Microwave thermal imaging: initialin vivoexperience with a single heating zone
Autor: | Paul M. Meaney, Margaret W. Fanning, Keith D. Paulsen, Qianqian Fang, Dun Li, K. L. Moodie, Sarah A. Pendergrass |
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Rok vydání: | 2003 |
Předmět: |
Hyperthermia
Cancer Research Scanner Materials science Swine Physiology Radiation Body Temperature Nuclear magnetic resonance Physiology (medical) Abdomen Immersion medicine Animals Tube (fluid conveyance) Microwaves Monopole antenna Hyperthermia Induced Models Theoretical Torso medicine.disease medicine.anatomical_structure Microwave imaging Thermography Tomography X-Ray Computed Microwave Biomedical engineering |
Zdroj: | International Journal of Hyperthermia. 19:617-641 |
ISSN: | 1464-5157 0265-6736 |
Popis: | The deployment of hyperthermia as a routine adjuvant to radiation or chemotherapy is limited largely by the inability to devise treatment plans which can be monitored through temperature distribution feedback during therapy. A non-invasive microwave tomographic thermal imaging system is currently being developed which has previously exhibited excellent correlation between the recovered electrical conductivity of a heated zone and its actual temperature change during phantom studies. To extend the validation of this approach in vivo, the imaging system has been re-configured for small animal experiments to operate within the bore of a CT scanner for anatomical and thermometry registration. A series of 5-7 day old pigs have been imaged during hyperthermia with a monopole antenna array submerged in a saline tank where a small plastic tube surgically inserted the length of the abdomen has been used to create a zone of heated saline at pre-selected temperatures. Tomographic microwave data over the frequency range of 300-1000 MHz of the pig abdomen in the plane perpendicular to the torso is collected at regular intervals after the tube saline temperatures have settled to the desired settings. Images are reconstructed over a range of operating frequencies. The tube location is clearly visible and the recovered saline conductivity varies linearly with the controlled temperature values. Difference images utilizing the baseline state prior to heating reinforces the linear relationship between temperature and imaged saline conductivity. Demonstration of in vivo temperature recovery and correlation with an independent monitoring device is an important milestone prior to clinical integration of this non-invasive imaging system with a thermal therapy device. |
Databáze: | OpenAIRE |
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