Antimicrobial wound care dressing

What is claimed is: 1. A method of treating a bacterial infection in a wound, the method comprising: applying an antimicrobial dressing to the wound, said antimicrobial dressing comprising: a substrate; at least one pair of electrodes positioned on or within the substrate, wherein the at least pair of electrodes comprise a conductive anode configured to be in contact with at least a first portion of the wound and a conductive cathode configured to be in contact with at least a second portion of the wound; and a plurality of electrodes in a spaced pattern on the substrate, wherein at least a portion of the plurality of electrodes in the spaced pattern are configured to be in contact with the wound; inducing, by an energy source configured to be connected to the at least one pair of electrodes, an electrical current to flow from the conductive anode, through the wound, to the conductive cathode, wherein the energy source configured to be connected to the at least one pair of electrodes comprises the portion of the plurality of electrodes in the spaced pattern on the substrate that are configured to be in contact with the wound, a first subset of the plurality of electrodes connected in electrical series with the anode and a second set of the plurality of electrodes connected in electrical series with the cathode, and the plurality of electrodes are comprised of a biocompatible reduction/oxidation reaction material such that a voltage differential is created between the anode and the cathode, wherein said voltage differential causes the electrical current to flow from the conductive anode, through the wound, to the conductive cathode; and applying a therapeutically effective amount of an electric current to the wound from the antimicrobial dressing. 2. The method of claim 1 , wherein the electrical current flowing through the wound inhibits formation of a biofilm within the wound, at least partially disrupts a biofilm growing within the wound, at least partially destroys sessile bacteria within the wound, and/or at least partially destroys planktonic bacteria within the wound or disrupts bacterial growth in the wound or inhibits or disrupts biofilm in the wound. 3. The method of claim 2 , wherein the biofilm comprises sessile bacteria that are resistant to antibiotics. 4. A method of assembling an antimicrobial dressing, comprising: applying a layer of conductive material to an insulated base substrate to form at least one electrode pair on the insulated base substrate, wherein the electrode pair comprise a conductive anode and a conductive cathode that are electrically insulated from one another, connecting an energy source to the at least one electrode pair, wherein the energy source induces an electrical current to flow from the conductive anode, through a wound, to the conductive cathode; and forming a plurality of electrodes in a spaced pattern on the substrate, wherein at least a portion of the plurality of electrodes in the spaced pattern are configured to be in contact with the wound, and wherein the energy source connected to the at least one electrode pair comprises the portion of the plurality of electrodes in a spaced pattern on the substrate that are configured to be in contact with the wound, a first subset of the plurality of electrodes connected in electrical series with the anode and a second set of the plurality of electrodes connected in electrical series with the cathode, and the plurality of electrodes are comprised of a biocompatible reduction/oxidation reaction material such that a voltage differential is created between the anode and the cathode, wherein said voltage differential causes the electrical current to flow from the conductive anode, through the wound, to the conductive cathode. 5. The method of claim 4 , wherein applying the layer of conductive material to the insulated base substrate to form the at least one electrode pair on the insulated base substrate comprises printing the conductive anode and the conductive cathode on the substrate using screen-printing techniques or printing the conductive anode and the conductive cathode on the insulated base substrate using a printer. 6. The method of claim 4 , wherein applying the layer of conductive material to the insulated base substrate to form the at least one electrode pair on the insulated base substrate comprises weaving the conductive anode and the conductive cathode into the insulated base substrate.