Testing receptors is the prerogative of only those who are completely free of foreign radiation as discussed in the previous chapter.

Position While Testing

The tester must stand on level ground with feet apart, spine held erect and his body positioned so it is not aligned to the direction of his Vivaxis, in any of the four channelling positions. His clothing must not touch or ground against any furniture or other objects. He must remember, too, that if his Vivaxis is at a level above him he will keep a container of ice or acid (such as vinegar) between his feet in order to use his left index finger as the receiving finger.

It is reasonable to assume that each receptor has imprinted upon its wave pattern, characteristics that identify it with the particular magnetic position it occupies in the head or body with relation to the centre of magnetic influence. Further, as each receptor represents either a gland, organ, limb, etc., the chemistry associated with an individual part of the body produces an intricate characteristic, which is also inherent in the wave pattern of its receptor.

An example, analogous in many respects, was observed while attending a demonstration of atomic absorption. A sample of fluid was put into a complex electronic machine and each element in the fluid, magnesium, copper, calcium, etc., had an identifying characteristic wave. Through wave interpretation the machine's computer recorded each element within the sample.

As we have previously mentioned in the testing of receptors, the tip of the left index fingernail is placed directly over the receptor to be tested while taking care not to exert any pressure on the receptor itself. The recording instrument, the angle wire, is held correctly (see Photo) in the right hand to record the wave pattern transferred from the receptor into the atomic structure of the wire. This instrument, under the influence of the wave pattern, responds by moving in a horizontal plane to a definite channel. The direction of the channel is determined by several factors;

1. The position of the receptor on the head in relation to the centre of magnetic influence,

2. The direction the tester is standing in relation to his own Vivaxis,

3. The energy stimulation due to motion, voluntary or involuntary, e.g., moving a limb or the beating of the heart.

Brain Receptor

There are numerous brain receptors strategically located throughout different parts of the head. It is the only type of receptor that is stimulated by using the mind to solve mathematical exercises, such as a simple problem in multiplication; therefore, we use this characteristic to help identify it. For example, the tester holds his left index finger to the site of a receptor on the head which may or may not be a brain receptor. In order to determine if it is, he creates an energy wave by silently concentrating his mind upon a multiplication table; immediately all brain receptors are stimulated. If his finger is over a brain receptor the recording wire alternates back and forth in the horizontal plane, orientated in the direction of his Vivaxis. The instant he stops multiplying the brain receptor ceases to be stimulated and consequently the wire terminates its motion.

If there is no well-defined alternating motion of the recording wire while he multiplies, then it is not a brain receptor. It is essential the tester concentrates in silence and without moving to prevent receptors associated with the ears and limbs from becoming stimulated which may lead to wrong identification.

Brain receptors relaying a wave message to a movable segment of the body.

Each movable part of the body is controlled by specific brain receptors. In contrast to the situation of the mathematical problem, not all brain receptors are simultaneously stimulated when a message is sent to move a particular limb, but only the brain receptors specifically associated with that limb. When a wave message to move a part of the body is relayed, the brain receptors responsible for the movement show their stimulation by the same alternating motion of the recording wire. A wave train can be followed along a definite path leading away from the site of the brain receptor to a receptor on the head representing the limb to which the message is being relayed. If the receiving finger moves beyond the limb receptor, the recording wire ceases to show activated response. It is a useful method for locating receptors on the head associated with the different limbs.

We have demonstrated in seminars that a limb has associated receptors in the four quadrants of the head, with their own allocated brain receptors operating them. For example, one brain and knee receptor will be responsible for the forward motion of the knee, another brain and knee receptor for the backward motion, a third pair for the upward motion and a fourth pair for the downward motion. (See Figure 7.) The brain receptors responsible for the various motions change their role as the tester faces different directions relative to his channel. A slow motion of the knee is necessary while testing in order to be able to differentiate and note the variations. It has been observed, that the magnetic moment of each brain receptor is changed as the tester moves position and consequently the receptor's control function is changed also. A particular case of multiple sclerosis helped to illustrate this: her discrepancies varied according to the position in which she faced. It was a common complaint, "Sometimes I cannot move my leg forward". By way of experiment, I requested she turn and face in a different direction. To her surprise she could now move the leg forward but could not move it back.

FIGURE 7

• Brain receptor X Knee receptor

Pathway of wave message sent from a brain receptor to a knee receptor.

The explanation for this phenomenon was a disturbed brain receptor which was out of commission. With the person faced in another position, a different and normal brain receptor became responsible for the forward movement and the leg received the message to come forward. However, now the role of the disrupted brain receptor was to control the backward motion but it was unable to deliver the necessary message. We found when the pattern of energies in the circuit of the faulty brain receptor was corrected, the leg then responded to wave messages and she then had the ability to move the leg forward and backward in a normal manner.

Brain receptors are strategically located where their magnetic influences are predominant in the control of wave motion. Significantly, a brain receptor is always sandwiched in between two code receptors; one code receptor with a clockwise motion, the other with a counterclockwise motion. In summary, the magnetic moments in the various brain receptors vary as the direction of the head and body are shifted and, in turn, their responsibilities are changed. The complex arrangement is best understood by demonstration as we endeavour to show with actual cases in seminars.