We report a novel plastic biochip for the sensitive colorimetric detection of analytes of interest. This type of biochip is designed to perform bioassays in a sandwich format, i.e., employing the immobilized probe molecules to capture target and then utilizing gold nanoparticle (AuNP)-labeled reporters to screen the biorecognition events. To fabricate and implement such plastic biochips, not only have we demonstrated the probe immobilization, sensor unit formation, signal transduction and visualization on the plastic substrate, but we have also introduced new methods for imaging and analysis of them. As two proof-of-concept detection applications, plastic immunochips and DNA biochips have been fabricated and their responses to human IgG and DNA have been examined respectively. To further assess the detection sensitivity of the colorimetric-based biochip, we have compared it with an enzyme-catalyzed-based biochip and with a conventional fluorescent-based biochip. We believe the colorimetric-based plastic biochip presented herein is able to fully combine the advantage of colorimetric detection and plastic substrate, thus making it an ideal platform for point-of-care analysis and diagnostics.
Direct ink writing (DIW) of energetic materials has been an area of interest for micro size charge. In this work, 3, 4‐dinitrofurazanofuroxan (DNTF) based composite was prepared with nitrocotton (NC) and Viton as binders by DIW. Scanning Electro Microscope (SEM) and X‐ray diffraction were employed to characterize the composite samples. The impact sensitivity and thermal decomposition of the composites were also tested and analyzed. In addition, the critical size of detonation and detonation velocity were measured. The results show that DNTF based composite has a high density with whose value is 1.785 g cm−3, reaching 93.16 % of theoretical maximum density (TMD). The particles in composites are spheroidal with size ranging from 1 to 2 μm. Compared with raw DNTF, the obtained composite has a lower impact sensitivity and higher thermal stability. Moreover, the composites exhibit excellent detonation properties, whose critical size of detonation is around 0.01 mm and the mean detonation velocity is 8580 m s−1 at the charging width of 1 mm. Furthermore, part performances of this composite are contrasted with previous reported CL‐20 based composite and show better characters.
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