成像体模
生物医学工程
材料科学
光热治疗
生物医学中的光声成像
热电偶
传感器
热成像
血管内超声
温度测量
重复性
烧蚀
热烧蚀
图像分辨率
时间分辨率
温度计
医学影像学
基准标记
光声效应
热的
分辨率(逻辑)
远程病人监护
工件(错误)
光声多普勒效应
拉回
放射科
扫描仪
光学
光声层析成像
作者
Dongjian Wu,Qingrong Xia,Kaicheng Yu,Yiming Ma,Haokun Zhang,Riqiang Lin,Yi Shen,X. G. Gong,Puxiang Lai,Mingjian Sun
标识
DOI:10.1002/lpor.202502499
摘要
ABSTRACT Atherosclerosis is a major cause of cardiovascular diseases, and photothermal ablation offers a minimally invasive alternative but is limited by unreliable thermal monitoring. Conventional probes such as thermocouples and fiber‐optic sensors are direct lesion‐contact probes, providing only point or surface measurements with slow response and failing to capture spatial distributions. Meanwhile, current photoacoustic (PA) thermometry relies on bulky arrays and possesses inadequate resolution for small lesions, which is incompatible with catheter applications. Here, this work achieves real‐time intravascular temperature monitoring through photoacoustic endoscopic thermometry with spatially adaptive weighting (PAET‐SAW). Using a miniaturized single‐element transducer with rotational pullback scanning for 3D acquisition, our PAET system enables dual‐modality imaging with real‐time feedback. Phantom and ex vivo validations demonstrate reliable thermometry at 20 Hz with ≤ 0.68°C error and a ∼2 s faster response than thermocouples. Simulated therapeutic experiments further confirm that PAET‐SAW‐guided monitoring reduces excessive thermal dose and suppresses overshoot, underscoring strong clinical potential for precision intravascular interventions.
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