2nd CLABIO,Montevideo,September 30 - October 02, 2015
E-Book, Englisch, Band 54, 98 Seiten, eBook
Reihe: IFMBE Proceedings
ISBN: 978-981-287-928-8
Verlag: Springer Singapore
Format: PDF
Kopierschutz: 1 - PDF Watermark
Montevideo, Uruguay - September 30 - October 02, 2015.The works cover a broad range in Biomedical Engineering and Computing, Medical Physics and Medical Sciences, Environment, Biology and Chemistry. The topics are:
·Bioimpedance Applications
·Bioimpedance Instrumentation
·Body and Tissue Composition
·Cell Culture and Cell Suspension
·Electrical Impedance Tomography
·Electrode Modelling
·Magnetic Induction - Electrical Impedance Tomography
·Magnetic Resonance - Electrical Impedance Tomography
·Nonlinear Phenomena
·Organ and Tissue Impedance
·Plant Tissue Impedance
·Skin Impedance Modelling
·Technological Advances in Bioimpedance
·Theory and Modelling
Zielgruppe
Research
Autoren/Hrsg.
Weitere Infos & Material
1;Preface;6
2;CLABIO 2015 Committees;7
3;CLABIO 2015 CONFERENCE TOPICS;9
4;Speakers;10
5;Sponsors;11
6;Table of Contents;12
7;High Precision System for Bioimpedance Measurement;14
7.1;I. INTRODUCTION;14
7.2;II. HARDWARE;14
7.3;III. FAST ALGORITHM FOR BIO-IMPEDANCE MEASUREMENT;15
7.4;IV. EXPERIMENT RESULTS;16
7.5;V. CONCLUSION;17
8;Effects of Head Model Inaccuracies on Regional Scalp and Skull ConductivityEstimation Using Real EIT Measurements;18
8.1;I. INTRODUCTION;18
8.2;II. METHODS;19
8.3;III. RESULTS;20
8.4;IV. DISCUSSION;20
8.5;V. CONCLUSIONS;21
9;Electrolytic Extracellular Phantom to Study the Low-Frequency Conductivityof Cervical Neoplasia;22
9.1;I. INTRODUCTION;22
9.2;II. MATERIALS AND METHODS;22
9.3;III. RESULTS AND DISCUSSION;23
9.4;IV. CONCLUSIONS;23
10;Bone Electrical Impedance and Tomographic Reconstructionof Fracture Detection: A Review;25
10.1;I. INTRODUCTION;25
10.2;II. LONG BONE FRACTURE;25
10.3;III. THE ABERBEEN IMPEDANCE IMAGING SYSTEM;26
10.4;IV. REVIEW OF EIT APPLIED TO BONE;27
10.5;V. ANALYSIS OF THE RESULTS 2 DECADES LATER;27
10.6;VI. POSSIBLE APPLICATION AND IMPROVEMENTS;28
10.7;VII. DISCUSSION AND CONCLUSIONS;28
11;Audio Codec and Digital Signal Processor for an ElectricalImpedance Tomography System;29
11.1;I. INTRODUCTION;29
11.2;II. SYSTEM DESCRIPTION;30
11.3;III. RESULTS;31
11.4;IV. CONCLUSION;31
12;Segmental Electrical Bioimpedance Measurementswith a Single Lead (Electrode) Displacement;33
12.1;I. INTRODUCTION;33
12.2;II. MATERIALS AND METHODS;34
12.3;III. RESULTS;35
12.4;IV. DICUSSION;35
12.5;V. CONCLUSION;36
13;An Alternative Electrical Impedance Myography Technique for Assessmentof Local Muscular Fatigue;37
13.1;I. INTRODUCTION;37
13.2;II. METHODS;37
13.3;III. RESULTS;39
13.4;IV. DISCUSSION;40
13.5;V. CONCLUSION;40
14;In Vitro Luminal Measurements of Colon Electrical Impedance in Rabbits;41
14.1;I. INTRODUCTION;41
14.2;II - MATERIAL AND METHODS;42
14.3;III - RESULTS;42
14.4;IV. DISCUSSION;42
14.5;V - CONCLUSIONS;43
15;Assessment of Systolic Heart Function byWavelet Analysisof the Impedance Cardiogram;45
15.1;I. INTRODUCTION;45
15.2;II. MEASUREMENTS AND ITS PROCESSINGALGORITHM;46
15.3;III. RESULTS;47
15.4;IV. CONCLUSIONS;48
16;Impedance-Based Monitoring for Tissue Engineering Applications;49
16.1;I. INTRODUCTION;49
16.2;II. MONITORING TISSUE ENGINEERING PROCESSES;50
16.3;III. CONCLUSIONS;51
17;Total Body Water (TBW) for Body Composition Assessmentin Young Adult Females from Colombia;53
17.1;I. INTRODUCTION;53
17.2;II. MATERIALS AND METHODS;53
17.3;III. RESULTS;54
17.4;IV. DISCUSSION;55
17.5;V. CONCLUSIONS;56
18;Electrical Properties of Normal Cervical Human Cells in Suspension:The Relation between Normal Tissue and Electrical Impedance Spectrum;57
18.1;I. INTRODUCTION;57
18.2;II. MATERIALS AND METHODS;57
18.3;III. RESULTS AND DISCUSSION;58
18.4;IV. CONCLUSIONS;59
19;Analog Front-End for the Integrated Circuit AD5933Used in Electrical Bioimpedance Measurements;61
19.1;I. INTRODUCTION;61
19.2;II. METHODOLOGY;61
19.3;III. RESULTS;62
19.4;IV. DISCUSSIONS;63
20;Impedance Analysis for Medical and Electrochemical ApplicationsUsing a Low Cost Instrumentation;65
20.1;I. INTRODUCTION;65
20.2;II. MODELLING;65
20.3;III. INSTRUMENTATION STRUCTURE;66
20.4;IV. EXPERIMENTAL RESULTS;67
21;Low-Cost Body Impedance Analyzer for Healthcare Applications;69
21.1;I. INTRODUCTION;69
21.2;II. METHODOLOGY;70
21.3;III. RESULTS;71
21.4;IV. DISCUSSIONS;72
21.5;V. CONCLUSION;72
22;Development of Portable Device to Measure Respiratory ActivityBased on Impedance Pneumography;73
22.1;I. INTRODUCTION;73
22.2;II. IMPEDANCE PNEUMOGRAPHY;73
22.3;III. HARDWARE IMPLEMENTATION;74
22.4;IV. SIGNAL ACQUISITION AND VALIDATION;75
22.5;V. DISCUSSION AND CONCLUSIONS;76
23;Signal Processing Architecture for Electrical Tomography Impedance;77
23.1;I. INTRODUCTION;77
23.2;II. PROPOSED ARCHITECTURE;77
23.3;III. RESULTS AND DISCUSSION;79
23.4;IV. CONCLUSION;80
24;In vivo Electrical-Impedance Spectroscopy (EIS) Readings in the Human Rectum;81
24.1;I. INTRODUCTION;81
24.2;II. MATERIALS AND METHODS;81
24.3;III. RESULTS;82
24.4;IV. DISCUSSION;83
24.5;V. CONCLUSIONS;83
25;Correlation between Algometry and Electrical Bioimpedance in Subjectswith and without Fibromyalgia;85
25.1;I. INTRODUCTION;85
25.2;II. MATERIALS AND METHODS;85
25.3;III. RESULTS;86
25.4;IV. DISCUSSION;87
25.5;V. CONCLUSION;87
26;Use of Bioimpedance Method to Quantify Changes in Left Ventricular Contractilityin Experiments on Anesthetized Rats;89
26.1;I. INTRODUCTION;89
26.2;II. METHODS;89
26.3;III. RESULTS;90
26.4;IV. DISCUSSION;91
26.5;V. CONCLUSIONS;92
27;Evaluation of the Heath-Carter Somatotype Revisited: New BioimpedanceEquations for Children and Adolescents;93
27.1;I. INTRODUCTION;93
27.2;II. SUBJECTS AND METHODS;93
27.3;III. RESULTS;94
27.4;IV. CONCLUSIONS;96
28;Author Index;97
29;Keyword Index;98
