Wollastonite nanofiber&amp;ndash;doped self-setting calcium phosphate bioactive cement for bone tissue regeneration

Guo, Han; Wei, Jie; Song, Wei; Zhang, Shan; Yan, Yonggang; Liu, Changsheng; Xiao, Tiqiao

doi:10.2147/ijn.s32061

Cited by 11 publications

(9 citation statements)

References 31 publications

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“…Being aware on the excellent bioresorbability of DCPD and CDHA, researchers are focused on attempts to overcome the mechanical weakness of the self-setting calcium orthophosphate formulations by using different fillers, fibers and reinforcing additives that give rise to formation of various multiphasic biocomposites [ 128 , 129 , 133 , 225 , 296 , 459 , 462 , 463 , 464 , 465 , 466 , 467 , 468 , 469 , 470 , 471 ]. Even carbon nanotubes have been successfully tested to reinforce the self-setting formulations [ 29 , 472 , 473 , 474 ].…”

Section: Reinforced Formulations and Concretesmentioning

confidence: 99%

Self-Setting Calcium Orthophosphate Formulations

Dorozhkin¹

2013

JFB

151

107

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In early 1980s, researchers discovered self-setting calcium orthophosphate cements, which are bioactive and biodegradable grafting bioceramics in the form of a powder and a liquid. After mixing, both phases form pastes, which set and harden forming either a non-stoichiometric calcium deficient hydroxyapatite or brushite. Since both of them are remarkably biocompartible, bioresorbable and osteoconductive, self-setting calcium orthophosphate formulations appear to be promising bioceramics for bone grafting. Furthermore, such formulations possess excellent molding capabilities, easy manipulation and nearly perfect adaptation to the complex shapes of bone defects, followed by gradual bioresorption and new bone formation. In addition, reinforced formulations have been introduced, which might be described as calcium orthophosphate concretes. The discovery of self-setting properties opened up a new era in the medical application of calcium orthophosphates and many commercial trademarks have been introduced as a result. Currently such formulations are widely used as synthetic bone grafts, with several advantages, such as pourability and injectability. Moreover, their low-temperature setting reactions and intrinsic porosity allow loading by drugs, biomolecules and even cells for tissue engineering purposes. In this review, an insight into the self-setting calcium orthophosphate formulations, as excellent bioceramics suitable for both dental and bone grafting applications, has been provided.

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Section: Reinforced Formulations and Concretesmentioning

confidence: 99%

Self-Setting Calcium Orthophosphate Formulations

Dorozhkin¹

2013

JFB

151

107

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“…17,21,22 New techniques have been developed for the synthesis of wollastonite, including the use of additives and processing at lower temperatures in order to improve its physical, chemical, and biological properties. 18,22,24 Analysis of all the procedures employed to improve the performance of this material underscores the fact that great effort has been placed to this end, as demonstrated in the literature. In addition, structural changes and experiments have been performed to test the full potential of this material; favorable results were observed for the association of wollastonite with recombinant human bone morphogenetic protein-2 28 and for magnesium-doped wollastonite, both in terms of bone regeneration potential and for improved mechanical properties.…”

Section: Discussionmentioning

confidence: 99%

“…Use of wollastonite was associated with better tissue biocompatibility, [24][25][26] faster biomaterial resorption rate, 17,21 and improved bone repair, [17][18][19]21,[24][25][26] especially in the adapted formulations.…”

Section: Study Characteristicsmentioning

confidence: 99%

Calcium silicate as a graft material for bone fractures: a systematic review

et al. 2018

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ObjectiveThe goal of this review was to determine whether calcium silicate (wollastonite) as a bone graft material is a viable alternative to autogenous bone or whether the evidence base for its use is weak.MethodsIn this systematic review, electronic databases (MEDLINE/PubMed and BVS) were searched for relevant articles in indexed journals. Articles published in a 10-year period were identified (n = 48). After initial selection, 17 articles were assessed for eligibility; subsequently, seven articles were excluded and 10 articles were included.ResultsAmong the studies included, 20% emphasized the importance of randomization, which adds reliability to the study, minimizing the risk of bias. High variability was observed in the material used, such as additives, amounts, dosage, and chemical alterations, rendering direct comparison among these studies impossible. The experimental periods varied considerably; one of the studies did not include statistical analysis, weakening the evaluation. Nonetheless, the true potential of wollastonite as a graft material conducive to new bone formation was reported in all studies.ConclusionThe results support the use of wollastonite as a bone graft material. The initial research question was answered despite the significant variability observed among these preclinical studies, which hindered the precision of this analysis.

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“…There was no effect on the setting time or the compressive strength of wnf-CPC but the hydrophilicity and degradability of wnf-CPC were significantly improved by the addition of WNFs, which was attributed to the change of microstructure. Wnf-CPCs were then evaluated in a rabbit bone defect model and showed enhanced efficiency of new bone formation when compared with CPC alone [93] . The excellent biocompatibility and bioactive properties predestine ceramic scaffolds for use as bone graft substitutes for bone regeneration applications.…”

Section: Bone Tissue Engineeringmentioning

confidence: 99%

Nanotechnologies in tissue engineering

Bigdeli

Lyer

Detsch

et al. 2013

Nanotechnology Reviews

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As an interdisciplinary field, tissue engineering (TE) aims to regenerate tissues by combining the principles of cell biology, material science, and biomedical engineering. Nanotechnology creates new materials that might enable further tissue-engineering applications. In this context, the introduction of nanotechnology and nanomaterials promises a biomimetic approach by mimicking nature. This review summarizes the current scope of nanotechnology implementation possibilities in the field of tissue engineering of bone, muscle, and vascular grafts with forms on nanofibrous structures.

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Wollastonite nanofiber–doped self-setting calcium phosphate bioactive cement for bone tissue regeneration

Cited by 11 publications

References 31 publications

Self-Setting Calcium Orthophosphate Formulations

Self-Setting Calcium Orthophosphate Formulations

Calcium silicate as a graft material for bone fractures: a systematic review

Nanotechnologies in tissue engineering

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