A method of acoustophoresis using selection particles that alter acoustic response is provided. The method can include selecting a set of selection particles based on surface markers of a plurality of target particles to be separated using acoustophoresis. The method can include incubating the set of selection particles with the plurality of target particles in a solution such that the set of selection particles bind with the surface markers on the plurality of target particles to create a plurality of bound particles. The method can include providing the plurality of bound particles to an acoustophoresis device tuned to separate the particles based on a net acoustic contrast between each of the plurality of bound particles. The method can include receiving a plurality of output streams from the acoustophoresis device that each include a respective bound particle of the plurality of bound particles.

The present invention relates to a method for diagnosis of delayed bone fracture healing, comprising determining the frequency of a subpopulation of CD8+ cells selected from a first group comprised of CD8+CD57+, CD8+CD28− and CD8+CD28−/CD57+, in a sample obtained from a subject. The present invention further relates to a system and a kit of parts for prediction and resulting options for preventing of delayed bone fracture healing.

The present invention relates to a method for providing a neopeptide-specific T cell, wherein the neopeptide-specific T cell forms a complex having a half-life (T½) of at least 50 s with a neopeptide-MHC monomer. The present invention further relates to a T cell obtainable by the method as well as a pharmaceutical composition comprising such T cells.

The invention relates to peripheral blood mononuclear cell (PBMC) monolayers or bone-marrow cell monolayers and methods for its culture and corresponding uses of said monolayers. The present invention also relates, in some aspects, to screening methods comprising the PBMC monolayer or bone-marrow cell monolayer of the invention for determination of response or lack of response of a disease to a therapeutic agent and/or drug screening methods. In some aspects, the invention further relates to methods for diagnosing a disease or predisposition to a disease in a PBMC donor or bone-marrow cell donor comprising the PBMCs/bone-marrow cells cultured according to the method of the invention and/or to methods for determining whether the disease is likely to respond or is responsive to treatment with a therapeutic agent.

The present invention is directed to methods of using biomarkers to assess treatment of gastrointestinal inflammatory disorders with beta7 antagonists. More particularly, the present invention relates to methods of using the level of gut-homing lymphocytes in peripheral blood, the level of drug occupancy on gut-homing lymphocytes, and/or the level of beta7 integrin receptors on gut-homing lymphocytes as indicators (or biomarkers) of the effect, efficacy, safety, prognosis, and/or dosing of therapeutic agents, such as beta7 integrin antagonists, for the treatment of gastrointestinal inflammatory disorders.

Provided herein are compositions and methods for identifying cancer cells. In particular, provided herein are optimized assays for identifying a variety of different cancer cells present in a sample at low concentrations.

The invention relates to peripheral blood mononuclear cell (PBMC) monolayers or bone-marrow cell monolayers and methods for its culture and corresponding uses of said monolayers. The present invention also relates, in some aspects, to screening methods comprising the PBMC monolayer or bone-marrow cell monolayer of the invention for determination of response or lack of response of a disease to a therapeutic agent and/or drug screening methods. In some aspects, the invention further relates to methods for diagnosing a disease or predisposition to a disease in a PBMC donor or bone-marrow cell donor comprising the PBMCs/bone-marrow cells cultured according to the method of the invention and/or to methods for determining whether the disease is likely to respond or is responsive to treatment with a therapeutic agent.

The present disclosure relates in some aspects to methods, cells, and compositions for preparing cells and compositions for genetic engineering and cell therapy. Provided in some embodiments are streamlined cell preparation methods, e.g., for isolation, processing, incubation, and genetic engineering of cells and populations of cells. Also provided are cells and compositions produced by the methods and methods of their use. The cells can include immune cells, such as T cells, and generally include a plurality of isolated T cell populations or types. In some aspects, the methods arc capable of preparing of a plurality of different cell populations for adoptive therapy using fewer steps and/or resources and/or reduced handling compared with other methods.

Multispecific antibodies binding to human CD40 and human CD137, methods for preparing such multispecific antibodies, and methods of using such multispecific antibodies for therapeutic or other purposes.

The present invention relates to peptides and their ability to identify and bind to T cells specific for HBV-infected hepa-tocytes. In an first aspect of the invention, there is provided a peptide comprising an amino sequence selected from the group consisting of STLPETAVVRR, STLPETAVVR, STLPETTVVRR, STLPETTVIRR, STPPETTVVRR, STLPETTVVGR and STIPETTVVRR, wherein the peptide is derived from Hepatitis B virus core169 and is capable of binding HLA-A*1101 and when bound to HLA-A*1101 s capable of identifying T cells specific for Hepatitis B virus. In a second aspect of the invention, there is provided A T cell expressing a T cell receptor (TCR) molecule, wherein the TCR molecule comprises an amino acid sequence selected from the group comprising: CASGDSNSPLHF, CASSGGQIVYEQYF, CSARGGRGGDYTF and CASSQDWTEAFF, the T cell receptor is able to bind to a pep-tide according to the first aspect of the invention.