Herein,
a hand-drawing paper-based bipolar electrode (BPE) electrochemiluminescence
(ECL) platform for M.SssI methyltransferase (M.SssI MTase) assay was
proposed via employing high electrocatalytic Pt@CeO2 as
an ECL co-reaction accelerator and pencil-drawing graphite electric
circuits as wires and electrodes. Notably, the introduction of pencil-drawing
trace not only simplified the manufacturing process but also reduced
the cost and saved fabricating time. Meanwhile, Pt@CeO2 with good electrocatalytic activity and satisfactory chemical stability
was used at the anode of the closed BPE-ECL device to accelerate the
oxidation rate of uric acid. Due to the balanced charges of the bipolar
electrode, the ECL response of the MnS: CdS@ZnS/S2O82– system emitted on the cathode was enhanced.
In situ growth of gold nanoparticles in the two electrode areas was
convenient for DNA immobilization. With the above points in mind,
the specific DNA double strands functionalized via Pt@CeO2 were employed to identify M.SssI MTase. The unmethylated DNA double
strands were cut by HpaII endonuclease, resulting
in the quenching of the ECL signal. Under the optimal conditions,
sensitive detection of M.SssI MTase in a wide linear range of 0.01–100
U·mL–1 with a satisfactory detection limit
of 0.008 U·mL–1 was realized. The reliable
and versatile BPE-ECL tool for the determination of M.SssI MTase with
easy-to-operate pencil-drawing traces and independent solution systems
provides a new opportunity to develop paper-based devices applied
in early disease diagnosis and pathogenesis research.