Electrochemical Detection of Tyrosinase in Cell Lysates at Functionalized Nanochannels via Amplifying of Ionic Current Response

Tyrosinase is an important enzyme in the metabolism of melanin and catecholamine, as well as an important antigen in autoimmunity of vitiligo. However, it is still a challenge to develop a selective and sensitive sensing approach for monitoring of tyrosinase in cell environment. In this work, a sensing strategy based on ion current rectification induced by nanochannels was established to electrochemically detect inactive tyrosinase. Functionalized alumina nanochannels were decorated by tyramine as an electrochemical platform to selectively determine tyrosinase via chemically specific reaction between phenolic hydroxyl groups of tyramine and tyrosinase. On the other hand, Fe²⁺ was further bonded with dihydroxyl groups generated by tyrosinase in nanochannels to amplify charge changes, resulting in the enhancement on the detection sensitivity for tyrosinase. Based on this principle, the developed electrochemical sensor showed a good linearity towards tyrosinase from 2 to 50 U/mL with a detection limit down to 0.83 U/mL, which can fulfil the requirement for detection of tyrosinase in cells. Eventually, the present electrochemical sensor was successfully employed in the selective and sensitive determination of tyrosinase in cell lysates. The results suggested that the activity of tyrosinase in B16 cells was 1.7-fold higher than that of Hela cells.