EEG Technology (eBook)
288 Seiten
Elsevier Science (Verlag)
978-1-4831-9216-1 (ISBN)
EEG Technology provides information and advice related to electroencephalography (EEG). The objective and purpose of this book is to learn more about people given that a person's brain is the person, in sickness or in health. This book is organized into eight chapters. This second edition remains almost the same as the previous volume except for some additions in Chapter 1 and reorganization of some chapters. Chapter 4 was revised to reflect the changes in the design of EEG machines; Chapters 5 and 6 were expanded to include more factual description of EEG records; and Chapters 7 and 8 were expanded and extensively revised to reflect major advances in signal analysis procedures. This book will be of interest to people with studies on EEG and those in the medical profession.
Front Cover 1
EEG Technology 4
Copyright Page 5
Table of Contents 6
Foreword 12
Preface to the Second Edition 14
Preface to the First Edition 16
Chapter 1. Origins of the Electroencephalogram 18
1.1. HISTORICAL INTRODUCTION 18
1.2. PHYSICAL STRUCTURE OF THE BRAIN 20
1.3. ELECTRICAL ACTIVITY OF THE BRAIN 22
1.4. RELATION BETWEEN SCALP AND CORTICAL EEG 27
REFERENCES 30
Chapter 2. Electrodes 34
2.1. INTRODUCTION 34
2.2. TYPES OF ELECTRODES 34
2.3. CHLORIDING OF SILVER ELECTRODES 37
2.4. MEASUREMENT OF ELECTRODE RESISTANCE 39
2.5. ELECTRODE CHARACTERISTICS 40
2.6. EQUIVALENT CIRCUIT OF AN ELECTRODE IN A
43
2.7 MEASUREMENT OF
44
2.8. ELECTRODES FOR D.C. RECORDING 47
2.9 ELECTRODES FOR A.C. RECORDING 49
REFERENCES 49
Chapter 3. Connecting Electrodes to Amplifiers 52
3.1. INTRODUCTION 52
3.2. BIPOLAR DERIVATIONS 53
3.3. COMMON REFERENCE DERIVATIONS 56
3.4. COMMON AVERAGE REFERENCE DERIVATIONS 60
3.5. GENERAL QUALIFICATIONS 64
REFERENCES 65
Chapter 4. Recording Systems 66
4.1. INTRODUCTION 66
4.2. CHARACTERISTICS OF THE INPUT CIRCUIT 66
4.3. CHARACTERISTICS OF THE RECORDING
72
4.4. THE FREQUENCY RESPONSE CONTROLS 78
4.5. THE WRITER AND PEN DAMPING EFFECTS 84
4.6. THE 'ELECTRODE-AMPLIFIER' RECORDING
87
4.7. THE OVERALL SYSTEM 87
4.8. TESTING THE RECORDING SYSTEM 90
4.9. FAULT FINDING 95
REFERENCES 97
Chapter 5. Operational Techniques 98
5.1. INTRODUCTION 98
5.2. ELECTRODE PLACEMENT 99
5.3. DESIGN OF MONTAGES 102
5.4. APPLICATION OF ELECTRODES 105
5.5. RECORDING PROCEDURE 107
5.6. EVOCATIVE TECHNIQUES 109
5.7 USE OF OPERATIONAL CONTROLS 113
5.8 ARTEFACTS 115
REFERENCES 124
Chapter 6. Visual Analysis of the EEG 127
6.1. INTRODUCTION 127
6.2. TEMPORAL PATTERNS 127
6.3. SPATIAL PATTERNS 136
6.4. SPATIAL ANALYSIS 140
6.5. DESCRIBING THE EEG RECORD 148
REFERENCES 150
Chapter 7. Special Techniques 152
7.1 USE OF SPECIAL ELECTRODES 152
7.2. RECORDING IN INTENSIVE CARE UNITS 157
7.3. OVERNIGHT SLEEP RECORDING 161
7.4. D.C. RECORDING 164
7.5 RECORDING OF VARIABLES OTHER THAN THE EEG 167
7.6 CONNECTING ANCILLARY EQUIPMENT TO EEG
174
7.7 RECORDING OF EEG SIGNALS ON
176
7.8 RECORDING OF EVOKED RESPONSES 178
7.9 TELEMETRY 196
REFERENCES 201
Chapter 8. EEG Signal Analysis 210
8.1. INTRODUCTION 210
8.2. ANALOGUE AND DIGITAL METHODS 211
8.3. AMPLITUDE MEASURES 214
8.4. MEASUREMENT OF WAVE INDICES 218
8.5. FREQUENCY ANALYSIS—THEORETICAL BASIS 219
8.6. FREQUENCY ANALYSIS—ANALOGUE METHODS 224
8.7. CORRELATION ANALYSIS 234
8.8. FREQUENCY ANALYSIS—DIGITAL 242
8.9. SPATIAL ANALYSIS 248
8.10. PHASE AND TIME DELAY ANALYSIS 254
8.11. SOME OTHER METHODS OF PROCESSING EEG
255
8.12. STATISTICAL TREATMENT OF EEG DATA 262
8.13. CONCLUSION 264
REFERENCES 265
Appendices 274
Appendix A: Preparation of isotonic electrode jelly (from Shackel, 1958) 274
Appendix B: Preparation of bentonite paste (from Taylor, 1969) 274
Appendix C: Calculation of amplitude and timing errors due to arc distortion 275
Appendix D: Binary notation 276
Appendix E: An example of numerical Fourier analysis 278
Appendix F: Factual report 281
Index 286
Origins of the Electroencephalogram
Publisher Summary
This chapter discusses the origins of the electroencephalogram (EEG). It was not until 1929 that Hans Berger published the first report of the EEG of man, as all the early work was done on animals. The chapter also discusses the electrical activity of the brain. Signals from the sense organs to the brain are transmitted along nerve fibers as series of pulses whose pulse recurrence frequency is dependent upon the amplitude of the external stimulus. As these nerve fibers from the receptor organs enter the cerebral cortex there can be profuse branching, so that the incoming pulses are spread over an appreciable area of cortex. The branched fibers do not connect directly into the neurons but terminate on cell bodies and dendrites by means of small swellings called synaptic knobs. The pulses are transmitted from the fibers across the synaptic membranes into the cell structure. Both neurons and nerve fibers are composed mainly of fluid contained within very thin membranes. Progressive transient disturbance of the resting potential along a fiber is used to transmit information from one end to the other.
1.1 HISTORICAL INTRODUCTION
In 1875 Richard Caton, a British physiologist, reported that: ‘Feeble currents of varying direction pass through the multiplier when electrodes are placed on two points of the external surface [of the brain], or one electrode on the grey matter, and one on the surface of the skull.’ Caton was investigating the electrical activity of the brains of cats, monkeys and rabbits using non-polarizable cortical electrodes connected to a galvanometer with optical magnification.
In the years that followed, several workers, some not knowing of Caton’s observations, investigated the electroencephalogram (EEG) of animals and showed changes of spontaneous activity and evoked responses to external stimuli. Considering the equipment available and the knowledge of electricity at that time, the experiments performed were of the highest order and can still be studied with profit. Caton, in 1887, worked with unanaesthetized unrestrained animals with light insulated wires, suspended from an overhead support, connecting the electrodes to the galvanometer. In 1890 Beck, in Poland, used non-polarizable electrodes and backed off the standing potentials with a Daniel cell and rheostat in one side of the galvanometer—no a.c. coupling here! In 1876 Danilevskey, in Kharkov, showed a change of the standing potential of the cortex in response to acoustic stimuli. The development in the 1930s of valve amplifiers with a.c. coupling undoubtedly impeded further study of the changes in steady potentials which the earlier workers had investigated so successfully. Only recently has this interesting aspect of the electrical activity of the brain been re-investigated.
In 1914 Cybulski recorded an epileptic seizure caused by cortical stimulation in a dog. Kaufmann, doing similar experiments in 1910, commented on the great difficulty he had in maintaining electrode contact during the seizure—a not uncommon complaint today! For a full account of these early experiments and scientists the reader is referred to Brazier (1961).
All the early work was done on animals and it was not until 1929 that Hans Berger published the first report of the electroencephalogram of man. Berger, a psychiatrist, working almost in isolation in Jena, had been investigating the EEG for a number of years. He used many different types of electrodes driving string or double coil galvanometers. One of the main reasons for his success, apart from his almost obsessive tenacity, was his working relationship with the neurosurgeons who provided him with patients in whom pieces of skull had been removed. This enabled him to get zinc plated needle electrodes into the epidural tissue very close to the surface of cortex. Although Berger published his first observations in 1929 with one or more papers in each subsequent year until 1938, many of them were ignored until Adrian and Matthews repeated the scalp investigations and published in 1934. Berger’s fourteen reports, with one correction in 1937 in which he reports an error due to 50 Hz mains interference, have been beautifully translated from the German by Gloor (1969). These show the depth of Berger’s work in which polygraphic recordings and evoked responses were studied in 1930, the relative merits of unipolar and bipolar recordings discussed in 1935 and frequency analysis described in 1936!
In much of the early work photography was used to record the deflections of the galvanometer light beam, but this was expensive; many workers had to read off the scale at regular intervals, and then plot the activity. In the 1930s, when the galvanometer was replaced by valve amplifiers with a.c. coupling, the activity was displayed on cathode-ray oscilloscopes and photographed. Pen writers were available in the 1940s and made it possible to have an immediate permanent record. The other great technical advance at this time was the use of the differential amplifier which eliminated much of the interference from external sources (Parr and Walter, 1943).
Since 1940 there has been little change of basic technique; most of the technical effort has been devoted to the construction of reliable multichannel recorders. A return to d.c. recording was achieved in the 1950s using transistor chopper amplifiers, but electrodes still presented a serious limitation to the stability that could be attained. This problem remains with us today (Chapter 2).
1.2 PHYSICAL STRUCTURE OF THE BRAIN
1.2.1 Gross anatomy
The brain consists of two hemispheres, the cerebellum and brainstem. The two hemispheres are separated by the longitudinal fissure across which there is a large connective band of fibres called the corpus callosum. The brainstem is a complex agglomeration of structures including the midbrain, pons medulla and reticular formation. Between the midbrain and cerebral hemispheres is the thalamus which is composed of groups of cells known as nuclei.
The outer surfaces of the cerebral hemispheres are composed of nerve cells (neurones) and form the cerebral cortex. These surfaces are highly convoluted and are separated into regions by a number of fissures (sulci) the largest of which are the Rolandic and Sylvian (Figure 1.1). This complex indentation increases the surface area (and thus the number of neurones) to more than twice that of a smooth sphere of the same size. Beneath the cortex nerve fibres lead to the other parts of the brain and body. Parts of the cortex are concerned with particular functions, for example the occipital region deals with visual information whilst auditory information is processed in the temporal lobe. Some of these regions are shown in Figure 1.1 Because of the colour, the regions composed of neurones, which includes the cerebral cortex, is known as grey matter; fibrous tissue is called white matter.
Figure 1.1 Lateral view of major areas of the brain
1.2.2 Physical structure of tissue
Microscopic examination of brain sections yields information only if the tissue is stained with a dye or with silver. The cerebral cortex then appears as an intricate network of fibres and neurones (Plate I). The white matter is seen to be composed of fibres, each wrapped in an insulating sheath of myelin. Electron-microscopic photographs show that the fibres and neurones are separated by a vast system of glial cells which outnumber the neurones by a factor of 10. All these methods of examination reveal only the physical positions of the fibres, neurones and glia, and not their functional relationships.
Plate I A section of the visual cortex of a cat showing a number of pyramidal neurones (reproduced from Organization of the Cerebral Cortex by D. A. Sholl by courtesy of Methuen)
The average thickness of cortex in man is 2.5 mm, the cortical area is about 2,300 cm2 and the neuronal density about 10 neurones/0001 mm3 (Sholl, 1956). The total number of neurones is about 6 × 109. Although there are several types of neurone, the basic structure is similar to that shown in Figure 1.2 The branch-like dendrites can spread through a considerable volume of cortex. Many neurones are within the dendrites of a single neurone and the number of possible interactions is astronomical.
Figure 1.2 Drawing of a pyramidal neurone from the cortex of a cat (composed from 3 photographs) (reproduced from Organization of the Cerebral Cortex by D. A. Sholl by courtesy of Methuen)
The dendritic structure of a newly-born baby is very sparse but there is rapid growth in the first months of life and this probably accounts for the change of EEG pattern during this period. The ultimate richness and complexity of dendritic connections depend upon the environmental complexity in which an animal—and presumably also a child—is reared. Isolation results in less branching of dendrites than when the animal has been trained in a complex environment (Rosenzweig and colleagues, 1962; Holloway, 1966).
1.3 ELECTRICAL ACTIVITY...
| Erscheint lt. Verlag | 28.6.2014 |
|---|---|
| Sprache | englisch |
| Themenwelt | Sachbuch/Ratgeber ► Gesundheit / Leben / Psychologie ► Krankheiten / Heilverfahren |
| Medizin / Pharmazie ► Medizinische Fachgebiete ► Innere Medizin | |
| Technik ► Bauwesen | |
| ISBN-10 | 1-4831-9216-4 / 1483192164 |
| ISBN-13 | 978-1-4831-9216-1 / 9781483192161 |
| Informationen gemäß Produktsicherheitsverordnung (GPSR) | |
| Haben Sie eine Frage zum Produkt? |
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