also provided is a method of determining whether a sample comprises an activator, using the above-described compound. Additionally provided is a method of determining whether a cell comprises a nitroreductase using the above-described compound where nitroreductase is the activator. Further provided is a method of determining whether a mammalian cell is hypoxic using the above-described compound where nitroreductase is the activator. A method of detecting a microorganism that comprises a nitroreductase, using the above-described compound where nitroreductase is the activator, is also provided. Also provided is a method of identifying nitroreductase in a sample, using the above-described compound where nitroreductase is the activator.

A system for the electrochemical detection of triglyceride levels includes a test strip including an electrode and a counter electrode, the electrode and counter electrode located proximate to a sample reception area; and a coating on one of the electrode and counter electrode, the coating including a reagent coating for triglycerides.