Abstract: Provided herein is a process for preparing a microparticulate complex of a particle-forming component (“PFC”) and a nucleic acid-like component (“NAC”) in a monophasic composition comprising water and a water-miscible organic solvent. Also provided is a microparticulate complex that comprises a particle-forming component complexed to a nucleic acid-like component, and a composition comprising water and the microparticulate complex. Further provided is a method of delivery of a nucleic acid-like component to a cell or to a patient by contacting the cell with or administering to the patient a composition comprising water and the microparticulate complex described herein. Still further, a charge-changing composition represented by the formula A-X—B is provided.

Abstract: A process for preparing a microparticulate complex is provided. The process comprises (a) combining a particle-forming component (“PFC”) and a nucleic acid-like component (“NAC”) in a monophasic composition comprising water and a water-miscible, organic solvent to form a mixture wherein the PFC and the NAC are independently molecularly or micellarly soluble in the aqueous/organic solvent system, and (b) reducing the amount of the organic solvent in the mixture. This effects formation of the microparticulate complex of the NAC and the PFC. Also provided is a microparticulate complex that comprises a particle-forming component complexed to a nucleic acid-like component forming an approximately spherical particle, wherein the particle-forming component encloses an interior of the particle containing the nucleic acid-like component and the so-enclosed interior volume has less than about 50% (preferably less than 20%) of the volume containing free water.

Abstract: The present invention provides liposome compositions containing substituted ammonium and/or polyanion, and optionally with a desired therapeutic or imaging entity. The present invention also provides methods of making the liposome compositions provided by the present invention.

Abstract: The present invention provides liposome compositions containing substituted ammonium and/or polyanion, and optionally with a desired therapeutic or imaging entity. The present invention also provides methods of making the liposome compositions provided by the present invention.

Abstract: The present invention provides liposome compositions containing substituted ammonium and/or polyanion, and optionally with a desired therapeutic or imaging entity. The present invention also provides methods of making the liposome compositions provided by the present invention.

Abstract: The present invention provides two new camptothecin derivatives, which were identified as S,R- and S,S-topotecan lactates, respectively. Both compounds have anticancer activities. Pharmaceutical compositions of the new camptothecin derivatives, and cancer therapies with the new camptothecin derivatives or their pharmaceutical compositions were also provided.

Abstract: The present invention provides liposome compositions containing substituted ammonium and/or polyanion, and optionally with a desired therapeutic or imaging entity. The present invention also provide methods of making the liposome compositions provided by the present invention.

Abstract: The present invention provides for the development of endocytosis-sensitive probes, and a remote method for measuring cellular endocytosis. These probes are based on the reduced water permeability of a nanoparticle or liposomal delivery system, and inherent degradability or disruption of barrier integrity upon endocytosis. The invention also provides for liposomes having combined therapeutic and diagnostic utilities by co-encapsulating ionically coupled diagnostic and therapeutic agents, in one embodiment, by a method using anionic chelators to prepare electrochemical gradients for loading of amphipathic therapeutic bases into liposomes already encapsulating an imaging agent. The invention provides for imaging of therapeutic liposomes by inserting a lipopolymer anchored, remotely sensing reporter molecules into liposomal lipid layer. The invention allows for an integrated delivery system capable of imaging molecular fingerprints in diseased tissues, treatment, and treatment monitoring.

Abstract: An ophthalmic drug delivery system that contains phospholipid and cholesterol for prolonging drug lifetime in the eyes.

Abstract: The present invention provides for immunoliposomes that optimizes internalization of a drug into target cells bearing a characteristic cell surface marker. The immunoliposomes comprise an Fab? domain of an antibody that specifically binds the characteristic marker, an amphipathic vesicle-forming lipid, and a polyethylene glycol derivatized lipid. The invention also provides for growth-inhibiting immunoliposomes that lack growth-inhibiting therapeutic agents and yet are capable of inhibiting the growth and proliferation of target cells.

Abstract: The present invention provides two new camptothecin derivatives, which were identified as S,R- and S,S-topotecan lactates, respectively. Both compounds have anticancer activities. Pharmaceutical compositions of the new camptothecin derivatives, and cancer therapies with the new camptothecin derivatives or their pharmaceutical compositions were also provided.

Abstract: The present invention provides novel monoclonal antibodies with a high binding affinity to all five isoforms of human VEGF.

Abstract: The present invention provides for immunoliposomes that optimizes internalization of a drug into target cells bearing a characteristic cell surface marker. The immunoliposomes comprise an Fab? domain of an antibody that specifically binds the characteristic marker, an amphipathic vesicle-forming lipid, and a polyethylene glycol derivatized lipid. The invention also provides for growth-inhibiting immunoliposomes that lack growth-inhibiting therapeutic agents and yet are capable of inhibiting the growth and proliferation of target cells.

Abstract: The present invention provides novel monoclonal antibodies with a high binding affinity to all five isoforms of human VEGF.

Abstract: A process for preparing a microparticulate complex is provided. The process comprises (a) combining a particle-forming component (“PFC”) and a nucleic acid-like component (“NAC”) in a monophasic composition comprising water and a water-miscible, organic solvent to form a mixture wherein the PFC and the NAC are independently molecularly or micellarly soluble in the aqueous/organic solvent system, and (b) reducing the amount of the organic solvent in the mixture. This effects formation of the microparticulate complex of the NAC and the PFC. Also provided is a microparticulate complex that comprises a particle-forming component complexed to a nucleic acid-like component forming an approximately spherical particle, wherein the particle-forming component encloses an interior of the particle containing the nucleic acid-like component and the so-enclosed interior volume has less than about 50% (preferably less than 20%) of the volume containing free water.

Abstract: The present invention provides for immunoliposomes that optimizes internalization of a drug into target cells bearing a characteristic cell surface marker. The immunoliposomes comprise an Fab? domain of an antibody that specifically binds the characteristic marker, an amphipathic vesicle-forming lipid, and a polyethylene glycol derivatized lipid. The invention also provides for growth-inhibiting immunoliposomes that lack growth-inhibiting therapeutic agents and yet are capable of inhibiting the growth and proliferation of target cells.

Abstract: The present invention provides for lipid:nucleic acid complexes that have increased shelf life and high transfection activity in vivo following intravenous injection, and methods of preparing such complexes. The methods generally involve contacting a nucleic acid with an organic polycation to produce a condensed nucleic acid, and then combining the condensed nucleic acid with a lipid comprising an amphiphilic cationic lipid to produce the lipid:nucleic acid complex. This complex can be further stabilized by the addition of a hydrophilic polymer attached to hydrophobic side chains. The complex can also be made specific for specific cells, by incorporating a targeting moiety such as an Fab? fragment attached to a hydrophilic polymer.

Abstract: An emulsion composition includes prostaglandin E1 (PGE1), a phospholipid with a high purity and a non-proton-providing surfactant that improves stability of PGE1. Embodiments of the emulsion composition include an effective amount of PGE1, about 1% to about 30% (w/w) of a pharmaceutically acceptable oil as an oil base based on the weight of the emulsion composition, about 1% to about 30% (w/w) of a phospholipid with a high purity based on the weight of the oil base, about 1.6% to about 40% (w/w) of a non-proton-providing surfactant based on the weight of the oil base, and the balance of the emulsion composition being water.

Abstract: The invention provides a sustained release composition for intravitreal injection to the eye of a subject in need thereof. The sustained release composition contains an effective amount of a therapeutic agent in association with a nanosphere. The nanosphere contains a particle that comprises a particle-forming component capable of forming a vesicle, and an agent-carrying component capable of forming a complex with the therapeutic agent via electrostatic charge-charge interaction or hydrophobic-hydrophobic interaction. The particle-forming component has at least one head group moiety selected from a hydrophobic head group moiety, a polar head group moiety and a combination thereof. The agent-carrying component is a chemical entity that contains one or more negatively or positively charged groups.

Abstract: The invention provides a liposome composition for delivering high pay-load of a therapeutic agent to neovascularization sites of the eyes in a patient in need thereof. The liposome composition for entrapping the therapeutic agent comprises a particle forming component composed of a variety of vesicle-forming lipids, and an agent-carrying component able to form a complex with the therapeutic agent via electrostatic charge-charge interaction or hydrophobic-hydrophobic interaction; wherein the liposome composition comprising the therapeutic agent has a mean particle diameter of about 30 to 200 nm and may accumulate at the neovascularization sites of the eyes 24 hours after the intravenous administration of the liposome composition comprising the therapeutic agent to the patient.