The present invention discloses a new efficient process for the preparation of the KDR-targeting peptide-phospholipid conjugate of formula (I), which can be useful in therapeutic and diagnostic compositions and particularly in the preparation of ultrasound contrast agents.

Compositions containing lipid nanoparticles and nucleic acid therapeutic agents are disclosed. For example, calcium phosphate nanoparticles having a lipid coating are provided, wherein the calcium phosphate nanoparticles include a cyclic dinucleotide and the lipid coating includes phosphatidylserine. The compositions can be formulated for administration to the lungs of a subject via inhalation, or for administration via injection. Methods for the treatment of lung cancer and other cancers are also described. Targeted delivery of therapeutic agents such as cyclic dinucleotides to antigen presenting immune cells via the disclosed methods can elicit beneficial antitumor immunity.

The present invention relates to an ionic complex comprising a cationic polypeptide and an anionic excipient selected from: a PEG-carboxylic acid; a fatty acid having 10 or more carbon atoms; an anionic phospholipid; and a combination thereof. The invention also relates to a pharmaceutical composition comprising the ionic complex of the invention and a pharmaceutically acceptable carrier. The cationic polypeptide of the ionic complex has pharmacological activity and the complex can provide a more desirable pharmacokinetic profile for the cationic polypeptide of the complex as compared to the cationic polypeptide alone following administration. As such, the invention also relates to the use of the ionic complex and pharmaceutical composition comprising same to treat a subject suffering from a disease or disorder that is responsive to the cationic polypeptide of the ionic complex.

The present invention provides compositions comprising nucleic acid molecules, such as mRNA molecules, encapsulated within lipid particles. The compositions are useful, for example, to introduce the mRNA molecules into a human subject where they are translated to produce a polypeptide that functions to ameliorate one or more symptoms of a disease.

The present invention relates to an annexin-coated particle, comprising a negatively charged phospholipid and an annexin non-covalently coupled thereto. The present invention further relates to a composition comprising an annexin-coated particle. Furthermore, the present invention relates to a product for use in a method of preventing or treating a disease selected from a chronic inflammatory disease, an autoimmune disease, an allergy, and a cancer, said product comprising an annexin-coated particle, and/or a composition. The present invention further relates to a method of preparing an annexin-coated particle.

Disclosed herein are spherical high-density lipoprotein-like nanoparticles (HDL-NP) having a soft material core (e.g., a lipid-conjugated inorganic core). Also disclosed herein are methods for synthesizing the spherical HDL-NPs. Also disclosed herein are methods for treating disorders such as cardiovascular disease, cancer, inflammatory disorders or reducing NF-kB activity with the spherical HDL-NPs.

Provided herein is a liposome comprising: a) a conjugate comprising a lysophospholipid and a photosensitizer; b) a first derivatized phospholipid comprising a first phospholipid and a strained cyclooctyne moiety; c) a second derivatized phospholipid comprising a second phospholipid and a polyethylene glycol polymer; and d) a cationic or anionic lipid. Also provided herein is a liposome comprising: a) a conjugate comprising a lysophospholipid and a photosensitizer; b) a first derivatized phospholipid comprising a first phospholipid and a targeting moiety; c) a second derivatized phospholipid comprising a second phospholipid and a polyethylene glycol polymer; and d) a cationic or anionic lipid. The liposomes provided herein can be used, for example, in the treatment of cancer or in the imaging of cancer tumors.

The present invention relates to the combination of a Dbait molecule with a protein kinase inhibitor for treating cancer.

This invention relates, at least in part, to compositions comprising synthetic nanocarriers and immunosuppressants that result in immune suppressive effects. Such compositions can further comprise antigen and provide antigen-specific tolerogenic immune responses.

In certain embodiments a platform technology for the facilitating immune therapy in the treatment of cancer is provided. In certain embodiments nanocarriers are provided that facilitate delivery of an IDO inhibitor in conjunction with an inducer of cell death (ICD-inducer). In certain embodiments the IDO inhibitor is conjugated to a component of a lipid bilayer forming a nanovesicle. In still another embodiment, methods and compositions are provided where an ICD-inducing agent (e.g., doxorubicin, oxaliplatin, mitoxantrone etc.) and an IDO pathway inhibitor (e.g., an IDO inhibitor-prodrug) are integrated into a nanocarrier (e.g. a lipid-bilayer (LB)-coated nanoparticle), that allows systemic delivery to orthotopic pancreatic cancer site.