An objective of the present invention is to provide non-human animal models of cancer pathology, which mimic the hierarchical organization, cancer progression process, or biological property of human cancer tissues, and uses thereof. To achieve the objective described above, first, the present inventors transplanted cells of NOG-established cancer lines into NOG mice and morphologically observed the resulting tissue organization. As a result, the non-human animal models were demonstrated to exhibit pathologies (the hierarchical organization, cancer progression process, or biological properties of the cancer cells) similar to that of human cancer. Specifically, the present inventors succeeded in preparing non-human animal models exhibiting pathologies more similar to a human cancer, and cell culture systems using NOG-established cancer cell lines where the in vitro cell morphology is more similar to that of human cancer.

The present invention relates to a chemical compound comprising (i) a polycationic polymer, coupled to (ii) a dye. The present invention further relates to a method for visualizing a glycosamine-containing structure in a biological sample comprising a) contacting an inner lumen of said biological sample with a dye-conjugated polycationic polymer, preferably with the chemical compound according to the present invention; b) tissue-clearing said biological sample; and, thereby, c) visualizing an internal glycosamine-containing structure in said biological sample. The present invention also relates to a method for determining the number and/or size of glomeruli in a kidney or a sample thereof making use of the method for visualizing a glycosamine-containing structure; and also relates to kits and uses related to said chemical compounds and said methods.

Disclosed is the use of a DKK1 gene or the coded protein inhibitor thereof for the preparation of a composition or formulation used to prevent and/or treat tumor cachexia and diseases associated with diabetes. By inhibiting the expression or activity of the DKK1 gene or the protein encoded thereby in tumor cells, which can effectively prevent and/or treat tumor cachexia and diseases associated with diabetes, also provided is a method for detecting the protein expression level of DKK1 in blood, which level is taken as an indicator for precise treatment and judging prognosis.

The present disclosure provides methods of evaluating a therapeutic agent for cancer, and methods of cancer treatment.

A method for transparentizing biological tissue in a living state, which comprises applying a solution to the biological tissue, the solution containing one or more compounds selected from the group consisting of a nucleotide, a nucleotide derivative, a macromolecule containing a nucleotide or a nucleotide derivative, and a nucleotide polymer; a composition for transparentizing biological tissue in a living state, which comprises the aforementioned compound; and a kit for transparentizing biological tissue in a living state, which comprises the aforementioned compound.

The present disclosure provides a newly-identified transitional cell state in alveolar regeneration, models to ablate lung alveolar type-1 cells that leads to lung fibrosis and emphysema, a scalable, an ex vivo lung fibrosis model that uses co-cultured lung fibroblasts and pre-alveolar type-1 transitional cell state (PATS) for the use of disease modeling and drug screening, and methods of using same.

The present invention relates to agents and methods for treating gastrointestinal cancer (e.g., metastatic colorectal cancer) in a subject in need thereof. The method includes suppressing the enzymatic activity of DHODH and/or decreasing the level of creatine via suppression of creatine transporter channel SLC6a8 in the subject. In some embodiments, the suppression step can be carried out by administering to the subject a set of small molecule compounds.

The present invention provides method for monitoring physiological status of an organ in a subject by monitoring morphological changes over time in transplanted tissue on an eye of the subject.

A method of treating a patient who has hepatocellular carcinoma (HCC), colorectal carcinoma (CRC), glioblastoma (GB), gastric cancer (GC), esophageal cancer, NSCLC, pancreatic cancer (PC), renal cell carcinoma (RCC), benign prostate hyperplasia (BPH), prostate cancer (PCA), ovarian cancer (OC), melanoma, breast cancer (BRCA), CLL, Merkel cell carcinoma (MCC), SCLC, Non-Hodgkin lymphoma (NHL), AML, gallbladder cancer and cholangiocarcinoma (GBC, CCC), urinary bladder cancer (UBC), and uterine cancer (UEC) includes administering to said patient a composition containing a population of activated T cells that selectively recognize cells in the patient that aberrantly express a peptide. A pharmaceutical composition contains activated T cells that selectively recognize cells in a patient that aberrantly express a peptide, and a pharmaceutically acceptable carrier, in which the T cells bind to the peptide in a complex with an MHC class I molecule, and the composition is for treating the patient who has HCC, CRC, GB, GC, esophageal cancer, NSCLC, PC, RCC, BPH, PCA, OC, melanoma, BRCA, CLL, MCC, SCLC, NHL, AML, GBC, CCC, UBC, and/or UEC. A method of treating a patient who has HCC, CRC, GB, GC, esophageal cancer, NSCLC, PC, RCC, BPH, PCA, OC, melanoma, BRCA, CLL, MCC, SCLC, NHL, AML, GBC, CCC, UBC, and/or UEC includes administering to said patient a composition comprising a peptide in the form of a pharmaceutically acceptable salt, thereby inducing a T-cell response to the HCC, CRC, GB, GC, esophageal cancer, NSCLC, PC, RCC, BPH, PCA, OC, melanoma, BRCA, CLL, MCC, SCLC, NHL, AML, GBC, CCC, UBC, and/or UEC.

A 3D microfluidic device for use as an in vitro lymph node is described. The microfluidic device has a body with a semi-circular inner wall and a first channel located adjacent along the semi-circular inner wall, the first channel corresponding to a subcapsular sinus region of a lymph node, a second channel located adjacent the first channel, the second channel corresponding to a reticular network, and a bottom cavity and top cavity, centrally located, corresponding to a paracortex and follicle of a lymph node, respectively. The various compartments of the device are separated by circumferentially and horizontally located rows of micro-pillars. A lab-on-a-chip device incorporating the microfluidic device is also described.