Enzyme-like nanocatalytic reactions developed for high signal amplification in biosensors are of limited use because of their low reaction rates and/or unwanted side reactions in aqueous electrolyte solutions containing dissolved O. Herein, we report a nitrosoreductase-like catalytic reaction, employing 4-nitroso-1-naphthol, Pd nanoparticles, and HN-BH, which affords a high reaction rate and minimal side reactions, enabling its use in ultrasensitive electrochemical biosensors. 4-Nitroso-1-naphthol was chosen after five hydroxy-nitro(so)arene compounds were compared in terms of high signal and low background levels. Importantly, the nanocatalytic reaction occurs without the self-hydrolysis and induction period observed in the nanocatalytic reduction of nitroarenes by NaBH. The high signal level results from (i) fast nanocatalytic 4-nitroso-1-naphthol reduction, (ii) fast electrochemical redox cycling, and (iii) the low influence of dissolved O. The low background level results from (i) slow direct reaction between 4-nitroso-1-naphthol and HN-BH, (ii) slow electrode-mediated reaction between 4-nitroso-1-naphthol and HN-BH, and (iii) slow electrooxidation of HN-BH at electrode. When applied to the detection of parathyroid hormone, the detection limit of the newly developed biosensor was ∼0.3 pg/mL. The nitrosoreductase-like nanocatalytic reaction is highly promising for ultrasensitive and stable biosensing.
Simple and sensitive competitive immunosensors for small molecules are difficult to obtain, especially in serum containing numerous interfering species (ISs) with different concentrations. Herein, we report a washing-free and sensitive (competitive) displacement immunosensor for cortisol in human serum, based on electron mediation of Os(bpy)Cl between an electrode and a redox label [oxygen-insensitive diaphorase (DI)] (i.e., electrochemical-enzymatic redox cycling). The anticortisol IgG-DI conjugate bound to a cortisol-immobilized electrode is displaced by competitive binding of cortisol in serum and diffuses away from the electrode during incubation; therefore, the concentration of the displaced conjugate near the electrode becomes very low, even without washing. Electrochemically interfering ascorbic acid is converted to a redox-inactive species by ascorbate oxidase during incubation. The remaining bound conjugate mainly contributes to electrochemical currents. Compared with ferrocene methanol, Fe(CN), and Ru(NH), the electrochemical and redox cycling behaviors of Os(bpy)Cl are influenced significantly less by ISs in serum. Comparative studies reveal that washing-free displacement assay shows better cortisol-induced signal change than three other assays. The surface concentration of cortisol immobilized on the electrode is optimized, because the electrochemical signal is highly dependent on the surface concentration. When the washing-free displacement immunosensor is applied for the detection of cortisol in artificial serum, cortisol is measured with a detection limit of ∼30 pM within 12 min. The cortisol concentrations measured in clinical serum samples agree well with those obtained using a commercial instrument. The new immunosensor is highly promising for the simple, sensitive, and rapid point-of-care detection of small molecules.
Conventional sandwich immunosensors rely on antibody
recognition
layers to selectively capture and detect target antigen analytes.
However, the fabrication of these traditional affinity sensors is
typically associated with lengthy and multistep surface modifications
of electrodes and faces the challenge of nonspecific adsorption from
complex sample matrices. Here, we report on a unique design of bioelectronic
affinity sensors by using natural cell membranes as recognition layers
for protein detection and prevention of biofouling. Specifically,
we employ the human macrophage (MΦ) membrane together with the
human red blood cell (RBC) membrane to coat electrochemical transducers
through a one-step process. The natural protein receptors on the MΦ
membrane are used to capture target antigens, while the RBC membrane
effectively prevents nonspecific surface binding. In an attempt to
detect tumor necrosis factor alpha (TNF-α) cytokine using the
bioelectronic affinity sensor, it demonstrates a remarkable limit
of detection of 150 pM. This new sensor design integrates natural
cell membranes and electronic transduction, which offers synergistic
functionalities toward a broad range of biosensing applications.
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