Motion of Molecules in Supramolecular Scaffolds Enhances Bone Regeneration

化学 超分子化学 再生(生物学) 分子 纳米技术 细胞生物学 有机化学 生物 材料科学
作者
Ruomeng Qiu,Wei Ji,Zaida Álvarez,Hiroaki Sai,Zijun Gao,Feng Chen,Alexander Linton,Nicholas Lanzetta,Deleted Author ID,Hogan Brecount,Jingyuan Li,Jacqueline Inglis,Steven Kurapaty,Stuart R. Stock,Wellington K. Hsu,Liam C. Palmer,Erin L. Hsu,Samuel I. Stupp
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:147 (25): 21586-21599
标识
DOI:10.1021/jacs.5c02930
摘要

The regeneration of human tissues is a great scientific challenge and a critical factor to achieve a long healthspan and prevent disabilities due to injury or disease. Materials chemistry can contribute to this goal with the development of bioactive supramolecular systems that can signal cells for regeneration. Recent work in our laboratory using in vivo models of spinal cord injury and cartilage regeneration has demonstrated that the motion of bioactive molecules in supramolecular scaffolds enhances receptor signaling. We report here on a novel molecular strategy to control supramolecular motion in filamentous assemblies using bone regeneration as a functional target. The supramolecular assemblies are composed of monomers that arrange, by design, with either parallel or antiparallel β-sheets, and some of them contain a terminal peptide sequence that binds BMP-2. We found that parallel β-sheet supramolecular assemblies promote greater osteogenic differentiation of progenitor cells in vitro relative to antiparallel assemblies, as well as superior quality of newly regenerated bone in a rat model of spinal fusion. Furthermore, these assemblies drastically reduce the dangerous supraphysiological dose of BMP-2 used clinically for spinal fusion. We attribute the enhanced bioactivity to the weaker nature of hydrogen bonds in parallel relative to antiparallel β-sheet assemblies, which in turn allows greater supramolecular motion and cell signaling of the growth factor-binding molecules.
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