A transdermal delivery system of microneedles containing a bioactive material, comprising at least one layer of a support material; at least one biodegradable needle associated with the support material, each needle comprising at least one biodegradable polymer and at least one sugar, wherein each biodegradable needle is hollow and is adapted to retain a bioactive material.

Disclosed herein are methods of detecting a target viral nucleic acid sequence, determining the localization of the target viral nucleic acid sequence, and/or quantifying the number of target viral nucleic acid sequences in a cell. This method may be used on small target nucleic acid sequences, and may be referred to as Nano-FISH or viral Nano-FISH.

The invention relates to methods of treatment of a solid tumor in a patient in need thereof, comprising administering to the patient: (i) an effective amount of engineered immune cells originating from a donor expressing at their cell surface a Chimeric Antigen Receptor (CAR) directed against Fibroblast Activation Protein (FAP), and (ii) an effective amount of an immunotherapy treatment that elicits an immune response in the patient.

The present invention provides, in some embodiments, methods, compositions, systems, and kits comprising nano-satellite complexes comprising: a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core; 3-25 satellite particles attached to, or absorbed to, said biocompatible coating; a plurality of antigenic peptides conjugated to, or absorbed to, said satellite particles; and at least one additional property. In other embodiments, provided herein are nano-satellite complexes comprising: a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core; a plurality of satellite particles attached to, or absorbed to, said biocompatible coating; a plurality of antigenic peptides conjugated to, or absorbed to, said satellite particles; and a plurality of LIGHT (TNFSF14) peptides conjugated to, or absorbed to, said satellite particles. In some embodiments, administration of the nanosatellite complexes to a subject with cancer achieves long-term cancer remission (e.g., when combined with an immune checkpoint inhibitor, such as PD1).

Embodiments described herein relate to methods, devices, and computer systems thereof for the derivation of T CAR libraries (Universal Subject or Individual Subject) for personalized treatment of disease in a subject. In certain embodiments, differential screening of normal and diseased tissue expression data is utilized to determine disease-specific antigens and thereby generate T CAR cells reactive to such antigens to form a disease-specific library. In certain embodiments, determination of the most effective T CAR clones from the disease-specific library is based on the subject's own disease-specific antigens. In certain embodiments, a subject is treated with a therapeutically effective amount of T CAR clones.

Regulatory B cells (tBreg) are disclosed herein. These regulatory B cells express CD25 (CD25.sup.+) a pan B cell marker such as B220 (B220.sup.+), and also express CD19 (CD19.sup.+). These regulatory B cells suppress resting and activated T cells in cell contact-dependent manner. Methods for generating these regulatory B cells are also disclosed herein, as are methods for using these regulatory B cells to produce regulatory T cells (Treg). In some embodiments, methods for treating an immune-mediated disorder, such as an autoimmune disease, transplant rejection, graft-versus-host disease or inflammation, are disclosed. These methods include increasing regulatory B cell number or activity and/or by administering autologous regulatory B cells. Methods for treating cancer are also disclosed herein. These methods include decreasing regulatory B cell activity and/or number.

The present invention provides a method for activating a Natural Killer (NK) cell by contacting the NK cell in vitro with an activating tumor cell preparation (ATCP). The invention also provides an activated NK cell produced by such a method and its use in the treatment of cancer.

The present invention relates to an ErbB2-specific NK-92 cell or cell line containing a lentiviral vector encoding a chimeric antigen receptor and preferably two vector integration loci in its cellular genome. The present invention further relates to the use of the ErbB2-specific NK-92 cell or cell line in the prevention and/or treatment of cancer, preferably ErbB2-expressing cancers. The present invention further relates to the use of the ErbB2-specific NK-92 cell or cell line as targeted cell therapeutic agent and/or for adoptive cancer immunotherapy. The present invention further relates to a method for generating an ErbB2-specific NK-92 cell or cell line as well as to a method for identifying an ErbB2-specific NK-92 cell or cell line and to the ErbB2-specific NK-92 cell or cell line obtained or identified by the methods as well as their uses.

Cancer treatment is provided, by irradiating an individual with a localized, high single dose or short course of doses at a primary tumor site; collecting T cells from the individual after a period of time sufficient activation of an anti-tumor response; treating the individual with an effective dose of dose of chemotherapy; and reintroducing the T cell population back to the individual.

Methods of inhibiting metastasis in cancer patients are provided, wherein the methods comprise reducing TGF signaling, for example, by reducing TGF receptor II expression in myeloid cells. Vectors comprising a TGF receptor II RNAi nucleic acid sequence operably linked to a myeloid specific promoter also are provided. A method of diagnosing cancer in an individual by determining TGF receptor II expression in myeloid cells in the individual is provided. Additionally, a method of modulating TGF activity in myeloid cells in a cancer patient comprising administering a regulator of at least one of the GSK3 and PI3K pathways to the patient is provided.