The present invention is drawn, in part, to biocompatible compositions comprising a biocompatible polymer matrix and conditioned cell medium comprising i) a cell culture medium and ii) one or more agents synthesized by and secreted from one or more cells cultured in the cell culture medium, as well as therapeutic uses thereof, particularly in modulating bone and/or gum tissue growth.

The present invention is drawn, in part, to biocompatible compositions comprising a biocompatible polymer matrix and conditioned cell medium comprising i) a cell culture medium and ii) one or more agents synthesized by and secreted from one or more cells cultured in the cell culture medium, as well as therapeutic uses thereof, particularly in modulating bone and/or gum tissue growth.

The described invention provides an ex vivo dynamic multiple myeloma cancer niche contained in a pumpless perfusion culture device. The dynamic multiple myeloma cancer niche includes (a) a three-dimensional tissue construct containing a dynamic ex vivo bone marrow niche, which contains a mineralized bone-like tissue containing viable osteoblasts self-organized into cohesive multiple cell layers and an extracellular matrix secreted by the viable adherent osteoblasts; and a microenvironment dynamically perfused by nutrients and dissolved gas molecules; and (b) human myeloma cells seeded from a biospecimen composition comprising mononuclear cells and the multiple myeloma cells. The human myeloma cells are in contact with osteoblasts of the bone marrow niche, and the viability of the human myeloma cells is maintained by the multiple myeloma cancer niche.

The present invention relates to compositions comprising induced T regulatory cells (iTregs), methods of making the compositions, and methods of using the compositions for enhancing bone remodeling in the treatment of Osteogenesis Imperfecta (OI).

A 3D decellularized bone scaffold seeded with cancer cells, such as prostate cancer cells or Ewing's sarcoma is provided. The three-dimensional includes Ewing's sarcoma (ES) tumor cells; and an engineered human bone scaffold. The engineered human bone scaffold further includes osteoblasts that secrete substance of the human bone, and osteoclasts that absorb bone tissue during growth and healing. The engineered human bone scaffold includes the tissue engineered three-dimensional model which recapitulates the osteolytic process. The engineered human bone scaffold is engineered by co-culturing of osteoblasts and osteoclasts. The osteoblast is produced by cell differentiation process from mesenchymal stem cells. The osteoclast is produced by cell differentiation from human monocytes, wherein the human monocytes are isolated from buffy coats. The scaffold can be used with cancer cell lines to identify therapeutic targets to slow, stop, and reverse tumor growth and progression as well as to predict the efficacy of potential therapeutics.

A 3D decellularized bone scaffold seeded with cancer cells, such as prostate cancer cells or Ewing's sarcoma is provided. The three-dimensional includes Ewing's sarcoma (ES) tumor cells; and an engineered human bone scaffold. The engineered human bone scaffold further includes osteoblasts that secrete substance of the human bone, and osteoclasts that absorb bone tissue during growth and healing. The engineered human bone scaffold includes the tissue engineered three-dimensional model which recapitulates the osteolytic process. The engineered human bone scaffold is engineered by co-culturing of osteoblasts and osteoclasts. The osteoblast is produced by cell differentiation process from mesenchymal stem cells. The osteoclast is produced by cell differentiation from human monocytes, wherein the human monocytes are isolated from buffy coats. The scaffold can be used with cancer cell lines to identify therapeutic targets to slow, stop, and reverse tumor growth and progression as well as to predict the efficacy of potential therapeutics.

The present application relates to methods of activating a NK cells in vitro, ex vivo, and/or in vivo by an osteoclast cell (OC) and/or a dendritic cell, and methods of treating disease using these activated NK cells.

The described invention provides an ex vivo dynamic multiple myeloma cancer niche contained in a pumpless perfusion culture device. The dynamic multiple myeloma cancer niche includes (a) a three-dimensional tissue construct containing a dynamic ex vivo bone marrow niche, which contains a mineralized bone-like tissue containing viable osteoblasts self-organized into cohesive multiple cell layers and an extracellular matrix secreted by the viable adherent osteoblasts; and a microenvironment dynamically perfused by nutrients and dissolved gas molecules; and (b) human myeloma cells seeded from a biospecimen composition comprising mononuclear cells and the multiple myeloma cells. The human myeloma cells are in contact with osteoblasts of the bone marrow niche, and the viability of the human myeloma cells is maintained by the multiple myeloma cancer niche.

The present invention is drawn, in part, to biocompatible compositions comprising a biocompatible polymer matrix and conditioned cell medium comprising i) a cell culture medium and ii) one or more agents synthesized by and secreted from one or more cells cultured in the cell culture medium, as well as therapeutic uses thereof, particularly in modulating bone and/or gum tissue growth.

The present application relates to methods of activating a NK cells in vitro, ex vivo, and/or in vivo by an osteoclast cell (OC) and/or a dendritic cell, and methods of treating disease using these activated NK cells.