Zhiyu Sheng, Ran Wei, Mengyue Chen, Matthew B Wielgat, Dhanansayan Shanmuganayagam, Edith Tzeng, Xuecang Geng, Xiaoning Jiang, Kang Kim
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引用次数: 0
Abstract
Objective: Characterization of atherosclerosis plaque (AP) is critical for diagnosing rupture-prone AP that directly causes stroke and heart attack, and for guiding in-time interventions and avoiding unnecessary surgeries for stable cases. Ultrasound thermal strain imaging (US-TSI) is known to be capable of characterizing lipids, an important feature of rupture-prone AP. However, before translating US-TSI to in vivo clinical applications, significant technical challenges must be overcome, primarily the requirements of a well-controlled heating strategy to achieve a rapid, safe and spatial-temporal-precise local tissue temperature increase.
Methods: To address these issues, we recently developed a novel US-TSI transducer that integrates dual ultrasound heating arrays that use the thermal effect of the acoustic radiation force, and an ultrasound imaging array to reconstruct the spatial thermal strain map.
Results: This article presents the first comprehensive test results of our new US-TSI transducer including benchtop US-TSI experiments on ultrasound gelatin phantoms with spatial temperature measurements to compare the thermal strain pattern and the corresponding 2-D temperature map, and US-TSI experiments on a pig with temperature measurements to verify the in vivo feasibility and safety further. A clear thermal strain pattern was obtained as a maximum of -0.25% in phantom and -0.08% in vivo, which corresponds with a reasonable temperature increase, 2.5°C in the phantom and 0.9°C in vivo. There was also a high resemblance between the thermal strain pattern and corresponding temperature measurements.
Conclusion: The results demonstrate the effectiveness and safety of performing US-TSI using our new array transducer.
期刊介绍:
Ultrasound in Medicine and Biology is the official journal of the World Federation for Ultrasound in Medicine and Biology. The journal publishes original contributions that demonstrate a novel application of an existing ultrasound technology in clinical diagnostic, interventional and therapeutic applications, new and improved clinical techniques, the physics, engineering and technology of ultrasound in medicine and biology, and the interactions between ultrasound and biological systems, including bioeffects. Papers that simply utilize standard diagnostic ultrasound as a measuring tool will be considered out of scope. Extended critical reviews of subjects of contemporary interest in the field are also published, in addition to occasional editorial articles, clinical and technical notes, book reviews, letters to the editor and a calendar of forthcoming meetings. It is the aim of the journal fully to meet the information and publication requirements of the clinicians, scientists, engineers and other professionals who constitute the biomedical ultrasonic community.
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