Abstract: Described herein is the design and construction of a class of lipoprotein targeting protease inhibitors. Small peptides with protease inhibitor activity are conjugated to hydrophobic, lipoprotein targeting molecules using, for instance, amine reactive chemistry. Methods of use of the resultant lipoprotein targeting protease inhibitor (antiprotease) molecules are also described. Also described is the production and use of protease inhibitor enriched HDL particles, as well as A1AT-peptide-enriched HDL particles, and their use in various therapeutic contexts.

Abstract: Described herein is the design and construction of a class of lipoprotein targeting protease inhibitors. Small peptides with protease inhibitor activity are conjugated to hydrophobic, lipoprotein targeting molecules using, for instance, amine reactive chemistry. Methods of use of the resultant lipoprotein targeting protease inhibitor (antiprotease) molecules are also described. Also described is the production and use of protease inhibitor enriched HDL particles, as well as AlAT-peptide-enriched HDL particles, and their use in various therapeutic contexts.

Abstract: A method of treating an asthmatic subject is provided. The method includes determining serum level of serum amyloid A (SAA) in the subject; comparing the serum level with a pre-determined threshold; and administering to the subject a therapeutically effective amount of a COX-2 inhibitor if the serum level is greater than or equal to the threshold.

Abstract: A method of assessing the risk for development of cardiovascular disease (CVD) or an inflammatory disease in a patient comprises (i) incubating a sample of body fluid with donor particles, wherein the donor particles are coated with a lipid and a first quantity of detectably labeled, non-exchangeable lipid probe (NELP); (ii) separating the detectably labeled NELP-associated HDL into a first portion and the donor particles into a second portion; (iii) measuring the second quantity of detectably labeled NELP in the first portion; (iv) determining a detectably labeled NELP efflux value for the patient; and (v) comparing the detectably labeled NELP efflux value for the patient to a reference standard. Related methods of lowering the risk for development of CVD or an inflammatory disease in a patient and methods of measuring the quantity of functional HDL in a sample of body fluid are also provided.

Abstract: Described herein is the design and construction of a class of lipoprotein targeting protease inhibitors. Small peptides with protease inhibitor activity are conjugated to hydrophobic, lipoprotein targeting molecules using, for instance, amine reactive chemistry. Methods of use of the resultant lipoprotein targeting protease inhibitor (antiprotease) molecules are also described. Also described is the production and use of protease inhibitor enriched HDL particles, as well as A1AT-peptide-enriched HDL particles, and their use in various therapeutic contexts.

Abstract: Described herein is the design and construction of a class of lipoprotein targeting protease inhibitors. Small peptides with protease inhibitor activity are conjugated to hydrophobic, lipoprotein targeting molecules using, for instance, amine reactive chemistry. Methods of use of the resultant lipoprotein targeting protease inhibitor (antiprotease) molecules are also described. Also described is the production and use of protease inhibitor enriched HDL particles, as well as A1AT-peptide-enriched HDL particles, and their use in various therapeutic contexts.

Abstract: The invention provide herein provides for a targeted drug delivery vehicle compositions, methods of manufacture, and methods of treatment for therapeutic applications.

Abstract: Described herein is the design and construction of a class of lipoprotein targeting protease inhibitors. Small peptides with protease inhibitor activity are conjugated to hydrophobic, lipoprotein targeting molecules using, for instance, amine reactive chemistry. Methods of use of the resultant lipoprotein targeting protease inhibitor (antiprotease) molecules are also described. Also described is the production and use of protease inhibitor enriched HDL particles, as well as A1AT-peptide-enriched HDL particles, and their use in various therapeutic contexts.

Abstract: The present disclosure provides targeted drug delivery vehicle compositions comprising a drug composition and targeted poly-amino-acid subunits, methods of manufacture, and methods of treatment for numerous diseases.

Abstract: The invention provide herein provides for a targeted drug delivery vehicle compositions, methods of manufacture, and methods of treatment for therapeutic applications.

Abstract: Disclosed herein are peptides and peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway, as well as peptides that activate lipoprotein lipase, and compositions comprising such peptides or combinations thereof. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells and activate lipoprotein lipase within cells are also disclosed herein.

Abstract: Disclosed herein are peptides or peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells are also disclosed herein.

Abstract: Hydrocarbon stapling of apolipoprotein mimetic peptides increases the helicity of the peptides, enhances their ability to promote cholesterol efflux by multiple mechanisms and makes them resistant to proteolysis. Hydrocarbon stapled amphipathic helical peptides are useful in the treatment of cardiovascular diseases and other disorders.

Abstract: The invention provide herein provides for a targeted drug delivery vehicle compositions, methods of manufacture, and methods of treatment for therapeutic applications.

Abstract: Disclosed herein are peptides or peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells are also disclosed herein.

Abstract: Disclosed herein are peptides or peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells are also disclosed herein.

Abstract: Disclosed herein are peptides or peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells are also disclosed herein.

Abstract: Disclosed are methods of diagnosing cardiovascular disease comprising measuring sphingolipids. Also disclosed are methods of predicting cardiovascular disease comprising measuring sphingolipids. Also disclosed are methods of identifying subjects at risk of developing cardiovascular disease comprising measuring sphingolipids.

Abstract: Disclosed herein are peptides and peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway, as well as peptides that activate lipoprotein lipase, and compositions comprising such peptides or combinations thereof. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells and activate lipoprotein lipase within cells are also disclosed herein.

Abstract: Disclosed herein are peptides or peptide analogs with multiple amphipathic ?-helical domains that promote lipid efflux from cells via an ABCA1-dependent pathway. Also provided herein are methods of using multi-domain amphipathic ?-helical peptides or peptide analogs to treat or inhibit dyslipidemic disorders. Methods for identifying non-cytotoxic peptides that promote ABCA1-dependent lipid efflux from cells are also disclosed herein.