Compositional and histological comparison of carbonate apatite fabricated by dissolution–precipitation reaction and Bio-Oss®

Fujisawa, Kenji; Akita, Kazuya; Fukuda, Nobuhiro; Kamada, Kumiko; Kudoh, Takaharu; Ohe, Go; Mano, Takamitsu; Tsuru, Kanji; Ishikawa, Kunio; Miyamoto, Youji

doi:10.1007/s10856-018-6129-2

Cited by 42 publications

(55 citation statements)

References 50 publications

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“…In fact, Spence et al () reported that higher carbonate content led to an increased osteoclastogenesis and allowed resorption of the substitute in a dose dependent manner in vivo. Further, Fujisawa et al () reported that the size of the CO 3 Ap granules became smaller with implantation time in vivo. The resorption of bone or dissolution of apatite elevates Ca 2+ concentration since both bone and apatite are composed of calcium phosphate.…”

Section: Discussionmentioning

confidence: 98%

“…The CO 3 Ap block fabricated in an aqueous solution upregulated osteoblastic differentiation of human bone marrow cells, and was resorbed by osteoclasts (Ishikawa, ; Kanayama et al, ; Nagai et al, ; Spence, Patel, Brooks, Bonfield, & Rushton, ). Fujisawa et al () reported that the CO 3 Ap showed faster bone formation especially in the cortical bone portion than Bio‐Oss, a bovine‐derived xenograft, at 8 weeks after implantation in the bone defect of a rabbit femur. These results clearly demonstrated the potential value of the CO 3 Ap block as an alternative to autografts.…”

Section: Introductionmentioning

confidence: 99%

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Histological comparison of three apatitic bone substitutes with different carbonate contents in alveolar bone defects in a beagle mandible with simultaneous implant installation

et al. 2019

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Since bone apatite is a carbonate apatite containing carbonate in an apatitic structure, carbonate content may be one of the factors governing the osteoconductivity of apatitic bone substitutes. The aim of this study was to evaluate the effects of carbonate content on the osteoconductivity of apatitic bone substitutes using three commercially available bone substitutes for the reconstruction of alveolar bone defects of a beagle mandible with simultaneous dental implant installation. NEOBONE, Bio‐Oss, and Cytrans that contain 0.1, 5.5, and 12.0 mass% of carbonate, respectively, were used in this study. The amount of newly formed bone in the upper portion of the alveolar bone defect of the beagle's mandible was 0.7, 6.6, and 39.4% at 4 weeks after surgery and 4.7, 39.5, and 75.2% at 12 weeks after surgery for NEOBONE, Bio‐Oss, and Cytrans, respectively. The results indicate that bone‐to‐implant contact ratio was the largest for Cytrans. Additionally, the continuity of the alveolar ridge was restored in the case of Cytrans, whereas the continuity of the alveolar ridge was not sufficient when using NEOBONE and Bio‐Oss. Both Cytrans and Bio‐Oss that have a relatively larger carbonate content in their apatitic structure was resorbed with time. We concluded that carbonate content is one of important factors governing the osteoconductivity of apatitic bone substitutes.

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Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Histological comparison of three apatitic bone substitutes with different carbonate contents in alveolar bone defects in a beagle mandible with simultaneous implant installation

et al. 2019

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“…All samples were characterized as apatite without any other types of crystalline phases. Both samples had similar patterns, with pronounced peaks between 473 and 700 cm −1 [35], and absorption peaks ascribed to phosphatase band peaks at 962, 1051, and 1089 cm −1 (Figure 5). The results of the FTIR and XRD characterization analysis of sintered PGPT and porcine control particles agreed with a study done by Figueiredo et al which compared the physicochemical properties of bone substitutes used in dentistry vs. calcined human bone.…”

Section: Fourier Transform Infrared Spectroscopy Profilesmentioning

confidence: 80%

Argon Plasma Surface Modified Porcine Bone Substitute Improved Osteoblast-Like Cell Behavior

et al. 2019

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Low-temperature plasma-treated porcine grafts (PGPT) may be an effective means for treating demanding osseous defects and enhance our understanding of plasma-tissue engineering. We chemically characterized porcine grafts under low-temperature Argon plasma treatment (CAP) and evaluated their biocompatibility in-vitro. Our results showed that PGPT did not differ in roughness, dominant crystalline phases, absorption peaks corresponding to phosphate band peaks, or micro-meso pore size, compared to non-treated porcine grafts. The PGPT Ca/P ratio was 2.16; whereas the porcine control ratio was 2.04 (p < 0.05). PGPT’s [C 1s], [P 2p] and [Ca 2p] values were 24.3%, 5.6% and 11.0%, respectively, indicating that PGPT was an apatite without another crystalline phase. Cell viability and alkaline phosphatase assays revealed enhanced proliferation and osteoblastic differentiation for the cells cultivated in the PGPT media after 5 days (p < 0.05). The cells cultured in PGPT medium had higher bone sialoprotein and osteocalcin relative mRNA expression compared to cells cultured in non-treated porcine grafts (p < 0.05). CAP treatment of porcine particles did not modify the biomaterial’s surface and improved the proliferation and differentiation of osteoblast-like cells.

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“…Compared with HA and β-TCP, carbonate apatite (CO 3Ap) can also be easily substituted for bone because its hydroxyl group is replaced with a carbonate group, and it therefore produces a skeleton has a porous microstructure that is morphologically similar to that of human cancellous bone 7) . CO3Ap granules show greater bone formation in the cortical portion of a bone defect than Bio-Oss, which is a deproteinized bovine bone mineral 8) . CO3Ap has also shown faster bone healing than HA via the activation of bone metabolism, which stimulates bone matrix formation by osteoblasts and bone absorption by osteoclasts 9) .…”

Section: Introductionmentioning

confidence: 96%

Comparison of the vertical bone defect healing abilities of carbonate apatite, β-tricalcium phosphate, hydroxyapatite and bovine-derived heterogeneous bone

et al. 2020

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The treatment of vertical bone defects caused by severe periodontal disease requires the regeneration of periodontal tissue. Although various bone substitutes have been clinically applied to vertical bone defect correction, the evaluation of these materials in periodontal tissue remains incomplete. The purpose of this study was to examine the bone regeneration abilities of various bone substitutes including Cytrans, Cerasorb, Neobone and Bio-Oss in a 3-wall bone defect animal model. All of these bone substitutes showed a similar healing ability to periodontal ligament and cementum. However, Cytrans showed the fastest bone healing ability compared with the other materials at 4 weeks post-transplantation. In addition, the recruitment of osteoclasts and endothelial cells was observed in Cytrans grafts at 4 weeks, but only detected at 8 weeks in the other materials. These results suggest that Cytrans promotes faster bone healing by inducing bone remodeling and angiogenesis.

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Compositional and histological comparison of carbonate apatite fabricated by dissolution–precipitation reaction and Bio-Oss®

Cited by 42 publications

References 50 publications

Histological comparison of three apatitic bone substitutes with different carbonate contents in alveolar bone defects in a beagle mandible with simultaneous implant installation

Histological comparison of three apatitic bone substitutes with different carbonate contents in alveolar bone defects in a beagle mandible with simultaneous implant installation

Argon Plasma Surface Modified Porcine Bone Substitute Improved Osteoblast-Like Cell Behavior

Comparison of the vertical bone defect healing abilities of carbonate apatite, β-tricalcium phosphate, hydroxyapatite and bovine-derived heterogeneous bone

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