Repair of Bone Defects with Chitosan-Collagen Biomembrane and Scaffold Containing Calcium Aluminate Cement

Moraes, Paola Castro; Marques, Isabela Cristina de Souza; Basso, Fernanda Gonçalves; Rossetto, Hebert Luis; Pires‐de‐Souza, Fernanda de Carvalho Panzeri; Costa, Carlos Alberto de Souza; Garcia, Lucas da Fonseca Roberti

doi:10.1590/0103-6440201601454

Cited by 16 publications

(17 citation statements)

References 21 publications

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“…The authors also showed that CHAlCa scaffold acts as a biocompatible and bioactive matrix, since cell proliferation, ALP activity, DSPP mRNA expression and calcium-rich matrix deposition were significantly enhanced in those HDPCs seeded onto its structure. The bioactive potential of CHAlCa may be related to the hydration process of AlCa cement when in contact with humidity, releasing Ca²+ and Al³+ ions over a long period of time (15). It has been shown that CHAlCa scaffold is capable of releasing Ca²+ when immersed in water, leading to the establishment of an alkaline (pH=9.0) environment within 24 h, followed by a stabilization (pH =7.8) up to 7 days (9).…”

Section: Discussionmentioning

confidence: 99%

“…It has been shown that CHAlCa scaffold is capable of releasing Ca²+ when immersed in water, leading to the establishment of an alkaline (pH=9.0) environment within 24 h, followed by a stabilization (pH =7.8) up to 7 days (9). A number of studies demonstrated that Ca²+ gradient exerts chemotactic, proliferative, and bioactive effects on MSCs (7,8,15). In these studies, the authors reported that a slightly alkaline environment (pH 8.0-9.0) favors odontoblastic differentiation of pulp cells.…”

Section: Discussionmentioning

confidence: 99%

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Simvastatin-Enriched Macro-Porous Chitosan-Calcium-Aluminate Scaffold for Mineralized Tissue Regeneration

et al. 2020

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The present study evaluated the odontogenic potential of human dental pulp cells (HDPCs) exposed to chitosan scaffolds containing calcium aluminate (CHAlCa) associated or not with low doses of simvastatin (SV). Chitosan scaffolds received a suspension of calcium aluminate (AlCa) and were then immersed into solutions containing SV. The following groups were established: chitosan-calcium-aluminate scaffolds (CHAlCa - Control), chitosan calcium-aluminate with 0.5 µM SV (CHAlCa-SV0.5), and chitosan calcium-aluminate with 1.0 µM SV (CHAlCa-SV1.0). The morphology and composition of the scaffolds were evaluated by SEM and EDS, respectively. After 14 days of HDPCs culture on scaffolds, cell viability, adhesion and spread, mineralized matrix deposition as well as gene expression of odontogenic markers were assessed. Calcium aluminate particles were incorporated into the chitosan matrix, which exhibited regular pores homogeneously distributed throughout its structure. The selected SV dosages were biocompatible with HDPCs. Chitosan-calcium-aluminate scaffolds with 1 µM SV induced the odontoblastic phenotype in the HDPCs, which showed enhanced mineralized matrix deposition and up-regulated ALP, Col1A1, and DMP-1 expression. Therefore, one can conclude that the incorporation of calcium aluminate and simvastatin in chitosan scaffolds had a synergistic effect on HDPCs, favoring odontogenic cell differentiation and mineralized matrix deposition.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Simvastatin-Enriched Macro-Porous Chitosan-Calcium-Aluminate Scaffold for Mineralized Tissue Regeneration

et al. 2020

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“…Chitosan is a cationic polysaccharide, deriving from chitin deacetylation, which has gained a prominent place in biomedicine for a wide range of applications including drug delivery, wound dressings, bacterial contamination control, fat binding, and tissue engineering [1,2,3,4,5]. The peculiarity of chitosan, compared to other polysaccharides, is that it has been shown to provoke minimal or no foreign-body reaction, including inflammatory response and fibrotic encapsulation when used in hydrogel systems [6,7], polyelectrolyte multilayers [8], biomembranes [9] and as a porous 3-D scaffold [10]. Besides, chitosan has been shown to promote cell adhesion and proliferation in tissue engineering applications, especially when applied for bone tissue regeneration where it showed osteoconductivity and ability to promote osteogenic differentiation [11,12,13,14,15,16].…”

Section: Introductionmentioning

confidence: 99%

Graphene Oxide Oxygen Content Affects Physical and Biological Properties of Scaffolds Based on Chitosan/Graphene Oxide Conjugates

et al. 2019

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Tissue engineering is a highly interdisciplinary field of medicine aiming at regenerating damaged tissues by combining cells with porous scaffolds materials. Scaffolds are templates for tissue regeneration and should ensure suitable cell adhesion and mechanical stability throughout the application period. Chitosan (CS) is a biocompatible polymer highly investigated for scaffold preparation but suffers from poor mechanical strength. In this study, graphene oxide (GO) was conjugated to chitosan at two weight ratios 0.3% and 1%, and the resulting conjugates were used to prepare composite scaffolds with improved mechanical strength. To study the effect of GO oxidation degree on scaffold mechanical and biological properties, GO samples at two different oxygen contents were employed. The obtained GO/CS scaffolds were highly porous and showed good swelling in water, though to a lesser extent than pure CS scaffold. In contrast, GO increased scaffold thermal stability and mechanical strength with respect to pure CS, especially when the GO at low oxygen content was used. The scaffold in vitro cytocompatibility using human primary dermal fibroblasts was also affected by the type of used GO. Specifically, the GO with less content of oxygen provided the scaffold with the best biocompatibility.

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“…Moraes et al 14 estudaram o reparo ósseo em defeitos na calvária de coelhos, em quatro grupos de intervenção: um com biomembrana de quitosana, outro com um scaffolds de aluminato de cálcio, um grupo controle e um com osso autólogo. No entanto diferente do que foi relatado no estudo de Chen et al 12 , o autor encontrou que a biomembrana de quitosana obteve menor cicatrização óssea entre os grupos.…”

Section: Discussionunclassified

Aplicações e possibilidades terapêuticas do uso do biomaterial quitosana para a odontologia: revisão de literatura

Lopes¹,

Maciel²,

Neto³

et al. 2020

Arch Health Invest

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A quitosana, polissacarídeo linear obtido a partir do exoesqueleto de crustáceos e artrópodes, tem sido pesquisada em Odontologia por suas diversas propriedades terapêuticas. O objetivo do presente estudo foi realizar uma revisão da literatura sobre as aplicações atuais e as possibilidades terapêuticas da quitosana na odontologia. A busca foi realizada através do banco de dados eletrônico do Pubmed, utilizando os descritores Quitosana, Odontologia e Biomateriais. Foram incluídas pesquisas científicas utilizando quitosana em diversas áreas da odontologia e excluídas revisões de literatura e estudos não odontológicos, sendo selecionados 13 artigos. A quitosana induz resposta transcricional e anti-inflamatória em fibroblastos gengivais sobre citocinas inflamatórias, fatores transformadores do crescimento (TGF -β) e fatores de crescimento tumoral (TNF-α) que estão diretamente relacionados à atividade patológica periodontal. Nas infecções endodônticas persistentes, a substância atua criando ligações de hidrogênio e liberação de íons cálcio, o que potencializa a ação dos irrigadores intracanal, além de causar menos estresse oxidativo. Para a odontologia restauradora, a quitosana demonstrou eficácia como auxiliar no condicionamento da dentina e mostrou potencial para induzir a migração de odontoblastos na proteção do complexo dentino-pulpar. A substância atua como uma cura de feridas orais devido à sua capacidade de estimular a formação de fibroblastos e novos vasos sanguíneos, além de células anti-inflamatórias. Descritores: Biopolímeros; Biomateriais; Biotecnologia. Referências Zhao X, Li P, Guo B, Ma PX. Antibacterial and conductive injectable hydrogels based on quaternized chitosan-graft-polyaniline/oxidized dextran for tissue engineering. Acta Biomater. 2015;26:236-48. Tomihata K, Ikada Y. In vitro and in vivo degradation of films of chitin and its deacetylated derivatives. Biomaterials. 1997;18(7):567-75 Citgez B, Cengiz AN, Akgun I, Uludag M, Yetkin G, Bahat N, Ozcan O, Polat N, Akcakaya A, Karatepe O. Effects of chitosan on healing and strength of colonic anastomosis in rats. Acta Cir Bras. 2012;27(10):707-12. Azevedo VVC, Chaves SA, Bezerra DC, Lia Fook MV, Costa ACFM. Quitina e Quitosana: aplicações como biomateriais. Rev Eletr Mater Proc. 2007;2(3):27-34. Tavaria FK, Costa EM, Pina-Vaz I, Carvalho MF, Pintado MM. A quitosana como biomaterial odontológico: estado da arte. Rev Bras Eng Bioméd. 2013;29(1):110-20. Ueno H, Nakamura F, Murakami M, Okumura M, Kadosawa T, Fujinag T. Evaluation effects of chitosan for the extracellular matrix production by fibroblasts and the growth factors production by macrophages. Biomaterials. 2001;22(15):2125-30. Shahid F, Abuzaytoun R. Chitin, chitosan, and co-products: chemistry, production, applications, and health effects. Adv Food Nutr Res. 2005;49(1):93-135. Croisier F, Jerome C. Chitosan-based biomaterials for tissue engineering. Eur Polym J. 2013;49(1):780-92. Giovino C, Ayensu I, Tetteh J, Boateng JS. An integrated buccal delivery system combining chitosan films impregnated with peptide loaded PEG-b-PLA nanoparticles. Colloids Surf B Biointerfaces. 2013;112(1):9-15. Wieckiewicz M, Boening KW, Grychowska N, Paradowska-Stolarz,U. Clinical Application of Chitosan in Dental Specialities. Mini Rev Med Chem. 2017;17(5):401-9. Ravi Kumar MNV. A análise dos pedidos de quitina e quitosana. R React Funct 2000;46(1):1-27. Chen CK, Chang NJ, Wu YT, Fu E, Shen EC, Feng CW, Wen ZH. Bone Formation Using Cross-Linked Chitosan Scaffolds in Rat Calvarial Defects. Implant Dent. 2018;27(1):15-21 Pavez L, Tobar N, Chacon C, Arancibia R, Martinez C, Tapia et al. Chitosan triclosan particles modulate inflammatory signaling in gingival fibroblasts. J Periodontal Res. 2017; 53(2):232-39. Moraes PC, Marques ICS, Basso FG, Rosseto HL, Pires de Sousa FCP, Costa CAS et al. Repair of Bone Defects with Chitosan- Collagen Biomembrane and Scaffold Containing Calcium Aluminate Cement. Braz Dent J. 2017;28(3):287-95. Aydin UZ, Akpinar KE, Hepokur C, Erdönmez D. Assessment of toxicity and oxidative DNA damage of sodium hypochlorite, chitosan and propolis on fibroblast cells. Braz Oral Res. 2018;32(1):1-8. Özdoğan AI, Ilarslan YD, Kösemehmetoğlu K, Acka G, Kutlu HB, Comerdov E et al. In Vivo Evaluation of Chitosan Based Local Delivery Systems for Atorvastatin in Treatment of Periodontitis. Int J Pharm. 2018;25(1):470-76. Paiola FG, Lopes FC, Mazzi-Chaves JF, Pereira RD, Oliveira HF, Queiroz AM et al. How to improve root canal filling in teeth subjected to radiation therapy for câncer. Braz Oral Res. 2018;32(1):1-9. Farhadian N, Godiny M, Moradi S, Hemati Azandaryani A, Shahlaei M. Chitosan/gelatin as a new nano-carrier system for calcium hydroxide delivery in endodontic applications: Development, characterization and process optimization. Mater Sci Eng C Mater Biol Appl. 2018;92:540-46. Subhi H, Reza F, Husein A, Al Shehadat SA, Nurul AA. Gypsum-Based Material for Dental Pulp Capping: Effect of Chitosan and BMP-2 on Physical, Mechanical, and Cellular Properties. Int J Biomater. 2018;2018:3804293. Soares DG, Anovazzi G, Bordini EAF, Zuta UO, Silva Leite MLA, Basso FG, Hebling J, de Souza Costa CA. Biological Analysis of Simvastatin-releasing Chitosan Scaffold as a Cell-free System for Pulp-dentin Regeneration. J Endod. 2018;44(6):971-76. Işılay Özdoğan A, Akca G, Şenel S. Development and in vitro evaluation of chitosan based system for local delivery of atorvastatin for treatment of periodontitis. Eur J Pharm Sci. 2018;124:208-16. Kesim B, Burak AK, Ustun Y, Delikan E, Gungor A. Effect of chitosan on sealer penetration into the dentinal tubules. Niger J Clin Pract. 2018;21(10):1284-90. Guo JM, Makvandi P, Wei CC, Chen JH, Xu HK, Breschi L, Pashley DH, Huang C, Niu LN, Tay FR. Polymer conjugation optimizes EDTA as a calcium-chelating agent that exclusively removes extrafibrillar minerals from mineralized collagen. Acta Biomater. 2019;90:424-40. Susanto A, Susanah S, Priosoeryanto BP, Satari MH, Komara I. The effect of the chitosan-collagen membrane on wound healing process in rat mandibular defect. J Indian Soc Periodontol. 2019;23(2):113-18.

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Repair of Bone Defects with Chitosan-Collagen Biomembrane and Scaffold Containing Calcium Aluminate Cement

Cited by 16 publications

References 21 publications

Simvastatin-Enriched Macro-Porous Chitosan-Calcium-Aluminate Scaffold for Mineralized Tissue Regeneration

Simvastatin-Enriched Macro-Porous Chitosan-Calcium-Aluminate Scaffold for Mineralized Tissue Regeneration

Graphene Oxide Oxygen Content Affects Physical and Biological Properties of Scaffolds Based on Chitosan/Graphene Oxide Conjugates

Aplicações e possibilidades terapêuticas do uso do biomaterial quitosana para a odontologia: revisão de literatura

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