The invention described herein provides biological markers for the diagnosis, prognosis, and monitoring of prostate cancer

A method of screening a cereblon modifying compound for treating a disease or disorder, comprising: obtaining a sample; determining a first protein level of SALL4; administering the cereblon modifying compound to the sample; determining a second protein level of SALL4; comparing the first level and the second protein level of SALL4 to determine if the cereblon modifying compound induces degradation of SALL4; and selecting the cereblon modifying compound that does not induce degradation of SALL4.

Objects of the present invention are to find a marker by which progression of arteriosclerosis can be directly grasped, to thereby provide motivation for prevention or treatment of arteriosclerosis itself, and to provide means for accurately grasping condition of arteriosclerosis-related disease including arteriosclerotic disease. The invention provides a method for acquiring data on progression of arteriosclerosis, the method including determining a level of an antibody against SH3BP5 protein or a part thereof in a body fluid sample collected from a biological body, and a data acquisition kit for performing the data acquisition method.

The present application relates to a marker gene for detecting the proliferative ability of stem cells and uses thereof, and provides a marker detection composition for detecting the proliferative ability of stem cells, a kit for detecting the proliferative ability of stem cells, and a composition for improving the proliferative ability of stem cells, etc. According to the composition or method according to an aspect, stem cells having a high proliferative ability may be easily selected, and the proliferative ability of stern cells may be significantly improved.

A method of screening a cereblon modifying compound for treating a disease or disorder, comprising: obtaining a sample; determining a first protein level of SALL4; administering the cereblon modifying compound to the sample; determining a second protein level of SALL4; comparing the first level and the second protein level of SALL4 to determine if the cereblon modifying compound induces degradation of SALL4; and selecting the cereblon modifying compound that does not induce degradation of SALL4.

This invention is in the field of medical devices. Specifically, the present invention provides portable medical devices that allow real-time detection of analytes from a biological fluid. The methods and devices are particularly useful for providing point-of-care testing for a variety of medical applications.

A method for diagnosing a disease can include detecting, in a sample from a patient, an autoantibody binding to Septin-7. A polypeptide comprising Septin-7 or a variant thereof can be used for the diagnosis of a disease. Preferably, the polypeptide is used to detect an autoantibody binding to Septin-7 in a sample. A kit is useful for the diagnosis of a disease. The kit may include a polypeptide that includes Septin-7 or a variant thereof or a medical device that includes a polypeptide that includes Septin-7 or a variant thereof and an autoantibody to Septin-7.

Provided is an isolated TrkB agonist antibody that binds to an epitope contained in one of the extracellular domains of TrkB and is capable of activating TrkB, wherein the extracellular domains comprises extracellular D1, D2, D3, D4, D5 domains and juxtamembrane domain of TrkB. Methods of using the TrkB agonist antibody in treating or reducing the risk of a TrkB associated conditions in a subject, wherein said condition is selected from cell differentiation, synaptic development, neural injury repairing and/or neurite branching.

The present disclosure relates to use of GDF-15 as a safety biomarker for determining a toxicological effect of a Mdm2 inhibitor; an ex vivo method for determining a toxicological effect of a Mdm2 inhibitor in a subject, in particular for determining a likelihood of developing thrombocytopenia in a subject in response to administration of a dose of a Mdm2 inhibitor; methods of using a Mdm2 inhibitor in the treatment of cancer in a subject; a kit for use in predicting the likelihood that a patient having cancer will develop thrombocytopenia in response to a treatment with a dose of a Mdm2 inhibitor; a kit for use in treating a patient having cancer and related disclosure embodiments.

The present disclosure relates to use of GDF-15 as a safety biomarker for determining a toxicological effect of a Mdm2 inhibitor; an ex vivo method for determining a toxicological effect of a Mdm2 inhibitor in a subject, in particular for determining a likelihood of developing thrombocytopenia in a subject in response to administration of a dose of a Mdm2 inhibitor; methods of using a Mdm2 inhibitor in the treatment of cancer in a subject; a kit for use in predicting the likelihood that a patient having cancer will develop thrombocytopenia in response to a treatment with a dose of a Mdm2 inhibitor; a kit for use in treating a patient having cancer and related disclosure embodiments.