| Literature DB >> 30605244 |
Quanchang Jin1, Hui-Jiuan Chen1, Xiangling Li1, Xinshuo Huang1, Qianni Wu1, Gen He1, Tian Hang1, Chengduan Yang1, Zhen Jiang1, Enlai Li1, Aihua Zhang1, Zhihong Lin1, Fanmao Liu1, Xi Xie1.
Abstract
A variety of nanomaterial-based biosensors have been developed to sensitively detect biomolecules in vitro, yet limited success has been achieved in real-time sensing in vivo. The application of microneedles (MN) may offer a solution for painless and minimally-invasive transdermal biosensing. However, integration of nanostructural materials on microneedle surface as transdermal electrodes remains challenging in applications. Here, a transdermal H2 O2 electrochemical biosensor based on MNs integrated with nanohybrid consisting of reduced graphene oxide and Pt nanoparticles (Pt/rGO) is developed. The Pt/rGO significantly improves the detection sensitivity of the MN electrode, while the MNs are utilized as a painless transdermal tool to access the in vivo environment. The Pt/rGO nanostructures are protected by a water-soluble polymer layer to avoid mechanical destruction during the MN skin insertion process. The polymer layer can readily be dissolved by the interstitial fluid and exposes the Pt/rGO on MNs for biosensing in vivo. The applications of the Pt/rGO-integrated MNs for in situ and real-time sensing of H2 O2 in vivo are demonstrated both on pigskin and living mice. This work offers a unique real-time transdermal biosensing system, which is a promising tool for sensing in vivo with high sensitivity but in a minimally-invasive manner.Entities:
Keywords: microneedle sensors; mini-invasive and painless; nanohybrid electrodes; real-time biosensors; transdermal electrodes
Mesh:
Substances:
Year: 2019 PMID: 30605244 DOI: 10.1002/smll.201804298
Source DB: PubMed Journal: Small ISSN: 1613-6810 Impact factor: 15.153