On-line microfluidic sensor integrated with a micro array electrode and enzyme-modified pre-reactor for the real-time monitoring of blood catecholamine

Abstract We developed an on-line microfluidic sensing device with an interdigitated array (IDA) electrode and a micro pre-reactor for the real-time monitoring of blood catecholamine (CA) and succeeded in the highly sensitive detection of dopamine (DA) in the presence of L-ascorbic acid (AA). Our device exhibits the lowest detection limit (110 ± 10 pM (S/N=3)), of reported catecholamine sensors. The improvement in sensitivity results from the high redox cycling of DA and the increase in the mass transfer rate per unit time onto the IDA electrode achieved by the flow measurement. The pre-reactor was integrated upstream in the micro flow channel to eliminate AA. A large number of rectangular shaped micropillars, which were modified with ascorbate oxidase, were formed in the pre-reactor to increase the surface area. The flow was disturbed by the two dimensional micropillar arrangement. This structure enables us to increase the elimination efficiency for AA. As a result, we achieved both the continuous and highly selective detection of 1 nM DA with complete elimination of 10 μM AA in the sample solution without employing any selective membrane such as Nafion, whose use reduces sensitivity due to the low diffusion coefficient of DA inside the membrane.