Y. Iseki, Keito Nakamura, Daisuke Anan, Kazuo Kato
{"title":"Ultrasound-Guided Resonant Cavity Applicator系统:- Non-invasive Measurement of Temperature Distributions -@@@-利用超声波影像诊断设备的无创温度测量-","authors":"Y. Iseki, Keito Nakamura, Daisuke Anan, Kazuo Kato","doi":"10.3191/THERMALMED.31.13","DOIUrl":null,"url":null,"abstract":":This paper describes the ultrasound-guided resonant cavity applicator system which has a function for measuring temperature distributions non-invasively. We had already proposed the resonant cavity applicator for non-invasive hyperthermia treatments. In this heating system,it was shown that the applicator could heat deep seated tumor without undesirable hotspots. In addition,the resonant cavity applicator could control the heated area inside tumors corresponding to the symptom of the patients. In the clinic,a real time monitoring system to acquire the targeted area and temperature distributions inside human body is necessary for effective hyperthermia treatments. In this paper, we proposed the ultrasound-guided resonant cavity applicator system which has a possibility of measuring temperature distributions inside human body. The method of measuring temperature distributions was based on the thermal dependence of local change in speed of sound and thermal expansion. Here,we described the method to estimate temperature distributions inside the agar phantom heated by the developed ultrasound-guided resonant cavity applicator. First, we tried to heat the agar phantom inside a hot water bath to discuss the relationship between temperature rises and changes of the ultrasound images. Next, we measured temperature distributions inside the agar phantom heated by the resonant cavity applicator using a diagnostic ultrasound imaging system. Also,we discussed the results of the measured temperature distributions inside the agar phantom for controlling the heated area. From our heating experiments,it was confirmed that the proposed method was useful to measure temperature distributions and hotspot locations inside the heated object non-invasively.","PeriodicalId":23299,"journal":{"name":"Thermal Medicine","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2015-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"9","resultStr":"{\"title\":\"Development of Ultrasound-Guided Resonant Cavity Applicator System: - Non-invasive Measurement of Temperature Distributions -@@@- 超音波画像診断装置を用いた非侵襲温度計測 -\",\"authors\":\"Y. Iseki, Keito Nakamura, Daisuke Anan, Kazuo Kato\",\"doi\":\"10.3191/THERMALMED.31.13\",\"DOIUrl\":null,\"url\":null,\"abstract\":\":This paper describes the ultrasound-guided resonant cavity applicator system which has a function for measuring temperature distributions non-invasively. We had already proposed the resonant cavity applicator for non-invasive hyperthermia treatments. In this heating system,it was shown that the applicator could heat deep seated tumor without undesirable hotspots. In addition,the resonant cavity applicator could control the heated area inside tumors corresponding to the symptom of the patients. In the clinic,a real time monitoring system to acquire the targeted area and temperature distributions inside human body is necessary for effective hyperthermia treatments. In this paper, we proposed the ultrasound-guided resonant cavity applicator system which has a possibility of measuring temperature distributions inside human body. The method of measuring temperature distributions was based on the thermal dependence of local change in speed of sound and thermal expansion. Here,we described the method to estimate temperature distributions inside the agar phantom heated by the developed ultrasound-guided resonant cavity applicator. First, we tried to heat the agar phantom inside a hot water bath to discuss the relationship between temperature rises and changes of the ultrasound images. Next, we measured temperature distributions inside the agar phantom heated by the resonant cavity applicator using a diagnostic ultrasound imaging system. Also,we discussed the results of the measured temperature distributions inside the agar phantom for controlling the heated area. 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Development of Ultrasound-Guided Resonant Cavity Applicator System: - Non-invasive Measurement of Temperature Distributions -@@@- 超音波画像診断装置を用いた非侵襲温度計測 -
:This paper describes the ultrasound-guided resonant cavity applicator system which has a function for measuring temperature distributions non-invasively. We had already proposed the resonant cavity applicator for non-invasive hyperthermia treatments. In this heating system,it was shown that the applicator could heat deep seated tumor without undesirable hotspots. In addition,the resonant cavity applicator could control the heated area inside tumors corresponding to the symptom of the patients. In the clinic,a real time monitoring system to acquire the targeted area and temperature distributions inside human body is necessary for effective hyperthermia treatments. In this paper, we proposed the ultrasound-guided resonant cavity applicator system which has a possibility of measuring temperature distributions inside human body. The method of measuring temperature distributions was based on the thermal dependence of local change in speed of sound and thermal expansion. Here,we described the method to estimate temperature distributions inside the agar phantom heated by the developed ultrasound-guided resonant cavity applicator. First, we tried to heat the agar phantom inside a hot water bath to discuss the relationship between temperature rises and changes of the ultrasound images. Next, we measured temperature distributions inside the agar phantom heated by the resonant cavity applicator using a diagnostic ultrasound imaging system. Also,we discussed the results of the measured temperature distributions inside the agar phantom for controlling the heated area. From our heating experiments,it was confirmed that the proposed method was useful to measure temperature distributions and hotspot locations inside the heated object non-invasively.