Jaakko Malmivuo: Bioelectromagnetism
Recorded at the Ragnar Granit Institute, Autumn 2006.
(Flash, 360x270 pix + 720x540 pix)How to view the video files is found from: "Technical Requirements".
Lecture 1 | ||
Introduction | ||
Intro | Bioelectromagnetism, Main topics, Textbook, Interdisciplinary sciences | |
1.1 - 1.2 | Bioelectromagnetism, Subdivisions of bioelectromagnetism | |
1.3 | Bioelectric phenomena, Generation of bioelectric signals, Importance of bioelectromagnetism, Funny example | |
1.4 | History of bioelectromagnetism, William Gilbert, Jan Swammerdam, Luigi Galvani, Electrotherapy | |
1.4.3 | Hans Christian Ørstedt, Hans Berger - EEG, Magnetocardiogram, Hermann Helmholtz, Nernst equation | |
Lecture 2 | ||
Part I | Anatomical and Physiological Basis of Bioelectromagnetism | |
2 | Nerve and muscle cell, Cell membrane, Motoneuron | |
2.2.3 | Synapse, Striated muscle, Bioelectric function, Response of the membrane potential, Conduction of nerve impulse | |
3 | Subthreshold membrane phenomena, Nernst equation, Electric potential and field, Nernst-Planc equation, Illustration | |
3.3 | The origin of resting voltage, Electric circuit of membrane, Goldman-Hodgkin-Katz equation, Reversal voltage, Transmembrane ion flux | |
Lecture 3 | ||
3 | Subthreshold membrane phenomena, Nernst equation, Goldman-Hodgkin-Katz equation, Transmembrane ion flux | |
3.6 | Cable equation of the axon, Steady state response, Stimulation with step-current, Strength-duration relation | |
4 | Active behavior of the membrane, Voltage clamp method, Space clamp, Voltage clamp | |
4.2.3 | Voltage clamp, Examples, Transmembrane ion flux, Preparation of an axon, Fugu fish | |
4.4 | Hodgin-Huxley model, Parallel conductance model, Voltage clamp experiments, Model for potassium conductance | |
Lecture 4 | ||
4.4 | Hodgkin-Huxley model, Parallel conductance model, Potassium conductance, Model for potassium conductance | |
4.4.4 | Sodium conductance, Model for sodium conductance, A model for channel gating | |
4.4.5 | Hodgin-Huxley equations, Sodium and potassium conductances, Propagating nerve impulse | |
4.5 | Patch clamp method, Current through a single ion channel, Modern understanding of the ionic channels | |
5 | Synapses, receptor cells and brain, Excitatory and inhibitory synapses, Spatial and temporal summation, Electric model of the synapse | |
Lecture 5 | ||
4.4 - 4.5 | Model for potassium and sodium conductances, Nobel Prize 1991, Patch clamp method | |
5 | Synapses, receptor cells and brain, Reflex arch, Division of sensory and motoric functions, Cranial nerves | |
6 | The heart, Anatomy and physiology of the heart, Cross-section video, Striated muscle, Syncytium | |
6.1 | Cardiac cycle, Generation of bioelectric signal, Conduction system, Intrinsic frequency, Electrophysiology of the heart | |
6.2.2 - 6.3 | Total excitation of the isolated human heart, Genesis of the electrocardiogram | |
Lecture 6 | ||
Part II | Bioelectric Sources and Conductors and Their Modeling | |
7 | Volume source and volume conductor | |
7.2 | Bioelectric source and its electric field | |
7.2.2 | Volume source in a homogeneous volume conductor | |
7.3 | The concept of modeling | |
7.4 | The human body as a volume conductor | |
7.5 | Forward and inverse problems | |
Lecture 7 | ||
7.1 - 7.3 | Volume source, Piecewise homogeneous volume conductor, Green's theorem, Dipole | |
Part III | Theoretical Methods in Bioelectromagnetism | |
11 | Solid angle theorem, Double layer, Inhomogeneous double layer, Double layer sources | |
11.4 | Lead Vector, Ohm's Law, lead vector concept, Lead voltage between two measurement points | |
11.4.3 | Einthoven triangle, Burger Model, Variation of the Frank model | |
11.5 | Lead vector, Image surface, Points inside the image surface, Design of orthonormal lead systems | |
Lecture 8 | ||
11.2 | Solid angle theorem, Double layer source, Lead vector | |
11.5 | Image surface, Design of orthonormal lead systems | |
11.6 | Lead field, Sensitivity distribution, Linearity, Superposition | |
11.6.3 | Reciprocity, Hermann von Helmholtz, Historical approach, Electric lead | |
11.6.5 | Ideal lead field, Effect of electrode configuration, Synthesizing an ideal lead field | |
Lecture 9 | ||
11.6 | Review of lead field concept, Sensitivity distribution, Reciprocity and electric lead | |
11.7 | Gabor-Nelson theorem, Summary of the theoretical methods | |
12.1 - 12.2 | Biomagnetism, Equations, Biomagnetic fields | |
12.3 | Reciprocity theorem for magnetic fields, Equations for electric and magnetic leads | |
12.4 - 12.8 | Magnetic dipole moment, Ideal lead field, Synthesization of ideal magnetic lead, Radial and tangential sensitivities | |
Lecture 10 | ||
12.3 | Reciprocity theorem for magnetic fields, Biomagnetic fields repeated | |
12.4 - 12.9 | Magnetic dipole moment, Special properties of magnetic lead fields | |
12.11 | Sensitivity distribution of basic magnetic leads, Magnetometers | |
12.10 | Independence of bioelectric and biomagnetic fields, Helmholtz theorem | |
Part IV | Electric and Magnetic Measurement of the Electric Activity of Neural Tissue | |
IV 13 -13.6 | Electroencephalograpy, EEG lead systems, Behavior of EEG signal | |
14.1, 14.2 | Magnetoencephalography, History, Sensitivity distribution, Axial and planar gradiometers | |
14.3 | Comparison of EEG and MEG half sensitivity, Electrode in the source region | |
14.3, 14.4 | Effect of skull resistivity, Summary. | |
Lecture 11 | ||
Part V | Electric and Magnetic Measurement of the Electric Activity of the Heart | |
15.1 | 12-lead ECG system, Waller, Einthoven | |
15.2 | ECG Signal | |
15.3 - 15.5 | Wilson central terminal, Goldberger leads, Precordial leads | |
15.6, 15.7 | Modifications of the 12-lead system, The information content of the 12 lead system | |
Lecture 12 | ||
16 - 16.2.3 | VCG Lead systems, Uncorrected VCG lead systems | |
16.3 | Corrected VCG Systems, Frank lead system | |
Lecture 13 | ||
16.3.1 | Frank lead system repeated | |
16.3.2 - 16.3.5 | Lead systems: McFee-Parungao, SVEC III, Gabor-Nelson | |
16.4 | Discussion on VCG leads | |
17 - 17.4 | Other lead systems, Moving dipole, Multiple-dipole model, Multipole, Clinical diagnosis | |
17.4 | Summary of models used | |
18 - 18.3 | Distortion factors in ECG, Effect of the inhomogeneities, Brody effect | |
Lecture 14 | ||
18.3 – 18.5 | Brody effect, Direction of ventricular activation, Effect of blood resistivity | |
19 – 19.4 | The basis of ECG diagnosis, The application areas of ECG diagnosis, Electric axis of the heart, Ventricular arrhythmias | |
19.5 – 19.7 | Disorders in the activation sequence, Myocardial ischemia and infarction | |
20 | Magnetocardiography, History, Standard grid | |
Lecture 15 | ||
20.3 | Magnetocardiography, Methods for detecting magnetic heart vector, McFee lead system, XYZ-lead system, ABC-lead system | |
20.4 – 20.6 | Sensitrivity distribution, Generation of MCG signal | |
20.7 | Clinical applications: Fetal MCG, DC-MCG | |
20.7 | General solution for the clinical application, Theoretical aspects, Helmholz's theorem | |
20.7. II | The electromagnetocardiography method (EMCG), Clinical study, Results | |
Lecture 16 | ||
Part VI | Electric and Magnetic Stimulation of Neural Tissue | |
21 | History, Applications, Taser | |
22, VII, 23 | Magnetic stimulation, History, Principle of magnetic stimulation, Distribution of stimulation current | |
Part VII | Electric and Magnetic Stimulation of the Heart | |
23 | Pacemakers | |
24 | Cardiac defibrillation, Mechanism, Defibrillator devices | |
Part VIII | Measurement of the Intrinsic Electric Properties of Biological Tissues | |
25 – 25.3 | Impedance cardiography, Signals, Origin of the impedance signal | |
Lecture 17 | ||
25.3, 25.4 | Impedance cardiography, Signals, Origin of the signal | |
25.4.5 – 25.6 | Accuracy of the impedance cardiography, Other applications of impedance pletysmography | |
26 | Impedance tomography, Measurement methods, Image reconstruction | |
27 | Electrodermal response, Lie detector | |
Part IX | Other Bioelectromagnetic Phenomena | |
28 | The Electric Signals Originating in the Eye, EOG, Electroretinogram | |
Lecture 18 | ||
Summary I | Objectives, Discipline bioelectromagnetism | |
Summary II | Subthreshold membrane phenomena, Nerst equation, Origin of the resting voltage | |
Summary III | Active behavior of the membrane, Voltage clamp, Results | |
Summary IV | Bioelectric sources and conductors, Models | |
Lecture 19 | ||
Summary V | Theoretical methods in bioelectromagnetism, Solid angle theorem, Image surface, Linearity, Superposition, Electric lead |