The surface electric
potential of biomaterials has been extensively
proven to play a critical role in stem cells’ fate. However,
there are ambiguous reports on the relation of stem cells’
osteogenic capacity to surface potential characteristics (potential
polarity and intensity). To address this, we adopted a surface with
a wide potential range and both positive/negative polarity in a comprehensive
view to get insight into surface potential-regulating cellular osteogenic
differentiation. Tb
x
Dy1–x
Fe2 alloy/poly(vinylidene fluoride-trifluoroethylene)
magnetoelectric films were prepared, and the film could provide controllable
surface potential characteristics with positive or negative polarity
and potential (ϕME) intensity variation from 0 to
±120 mV as well as keep the surface chemical composition and
microstructure unchanged. Cell culture results showed that osteogenic
differentiation of mesenchymal stem cells on both positive and negative
potential films was obviously upregulated when the /ϕME/ intensities were set from 0–55 mV. Differently, the highest
upregulated osteogenic differentiation on the positive potential films
corresponded to the /ϕME/ intensity from 35–55
mV and was better than that on the negative potential films whereas
the highest on the negative potential films corresponded to the /ϕME/ intensity from 0–35 mV and was better than that
on the positive potential films. This fact could illustrate why previous
reports appeared ambiguously; i.e., the comparative result in osteogenic
differentiation between the positive and negative potential films
strongly depends on the selection of surface potential intensity.
On the basis of assaying of the exposed functional sites (RGD and
PHSRN) of the adsorbed fibronectin (FN) and the expression of cellular
integrin α5 and β1 subunits, the difference in the behavior
between the positive and negative potential films was attributed to
the distinct conformation of adsorbed fibronectin (FN) and the opposite
changing trend with /ϕME/ for the two films, which
triggers the osteogenesis-related FAK/ERK signaling pathway to a different
extent. This study could provide new cognition for the in-depth understanding
of the regulation mechanism underlying surface potential characteristics
in cell behaviors.
Electrical stimulation has been proved to be critical to regulate cell behavior. But, cell behavior is also susceptible to multiple parameters of the adverse interferences such as surface current, electrochemical reaction products, and non‐uniform compositions, which often occur during direct electric stimulation. To effectively prevent the adverse interferences, a novel piezoelectric poly(vinylidene fluoride‐trfluoroethylene)(P(VDF‐TrFE)) layer was designed to coat onto the indium tin oxide (ITO) planar microelectrode. We found the electrical stimulation was able to regulate the osteogenic differentiation of mesenchymal stem cells (MSCs) through calcium‐mediated PKC signaling pathway. Meanwhile, the surface charge of the designed P(VDF‐TrFE) coating layer could be easily controlled by the pre‐polarization process, which was demonstrated to trigger integrin‐mediated FAK signaling pathway, finally up‐regulating the osteogenic differentiation of MSCs. Strikingly, the crosstalk in the downstream of the two signaling cascades further strengthened the ERK pathway activation for osteogenic differentiation of MSCs. This P(VDF‐TrFE) layer coated electrical stimulation microelectrodes therefore provide a distinct strategy to manipulate multiple‐elements of biomaterial surface to regulate stem cell fate commitment.
Macrophages have two functionalized phenotypes, M1 and M2, and the regulation of M1/M2 polarization of macrophages is critical for tissue repair. Tissue-derived immune factors are considered the major drivers of macrophage polarization.Based on the main cytokine-induced polarization pathways, we tested the effect of electrical stimulation (ES) of macrophages on the regulation of M1/M2 polarization and a possible synergistic effect with the cytokines. Indium tin oxide (ITO) planar microelectrodes were used to produce ES under different voltages, frequencies and waveforms. We evaluated the influence of ES on the cytokine-induced M1/M2 polarization using mouse bone marrow-derived macrophages cultured with both lipopolysaccharide (LPS)/IFN-γ factors and IL-4 factors for M1 and M2, respectively. The results showed that ES promoted the cytokine-induced macrophage polarization. Importantly, we found that stimulation with a square waveform selectively promoted LPS/IFN-γ-induced M1 polarization, while stimulation with a sinusoidal waveform promoted both LPS/IFN-γ-induced M1, and IL-4-induced M2 polarization. Mechanistically, stimulation with a square waveform affected the intracellular ion concentration, whereas stimulation with a sinusoidal waveform promoted both the intracellular ion concentration and membrane receptors. We hereby establish an ES-mediated strategy for immunomodulation via macrophage polarization.
The micromorphology of fillers plays an important role in tribological and mechanical properties of polymer matrices. In this work, a TiO2-decorated Ti2C3 (TiO2/Ti3C2) composite particle with unique micro-nano morphology was engineered to improve the tribological and thermo-mechanical properties of epoxy resin. The TiO2/Ti3C2 were synthesized by hydrothermal growth of TiO2 nanodots onto the surface of accordion-like Ti3C2 microparticles, and three different decoration degrees (low, medium, high density) of TiO2/Ti3C2 were prepared by regulating the concentration of TiO2 precursor solution. Tribological test results indicated that the incorporation of TiO2/Ti3C2 can effectively improve the wear rate of epoxy resin. Among them, the medium density TiO2/Ti3C2/epoxy nanocomposites gained a minimum wear rate. This may be ascribed by the moderate TiO2 nanodot protuberances on the Ti3C2 surface induced a strong mechanical interlock effect between medium-density TiO2/Ti3C2 and the epoxy matrix, which can bear a higher normal shear stress during sliding friction. The morphologies of worn surfaces and wear debris revealed that the wear form was gradually transformed from fatigue wear in neat epoxy to abrasive wear in TiO2/Ti3C2/epoxy nanocomposites. Moreover, the results of thermo-mechanical property indicated that incorporation of TiO2/Ti3C2 also effectively improved the storage modulus and glass transition temperature of epoxy resin.
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