Abstract: A nanoformulation that includes loaded nanoparticles. Each nanoparticle includes a modified chitosan polymer encapsulating at least one vitamin D derivative, at least one vitamin D metabolite, or combinations thereof. The modified chitosan polymer includes chitosan covalently linked to at least one entity selected from the group consisting of fatty acids (omega-3-fattay acids), amino acids, deoxycholic acid, alginate, arginine-alginate, hyaluronic acid, collagen, collagen-hydroxyapatite, poly(lactic-co-glycolic acid) (PLGA), and combinations thereof. A structure includes a medium and the nanoformulation, wherein the nanoparticles are dispersed in the medium. A method of using the nanoformulation to treat a disorder and improve efficacy of current therapies where resistance develop in a patient includes administering to the patient a therapeutically effective amount of the nanoformulation for treating the disorder.

Abstract: A dual thyrointegrin antagonist and a method for treating an angiogenesis-mediated disorder and/or a hyperthyroidism disorders by introducing the dual thyrointegrin antagonist into animals (e.g., mammals, human beings). The dual thyrointegrin antagonist includes a chemical structure having a thyroid hormone antagonist and ?v?3 integrin antagonist in the same molecule.

Abstract: Nanoparticles comprising VIP and their use in treating, e.g. pulmonary hypertension. Such nanoparticles provide improved delivery of VIP and allow for acute treatment and optionally for sustained release of VIP in a patient.

Abstract: Disclosed are methods of treating subjects having conditions related to angiogenesis including administering an effective amount of a polymeric Nanoparticle form of thyroid hormone agonist, partial agonist or an antagonist thereof, to promote or inhibit angiogenesis in the subject. Compositions of the polymeric forms of thyroid hormone, or thyroid hormone analogs, are also disclosed.

Abstract: A dual thyrointegrin antagonist and a method for treating an angiogenesis-mediated disorder and/or a hyperthyroidism disorders by introducing the dual thyrointegrin antagonist into animals (e.g., mammals, human beings). The dual thyrointegrin antagonist includes a chemical structure having a thyroid hormone antagonist and ?v?3 integrin antagonist in the same molecule.

Abstract: Thyroid hormone antagonists and their nanoparticle formulations (Nanotetrac™ or Nanotriac™) act at a cell surface receptor to block angiogenesis and tumor cell proliferation. The complex anti-angiogenic performs actions on specific cytokines and chemokines. Thyroid hormone antagonists inhibit expression in tumor cells of cytokine genes, e.g., specific interleukins, and chemokine genes, such as fractalkine (CX3CL1), and chemokine receptor genes (CX3CR1) that are targets in the development of inflammation-suppressant drugs. This application discloses a novel composition of Tetra or Tri-iodothyroacetic acid (tetrac or triac), other thyroid partial agonists or antagonists and their nanoparticle formulations conjugated to polymers and encapsulating non-steroidal anti-inflammatory, anti-inflammatory glucocorticoids, and/or polyphenols for the management of various acute and chronic inflammatory disorders ranging from neurological, vascular, and musculoskeletal disorders.

Abstract: Disclosed are methods of increasing the chemosensitivity of normal and/or chemoresistant tumor or cancer cells using thyroid hormone analogs and/or nanoparticulate or polymeric forms thereof. Also disclosed are methods of increasing radiosensitivity of normal and/or radioresistant tumor or cancer cells using thyroid hormone analogs and/or nanoparticulate or polymeric forms thereof.

Abstract: Disclosed are methods of treating subjects having conditions related to angiogenesis including administering an effective amount of a polymeric Nanoparticle form of thyroid hormone agonist, partial agonist or an antagonist thereof, to promote or inhibit angiogenesis in the subject. Compositions of the polymeric forms of thyroid hormone, or thyroid hormone analogs, are also disclosed.

Abstract: Disclosed are methods of treating subjects having conditions related to angiogenesis including administering an effective amount of a polymeric form of thyroid hormone, or an antagonist thereof, to promote or inhibit angiogenesis in the subject. Compositions of the polymeric forms of thyroid hormone, or thyroid hormone analogs, are also disclosed.

Abstract: Disclosed are methods of treating subjects having conditions related to angiogenesis including administering an effective amount of a polymeric form of thyroid hormone, or an antagonist thereof, to promote or inhibit angiogenesis in the subject. Compositions of the polymeric forms of thyroid hormone, or thyroid hormone analogs, are also disclosed.

Abstract: Disclosed are methods of treating subjects having conditions related to angiogenesis including administering an effective amount of a polymeric Nanoparticle form of thyroid hormone agonist, partial agonist or an antagonist thereof, to promote or inhibit angiogenesis in the subject. Compositions of the polymeric forms of thyroid hormone, or thyroid hormone analogs, are also disclosed.

Abstract: Aspects of the present invention relate to compounds and methods useful in modulating angiogenesis and methods of treating or preventing diseases associated with angiogenesis by administering a polycationic compound. The present invention relates to methods of use and compositions for inhibiting angiogenesis-mediated disorders in mammals including animals and humans. Additionally, this invention relates to the combined use of polycations with other anti-angiogenesis agents for the treatment of different angiogenesis-mediated disorders. Additionally, those polycationic compounds can be used with various anti-inflammatory and cytotoxic agents as well as with radio-therapeutic agents in cancer patients to prevent and treat tumor growth and metastasis.

Abstract: The present invention provides a composition, a dairy product, and a method for treating a disorder in a subject. The composition includes (i) polymeric nanoparticles and (ii) camel derived glycosaminoglycans (GAG)s ionic complex encapsulated into the nanoparticles, at least one active ingredient encapsulated into the nanoparticles, or combinations thereof. The nanoparticles are lactoferrin nanoparticles including camel derived lactoferrin, casein nanoparticles including camel derived casein, or combinations thereof. The dairy product includes ice cream or frozen yogurt, wherein the ice cream or frozen yogurt includes the composition and is derived from camel milk or other species of milk. The method for treating a disorder in a subject includes administering a therapeutic dose of the composition to the subject.

Abstract: A composition and an associated method for hepatic targeted delivery of thyroid receptor beta1 (TR?1) agonist to a liver of a subject. The composition includes hydrophobic nanoparticles, a liver targeting moiety exterior to each nanoparticle and covalently bonded to each nanoparticle, and at least one TR?1 agonist encapsulated within each nanoparticle. The nanoparticles include chitosan hybrid nanoparticles, amine-modified PLGA nanoparticles, solid lipid nanoparticles, and combinations thereof. The liver targeting moiety includes Glycyrrhetinic acid (GA), Lactobionic acid (LA), or combinations thereof.

Abstract: A formulation comprising T3/VIP nanoparticles, wherein the T3/VIP nanoparticle comprises both T3 and VIP encapsulated or immobilized on a bioabsorbable polymer. The invention further provides for methods of making a formulation comprising a T3/VIP nanoparticle. The invention further provides for methods of treatment utilizing said T3/VIP nanoparticle.

Abstract: The present invention relates to methods of preventing or reducing the risk of acute and chronic rejection of transplanted organs. The invention relates to the administration of T3, VIP, and T3/VIP nanoparticles to a donor organ in order to prevent or reduce the risk of rejection, e.g. acute or chronic rejection.

Abstract: A filter and a method of forming a suture structure. The filter includes layered structure(s) interior to the filter. Each layered structure includes a carbon structure comprising carbon and a coating on a surface of the carbon structure. Each layered structure may further include a heparin layer that includes heparin and is on the coating. The coating of the filter includes cellulose, PMMA, PEMA, or PHEMA. The carbon structure may include an activated charcoal layer or carbon nanotube(s). The layered structure is configured to remove a contaminant flowing through the filter. The method of forming the suture structure includes forming a film on a suture that has been previously formed on a mammal. The film includes both a coating on the suture and a heparin layer that includes heparin and is on the coating. The coating of the suture structure includes cellulose, PMMA, PEMA, or PHEMA.

Abstract: A method for treating a subject, such as a human patient, having a vascular disorder. The treatment method administers a therapeutic effective amount of a nanoparticle or a chemical structure to the subject to treat the disorders. The nanoparticle includes a poly L-arginine polymer and a Factor VIIa inhibitor conjugated to, or encapsulated in, the poly L-arginine polymer. The chemical structure includes a Factor VIIa inhibitor that includes at least one nitric oxide (NO) donor. The disorder may be sickle cell disease; stimulated or pathological angiogenesis associated disorders, cancer, ocular angiogenesis-mediated disorders such as diabetic retinopathy and macular degeneration, coagulation and/or platelet activation-associated disorders, pulmonary hypertension, or combinations thereof.

Abstract: A composition and method for treating a bone condition of an animal. The composition includes a nanoformulation of active ingredients. The active ingredients include Lepidium Sativum or other Lepidium extracts, calcium, vitamin D, and antioxidants. The method for treating a bone condition includes introducing the composition into the animal.

Abstract: Nanoparticles comprising T3 and their use in treating, e.g., cardiac conditions, for example cardiac arrest, are provided. Such nanoparticles provide improved delivery of T3 and allow for acute treatment and optionally for sustained release of T3 in a patient.