An organ-on-a-chip microfluidic device is disclosed that mimics a human lymph node and/or human lymphoid tissue. The device can include cells from human blood and lymphatic tissue, include an extracellular matrix for the development of immune system components, and provide for the perfusion of fluids and solids resembling blood and lymphatic fluid within micrometer sized channels.

The present invention relates to the field of implants for the formation/regeneration of lymph nodes. In particular, the present invention relates to an implant comprising a biodegradable scaffold and lymph node fragments immobilized therein and/or thereon, to a method of manufacturing such an implant and to uses of such an implant.

ILC2 cells play a role in the pathogenesis of graft versus host disease (GvHD) and idiopathic pneumonia syndrome (IPS), both conditions associated with allogeneic stem cell transplantation. Infusion of IL-33 activated ILC2 cells into patients with ongoing GvHD or IPS, or prior to onset of GvHD or IPS in susceptible patients, substantially ameliorates the disease and improves survival.

A method for suppressing an immune response is provided. The method involves administration of isolated lymphoid tissue-derived suppressive stromal cells (LSSC) to a subject in need of such treatment in an amount effective to suppress the immune response in the subject. The invention also involves a method to isolate LSSC by digesting lymphoid tissue fragments using a combination of an enzyme mix and agitation and then collecting the LSSC. Pharmaceutical preparations comprising LSSC are also provided.

An organ-on-a-chip microfluidic device is disclosed that mimics a human lymph node and/or human lymphoid tissue. The device can include cells from human blood and lymphatic tissue, include an extracellular matrix for the development of immune system components, and provide for the perfusion of fluids and solids resembling blood and lymphatic fluid within micrometer sized channels.

Provided are a method for producing a cell tissue, including a culturing step of culturing cells capable of serving as a feeder inside opening pores and communicating pores of a porous film having a plurality of the opening pores provided on a surface thereof and the communicating pores communicating mutually adjacent opening pores with one another; and a porous film including a plurality of opening pores provided on a surface thereof and communicating pores communicating mutually adjacent opening pores with one another.

The present invention relates to: a method for producing a spheroid form of tonsil-derived stem cells, the method enhancing growth and differentiation efficiency of tonsil-derived stem cells; and a method for producing a spheroid form of parathyroid hormones from the same. The method of the present invention for producing a spheroid form of tonsil-derived stem cells cultures the tonsil-derived stem cells in the form of a spheroid to thereby enhance the proliferation rate of the stem cells per se and remarkably increase differentiation potency into parathyroid cells. Thereby, the method has a remarkable effect on the growth and differentiation of the tonsil-derived stem cells into parathyroid cells, etc.

The present application relates to tumor-associated dendritic cell (TADC) preparations and their use in treatment of tumor metastasis.

A method for suppressing an immune response is provided. The method involves administration of isolated lymphoid tissue-derived suppressive stromal cells (LSSC) to a subject in need of such treatment in an amount effective to suppress the immune response in the subject. The invention also involves a method to isolate LSSC by digesting lymphoid tissue fragments using a combination of an enzyme mix and agitation and then collecting the LSSC. Pharmaceutical preparations comprising LSSC are also provided.

Disclosed herein are methods, systems and devices to model adaptive immune responses and develop and/or test improved antibodies, vaccines, and other therapeutic agents. The adaptive immune responses can be modeled using lymphoid tissue derived from a subject. The methods, systems and devices disclosed herein can comprise modified T-cells.