Microsphere-based scaffolds encapsulating tricalcium phosphate and hydroxyapatite for bone regeneration

Gupta, Vineet; Lyne, Dina V.; Barragan, Marilyn; Berkland, Cory; Detamore, Michael S.

doi:10.1007/s10856-016-5734-1

Cited by 17 publications

(7 citation statements)

References 56 publications

(88 reference statements)

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“…Tricalcium phosphate has a similar chemical composition and structural and elastic moduli to HA, known as another important calcium phosphate-based biomaterial. Beta-tricalcium phosphate (β-TCP) not only possesses good biocompatibility and osteoconductivity, but also shows in vivo resorbability during the bone growth, making it an ideal candidate as a biomaterial for bone tissue engineering [151,152,153]. Mirjalili et al [154] successfully synthesized a β-TCP–CNT nanocomposite by solution precipitation method.…”

Section: Advancements In Cnt-based Scaffolds or Implants For Bone mentioning

confidence: 99%

Applications of Carbon Nanotubes in Bone Tissue Regeneration and Engineering: Superiority, Concerns, Current Advancements, and Prospects

et al. 2019

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With advances in bone tissue regeneration and engineering technology, various biomaterials as artificial bone substitutes have been widely developed and innovated for the treatment of bone defects or diseases. However, there are no available natural and synthetic biomaterials replicating the natural bone structure and properties under physiological conditions. The characteristic properties of carbon nanotubes (CNTs) make them an ideal candidate for developing innovative biomimetic materials in the bone biomedical field. Indeed, CNT-based materials and their composites possess the promising potential to revolutionize the design and integration of bone scaffolds or implants, as well as drug therapeutic systems. This review summarizes the unique physicochemical and biomedical properties of CNTs as structural biomaterials and reinforcing agents for bone repair as well as provides coverage of recent concerns and advancements in CNT-based materials and composites for bone tissue regeneration and engineering. Moreover, this review discusses the research progress in the design and development of novel CNT-based delivery systems in the field of bone tissue engineering.

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Section: Advancements In Cnt-based Scaffolds or Implants For Bone mentioning

confidence: 99%

Applications of Carbon Nanotubes in Bone Tissue Regeneration and Engineering: Superiority, Concerns, Current Advancements, and Prospects

et al. 2019

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“…At the same time, nHAP-incorporated PLGA microspheres are not only osteo-conductive/inductive, but also stable constructs that can withstand load-bearing in bone, to a certain extent. PLGA-based microsphere scaffolds are reported to be good substitute materials in bone tissue engineering when used as a composite material with nHAP or tricalcium phosphate [23]. In short, we intend to develop a hybrid bone tissue engineering scaffold with both load-bearing and bone regeneration capabilities using a high-strength PLGA-nHAP microsphere cavity fitted with biomimetic gelatin-nHAP cryogel.…”

Section: Introductionmentioning

confidence: 99%

Gelatin/Nanohyroxyapatite Cryogel Embedded Poly(lactic-co-glycolic Acid)/Nanohydroxyapatite Microsphere Hybrid Scaffolds for Simultaneous Bone Regeneration and Load-Bearing

et al. 2018

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It is desirable to combine load-bearing and bone regeneration capabilities in a single bone tissue engineering scaffold. For this purpose, we developed a high strength hybrid scaffold using a sintered poly(lactic- co -glycolic acid) (PLGA)/nanohydroxyapatite (nHAP) microsphere cavity fitted with gelatin/nHAP cryogel disks in the center. Osteo-conductive/osteo-inductive nHAP was incorporated in 250–500 μm PLGA microspheres at 40% ( w / w ) as the base matrix for the high strength cavity-shaped microsphere scaffold, while 20% ( w / w ) nHAP was incorporated into gelatin cryogels as an embedded core for bone regeneration purposes. The physico-chemical properties of the microsphere, cryogel, and hybrid scaffolds were characterized in detail. The ultimate stress and Young’s modulus of the hybrid scaffold showed 25- and 21-fold increases from the cryogel scaffold. In vitro studies using rabbit bone marrow-derived stem cells (rBMSCs) in cryogel and hybrid scaffolds through DNA content, alkaline phosphatase activity, and mineral deposition by SEM/EDS, showed the prominence of both scaffolds in cell proliferation and osteogenic differentiation of rBMSCs in a normal medium. Calcium contents analysis, immunofluorescent staining of collagen I (COL I), and osteocalcin (OCN) and relative mRNA expression of COL I, OCN and osteopontin (OPN) confirmed in vitro differentiation of rBMSCs in the hybrid scaffold toward the bone lineage. From compression testing, the cell/hybrid scaffold construct showed a 1.93 times increase of Young’s modulus from day 14 to day 28, due to mineral deposition. The relative mRNA expression of osteogenic marker genes COL I, OCN, and OPN showed 5.5, 18.7, and 7.2 folds increase from day 14 to day 28, respectively, confirming bone regeneration. From animal studies, the rBMSCs-seeded hybrid constructs could repair mid-diaphyseal tibia defects in rabbits, as evaluated by micro-computed tomography (μ-CT) and histological analyses. The hybrid scaffold will be useful for bone regeneration in load-bearing areas.

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“…In contrast, TCP with intrinsic osteoconductivity but significantly low degradation, is usually chosen to adjust the performance of composite scaffolds. Unfortunately, the conventional mechanical mixing approach usually fails to tailor the physicochemical and biological properties of the TCP/CSi composites or even compromise them. ,, In this aspect, core–shell TCP@CSi-Mg4 design can adjust biodegradation behaviors of the scaffolds precisely by distributing bioceramic components with different biodegradation rates in the core and shell layers.…”

Section: Discussionmentioning

confidence: 99%

Core–Shell Bioactive Ceramic Robocasting: Tuning Component Distribution Beneficial for Highly Efficient Alveolar Bone Regeneration and Repair

Lei

Wei

Wang

et al. 2020

ACS Biomater. Sci. Eng.

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Biodegradable ceramic (composite) scaffolds have inspired worldwide efforts in bone regenerative medicine. However, balancing the biodegradation with the bone’s natural healing time scale remains difficult; in particularl, there is a lack of strategy to control component distribution and bioactive ion release favorable for stimulating alveolar bone tissue ingrowth in situ within an expected time window. Here we aimed to develop the robocasting core–shell bioceramic scaffolds and investigate their physicochemical properties and osteostimulative capability in beagle alveolar bone defect model. The β-tircalcium phosphate (TCP) and 5% Mg-doped calcium silicate (CSi-Mg5) were used to fabricate the core–shell-typed TCP@TCP, CSi-Mg5@CSi-Mg5 and TCP@CSi-Mg5 porous scaffolds. Both in vitro and in vivo studies show that the CSi-Mg5 shell readily contributed to the initial mechanical strength and early-stage osteogenic activity of the TCP@CSi-Mg5 scaffolds, including tunable ion release, enhanced biodegradation, and outstanding osteogenesis capacity in comparison with the CSi-Mg5@CSi-Mg5 scaffolds and clinically available Bio-Oss granules in alveolar bone defects. Therefore, the presented core–shell robocasting of bioceramic technology and porous scaffold biomaterials enables an accurate preparation of highly bioactive and biodegradable scaffolds with a large freedom of design, and thereby may be beneficial for fabricating osteostimulation-tuned porous scaffolds for the challengeable alveolar bone defect reconstruction medicine.

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Microsphere-based scaffolds encapsulating tricalcium phosphate and hydroxyapatite for bone regeneration

Cited by 17 publications

References 56 publications

Applications of Carbon Nanotubes in Bone Tissue Regeneration and Engineering: Superiority, Concerns, Current Advancements, and Prospects

Applications of Carbon Nanotubes in Bone Tissue Regeneration and Engineering: Superiority, Concerns, Current Advancements, and Prospects

Gelatin/Nanohyroxyapatite Cryogel Embedded Poly(lactic-co-glycolic Acid)/Nanohydroxyapatite Microsphere Hybrid Scaffolds for Simultaneous Bone Regeneration and Load-Bearing

Core–Shell Bioactive Ceramic Robocasting: Tuning Component Distribution Beneficial for Highly Efficient Alveolar Bone Regeneration and Repair

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