A Whole-Cell Surface Plasmon Resonance Sensor Based on a Leucine Auxotroph of Escherichia coli Displaying a Gold-Binding Protein: Usefulness for Diagnosis of Maple Syrup Urine Disease

Monitoring Metabolites Using an NAD(P)H-sensitive Polymer Dot and a Metabolite-Specific Enzyme

We introduce an NAD(P)H-sensitive polymer dot (Pdot) biosensor for point-of-care monitoring of metabolites. The Pdot is combined with a metabolite-specific NAD(P)H-dependent enzyme that catalyzes the oxidation of the metabolite, generating NAD(P)H. Upon UV illumination, the NAD(P)H quenches the fluorescence emission of Pdot at 627 nm via electron transfer, and also fluoresces at 458 nm, resulting in a shift from red to blue emission at higher NAD(P)H concentrations. Metabolite concentration is quantified ratiometrically-based on the ratio of blue-to-red channel emission intensities, with a digital camera-with high sensitivity and specificity. We demonstrate phenylalanine biosensing in human plasma for a phenylketonuria screening test, quantifying several other disease-related metabolites (lactate, glucose, glutamate, and β-hydroxybutyrate), and a paper-based assay with smartphore imaging for point-of-care use.

Detection of Phenylketonuria Markers Using a ZIF-67 Encapsulated PtPd Alloy Nanoparticle (PtPd@ZIF-67)-Based Disposable Electrochemical Microsensor

Phenylketonuria (PKU) is a common disease in congenital disorder of amino acid metabolism, which can lead to intellectual disability, seizures, behavioral problems, and mental disorders. We report herein a facile method to screen for PKU by the measurements of its metabolites (markers). In this work, a disposable electrochemical microsensor modified with a ZIF (zeolitic imidazolate framework)-based nanocomposite is constructed, in which ZIF-67 crystals are encapsulated with PtPd alloy nanoparticles (NPs) forming the nanocomposite (PtPd@ZIF-67). According to electrochemical measurements, the PtPd@ZIF-67-modified microsensor shows good responses and selectivity to phenylpyruvic acid and phenylacetic acid, while almost no response toward other amino acid analogues is observed. Here, a new sensing mechanism based on the acylation reaction between the imidazole linker in ZIF-67 and carboxyl in PKU markers has been proposed and verified through the Fourier-transform infrared spectroscopy study. Moreover, the encapsulated PtPd NPs elevate the electron transfer capability of the PtPd@ZIF-67-modified microsensor and further improve the electrochemical sensing performance. Finally, we demonstrate that the developed PtPd@ZIF-67-modified microsensor has the possibility to sensing of PKU markers with high response and good specificity and may be extended to exploit the point-of-care rapid PKU screening.