Samenvatting
Hydrogels play an important role in tissue engineering due to their native extracellular matrix-like characteristics, but they are insufficient in providing the necessary stimuli to support tissue formation. Efforts to integrate bioactive cues directly into hydrogels are hindered by incompatibility with hydrophobic drugs, issues of burst/uncontrolled release, and rapid degradation of the bioactive molecules. Skeletal muscle tissue repair requires internal stimuli and communication between cells for regeneration, and nanocomposite systems offer to improve the therapeutic effects in tissue regeneration. Here, the versatility of mesoporous silica nanoparticles (MSN) was leveraged to formulate a nanoparticle-hydrogel composite and to combine the benefits of controlled delivery of bioactive cues and cellular support. The tunable surface characteristics of MSNs were exploited to optimize homogeneity and intracellular drug delivery in a 3D matrix. Nanocomposite hydrogels formulated with acetylated or succinylated MSNs achieved high homogeneity in 3D distribution, with succinylated MSNs being rapidly internalized and acetylated MSNs exhibiting slower cellular uptake. MSN-hydrogel nanocomposites simultaneously allowed efficient local intracellular delivery of a hydrophobic model drug. To further study the efficiency of directing cell response, a Notch signaling inhibitor (DAPT) was incorporated into succinylated MSNs and incorporated into the hydrogel. MSN-hydrogel nanocomposites effectively downregulated the Notch signaling target genes, and accelerated and maintained the expression of myogenic markers. The current findings demonstrate a proof-of-concept in effective surface engineering strategies for MSN-based nanocomposites, suited for hydrophobic drug delivery in tissue regeneration with guided cues.
| Originele taal-2 | Engels |
|---|---|
| Artikelnummer | 100865 |
| Aantal pagina's | 16 |
| Tijdschrift | Materials Today Bio |
| Volume | 23 |
| DOI's | |
| Status | Gepubliceerd - dec. 2023 |
Bibliografische nota
Publisher Copyright:© 2023 The Authors
Financiering
Imaging/Flow cytometry was performed at the Cell Imaging and Cytometry Core, Turku Bioscience Centre, Turku, Finland, with the support of Biocenter Finland. Jan-Henrik Smått is greatly acknowledged for his assistance in TGA measurements. European Regional Development Fund (ERDF) REACT EU (AMBioPharma project, Centre for Additive Manufacturing for Life Science and Pharmaceutical Industry, project code A77805) and Business Finland co-creation project “3D Cure” (575/31/2023) (EÖ, JMR), Swedish Cultural Foundation (EÖ, MP) and Magnus Ehrnrooth Foundation (EÖ), Finnish Cultural Foundation (MP) and the Graduate School of Åbo Akademi University (SS) are acknowledged for financial support. The Ministry of Higher Education of Arab Republic of Egypt is acknowledged for their financial support (AM). This research was also supported by the Sigrid Jusélius Foundation (JMR, CS), Academy of Finland SPACE (#316882, Spatiotemporal control of cell functions) project (CS), InFLAMES Flagship Programme (#337531) (CS) and the ÅAU Center of Excellence project BACE (Bioelectronic Activation of Cell Functions) (CS). This work is further part of the activities of the strategic research profiling area Solutions for Health at Åbo Akademi University (Academy of Finland, project #336355). Illustrations were created with BioRender.com. Imaging/Flow cytometry was performed at the Cell Imaging and Cytometry Core, Turku Bioscience Centre, Turku, Finland, with the support of Biocenter Finland . Jan-Henrik Smått is greatly acknowledged for his assistance in TGA measurements. European Regional Development Fund ( ERDF ) REACT EU (AMBioPharma project, Centre for Additive Manufacturing for Life Science and Pharmaceutical Industry, project code A77805) and Business Finland co-creation project “3D Cure” (575/31/2023) (EÖ, JMR), Swedish Cultural Foundation (EÖ, MP) and Magnus Ehrnrooth Foundation (EÖ), Finnish Cultural Foundation (MP) and the Graduate School of Åbo Akademi University (SS) are acknowledged for financial support. The Ministry of Higher Education of Arab Republic of Egypt is acknowledged for their financial support (AM). This research was also supported by the Sigrid Jusélius Foundation (JMR, CS ), Academy of Finland SPACE (#316882, Spatiotemporal control of cell functions) project ( CS ), InFLAMES Flagship Programme (#337531) ( CS ) and the ÅAU Center of Excellence project BACE (Bioelectronic Activation of Cell Functions) ( CS ). This work is further part of the activities of the strategic research profiling area Solutions for Health at Åbo Akademi University (Academy of Finland, project #336355). Illustrations were created with BioRender.com .
| Financiers | Financiernummer |
|---|---|
| Academy of Finland | 337531, 316882 |
| European Regional Development Fund | A77805 |
| Åbo Akademi University | 336355 |