Extended-gate field-effect transistor packed in micro channel for glucose, urea and protein biomarker detection.

This study developed a packaging method to integrate the extended-gate field-effect transistor (EGFET) into a microfluidic chip as a biological sensor. In addition, we present two immobilization approaches for the bio-recognition that are appropriate to this chip, allowing it to measure the concentrations of hydrogen ions, glucose, urea, and specific proteins in a solution. Alginate-calcium microcubes were used to embed the enzymes and magnetic powder (enzyme carrier).

A CMOS cantilever-based label-free DNA SoC with improved sensitivity for hepatitis B virus detection.

This paper presents a highly-integrated DNA detection SoC, where several kinds of cantilever DNA sensors, a readout circuit, an MCU, voltage regulators, and a wireless transceiver, are integrated monolithically in a 0.35 μm CMOS Bio-MEMS process. The cantilever-based biosensors with embedded piezoresistors aim to transduce DNA hybridization into resistance variation without cumbersome labeling process.

Optical sensing of urinary melatonin with molecularly imprinted poly(ethylene-co-vinyl alcohol) coated zinc oxide nanorod arrays.

In this work, aligned zinc oxide (ZnO) nanorods were selectively hydrothermally grown on acetate-seeded spots on a gold substrate; the nanorods had an average length and diameter of 1.7μm and 240nm, respectively. Melatonin was imprinted into poly(ethylene-co-vinyl alcohol), EVAL, which was coated onto ZnO nanorod arrays.

A micro-cantilever sensor chip based on contact angle analysis for a label-free troponin I immunoassay.

Cantilever sensors have been extensively explored as a promising technique for real-time and label-free analyses in biological systems. A major sensing principle utilized by state-of-the-art cantilever sensors is based on analyte-induced surface stress changes, which result in static bending of a cantilever. The sensor performance, however, suffers from the intrinsically small change in surface stress induced by analytes, especially for molecular recognition such as antigen-antibody binding.