The invention provides methods, compositions, and medical kits comprising a nitrite-reductase promoter, such as an allosteric modulator of hemoglobin, for use in treating medical disorders and preservation of blood products. In one aspect, the invention provides methods, compositions, and medical kits comprising an inorganic nitrite salt and a nitrite-reductase promoter, such as an allosteric modulator of hemoglobin, for use in treating medical disorders, such as cancer, cardiovascular disorders, ischemic conditions, hemolytic conditions, and bacterial infections. Exemplary inorganic nitrite salts include sodium nitrite and arginine nitrite. Exemplary allosteric modulators of hemoglobin described herein include alkyl-substituted and acyl-substituted di-nitroheterocycles.

This automated analysis device is provided with a plurality of analysis units for analyzing a specimen, a buffer portion which holds a plurality of specimen racks on which are placed specimen containers holding the specimen, a sampler portion which conveys the specimen racks held in the buffer portion to the analysis units, and a control portion which, when performing a process to deliver the specimen racks to the plurality of analysis units, outputs synchronization signals to all the plurality of analysis units, wherein the analysis unit performs a delivery process starting from the synchronization signal, and the analysis unit performs a delivery process starting from the synchronization signal.

Production of “regenerative medicine products” is facilitated using a quality by design (QbD) approach. A production device produces a medical product and analyzes a starting material and a central management device determines processing conditions in the production device. By transmitting and receiving data pertaining to the starting material between the production device and central management device data, the medical product is produced while production conditions therefor are continuously optimized. Thus, it is easy to produce a medical product while reducing or eliminating effects from changes in cells and tissues over time, from oscillation during transport, and from changes in surrounding environment such as changes in temperature, and to produce the desired medical product even when there are individual differences in the starting material.

Production of “regenerative medicine products” is facilitated using a quality by design (QbD) approach. A production device produces a medical product and analyzes a starting material and a central management device determines processing conditions in the production device. By transmitting and receiving data pertaining to the starting material between the production device and central management device data, the medical product is produced while production conditions therefor are continuously optimized. Thus, it is easy to produce a medical product while reducing or eliminating effects from changes in cells and tissues over time, from oscillation during transport, and from changes in surrounding environment such as changes in temperature, and to produce the desired medical product even when there are individual differences in the starting material.

In certain embodiments methods of treating X-Linked Hyper-IgM Syndrome (XHIM) in a mammal am provided where the methods comprise: i) providing differentiated T cells and/or stem/progenitor cells from the mammal; ii) performing a targeted insertion of a corrective CD40L cDNA at the CD40LG gene locus in said cells to provide a corrected CD40LG gene wherein said targeted insertion places said corrective CD40L cDNA downstream and operably linked to the endogenous CD40LG enhancer/promoter, and iii) introducing said cells into said mammal where said corrected CD40LG gene is expressed in a physiologically regulated manner.

Inhibition of the VIP signaling pathway with VIP antagonist is contemplated. In certain embodiments, the disclosure relates to methods of enhancing the immune response to a cell therapy comprising administering a VIP antagonist to a subject in combination with a cell. In certain embodiments, the subject is diagnosed with leukemia or lymphoma. In certain embodiments, the cell is a blood cell, bone marrow cell, leukocyte, T-cell, natural killer cell, a hematopoietic stem cell, a G-CSF mobilized or non-mobilized blood mononuclear cell.

Inhibition of the VIP signaling pathway with VIP antagonist is contemplated. In certain embodiments, the disclosure relates to methods of enhancing the immune response to a cell therapy comprising administering a VIP antagonist to a subject in combination with a cell. In certain embodiments, the subject is diagnosed with leukemia or lymphoma. In certain embodiments, the cell is a blood cell, bone marrow cell, leukocyte, T-cell, natural killer cell, a hematopoietic stem cell, a G-CSF mobilized or non-mobilized blood mononuclear cell.

The present invention relates to compositions of extracellular vesicles (EVs) which are characterized by a strong proangiogenic activity and are effective in the therapeutic treatment of ischemic diseases and ischemic injuries or in wound healing. The extracellular vesicles (EVs) suitable for use in the compositions of the invention are either derived from a blood component or are selected by means of a potency test for pro-angiogenesis. Also disclosed is a method of manufacturing a pharmaceutical preparation of extracellular vesicles (EVs) characterized by a strong proangiogenic activity.

The present invention relates to compositions of extracellular vesicles (EVs) which are characterized by a strong proangiogenic activity and are effective in the therapeutic treatment of ischemic diseases and ischemic injuries or in wound healing. The extracellular vesicles (EVs) suitable for use in the compositions of the invention are either derived from a blood component or are selected by means of a potency test for pro-angiogenesis. Also disclosed is a method of manufacturing a pharmaceutical preparation of extracellular vesicles (EVs) characterized by a strong proangiogenic activity.

Cancer treatment methods that include adjusting the concentration of selected metabolites in a blood supply to yield a perfusate with metabolite concentrations that promote terminal cellular differentiation in a tumor and delivering the perfusate to an artery of a patient. In some examples, the methods include adjusting the concentration of glycerol in a blood supply to yield a perfusate with reduced osmotic pressure, adjusting the concentration of ascorbic acid in the perfusate to maintain a selected redox potential, adjusting the concentration of glutamine in the perfusate to downregulate histone deacetylases, adjusting the concentration of butyrate in the perfusate to signal starvation, and delivering the perfusate to an artery of a patient, wherein the concentrations of glycerol, ascorbic acid, glutamine, and butyrate are selected to promote terminal cellular differentiation in a tumor.