The present invention is directed to indirect ultrasonic cavitation-derived perivascular cells, to methods of use of a perivascular cell composition, to a method of processing a tissue and to an apparatus for the processing of a tissue. The methods include the mechanic indirect ultrasonication of a cellular non-structural tissue, and produce a perivascular fraction which includes perivascular cells. The methods of use are directed to the treatment of a variety of diseases and disorders and to the improvement of a tissue in a subject. The apparatus is provided for the processing of cellular non-structural tissue.

The present invention relates to the in vitro production of erythrocytes/granulocytes and to the treatment of myelodysplastic syndrome using a method for inducing hemoblast differentiation. The present invention provides a media composition comprising gelsolin as an active ingredient for inducing the differentiation of hematopoietic precursor cells into erythrocytes/granulocytes, and a pharmaceutical composition comprising gelsolin as an active ingredient for treating myelodysplastic syndrome. Since the composition of the present invention improves the efficiency of differentiation of hematopoietic precursor cells into erythrocytes/granulocytes while maintaining a low rate of occurrence of cell dysplasia and having the effect of improving the enucleation rate and cell survivability, the present invention can be effectively used for producing erythrocytes/granulocytes in vitro and for treating myelodysplastic syndrome.

Disclosed are an inflammation-targeted neutrophil granulocyte drug delivery system and use thereof, wherein the drug delivery system includes neutrophil granulocytes and a therapeutic substance or a detectable substance loaded into the neutrophil granulocytes or onto the surface of the neutrophil granulocytes in a direct or indirect way. By using the neutrophil granulocytes as a carrier of a drug, the drug is actively targeted to an inflammatory site, thereby increasing the drug concentration at the inflammatory site. Under the stimulation of cytokines, the neutrophil granulocytes arriving at the inflammatory site are abnormally activated, disintegrate rapidly, and die in the way of “Neutrophil extracellular traps (NETs)”. This helps to rapidly release the loaded drug to the targeted site, so as to improve the therapeutic effect and reduce the toxic and side effects.

The present invention has an object to solve the problem in a method for separating nucleated cells from a cell-containing fluid using a cell separation filter. Specifically, the present invention provides a cell separation filter and a method for preparing cells using a cell separation filter, which are capable of reducing unnecessary cell contamination in a nucleated cell fraction without needs of designing non-woven fabrics to suit cell species to be recovered. The present invention also provides a cell separation filter and a method for preparing cells using the filter capable of improving the recovery yield of nucleated cells. The present invention provides a cell separation filter comprising: a container having an inlet and an outlet, an adsorbent filled in the container, and a partition having an opening, the partition separating the adsorbent. The present invention also provides a method for preparing nucleated cells including the steps of: introducing a cell-containing fluid through the inlet of the cell separation filter to contact the cell-containing fluid with the adsorbent; and recovering a nucleated cell fraction from the filter.

The present invention relates to the discovery of a role of the nuclear receptor retinoid-related orphan receptor gamma (RORgamma) in tumor suppression. The introduction and expression of RORgamma result in genes activation within innate immune cells that trigger recognition and suppression of tumor cells. Thus, in various embodiments described herein, the invention encompasses a composition or a cell comprising a viral vector comprising nucleic acid sequences encoding RORgamma under the control of a neutrophil specific promoter. Additionally, the invention relates to methods of treating cancer by administering to a subject a composition that confers or increases innate immune cell anti-tumor immunity, methods for providing anti-tumor immunity in a subject, methods of stimulating innate immune response to a cell population or a tissue in a mammal and methods of diagnosing anti-tumor immunity response. Furthermore, the invention encompasses a kit for carrying out the aforementioned methods.

Described herein is a novel, highly efficient system to remove erythrocytes and purify leukocytes would raise the quality of UCB and other transplant grafts, thereby significantly improving patient outcomes.

A pure platelet-rich plasma (P-PRP) composition as an alternative to conventional antibiotic treatment of subclinical mastitis caused by Gram-positive bacteria in bovine including five live platelets and leukocytes, an anticoagulant, and an activating substance.

This disclosure describes, generally, a modified form of CD16, genetically-modified cells that express the modified CD16, and methods that involve the genetically-modified cells. The modified form of CD16 can exhibit increased anti-tumor and/or anti-viral activity due, at least in part, to reduced susceptibility to ADAM17-mediated shedding upon NK cell stimulation.

The present disclosure provides a superparamagnetism-modified and neutrophil exosome biomimetic vesicle-based biological preparation for drug delivery, and a preparation method thereof, belonging to the technical field of engineered nanovesicle drug loading systems. The superparamagnetism-modified and neutrophil exosome biomimetic vesicle-based biological preparation for drug delivery prepared by the preparation method acts on tumor cell lines. It is found that the superparamagnetism-modified and neutrophil exosome biomimetic vesicle-based biological preparation for drug delivery can specifically target tumor cells, induce tumor cell apoptosis, and inhibit tumor growth. The biological preparation significantly extends a survival time of mice and improves an efficacy of drugs against cancers.

Disclosed are compositions comprising chimeric antigen receptors (CARs) and related methods of use in cancer immunotherapy. Compositions include reprogrammed immune cells (e.g., macrophages, neutrophils, dendritic cells, and T cells) that are metabolically fit for tumor microenvironments. The engineered immune cells are reprogrammed to express one or more of recombinant CARs at their cell surfaces and are loaded with glycolysis accelerating metabolites (e.g., F16BP or succinate). Methods of treating a subject with a condition, such as cancer, are also disclosed and include administering an effective amount of a composition comprising an engineered immune cell to a subject in need thereof.