Provided herein is a pharmaceutical composition comprising at least one isoflavonoid. Also provided herein are methods of treating cancer, sensitizing cancer cells, and inducing apoptosis in cancer cells by administering such compositions.

Disclosed herein are methods for reversing hepatic steatosis by providing a consumable composition. Some embodiments provided include, for example, administering a compound of Formula (I) or compound of Formula (II). Some embodiments provide the composition is formulated as a dietary supplement, food ingredient or additive, a medical food, nutraceutical or pharmaceutical composition.

Disclosed herein are methods for reversing hepatic steatosis by providing a consumable composition. Some embodiments provided include, for example, administering a compound of Formula (I) or compound of Formula (II). Some embodiments provide the composition is formulated as a dietary supplement, food ingredient or additive, a medical food, nutraceutical or pharmaceutical composition.

The present invention provides liposome compositions containing sparingly soluble drugs that are used to treat life-threatening diseases. A preferred method of encapsulating a drug inside a liposome is by remote or active loading. Remote loading of a drug into liposomes containing a transmembrane electrochemical gradient is initiated by co-mixing a liposome suspension with a solution of drug, whereby the neutral form of the compound freely enters the liposome and becomes electrostatically charged thereby preventing the reverse transfer out of the liposome. There is a continuous build-up of compound within the liposome interior until the electrochemical gradient is dissipated or all the drug is encapsulated in the liposome. However, this process as described in the literature has been limited to drugs that are freely soluble in aqueous solution or solubilized as a water-soluble complex. This invention describes compositions and methods for remote loading drugs with low water solubility (<2 mg/mL). In the preferred embodiment the drug in the solubilizing agent is mixed with the liposomes in aqueous suspension so that the concentration of solubilizing agent is lowered to below its capacity to completely solubilize the drug. This results in the drug precipitating but remote loading is capability retained. The process is scalable and the resulting drug-loaded liposomes are characterized by a high drug-to-lipid ratios and predictable drug retention when the liposome encapsulated drug is administered in patients.

The present invention provides liposome compositions containing sparingly soluble drugs that are used to treat life-threatening diseases. A preferred method of encapsulating a drug inside a liposome is by remote or active loading. Remote loading of a drug into liposomes containing a transmembrane electrochemical gradient is initiated by co-mixing a liposome suspension with a solution of drug, whereby the neutral form of the compound freely enters the liposome and becomes electrostatically charged thereby preventing the reverse transfer out of the liposome. There is a continuous build-up of compound within the liposome interior until the electrochemical gradient is dissipated or all the drug is encapsulated in the liposome. However, this process as described in the literature has been limited to drugs that are freely soluble in aqueous solution or solubilized as a water-soluble complex. This invention describes compositions and methods for remote loading drugs with low water solubility (<2 mg/mL). In the preferred embodiment the drug in the solubilizing agent is mixed with the liposomes in aqueous suspension so that the concentration of solubilizing agent is lowered to below its capacity to completely solubilize the drug. This results in the drug precipitating but remote loading is capability retained. The process is scalable and the resulting drug-loaded liposomes are characterized by a high drug-to-lipid ratios and predictable drug retention when the liposome encapsulated drug is administered in patients.

Provided are methods of treating cancer that comprise administering a polypeptide (e.g. a fusion polypeptide) that comprises a SIRPα D1 domain variant and an Fc domain variant in combination with at least one chemotherapy agent and/or at least one therapeutic antibody. Also provided are related kits.

Provided are methods of treating cancer that comprise administering a polypeptide (e.g. a fusion polypeptide) that comprises a SIRPα D1 domain variant and an Fc domain variant in combination with at least one chemotherapy agent and/or at least one therapeutic antibody. Also provided are related kits.

Disclosed are combination therapy methods useful for the therapeutic treatment of cancer by combining local administration of compositions containing antineoplastic particles, such as taxane particles, with systemic administration of compositions containing immunotherapeutic agents. Local administration methods include topical application, pulmonary administration, intratumoral injection, intraperitoneal injection, and intracystic injection.

Disclosed are combination therapy methods useful for the therapeutic treatment of cancer by combining local administration of compositions containing antineoplastic particles, such as taxane particles, with systemic administration of compositions containing immunotherapeutic agents. Local administration methods include topical application, pulmonary administration, intratumoral injection, intraperitoneal injection, and intracystic injection.

Disclosed are combination therapy methods useful for the therapeutic treatment of cancer by combining local administration of compositions containing antineoplastic particles, such as taxane particles, with systemic administration of compositions containing immunotherapeutic agents. Local administration methods include topical application, pulmonary administration, intratumoral injection, intraperitoneal injection, and intracystic injection.