posted on 2019-01-29, 00:00authored byJaime Santillán, Emmanuel A. Dwomoh, Yaiel G. Rodríguez-Avilés, Samir A. Bello, Eduardo Nicolau
Tissue
engineering leads to the development of biomaterial scaffolds
where its biocompatibility and bioactivity are often improved after
performing physical or chemical surface modification treatments. Micropatterning,
soft lithography, and biofabrication are also approaches that provide
a biomimetic microenvironment but have proven very costly and time
consuming. In this concern, an appropriate substrate with suitable
sites for cell attachment represents a major factor in cell behavior
and biological functions. For this reason, our strategy was to fabricate
a standard fibrous biomaterial with reproducible surface topography,
incorporating microbeads and nanofeatures, and show the positive outcomes
of the new substrate reflected on cell functions of bone cells. The
electrospun polycaprolactone (PCL) beads-on-string membranes were
obtained by adjusting the spinning solution at different concentrations
until continuous beads were formed. Cell adhesion and proliferation,
on the PCL scaffold, were analyzed the subsequent 2 days after initial
culture. Complementary studies of cytoskeleton spreading and differentiation
were analyzed after 7 and 14 days of the initial incubation. The scanning
electron microscopy (SEM) images showed evidence of the formation
of beads-on-string nanofibers and suggested that as-formed microstructures
worked as attachment sites for osteoblasts. We investigated cell proliferation
using anti-BrdU fluorescence assay, and results show a similar proliferation
rate of cells cultured between PCL scaffolds and control. Finally,
Phalloidin TRITC and antisialoprotein antibody were used to analyze
cell spreading and differentiation after 7 and 14 days, respectively.
This work shows a low-cost fabrication method to produce a biodegradable
scaffold with micro/nanostructured characteristics that favor cell
adhesion, proliferation, maturation, and subsequent differentiation
of osteoblasts. According to the results, the biocompatibility of
PCL beads-on-string could be comparable to other complex biomaterials,
and we conclude that our scaffold is optimal for applications in bone
tissue regeneration.