PEMF and Anti-Aging
Scientific Study
How Pulsed electromagnetic fields (PEMF) promote longevity and reduce the rate of aging
Author: Dr. William Pawluk
At the cellular level, aging is a process of declining capacity for the repair of cell injury. With aging there is cumulative, unrepaired natural or unnatural cell injury. Cell injury results when cells can no longer adapt to stress have unrecoverable exposure to damaging agents suffer from intrinsic abnormalities, whether genetic or nutrient-based.
Cell injury can progress from milder reversible states through more severe irreversible conditions leading to tissue and or organ failure of varying degrees,
Promoting longevity requires intervention of the underlying causal conditions of cell injury where possible and facilitating cell recovery and repair at the earliest stages of cell injury.
Aging can be slowed or reversed by ongoing health maintenance, whole nutritional food, clean air and water, sunshine and the proactive use of low intensity, low frequency PEMF's.
PEMF's improve the rate of aging by reducing and/or reversing various degrees of cell injury.
PEMF's are known to pass uninhibited through the body, while inducing charge in cells and tissues, consequently affecting biochemical and physiologic processes in the direction of reducing cell injury, and therefore aging.
PEMF's improve biochemical activity at the cellular level and allow Macro and Micro nutrients and other life extending chemistry in the body to migrate more freely to be more functionally useful.
With approximately 70 trillion cells in an adult body, cell injury is common and repair is ongoing.
Cell injury results when cells are:
stressed so that they are no longer able to adapt when cells are exposed to damaging agents or suffer from intrinsic abnormalities
The normal cell has a narrow range of function and structure. It handles physiologic demands, maintains a balanced state called homeostasis. Adaptations are reversible functional and
structural responses to more severe physiologic stresses. With adaptation, new but altered steady states still happen, allowing the cell to survive and continue to function.
Cell Injury results when:
the limits of adaptive responses of cells are exceeded or if cells are exposed to injurious agents or stress are deprived of essential nutrients, or become compromised by mutations that affect essential cellular constituents
For instance, in response to increased hemodynamic loads, the heart muscle becomes enlarged, a form of adaptation, and can even undergo injury. If the blood supply to the myocardium is compromised or inadequate, the muscle first suffers reversible injury, manifested by certain cell changes. If this is not reversed, the cells suffer irreversible injury and die.
All disease starts with micro-molecular or structural alterations in individual cells. Injury to sufficient numbers of cells and to the matrix between cells ultimately leads to tissue and organ injury. The cumulative burden of these unrecovered cells and cell functions, leads to aging. The end results of genetic, biochemical, or structural changes in cells and tissues are functional abnormalities, which lead to clinical manifestations (symptoms and signs) and then may become disease. Cell injury progresses through a reversible stage and may end in cell death.
The hallmarks of reversible injury are;
reduced oxidative phosphorylation with depletion of ATP cellular swelling caused by changes in ion concentrations and water influx mitochondria and cell skeleton alterations and DNA damage
Within limits, the cell can repair these derangements and if the injurious stimulus goes away, can return to normal.
With continuing damage, the injury becomes irreversible, the cell cannot recover and it dies, either through necrosis or apoptosis
The major causes of cell injury are:
Oxygen Deprivation, Physical Agents, Chemical Agents and Drugs, Infectious Agents, Immunologic Reactions, Genetic Derangements and Nutritional imbalance.
Physical agents causing cell injury include mechanical trauma extremes of temperature (burns and deep cold) sudden changes in atmospheric pressure, radiation and electric shock, Mechanical trauma, which we most commonly associate with injury, including sprains, dislocations, muscle tears, fractures, etc., are a fraction of the causes of aging.
Cell injury progresses through various stages, during any of which repair may be possible if adequately facilitated, either naturally or by the application of various treatments. All stresses and noxious influences exert their effects first at the molecular or biochemical level. There is a time lag between the stress and the physical changes of cell injury or death. Persistent or excessive injury, causes cells to pass a nebulous "point of no return" into irreversible injury and cell death.
Let me say it again, cellular or tissue swelling is the first manifestation of almost all forms of injury to cells.
The cell response to injurious stimuli depends on the nature of the injury, its duration, and its severity. The consequences of cell injury depend on the type, state, and adaptability of the injured cell, including nutritional and hormonal status, vulnerability of the cell, eg: to hypoxia, degree of toxic exposure. Any injurious stimulus simultaneously triggers multiple interconnected mechanisms that damage cells.
Treatment and prevention approaches should address multiple mechanisms of cell injury.
Poor natural apoptosis ("too little or too much') can also explain aspects of a wide range of diseases.
Increased apoptosis results in excessive premature cell death causing neurodegenerative diseases, ischemic injury, eg: heart attack or stroke; and the premature death of virus-infected cells. So-called natural aging is contributed to by progressive reductions in many hormones, loss of muscle mass, reductions in GI tract neurons, stomach acid production clouding of lenses, etc. With age there are physiologic and structural alterations in almost all organ systems.
Cellular aging is therefore the progressive accumulation over the years of chronic sublethal cell injury that may or may not lead to cell death but does lead to a diminished capacity of the cell to respond to injury.
PEMF can be used to improve body function and reduce the effects of cell injury.
Low-frequency pulsed electromagnetic fields or PEMF's at the right intensities penetrate through the entire body affecting every cell in their path. Either whole body or smaller more intense PMFs affect all the cells in the body.
The classic effects of PMFs touch almost all aspects of cell injury, especially early in the injury process.
They work to:
reduce edema improve circulation open cell membrane channels increase production of ATP stimulate repair mechanisms, and enhance apoptosis of chronic inflammatory cells.
Only cells that are out of balance are affected by PEMF energy.
There is no other technology that I'm aware of that can with a single modality have both the range and depth of action that clinically directed PMFs can have, with no harm to healthy cells.
Conclusion
Everybody has a least millions of cells in the process of cell injury on a constant, daily basis. Unresolved cell injury, leads to cell death and contributes to and accelerates human aging. PEMF's prevent and reverse cell injury at the earliest stages. PEMF devices support the treatment of many health conditions and is a tool for anti-aging and prolonging a healthier quality of life.Support The Bees
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