Miniaturized Biosensors Open New Possibilities for Minimally Invasive Implants
By HospiMedica International staff writers Posted on 23 Nov 2022 |
Diagnosing and monitoring diseases often rely on the detection of molecules called “biomarkers”. However, the detection of such biomarkers need periodic blood draws, which are expensive, time consuming, require specialized equipment, and provide no continuous data. To avoid this, and provide real-time biomarker detection, a team of researchers has pioneered the development of implantable aptamer-based sensors. These devices are electrochemical sensors based on DNA and they successfully track small molecules in real time. The new method for the miniaturization of biosensors will enable new possibilities for minimally invasive implants. The miniaturized transistors are fabricated on thin, flexible substrates, and amplify biosignals, producing currents more than 200 times larger than analogous alternatives.
A key step to translate these sensors to real-life applications in the clinic is to make them as small and minimally invasive as possible. To solve this miniaturization challenge, researchers at University of Cambridge (Cambridge, UK) teamed up with the Plaxco Lab at the University of California Santa Barbara (Santa Barbara, CA, USA) to discover a way to combine aptamer-based sensors with an amplifying transistor platform. Together, they developed biosensors based on organic electrochemical transistors (OECTs), which maintain high performances of the aptamer sensors even when shrunk to quite small dimensions.
Previous aptamer sensors were made of thin, millimeters-long wires. In contrast, the new transistor biosensors are so small that they are barely visible to the naked eye. This technology will be useful for medical applications that require sensors in delicate areas. For example, such a minimally invasive sensor could enable implantation in the brain – an ideal region to track biomarkers linked with mental disorders, such as depression. The cross-disciplinary research team will now explore possible next directions of this work. For example, another benefit of signal amplification is improved lifetime, so the sensor can operate for longer without being replaced. Each of these improvements is one step closer to deployment in humans for tracking anything from drugs to hormones to neurotransmitters.
“This work is an important step towards creating better tools for healthcare providers. With this type of sensor, physicians will be able to gain unprecedented real-time data for tracking their patients’ health,” said Sophia Bidinger, research student and lead author of the paper.
“The most exciting aspect of this work is that it could be used to detect virtually any small molecule. This will help doctors gain much more patient specific insight than ever before,” added paper co-author Professor George Malliaras.
“There is a huge market opportunity for continuous molecular monitoring. Besides glucose, there are not very many commercially available sensors. More tools for supporting continuous, in vivo sensing will save lives,” stated paper co-author Professor Tawfique Hasan.
Related Links:
University of Cambridge
University of California Santa Barbara
Latest Surgical Techniques News
- Flexible Microdisplay Visualizes Brain Activity in Real-Time To Guide Neurosurgeons
- Next-Gen Computer Assisted Vacuum Thrombectomy Technology Rapidly Removes Blood Clots
- Hydrogel-Based Miniaturized Electric Generators to Power Biomedical Devices
- Custom 3D-Printed Orthopedic Implants Transform Joint Replacement Surgery
- Wearable Technology Monitors and Analyzes Surgeons' Posture during Long Surgical Procedures
- Cutting-Edge Imaging Platform Detects Residual Breast Cancer Missed During Lumpectomy Surgery
- Computational Models Predict Heart Valve Leakage in Children
- Breakthrough Device Enables Clear and Real-Time Visual Guidance for Effective Cardiovascular Interventions
- World’s First Microscopic Probe to Revolutionize Early Cancer Diagnosis
- World’s Smallest Implantable Brain Stimulator Demonstrated in Human Patient
- Robotically Assisted Lung Transplants Could Soon Become a Reality
- AI to Provide Heart Transplant Surgeons with New Decision-Making Data
- New Surgical Tool Empowers Precision and Confidence in Operating Room
- Future Muscle-Powered Surgical Robots Could Perform Minimally Invasive Procedures inside Body
- Non-Invasive Technique Combines Cardiac CT with AI-Powered Blood Flow for Heart Bypass Surgery
- First-Of-Its-Kind Device Repairs Leaky Tricuspid Heart Valve