Chitosan-Based Biomimetically Mineralized Composite Materials in Human Hard Tissue Repair

Hu, Die; Ren, Qian; Li, Zhongcheng; Zhang, Linglin

doi:10.3390/molecules25204785

Cited by 40 publications

(25 citation statements)

References 124 publications

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“…Chitosan has been considered a versatile polymer for tissue engineering applications due to its biocompatibility, controllable biodegradability, and the capability of being processed into different architectures (Hu et al 2020; Tang et al 2020). Amino (-NH 2 ) and hydroxyl groups (-OH) are effective centers for complexing with metal ions and are directly involved in the metal-chitosan coordination process (Hu et al 2020).…”

Section: Discussionmentioning

confidence: 99%

“…Chitosan has attracted attention for dentin tissue regeneration due to glycosaminoglycan-like polymeric chains, which favor pulp cells interaction, along with proved biocompatibility, biodegradability into nontoxic components, protein affinity, and hemostatic and antimicrobial potential (Hu et al 2020; Tang et al 2020). Previous in vivo studies have already demonstrated that chitosan scaffolds might be useful for in situ tissue engineering of dentin due to adequate absence of cell/tissue toxicity, promoting cell mobilization and interaction, ultimately with odontoblastic differentiation and mineralized tissue deposition in absence of inflammatory reaction on surrounding pulp tissue (Li et al 2014; Machado et al 2020).…”

Section: Introductionmentioning

confidence: 99%

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Chitosan-Calcium-Simvastatin Scaffold as an Inductive Cell-Free Platform

Soares¹,

Bordini

Bronze‐Uhle³

et al. 2021

J Dent Res

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The development of biomaterials based on the combination of biopolymers with bioactive compounds to develop delivery systems capable of modulating dentin regeneration mediated by resident cells is the goal of current biology-based strategies for regenerative dentistry. In this article, the bioactive potential of a simvastatin (SV)–releasing chitosan-calcium-hydroxide (CH-Ca) scaffold was assessed. After the incorporation of SV into CH-Ca, characterization of the scaffold was performed. Dental pulp cells (DPCs) were seeded onto scaffolds for the assessment of cytocompatibility, and odontoblastic differentiation was evaluated in a microenvironment surrounded by dentin. Thereafter, the cell-free scaffold was adapted to dentin discs positioned in artificial pulp chambers in direct contact with a 3-dimensional (3D) culture of DPCs, and the system was sealed to simulate internal pressure at 20 cm/H2O. In vivo experiments with cell-free scaffolds were performed in rats’ calvaria defects. Fourier-transform infrared spectroscopy spectra proved incorporation of Ca and SV into the scaffold structure. Ca and SV were released upon immersion in a neutral environment. Viable DPCs were able to spread and proliferate on the scaffold over 14 d. Odontoblastic differentiation occurred in the DPC/scaffold constructs in contact with dentin, in which SV supplementation promoted odontoblastic marker overexpression and enhanced mineralized matrix deposition. The chemoattractant potential of the CH-Ca scaffold was improved by SV, with numerous viable and dentin sialoprotein–positive cells from the 3D culture being observed on its surface. Cells at 3D culture featured increased gene expression of odontoblastic markers in contact with the SV-enriched CH-Ca scaffold. CH-Ca-SV led to intense mineralization in vivo, presenting mineralization foci inside its structure. In conclusion, the CH-Ca-SV scaffold induces differentiation of DPCs into a highly mineralizing phenotype in the presence of dentin, creating a microenvironment capable of attracting pulp cells to its surface and inducing the overexpression of odontoblastic markers in a cell-homing strategy.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Chitosan-Calcium-Simvastatin Scaffold as an Inductive Cell-Free Platform

Soares¹,

Bordini

Bronze‐Uhle³

et al. 2021

J Dent Res

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“…Researchers have tried and are still trying to overwhelm the shortfalls. The most hopeful ones are those that combine chitosan-based formulations and synthetic inorganic biomaterial similar to the calcified phase of natural bone [42].…”

Section: Chitosan In Bone Tissues Therapymentioning

confidence: 99%

Chitosan Based Biocomposites for Hard Tissue Engineering

Dabbarh¹,

Elbakali-Kassimi²,

Berrada³

2021

Chitin and Chitosan - Physicochemical Properties and Industrial Applications [Working Title]

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Bone is the second most transplanted organ, just after blood. It provides structural support, protection for organs and soft tissues. It holds some critical biological processes such as the bone marrow blood forming system. It is responsible for storing and supplying minerals such calcium and phosphate. Bone is a connective tissue formed by two predominant phases: an inorganic phase containing mainly apatitic calcium and phosphate and an organic phase made of fibrous type I collagen. This natural biocomposite has many biological features such osteoconductivity, osteoinductivity, osteogenicity and is subject to a continuous remodeling process through osteoclastic and osteoblastic activities. In biomedical engineering, the restoration of damaged hard tissue with autologous bone is not always possible or even the best option. The development of some safe and low-cost alternatives such as biocomposites that mimic organic and calcified bone materials have shown very good results and offer an alternative to autologous bone implants. However, the mechanical properties of biocomposites still present a big challenge as a hard tissue substitute. This chapter reviews the properties of bone substitute materials chitosan and calcium phosphates, discusses strategies used in the treatment of calcified hard tissues as well as new approaches developed in this field.

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“…HA is one of the most used biomaterials for bone regeneration because its inorganic component is similar to natural apatite, the mineral that constitutes bone matrix and provides rigidity to bone [ 3 , 4 ]. It is biocompatible, minimally inflammatory, osteoconductive, osteoinductive, and biodegradable [ 5 , 6 ]. Moreover, HA can be prepared both by synthetic and natural sources via easy fabrication strategies, which makes it an attractive grafting material [ 7 ].…”

Section: Introductionmentioning

confidence: 99%

Antimicrobial Effect and Cytotoxic Evaluation of Mg-Doped Hydroxyapatite Functionalized with Au-Nano Rods

et al. 2021

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Hydroxyapatite (HA) is the main inorganic mineral that constitutes bone matrix and represents the most used biomaterial for bone regeneration. Over the years, it has been demonstrated that HA exhibits good biocompatibility, osteoconductivity, and osteoinductivity both in vitro and in vivo, and can be prepared by synthetic and natural sources via easy fabrication strategies. However, its low antibacterial property and its fragile nature restricts its usage for bone graft applications. In this study we functionalized a MgHA scaffold with gold nanorods (AuNRs) and evaluated its antibacterial effect against S. aureus and E. coli in both suspension and adhesion and its cytotoxicity over time (1 to 24 days). Results show that the AuNRs nano-functionalization improves the antibacterial activity with 100% bacterial reduction after 24 h. The toxicity study, however, indicates a 4.38-fold cell number decrease at 24 days. Although further optimization on nano-functionalization process are needed for cytotoxicity, these data indicated that Au-NRs nano-functionalization is a very promising method for improving the antibacterial properties of HA.

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Chitosan-Based Biomimetically Mineralized Composite Materials in Human Hard Tissue Repair

Cited by 40 publications

References 124 publications

Chitosan-Calcium-Simvastatin Scaffold as an Inductive Cell-Free Platform

Chitosan-Calcium-Simvastatin Scaffold as an Inductive Cell-Free Platform

Chitosan Based Biocomposites for Hard Tissue Engineering

Antimicrobial Effect and Cytotoxic Evaluation of Mg-Doped Hydroxyapatite Functionalized with Au-Nano Rods

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