A novel photoluminescent glucose nanosensor was facilely prepared by coupling glucose oxidase(GOx)with poly-L-lysine coated oxygen nanosensors via a glutaraldehyde-mediated Schiff-base reaction.The GOx molecules residing on particle surface catalyzed glucose with the expense of oxygen,which was detected by the sensing particle core incorporated with the reference dye coumarin 6 and oxygen probe Pt(Ⅱ)-meso-tetra(pentafluorophenyl)porphine.The proposed glucose nanosensors(~150 nm in hydrodynamic diameter)had a quick response time varied from less than 2 minute to 4 minute.Glucose calibration was performed with ratiometric photoluminescence and time-resolved fluorescence(TRF)respectively,and a series of calibration plots were constructed according to determination time.In comparison,the ratiometric method resulted in wide dynamic range(e.g.2-10 mM)and high limit of detection(~1-2 mM),while the TRF mode gave narrow dynamic range(e.g.1-6 mM)with low detection limit(~0.1-0.2 mM).Finally the enzymatic glucose nanosensors were tested in human serum samples with a TRF microplate reader.