Methods of identifying a compound, such as a test compound, and applications thereof are provided. For example, methods of identifying a compound that preferentially affects, increases, or decreases a level of association of a macromolecule with one or more target condensates or methods of identifying a compound that preferentially causes a macromolecule to associate or disassociate with one or more target condensates are provided. Additionally, methods of designing and/or identifying and/or making a compound, or portion thereof, with a desired characteristic are provided.

The present disclosure provides in vitro methods for determining the potency of a cell-based therapy or treatment. In alternative embodiments, provided are compositions, including products of manufacture and kits, and methods, comprising (or comprising use of) quantitative in vitro assays for determining the potency of cell-based therapies or treatments, including those used in the treatment of retinal degeneration.

The present invention relates to compositions, methods, and kits for predicting a subject's response to a CAR T cell therapy, by analyzing the intestinal microbiome of the subject. The present disclosure also provides a method of detecting patients at risk for a poor response to CAR T cell therapy by measuring the level of the presently disclosed bacteria or bacterial genes in the microflora or microbiome of a patient receiving or considered for CAR T cell therapy. The present disclosure further provides therapeutic compositions and methods for treating a subject having a cancer, by improving the subject's response to a CAR T cell therapy.

Provided herein are methods for detecting an estrogen-induced cancer in a subject, for identifying a subject at risk of developing an estrogen-induced cancer and for determining or predicting prognosis for a subject with an estrogen-induced cancer. The methods of the disclosure comprise determining the level of expression of ALPPL2 in a biological sample, typically a blood sample, obtained from a subject.

A method that is capable of stably preserving hemoglobin in a solution. A method for stabilizing hemoglobin in a solution includes causing at least one of acetylacetone or uric acid to coexist in the solution containing hemoglobin.

A sealed bag containing a reference fluid for the calibration and/or quality control of a creatine and/or creatinine sensor, the bag comprising: an inner polymer layer and an outer polymer layer; and an aluminium oxide gas barrier layer there between; and wherein the inner polymer layer is in contact with the reference fluid.

Improved methods for treating cancer are provided herein by determining if a cancer patient, particularly a colon cancer patient or a gastric cancer patient, will clinically respond in a favorable manner to a therapeutic strategy comprising the FOLFOX regimen (fluorouracil, leucovorin, and oxaliplatin) or a combination of capecitabine and cisplatin. Diagnostic methods for measuring the OPRT, TYMP, and/or UCK2 proteins in a tissue sample, such as a tumor sample, from the patient are provided.

Provided are methods for determining the amount of thyroglobulin in a sample using various purification steps followed by mass spectrometry. The methods generally involve purifying thyroglobulin in a test sample, digesting thyroglobulin to form peptide T129, purifying peptide T129, ionizing peptide T129, detecting the amount of peptide T129 ion generated, and relating the amount of peptide T129 ion to the amount of thyroglobulin originally present in the sample.

A method of distinguishing a control solution from a sample in an electrochemical test sensor is performed. The method includes adding a control marker to the control solution. The control solution includes the control marker and analyte. The test sensor includes working and counter electrodes, and a reagent. A potential is applied to the test sensor to oxidize the control marker and the analyte. The resulting electrical current is measured. A potential is applied to the test sensor lower than the other potential in which the potential is sufficient to oxidize the analyte and not the control marker. The resulting electrical current is measured. Determining whether a control solution or a sample is present based on the measured electrical currents. To increase the measured current, a salt may be added to the control solution in an amount sufficient to increase the electrical current by at least 5% as compared to a control solution in the absence of a salt.

The present invention provides novel compositions and methods for creating quantitative standards to calibrate analytes. These compositions and methods enable the creation of standards and calibrators for analyzing analytes and measuring clinical biomarkers. Also provided are kits comprising the novel compositions for use in assays, for example sandwich immunoassays.