Effect of polymer deposition method on thermoresponsive polymer films and resulting cellular behavior.

Poly(N-isopropyl acrylamide) or pNIPAM is a thermoresponsive polymer that is widely studied for use in bioengineering applications. The interest in this polymer lies in the polymer's unique capability to undergo a sharp property change near physiological temperature, which aids in the spontaneous release of biological cells from substrates. Currently, there are many methods for depositing pNIPAM onto substrates, including atom-transfer radical polymerization (ATRP) and electron beam ionization. Each method yields pNIPAM-coated substrates with different surface characteristics that can influence cell behavior. In this work, we compare two methods of pNIPAM deposition: plasma deposition and codeposition with a sol-gel. The resulting pNIPAM films were analyzed for use as substrates for mammalian cell culture based on surface characterization (XPS, ToF-SIMS, AFM, contact angles), cell attachment/detachment studies, and an analysis of exocytosis function using carbon-fiber microelectrode amperometry (CFMA). We find that although both methods are useful for the deposition of functional pNIPAM films, plasma deposition is much preferred for cell-sheet engineering applications because of the films' thermoresponse, minimal change in cell density, and maintenance of supported cell exocytosis function.

The effects of cell culture parameters on cell release kinetics from thermoresponsive surfaces.

The thermoresponsive properties of poly(N-isopropyl acrylamide) (pNIPAM) have led to its wide use in bioengineering applications, including the reversible adhesion of mammalian cells. The groups performing this research have used different solutions to initiate cell release and have varied the temperature of the solution during detachment. To our knowledge, there has been no direct correlation between the solution identity or temperature on the efficiency of cell release from pNIPAM films. In this work, we present a study of the effect of the solution type and temperature used to initiate detachment on the time required to achieve 100% detachment of bovine aortic endothelial cells (BAECs) from pNIPAM. The pNIPAM films used in this work were obtained using a novel technique using a spin-coated solution containing pNIPAM (spNIPAM). We found that the fastest, most reliable release of cells occurred below the LCST of the polymer at 4 degrees C in serum free media (SFM). As it is sometimes desirable to stop cell metabolism at the time of detachment (e.g., to "freeze" protein expression prior to subsequent analysis), the use of extremely cold SFM would be ideal in such cases.