A 3D microfluidic device for use as an in vitro lymph node is described. The microfluidic device has a body with a semi-circular inner wall and a first channel located adjacent along the semi-circular inner wall, the first channel corresponding to a subcapsular sinus region of a lymph node, a second channel located adjacent the first channel, the second channel corresponding to a reticular network, and a bottom cavity and top cavity, centrally located, corresponding to a paracortex and follicle of a lymph node, respectively. The various compartments of the device are separated by circumferentially and horizontally located rows of micro-pillars. A lab-on-a-chip device incorporating the microfluidic device is also described.

Systems, devices, and methods for monitoring and assessing immunotherapy toxicity are discussed. An exemplary system receives physiologic information from a patient using an ambulatory medical device. In response to an immunotherapy such as CAR T-cell therapy, the system determines a toxicity indication using the received physiologic information. A therapy can be initiated or adjusted using the toxicity indication.

Described are multi-functional beads and methods to capture rare cells directly from low-volume biological samples and perform both functional and genomic assays from those cells. This is accomplished using a multifunctional capture bead that allows co-localization of both the single cell capture element and the molecular assay components. When combined with a digital microfluidic platform this enables encoding and/or barcoding of specific single cells.

The present invention relates to peptides, proteins, nucleic acids and cells for use in immunotherapeutic methods. In particular, the present invention relates to the immunotherapy of cancer. The present invention furthermore relates to tumor-associated T-cell peptide epitopes, alone or in combination with other tumor-associated peptides that can for example serve as active pharmaceutical ingredients of vaccine compositions that stimulate anti-tumor immune responses, or to stimulate T cells ex vivo and transfer into patients. Peptides bound to molecules of the major histocompatibility complex (MHC), or peptides as such, can also be targets of antibodies, soluble T-cell receptors, and other binding molecules.

A method for T-cell epitope prediction where quantitative scores of stability in the binding between peptides and MHC molecules are integrated into the derivation of the likelihood that a peptide of defined amino acid sequence constitutes a T-cell epitope. Preferably, stability data are obtained an MS-based method for identification of MHC binding peptides, where the binding capability is quantitatively assessed to allow distinction between stably binding peptides and peptides that are unlikely to be presented to T-cells. The method includes a step of time-course or thermostability testing of naturally processed peptides bound to MHC. Also disclosed are methods for preparation of personalized immunogenic compositions, methods of therapeutic treatment of malignancies, and a computer system that implements the T-cell epitope prediction method.

Some embodiments disclosed herein provide a plurality of compositions each comprising a protein binding reagent conjugated with an oligonucleotide. The oligonucleotide comprises a unique identifier for the protein binding reagent it is conjugated with, and the protein binding reagent is capable of specifically binding to a protein target. Further disclosed are methods and kits for quantitative analysis of a plurality of protein targets in a sample and for simultaneous quantitative analysis of protein and nucleic acid targets in a sample. Also disclosed herein are systems and methods for preparing a labeled biomolecule reagent, including a labeled biomolecule agent comprising a protein binding reagent conjugated with an oligonucleotide.

Disclosed herein are methods and systems for evaluating the bioenergetic poise and bioenergetic capacity of living cells in a single assay.

The application provides T cell gene expression signatures that can be used to predict T cell therapy outcomes.

Provided are methods and compositions for labeling an allergen-specific pathogenic CD4+ T-cell. The method can comprise contacting a cell population comprising CD4+ T cells with a suspected allergen to provide a challenged cell population, contacting the challenged cell population, or a subpopulation thereof, with a first molecule that specifically binds to a biomarker for an allergen-specific pathogenic T cell, wherein binding of the first molecule to the biomarker on a CD4+ cell indicates the cell is an allergen-specific pathogenic CD4+ T cell, and detecting binding of the first molecule to a CD4+ cell, wherein binding to the cell indicates the cell is an allergen-specific pathogenic CD4+ T cell. The method is applicable to monitoring the presence of allergen-specific pathogenic CD4+ T cells and/or efficacy of immunotherapy for allergies in a subject.

The disclosure provides nonsteroidal anti-inflammatory compositions and methods of use thereof. Specifically, the disclosure provides cell-free or substantially cell-free regenerative nonsteroidal anti-inflammatory compositions derived from placenta and/or from MSC cells isolated therefrom, methods for producing said compositions, and uses thereof to treat chronic and acute inflammatory conditions and diseases.