In vivo evaluation of tricalcium phosphate scaffold for cranial prosthesis application

In vivo evaluation of tricalcium phosphate scaffold for cranial prosthesis application

Tricalcium phosphate beta phase (β-TCP) is a promising bioceramic that stimulates the formation of bone tissue due to its chemical composition, which is similar to those of bones and teeth, showing promising osseointegration and osteoinduction results. Its main applications are in the regeneration a...

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Bibliographic Details
Published in:Materials chemistry and physics Vol. 283; p. 125993
Main Authors: Ruiz-Aguilar, C., Gaytan-Tocaven, L., Paredes, R.G.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 01-05-2022
Elsevier BV
Subjects:
Bioceramics
Biomedical materials
Bone tissue
Bones
Brain
Calcium phosphates
Chemical composition
Cognitive ability
Hydroxyapatite
In vivo
In vivo methods and tests
Prostheses
Regeneration (physiology)
Scaffold
Scaffolds
Skull
Tricalcium phosphate
Tricalcium phosphate
Brain
In vivo
Bone tissue
Scaffold
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Summary:Tricalcium phosphate beta phase (β-TCP) is a promising bioceramic that stimulates the formation of bone tissue due to its chemical composition, which is similar to those of bones and teeth, showing promising osseointegration and osteoinduction results. Its main applications are in the regeneration and stimulation of cortical and trabecular bone tissue. β-TCP can be used in the human body in different ways: scaffolds, coatings, or granules. In the present investigation, we analyzed the implant bioactivity effects of a β-TCP scaffold in the skull at different timeslots. The scaffolds were characterized physically and chemically before being implanted in vivo. The authors evaluated possible behavioral consequences in cognitive and motor tests on Wistar rats during the time when the tricalcium phosphate scaffolds were reabsorbed, which stimulated the bone regeneration on the cranial defect. The results of the β-TCP scaffolds as skull implant in rats showed an excellent hydroxyapatite (HA) precipitation on the implant's surface, stimulating new bone formation in the defect zone without affecting the motor and cognitive abilities of the animals' during the six weeks after implantation. [Display omitted] •Aspects of learning, memory, and motor skills in Wistar rats while the dissolution of the cranial implant was evaluated.•β-TCP scaffolds allow osteoinduction and osteointegration in the rat skull at 8 weeks.•The scaffold ceramic implant did not cause motor or cognitive damage in the implanted subjects.
ISSN:0254-0584
1879-3312
DOI:10.1016/j.matchemphys.2022.125993