Assessment of the regenerative potential of macro-porous chitosan-calcium simvastatin scaffolds on bone cells.
Marjorie de Oliveira GallinariEster Alves Ferreira BordiniVitor de Toledo StuaniFernanda Balestrero CassianoCamila Correa da Silva Braga de MeloJuliano Milanezi de AlmeidaLuciano Tavares Angelo CintraCarlos Alberto de Souza CostaDiana Gabriela Soares Dos PassosPublished in: Brazilian oral research (2023)
This study evaluated the bioactive potential of a macro-porous chitosan scaffold incorporated with calcium hydroxide (CH-Ca) and functionalized with bioactive doses of simvastatin (SV) for bone tissue regeneration. Initially, the bioactive dose of SV in osteoblastic cells (SAOS-2) was determined. For the direct contact experiment, SAOS-2 cells were plated on scaffolds to assess cell viability and osteogenic differentiation. The second assay was performed at a distance using extracts from scaffolds incubated in culture medium to assess the effect of conditioned medium on viability and osteogenic differentiation. The initial screening showed that 1 μM SV presented the best biostimulating effects, and this dose was selected for incorporation into the CH-Ca and pure chitosan (CH) scaffolds. The cells remained viable throughout the direct contact experiment, with the greatest cell density in the CH-Ca and CH-Ca-SV scaffolds because of their higher porosity. The CH-Ca-SV scaffold showed the most intense bio-stimulating effect in assays in the presence and absence of osteogenic medium, leading to an increased deposition of mineralized matrix. There was an increase in the viability of cells exposed to the extracts for CH-Ca, CH-SV, and CH-Ca-SV during the one-day period. There was an increase in ALP activity in the CH-Ca and CH-Ca-SV; however, the CH-Ca-SV scaffold resulted in an intense increase in the deposition of mineralized nodules, approximately 56.4% at 7 days and 117% at 14 days, compared with CH (control). In conclusion, functionalization of the CH-Ca scaffold with SV promoted an increase in bioactivity, presenting a promising option for bone tissue regeneration.
Keyphrases
- tissue engineering
- room temperature
- induced apoptosis
- cell cycle arrest
- mesenchymal stem cells
- stem cells
- protein kinase
- drug delivery
- bone marrow
- endoplasmic reticulum stress
- wound healing
- cell therapy
- ionic liquid
- bone regeneration
- quantum dots
- gold nanoparticles
- case report
- angiotensin ii
- human health
- tandem mass spectrometry