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ISSN Печать: 0278-940X
ISSN Онлайн: 1943-619X
Indexed in
Bioelectrical Impedance Techniques in Medicine
Part III: Impedance Imaging
Third Section: Medical Applications
Краткое описание
In several areas of clinical medicine, electrical impedance tomography could offer significant advantages over existing methods. These advantages have been supported by preliminary studies or by validation studies, which are described. The suggested applications are reviewed in this section. They mainly concern developments in impedance variations on brain, lung (neonatal, edema, emphysema), and heart; changes in blood volume, gastrointestinal system (gastric emptying, gastroesophageal reflux, pharyngeal transit time); pelvis (pelvis congestion); and thermal mapping in hyperthermia and breast (tissue characterization). The conductivity information at one frequency in a pixel is insufficient to take into account the very complex physiological mechanisms that underlie the observed impedance changes. To gain a better understanding of these mechanisms, research is currently being carried out on imaging of the imaginary part, parametric imaging, spectroscopic imaging, and 3D imaging, which are developed at the end of this section.
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Frerichs Inéz, Electrical impedance tomography (EIT) in applications related to lung and ventilation: a review of experimental and clinical activities, Physiological Measurement, 21, 2, 2000. Crossref
-
Birg l zlem, Ey boglu B Murat, Ider Y Ziya, Current constrained voltage scaled reconstruction (CCVSR) algorithm for MR-EIT and its performance with different probing current patterns, Physics in Medicine and Biology, 48, 5, 2003. Crossref
-
Gençer Nevzat G, Tek M Nejat, Forward problem solution for electrical conductivity imaging via contactless measurements, Physics in Medicine and Biology, 44, 4, 1999. Crossref
-
Diao Jietao, Zhou Zhou, Li Nan, Nie Hongshan, Yu Hongqi, Xu Hui, High Accuracy Biological Impedance Measurement System Design and Calibration, 2012 Third International Conference on Digital Manufacturing & Automation, 2012. Crossref
-
Gonzalez C.A., Rubinsky B., Frequency Dependence of Phase Shift in Edema: a Theoretical Study with Magnetic Induction, 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference, 2005. Crossref
-
Ma Hang, Li Haoting, Liu Xuechao, Li Weichen, Xia Junying, Liu Benyuan, Shi Xuetao, Dong Xiuzhen, Fu Feng, Real-Time Monitoring of Contact Impedance From Multiple Electrode–Scalp Interfaces During Cerebral Electrical Impedance Tomography, IEEE Access, 7, 2019. Crossref
-
Gozu Mehmet Soner, Zengin Reyhan, Gencer Nevzat Guneri, Numerical studies for Hall Effect Imaging using linear phased array transducer, 2014 18th National Biomedical Engineering Meeting, 2014. Crossref
-
Colina Gallo Evelyn, González Correa Carlos Augusto, Miranda Mercado David Alejandro, Miografía por impedancia eléctrica, Revista Colombiana de Médicina Física y Rehabilitación, 26, 1, 2016. Crossref
-
Eyüboğlu B.M., Değirmenci E., Anisotropic Conductivity Imaging with MREIT Using Equipotential Projection Algorithm, in 13th International Conference on Electrical Bioimpedance and the 8th Conference on Electrical Impedance Tomography, 17, 2007. Crossref
-
Johnson Lee, Scribner Dean, Skeath Perry, Klein Richard, Ilg Doug, Perkins Keith, Helfgott Maxwell, Sanders Reginald, Panigrahi Dipak, Impedance-based retinal contact imaging as an aid for the placement of high resolution epiretinal prostheses, Journal of Neural Engineering, 4, 1, 2007. Crossref
-
Hui Xia , Guoqing Liu , Xiaoping Zeng , Experimental study of magneto-acousto-electrical tomography, 2011 Second International Conference on Mechanic Automation and Control Engineering, 2011. Crossref
-
Ulker B., Gencer N.G., Implementation of a data acquisition system for contactless conductivity imaging, 2001 Conference Proceedings of the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 4, 2001. Crossref
-
Ruiz-Vargas A, Arkwright J W, Ivorra Antoni, A portable bioimpedance measurement system based on Red Pitaya for monitoring and detecting abnormalities in the gastrointestinal tract, 2016 IEEE EMBS Conference on Biomedical Engineering and Sciences (IECBES), 2016. Crossref
-
Jackson Alan, Technical Progress in Neuroradiology and Its Application, in Recent Advances in Diagnostic Neuroradiology, 2001. Crossref
-
Oschman James L., Electricity and Magnetism in Diagnosis and Therapeutics, in Energy Medicine, 2016. Crossref
-
González-Correa Carlos-Augusto, Clinical Applications of Electrical Impedance Spectroscopy, in Bioimpedance in Biomedical Applications and Research, 2018. Crossref
-
Wen Han, Feasibility of Biomedical Applications of Hall Effect Imaging, Ultrasonic Imaging, 22, 2, 2000. Crossref
-
Fu Yan, Tan Chao, Dong Feng, Analysis of response for magnetic induction tomography with internal source, Measurement, 78, 2016. Crossref
-
Li Nan, Xu Hui, Wang Wei, Zhou Zhou, Qiao Guofeng, Li David D-U, A high-speed bioelectrical impedance spectroscopy system based on the digital auto-balancing bridge method, Measurement Science and Technology, 24, 6, 2013. Crossref
-
Eyüboglu B. Murat, Electrical Impedance Imaging, Injected Current, in Wiley Encyclopedia of Biomedical Engineering, 2006. Crossref
-
Bouchaala Dhouha, Kanoun Olfa, Derbel Nabil, High accurate and wideband current excitation for bioimpedance health monitoring systems, Measurement, 79, 2016. Crossref
-
Xia Hui, Liu Guoqiang, Li Yanhong, Zhang Yang, Li Shiqiang, Zhang Laifu, Numerical Simulation Method of Acoustic Field Positive Problem Based on Magnetoacoustic Tomography with Magnetic Induction, 2010 4th International Conference on Bioinformatics and Biomedical Engineering, 2010. Crossref
-
González César A, Rubinsky Boris, A theoretical study on magnetic induction frequency dependence of phase shift in oedema and haematoma, Physiological Measurement, 27, 9, 2006. Crossref
-
Beckmann N., Tigani B., Ekatodramis D., Borer R., Mazzoni L., Fozard J.R., Pulmonary edema induced by allergen challenge in the rat: Noninvasive assessment by magnetic resonance imaging, Magnetic Resonance in Medicine, 45, 1, 2001. Crossref
-
Younghak Cho , Hyun Soo Kim , Frazier A.B., Chen Z.G., Dong Moon Shin , Han A., Whole-Cell Impedance Analysis for Highly and Poorly Metastatic Cancer Cells, Journal of Microelectromechanical Systems, 18, 4, 2009. Crossref
-
Smit H, Vonk Noordegraaf A, van Genderingen H, Kunst P, Imaging of the thorax by EIT, in Electrical Impedance Tomography, 20042253, 2004. Crossref
-
Abdalla S., Al-ameer S. S., Al-Magaishi S. H., Electrical properties with relaxation through human blood, Biomicrofluidics, 4, 3, 2010. Crossref
-
Ramirez de Peña Doris, Almanza Dagoberto, Ángel Luis Alberto, Pinzón Segura Daniel, Zambrano Adriana, Mera Nidia, Contento Ricardo, Bermúdez Sandra, Giraldo Juliette, Cáceres Lilián, Osorio Diana, Sabogal Paola, Suárez Yeinny, González Leny, León Juliana, Barrera Laura, Estimación del agua corporal total y del peso seco usando impedancia bioeléctrica tetrapolar de multifrecuencia en pacientes en hemodiálisis. Universidad Nacional de Colombia, Unidad Renal Fundación Hospital San Carlos, Cruz Roja y Centro de Investigación, Revista de la Facultad de Medicina, 63, 1, 2015. Crossref
-
Levy S., Adam D., Bresler Y., Electromagnetic impedance tomography (EMIT): a new method for impedance imaging, IEEE Transactions on Medical Imaging, 21, 6, 2002. Crossref
-
Jose P. Subha Hency, Rajasekaran K., Rajalakshmy P., Jebastina Blessy, A Non-Invasive Method for Measurement of Blood Glucose using Bio Impedance Technique, 2019 2nd International Conference on Signal Processing and Communication (ICSPC), 2019. Crossref
-
Ulker B., Gencer N.G., Implementation of a data acquisition system for contactless conductivity imaging, IEEE Engineering in Medicine and Biology Magazine, 21, 5, 2002. Crossref
-
Gencer N.G., Tek M.N., Electrical conductivity imaging via contactless measurements, IEEE Transactions on Medical Imaging, 18, 7, 1999. Crossref
-
Sadleir R. J., Fox R. A., Turner V. F., Inflatable belt for the application of electrode arrays, Review of Scientific Instruments, 71, 2, 2000. Crossref
-
Bhakoo Kishore K, Bell Jimmy D, Cox I.Jane, Taylor-Robinson Simon D, The Application of Magnetic Resonance Imaging and Spectroscopy to Gene Therapy, in Imaging in Biological Research, Part B, 386, 2004. Crossref
-
Frerichs I., Hahn G., Hellige G., Thoracic electrical impedance tomographic measurements during volume controlled ventilation-effects of tidal volume and positive end-expiratory pressure, IEEE Transactions on Medical Imaging, 18, 9, 1999. Crossref
-
Nan Li , Hui Xu , Zhou Zhou , Jinling Xin , Zhaolin Sun , Xin Xu , Reconfigurable Bioimpedance Emulation System for Electrical Impedance Tomography System Validation, IEEE Transactions on Biomedical Circuits and Systems, 7, 4, 2013. Crossref
-
Strodthoff Nils, Strodthoff Claas, Becher Tobias, Weiler Norbert, Frerichs Inez, Inferring Respiratory and Circulatory Parameters from Electrical Impedance Tomography With Deep Recurrent Models, IEEE Journal of Biomedical and Health Informatics, 25, 8, 2021. Crossref
-
Bell JD, Taylor-Robinson SD, Assessing gene expression in vivo: magnetic resonance imaging and spectroscopy, Gene Therapy, 7, 15, 2000. Crossref
-
Hong Jhih-Lin, Lan Kung-Chieh, Jang Ling-Sheng, Electrical characteristics analysis of various cancer cells using a microfluidic device based on single-cell impedance measurement, Sensors and Actuators B: Chemical, 173, 2012. Crossref
-
Moqadam Sepideh Mohammadi, Grewal Parvind Kaur, Haeri Zahra, Ingledew Paris Ann, Kohli Kirpal, Golnaraghi Farid, Cancer detection based on electrical impedance spectroscopy: A clinical study, Journal of Electrical Bioimpedance, 9, 1, 2018. Crossref