Abstract: This disclosure pertains to a non-living biological product. Particularly, exosomes derived from stem cells can help restore heart function. According to certain embodiments, a fluid-induced shear stress mechanical stimulation process of stem cells is used to augmented quantity and quality of exosomes produced from stem cells. These exosomes serve as a therapeutic agent for the regenerative repair of diseases, such as diseased heart tissues. Therefore, compositions comprising the exosomes derived from stem cells and methods of treating a degenerative disease by administering the exosomes isolated from stem cells are also provided.

Abstract: This disclosure pertains to a non-living biological product. Particularly, exosomes derived from stem cells can help restore heart function. According to certain embodiments, a fluid-induced shear stress mechanical stimulation process of stem cells is used to augmented quantity and quality of exosomes produced from stem cells. These exosomes serve as a therapeutic agent for the regenerative repair of diseases, such as diseased heart tissues. Therefore, compositions comprising the exosomes derived from stem cells and methods of treating a degenerative disease by administering the exosomes isolated from stem cells are also provided.

Abstract: This disclosure pertains to a non-living biological product. Particularly, exosomes derived from stem cells can help restore heart function. According to certain embodiments, a fluid-induced shear stress mechanical stimulation process of stem cells is used to augmented quantity and quality of exosomes produced from stem cells. These exosomes serve as a therapeutic agent for the regenerative repair of diseases, such as diseased heart tissues. Therefore, compositions comprising the exosomes derived from stem cells and methods of treating a degenerative disease by administering the exosomes isolated from stem cells are also provided.

Abstract: The current invention provides novel nitinol alloys, particularly, nitinol alloys containing a third metallic element referred to as ternary nitinol alloys. Accordingly, the current invention provides nitinol alloys including, but not limited to, Nickel-Titanium-Chromium (NiTiCr) and Nickel-Titanium-Tantalum (NiTiTa). The current invention also provides implants manufactured from the ternary nitinol alloys. The implants comprise the ternary nitinol alloys and are, optionally, surface treated to promote anti-thrombogenicity and biocompatibility, for example, through magnetoelectropolishing (MEP). Accordingly, the current invention provides nitinol alloys and implants comprising the nitinol alloys that reduce the risk of clotting due to stagnant blood flow, eliminate flushing, and minimize infection and damage to blood vessels.

Abstract: Described herein is a bioreactor system and modules capable of developing physiologically relevant fluid-induced shear stresses and regionally specific flow patterns to scaffold specimens and which can couple these stresses to cyclic flexure and/or stretch states. Methods of use of the bioreactor system and module also are provided.

Abstract: Described herein is a bioreactor system and modules capable of developing physiologically relevant fluid-induced shear stresses and regionally specific flow patterns to scaffold specimens and which can couple these stresses to cyclic flexure and/or stretch states. Methods of use of the bioreactor system and module also are provided.