An in vitro biochemical fuel cell based upon the enzymatically catalyzed aerobic oxidation of glucose is described. The anodic half-reaction employs an electron transfer sequence consisting of the glucose oxidase reductive half-reaction and dichloroindophenol. The cathodic half-reaction involves reduction of molecular oxygen. A high Faradic efficiency for the intact cell approaching 100% has been experimentally demonstrated. The steady state current is exponentially related to the concentration of the terminal electron transfer species in the anodic chamber. The behavior is consistent with application of the Nernst relationship to define the cell potential and a simple resistance circuit. The discharge profile of the cell after complete oxidation of the primary fuel, glucose, can be modeled as a capacitor discharging through a resistor.