nonalert brain wave patterns

Marks on the readout of EEG instruments showing patterns associated with non-attention of the subject

(See also: Nonalert brain wave patterns, Body Mind and Soul)

patterns

The style of the lines made on the EEG printouts during biofeedback work, caused from the many levels of brain wave consciousness with variations and similarities so as to categorize a scale of these patters for the future

(See also: Patterns, Body Mind and Soul)

In 1924, the German psychiatrist Hans Berger connected a couple of electrodes (small round discs of metal) to a patient's scalp and detected a small current by using a delicate galvanometer. During the years 1929-1938 he published 14 reports about his studies of EEGs, and much of our modern knowledge of the subject, especially in the middle frequencies, is due to his research (Kaiser 2005). Berger analyzed EEGs qualitatively, but in 1932 G. Dietsch applied Fourier analysis to seven records of EEG and became the f ...

See also:

Neurofeedback, Neurofeedback - History and application, Neurofeedback - Low Energy Neurofeedback System LENS, Neurofeedback - Scientologists Parapsychologists and Less Mainstream Users of Neurofeedback

Read more here: » Neurofeedback: Encyclopedia II - Neurofeedback - History and application

The diagnosis of epilepsy requires the presence of recurrent, unprovoked seizures; accordingly, it is usually made based on the medical history. EEG, brain MRI, SPECT, PET, and magnetoencephalography may be useful to discover an etiology for the epilepsy, discover the affected brain region, or classify the epileptic syndrome, but these studies are not useful in making the initial diagnosis. Long-term video-EEG monitoring for epilepsy is the gold standard for diagnosis, but it is not routinely employed owing to its high cost and inconvenience. It is, however, sometimes used to distinguish psychogenic ...

See also:

Epilepsy, Epilepsy - Causes, Epilepsy - Diagnosis, Epilepsy - Types of seizure, Epilepsy - Seizure syndromes, Epilepsy - Treatment, Epilepsy - Responding to a seizure, Epilepsy - Pharmacologic treatment, Epilepsy - Surgical Treatment, Epilepsy - Other Treatment, Epilepsy - History and Stigma, Epilepsy - Legal implications, Epilepsy - Important investigators of epilepsy

Read more here: » Epilepsy: Encyclopedia II - Epilepsy - Diagnosis

Historically four major types of continuous rhythmic sinusoidal EEG waves are recognized (alpha, beta, delta and theta). There is no precise agreement on the frequency ranges for each type. Delta is the frequency range up to 4 Hz and is often associated with the very young and certain encephalopathies and underlying lesions. It is seen in deep sleep. Theta is the frequency range from 4 Hz to 8 Hz and is associated with drowsiness, childhood, adolescence and young adulthood. This EEG frequency can sometimes be ...

See also:

Electroencephalography, Electroencephalography - Methods, Electroencephalography - Wave types, Electroencephalography - History, Electroencephalography - Notes

Read more here: » Electroencephalography: Encyclopedia II - Electroencephalography - Wave types

There are numerous fields that require the use of estimation theory. Some of these fields include (but by no means limited to): Medicine Clinical trials Imaging: CAT EEG EKG/ECG MRI Medical ultrasonography Opinion polls Quality control Radar, sonar Localization of objects Telecommunications Channel parameters Noise variance DC gain (see example below) See also:

Estimation theory, Estimation theory - Fields that use estimation theory, Estimation theory - Estimation process, Estimation theory - Basics, Estimation theory - Estimators, Estimation theory - Example: DC gain in white Gaussian noise, Estimation theory - Maximum likelihood, Estimation theory - Cramér-Rao lower bounds, Estimation theory - Books

Read more here: » Estimation theory: Encyclopedia II - Estimation theory - Fields that use estimation theory

Headaches can serve as warning signals of more serious disorders. This is particularly true for headaches caused by traction or inflammation. When an underlying cause is suspected for the headache, further diagnostic tests will be done. A test called an electroencephalogram (EEG) may be given to measure brain activity. EEGs can indicate a malfunction in the brain, but they cannot usually pinpoint a problem that might be causing a headache. A physician may suggest that a patient with unusual headaches undergo a computed tomographic (CT) scan ...

See also:

Headache, Headache - Pathophysiology, Headache - Types, Headache - Causes, Headache - Diagnosis, Headache - Treatment

Read more here: » Headache: Encyclopedia II - Headache - Diagnosis

There have also been experiments in humans utilizing modern invasive and non-invasive neuroimaging technologies as interfaces. The most commonly studied potential interface for humans has been electroencephalography (EEG), mainly due to its fine temporal resolution, ease of use, portability, and cost of set-up. However practical use of EEG as a BCI requires a great deal of user training and is highly susceptible to noise. In 2004 scientists of the Fraunhofer Society utilized neural networks to shift the learning phase from the user to the co ...

See also:

Brain-computer interface, Brain-computer interface - Neuroprosthetics, Brain-computer interface - BCIs in monkeys, Brain-computer interface - Human BCI research, Brain-computer interface - Practical BCIs, Brain-computer interface - Theme in fiction

Read more here: » Brain-computer interface: Encyclopedia II - Brain-computer interface - Human BCI research

The diagnosis of epilepsy requires the presence of recurrent, unprovoked seizures; accordingly, it is usually made based on the medical history. EEG, brain MRI, SPECT, PET, and magnetoencephalography may be useful to discover an etiology for the epilepsy, discover the affected brain region, or classify the epileptic syndrome, but these studies are not useful in making the initial diagnosis. Long-term video-EEG monitoring for epilepsy is the gold standard for diagnosis, but it is not routinely employed owing to its high cost and inconvenience. It is, however, sometimes used to distinguish psychogenic ...

See also:

Epilepsy, Epilepsy - Diagnosis, Epilepsy - Causes, Epilepsy - Normal provocants, Epilepsy - Types of seizure, Epilepsy - Seizure syndromes, Epilepsy - Treatment, Epilepsy - Responding to a seizure, Epilepsy - Pharmacologic treatment, Epilepsy - Surgical Treatment, Epilepsy - Other Treatment, Epilepsy - History and Stigma, Epilepsy - Legal implications, Epilepsy - Important investigators of epilepsy, Epilepsy - Notes and references

Read more here: » Epilepsy: Encyclopedia II - Epilepsy - Diagnosis

The recording is obtained by placing electrodes on the scalp, usually after preparing the scalp area by light abrasion and application of a conductive gel to reduce impedance. Each electrode is connected to an input of a differential amplifier (one amplifier per pair of electrodes), which amplifies the voltage between them (typically 1,000–100,000 times, or 60–100 dB of voltage gain), and then displays it on a screen or inputs it to a computer. The amplitude of the EEG is about 100 µV when measured on the scalp, and about ...

See also:

Electroencephalography, Electroencephalography - Methods, Electroencephalography - Wave types, Electroencephalography - History, Electroencephalography - Notes

Read more here: » Electroencephalography: Encyclopedia II - Electroencephalography - Methods

One variety of biofeedback is EEG feedback, which uses electrodes placed on the scalp to garner information about the user's brainwaves. This type of biofeedback is discussed in the article neurofeedback. Other types of biofeedback include the following: electromyogram biofeedback, which uses sensors and electrodes to measure muscle tension, and which is used to treat stress-related illnesses, such as asthma and ulcers galvanic skin tension biofeedback, which measures the minute activities of sweat glands and whi ...

See also:

Biofeedback, Biofeedback - Origins of biofeedback, Biofeedback - Types of biofeedback, Biofeedback - Criticisms, Biofeedback - Possible beneficial side effects

Read more here: » Biofeedback: Encyclopedia II - Biofeedback - Types of biofeedback

Biofeedback:

A general term for techniques that involve giving a person information about their current physiological state (e.g., heart rate, EEG). Biofeedback is used to enable people to control consciously their physiological processes.

(See also: Biofeedback, Psychic, Psychic Dictionary, Parapsychology, Parapsychology Dictionary)

Bioelectromagnetics - Calcium efflux. Bioelectromagnetics - Neurotransmitter systems. Bioelectromagnetics - DNA strand breaks and genotoxicity. Bioelectromagnetics - Ornithine decarboxylase. Bioelectromagnetics - Melatonin. Bioelectromagnetics - Bacterial growth and metabolism. ...

See also:

Bioelectromagnetics, Bioelectromagnetics - Introduction: general features of observed interactions, Bioelectromagnetics - Thermal vs nonthermal nature, Bioelectromagnetics - Noise-masking time and space integration cooperativity, Bioelectromagnetics - Intrinsic fields, Bioelectromagnetics - Natural fields, Bioelectromagnetics - Primary interaction mechanisms, Bioelectromagnetics - Membrane polarization, Bioelectromagnetics - Electrorotation, Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance, Bioelectromagnetics - Nonlinear kinetics, Bioelectromagnetics - Frohlich-style macro dipole interactions, Bioelectromagnetics - DNA conduction, Bioelectromagnetics - Microtubule waveguides, Bioelectromagnetics - Ferromagnetic domains, Bioelectromagnetics - Frequency selectivity from spatial features, Bioelectromagnetics - Effects on the level of a cell or below, Bioelectromagnetics - Calcium efflux, Bioelectromagnetics - Neurotransmitter systems, Bioelectromagnetics - DNA strand breaks and genotoxicity, Bioelectromagnetics - Ornithine decarboxylase, Bioelectromagnetics - Melatonin, Bioelectromagnetics - Bacterial growth and metabolism, Bioelectromagnetics - Effects on the level of an organ or system, Bioelectromagnetics - Blood-brain barrier permittivity, Bioelectromagnetics - EEG changes, Bioelectromagnetics - Wound healing regeneration and bone growth, Bioelectromagnetics - Cancer promotion, Bioelectromagnetics - Whole-organism effects, Bioelectromagnetics - Electrical sensing organs fish etc, Bioelectromagnetics - Navigation bees pidgeons etc, Bioelectromagnetics - Effects on embryonic development, Bioelectromagnetics - Behavioral effects, Bioelectromagnetics - Effects of artificial fields, Bioelectromagnetics - Powerlines, Bioelectromagnetics - CRTs, Bioelectromagnetics - Cell phones, Bioelectromagnetics - Radar, Bioelectromagnetics - Other transmitters radio TV ..., Bioelectromagnetics - Medical applications, Bioelectromagnetics - Bone fracture healing, Bioelectromagnetics - TMS and related, Bioelectromagnetics - Low-level Laser Therapy LLLT, Bioelectromagnetics - Strong magnetic pulses for disinfection, Bioelectromagnetics - Other

Read more here: » Bioelectromagnetics: Encyclopedia II - Bioelectromagnetics - Effects on the level of a cell or below

Bioelectromagnetics - Powerlines. Bioelectromagnetics - CRTs. Bioelectromagnetics - Cell phones. Bioelectromagnetics - Radar. Bioelectromagnetics - Other transmitters radio TV .... ...

See also:

Bioelectromagnetics, Bioelectromagnetics - Introduction: general features of observed interactions, Bioelectromagnetics - Thermal vs nonthermal nature, Bioelectromagnetics - Noise-masking time and space integration cooperativity, Bioelectromagnetics - Intrinsic fields, Bioelectromagnetics - Natural fields, Bioelectromagnetics - Primary interaction mechanisms, Bioelectromagnetics - Membrane polarization, Bioelectromagnetics - Electrorotation, Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance, Bioelectromagnetics - Nonlinear kinetics, Bioelectromagnetics - Frohlich-style macro dipole interactions, Bioelectromagnetics - DNA conduction, Bioelectromagnetics - Microtubule waveguides, Bioelectromagnetics - Ferromagnetic domains, Bioelectromagnetics - Frequency selectivity from spatial features, Bioelectromagnetics - Effects on the level of a cell or below, Bioelectromagnetics - Calcium efflux, Bioelectromagnetics - Neurotransmitter systems, Bioelectromagnetics - DNA strand breaks and genotoxicity, Bioelectromagnetics - Ornithine decarboxylase, Bioelectromagnetics - Melatonin, Bioelectromagnetics - Bacterial growth and metabolism, Bioelectromagnetics - Effects on the level of an organ or system, Bioelectromagnetics - Blood-brain barrier permittivity, Bioelectromagnetics - EEG changes, Bioelectromagnetics - Wound healing regeneration and bone growth, Bioelectromagnetics - Cancer promotion, Bioelectromagnetics - Whole-organism effects, Bioelectromagnetics - Electrical sensing organs fish etc, Bioelectromagnetics - Navigation bees pidgeons etc, Bioelectromagnetics - Effects on embryonic development, Bioelectromagnetics - Behavioral effects, Bioelectromagnetics - Effects of artificial fields, Bioelectromagnetics - Powerlines, Bioelectromagnetics - CRTs, Bioelectromagnetics - Cell phones, Bioelectromagnetics - Radar, Bioelectromagnetics - Other transmitters radio TV ..., Bioelectromagnetics - Medical applications, Bioelectromagnetics - Bone fracture healing, Bioelectromagnetics - TMS and related, Bioelectromagnetics - Low-level Laser Therapy LLLT, Bioelectromagnetics - Strong magnetic pulses for disinfection, Bioelectromagnetics - Other

Read more here: » Bioelectromagnetics: Encyclopedia II - Bioelectromagnetics - Effects of artificial fields

As a young man Walter was greatly influenced by the work of the famous Russian physiologist Ivan Pavlov. He visited the lab of Hans Berger, who invented the electroencephalograph, or EEG machine, for measuring electrical activity in the brain. Walter produced his own versions of Berger's machine with improved capabilities, which allowed it to detect a variety of brain wave types ranging from the h ...

See also:

William Grey Walter, William Grey Walter - Overview, William Grey Walter - Walter's work on brain waves, William Grey Walter - The tortoises, William Grey Walter - Books and articles, William Grey Walter - Source

Read more here: » William Grey Walter: Encyclopedia II - William Grey Walter - Walter's work on brain waves

Biofeedback

A scientific technique to tune into and consciously control bodily functions through the use of EEG (electroencephalographic) feedback instruments to monitor brain waves and skin resistance with the goal of modification of brain waves. and feeds that information back to the user.

Participants can learn to control heart rates or generate brain wave activity (alpha, beta, and delta) at will to induce altered states of consciousness. Enhances the capacity for relaxation and/or inducing meditative states and physiological control similar to that in yoga and Zen.

(See also: Biofeedback, New Age Spirituality, Body Mind and Soul)

Many surgeons lay a temporary shunt to ensure blood supply to the brain during the procedure. Some recommend neuromonitoring with electroencephalography (EEG) throughout the procedure. The internal, common and external carotid arteries are clamped, the lumen of the internal carotid artery is opened, and the atheromatous plaque substance removed. The artery is closed, hemostasis achieved, and the overlying layers closed. ...

See also:

Carotid endarterectomy, Carotid endarterectomy - Procedure, Carotid endarterectomy - Indications, Carotid endarterectomy - Contra-indications, Carotid endarterectomy - Complications, Carotid endarterectomy - Reference, Carotid endarterectomy - External link

Read more here: » Carotid endarterectomy: Encyclopedia II - Carotid endarterectomy - Procedure

Bioelectromagnetics - Thermal vs nonthermal nature. Most of the molecules that make up the human body interact only weakly with electromagnetic fields (EMF) that are in the radiofrequency or extremely low frequency bands. One basic interactiion is the absorption of energy from the EMF, which can cause tissue to heat up; more intense field exposures will produce greater heating. This heat deposition can lead to biological effects ranging from discomfort to protein denaturation to burns. Many nations and regulatory ...

See also:

Bioelectromagnetics, Bioelectromagnetics - Introduction: general features of observed interactions, Bioelectromagnetics - Thermal vs nonthermal nature, Bioelectromagnetics - Noise-masking time and space integration cooperativity, Bioelectromagnetics - Intrinsic fields, Bioelectromagnetics - Natural fields, Bioelectromagnetics - Primary interaction mechanisms, Bioelectromagnetics - Membrane polarization, Bioelectromagnetics - Electrorotation, Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance, Bioelectromagnetics - Nonlinear kinetics, Bioelectromagnetics - Frohlich-style macro dipole interactions, Bioelectromagnetics - DNA conduction, Bioelectromagnetics - Microtubule waveguides, Bioelectromagnetics - Ferromagnetic domains, Bioelectromagnetics - Frequency selectivity from spatial features, Bioelectromagnetics - Effects on the level of a cell or below, Bioelectromagnetics - Calcium efflux, Bioelectromagnetics - Neurotransmitter systems, Bioelectromagnetics - DNA strand breaks and genotoxicity, Bioelectromagnetics - Ornithine decarboxylase, Bioelectromagnetics - Melatonin, Bioelectromagnetics - Bacterial growth and metabolism, Bioelectromagnetics - Effects on the level of an organ or system, Bioelectromagnetics - Blood-brain barrier permittivity, Bioelectromagnetics - EEG changes, Bioelectromagnetics - Wound healing regeneration and bone growth, Bioelectromagnetics - Cancer promotion, Bioelectromagnetics - Whole-organism effects, Bioelectromagnetics - Electrical sensing organs fish etc, Bioelectromagnetics - Navigation bees pidgeons etc, Bioelectromagnetics - Effects on embryonic development, Bioelectromagnetics - Behavioral effects, Bioelectromagnetics - Effects of artificial fields, Bioelectromagnetics - Powerlines, Bioelectromagnetics - CRTs, Bioelectromagnetics - Cell phones, Bioelectromagnetics - Radar, Bioelectromagnetics - Other transmitters radio TV ..., Bioelectromagnetics - Medical applications, Bioelectromagnetics - Bone fracture healing, Bioelectromagnetics - TMS and related, Bioelectromagnetics - Low-level Laser Therapy LLLT, Bioelectromagnetics - Strong magnetic pulses for disinfection, Bioelectromagnetics - Other

Read more here: » Bioelectromagnetics: Encyclopedia II - Bioelectromagnetics - Introduction: general features of observed interactions

Bioelectromagnetics - Membrane polarization. Bioelectromagnetics - Electrorotation. Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance. Bioelectromagnetics - Nonlinear kinetics. Bioelectromagnetics - Frohlich-style macro dipole interactions. Bioelectromagnetics - DNA conduction. Bioelectromagnetics - Microtubule waveguides. ...

See also:

Bioelectromagnetics, Bioelectromagnetics - Introduction: general features of observed interactions, Bioelectromagnetics - Thermal vs nonthermal nature, Bioelectromagnetics - Noise-masking time and space integration cooperativity, Bioelectromagnetics - Intrinsic fields, Bioelectromagnetics - Natural fields, Bioelectromagnetics - Primary interaction mechanisms, Bioelectromagnetics - Membrane polarization, Bioelectromagnetics - Electrorotation, Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance, Bioelectromagnetics - Nonlinear kinetics, Bioelectromagnetics - Frohlich-style macro dipole interactions, Bioelectromagnetics - DNA conduction, Bioelectromagnetics - Microtubule waveguides, Bioelectromagnetics - Ferromagnetic domains, Bioelectromagnetics - Frequency selectivity from spatial features, Bioelectromagnetics - Effects on the level of a cell or below, Bioelectromagnetics - Calcium efflux, Bioelectromagnetics - Neurotransmitter systems, Bioelectromagnetics - DNA strand breaks and genotoxicity, Bioelectromagnetics - Ornithine decarboxylase, Bioelectromagnetics - Melatonin, Bioelectromagnetics - Bacterial growth and metabolism, Bioelectromagnetics - Effects on the level of an organ or system, Bioelectromagnetics - Blood-brain barrier permittivity, Bioelectromagnetics - EEG changes, Bioelectromagnetics - Wound healing regeneration and bone growth, Bioelectromagnetics - Cancer promotion, Bioelectromagnetics - Whole-organism effects, Bioelectromagnetics - Electrical sensing organs fish etc, Bioelectromagnetics - Navigation bees pidgeons etc, Bioelectromagnetics - Effects on embryonic development, Bioelectromagnetics - Behavioral effects, Bioelectromagnetics - Effects of artificial fields, Bioelectromagnetics - Powerlines, Bioelectromagnetics - CRTs, Bioelectromagnetics - Cell phones, Bioelectromagnetics - Radar, Bioelectromagnetics - Other transmitters radio TV ..., Bioelectromagnetics - Medical applications, Bioelectromagnetics - Bone fracture healing, Bioelectromagnetics - TMS and related, Bioelectromagnetics - Low-level Laser Therapy LLLT, Bioelectromagnetics - Strong magnetic pulses for disinfection, Bioelectromagnetics - Other

Read more here: » Bioelectromagnetics: Encyclopedia II - Bioelectromagnetics - Primary interaction mechanisms

In the 1920s and 1930s, when practicing as a psychiatrist in Palestine, Velikovsky had a dozen or so of his papers on psychiatry and psychoanalysis published in various German and English-language medical and psychoanalytic journals. Topics included a proposal that epileptic patients could be diagnosed by means of their abnormal EEG readings, and a precocious analysis of Sigmund Freud's own dreams. However, the work for which Velikovsky became best known was developed by him during the early 1940s, whilst living in New York. He summar ...

See also:

Immanuel Velikovsky, Immanuel Velikovsky - Biography, Immanuel Velikovsky - Velikovsky's Theories, Immanuel Velikovsky - The Revised Chronology, Immanuel Velikovsky - Criticism, Immanuel Velikovsky - Books by Velikovsky, Immanuel Velikovsky - Organisations sympathetic to Velikovsky's work:

Read more here: » Immanuel Velikovsky: Encyclopedia II - Immanuel Velikovsky - Velikovsky's Theories

An example of application of ICA algorithms is to EEG recordings of scalp potentials in humans. The electrical signals originating from the brain are quite weak at the scalp, in the microvolt range, and there are larger artifactual components arising from eye movements and muscles. It has been a difficult challenge to eliminate these artifacts without altering the brain signals. ICA is ideally suited to this task, since the brain and the scalp are good volume conductors and to a good approximation, the recordings are different linear mixture ...

See also:

Independent component analysis, Independent component analysis - Definition, Independent component analysis - Mathematical definitions, Independent component analysis - General definition, Independent component analysis - Generative model, Independent component analysis - Identifiability, Independent component analysis - History and background, Independent component analysis - Applications

Read more here: » Independent component analysis: Encyclopedia II - Independent component analysis - Applications

Bioelectromagnetics - Electrical sensing organs fish etc. Bioelectromagnetics - Navigation bees pidgeons etc. Bioelectromagnetics - Effects on embryonic development. Bioelectromagnetics - Behavioral effects. Many subtle, and at times, not-so-subtle effects on behaviour have been reported from exposure to magnetic fields, with a particular focus in research on pulsed magnetic fields. The specific pulseform used appears to be an ...

See also:

Bioelectromagnetics, Bioelectromagnetics - Introduction: general features of observed interactions, Bioelectromagnetics - Thermal vs nonthermal nature, Bioelectromagnetics - Noise-masking time and space integration cooperativity, Bioelectromagnetics - Intrinsic fields, Bioelectromagnetics - Natural fields, Bioelectromagnetics - Primary interaction mechanisms, Bioelectromagnetics - Membrane polarization, Bioelectromagnetics - Electrorotation, Bioelectromagnetics - Ion cyclotron resonance and ion parametric resonance, Bioelectromagnetics - Nonlinear kinetics, Bioelectromagnetics - Frohlich-style macro dipole interactions, Bioelectromagnetics - DNA conduction, Bioelectromagnetics - Microtubule waveguides, Bioelectromagnetics - Ferromagnetic domains, Bioelectromagnetics - Frequency selectivity from spatial features, Bioelectromagnetics - Effects on the level of a cell or below, Bioelectromagnetics - Calcium efflux, Bioelectromagnetics - Neurotransmitter systems, Bioelectromagnetics - DNA strand breaks and genotoxicity, Bioelectromagnetics - Ornithine decarboxylase, Bioelectromagnetics - Melatonin, Bioelectromagnetics - Bacterial growth and metabolism, Bioelectromagnetics - Effects on the level of an organ or system, Bioelectromagnetics - Blood-brain barrier permittivity, Bioelectromagnetics - EEG changes, Bioelectromagnetics - Wound healing regeneration and bone growth, Bioelectromagnetics - Cancer promotion, Bioelectromagnetics - Whole-organism effects, Bioelectromagnetics - Electrical sensing organs fish etc, Bioelectromagnetics - Navigation bees pidgeons etc, Bioelectromagnetics - Effects on embryonic development, Bioelectromagnetics - Behavioral effects, Bioelectromagnetics - Effects of artificial fields, Bioelectromagnetics - Powerlines, Bioelectromagnetics - CRTs, Bioelectromagnetics - Cell phones, Bioelectromagnetics - Radar, Bioelectromagnetics - Other transmitters radio TV ..., Bioelectromagnetics - Medical applications, Bioelectromagnetics - Bone fracture healing, Bioelectromagnetics - TMS and related, Bioelectromagnetics - Low-level Laser Therapy LLLT, Bioelectromagnetics - Strong magnetic pulses for disinfection, Bioelectromagnetics - Other

Read more here: » Bioelectromagnetics: Encyclopedia II - Bioelectromagnetics - Whole-organism effects