Osteogenesis Enhancement with 3D Printed Gene-Activated Sodium Alginate Scaffolds

Khvorostina, Maria A.; Миронов, А. Н.; Nedorubova, Irina Alekseevna; Бухарова, Т. Б.; Vasilyev, A. V.; Goldshtein, D. V.; Komlev, V. S.; Попов, В. К.

doi:10.3390/gels9040315

Cited by 4 publications

(1 citation statement)

References 58 publications

(66 reference statements)

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“…undergo in vitro cell tests after different periods of infiltration, highlighting the necessity of the careful tailoring of biomaterials with appropriate chemical composition, microstructure, pore size, and porosity to optimize conditions for stimulating bone tissue regeneration [37][38][39][40]. Engineered cells and gene-activated materials [41][42][43][44] will open up new avenues for research on bone growth and regeneration by incorporating bioabsorbable apatite nanocrystals with diverse micro morphologies into the three-dimensional micropore structure of the material. Figure 7c illustrates the presence of a narrow wall, measuring approximately 1µm, separating the two fully occupied internal micro-caves.…”

Section: The Effect Of Sbf Immersion On the Microstructure Of An Ha/w...mentioning

confidence: 99%

Investigation on the Microstructural Diversity of a Three-Dimensional Porous Hydroxyapatite/Wollastonite Skeleton via Biomineralization in Simulated Body Fluids

Jiang,

Li,

Yang

et al. 2023

Applied Sciences

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The occurrence of fractures has emerged as one of the most prevalent injuries in the human body. In bone reconstruction surgery, after the implantation of porous hydroxyapatite materials, there is an initial infiltration of body fluids into the porous implant, followed by biomineralization-mediated apatite crystal formation and the subsequent ingrowth of bone cells. Despite extensive research efforts in this field, previous investigations have primarily focused on the formation of apatite crystals on exposed surfaces, with limited literature available regarding the formation of apatite crystals within the internal microstructures of bone implants. Herein, we demonstrate the occurrence of dynamic biomineralization within a three-dimensional porous hydroxyapatite/wollastonite (HA/WS) skeleton, leading to the abundant formation of nano-sized apatite crystals across diverse internal environments. Our findings reveal that these apatite nanocrystals demonstrate distinct rates of nucleation, packing densities, and crystal forms in comparison to those formed on the surface. Therefore, the objective of this study was to elucidate the temporal evolution of biomineralization processes by investigating the microstructures of nanocrystals on the internal surfaces of HA/WS three-dimensional porous materials at distinct stages of biomineralization and subsequently explore the biological activity exhibited by HA/WS when combined with cell investigation into apatite crystal biomineralization mechanisms at the nanoscale, aiming to comprehend natural bone formation processes and develop efficacious biomimetic implants for tissue engineering applications. The simultaneous examination of bone cell attachment and its interaction with ongoing internal nanocrystal formation will provide valuable insights for designing optimal scaffolds conducive to bone cell growth, which is imperative in tissue engineering endeavors.

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Section: The Effect Of Sbf Immersion On the Microstructure Of An Ha/w...mentioning

confidence: 99%

Investigation on the Microstructural Diversity of a Three-Dimensional Porous Hydroxyapatite/Wollastonite Skeleton via Biomineralization in Simulated Body Fluids

Jiang,

Li,

Yang

et al. 2023

Applied Sciences

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Harnessing alginate-based nanocomposites as nucleic acid/gene delivery platforms to address diverse biomedical issues: A progressive review

Konwarh,

Singh,

Varadarajan

et al. 2024

Carbohydrate Polymer Technologies and Applications

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Mg-Sr-Ca containing bioactive glass nanoparticles hydrogel modified mineralized collagen scaffold for bone repair

Sun,

Shi,

Niu

et al. 2024

J Biomater Appl

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The aim of this study is to explore the therapeutic effects of Mg-Sr-Ca containing bioactive glass nanoparticles sodium alginate hydrogel modified mineralized collagen scaffold (Mg-Sr-Ca-BGNs-SA-MC) on the repair of osteoporotic bone defect. During the study, Mg-Sr-Ca containing bioactive glass nanoparticles (Mg-Sr-Ca-BGNs) were synthesized using the sol-gel method, and the Mg-Sr-Ca-BGNs-SA-MC scaffold was synthesized by a simple method. The Mg-Sr-Ca-BGNs and the Mg-Sr-Ca-BGNs-SA-MC scaffold were observed by scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The elements of Mg, Sr, Ca and Si were effectively integrated into Mg-Sr-Ca-BGNs. SEM analysis revealed the presence of Mg-Sr-Ca-BGNs on the scaffold’s surface. Furthermore, the cytotoxicity of the scaffolds were assessed using a live/dead assay. The result of the live/dead assay demonstrated that the scaffold materials were non-toxic to cell growth. More importantly, the in vivo study indicated that implanted scaffold promoted tissue regeneration and integration with newly formed bone. Overall, the Mg-Sr-Ca-BGNs-SA-MC scaffold is suitable for guided bone regeneration and beneficial to repair of osteoporotic bone defects.

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Osteogenesis Enhancement with 3D Printed Gene-Activated Sodium Alginate Scaffolds

Cited by 4 publications

References 58 publications

Investigation on the Microstructural Diversity of a Three-Dimensional Porous Hydroxyapatite/Wollastonite Skeleton via Biomineralization in Simulated Body Fluids

Investigation on the Microstructural Diversity of a Three-Dimensional Porous Hydroxyapatite/Wollastonite Skeleton via Biomineralization in Simulated Body Fluids

Harnessing alginate-based nanocomposites as nucleic acid/gene delivery platforms to address diverse biomedical issues: A progressive review

Mg-Sr-Ca containing bioactive glass nanoparticles hydrogel modified mineralized collagen scaffold for bone repair

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