R W M Lau scite author profile

Three experimental techniques based on automatic swept-frequency network and impedance analysers were used to measure the dielectric properties of tissue in the frequency range 10 Hz to 20 GHz. The technique used in conjunction with the impedance analyser is described. Results are given for a number of human and animal tissues, at body temperature, across the frequency range, demonstrating that good agreement was achieved between measurements using the three pieces of equipment. Moreover, the measured values fall well within the body of corresponding literature data.

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The dielectric properties of biological tissues: III. Parametric models for the dielectric spectrum of tissues

Gabriel

1996

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A parametric model was developed to describe the variation of dielectric properties of tissues as a function of frequency. The experimental spectrum from 10 Hz to 100 GHz was modelled with four dispersion regions. The development of the model was based on recently acquired data, complemented by data surveyed from the literature. The purpose is to enable the prediction of dielectric data that are in line with those contained in the vast body of literature on the subject. The analysis was carried out on a Microsoft Excel spreadsheet. Parameters are given for 17 tissue types.

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Electromagnetic and thermal modeling of SAR and temperature fields in tissue due to an RF decoupling coil

Hand¹,

Lau²,

Lagendijk³

et al. 1999

Magn. Reson. Med.

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SAR and Temperature Changes in the Leg Due to an RF Decoupling Coil at Frequencies Between 64 and 213 MHz

Hand

Lagendijk

Hajnal

et al. 2000

J. Magn. Reson. Imaging

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Specific absorption rate (SAR) due to a butterfly surface coil in a realistic model of the leg was calculated for frequencies 64 < < 213 MHz. The resulting temperature distribution and temperature changes (⌬T) were found using the bioheat transfer equation. To compare results at different frequencies, the minimum B-field within the coil's footprint in the plane parallel to the coil but displaced 50 mm from it was kept constant. To achieve the same minimum B-field as that associated with operation at 64 MHz that was compliant with safety guidelines (peak SAR in 1 cm 3 of tissue of 2.3 W/kg), it was predicted that SAR would exceed recommended levels when > 149 MHz.

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A meshfree study of the Kalthoff–Winkler experiment in 3D at room and low temperatures under dynamic loading using viscoplastic modelling

Raymond

Lemiale

Ibrahim

et al. 2014

Engineering Analysis with Boundary Elements

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R W M Lau

The dielectric properties of biological tissues: II. Measurements in the frequency range 10 Hz to 20 GHz

The dielectric properties of biological tissues: III. Parametric models for the dielectric spectrum of tissues

Electromagnetic and thermal modeling of SAR and temperature fields in tissue due to an RF decoupling coil

SAR and Temperature Changes in the Leg Due to an RF Decoupling Coil at Frequencies Between 64 and 213 MHz

A meshfree study of the Kalthoff–Winkler experiment in 3D at room and low temperatures under dynamic loading using viscoplastic modelling

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