A method and device treats cancer where blood from a cancer patient passes through an array of passageways within an interior of a chamber. The passageways include wells having porous membrane wall portions that enable a molecular-sized activating agent in a carrier fluid that enhances an immune response to pass through these porous wall portions. Pore size is such to allow the molecular-sized activating agent in the interior of the chamber to enter the wells yet prevents immune cells and cancer cells in the wells to pass through the porous wall portions into the interior of the chamber. Blood is retained in the wells so that it remains in contact with the immune cells and cancer cells for a predetermined period sufficient to enhance an immune response. Then the cells with an enhanced immune response are return to the patient.

A method for filtering blood is disclosed that in one embodiment includes the steps of depositing unfiltered blood along at least one side of a semi-permeable surface having multiple pores, depositing target tissue along at least an opposing side of the semi-permeable surface, and permitting the unfiltered blood to flow at least partially along the semi-permeable surface to filter the unfiltered blood. Embodiments of the invention can remove self-directed autoantibodies from the blood while reducing the complications of conventional treatments such as plasmaphoresis, and return the patient's own blood cells and its plasma components, less the disease-causing self-directed antibodies. A blood filter and a blood bag are also disclosed.

Disclosed is a method for treating of Cockayne Syndrome (CS). Specifically, the invention pertains to a method for the extracorporeal treatment of a body fluid by removing the body fluid from a living body diseased with CS, and applying a targeted antibody either a mTOR antigen or a DAP1 in a bodily fluid such as blood, creating an antibody-antigen complex, removing antibody-antigen complex from the bodily fluid, and returning the purified bodily fluid to the CS patient.

An object of the present invention is to provide a material which can remove an activated leukocyte-activated platelet complex with high efficiency. The present invention provides a material for removing an activated leukocyte-activated platelet complex, the material being a water-insoluble carrier to the surface of which carrier a compound(s) having a charged functional group(s) is(are) bound, wherein an extending length ratio of the surface is 4 to 7.

The present disclosure provides cell therapy production systems that can suitably be used in a patient bedside setting. Such systems allow for direct removal of a patient's blood, automated processing to produce a cell therapy, and then infusion back into the patient, without the need to remove the system from the patient's bedside. Also provided herein are systems for production of cell therapies in a bedside setting.

The present invention generally relates to systems and methods for targeted removal of a substance or biomolecule such as a protein from a biological fluid, such as blood. In some cases, the blood may be withdrawn from a subject, treated, and returned to the subject. Previous techniques for removal of biological materials from blood, such as hemodialysis and plasmapheresis, were generally non-specific (i.e., they removed a multitude of proteins/toxins from the blood). By contrast, novel methods and devices described herein are capable of removing specific or single substances such as proteins from biological fluids such as blood in a specific manner. Such highly specific protein removal has a broad array of clinical applications, including treatment of inflammatory conditions and autoimmune diseases.

Provided are methods of treating a subject in need of treatment for a disease caused by a loss of function or activity of a protein. Also provided are methods of treating a subject in need of treatment for a disease caused by a gain of function, activity or expression, of a protein.

The present disclosure describes a system and method for microfluidic separation. More particularly, the disclosure describes a system and method for the purification of a fluid by the removal of undesired particles. The device includes microfluidic separation channels that include multiple outlets. The device also includes isolation slots positioned between each of the microfluidic separation channels. The device's base includes multiple acoustic transducers which in some implementations are configured to protrude into the isolation slots. The acoustic transducers are configured to generate aggregation axes within the separation channels, which are used to separate out undesired particles.

The present invention provides biological molecules for use in detecting, identifying and/or removing microbes and microbial components; diagnostic, therapeutic and filtration devices comprising the biological molecules; and systems and methods for treating fluids using the biological molecules and devices of the invention.

Provided herein are bedside, parenterally patient connected, closed-loop and complete systems and methods for cell purification.