Two parallel enzymatic oxygen-consumed reaction including oxidation of hypoxanthine by xanthine oxidase (EC 1.17.3.2) and oxidation of catechol by tyrosinase (EC 1.14.18.1) were utilized to constructed novel allopurinol biosensor. In this project, the concentration increase of allopurinol (inhibitor) would inhibit the activity of enzymatic oxygen-consumption by xanthine oxidase. Subsequently, tyrosinase could divvy more oxygen to produce catechol quinone, and it could be observed that more current response was recorded from electrochemical reduction of catechol quinone at 0.0V (vs. Ag/AgCl). In contrast to the determination of traditional inhibition type which the signal was inverse proportional to the concentration of inhibitor, the signal is proportional to the concentration of allopurinol. Moreover, in this biosensor, the monolayer of enzyme modifier and 0.0V detection potential were adapted to obtains fast response (t90%-10% = 2.9 second) and efficiently avoids common interference of substances that co-exist in serum. This allopurinol biosensor possesses linear range 5μM－100μM (R=0.998) that satisfy with therapeutic range (5-15mg/L), sensitivity is 8.79 nA/μM, detection limit is 1.4μM, the relative standard deviation (RSD) is 4.2%. Allopurinol was used to primary treatment of hyperuricemia and its complication. However, it potentially causes serious hypersensitivity such as Stevens–Johnson syndrome (SJS) and toxic epidermal necrolysis (TENS) on several patients after allopurinol treating. Therefore, the determination of allopurinol is important and necessary for clinical monitoring and quality assurance of pharmacy.