Evaluation of a Novel HA/ZrO2-Based Porous Bioceramic Artificial Vertebral Body Combined with a rhBMP-2/Chitosan Slow-Release Hydrogel

Shi, Yihui; Quan, Renfu; Xie, Shangju; Li, Qiang; Cao, Guoliang; Zhuang, Wei; Zhang, Liang; Shao, Rongxue; Yang, Disheng

doi:10.1371/journal.pone.0157698

Cited by 8 publications

(5 citation statements)

References 31 publications

(25 reference statements)

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“…Although studies in dogs, minipigs, sheep, and non-human primates, could provide a better insight into new bone formation and scaffold effectiveness thanks to the closer resemblance to the human bone, only studies employing rat and rabbit models were found to satisfy eligibility criteria, and were, therefore, included in the present systematic review [21,[27][28][29]126]. Even though after the first step of screening, studies in dogs, sheep, and pigs were included, the full-text analysis revealed that most of these studies did not meet the selection criteria due to a reduced sample size (n < 6 animals per group) or the non-critical dimensions of the bone defects [94,100,102,103,106]. Among the papers included, the most frequently used CSD model was the CSD in rat calvaria, which is one of the most commonly used animal models for evaluating bone healing [23,127].…”

Section: Discussionmentioning

confidence: 99%

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

et al. 2020

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Bioceramic scaffolds are appealing for alveolar bone regeneration, because they are emerging as promising alternatives to autogenous and heterogenous bone grafts. The aim of this systematic review is to answer to the focal question: in critical-sized bone defects in experimental animal models, does the use of a bioceramic scaffolds improve new bone formation, compared with leaving the empty defect without grafting materials or using autogenous bone or deproteinized bovine-derived bone substitutes? Electronic databases were searched using specific search terms. A hand search was also undertaken. Only randomized and controlled studies in the English language, published in peer-reviewed journals between 2013 and 2018, using critical-sized bone defect models in non-medically compromised animals, were considered. Risk of bias assessment was performed using the SYRCLE tool. A meta-analysis was planned to synthesize the evidence, if possible. Thirteen studies reporting on small animal models (six studies on rats and seven on rabbits) were included. The calvarial bone defect was the most common experimental site. The empty defect was used as the only control in all studies except one. In all studies the bioceramic materials demonstrated a trend for better outcomes compared to an empty control. Due to heterogeneity in protocols and outcomes among the included studies, no meta-analysis could be performed. Bioceramics can be considered promising grafting materials, though further evidence is needed.

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Section: Discussionmentioning

confidence: 99%

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

et al. 2020

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“…Therefore, the BMP‐2 release rate is an important factor in inducing effective bone regeneration (Seo, Koh, & Song, ). Our previous study showed that 28% and 49% of recombinant human BMP‐2 was released on Days 1 and 3, respectively, after BMP‐2 was added into gelatin/chitosan slow‐release hydrogel and was then released slowly from Days 3 to 15, with a cumulative release of 74% by Day 12 and 77% by Day 15 (Shi et al, ). In the present study, loading of BMP‐2 in the gelatin/chitosan slow‐release hydrogel was performed using the technology of complex emulsion cross‐linking, thereby reducing the BMP‐2 release rate and improving its biological effects.…”

Section: Discussionmentioning

confidence: 99%

“…by Day 12 and 77% by Day 15 (Shi et al, 2016). In the present study, loading of BMP-2 in the gelatin/chitosan slow-release hydrogel was performed using the technology of complex emulsion cross-linking, thereby reducing the BMP-2 release rate and improving its biological effects.…”

Section: Discussionmentioning

confidence: 99%

Effects of a bone graft substitute consisting of porous gradient HA/ZrO₂and gelatin/chitosan slow‐release hydrogel containing BMP‐2 and BMSCs on lumbar vertebral defect repair in rhesus monkey

Shao

Quan

Wang

et al. 2017

J Tissue Eng Regen Med

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Dense biomaterial plays an important role in bone replacement. However, it fails to induce bone cell migration into graft material. In the present study, a novel bone graft substitute (BGS) consisting of porous gradient hydroxyapatite/zirconia composite (PGHC) and gelatin/chitosan slow-release hydrogel containing bone morphogenetic protein 2 and bone mesenchymal stem cells was designed and prepared to repair lumbar vertebral defects. The morphological characteristics of the BGS evaluated by a scanning electron microscope showed that it had a three-dimensional network structure with uniformly distributed chitosan microspheres on the surfaces of the graft material and the interior of the pores. Then, BGS (Group A), PGHC (Group B), or autologous bone (Group C) was implanted into lumbar vertebral body defects in a total of 24 healthy rhesus monkeys. After 8 and 16 weeks, anteroposterior and lateral radiographs of the lumbar spine, microcomputed tomography, histomorphometry, biomechanical testing, and biochemical testing for bone matrix markers, including Type I collagen, osteocalcin, osteopontin, basic fibroblast growth factor, alkaline phosphatase, and vascular endothelial growth factor, were performed to examine the reparative efficacy of the BGS and PGHC. The BGS displayed excellent ability to repair the lumbar vertebral defect in rhesus monkeys. Radiography, microcomputed tomography scanning, and histomorphological characterization showed that the newly formed bone volume in the interior of the pores in the BGS was significantly higher than in the PGHC. The results of biomechanical testing indicated that the vertebral body compression strength of the PGHC implant was lower than the other implants. Reverse-transcription polymerase chain reaction and western blot analyses showed that the expression of bone-related proteins in the BGS implant was significantly higher than in the PGHC implant. The BGS displayed reparative effects similar to autologous bone. Therefore, BGS use in vertebral bone defect repair appears promising.

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“…79 In addition, zirconia/HA-based porous bioceramics loaded with recombinant human BMP-2 promote the repair of bony defect and facilitate bone growth in vivo, which might substitute the use of iliac bone grafts in routine clinical practice. 80 Taken together, zirconia-based scaffolds show good mechanical performances and biocompatibility and are promising biomaterials to be used in bone reconstruction needed in the treatment of load-bearing large bone defects.…”

Section: Osteogenic Scaffolds For Hard Tissue Engineeringmentioning

confidence: 99%

Zirconia-Based Biomaterials for Hard Tissue Reconstruction

Tosiriwatanapong

Singhatanadgit

2018

Bone�Tissue�Regen�Insights

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Implantable biomaterials are increasingly important in the practice of modern medicine, including fixative, replacement, and regeneration therapies, for reconstruction of hard tissues in patients with pathologic osseous and dental conditions. A number of newly developed advanced biomaterials have been introduced as promising candidates for tissue reconstruction. Among these, zirconia-based biomaterials have gained attention as a biomaterial for hard tissue reconstruction due to superior mechanical properties and good chemical and biological compatibilities. This review summarizes the types of zirconia, advantages of zirconia-based biomaterials for hard tissue reconstruction including bone and dental tissues, responses of tissue and cells to zirconia, and surface modifications for enhanced bioactivity of zirconia. Current and future applications of zirconia-based biomaterials for bone and dental reconstruction, ie, medical implanted devices, dental prostheses, and biocompatible osteogenic scaffolds, are also discussed.

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Evaluation of a Novel HA/ZrO2-Based Porous Bioceramic Artificial Vertebral Body Combined with a rhBMP-2/Chitosan Slow-Release Hydrogel

Cited by 8 publications

References 31 publications

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

Effects of a bone graft substitute consisting of porous gradient HA/ZrO₂and gelatin/chitosan slow‐release hydrogel containing BMP‐2 and BMSCs on lumbar vertebral defect repair in rhesus monkey

Zirconia-Based Biomaterials for Hard Tissue Reconstruction

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Evaluation of a Novel HA/ZrO2-Based Porous Bioceramic Artificial Vertebral Body Combined with a rhBMP-2/Chitosan Slow-Release Hydrogel

Cited by 8 publications

References 31 publications

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

The Impact of Bioceramic Scaffolds on Bone Regeneration in Preclinical In Vivo Studies: A Systematic Review

Effects of a bone graft substitute consisting of porous gradient HA/ZrO2and gelatin/chitosan slow‐release hydrogel containing BMP‐2 and BMSCs on lumbar vertebral defect repair in rhesus monkey

Zirconia-Based Biomaterials for Hard Tissue Reconstruction

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Product

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Effects of a bone graft substitute consisting of porous gradient HA/ZrO₂and gelatin/chitosan slow‐release hydrogel containing BMP‐2 and BMSCs on lumbar vertebral defect repair in rhesus monkey