Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful for therapy of TNF?-mediated pathologies and conditions, including vascular inflammatory pathologies.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: A device (12) and method are provided for percutaneous transdermal delivery of a potent pharmacologically active agent. The agent is dissolved in water to form an aqueous coating solution having an appropriate viscosity for coating extremely tiny skin piercing elements (10). The coating solution is applied to the skin piercing elements (10) using known coating techniques and then dried. The device (12) is applied to the skin of a living animal (e.g., a human), causing the microprotrusions (10) to pierce the stratum corneum and deliver a therapeutically effect dose of the agent to the animal.

Abstract: Anti-TNF antibodies and anti-TNF peptides, specific for tumor necrosis factor (TNF) are useful for in vivo diagnosis and therapy of a number of TNF-mediated pathologies and conditions, as well as polynucleotides coding for anti-TNF murine and chimeric antibodies, peptides, methods of making and using the antibody or peptides in immunoassays and immuno-therapeutic approaches are provided, where the anti-TNF peptide is selected from a soluble portion of TNF receptor, an anti-TNF antibody or structural analog thereof.

Abstract: An apparatus and method for transdermally delivering a biologically active agent comprising a delivery system having a microprojection member (or system) that includes a plurality of microprojections (or array thereof) that are adapted to pierce through the stratum corneum into the underlying epidermis layer, or epidermis and dermis layers. In one embodiment, an Epoetin-based agent is contained in a biocompatible coating that is applied to the microprojection member. In a further embodiment, the delivery system includes a gel pack having an Epoetin-based agent-containing hydrogel formulation that is disposed on the microprojection member after application to the skin of a patient. In an alternative embodiment, the Epoetin-based agent is contained in both the coating and the hydrogel formulation.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: A method and device are described for applying a microprotrusion member (44) including a plurality of microprotrusions (90) to the stratum corneum with impact. The method and device are used to improve transport of an agent across the skin for agent delivery or sampling. The applicator (10, 60, 80) causes the microprotrusion member (44) to impact the stratum corneum with a certain amount of impact determined to effectively pierce the skin with the microprotrusions (90). The preferred applicator (10, 60, 80) impacts the stratum corneum with the microprotrusion member (44) with an impact of at least 0.05 joules per cm2 of the microprotrusion member (44) in 10 msec or less.

Abstract: Anti-TNF antibodies and anti-TNF peptides, specific for tumor necrosis factor (TNF) are useful for in vivo diagnosis and therapy of a number of TNF-mediated pathologies and conditions, as well as polynucleotides coding for anti-TNF murine and chimeric antibodies, peptides, methods of making and using the antibody or peptides in immunoassays and immuno-therapeutic approaches are provided, where the anti-TNF peptide is selected from a soluble portion of TNF receptor, an anti-TNF antibody or structural analog thereof.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: Anti-TNF antibodies, fragments and regions thereof which are specific for human tumor necrosis factor-? (TNF?) and are useful in vivo diagnosis and therapy of a number of TNF?-mediated pathologies and conditions, as well as polynucleotides coding for murine and chimeric antibodies, methods of producing the antibody, methods of use of the anti-TNF antibody, or fragment, region or derivative thereof, in immunoassays and immunotherapeutic approaches are provided.

Abstract: An apparatus and method for transdermally delivering desmopressin comprising a delivery system having a microprojection member (or system) that includes a plurality of microprojections (or array thereof) that are adapted to pierce through the stratum corneum into the underlying epidermis layer, or epidermis and dermis layers. In one embodiment, the desmopressin is contained in a biocompatible coating that is applied to the microprojection member.

Abstract: Skin patches (20) having a microprojection array (10), a reservoir (18) containing an antigenic agent and an immune response augmenting adjuvant, and methods of using same to vaccinate animals (e.g., humans) is disclosed. In a preferred embodiment, the microprojection arrays (10) are composed of a photoetched and micro-punched titanium foil (14). The microprojections (12) are coated with a liquid formulation containing a vaccine antigen and an adjuvant such as glucosaminyl muramyl dipeptide, dried, and applied to skin of the animal to be vaccinated using an impact applicator. The microprojections (12) create superficial pathways through the stratum corneum to facilitate permeation of antigenic agent and adjuvant. Antigen dose and depth of penetration can be controlled. This technology has broad applicability for a wide variety of therapeutic vaccines to improve efficacy, and convenience of use.

Abstract: A transdermal delivery system having a microprojection array with one or more voids configured to allow an adhesive backing to attach to a user's skin and, hence, improve retention of the system thereto. Radial voids can be configured to enhance compliance of the array to conform more readily to non-flat areas of the skin.

Abstract: An apparatus and method for transdermally delivering a biologically active agent comprising a delivery system having a microprojection member (or assembly) that includes a plurality of microprojections (or array thereof) that are adapted to pierce through the stratum corneum into the underlying epidermis layer, or epidermis and dermis layers. In one embodiment, the VEGF-based agent is contained in a biocompatible coating that is applied to the microprojection member.

Abstract: An apparatus and method for transdermally delivering a natriuretic peptide comprising a delivery system having a microprojection member that includes a plurality of microprojections (or array thereof) that are adapted to pierce through the stratum corneum into the underlying epidermis layer, or epidermis and dermis layers. In one embodiment, the natriuretic peptide is contained in a biocompatible coating that is applied to the microprojection member. In a further embodiment, the delivery system includes a natriuretic peptide-containing hydrogel formulation. In an alternative embodiment, the natriuretic peptide is contained in both the coating and the hydrogel formulation. In yet another embodiment, the natriuretic peptide is contained in a solid state formulation.

Abstract: A transdermal agent delivery apparatus and system having a low infection potential comprising a delivery system having a microprojection member (or system) that includes a plurality of microprojections (or array thereof) that are adapted to pierce through the stratum corneum into the underlying epidermis layer, or epidermis and dermis layers. In one embodiment, the microprojection member includes a biocompatible coating having at least one biologically active agent and at least one antimicrobial agent disposed therein. In another embodiment, the microprojection member includes a hydrogel formulation having at least one biologically active agent and at least one antimicrobial agent. In yet another embodiment, the microprojection member includes a hydrogel formulation having at least one antimicrobial agent and a solid film having at least one biologically active agent.

Abstract: A microprojection array having at least first and second microprojections, the first and second microprojections having inner and outer faces, the first microprojection inner face being disposed substantially parallel to the second microprojection inner face; and a biocompatible coating disposed on the first and second microprojection inner faces, the first and second microprojections being adapted to substantially restrict contact of the coating with biological tissue during insertion of the first and second microprojections into the tissue.