Please use this identifier to cite or link to this item:https://hdl.handle.net/20.500.12512/13528
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dc.contributor.authorPetrauskaitė, Odeta-
dc.contributor.authorLiesienė, Jolanta-
dc.contributor.authorJuodžbalys, Gintaras-
dc.contributor.authorGomes, Pedro de Sousa-
dc.contributor.authorCosta, Maria Elisabete Jorge Vieira da-
dc.coverage.spatialLV-
dc.date.accessioned2019-12-23T00:24:29Z-
dc.date.available2019-12-23T00:24:29Z-
dc.date.issued2012-
dc.identifier.other990000810940107106-
dc.identifier.otherKMU02-000081094-
dc.identifier.other(Li-KaLSM)000081094KMU02-Aleph-
dc.identifier.urihttps://elsevier.conference-services.net/resources/247/3159/pdf/HYMA2013_0289.pdf-
dc.description.abstractNowadays one of the most promising approaches in bone tissue engineering is processing of highly porous polymer-based three-dimensional scaffolds which serve as frameworks for bone tissue in-growth. In order to increase the bioactivity or/and mechanical properties of the scaffold usually bioceramics are embedded into the polymer matrix. The present work explores nanohydroxyapatite/ cellulose scaffolds for bone tissue regeneration in bone cavities. The composite scaffolds were prepared by reinforcing a gel of regenerated cellulose with nanohydroxyapatite. A highly porous structure of the matrix was obtained by freeze-drying method. It was found out that the porous structure of the composite depended on the solvent which was in its discontinuous phase before freeze-drying, as well as on morphology of hydroxyapatite nanoparticles. The pore size of prepared matrix ranged from nanometric to micron scale, thus confirming cell adhesion, proliferation and space for vascularization. Biomimetic mineralization was performed in a simulated body fluid (pH 7.4) at 37 °C. Scaffolds bioactivity was substantiated by appearance of bone-like apatite onto the surface. Mass increase measurements showed that the mass percentage of hydroxyapatite was approx. 11 %. Furthermore, the interaction of MG-63 human osteoblastic-cells with novel scaffolds was investigated. The results showed that composites were not cytotoxic and induced the growth of the seeded osteoblastic-like cells. Attained results confirm the suitability of prepared scaffolds for bone tissue regeneration in vivoen
dc.description.sponsorshipKauno technologijos universitetas-
dc.description.sponsorshipLietuvos sveikatos mokslų universitetas-
dc.description.sponsorshipVeido ir žandikaulių chirurgijos klinika-
dc.format.extentno. [B.1.5.5]-
dc.language.isoen-
dc.relation.ispartofThird International Conference on Multifunctional, Hybrid and Nanomaterials : 3-7 March 2013 in Sorrento (near Naples), Italy / Organised by Elsevier ; Organising Committee: Markus Antonietti, Kazuyuki Kuroda, Jacques Livage, Samuel I. Stupp. Sorrento, 2013-
dc.relation.ispartofseries(Poster Session 1)-
dc.subjectBone regenerationen
dc.subjectTissue engineeringen
dc.subjectBiocompatible materialsen
dc.subjectchemistryen
dc.subjectCelluloseen
dc.subjectchemistryen
dc.subjectCarboxymethylcellulose sodiumen
dc.subjectchemistryen
dc.subjectNanocompositesen
dc.subjectchemistryen
dc.subjectMaterials testingen
dc.subjectmethodsen
dc.subject.classificationKonferencijų tezės nerecenzuojamuose leidiniuose / Conference theses in non-peer-reviewed publications (T2)-
dc.subject.otherMedicina / Medicine (M001)-
dc.titleNano-hydroxyapatite/cellulose scaffoldsen
dc.typeconference paper-
dc.date.updated2021-12-16T11:48Z-
local.typeT-
item.fulltextNo Fulltext-
item.grantfulltextnone-
crisitem.author.deptLietuvos sveikatos mokslų universitetas-
Appears in Collections:Universiteto mokslo publikacijos / University Research Publications
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