Analyzing temperature dependence of electrical impedance myography parameters using finite element model

Khondokar M.F. Rabbi, Somen Baidya, Mohammad A. Ahad

Research output: Contribution to book or proceedingConference articlepeer-review

1 Scopus citations

Abstract

Electrical Impedance Myography (EIM) is a non-invasive electrophysiological approach for the assessment of neuromuscular diseases. Finite element model of the EIM experiment has been proposed recently which can predict the actual model results. EIM parameters depend on various factors such as fat thickness, muscle thickness, inter electrode distances etc. In this study, we attempt to analyze the changes in EIM parameters due to ambient temperature with different subcutaneous fat thickness. We observe that resistance and reactance increases with increase in fat thickness and decreases with temperature increment. For example, with 10mm fat thickness, due to temperature variation, percentage changes in resistance is 0.32% and percentage changes in reactance is 1.50%. Further simulation shows that percentage changes in resistance increase with the fat thickness and percentage changes in reactance decrease with fat thickness due to increase in temperature.

Original languageEnglish
Title of host publicationIEEE SoutheastCon 2015 - Conference Proceedings
PublisherInstitute of Electrical and Electronics Engineers Inc.
EditionJune
ISBN (Electronic)9781467373005
DOIs
StatePublished - Jun 24 2015
EventIEEE SoutheastCon 2015 - Fort Lauderdale, United States
Duration: Apr 9 2015Apr 12 2015

Publication series

NameConference Proceedings - IEEE SOUTHEASTCON
NumberJune
Volume2015-June
ISSN (Print)1091-0050
ISSN (Electronic)1558-058X

Conference

ConferenceIEEE SoutheastCon 2015
Country/TerritoryUnited States
CityFort Lauderdale
Period04/9/1504/12/15

Scopus Subject Areas

  • Computer Networks and Communications
  • Software
  • Electrical and Electronic Engineering
  • Control and Systems Engineering
  • Signal Processing

Keywords

  • EIM
  • FEM
  • Temperature dependency of human body tissue

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