The effect of using a dielectric matching medium in focused microwave radiometry: an anatomically detailed head model study

Microwave radiometry is a passive technique used to measure in-depth temperature distributions inside the human body , potentially useful in clinical applications. Experimental data imply that it may provide the capability of detecting in-depth local variations of temperature and/or conductivity of...

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Bibliographic Details
Published in:Medical & biological engineering & computing 2018-05, Vol.56 (5), p.809-816
Main Authors: Koutsoupidou, Maria, Groumpas, Evangelos, Karanasiou, Irene S., Christopoulou, Maria, Nikita, Konstantina, Uzunoglu, Nikolaos
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Biomedical Engineering and Bioengineering
Biomedicine
Body temperature
Brain
Brain research
Computer Applications
Computer simulation
Conductivity
Diagnostic software
Diagnostic systems
Experimental data
Head
Human Physiology
Imaging
Matching
Microwave frequencies
Microwave radiometers
Monitoring
Neuroimaging
Original Article
Radiology
Radiometry
Simulation analysis
Spatial discrimination
Spatial resolution
Temperature effects
Therapeutic applications
Thermal simulation
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Summary:Microwave radiometry is a passive technique used to measure in-depth temperature distributions inside the human body , potentially useful in clinical applications. Experimental data imply that it may provide the capability of detecting in-depth local variations of temperature and/or conductivity of excitable tissues at microwave frequencies. Specifically, microwave radiometry may allow the real-time monitoring of brain temperature and/or conductivity changes, associated with local brain activation. In this paper, recent results of our ongoing research regarding the capabilities of focused microwave radiometry for brain intracranial applications are presented. Electromagnetic and thermal simulation analysis was performed using an anatomically detailed head model and a dielectric cap as matching medium placed around it, in order to improve the sensitivity and the focusing attributes of the system. The theoretical results were compared to experimental data elicited while exploring that the sensing depth and spatial resolution of the proposed imaging method at 2.1 GHz areas located 3 cm deep inside the brain can be measured, while at 2.5 GHz , the sensing area is confined specifically to the area of interest. The results exhibit the system’s potential as a complementary brain imaging tool for multifrequency in-depth passive monitoring which could be clinically useful for therapeutic, diagnostic , and research applications.
ISSN:0140-0118
1741-0444
DOI:10.1007/s11517-017-1729-4