Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Described herein are compositions and methods related to derivation of human notochordal cells differentiated from induced pluripotent stem cells (iPSCs). The inventors have developed a two-step process for generating these iPSC-derived notochordal cells (iNCs), which can provide a renewable source of therapeutic material for use in degenerative disc disease (DDD). As iNCs are capable of reversing DDD and supporting regeneration of intervertebral disc (IVD) tissue based on the understanding that NC cells maintain homeostasis and repair of other IVD cell types such as nuclear pulposus (NP).

Abstract: An osteogenic composition for implantation at or near a target tissue site beneath the skin is provided, the osteogenic composition comprising bone morphogenetic protein and a NEMO binding domain peptide, where the NEMO binding domain peptide reduces soft tissue inflammation at or near the target tissue site. In some embodiments, a method is provided for treating a target tissue site in a patient in need of such treatment, the method comprising implanting an osteogenic composition comprising bone morphogenetic protein and a NEMO binding domain peptide, where the NEMO binding domain peptide reduces soft tissue inflammation at or near the target tissue site.

Abstract: Described herein are methods and compositions using PTH and mesenchymal stem cells (MSCs) for treatment of osteoporosis, bone fractures, and related conditions. Administration of both PTH and MSCs leads to increased homing of MSCs to sites of vertebral bone and rib fracture. The described methods and compositions provide therapeutic approaches that rely, in-part, on stem cell capacity for regeneration and repair. The potential for enhanced bone formation and fracture repair may allow for both preventative and palliative treatments in osteoporotic patients, with combined PTH+MSC therapy producing bone regeneration capacity that is significantly superior to either treatment alone.

Abstract: An osteogenic composition for implantation at or near a target tissue site beneath the skin is provided, the osteogenic composition comprising bone morphogenetic protein and a NEMO binding domain peptide, where the NEMO binding domain peptide reduces soft tissue inflammation at or near the target tissue site. In some embodiments, a method is provided for treating a target tissue site in a patient in need of such treatment, the method comprising implanting an osteogenic composition comprising bone morphogenetic protein and a NEMO binding domain peptide, where the NEMO binding domain peptide reduces soft tissue inflammation at or near the target tissue site.

Abstract: Described herein are compositions and methods related to derivation of human notochordal cells differentiated from induced pluripotent stem cells (iPSCs). The inventors have developed a two-step process for generating these iPSC-derived notochordal cells (iNCs), which can provide a renewable source of therapeutic material for use in degenerative disc disease (DDD). As iNCs are capable of reversing DDD and supporting regeneration of invertebral disc (IVD) tissue based on the understanding that NC cells maintain homeostasis and repair of other IVD cell types such as nuclear pulposus (NP).

Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Microfluidic “organ-on-a-chip” devices have been developed with the aim to replicate human tissues in vitro. However, there is no option to quantitatively monitor biological processes that take place within the chip, over time. Destructive methods in order to analyze, tissue formation, gene expression, protein secretion etc. require the harvest of the “tissue” at a certain time point. Described herein are methods and compositions for non-destructive molecular imaging methods and systems in order to quantitatively monitor specific biological processes, over time, within the chip, without the need to harvest.

Abstract: Described herein are methods and compositions using PTH and mesenchymal stem cells (MSCs) for treatment of osteoporosis, bone fractures, and related conditions. Administration of both PTH and MSCs leads to increased homing of MSCs to sites of vertebral bone and rib fracture. The described methods and compositions provide therapeutic approaches that rely, in-part, on stem cell capacity for regeneration and repair. The potential for enhanced bone formation and fracture repair may allow for both preventative and palliative treatments in osteoporotic patients, with combined PTH+MSC therapy producing bone regeneration capacity that is significantly superior to either treatment alone.