Micro pillars of copper-nickel alloys were prepared by micro-anode guided electroplating (MAGE) process. The effect of pH value in the Cu-Ni citrate baths ranging from 4.5 to 6.5, and the voltage changing from 4.0 V to 4.6 V was investigated. The reaction mechanism was found to correlate to the pH-dependence of the transformation between the chelates (Cu_2Cit_2_(H-1))^(3-) and (Cu_2Cit_2H_(-2))^(4-). The information from surface morphology observed by SEM, chemical composition analyzed by EDS, and crystal structure analyzed by XRD was useful to delineate the mechanical properties of the micro pillars. The mechanism of MAGE is explored through the cathodic polarization and a simulation of electric field in terms of a commercial software Comsol. The sensing of Cu-Ni alloying pillars to the glucose was potentiostatically studied. The linear range of the current in response to glucose concentration was found to vary depending on the alloy composition. The Ni-enriched alloy takes the advantage of higher sensitive; however, Cu-enriched alloy benefits the test in a wider concentration of glucose. Comparing to the conventional sensor, the Cu-Ni micro pillars demonstrate a superior sensitivity in glucose sense. The excellent sensitivity is ascribed to their nanocrystals which offers higher electrocatalytic area to enhance the charge-transfer in the sensing of glucose.