Methods and compositions for treating a subject suffering from adrenocortical carcinoma and having excess cortisol are disclosed. The methods provide therapeutic benefits including reduction of ACC tumor load, restoration of T-cell and natural killer (NK) cell signaling pathways, increase in T-cell and NK cell infiltration into the ACC tumor, reduction of neutrophil infiltration into the ACC tumor in the patient, and other therapeutic benefits. The methods include administration of a glucocorticoid receptor modulator (GRM) (which may be a selective glucocorticoid receptor modulator (SGRM)) and an antibody checkpoint inhibitor. In embodiments, the GRM (e.g., a SGRM) is orally administered. The GRM may be a nonsteroidal compound comprising: a fused azadecalin structure; a heteroaryl ketone fused azadecalin structure; or an octahydro fused azadecalin structure.

Methods and compositions for treating a subject suffering from adrenocortical carcinoma and having excess cortisol are disclosed. The methods provide therapeutic benefits including reduction of ACC tumor load, restoration of T-cell and natural killer (NK) cell signaling pathways, increase in T-cell and NK cell infiltration into the ACC tumor, reduction of neutrophil infiltration into the ACC tumor in the patient, and other therapeutic benefits. The methods include administration of a glucocorticoid receptor modulator (GRM) (which may be a selective glucocorticoid receptor modulator (SGRM)) and an antibody checkpoint inhibitor. In embodiments, the GRM (e.g., a SGRM) is orally administered. The GRM may be a nonsteroidal compound comprising: a fused azadecalin structure; a heteroaryl ketone fused azadecalin structure; or an octahydro fused azadecalin structure.

Methods and compositions for treating a subject suffering from adrenocortical carcinoma and having excess cortisol are disclosed. The methods provide therapeutic benefits including reduction of ACC tumor load, restoration of T-cell and natural killer (NK) cell signaling pathways, increase in T-cell and NK cell infiltration into the ACC tumor, reduction of neutrophil infiltration into the ACC tumor in the patient, and other therapeutic benefits. The methods include administration of a glucocorticoid receptor modulator (GRM) (which may be a selective glucocorticoid receptor modulator (SGRM)) and an antibody checkpoint inhibitor. In embodiments, the GRM (e.g., a SGRM) is orally administered. The GRM may be a nonsteroidal compound comprising: a fused azadecalin structure; a heteroaryl ketone fused azadecalin structure; or an octahydro fused azadecalin structure.

The present disclosure relates to several embodiments of a stent. For example, the present disclosure describes a stent comprising a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; and particles selected from biocompatible amorphous particles, bioabsorbable amorphous particles, and combinations thereof.

The stent may also include a coating of a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; nanocapsules and a therapeutic agent encapsulated in the nanocapsules.

The stent disclosed herein enables the walls of an airway or blood vessel to be supported, while there is controlled delivery of the therapeutic agent to said airway or blood vessel to prevent, cure, alleviate or repair symptoms of disease.

The present disclosure relates to several embodiments of a stent. For example, the present disclosure describes a stent comprising a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; and particles selected from biocompatible amorphous particles, bioabsorbable amorphous particles, and combinations thereof.

The stent may also include a coating of a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; nanocapsules and a therapeutic agent encapsulated in the nanocapsules.

The stent disclosed herein enables the walls of an airway or blood vessel to be supported, while there is controlled delivery of the therapeutic agent to said airway or blood vessel to prevent, cure, alleviate or repair symptoms of disease.

The present invention in the field of cancer therapeutics is based on the finding that when cannabinoids are administered to cancer subjects after a chemotherapeutic agent has been administered, the combined treatment leads to increased survival prognosis, a reduction in disease progression, stabilisation of disease state and inhibition of tumour growth than administration of the chemotherapeutic agent alone. There is provided a pharmaceutical composition comprising a chemotherapeutic agent for use in the treatment of bladder, brain and spinal cord, colorectal, head and neck, lung, lymphoma, neuroendocrine, oesophageal, ovarian, pancreatic and prostate cancer, wherein said treatment comprises a first phase in which the chemotherapeutic agent is administered, and a subsequent second phase in which a cannabinoid is administered.

The present invention in the field of cancer therapeutics is based on the finding that when cannabinoids are administered to cancer subjects after a chemotherapeutic agent has been administered, the combined treatment leads to increased survival prognosis, a reduction in disease progression, stabilisation of disease state and inhibition of tumour growth than administration of the chemotherapeutic agent alone. There is provided a pharmaceutical composition comprising a chemotherapeutic agent for use in the treatment of bladder, brain and spinal cord, colorectal, head and neck, lung, lymphoma, neuroendocrine, oesophageal, ovarian, pancreatic and prostate cancer, wherein said treatment comprises a first phase in which the chemotherapeutic agent is administered, and a subsequent second phase in which a cannabinoid is administered.

The present invention in the field of cancer therapeutics is based on the finding that when cannabinoids are administered to cancer subjects after a chemotherapeutic agent has been administered, the combined treatment leads to increased survival prognosis, a reduction in disease progression, stabilisation of disease state and inhibition of tumour growth than administration of the chemotherapeutic agent alone. There is provided a pharmaceutical composition comprising a chemotherapeutic agent for use in the treatment of bladder, brain and spinal cord, colorectal, head and neck, lung, lymphoma, neuroendocrine, oesophageal, ovarian, pancreatic and prostate cancer, wherein said treatment comprises a first phase in which the chemotherapeutic agent is administered, and a subsequent second phase in which a cannabinoid is administered.

The present disclosure describes, in part, compositions and methods for treating pathologic pains associated with malignant growth disorders by administering a therapeutically effective amount of K+/Cl-cotransporter (Kcc2/KCC2) gene expression enhancer to a subject in need.

The present disclosure describes, in part, compositions and methods for treating pathologic pains associated with malignant growth disorders by administering a therapeutically effective amount of K+/Cl-cotransporter (Kcc2/KCC2) gene expression enhancer to a subject in need.