To enhance the performance of sensors for biomedical applications, various kinds of advanced micro-nanomaterials, and micro-nanostructures including nanoscale probes have been utilized as the basis for sensors for the past decades. These sensors have been widely used for disease biomarker detection including both protein and nucleic acid biomarkers, single molecule detection, volatile organic compounds (VOCs) sensing, neural sensing, pressure sensing such as intraocular pressure monitoring, and skin sensing. In this Special issue, we focus on chemical and biochemical sensing and analyses using various types of the sensors, which are enabled by arrayed nanopores, cantilever-type nanoprobes, microelectrode arrays, and carbon nanotubes decorated with gold nanoparticles, respectively.

The Research Topic of Frontiers in Nanotechnology entitled “Advanced nanomaterials and nanostructures-based sensors for biomedical applications” presents a total of four papers (Figure 1), including two reviews and two original research papers. The review by Feng and Ji summarizes the progress of one nanomaterial self-ordered nanoporous structure anodic aluminum oxide (AAO) and its applications (Feng and Ji). This review is primarily focused on four types of AAO-based optical biosensing technologies: surface-enhanced Raman scattering, surface plasmon resonance, reflectometric interference spectroscopy, and photoluminescence spectroscopy. The review by Anwesha Sarkar summarizes the principle and some main applications of atomic force microscopy (AFM), specifically showcasing the nanoscale probes and chemically modified nanoscale probes of AFM as biosensors, to characterize other sensors, to improve drug delivery approaches, and to discuss future possibilities (Sarkar). The original research paper by Yamin Li et al. reports a wireless closed-loop system for epilepsy detection and suppression (Li et al.). This system consists of an implantable optrode, wireless recording, wireless energy supply, and a control module. The optrode is a microstructure formed by integrating a silicon microelectrode array (MEA) with an LED probe. The functions of the system have been demonstrated through animal experiments, including local field potential (LFP) real-time monitoring, seizure detection, wireless energy supply, light to release RuBi-GABA, and inhibiting seizures, indicating its potential as a practical wireless epilepsy therapy system. The original research by Noushin et al. reports a wearable wound patch for multiplexed monitoring wound biomarkers at the wound site, thereby providing real-time feedback on the inflammation phase of the wound (Noushin et al.) The sensing patch was fabricated utilizing an optimal composition of gold nanoparticles integrated multiwalled carbon nanotubes. In addition, a miniaturized Internet-of-things (IoT)-enabled potentiostat was developed and integrated with the patch, forming a wearable system, resulting in a solution to wound care through continuous, real-time, and in-situ monitoring of multiple wound biomarkers.

We hope the papers in this topic would trigger some new ideas using micro-nanomaterials and micro-nanostructures for next generation biomedical sensing technical platforms. We also would like to thank all authors of the papers published in this topic. The careful and timely reviews by reviewers for ensuring the quality of this research topic are also greatly appreciated.