Renewable bioelectronic interface for electrobiocatalytic reactor

1 . A bioelectronic device comprising: an electrically conductive carbon electrode; and a bioelectronic interface bonded to a surface of the electrically conductive carbon electrode, and configured to regenerate, the bioelectronic interface including a catalytically active material that facilitates electron transfer, the catalytically active material configured to be releasably and electrostatically bound directly or indirectly to the surface via a polyelectrolyte, wherein the polyelectrolyte is configured to be removably and electrostatically bound to a non-thiol ionic linker that is covalently bound to a carbon atom at the surface. 2 . The device of claim 1 , in which the catalytically active material includes an enzyme that is bound directly or indirectly to the polyelectrolyte. 3 . The device of claim 2 , in which the enzyme is an oxidoreductase, a dehydrogenase, a secondary alcohol dehydrogenase or a mannitol dehydrogenase. 4 - 8 . (canceled) 9 . The device of claim 1 , wherein the non-thiol ionic linker is glycine. 10 . The device of claim 1 , wherein said polyelectrolyte is comprised of a compound that includes a linking moiety covalently bound to the carbon atom at the surface of the electrically conductive carbon electrode, and further includes at least one ionized moiety for achieving the direct or indirect electrostatic bonding of the catalytically active material to the electrically conductive carbon electrode. 11 . The device of claim 1 , wherein the carbon substrate is a vitreous carbon substrate. 12 . The device of claim 11 , wherein the vitreous carbon substrate is a reticulated vitreous carbon electrode. 13 . The device of claim 1 , wherein the bioelectronic interface further comprises a redox cofactor that facilitates or enhances activity of the catalytically active material. 14 . The device of claim 13 , wherein the bioelectronic interface includes an electron mediator that reduces the electrical potential needed to transfer electrons during a chemical reaction. 15 . The device of claim 14 , wherein the electron mediator is toluidine blue O, neutral red or Nile blue A. 16 - 17 . (canceled) 18 . The device of claim 13 , wherein the redox cofactor is covalently bound to a polyelectrolyte that is electrostatically bound directly or indirectly to the surface of the electrically conductive carbon electrode. 19 . The device of claim 13 , wherein the redox cofactor is selected from nicotinamide adenine dinucleotide (NAD), nicotinamide adenine dinucleotide phosphate (NADP), flavin adenine dinucleotide (FAD), flavin mononucleotide (FMN), and combinations thereof. 20 . The device of claim 18 , wherein a boronate linkage is used to bind the redox cofactor to said polyelectrolyte. 21 . The device of claim 1 , wherein the polyelectrolyte is polyethyleneimine. 22 - 24 . (canceled) 25 . The device of claim 1 , wherein the catalytically active material is associated with polyelectrolyte multilayers (PEMs) that are bound together by alternating layers of oppositely charged polyelectrolytes. 26 . The device of claim 25 , wherein a redox cofactor is associated with PEMs that are bound together by alternating layers of oppositely charged polyelectrolytes. 27 . The device of claim 25 , wherein a redox cofactor and an electron mediator are associated with PEMs that are bound together by alternating layers of oppositely charged polyelectrolytes. 28 . The device of claim 25 , wherein the oppositely charged polyelectrolytes are polyethyleneimine (PEI) and polyacrylic acid (PAA). 29 . The device of claim 1 , wherein the polyelectrolyte ionically bonds a dehydrogenase enzyme and a redox cofactor to an ionically functionalized, electrically conductive carbon electrode to which an electron mediator is bound. 30 . The device of claim 29 , wherein the catalytically active material includes at least two different catalytically active components. 31 . The device of claim 30 , wherein said catalytically active components comprise different enzymes that catalyze different reactions. 32 . The device of claim 31 wherein said enzymes comprise a xylose isomerase and a mannitol dehydrogenase. 33 . The device of claim 31 , wherein a branched linking moiety and the polyelectrolyte are used to couple the enzymes, and optionally couple a redox cofactor for one or both of the enzymes, and/or optionally couple an electron mediator for one or both of the redox cofactors. 34 - 37 . (canceled) 38 . The device of claim 1 , wherein the covalent bond with a carbon atom is a carbon-nitrogen bond. 39 . The device of claim 1 containing no thiol linkages. 40 . The device of claim 1 wherein said interface is molecularly self-assembled. 41 . The device of claim 2 , wherein said modified component provides enzymatic surface coverage of up to about 3.3×10 −11 moles/cm 2 . 42 . The device of claim 25 wherein each of the PEMs has a thickness between about one and about five nanometers. 43 . A method comprising: providing a bioelectronic device comprising: an electrically conductive carbon electrode; and a bioelectronic interface bonded to a surface of the electrically conductive carbon electrode, and configured to regenerate, the bioelectronic interface including a catalytically active material that facilitates electron transfer, the catalytically active material configured to be releasably and electrostatically bound directly or indirectly to the surface via a polyelectrolyte, wherein the polyelectrolyte is configured to be removably and electrostatically bound to a non-thiol ionic linker that is covalently bound to a carbon atom at the surface.