Abstract: The disclosure is and includes at least an apparatus, system and method printing multilayer circuits on graphics. The multilayer print may include forming an electronic human machine interface, sensor readout, or a driver circuit, by way of example, and may include successively printing at least two functional ink layers comprising at least one conductive layer and at least one dielectric layer on a substrate comprising one of a thermoform and an overmold; printing at least one non-conductive graphical ink layer in the succession of the successively printing; curing each of the successively printed layers after the printing of each of the successively printed layers, wherein the curing of the successively printed functional ink layers comprises at least an ultra-violet curing; and squeegeeing at least the at least one conductive layer with a squeegee having a low durometer.

Abstract: The disclosure is and includes at least an apparatus, system and method printing multilayer circuits on graphics. The multilayer print may include forming an electronic human machine interface, sensor readout, or a driver circuit, by way of example, and may include successively printing at least two functional ink layers comprising at least one conductive layer and at least one dielectric layer on a substrate comprising one of a thermoform and an overmold; printing at least one non-conductive graphical ink layer in the succession of the successively printing; curing each of the successively printed layers after the printing of each of the successively printed layers, wherein the curing of the successively printed functional ink layers comprises at least an ultra-violet curing; and squeegeeing at least the at least one conductive layer with a squeegee having a low durometer.

Abstract: A method for flexible hybrid electronics (FHE) simultaneous printing of a plurality of electrical devices. The method includes providing a flexible substrate having a top surface and a bottom surface and providing vias through the substrate for all of the plurality of electrical devices. The method also includes printing circuit elements for the plurality of devices on the top surface of the substrate using a conductive ink, and printing circuit elements for the plurality of devices on the bottom surface of the substrate using the conductive ink, where printing the circuit elements on the top and bottom surfaces of the substrate causes the ink to flow through the vias to provide an electrical connection between the circuit elements on the top and bottom surfaces.

Abstract: The disclosure is and includes at least an apparatus, system and method printing multilayer circuits on graphics. The multilayer print may include forming an electronic human machine interface, sensor readout, or a driver circuit, by way of example, and may include successively printing at least two functional ink layers comprising at least one conductive layer and at least one dielectric layer on a substrate comprising one of a thermoform and an overmold; printing at least one non-conductive graphical ink layer in the succession of the successively printing; curing each of the successively printed layers after the printing of each of the successively printed layers, wherein the curing of the successively printed functional ink layers comprises at least an ultra-violet curing; and squeegeeing at least the at least one conductive layer with a squeegee having a low durometer.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.

Abstract: In alternative embodiments, provided are macrocellular structures or artificially configured plurality of cells, the so-called “cardioclusters” as provided herein, comprising: a core region or cluster: comprising a plurality of first cardiac stem cells or cardiac progenitor cells; and a second region or a peripheral region positioned at least partially surrounding the outer surface of the core region or cluster, or at least partially around the core region or cluster, comprising a plurality of second cardiac stem cells; and methods for making and using them. In alternative embodiments, the second cardiac progenitor cells are cardiac progenitor cells or cardiac stem cells, mesenchymal stem cells or mesenchymal progenitor cells, or endothelial progenitor cells or endothelial stem cells.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.

Abstract: In alternative embodiments, provided are chimeric cells, which in alternative embodiments are the so-called “cardiochimeras”, and methods for making and using them. In alternative embodiments, exemplary chimeric cells as provided herein comprise a cardiac stem cell of cardiac origin or a cardiac progenitor cell fused to either a mesenchymal progenitor cell or mesenchymal stem cell, an endothelial progenitor cell or endothelial stem cell, or a cardiac stem cell or a cardiac progenitor cell. In alternative embodiments, the chimeric cells as provided herein comprise an endothelial progenitor cell, which may or may not be of cardiac origin, fused to either a mesenchymal progenitor cell or mesenchymal stem cell, an endothelial progenitor cell or endothelial stem cell, or a cardiac stem cell or a cardiac progenitor cell. In alternative embodiments, methods for making chimeric cells as provided herein further comprise selecting a cell fusion product comprising a viable chimera of the fused cells.

Abstract: In alternative embodiments, provided are chimeric cells, which in alternative embodiments are the so-called “cardiochimeras”, and methods for making and using them. In alternative embodiments, exemplary chimeric cells as provided herein comprise a cardiac stem cell of cardiac origin or a cardiac progenitor cell fused to either a mesenchymal progenitor cell or mesenchymal stem cell, an endothelial progenitor cell or endothelial stem cell, or a cardiac stem cell or a cardiac progenitor cell. In alternative embodiments, the chimeric cells as provided herein comprise an endothelial progenitor cell, which may or may not be of cardiac origin, fused to either a mesenchymal progenitor cell or mesenchymal stem cell, an endothelial progenitor cell or endothelial stem cell, or a cardiac stem cell or a cardiac progenitor cell. In alternative embodiments, methods for making chimeric cells as provided herein further comprise selecting a cell fusion product comprising a viable chimera of the fused cells.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.

Abstract: In alternative embodiments, provided are macrocellular structures or artificially configured plurality of cells, the so-called “cardioclusters” as provided herein, comprising: a core region or cluster: comprising a plurality of first cardiac stem cells or cardiac progenitor cells; and a second region or a peripheral region positioned at least partially surrounding the outer surface of the core region or cluster, or at least partially around the core region or cluster, comprising a plurality of second cardiac stem cells; and methods for making and using them. In alternative embodiments, the second cardiac progenitor cells are cardiac progenitor cells or cardiac stem cells, mesenchymal stem cells or mesenchymal progenitor cells, or endothelial progenitor cells or endothelial stem cells.

Abstract: Disclosed are methods of protecting cells, especially non-vascular system, non-hematopoietic cells and tissues, from apoptosis and enhancing their engraftment, survival, and/or persistence by providing enhanced levels of PIM activity for the cell, including PIM-1 activity. Also disclosed are cells that have been engineered to express enhanced levels of PIM kinase, and methods of administering those cells to vertebrates.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.

Abstract: Disclosed are methods of protecting cells, especially non-vascular system, non-hematopoietic cells and tissues, from apoptosis and enhancing their engraftment, survival, and/or persistence by providing enhanced levels of PIM activity for the cell, including PIM-1 activity. Also disclosed are cells that have been engineered to express enhanced levels of PIM kinase, and methods of administering those cells to vertebrates.

Abstract: The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding the serine/threonine kinase PIM-1, and methods for making and using them; including methods for inducing cellular proliferation, and protecting cardiac cells from hypoxia and cellular apoptosis. The invention provides compositions (e.g., pharmaceutical compositions) comprising nucleic acids encoding PIM-1, and methods for enhancing the regenerative potential of stem cells in the heart.