Abstract: The disclosure relates to methods of diagnosis and prognosis, compositions for immunotherapies, methods of improving said compositions, and immunotherapies using the same (e.g., T cells, non-T cells, TCR-based therapies, CAR-based therapies, bispecific T-cell engagers (BiTEs), and/or immune checkpoint blockade).

Abstract: The disclosure provides methods of treating a malignancy comprising administering an effective dose of a chimeric receptor (e.g., CAR or TCR) genetically modified T cell immunotherapy. Some aspects of the disclosure relate to methods of determining an effective dose of a T cell immunotherapy comprising polyfunctional T cells prior to administration to the patient.

Abstract: The disclosure relates to methods of diagnosis and prognosis, compositions for immunotherapies, methods of improving said compositions, and immunotherapies using the same

Abstract: The disclosure provides methods of treating a malignancy comprising administering an effective dose of a chimeric receptor (e.g., CAR or TCR) genetically modified T cell immunotherapy. Some aspects of the disclosure relate to methods of determining an effective dose of a T cell immunotherapy comprising polyfunctional T cells prior to administration to the patient.

Abstract: The disclosure provides methods of treating a malignancy comprising administering an effective dose of a chimeric antigen receptor genetically modified T cell immunotherapy and methods for manufacturing such immunotherapy. Some aspects of the disclosure relate to methods of determining objective response of a patient to a T cell immunotherapy based on the levels of attributes prior to administration to the patient.

Abstract: The disclosure relates to, in part, methods of CAR-T cancer treatment and methods of predicting clinical outcomes in response to those treatments. The methods comprise the use of baseline Sum of Product Diameters of Index Lesions and baseline number of lines of prior therapy as indicators.

Abstract: The disclosure provides methods of treating a malignancy comprising administering an effective dose of a chimeric receptor (e.g., CAR or TCR) genetically modified T cell immunotherapy. Some aspects of the disclosure relate to methods of determining an effective dose of a T cell immunotherapy comprising polyfunctional T cells prior to administration to the patient.

Abstract: Methods and compositions for delivering macromolecules to or via the respiratory tract, such that the macromolecules exhibit improved local and/or systemic bioavailability are provided. Such methods utilize lipid-based microstructures formed in combination with at least one bioactive macromolecule, which have a superior ability to rapidly release the bioactive macromolecule(s) thereby resulting in improved local and/or systemic bioavailability of the bioactive macromolecule(s). Such improved bioavailability is believed to be due, in part, to reduction of scavenging by bronchoalveolar macrophages and/or mucociliary clearance.

Abstract: Compositions and methods are provided for the administration of particulates comprising at least one bioactive agent which, in selected embodiments, may comprise and immunoactive agent. In this respect, the invention provides for both topical and systemic delivery of the bioactive agent using, for example, the respiratory, gastrointestinal or urogenital tracts. The particulates may be in the form of dry powders or combined with a non-aqueous suspension medium to provide stabilized dispersions. In preferred embodiments, the disclosed compositions will be used in conjunction with inhalation devices such as metered dose inhalers, dry powder inhalers, atomizers or nebulizers for targeted delivery of the agent to mucosal surfaces.

Abstract: Methods and compositions for delivering macromolecules to or via the respiratory tract, such that the macromolecules exhibit improved local and/or systemic bioavailability are provided. Such methods utilize lipid-based microstructures formed in combination with at least one bioactive macromolecule, which have a superior ability to rapidly release the bioactive macromolecule(s) thereby resulting in improved local and/or systemic bioavailability of the bioactive macromolecule(s). Such improved bioavailability is believed to be due, in part, to reduction of scavenging by bronchoalveolar macrophages and/or mucociliary clearance.