13th International Conference on Electrical Bioimpedance and 8th Conference on Electrical Impedance Tomography 2007: ICEBI 2007, August 29th - September 2nd 2007, Graz, AustriaHermann Scharfetter, Robert Merwa These proceedings continue the series edited in the framework of the traditional triennial International Conference on El- trical Bio-Impedance (ICEBI), the most important platform for presenting recent scientific achievements in the area of el- th nd trical bio-impedance. The XIII ICEBI was held from Aug. 29 – Sept. 02 2007 at the Graz University of Technology in Graz, Austria. The organizers received 285 abstracts 264 of which were accepted for presentation. The authors of these - pers came from 34 different nations. Due to the kind support by the International Federation for Biomedical Engineering (IFMBE) the proceedings were p- lished by Springer in the proceedings series of the IFMBE. The editors would like to thank the IFMBE for this kind of s- vice which makes the results of the bioimpedance community visible on a very important publishing platform. According to the quality requirements of the IFMBE each paper had to pass a thorough two-stage review by two independent members of the scientific board. As a result 204 papers were selected for being printed in this issue. As already in previous years the ICEBI was held together with the Conference on Electrical Impedance Tomography, the annual meeting for biomedical impedance imaging. Consequently, the proceedings also contain many contributions from this very important and challenging branch of bioimpedance research. |
Contents
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Why is the measured impedance of the bladder tissue different from the computational modelling results? | 28 |
H Luomaaho P Kauppinen R Suuronen and J Hyttinen | 42 |
The Model of Vascular Bed for Estimation of Human Systemic Hydrohemodynamics | 56 |
Y Ülgen andS Mana | 70 |
Sensing the cell substrate interaction towards development of smart surfaces | 86 |
Electrical time constants of erythrocytes for confocal and uniform thickness membrane | 102 |
Imagereconstruction approaches for Philips magnetic induction M Vauhkonen M Hamsch and C H Igney | 468 |
Correction of systematic errors in frequency differential magnetic induction tomography | 476 |
R Merwa and H Scharfetter | 482 |
Projected Current from One Component of Magnetic Flux Density in MREIT | 488 |
Local harmonic Bz algorithm in MREIT Sungwhan Kim Jin Keun Seo Sungwan Kim Eung Je Woo Kiwan Jun and Chang Ok | 496 |
Newton Method for Injection Current Nonlinear EncodingICNE in MREIT | 500 |
Equipotential projection based MREIT reconstruction without potential measurements | 516 |
Mayer P Brunner F SmolleJüttner A Maier N Neuböck and H Scharfetter | 530 |
Q Fang X Liu I Cosic | 116 |
Tissue and Organ Impedance | 126 |
J RosellFerrer M A Garcia J Ramos R Bragos Y Salazar M Fernández X Viñolas and J Cinca | 140 |
Skin Impedance | 154 |
Evaluation of the effects of topical clobetasol propionate by electrical impedance | 168 |
Modelling and Data Processing | 181 |
A new hard and software concept for impedance spectroscopy analysers for broadband process measurements | 194 |
Geometry dependencies in tetrapolar electrode systems a finite element analysis on needle electrodes | 198 |
Electrodes and Instrumentation | 213 |
Multi Frequency Multi Channel Differential Impedance Analyzer for Rapid Assays | 229 |
P Annus A Kuusik R Land E Haldre M Min T Parve and G Poola | 242 |
Implantable bioimpedance system for measuring the impedance of kidney | 256 |
Salinesaturated Balsa Wood as a Testing Medium for Rotational Electrical Impedance Myography | 272 |
Digitally Controlled Reference Impedance Device for Test and Calibration | 276 |
A Custommade Demodulation Technique for ElTEIS Systems | 284 |
G Steiner M Soleimani H Dehghani D Watzenig and F Podd | 290 |
Y Xu S Haider andA Hrbek | 296 |
UltraThin Silicon Membrane as a Sensitive Substrate for Active Bioscreening | 304 |
Chilcott E L S Wong T Böcking and H G L Coster | 310 |
A González R Rojas and B Rubinsky | 316 |
Investigation of biological phantom for 2D and 3D breast EIT images | 328 |
Hwan Koo Tong In Oh and Eung Je | 334 |
in Electrical Impedance Tomography W Wang L Wang G Qiao P Prickett B Bramer B Tunstalland M AlAkaidi | 340 |
Complex Conductivity Spectra of Seven Materials and Phantom Design for EIT | 344 |
T Tang S Oh andR Sadleir | 360 |
JuanFelipe P J Abascal Simon R Arridge William R B Lionheart Richard H Bayford and David S Holder | 374 |
A new clinical data and image analysis tool for monitoring neonatal lung function | 388 |
Goharian M Soleimani A Jegatheesan and G R Moran | 402 |
Coregistration of Electrical Impedance Tomography and Magnetic Resonance Imaging | 416 |
Sungho Oh Te Tang and Rosalind Sadleir | 426 |
a step forward for virtual biopsy by EIT? | 432 |
Y He W Wang G Sze G Qiao DaWei Gu and B Bramer | 438 |
Using Micro Electrode Array For Online EIT Measurement | 444 |
Matthias Steffen and Steffen Leonhardt | 450 |
The influence of the coil configuration on the spatial resolution | 456 |
Y Maimaitijiang M A Roula S Watson R J Williams H Griffiths | 462 |
Evaluation of the performance of the Multifrequency Electrical Impedance Tomography MFEIT intended | 543 |
Early Findings A Hartov R J Halter A Borsic P Manwaring K D Paulsen and W A Wells P A Kaufman | 556 |
Fabrizi A McEwan D Oh and D S Holder | 570 |
Clinical Applications and Experimental Studies | 576 |
Impedance Cardiography in Cardiac Pacing | 582 |
Signal quality evaluation in Ambulatory Impedance Cardiography | 590 |
Using time interval parameters from impedance cardiography to evaluate autonomic nervous function | 596 |
B E Lingwood G N Healy Z B Kecskes K R Dunster P H Gray L C Ward P B Colditz | 602 |
Impedance rheography for systemic and pulmonary circulation study and clinical application | 608 |
Bioelectrical Impedance Analysis Measures the Ejection Fraction of the Calf Muscle Pump | 616 |
P Kassanos R K IlesR H Bayfordand A Demosthenous | 624 |
W Kim K S Kim Y S An J H Seo and C G Song | 630 |
Parameters for monitoring refeeding of anorexia nervosa patients by bioimpedance | 640 |
Popov and E Kitaeva | 646 |
Multifrequency Electrical Impedance Myography In Amyotrophic Lateral Sclerosis | 647 |
J Wtorek A Bujnowski A Nowakowski W Stojek J Rogowski B Trzeciak and J Siebert | 660 |
Electrical Impedance Scanning for Breast Cancer Risk Stratification in Young Women | 675 |
T Shiga Y Oshima H Kanai M Hirata K Hosoda and K Nakao | 688 |
Determination of the root canal length using impedance ratio method | 703 |
T Marjanović Z Stare I Lacković | 716 |
Equipment for realtime bioimpedance diagnostics of the functional state of human organism | 735 |
Variation of Magnetic Induction Plethysmogram on Human Thoracic Surface | 743 |
A Jabbari S Grimnes and Ø G Martinsen | 751 |
Estimation of fluid volume changes during haemodialysis with an anisotropic finite element model | 759 |
In Maintenance Hemodialysis Patients Lean Body Mass can be Evaluated by Bioelectrical Impedance Analysis | 767 |
A Device for Monitoring Hydration State in Hemodialysis Patients Using a Calf Bioimpedance Technique | 775 |
Males Are Different | 783 |
Carter F Zhu S R Sarkar G A Kaysen L Ramirez SB Heymsfield G Handelman N W Levin | 791 |
B H Cornish B E Lingwoodand L C Ward | 799 |
Best published equation for the calculation of Body Fat in a sample of Colombian young males | 803 |
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13th International Conference on Electrical Bioimpedance and the 8th Conference on Electrical Impedance | 820 |
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