The present invention relates to a compound of the following formula (I): (I) or a pharmaceutically acceptable salt and/or solvate thereof, notably for use as a drug, in particular in the treatment of cancer. The present invention also relates to a pharmaceutical composition comprising such a compound and to a method for the preparation of such a compound.

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Provided herein are methods for the treatment of brain metastasis by administering a kinase inhibitor targeted to a metastasis-promoting kinase identified by an in vivo kinase screen.

Provided herein are methods for the treatment of brain metastasis by administering a kinase inhibitor targeted to a metastasis-promoting kinase identified by an in vivo kinase screen.

The present invention generally relates to treatment of iron-related conditions with iron carbohydrate complexes. One aspect of the invention is a method of treatment of iron-related conditions with a single unit dosage of at least about 0.6 grams of elemental iron via an iron carbohydrate complex. The method generally employs iron carbohydrate complexes with nearly neutral pH, physiological osmolarity, and stable and non-immunogenic carbohydrate components so as to rapidly administer high single unit doses of iron intravenously to patients in need thereof.

The present invention generally relates to treatment of iron-related conditions with iron carbohydrate complexes. One aspect of the invention is a method of treatment of iron-related conditions with a single unit dosage of at least about 0.6 grams of elemental iron via an iron carbohydrate complex. The method generally employs iron carbohydrate complexes with nearly neutral pH, physiological osmolarity, and stable and non-immunogenic carbohydrate components so as to rapidly administer high single unit doses of iron intravenously to patients in need thereof.

An anti-myeloid-derived suppressor cells agent (“anti-MDSCs agent”) and a bacteriochlorophyll derivative (hereinafter “Bchl-D) for use in combination therapy for cancer, wherein the anti-MDSC agent and the Bchl-D are administered sequentially and the administration of the Bchl-D is followed by photodynamic therapy (PDT) or vascular targeted PDT (VTP).

An anti-myeloid-derived suppressor cells agent (“anti-MDSCs agent”) and a bacteriochlorophyll derivative (hereinafter “Bchl-D) for use in combination therapy for cancer, wherein the anti-MDSC agent and the Bchl-D are administered sequentially and the administration of the Bchl-D is followed by photodynamic therapy (PDT) or vascular targeted PDT (VTP).

An anti-myeloid-derived suppressor cells agent (“anti-MDSCs agent”) and a bacteriochlorophyll derivative (hereinafter “Bchl-D) for use in combination therapy for cancer, wherein the anti-MDSC agent and the Bchl-D are administered sequentially and the administration of the Bchl-D is followed by photodynamic therapy (PDT) or vascular targeted PDT (VTP).

A novel approach to the development of a personalized vaccine. This approach is based on: A) sequencing of the gag gene from an HIV-infected individual treated with antiretroviral therapy; B) sequencing of the HLA alleles of the same individual; C) selecting the epitopes recognized by the individual's own HLA Class I within the highly-conserved Gag.sub.256-377, Gag.sub.147-169 and/or Gag.sub.225-251 amino acid sequences. An original algorithm that designs the target peptide for the vaccine starting from viral and HLA sequences of an individual with HIV/AIDS, forms the core of the present invention. The original algorithm makes extensive use of existing open- source software for protein design. The peptides designed in this manner and accordingly synthesized may be exploited as a therapeutic vaccine against HIV/AIDS. Vehicles for such peptides may be an individual's own dendritic cells pulsed with the peptide combination or a specific viral or DNA vector leading to intracellular expression of the viral peptides. The present vaccine approach may contribute to control of viremia once antiretroviral therapies are suspended.

A novel approach to the development of a personalized vaccine. This approach is based on: A) sequencing of the gag gene from an HIV-infected individual treated with antiretroviral therapy; B) sequencing of the HLA alleles of the same individual; C) selecting the epitopes recognized by the individual's own HLA Class I within the highly-conserved Gag.sub.256-377, Gag.sub.147-169 and/or Gag.sub.225-251 amino acid sequences. An original algorithm that designs the target peptide for the vaccine starting from viral and HLA sequences of an individual with HIV/AIDS, forms the core of the present invention. The original algorithm makes extensive use of existing open- source software for protein design. The peptides designed in this manner and accordingly synthesized may be exploited as a therapeutic vaccine against HIV/AIDS. Vehicles for such peptides may be an individual's own dendritic cells pulsed with the peptide combination or a specific viral or DNA vector leading to intracellular expression of the viral peptides. The present vaccine approach may contribute to control of viremia once antiretroviral therapies are suspended.