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El-Fiqi, Ahmed,Kim, Joong-Hyun,Kim, Hae-Won American Chemical Society 2015 ACS APPLIED MATERIALS & INTERFACES Vol.7 No.2
<P>Designing scaffolds with bioactive composition and long-term drug delivery capacity is a promising method to improve the therapeutic efficacy in bone regeneration. Herein, electrospun fibrous scaffolds of polycaprolactone-gelatin incorporating mesoporous bioactive glass nanoparticles (mBGn) were proposed to be excellent matrix platforms for bone tissue engineering. In particular, the mBGn were loaded with osteogenic drug Dexamethasone (DEX) to elicit additional therapeutic potential. The mBGn-added fiber scaffolds demonstrated excellent properties, including improved mechanical tensile strength, elasticity, and hydrophilicity compared to pure biopolymer matrix. The scaffolds could release substantial amounts of calcium and silicate ions. The loading of DEX onto mBGn was as high as 63%, that is, 0.63 mg DEX loaded per 1 mg of mBGn, demonstrating an effective nanodepot role of the mBGn. The release of DEX from the mBGn-added fiber scaffolds was highly sustainable, profiling an almost linear release kinetics up to the test period of 28 days, after a rapid initial release of ∼30% within 24 h. The proliferation and osteogenic differentiation of stem cells derived from periodontal ligament were significantly improved by the mBGn incorporation and synergistically stimulated with DEX loading, as confirmed by both direct and indirect cultures. The effects on bone regeneration in vivo, as analyzed by microcomputed tomography and histological stains in a rat calvarium model over 6 weeks, were substantial with the mBGn incorporation and even better with DEX loading, evidencing the osteogenic effects of the drug-eluting nanocomposite fiber scaffolds in bone formation. The current scaffolds with bone-bioactive composition and drug delivery capacity may be potentially useful for bone regeneration as novel osteogenic matrices.</P><P><B>Graphic Abstract</B> <IMG SRC='http://pubs.acs.org/appl/literatum/publisher/achs/journals/content/aamick/2015/aamick.2015.7.issue-2/am5077759/production/images/medium/am-2014-077759_0009.gif'></P>
El-Fiqi, Ahmed,Buitrago, Jennifer O.,Yang, Sung Hee,Kim, Hae-Won Elsevier 2017 Acta Biomaterialia: structure-property-function re Vol.60 No.-
<P><B>Abstract</B></P> <P>Here we communicate the generation of biomimetically grown apatite spheres from aggregated bioglass nanoparticles and the potential properties applicable for drug delivery and cell/tissue engineering. Ion releasing nanoparticulates of bioglass (85%SiO<SUB>2</SUB>-15%CaO) in a mineralizing medium show an intriguing dynamic phenomenon – aggregation, mineralization to apatite, integration and growth into micron-sized (1.5–3μm) spheres. During the progressive ionic dissolution/precipitation reactions, nano-to-micro-morphology, glass-to-crystal composition, and the physico-chemical properties (porosity, surface area, and charge) change dynamically. With increasing reaction period, the apatite becomes more crystallized with increased crystallinity and crystal size, and gets a composition closer to the stoichiometry. The developed microspheres exhibit hierarchical surface nanostructure, negative charge (ς-potential of −20mV), and ultrahigh mesoporosity (mesopore size of 6.1nm, and the resultant surface area of 63.7m<SUP>2</SUP>/g and pore volume of 0.153cm<SUP>3</SUP>/g) at 14days of mineralization, which are even higher than those of its precursor bioglass nanoparticles. Thanks to these properties, the biomimetic mineral microspheres take up biological molecules effectively, <I>i.e.</I>, loading capacity of positive-charged protein is over 10%. Of note, the release is highly sustainable at a constant rate, <I>i.e.</I>, profiling almost ‘zero-order’ kinetics for 4weeks, suggesting the potential usefulness as protein delivery systems. The biomimetic mineral microspheres hold some remnant Si in the core region, and release calcium, phosphate, and silicate ions over the test period, implying the long-term ionic-related therapeutic functions. The mesenchymal stem cells favour the biomimetic spheres with an excellent viability. Due to the merit of sizes (a few micrometers), the spheres can be intercalated into cells, mediating cellular interactions in 3D cell-spheroid engineering, and also can stimulate osteogenic differentiation of cells when incorporated into cell-laden gels. The intriguing properties observed in this study, including biomimetic composition, high mesoporosity, release of therapeutic ions, effective loading and long-term release of proteins, and diverse yet favorable 3D cellular interactions, suggest great potential of the newly developed biomimetic microspheres in biomedical applications, such as drug delivery and cell/tissue engineering.</P> <P><B>Statement of Significance</B></P> <P>This work reports the generation of apatite spheres with a few micrometers in size biomimetically grown from bioactive glass nanoparticles, through a series of intriguing yet unprecedented phenomenon involving aggregation of nanoparticles, mineralization and sphere growth. The mineral microspheres possess some unique physico-chemical properties including mesoporosity, ultrahigh surface area, and therapeutic ionic release. Furthermore, the spheres show excellent loading and delivery capacity of protein molecules, and mediate favorable cellular interactions in 2D and 3D culture conditions, demonstrating a future multifunctional microcarrier platform for the therapeutics delivery and cell/tissue engineering.</P> <P><B>Graphical abstract</B></P> <P>[DISPLAY OMISSION]</P>
El-Fiqi, Ahmed,Kim, Joong-Hyun,Perez, Roman A.,Kim, Hae-Won Royal Society of Chemistry 2015 Journal of Materials Chemistry B Vol. No.
<P>Injectable calcium phosphate cements (CPCs) with strong mechanical properties and improved biological performance have the potential to be extensively used for bone regeneration. Although many additive materials have been incorporated into CPCs in order to achieve improvements in their mechanical and biological properties, somehow the results have not been fully satisfactory. Here we focus on using the nanoparticle form of mesoporous bioactive glasses (mBGn) as additive nano-components for alpha-tricalcium phosphate-based CPCs. The effects of mBGn incorporated up to 10 wt% into CPCs were examined in depth with respect to the setting time, morphology, injectability, wash-out properties, consistency, ionic release, pH change, and mechanical strength. The addition of mBGn significantly increased the surface area (for both the as-cemented and the hydrated compositions) and also significantly accelerated the setting reaction of CPCs. The injectability and the anti-washout property of CPCs were remarkably enhanced with the addition of mBGn. In striking contrast to the case of pure CPCs, the morphological changes observed in simulated body fluid (SBF) revealed a spherical development of apatite crystals, replicating the nanospherical morphology of the mBGn and consequently resulting in a nano-micro-roughened surface. The mechanical compressive strength substantially increased after SBF immersion and significantly higher values were recorded for mBGn/CPC as compared to pure CPCs. The ion release, including that of calcium, phosphate, and silicon, was recorded at substantial levels during the test period, and the addition of mBGn caused changes in the pH towards less acidic. The <I>in vivo</I> study of the mBGn/CPCs in rat subcutaneous tissue confirmed excellent tissue compatibility with little evidence of inflammatory reactions while exhibiting viable fibroblastic cells with a substantial presence of mature endothelial cells surrounding the cements. When implanted in a rat calvarium defect, a substantial degradation of the samples was noticed in the interfacial region. The proposed mBGn/CPC is a novel, promising cement formulation for the repair and regeneration of bone due to setting characteristics, physico-chemical and mechanical properties, and excellent <I>in vivo</I> tissue compatibility and bioactivity.</P>
Won, Jong-Eun,El-Fiqi, Ahmed,Jegal, Seung-Hwan,Han, Cheol-Min,Lee, Eun-Jung,Knowles, Jonathan C,Kim, Hae-Won SAGE Publications 2014 Journal of biomaterials applications Vol.28 No.8
<P>Synthetic biopolymers are commonly used for the repair and regeneration of damaged tissues. Specifically targeting bone, the composite approach of utilizing inorganic components is considered promising in terms of improving mechanical and biological properties. We developed gelatin-apatite co-precipitates which mimic the native bone matrix composition within poly(lactide-<I>co</I>-caprolactone) (PLCL). Ionic reaction of calcium and phosphate with gelatin molecules enabled the co-precipitate formation of gelatin-apatite nanocrystals at varying ratios. The gelatin-apatite precipitates formed were carbonated apatite in nature, and were homogeneously distributed within the gelatin matrix. The incorporation of gelatin-apatite significantly improved the mechanical properties, including tensile strength, elastic modulus and elongation at break, and the improvement was more pronounced as the apatite content increased. Of note, the tensile strength increased to as high as 45 MPa (a four-fold increase vs. PLCL), the elastic modulus was increased up to 1500 MPa (a five-fold increase vs. PLCL), and the elongation rate was ∼240% (twice vs. PLCL). These results support the strengthening role of the gelatin-apatite precipitates within PLCL. The gelatin-apatite addition considerably enhanced the water affinity and the acellular mineral-forming ability in vitro in simulated body fluid; moreover, it stimulated cell proliferation and osteogenic differentiation. Taken together, the GAp-PLCL nanocomposite composition is considered to have excellent mechanical and biological properties, which hold great potential for use as bone regenerative matrices.</P>