A wide variety of substrates can be functionalized to attach spacer molecules therein by exposing the substrates to a cold plasma ignited in dichlorosilane, silicon tetrachloride or hexachlorodisilane gas to implant silicon-chlorine functionalities in the substrate surface. The plasma implanted surface functionalities can then be utilized to initiate second stage gas phase derivatization reactions to form linker molecules attached to the substrate. Active biomolecules such as enzymes can then be bound to the exposed linker molecules to bind the bioactive molecules to the substrate while allowing freedom of movement and conformation of the bound molecule comparable to that of the free molecule.
Methods for producing plasma-treated, functionalized carbon-containing surfaces are provided. The methods include the steps of subjecting a carbon-containing substrate to a plasma to create surface active sites on the surface of the substrate and reacting the surface active sites with stable spacer molecules in the absence of plasma. Biomolecules may be immobilized on the resulting functionalized surfaces. The methods may be used to treat a variety of carbon-containing substrates, including polymeric surfaces, diamond-like carbon films and carbon nanotubes and nanoparticles.
