Jia-Quan Xu

Stretchable Electrochemical Sensor for Real-Time Monitoring of Cells and Tissues

Stretchable electrochemical sensors are conceivably a powerful technique that provides important chemical information to unravel elastic and curvilinear living body. However, no breakthrough was made in stretchable electrochemical device for biological detection. Herein, we synthesized Au nanotubes (NTs) with large aspect ratio to construct an effective stretchable electrochemical sensor. Interlacing network of Au NTs endows the sensor with desirable stability against mechanical deformation, and Au nanostructure provides excellent electrochemical performance and biocompatibility. This allows for the first time, real-time electrochemical monitoring of mechanically sensitive cells on the sensor both in their stretching-free and stretching states as well as sensing of the inner lining of blood vessels. The results demonstrate the great potential of this sensor in electrochemical detection of living body, opening a new window for stretchable electrochemical sensor in biological exploration.

Photocatalytically Renewable Micro‐electrochemical Sensor for Real‐Time Monitoring of Cells

Electrode fouling and passivation is a substantial and inevitable limitation in electrochemical biosensing, and it is a great challenge to efficiently remove the contaminant without changing the surface structure and electrochemical performance. Herein, we propose a versatile and efficient strategy based on photocatalytic cleaning to construct renewable electrochemical sensors for cell analysis. This kind of sensor was fabricated by controllable assembly of reduced graphene oxide (RGO) and TiO2 to form a sandwiching RGO@TiO2 structure, followed by deposition of Au nanoparticles (NPs) onto the RGO shell. The Au NPs-RGO composite shell provides high electrochemical performance. Meanwhile, the encapsulated TiO2 ensures an excellent photocatalytic cleaning property. Application of this renewable microsensor for detection of nitric oxide (NO) release from cells demonstrates the great potential of this strategy in electrode regeneration and biosensing.

Photocatalysis-Induced Renewable Field-Effect Transistor for Protein Detection.

The field-effect transistor (FET) biosensor has attracted extensive attentions, due to its unique features in detecting various biomolecules with high sensitivity and selectivity. However, currently used FET biosensors obtaining from expensive and elaborate micro/nanofabrication are always disposable because the analyte cannot be efficiently removed after detection. In this work, we established a photocatalysis-induced renewable graphene-FET (G-FET) biosensor for protein detection, by layer-to-layer assembling reduced graphene oxide (RGO) and RGO-encapsulated TiO2 composites to form a sandwiching RGO@TiO2 structure on a prefabricated FET sensor surface. After immobilization of anti-D-Dimer on the graphene surface, sensitive detection of D-Dimer was achieved with the detection limits of 10 pg/mL in PBS and 100 pg/mL in serum, respectively. Notably, renewal of the FET biosensor for recycling measurements was significantly realized by photocatalytically cleaning the substances on the graphene surface. This work demonstrates for the first time the development and application of photocatalytically renewable G-FET biosensor, paving a new way for G-FET sensor toward a plethora of diverse applications.

Degradable Zinc-Phosphate-Based Hierarchical Nanosubstrates for Capture and Release of Circulating Tumor Cells

Circulating tumor cells (CTCs) play a significant role in cancer diagnosis and personalized therapy, and it is still a significant challenge to efficiently capture and gently release CTCs from clinical samples for downstream manipulation and molecular analysis. Many CTC devices incorporating various nanostructures have been developed for CTC isolation with sufficient capture efficiency, however, fabricating such nanostructured substrates often requires elaborate design and complicated procedures. Here we fabricate a degradable zinc-phosphate-based hierarchical nanosubstrate (HZnPNS), and we demonstrate its excellent CTC-capture performance along with effective cell-release capability for downstream molecular analysis. This transparent hierarchical architecture prepared by a low-temperature hydrothermal method, enables substantially enhanced capture efficiency and convenient imaging. Biocompatible sodium citrate could rapidly dissolve the architecture at room temperature, allowing that 88 ± 4% of captured cells are gently released with a high viability of 92 ± 1%. Furthermore, antiepithelial cell adhesion molecule antibody functionalized HZnPNS (anti-EpCAM/HZnPNS) was successfully applied to isolate CTCs from whole blood samples of cancer patients, as well as release CTCs for global DNA methylation analysis, indicating it will serve as a simple and reliable alternative platform for CTC detection.

Conductive Polymer-Coated Carbon Nanotubes To Construct Stretchable and Transparent Electrochemical Sensors

Carbon nanotube (CNT)-based flexible sensors have been intensively developed for physical sensing. However, great challenges remain in fabricating stretchable CNT films with high electrochemical performance for real-time chemical sensing, due to large sheet resistance of CNT film and further resistance increase caused by separation between each CNT during stretching. Herein, we develop a facile and versatile strategy to construct single-walled carbon nanotubes (SWNTs)-based stretchable and transparent electrochemical sensors, by coating and binding each SWNT with conductive polymer. As a polymer with high conductivity, good electrochemical activity, and biocompatibility, poly(3,4-ethylenedioxythiophene) (PEDOT) acting as a superior conductive coating and binder reduces contact resistance and greatly improves the electrochemical performance of SWNTs film. Furthermore, PEDOT protects the SWNTs junctions from separation during stretching, which endows the sensor with highly mechanical compliance and excellent electrochemical performance during big deformation. These unique features allow real-time monitoring of biochemical signals from mechanically stretched cells. This work represents an important step toward construction of a high performance CNTs-based stretchable electrochemical sensor, therefore broadening the way for stretchable sensors in a diversity of biomedical applications.

Photochemical Synthesis of Shape-Controlled Nanostructured Gold on Zinc Oxide Nanorods as Photocatalytically Renewable Sensors.

Biosensors always suffer from passivation that prevents their reutilization. To address this issue, photocatalytically renewable sensors composed of semiconductor photocatalysts and sensing materials have emerged recently. In this work, we developed a robust and versatile method to construct different kinds of renewable biosensors consisting of ZnO nanorods and nanostructured Au. Via a facile and efficient photochemical reduction, various nanostructured Au was obtained successfully on ZnO nanorods. As-prepared sensors concurrently possess excellent sensing capability and desirable photocatalytic cleaning performance. Experimental results demonstrate that dendritic Au/ZnO composite has the strongest surface-enhanced Raman scattering (SERS) enhancement, and dense Au nanoparticles (NPs)/ZnO composite has the highest electrochemical activity, which was successfully used for electrochemical detection of NO release from cells. Furthermore, both of the SERS and electrochemical sensors can be regenerated efficiently for renewable applications via photodegrading adsorbed probe molecules and biomolecules. Our strategy provides an efficient and versatile method to construct various kinds of highly sensitive renewable sensors and might expand the application of the photocatalytically renewable sensor in the biosensing area.

Stretchable and Photocatalytically Renewable Electrochemical Sensor Based on Sandwich Nanonetworks for Real-Time Monitoring of Cells

Stretchable electrochemical (EC) sensors have broad prospects in real-time monitoring of living cells and tissues owing to their excellent elasticity and deformability. However, the redox reaction products and cell secretions are easily adsorbed on the electrode, resulting in sensor fouling and passivation. Herein, we developed a stretchable and photocatalytically renewable EC sensor based on Au nanotubes (NTs) and TiO2 nanowires (NWs) sandwich nanonetworks. The external Au NTs are used for EC sensing, and internal TiO2 NWs provide photocatalytic performance to degrade contaminants, which endows the sensor with excellent EC performance, high photocatalytic activity, and favorable mechanical tensile property. This allows highly sensitive recycling monitoring of NO released from endothelial cells and 5-HT released from mast cells under their stretching states in real time, therefore providing a promising tool to unravel elastic and mechanically sensitive cells, tissues, and organs.