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W3178959923 abstract "Abstract Background The therapeutic potential of exosomes derived from stem cells has attracted increasing interest recently, because they can exert similar paracrine functions of stem cells and overcome the limitations of stem cells transplantation. Exosomes derived from bone mesenchymal stem cells (BMSC-Exos) have been confirmed to promote osteogenesis and angiogenesis. The magnetic nanoparticles (eg. Fe 3 O 4 , γ-Fe 2 O 3 ) combined with a static magnetic field (SMF) has been commonly used to increase wound healing and bone regeneration. Hence, this study aims to evaluate whether exosomes derived from BMSCs preconditioned with a low dose of Fe 3 O 4 nanoparticles with or without the SMF, exert superior pro-osteogenic and pro-angiogenic activities in bone regeneration and the underlying mechanisms involved. Methods Two novel types of exosomes derived from preconditioned BMSCs that fabricated by regulating the contents with the stimulation of magnetic nanoparticles and/or a SMF. Then, the new exosomes were isolated by ultracentrifugation and characterized. Afterwards, we conducted in vitro experiments in which we measured osteogenic differentiation, cell proliferation, cell migration, and tube formation, then established an in vivo critical-sized calvarial defect rat model. The miRNA expression profiles were compared among the exosomes to detect the potential mechanism of improving osteogenesis and angiogenesis. At last, the function of exosomal miRNA during bone regeneration was confirmed by utilizing a series of gain- and loss-of-function experiments in vitro. Results 50 µg/mL Fe 3 O 4 nanoparticles and a 100 mT SMF were chosen as the optimum magnetic conditions to fabricate two new exosomes, named BMSC-Fe 3 O 4 -Exos and BMSC-Fe 3 O 4 -SMF-Exos. They were both confirmed to enhance osteogenesis and angiogenesis in vitro and in vivo compared with BMSC-Exos, and BMSC-Fe 3 O 4 -SMF-Exos had the most marked effect. The promotion effect was found to be related to the highly riched miR-1260a in BMSC-Fe 3 O 4 -SMF-Exos. Furthermore, miR-1260a was verified to enhance osteogenesis and angiogenesis through inhibition of HDAC7 and COL4A2, respectively. Conclusion These results suggest that low doses of Fe 3 O 4 nanoparticles combined with a SMF trigger exosomes to exert enhanced osteogenesis and angiogenesis and that targeting of HDAC7 and COL4A2 by exosomal miR-1260a plays a crucial role in this process. This work could provide a new protocol to promote bone regeneration for tissue engineering in the future. Graphical abstract" @default.
W3178959923 created "2021-07-19" @default.
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W3178959923 date "2021-07-13" @default.
W3178959923 modified "2023-10-06" @default.
W3178959923 title "Bone mesenchymal stem cells stimulation by magnetic nanoparticles and a static magnetic field: release of exosomal miR-1260a improves osteogenesis and angiogenesis" @default.
W3178959923 cites W2014946489 @default.
W3178959923 cites W2035430295 @default.
W3178959923 cites W2036671075 @default.
W3178959923 cites W2037395339 @default.
W3178959923 cites W2054250836 @default.
W3178959923 cites W2072153678 @default.
W3178959923 cites W2083381199 @default.
W3178959923 cites W2095932809 @default.
W3178959923 cites W2097386768 @default.
W3178959923 cites W2100932663 @default.
W3178959923 cites W2121354606 @default.
W3178959923 cites W2124756133 @default.
W3178959923 cites W2166586515 @default.
W3178959923 cites W2211955807 @default.
W3178959923 cites W2252126238 @default.
W3178959923 cites W2265746625 @default.
W3178959923 cites W2294569663 @default.
W3178959923 cites W2328718073 @default.
W3178959923 cites W2405919788 @default.
W3178959923 cites W2407890550 @default.
W3178959923 cites W2511878937 @default.
W3178959923 cites W2754066342 @default.
W3178959923 cites W2768241957 @default.
W3178959923 cites W2791126322 @default.
W3178959923 cites W2794409974 @default.
W3178959923 cites W2798157122 @default.
W3178959923 cites W2801701186 @default.
W3178959923 cites W2888107825 @default.
W3178959923 cites W2891853812 @default.
W3178959923 cites W2892361598 @default.
W3178959923 cites W2893323712 @default.
W3178959923 cites W2894095369 @default.
W3178959923 cites W2899953171 @default.
W3178959923 cites W2903665452 @default.
W3178959923 cites W2904809908 @default.
W3178959923 cites W2912016924 @default.
W3178959923 cites W2916125004 @default.
W3178959923 cites W2947291780 @default.
W3178959923 cites W2965698862 @default.
W3178959923 cites W2966428992 @default.
W3178959923 cites W2971311910 @default.
W3178959923 cites W2973111694 @default.
W3178959923 cites W2981519356 @default.
W3178959923 cites W2989744940 @default.
W3178959923 cites W2990380991 @default.
W3178959923 cites W2991540267 @default.
W3178959923 cites W2996771201 @default.
W3178959923 cites W3004260349 @default.
W3178959923 cites W3005104290 @default.
W3178959923 cites W3009372032 @default.
W3178959923 cites W3010595826 @default.
W3178959923 cites W3010912602 @default.
W3178959923 cites W3016360818 @default.
W3178959923 cites W3023935082 @default.
W3178959923 cites W3025351845 @default.
W3178959923 cites W302605884 @default.
W3178959923 cites W3035320341 @default.
W3178959923 cites W3037251899 @default.
W3178959923 cites W3047341898 @default.
W3178959923 cites W3087097773 @default.
W3178959923 cites W3092969909 @default.
W3178959923 cites W3094666245 @default.
W3178959923 cites W3108079922 @default.
W3178959923 cites W3159119403 @default.
W3178959923 doi "https://doi.org/10.1186/s12951-021-00958-6" @default.
W3178959923 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/8278669" @default.
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W3178959923 hasPublicationYear "2021" @default.
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