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Advanced nanostructured biosensors enabled by rational surface engineering for bacterial detection
October 2025
中興大學報導
【公關中心】食品微生物感測技術新突破:中興大學開發奈米刷狀結構微生物感測器 - 國立中興大學(National Chung Hsing University)
Breakthrough in Foodborne Microbe Detection: NCHU Develops Nanobrush-Structured Microbial Biosensor
Bacterial contamination poses a persistent challenge to public health, food safety, and environmental monitoring. A research team led by Prof. Shu-Ping Lin from the Graduate Institute of Biomedical Engineering, National Chung Hsing University (NCHU), has developed a nanobrush-structured microbial biosensor capable of rapid and highly sensitive identification of Gram-specific bacteria. The study has been published in the top 3% international journal Biosensors and Bioelectronics (2024 IF: 10.5; CHEMISTRY, ANALYTICAL: Rank 3/111; BIOPHYSICS: Rank 3/77).
This work was conducted in collaboration with Prof. Yu-De Liao from the Department of Electronics and Electrical Engineering, National Yang Ming Chiao Tung University (NYCU), whose team provided a portable electrochemical impedance spectroscopy (EIS) chip that enables field-based measurements outside laboratory settings. Mr. Nitish Kumar, the first author of the study, together with Assoc. Prof. Wei-Yao Hsia from NCHU’s Department of Veterinary Medicine, further validated the biosensor’s effectiveness in detecting Gram-negative bacteria in juice and milk samples, demonstrating its potential for broader applications in food safety and medical diagnostics.
The team engineered a novel nanobrush sensing platform, where the nanobrush density was precisely controlled via semiconductor etching, and its surface was functionalized with boronic acid (BA) to enhance bacterial recognition. This surface-engineered design effectively modulates the interfacial interactions between bacterial membranes and nanostructured electrodes, greatly improving bacterial adhesion and detection sensitivity, enabling accurate detection of trace bacteria in complex environments.
Key sensing characteristics of the Nanobrush-Structured Microbial Biosensor:
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Dynamic range: from 10 to 107 CFU/mL
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Response time: within 9 minutes
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High specificity: markedly higher sensitivity to Gram-negative bacteria (e.g., E. coli) than Gram-positive bacteria (e.g., S. aureus)
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Real-time detection: compatible with portable EIS chip-based readout systems
Prof. Lin emphasized that rational surface nanostructure engineering can significantly optimize the molecular interactions between nanoscale sensors and target microbes, offering a powerful new strategy for microbial biosensing and on-site food testing.
This research stems from the NSTC-funded project “AI-Assisted Real-Time Monitoring and Rapid Diagnostic System for Swine Diseases”, led by Prof. Yu-Chan Chao, and jointly developed by interdisciplinary teams from NCHU, NYCU, and National Cheng Kung University.
The practical applicability of the developed microbial biosensor has been successfully validated in liquid food samples using portable EIS IC measurements, demonstrating its strong potential for rapid Gram-specific bacterial detection and real-world food safety diagnostics.
Paper link: https://doi.org/10.1016/j.bios.2025.118112
PUBLICATION NEWS:
Versatile Dual-Gate 2D Transistor for Logic-in-Memory and Neuromodulation Applications
July 2025
中興大學報導
【公關中心】新世代電子技術:國立中興大學開發雙柵極二維電晶體,整合記憶、邏輯與仿神經元功能—發表於《Small》期刊 - 國立中興大學(National Chung Hsing University)
Next-Generation Electronics: NCHU Develops Dual-Gate 2D Transistor Integrating Memory, Logic, and Brain-Inspired Functions – Published in Small
An international research collaboration between National Chung Hsing University (NCHU), Taiwan, and Brno University of Technology (BUT), Czech Republic, has achieved a breakthrough in electronic device design.
Imagine a single device capable of storing information, performing logic operations, and adapting its behavior—much like neurons in the human brain. Researchers at NCHU have developed such a technology: a versatile dual-gate 2D transistor that integrates memory, logic, and neuromorphic (brain-inspired) functionalities into one compact platform.
This pioneering work, recently published in Small (Impact Factor: 12.1, 2024), highlights how ultra-thin 2D materials can enable smarter, more energy-efficient electronics. The study also reflects the success of NCHU’s collaboration with the Department of Microelectronics at BUT. Adam Šlechta, a recipient of the Visegrad‐Taiwan Scholarship at BUT, worked alongside Advaita Ghosh and Dr. Lester Uy Vinzons in Prof. Shu-Ping Lin’s Lab to realize this unprecedented multifunctional transistor.
Key Features and Innovations
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In-Memory Logic Processing: Executes reconfigurable OR and NOT logic operations directly within the memory unit, with tunable gain for NOT functions. This design reduces energy consumption and minimizes the circuit footprint compared to conventional systems.
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Neuromorphic Behavior with Adaptive Modulation: Mimics brain-like adaptability by responding dynamically to varying signal strengths, durations, and repetitions. The top gate acts as a “modulatory neuron,” enhancing or suppressing responses to simulate higher-level neural control.
Prof. Shu-Ping Lin of NCHU noted, “This device demonstrates the coexistence of memory, logic, and neuromodulation within a single 2D-material platform.” And Prof. Yen-Fu Lin added, “Our next goal is to optimize this design for large-scale integration, enabling applications in artificial intelligence hardware, neuromorphic computing, and beyond.”
With its compact size and multifunctionality, NCHU’s dual-gate 2D transistor represents a major step toward the next generation of electronics—not just faster and smaller, but also smarter, with capabilities reminiscent of biological intelligence.
Read the full article here: https://onlinelibrary.wiley.com/doi/10.1002/smll.202503991
APCOT 2026 & ICSS 2026
APCOT is a biannual conference of the Asia-Pacific scientific community on advanced sensors, actuators, and micro/nano technology. The conference provides a forum for scientists, engineers, and practitioners around the world to present their latest works, exchange ideas, and find new directions. The 12th APCOT will be held in Taichung, Taiwan, which is the second largest city in Taiwan. The city, located in central Taiwan, hosts numerous historic sites, modern attractions, natural sceneries, fine restaurants, and leisure spots. Please visit https://www.apcot2026.org for more information.
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Artificial Merkel discs in van der Waals heterostructures for bio-inspired tactile sensing
Jan 2025
中興大學報導
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