The disclosure provides methods for resolving an inconclusive cytological assessment of clinically relevant cells in a sample obtained from a patient based on the cytological detection of an antibody binding to a diagnostic protein in the clinically relevant cells in the sample.

Provided herein are B7-H3 antibodies, fragments of such antibodies, and compositions comprising the same. The antibodies, antibody fragments and compositions are useful in a number of analytical methods, including immunohistochemical and immunocytochemical detection and analysis of B7-H3. Also provided herein are isolated peptides and fusion proteins containing immunogenic determinants for said B7-H3 antibodies, animals immunized with the peptides and fusion proteins, isolated B cells obtained from the animals, and hybridomas made from the isolated B cells.

The subject of the invention is a new compound of the following chemical formula:
ABZ.sup.1-Dap(O2(Cbz)).sup.2-Dap(O1).sup.3-Dap(O2).sup.4-Arg.sup.5-ANB.sup.6-NH.sub.2 where: ABZ stands for 2-aminobenzoic acid; DAP stands for diaminopropanoic acid (Dap) derivatives, modified by the functionalised residues of mono-ethylene or diethylene glycol (PEG); ANB stands for 5-amino-2-nitrobenzoic acid The subject of the invention is a method for producing the new compound and a pharmaceutical solution for cancer detection, which contains the above-mentioned compound. The subject of the invention is a method for cancer detection through the in vitro analysis of a human urine sample to which a new compound is added and blended with a buffer of pH 7-9. The subject of the invention is also a kit for detecting cancer, in particular bladder cancer, and the use of hydrolysis of the new compound in the position no. 5 by proteasome 20s for cancer detection, in particular bladder cancer.

The present invention provides a novel approach to cancer diagnosis and therapy of cancer by providing compositions and methods for the identification and specific targeting of the cancer stem cell populations present in a tumour to eradicate, or slow or prevent tumour (5) growth and spread, including the potential for tumour metastasis, by modulation of the Renin-Angiotensin System including, but not limited to, Renin Receptor, Angiotensin II Receptor (2) and a secreted form of the Renin Receptor.

The present invention relates to an in vitro method for the prognosis of the survival time of a patient suffering from a solid cancer, comprising the quantification of the cell density of follicular B cells present in tumor-induced lymphoid structures from said patient, wherein a high density of follicular B cells indicates that the patient has a favorable prognosis and a low density of follicular B cells indicates that the patient has a poor prognosis.

The present invention relates to biomarkers associated with CTCL, including TOX, PLS3, KIR3DL2, GATA3 and RUNX3, where increased expression, relative to normal control, of one or more of TOX, PLS3, KIR3DL2, and/or GATA3 is associated with CTCL and decreased expression of RUNX3, relative to normal control, is associated with CTCL. One or more of these biomarkers may be used to diagnose CTCL and/or design and monitor treatment.

The present invention provides therapeutic and diagnostic methods and compositions for cancer, for example, bladder cancer. The invention provides methods of treating bladder cancer, methods of determining whether a patient suffering from bladder cancer is likely to respond to treatment comprising a PD-L1 axis binding antagonist, methods of predicting responsiveness of a patient suffering from bladder cancer to treatment comprising a PD-L1 axis binding antagonist, and methods of selecting a therapy for a patient suffering from bladder cancer, based on expression levels of a biomarker of the invention (e.g., PD-L1 expression levels in tumor-infiltrating immune cells in a tumor sample obtained from the patient) and/or based on the determination of a tumor sample subtype.

The present invention relates to an in vitro method for the diagnosis and/or prognosis of non-haematological tumours by analysing circulating tumour cells isolated from a blood sample or a derivative thereof and to a kit for such purpose. The present invention further relates to a specific culture medium particularly effective for use in such method.

Methods are provided for the detection and treatment of cancers having a KRAS mutation, which KRAS mutation may drive tumorigenesis in the cancer. In some embodiments the KRAS.sup.+ cancer is a lung adenocarcinoma.

A transplantation method to increase the establishment rate of human tumors in immunodeficient mice. A pocket is created in the mouse and the tumor and surrounding tissues are implanted in the pocket. The pocket is left open to oxygenate the tumor and surrounding tissues.