Dielectric properties of lung tissue as a function of air content

Nopp, P; Rapp, Eva; Pfützner, Helmut; Nakesch, H.; Ruhsam, Ch.

doi:10.1088/0031-9155/38/6/005

Cited by 79 publications

(73 citation statements)

References 14 publications

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“…The respective figures are not absolute and can vary according to the conditions of the environment or medium (e g. temperature). A temperature increase is associated with a decrease in impedance [1], due to the prominent increase in ions mobility [47][48][49] that "transport the current", and decrease viscosity of the extracellular fluid. A general increase of about 2% occurs in the conductivity of tissue [50] in the frequency range below 1 GHz, up to a temperature of about 40°C.…”

Section: Physiological Parameters Affecting Bioelectrical Impedance Amentioning

confidence: 99%

Bioelectrical Impedance as a Diagnostic Factor in the Clinical Practice and Prognostic Factor for Survival in Cancer Patients: Prediction, Accuracy and Reliability

Tuorkey¹

2012

J Biosens Bioelectron

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Bioimpedance analysis could provide a clear figure about changes in cells and tissues based on frequencydependent changes, due to their electrical resistances for the applied electrical current. This review explains the physical principle of bioimpedance. And to monitor the progression of radiation induced tissue injury, particularly in radiotherapies. The interaction of radiation with the biological tissues and a prediction for their earlier and later alterations due to exposure are discussed. As well as, an overview for tissue identification by bioelectrical impedance analysis (BIA) is proposed. Bioimpedance analysis "applications and its limitations" in the health care, clinical practice and prognosis of overall survival in cancer patients are discussed.

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Section: Physiological Parameters Affecting Bioelectrical Impedance Amentioning

confidence: 99%

Bioelectrical Impedance as a Diagnostic Factor in the Clinical Practice and Prognostic Factor for Survival in Cancer Patients: Prediction, Accuracy and Reliability

Tuorkey¹

2012

J Biosens Bioelectron

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“…In contrast to CT, the relatively new imaging technique, electrical impedance tomography (EIT) is noninvasive and radiation-free. EIT utilizes the phenomenon that changes in regional air content modify electrical impedance of lung tissue (Nopp et al, 1993). Small alternating electrical currents are applied at the chest wall surface during examination and the resultant potential differences are measured.…”

Section: Optimizing Peep With Imaging Techniquesmentioning

confidence: 99%

Optimizing Perioperative Ventilation Support with Adequate Settings of Positive End-Expiratory Pressure

Zhao¹,

Stahl²,

Müller-Lisse³

et al. 2012

Front Lines of Thoracic Surgery

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“…The dielectric properties of lung tissue changes as a function of air content within the lungs (Nopp et al, 1993). The electrical conductivity of inflated and deflated lung tissue was reported to be 0.093S/m and 0.243S/m respectively at 10kHz (Andreuccetti D, 1997).…”

Section: Introductionmentioning

confidence: 99%

Development of an electrical impedance based spirometer

2018

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Spirometry, or measurement of respiration conventionally involves measurement of the time variation of volume or flow of air breathed in or out through the mouth using an air-flow sensor. Electrical impedance of thorax changes during breathing and conceptually this modality should be applicable in spirometry, but no attempts have been made so far. This paper describes the development of an electrical impedance based spirometer placing electrodes on four limbs so that the whole lung volume may contribute to the measurement. An impedance based measurement system (IBS) consisting of a constant current drive at 11 kHz and necessary voltage measurement circuitry was designed and developed for this purpose. A portable oscilloscope (PicoScope 2208A) was used for acquisition of the measured voltage signal to a PC and an algorithm in Matlab software was used to demodulate the time varying impedance from a carrier signal. The variation of impedance with time during forced expiration as measured by the implemented impedance measurement system was compared with that obtained using a standard bellows type commercial spirometer (Vitalograph) on eight volunteers, between 22 and 32 years of age. The subjects included smokers, nonsmokers, and asthma patients. Repeatability of the measurements were satisfactory. The correlation coefficient between the spirogram obtained using the IBS and that obtained using standard spirometer varied from 0.81 to 0.99 indicating preliminary success of the proposed technique. However, a possible source of error is the bending of the body during forced expiration which, if prevented, may give a better outcome.

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Dielectric properties of lung tissue as a function of air content

Cited by 79 publications

References 14 publications

Bioelectrical Impedance as a Diagnostic Factor in the Clinical Practice and Prognostic Factor for Survival in Cancer Patients: Prediction, Accuracy and Reliability

Bioelectrical Impedance as a Diagnostic Factor in the Clinical Practice and Prognostic Factor for Survival in Cancer Patients: Prediction, Accuracy and Reliability

Optimizing Perioperative Ventilation Support with Adequate Settings of Positive End-Expiratory Pressure

Development of an electrical impedance based spirometer

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