Cell adhesion on ligand gradient substrates: A thermodynamic study

## Abstract Directional cell motility plays a key role in many biological processes like morphogenesis, inflammation, wound repair, angiogenesis, immune response, and tumor metastasis. Cells respond to the gradient in surface ligand density by directed locomotion towards the direction of higher lig

## Abstract Surface density profile of bioadhesive ligands greatly influences spreading and migration of cells on substrates. A 1D peeling model is developed to predict the equilibrium adhesion strength and peeling tension of a cell membrane, adhered on a substrate with linearly increasing density

## Abstract Synthetic phosphothioated (PTO) oligodeoxynucleotide (ODN) sequences are commonly used for a variety of applications that benefit from nuclease protection. The PTO modification is implemented mainly in antisense ODN, but also in ODN that were shown to activate members of the toll‐like r

## Abstract A continuum model was proposed to simulate a biological cell adhering to a substrate surface domain with selectively coated ligands. Cell adhesion was modeled by a traction‐separation law depending on the receptor‐ligand distance and their densities. It was found that the obtained sprea

## Abstract The regulation of cell motility on ligand‐adsorbed poly(ethylene glycol) (PEG)‐based polymeric biomaterials is governed by variables that are not well characterized. In this report, we examined keratinocyte migratory responsiveness to PEG‐variant tyrosine‐derived polycarbonates adsorbed