posted on 2024-07-21, 20:03authored byGuilherme
Castro Brito, Gustavo Fernandes Sousa, Moises Virgens Santana, André Sales Aguiar Furtado, Millena de Cassia Sousa E Silva, Thiago Ferreira
Candido Lima Verde, Renata Barbosa, Tatianny Soares Alves, Luana Marotta Reis Vasconcellos, Leonardo Alvares Sobral Silva, Vicente Galber Freitas Viana, José Figueredo-Silva, Antônio
Luiz Martins Maia Filho, Fernanda Roberta Marciano, Anderson Oliveira Lobo
In situ 3D printing is attractive for
the direct
repair of bone defects in underdeveloped countries and in emergency
situations. So far, the lack of an interesting method to produce filament
using FDA-approved biopolymers and nanoceramics combined with a portable
strategy limits the use of in situ 3D printing. Herein, we investigated
the osseointegration of new nanocomposite filaments based on polylactic
acid (PLA), laponite (Lap), and hydroxyapatite (Hap) printed directly
at the site of the bone defect in rats using a portable 3D printer.
The filaments were produced using a single-screw extruder (L/D = 26),
without the addition of solvents that can promote the toxicity of
the materials. In vitro performance was evaluated
in the cell differentiation process with mesenchymal stem cells (MSC)
by an alkaline phosphatase activity test and visualization of mineralization
nodules; a cell viability test and total protein dosage were performed
to evaluate cytotoxicity. For the in vivo analysis,
the PLA/Lap composite filaments with a diameter of 1.75 mm were printed
directly into bone defects of Wistar rats using a commercially available
portable 3D printer. Based on the in vitro and in vivo results, the in situ 3D printing
technique followed by rapid cooling proved to be promising for bone
tissue engineering. The absence of fibrous encapsulation and inflammatory
processes became a good indicator of effectiveness in terms of biocompatibility
parameters and bone tissue formation, and the use of the portable
3D printer showed a significant advantage in the application of this
material by in situ printing.