Unknown

Dataset Information

0

Injectable osteogenic microtissues containing mesenchymal stromal cells conformally fill and repair critical-size defects.

ABSTRACT: Repair of complex fractures with bone loss requires a potent, space-filling intervention to promote regeneration of bone. We present a biomaterials-based strategy combining mesenchymal stromal cells (MSC) with a chitosan-collagen matrix to form modular microtissues designed for delivery through a needle to conformally fill cavital defects. Implantation of microtissues into a calvarial defect in the mouse showed that osteogenically pre-differentiated MSC resulted in complete bridging of the cavity, while undifferentiated MSC produced mineralized tissue only in apposition to native bone. Decreasing the implant volume reduced bone regeneration, while increasing the MSC concentration also attenuated bone formation, suggesting that the cell-matrix ratio is important in achieving a robust response. Conformal filling of the defect with microtissues in a carrier gel resulted in complete healing. Taken together, these results show that modular microtissues can be used to augment the differentiated function of MSC and provide an extracellular environment that potentiates bone repair.

SUBMITTER: Annamalai RT 

PROVIDER: S-EPMC6500486 | biostudies-literature | 2019 Jul

REPOSITORIES: biostudies-literature

Json Xml
altmetric image

Publications

Injectable osteogenic microtissues containing mesenchymal stromal cells conformally fill and repair critical-size defects.

Annamalai Ramkumar T RT   Hong Xiaowei X   Schott Nicholas G NG   Tiruchinapally Gopinath G   Levi Benjamin B   Stegemann Jan P JP  

Biomaterials 20190404

Repair of complex fractures with bone loss requires a potent, space-filling intervention to promote regeneration of bone. We present a biomaterials-based strategy combining mesenchymal stromal cells (MSC) with a chitosan-collagen matrix to form modular microtissues designed for delivery through a needle to conformally fill cavital defects. Implantation of microtissues into a calvarial defect in the mouse showed that osteogenically pre-differentiated MSC resulted in complete bridging of the cavit  ...[more]

Similar Datasets

Unknown Human adipose derived stromal cells heal critical size mouse calvarial defects.
| S-EPMC2887361 | biostudies-literature
Unknown SHED repair critical-size calvarial defects in mice.
| S-EPMC2653202 | biostudies-literature
Unknown Bone marrow-derived stem/stromal cells (BMSC) 3D microtissues cultured in BMP-2 supplemented osteogenic induction medium are prone to adipogenesis.
| S-EPMC6267724 | biostudies-literature
Unknown Low-dose bone morphogenetic protein-2/stromal cell-derived factor-1? cotherapy induces bone regeneration in critical-size rat calvarial defects.
| S-EPMC4012411 | biostudies-literature
Transcriptomics Restoring Bone Regeneration in Critical Size Defects through Local Delivery of Angiogenic Factors
2024-08-08 | GSE262544 | GEO
Unknown Negative pressure therapy stimulates healing of critical-size calvarial defects in rabbits.
| S-EPMC3722738 | biostudies-other
Unknown Repairing Osteochondral Defects of Critical Size Using Multiple Costal Grafts: An Experimental Study.
| S-EPMC4568731 | biostudies-literature
Unknown Gradients in pore size enhance the osteogenic differentiation of human mesenchymal stromal cells in three-dimensional scaffolds.
| S-EPMC4790631 | biostudies-literature
Unknown Size does matter: an integrative in vivo-in silico approach for the treatment of critical size bone defects.
| S-EPMC4222588 | biostudies-literature
Unknown Genetically Engineered-MSC Therapies for Non-unions, Delayed Unions and Critical-size Bone Defects.
| S-EPMC6678255 | biostudies-literature