Spectroscopy study of the dynamics of the transencephalic electrical impedance in the perinatal brain during hypoxia

Seoane, Fernando; Lindecrantz, Kaj; Olsson, Torsten; Kjellmer, Ingemar; Flisberg, Anders; Bågenholm, Ralph

doi:10.1088/0967-3334/26/5/021

“…The total output impedance for this type of VCCS can be approximated by a general equivalent circuit modeled as three impedances building up a parallel bridge; see Figure 19, where Z in is the input impedance of the VCCS considering the Op-Amp ideal, Z i is the equivalent input impedance of the Op-Amp from the inverting input to ground, Z f is the impedance in the feedback loop, and opz(s) is the OpAmp impedance factor as defined in (10).…”

Section: Discussionmentioning

confidence: 99%

“…Notice that the notation changes in equation (2.13) from r 1 in equation (10) to r i, and from r in equation (2.10) to z * . Usually the resistivity effect of the plasma membrane is neglected and the membrane is considered as an ideal capacitor.…”

Section: Electrical Resistivity Of a Suspension Of Spherical Cellsmentioning

confidence: 99%

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Electrical Bioimpedance Cerebral Monitoring

Martinez¹,

Lindecrantz²

Encyclopedia of Healthcare Information Systems

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-i - A B S T R A C TNeurologically related injuries cause a similar number of deaths as cancer, and brain damage is the second commonest cause of death in the world and probably the leading cause of permanent disability. The devastating effects of most cases of brain damage could be avoided if it were detected and medical treatment initiated in time. The passive electrical properties of biological tissue have been investigated for almost a century and electrical bioimpedance studies in neurology have been performed for more than 50 years. Even considering the extensive efforts dedicated to investigating potential applications of electrical bioimpedance for brain monitoring, especially in the last 20 years, and the specifically acute need for such non-invasive and efficient diagnosis support tools, Electrical Bioimpedance technology has not made the expected breakthrough into clinical application yet. In order to reach this stage in the age of evidence-based medicine, the first essential step is to demonstrate the biophysical basis of the method under study. The present research work confirms that the cell swelling accompanying the hypoxic/ischemic injury mechanism modifies the electrical properties of brain tissue, and shows that by measuring the complex electrical bioimpedance it is possible to detect the changes resulting from brain damage. For the development of a successful monitoring method, after the vital biophysical validation it is critical to have available the proper electrical bioimpedance technology and to implement an efficient protocol of use. Electronic instrumentation is needed for broadband spectroscopy measurements of complex electrical bioimpedance; the selection of the electrode setup is crucial to obtain clinically relevant measurements, and the proper biosignal analysis and processing is the core of the diagnosis support system. This work has focused on all these aspects since they are fundamental for providing the solid medico-technological background necessary to enable the clinical usage of Electrical Bioimpedance for cerebral monitoring.Keywords: Electrical Bioimpedance Spectroscopy, Hypoxia, Ischemia, Stroke, Brain Monitoring, Impedance Measurements, Biomedical Instrumentation, Non-invasive Monitoring.-iiPreface -iii - P R E F A C EThis research work has been performed mainly in collaboration between the following research and academic institutions: the School of Engineering at University College of Borås, the Department of Signals and Systems at Chalmers University of Technology, the Sahlgrenska University Hospital, and the Sahlgrenska Academy at Göteborg University.Specific activities of this research work have been carried out in collaboration with the Department of Electronic Engineering at the Polytechnic University of Catalonia, Spain.This research work has been mainly funded by the Swedish Research Council (Vetenskapsrådet) through a research grant (No. 2002-5487). The research activity performed has also been part of the following European Network of Excellence: "Comp...

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“…The Op-Amp impedance factor, opz (10), plays the same role in the currentdriven VCCS as in the pure VCCS. As is seen in (9), opz is a crucial factor that links the value of Z in directly to the output impedance Z out .…”

Section: Output Impedancementioning

confidence: 99%

Electrical Bioimpedance Cerebral Monitoring

Seoane

¹

,

Lindecrantz

²

2008

Encyclopedia of Healthcare Information Systems

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-i - A B S T R A C TNeurologically related injuries cause a similar number of deaths as cancer, and brain damage is the second commonest cause of death in the world and probably the leading cause of permanent disability. The devastating effects of most cases of brain damage could be avoided if it were detected and medical treatment initiated in time. The passive electrical properties of biological tissue have been investigated for almost a century and electrical bioimpedance studies in neurology have been performed for more than 50 years. Even considering the extensive efforts dedicated to investigating potential applications of electrical bioimpedance for brain monitoring, especially in the last 20 years, and the specifically acute need for such non-invasive and efficient diagnosis support tools, Electrical Bioimpedance technology has not made the expected breakthrough into clinical application yet. In order to reach this stage in the age of evidence-based medicine, the first essential step is to demonstrate the biophysical basis of the method under study. The present research work confirms that the cell swelling accompanying the hypoxic/ischemic injury mechanism modifies the electrical properties of brain tissue, and shows that by measuring the complex electrical bioimpedance it is possible to detect the changes resulting from brain damage. For the development of a successful monitoring method, after the vital biophysical validation it is critical to have available the proper electrical bioimpedance technology and to implement an efficient protocol of use. Electronic instrumentation is needed for broadband spectroscopy measurements of complex electrical bioimpedance; the selection of the electrode setup is crucial to obtain clinically relevant measurements, and the proper biosignal analysis and processing is the core of the diagnosis support system. This work has focused on all these aspects since they are fundamental for providing the solid medico-technological background necessary to enable the clinical usage of Electrical Bioimpedance for cerebral monitoring.Keywords: Electrical Bioimpedance Spectroscopy, Hypoxia, Ischemia, Stroke, Brain Monitoring, Impedance Measurements, Biomedical Instrumentation, Non-invasive Monitoring.-iiPreface -iii - P R E F A C EThis research work has been performed mainly in collaboration between the following research and academic institutions: the School of Engineering at University College of Borås, the Department of Signals and Systems at Chalmers University of Technology, the Sahlgrenska University Hospital, and the Sahlgrenska Academy at Göteborg University.Specific activities of this research work have been carried out in collaboration with the Department of Electronic Engineering at the Polytechnic University of Catalonia, Spain.This research work has been mainly funded by the Swedish Research Council (Vetenskapsrådet) through a research grant (No. 2002-5487). The research activity performed has also been part of the following European Network of Excellence: "Comp...

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“…Examples of this are skin cancer screening (Aberg et al , Beetner et al 2003 and methods for detection of tumours (Skourou et al 2004(Skourou et al , 2007, meningitis (Van Kreel 2001), brain cellular oedema (Lingwood et al 2002, Seoane et al 2005 and breast cancer (Assenheimer et al 2001). All these applications depend on the EBI recorded over a wide frequency range.…”

Section: Introductionmentioning

confidence: 99%

Simple voltage-controlled current source for wideband electrical bioimpedance spectroscopy: circuit dependences and limitations

Seoane

¹

,

Macias

²

,

Bardia

³

et al. 2011

Meas. Sci. Technol.

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In this work, the single Op-Amp with load-in-the-loop topology as a current source is revisited. This circuit topology was already used as a voltage-controlled current source (VCCS) in the 1960s but was left unused when the requirements for higher frequency arose among the applications of electrical bioimpedance (EBI). The aim of the authors is not only limited to show that with the currently available electronic devices it is perfectly viable to use this simple VCCS topology as a working current source for wideband spectroscopy applications of EBI, but also to identify the limitations and the role of each of the circuit components in the most important parameter of a current for wideband applications: the output impedance. The study includes the eventual presence of a stray capacitance and also an original enhancement, driving with current the VCCS. Based on the theoretical analysis and experimental measurements, an accurate model of the output impedance is provided, explaining the role of the main constitutive elements of the circuit in the source's output impedance. Using the topologies presented in this work and the proposed model, any electronic designer can easily implement a simple and efficient current source for wideband EBI spectroscopy applications, e.g. in this study, values above 150 k at 1 MHz have been obtained, which to the knowledge of the authors are the largest values experimentally measured and reported for a current source in EBI at this frequency.

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Spectroscopy study of the dynamics of the transencephalic electrical impedance in the perinatal brain during hypoxia

Cited by 39 publications

References 27 publications

Electrical Bioimpedance Cerebral Monitoring

Electrical Bioimpedance Cerebral Monitoring

Electrical Bioimpedance Cerebral Monitoring

Simple voltage-controlled current source for wideband electrical bioimpedance spectroscopy: circuit dependences and limitations

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