材料科学
微尺度化学
透明度(行为)
触诊
热电效应
热电偶
碲
微观结构
光电子学
硅酮
光学透明度
纳米技术
热的
生物医学工程
电介质
计算机科学
触觉传感器
粘弹性
透射率
热电冷却
内窥镜检查
热电材料
复合材料
生物组织
单晶
机械工程
热电发电机
临床实习
医疗器械
作者
Shaowei Cui,Site Li,Zi-Xin Huang,Yanzhe Yu,Mingxue Cai,Xiangyin Bao,C. Zhang,T. S. Zhang,Lei Cheng,Wenxuan Zhang,Zheng Lou,S. -G. Wang,Wen Gong,Chao-Feng Wu,Lili Wang,Yu Wang
标识
DOI:10.1038/s41467-026-68317-3
摘要
Tactile endoscopes can provide physicians with rich sensory information, enabling fast and accurate medical diagnoses. However, existing tactile endoscopy sensors do not consider temperature perception, which is a very important diagnostic indicator in medicine. Here, we report for the first time a tellurium-based superelastic thermoelectric visual-tactile sensor. This platform achieves a breakthrough by combining tellurium thermocouples designed based on crystal structures with viscoelastic silicone encapsulation, enabling simultaneous microscale visual, thermal, and force measurements in a single device. By employing a morphologically optimized tellurium-polymer heterointerface and advanced deep neural network algorithms, we address the inherent trade-off between transparency and responsiveness, achieving artifact-free imaging, real-time thermal mapping, and microstructure force feedback. We conduct clinical endoscopic palpation experiments on live rabbits and successfully achieve tactile diagnosis of inflamed tissue including temperature distribution, especially in cases where visual distinction is difficult, pointing out possible development directions for intelligent endoscopy systems.
科研通智能强力驱动
Strongly Powered by AbleSci AI