Ultrasound doppler for improved diagnosis of disease in the paranasal sinuses

We propose a method to improve the diagnosis of infection in the paranasal sinuses, distinguishing between mucous and serous cases. The method utilizes a previously published method whereby the viscosity in a sealed container may be measured using an ultrasound Doppler method. As ultrasound propagat...

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Hauptverfasser:	Jansson, T., Persson, H.W., Holmer, N., Sahlstrand-Johnson, P., Jannert, M.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Acoustic signal detection Antibiotics Attenuation Clinical Medicine Containers Continuous-wave Doppler Diseases Doppler probe Imaging phantoms Irrigation Klinisk medicin Medical and Health Sciences Medicin och hälsovetenskap Oto-rhino-laryngologi Otorhinolaryngology Sinus cavity Ultrasonic imaging Ultrasonic variables measurement Viscosity
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creator	Jansson, T. Persson, H.W. Holmer, N. Sahlstrand-Johnson, P. Jannert, M.
description	We propose a method to improve the diagnosis of infection in the paranasal sinuses, distinguishing between mucous and serous cases. The method utilizes a previously published method whereby the viscosity in a sealed container may be measured using an ultrasound Doppler method. As ultrasound propagates in a liquid medium, due to attenuation, the resulting pressure gradient will cause the liquid to move in the propagation direction - the wellknown effect of acoustic streaming. The streaming velocity will, for a given acoustic output, be proportional to the viscosity of the fluid. In this study, we verify that acoustic streaming can be induced in an anthropomorphic sinus phantom cast from a human cranium. The sinus phantom was made from agar with added graphite providing sound attenuation prior to the sinus cavity corresponding to an in vivo situation. A number of water-glycerol solutions with scattering particles, were prepared to mimic a clinically interesting range of viscosities (7-47 mPas). Using a 4.2 MHz continuous wave Doppler probe, clearly detectable mean Doppler shifts in the range of 6.5 to 20 Hz were recorded A linear relationship was found between the Doppler shifts and 1/viscosity (R 2 =0.94, corrected for the square-law dependence of sound speed variation due to varying glycerol concentration).
doi_str_mv	10.1109/ULTSYM.2005.1602980
format	Conference Proceeding
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The method utilizes a previously published method whereby the viscosity in a sealed container may be measured using an ultrasound Doppler method. As ultrasound propagates in a liquid medium, due to attenuation, the resulting pressure gradient will cause the liquid to move in the propagation direction - the wellknown effect of acoustic streaming. The streaming velocity will, for a given acoustic output, be proportional to the viscosity of the fluid. In this study, we verify that acoustic streaming can be induced in an anthropomorphic sinus phantom cast from a human cranium. The sinus phantom was made from agar with added graphite providing sound attenuation prior to the sinus cavity corresponding to an in vivo situation. A number of water-glycerol solutions with scattering particles, were prepared to mimic a clinically interesting range of viscosities (7-47 mPas). Using a 4.2 MHz continuous wave Doppler probe, clearly detectable mean Doppler shifts in the range of 6.5 to 20 Hz were recorded A linear relationship was found between the Doppler shifts and 1/viscosity (R 2 =0.94, corrected for the square-law dependence of sound speed variation due to varying glycerol concentration).</abstract><pub>IEEE</pub><doi>10.1109/ULTSYM.2005.1602980</doi><tpages>3</tpages></addata></record>
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Acoustic signal detection Antibiotics Attenuation Clinical Medicine Containers Continuous-wave Doppler Diseases Doppler probe Imaging phantoms Irrigation Klinisk medicin Medical and Health Sciences Medicin och hälsovetenskap Oto-rhino-laryngologi Otorhinolaryngology Sinus cavity Ultrasonic imaging Ultrasonic variables measurement Viscosity
title	Ultrasound doppler for improved diagnosis of disease in the paranasal sinuses
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