posted on 2024-03-06, 13:34authored byMohammad Asadi Tokmedash, Jouha Min
Effective tissue regeneration and
immune responses are essential
for the success of biomaterial implantation. Although the interaction
between synthetic materials and biological systems is well-recognized,
the role of surface topographical cues in regulating the local osteoimmune
microenvironmentspecifically, their impact on host tissue
and immune cells, and their dynamic interactionsremains underexplored.
This study addresses this gap by investigating the impact of surface
topography on osteogenesis and immunomodulation. We fabricated MXene/hydroxyapatite
(HAP)-coated surfaces with controlled 2.5D nano-, submicro-, and microscale
topographical patterns using our custom bottom-up patterning method.
These engineered surfaces were employed to assess the behavior of
osteoblast precursor cells and macrophage polarization. Our results
demonstrate that MXene/HAP-coated surfaces with microscale crumpled
topography significantly influence osteogenic activity and macrophage
polarization: these surfaces notably enhanced osteoblast precursor
cell spreading, proliferation, and differentiation and facilitated
a shift in macrophages toward an anti-inflammatory, prohealing M2
phenotype. The observed cell responses indicate that the physical
cues from the crumpled topographies, combined with the chemical cues
from the MXene/HAP coatings, synergistically create a favorable osteoimmune
microenvironment. This study presents the first evidence of employing
MXene/HAP-multilayer coated surfaces with finely crumpled topography
to concurrently facilitate osteogenesis and immunomodulation for improved
implant-to-tissue integration. The tunable topographic patterns of
these coatings coupled with a facile and scalable fabrication process
make them widely applicable for various biomedical purposes. Our results
highlight the potential of these multilayer coatings with controlled
topography to improve the in vivo performance and fate of implants
by modulating the host response at the material interface.