Our charged cells and electromagnetism

2025-01-28

Our charged cells and electromagnetism

Lena Gummesson, Neokliniken
2025-01-28
16:31

Every cell in the body has an electrical voltage across its cell membrane, called the resting membrane potential. This means that the inside of the cell is electrically negative relative to the outside. This voltage arises because of differences in the concentration of ions (electrically charged particles) such as sodium (Na⁺) and potassium (K⁺) between the inside and outside of the cell. When there is energy, there is always a field around it that can be measured electrically and magnetically. Healthy cells and electromagnetism follow each other.

The voltage of the cell’s membrane potential (the cell at rest) is usually around -70 millivolts to -90 (mV) in a healthy cell. If the cell is not fit, the charge may be weaker.

Some cells can generate action potentials, which means that the inside of the cell temporarily becomes positive relative to the outside. These cells are electrically excitable and can rapidly change their membrane potential in response to stimuli. Examples are:

Nerve cells (neurons): transmit signals in the nervous system.
Muscle cells: use action potentials to contract (skeletal, cardiac and smooth muscle).
Sensory cells: convert sensory stimuli into electrical signals.
Endocrine cells: regulate hormone release.

Other cells, which cannot generate action potentials, are called non-excitable cells and include most epithelial cells, connective tissue cells and blood cells, which have other roles, such as structural support and metabolism.

The electrical charge of the cell is thus the result of a complex and careful balance between the movements and concentrations of ions. The electrical voltage is vital for the functioning of the nervous system, the rhythm of the heart, muscle work and a range of other biological processes.

Understanding this charge not only gives us insight into how cells work, but also how electrical signals can be disrupted in disease and ageing. The cell is not only a building block of the body, but also a dynamic and electrically charged entity that constantly works to sustain life.

Electromagnetic fields (EMF) and the electromagnetic spectrum

Electrically charged cells create electromagnetic fields by the movement of ions such as sodium, potassium and calcium in and out of the cell membrane, generating electric currents. According to the laws of physics, electric currents always create magnetic fields, and variations in the electric field (as in action potentials) lead to changes in magnetic fields (1).

The resting membrane potential creates electric fields around cells, and when charges move, magnetic fields are generated. The electromagnetic fields around individual cells are very weak. When cells aggregate into tissues and organs and work synchronously, their signals are amplified, making the electromagnetic fields easier to measure. These signals play a crucial role in understanding and monitoring the functions of the heart and brain, for example, and are routinely used in medicine for diagnostics and monitoring.

Heart: The heart’s electrical impulses that control the heartbeat measured by ECG and create measurable magnetic fields that can be measured by magnetocardiography (MCG)(2)
The brain: Brain waves (electrical activity in neurons) can be measured by EEG and generate weak magnetic fields that are measured by techniques such as magnetoencephalography (MEG)(3)

Electromagnetic fields are measured in cycles per second (Hertz, Hz). Frequency and wavelength are inversely proportional: low frequencies have long wavelengths and propagate with lower energy, while high frequencies have short wavelengths and higher energy. Biological processes generate low-frequency fields with localized effects. See image below.

Electromagnetic frequencies in frequency therapies

The Earth has natural electromagnetic frequencies, the best known of which is the Schumann resonance of about 7.83 Hz. It occurs between the Earth’s surface and the ionosphere due to lightning strikes and is part of the Earth’s electromagnetic environment. The resonance is linked to biological rhythms and brain waves, making it important in health and biological research(4).

If we map the most common frequency therapies into the electromagnetic spectrum (see figure below), we can place bioresonance and PEMF (pulsed electromagnetic fields) in the lowest fields where bioresonance is most often active in spectra between 1-9 Hz and PEMF clinical application is usually between 3-100 Hz but can start as low as 0.6 Hz(5).

Photobiomodulation (PBM), i.e. frequency therapy with visible and invisible infrared light, moves much higher up the spectrum with higher energy and shorter wavelengths.

Frequency therapy with sound is relatively low but broad in the electromagnetic field. From the inaudible (infrasound) to the audible sound range between 20 Hz and 20 000 Hz. A common form of sound therapy using inaudible infrasound is so-called binaural beats used to influence our brainwaves, which range from 1-100 Hz (most commonly 1-40 Hz). This is achieved by presenting two different tones through headphones in each ear where the frequency differences between them create this low frequency inaudible sound frequency.

Another form of sound therapy is the nine Solfeggio frequencies (between 174-963 Hz) where the 528 Hz frequency in a recent study showed healing effects down to the DNA level (6)

In future articles, we will delve a little deeper into some of the frequency therapies we touched on above.

Metatron bioresonance diagnostics from an electromagnetic perspective

The main focus of the Neoclinic is bioresonance with Metatron NLS diagnostics. The difference between bioresonance and other frequency therapies is that bioresonance can also diagnose and transmit the very specific frequencies needed in the individual case. Other frequency therapies create general healing frequencies and are great complements.

Bioresonance is based on the fact that each cell, tissue and organ in the body emits a unique electromagnetic frequency, sometimes called a ‘vibrational signature’. These frequencies are found in the extremely low frequency (ELF) spectrum of the electromagnetic scale.

Metatron uses these electromagnetic frequencies to identify pathologies, bacteria and toxins by analyzing the eddy magnetic fields of biological objects. This method makes it possible to diagnose the state of the body by tracking changes in the wave properties of tissues.

Eddy magnetics arise from the movement of electric charges and changes in magnetic fields. The wave properties of tissues describe how they are affected by and interact with different types of waves, such as electromagnetic waves, sound waves and mechanical waves and are important in medical diagnostics (e.g. ultrasound and MRI) and treatments (e.g. frequency therapies and lasers).

Via trigger sensors placed at the temples, Metatron connects to subcortical parts of the brain via electromagnetic waves. The deep brain structures that regulate autonomic functions and the body’s internal signaling and contain important information about an organism’s internal processes. This ‘readout ‘ is processed by a microprocessor and transmitted to the computer. The signals are compared to a reference database of ‘healthy’ and ‘diseased’ frequency patterns to identify imbalances.

When imbalances are identified, the system can send back specific frequencies that match the body’s needs to restore balance. Frequencies that stimulate the body’s natural healing processes by influencing the electromagnetic activity of the cell(7)

Frequencies can be very effective because dysfunction in the body occurs when cells, tissues and organs vibrate at abnormal frequencies. Healing frequencies restore balance by correcting these abnormalities.