The amount, type, and conformation of proteins adsorbed on an implanted biomaterial are believed to influence cell adhesion. Nevertheless, only a few research works have been dedicated to the contribution of protein adsorption force. To verify our hypothesis that the adsorption force of protein on biomaterial is another crucial mediator to cell adhesion, fibronectin (FN) adsorbed on self-assembled monolayers (SAMs) with terminal -OH, -CH3, and -NH2 was quantified for FN adsorption force (F(ad)) by utilizing a sphere/plane adsorption model and parallel plate flow chamber. As revealed, F(ad) on SAMs followed a chemistry-dependence of -NH2 > -CH3 ≫ -OH. It is further demonstrated that F(ad) together with FN conformation could regulate the late osteoblast adhesion and the consequent reorganization of the adsorbed FN and fibrillogenesis of the endogenous FN. Our study suggests that protein adsorption force plays a key role in cell adhesion and should be involved for better biomaterial design.
Low fluid shear stress (FSS) is the mechanical environment encountered by osteoblasts in implanted bones or native bones of bed rest patients. High sensitivity of osteoblasts to low FSS is beneficial to osteogenesis. We hypothesize that this sensitivity might be regulated by chemical microenvironment provided by scaffolds. To confirm this hypothesis, self-assembled monolayers (SAMs) were used to provide various surface chemistries including OH, CH3 , and NH2 while parallel-plate fluid flow system produced low FSS (5 dynes/cm(2) ). Alterations in S-phase cell fraction, alkaline phosphatase activity, fibronectin (Fn), and collagen type I (COL I) secretion compared to those without FSS exposure were detected to characterize the sensitivity. Osteoblasts on OH and CH3 SAMs demonstrated obvious sensitivity while on NH2 SAMs negligible sensitivity was observed. Examination of the cell aspect ratio, orientation, and focal adhesions before and after FSS exposure indicates that the full spreading and robust focal adhesions on NH2 SAMs should be responsible for the negligible sensitivity through increasing the cell tolerance to low FSS. Despite the higher sensitivity, the Fn and COL I depositions on both OH and CH3 SAMs after FSS exposure were still less than on NH2 SAMs without FSS exposure. These results suggest that elaborate design of surface chemical compositions is essential for orchestration of surface chemistry with low FSS to realize both high sensitivity and high matrix secretion, facilitating the formation of functional bone tissues in implanted bone.
Osteoblasts actively generate cell
traction force (CTF) to sense
chemical and mechanical microenvironments. Fluid shear stress (FSS)
is a principle mechanical stimulus for bone modeling/remodeling. FSS
and CTF share common interconnected elements for force transmission,
among which the role of the protein-material interfacial force (F
ad) remains unclear. Here, we found that, on
the low F
ad surface (5.47 ± 1.31
pN/FN), CTF overwhelmed F
ad to partially
desorb FN, and FSS exacerbated the desorption, resulting in disassembly
of the actin cytoskeleton and focal adhesions (FAs) to reduce CTF
and establishment of a new mechanical balance at the FN-material interface.
Contrarily, on the high F
ad surface (27.68
± 5.24 pN/FN), pure CTF or the combination of CTF and FSS induced
no FN desorption, and FSS promoted assembly of actin cytoskeletons
and disassembly of FAs, regaining new mechanical balance at the cell-FN
interface. These results indicate that F
ad is a mechanical regulator for transmission of CTF and FSS, which
has never been reported before.
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