If an organelle requires a certain element, the ionic concentration of that element inside the organelle will be very low. As higher concentrations of the needed element traveling through the blood vessels come closer to the cell, the lower concentration in the organelle will cause an attraction of the ions to be transported into the cell until its needs are met. When the organelle receives enough of the necessary elements, the ionic concentrations will become equalized. The ions concentrated in the blood will then repel the equal concentrations within the cell instead of attracting to them. The physics of polarity apply to the supply and demand of essential ionic nutrients regardless if the cell has to expend energy to obtain the required element or if the substance can diffuse itself through the cell membrane.

In the same respect every function and interaction of cellular processes are governed by polarity relationships at the ionic level. If you have two magnets with the same polarity facing each other, the magnets will resist the force being applied. These identical polarities will repel each other. If you hold the reverse polarity of the two magnets close to each other they will quickly join together because opposite polarities attract. This is how the body is able to sense the need and meet the demand for the requirements of the cells.

When the body becomes stressed it interferes with the interrelationship of ionic polarities within cells. This disrupts normal cellular function putting a burden on the cell. In a sense the cell begins to wobble or lose its spin. It becomes difficult to complete usually seamless interactions slowing cellular response and interrupting regular production. Some stress can even block the intake of vital substances. The imbalance of internal polarity will also begin to change the normal polarity of the cell itself. This in turn will affect the relationship the cell has to other cells around it causing an abnormal attraction or repelling of other cells. If the same condition occurs in nearby cells the problem becomes amplified affecting the overall histology of the tissue.

When cells become unusually polarized with opposite polarities they will attract together causing a condition of constricted histology within the tissue. If cells constrict together too tightly they can inhibit the supply of blood through the vessels, interfere with nerve communication and prevent the elimination of waste products from being removed through lymph vessels. The body may separate the affected tissue by encapsulating these cells inside a protein sac. When this disorder is discovered within the body it is referred to as a cyst, polyp or tumor.

When cells become unusually polarized with the same polarities they will repel each other causing a condition of dilated histology. In this situation the cells can push themselves so far apart they may no longer be close enough to blood vessels and nerve supply to get the needed nutrients or appropriate signals to and from the nervous system. Waste products will begin to accumulate around the cells if lymph vessels are too far away to properly remove cellular waste. This type of cellular histology is related to dysfunctions associated to atrophy (loss of movement or energy) within affected tissues in the body.

These polarity dysfunctions cause the cells to lose their vitality creating imbalance and disharmony within the cell. Left unresolved the body will not be able to maintain normal levels of functional health and wellness. This is how the effects of stress can lead to lack of energy, fatigue, pain syndromes, illness and disease. Resolving polarity relationships within the cell will revitalize cell function and performance allowing the body to resume its normal processes.