EEG - ElectroEncephaloGraph or ElectroEncephaloGram
An electroencephalograph is the instrument that generates a record of the electrical activity of the brain by measuring electric potentials using electrodes attached to the scalp.
An electroencephalogram is a graphic record of the electrical activity of the brain as recorded by an electroencephalograph.
EEG is an acronym for both
Electroencephalograph and Electroencephalogram. This is a
recording ("graph") of electrical signals ("electro") from the brain
("encephalo"). They are made on chart paper that moves underneath pens that
are connected to galvanometers that read the electrical signals from electrodes
on the scalp. These electrodes do not send any electricity to the person.
They only receive electrical signals naturally generated by the brain.
Alpha waves are detected at the eight electrode positions indicated in the
diagram. Usually, feedback is generated for the following four positions: O1,
O2, C3, C4. O is for Occipital, C is for Central, F is for Frontal, and T is
for Temporal.
History of the Discovery of the EEG
Richard Caton, a Liverpool physician and medical school lecturer,
discovered electrical brain signals by probing directly on the surface of
exposed brains of animals. He published his results in 1875. Caton
used a reflecting galvanometer which was invented in 1858 by Lord
Kelvin. Small changes in the position of a mirror attached to galvanometer
coils produces a much larger movement of a reflected spot of light. This was a
primitive form of amplification. Such instruments were capable of
measuring micro-amperes.
In 1887, Caton reported to the Ninth International Medical Congress
in Washington, D.C. that when he interrupted light falling on an animal's eye,
he detected negative variations in the electrical activity of the brain. It is
ironic that he had to use a flame because electric light bulbs and electric
power distribution were not yet widespread. He also discovered that electrical
activity occurred in the opposite side of the brain from the eye.
Most physiologists were unaware of Caton's work because they read
scientific journals and he published in medical journals. Adolph Beck
of Poland repeated and republished the work about 15 years after Caton in 1890
in a physiological journal. He went beyond Caton when he found that though a
sensory stimulus such as a flash or a sound clap induced a response at a single
point, there was a brain-wide interruption of the slow even pattern of
waves in the brain. It was not until 1949 that the reticular activating
system of the brain was discovered, which has an important role in
controlling brain state.
Fleischel von Marxow had made a similar discovery and placed the results in
a sealed letter in a vault in 1883, a cowardly way of hedging scientific bets,
as shown by the fact that he did not reveal it until after Beck's results were
published. Marxow's attempt to claim credit was trumped when Caton wrote to
the journal reminding them of his prior publication. A Russian scientist,
Vasili Yakovlevich Danilevsky had made similar experiments in 1876 and
published them in his doctoral thesis in 1877 (two years after Caton). Between
Danilevsky and Beck, Nikolai Y. Wedensky had used a telephone to listen to
electrical waves in the brains of cats and dogs. In 1912, Vladimir
V. Pravdich-Neminsky published photographic recordings of Brain Waves in dogs.
Dr. Hans Berger, an Austrian psychiatrist was the first to record
electroencephalographs from humans. After gaining his doctorate at the
University of Jena in 1897, Berger became aware of Richard Caton's work.
His experiments with animals were inconclusive by 1910, but after World War I
he decided to look for the EEG in the human brain. Though he worked with
primitive instruments such as string galvanometers he was a shy and secretive
man so he did not seek help.
In the early years of the 1920s Berger obtained his first results in
subjects who had skulls with gaps under the skin where bone was missing. He
made recordings on moving photographic paper with a wavy spot of light. This
was how Berger found the regular waves at about 10 cycles per second
that he named the Alpha waves because they were the first waveforms he
isolated in the human EEG.
Berger published a paper in 1929 based on the research he had done
five years earlier with his son Klaus as a subject. He made 73 recordings,
which became the first published EEGs of humans. Berger found that the
best recordings were made with an electrode on the occiput (lower rear of the
skull) and another on the forehead (which functions as a reference). During
the five years, the cautious Berger made recordings from himself and many other
subjects. He wanted to eliminate the possibility that blood circulation
might be creating harmonics in the recordings, so he made many recordings with
simultaneous electrocardiograms and blood pressure from the head. Berger also
eliminated the possibility that the waves originated in the skin by doing some
experiments with electrodes just below the skin with special insulation. In
1929, Berger wrote
"The electroencephalogram represents a continuous
curve with continuous oscillations in which ... one can distinguish larger
first order waves with an average duration of 90 milliseconds and smaller
second order waves of an average duration of 35 milliseconds [Beta waves]. The
larger deflections measure at most 150 to 200 microvolts...."
"We see in the electroencephalogram a concomitant phenomenon of
the continuous nerve processes which take place in the brain, exactly as the
electrocardiogram represents a concomitant phenomenon of the contractions of
the individual segments of the heart."
A year later Berger has accumulated 1,133 recordings from 76 subjects. In
a paper he published that year Berger first named the Alpha and Beta
waves and began to use the initials EEG for ElectroEncephaloGram.
Berger reported that the amplitude of the Beta waves was smaller than Alpha,
despite the fact that he was able to demonstrate that Beta waves were related
to mental concentration and to startle reactions.
In 1931 Berger found that alpha waves diminished during sleep,
during general anesthesia, and during cocaine stimulation. He reported that
the Alpha wave frequency was decreased in patients with high intracranial
pressure resulting from injuries. Berger also found, significantly, that
epileptic patients had large amplitude waves. He also wrote that
Alzheimer's disease and multiple sclerosis altered EEGs. On the other hand
Berger was disappointed to find that many illnesses had little or no obvious
effect on the recorded EEG. These included schizophrenia, melancholia,
manic-depression (bipolar illness), mental retardation, and aphasia (speech
loss). Modern research by Dr. Hardt and others has shown by using a
wider time perspective that integrated amplitude neurofeedback enhancement of alpha and
other Brain Waves has useful
effects for some of these types of sufferers.
The Carl Zeiss Foundation took note of Berger's growing discoveries
and gave him electronic amplifiers and a specially made oscillograph, along
with an assistant. With this sensitive equipment he repeated and replicated
his earlier work. Berger found that an epileptic patient had nearly
flat waves after a seizure but alpha waves slowly increased as consciousness
was regained. He recorded EEGs from young children and infants. Berger found
that Brain Waves began to appear only at about two months of age. This
corresponds to the time when the brain neurons become sheathed in myelin.
For several years, Berger's work was ignored by scientists because many
thought that overall brain wave recordings would just be confused roars and
then because the alpha waves were "dull" regular waves. In 1934 Edgar Adrian
and B.H.C. Matthews of the Cambridge Physiological Laboratory confirmed
Berger's research and published their results in the journal
Brain, where they referenced Berger's work. They used copper gauze
electrodes wrapped in saline soaked lint. They wanted to call the Alpha waves
the Berger rhythm, but Hans Berger was modest and rejected it.
Berger soon became world famous, except in Germany. There Hitler's
regime was oppressing his University of Jena. Thus he was greatly surprised
when in 1937 at an international congress in Paris he found himself celebrated
by researchers from around the world. However on September 30, 1938 he was
forced by Nazi officials to retire the next day. After a series of further
tragedies, Berger committed suicide in 1941. He was twice considered for
the Nobel Prize, but the Nazis prevented it from being awarded and
accepted. By contrast, in England two EEGs labs before the war had grown to 50
by the end because of the usefulness in diagnosing brain injuries.
MEG - MagnetoEncephaloGram
MEG is a new technology that holds great promise because it can detect
Brain Waves deep in the brain. However, if the brain's electrical field is
weak when measured at the scalp, the brain's magnetic field is weaker still,
especially when compared to the earth's magnetic field and motor magnets. It
requires large superconducting magnets, and today that requires liquid gases to
get cold enough.
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