Dr. Harold Saxton Burr (April 18, 1889 – February 17, 1973) was E. K. Hunt Professor of Anatomy at Yale University School of Medicine and researcher into bio-electrics –
From 1916 to 1956, Burr published, either alone or with others, 93 scientific papers.
The following excerpts are taken from “Blueprint For Immortality”, by Dr. Harold Saxton Burr.
- “The Universe in which we find ourselves and from which we can not be separated is a place of Law and Order. It is not an accident, nor chaos. It is organized and maintained by an Electro-dynamic field capable of determining the position and movement of all charged particles. For nearly half a century, the logical consequences of this theory have been subjected to rigorously controlled conditions and met with no contradictions.“
These were the statements of Dr. Harold Saxton Burr, Ph.D., who was E. K. Hunt Professor Emeritus, Anatomy at Yale University School of Medicine. Dr. Burr was a member of the faculty of medicine for over forty-three years. From 1916 to the late 1950’s, he published, either alone or with others, more than ninety-three scientific papers.
Dr. Burr discovered that all living things – from men to mice, from trees to seeds – are molded and controlled by electro-dynamic fields, which could be measured and mapped with standard voltmeters. These “fields of life,” or L-fields, are the basic blueprints of all life on this planet. Their discovery is of immense significance to all of us. Dr. Burr believed that, since measurements of L-field voltages can reveal physical and mental conditions, doctors should be able to use them to diagnose illness before symptoms develop, and so would have a better chance of successful treatment.
- “Electro-dynamic fields are invisible and intangible; and it is hard to visualize them. But a crude analogy may help to show what the fields of life – L-fields for short – do and why they are so important. Most people who have taken high school science will remember that if iron filings are scattered on a card held over a magnet, they will arrange themselves in the pattern of the ‘lines of force‘ of the magnet’s field. And if the filings are thrown away and fresh ones scattered on the card, the new filings will assume the same pattern as the old. Something like this happens in the human body. Its molecules and cells are constantly being torn apart and rebuilt with fresh material from the food we eat. But, thanks to the controlling L-fields, the new molecules and cells are rebuilt as before and arrange themselves in the same pattern as the old ones.”
- “Until modern instruments revealed the existence of the controlling L-fields, biologists were at a loss to explain how our bodies ‘keep in shape’ through ceaseless metabolism and changes of material. Now the mystery has been solved: the electro-dynamic field of the body serves as a matrix or mould which preserves the ‘shape’ or arrangement of any material poured into it, however often the material may be changed.”
- “When a cook looks at a jelly mould, she knows the shape of the jelly she will turn out of it. In much the same way, inspection with instruments of an L-field in its initial stage can reveal the future ‘shape’ or arrangement of the materials it will mould. When the L-field in a frog’s egg, for instance, is examined electrically, it is possible to show the future location of the frog’s nervous system because the frog’s L-field is the matrix which will determine the form which will develop from the egg.
- “To return to the cook, when she uses a battered mould, she expects to find some dents or bulges in the jelly. Similarly, a ‘battered’ L-field – that is, one with abnormal voltage patterns – can give a warning of something ‘out of shape’ in the body, sometimes in advance of actual symptoms. For example, malignancy in the ovary has been revealed by L-field measurements before any clinical sign could be observed. Such measurements, therefore, could help doctors to detect cancer early, when there is a better chance of treating it successfully.”
Dr. Burr decided to examine the electrical properties of cancer-susceptible mice to determine if the voltage measurements would change during the initiation and growth of cancer tissue. “The results of the experiment were surprisingly consistent. Twenty-four to twenty-eight hours after the implantation, changes were observed in the voltage gradients. This differential increased steadily and quite smoothly to reach a maximum of approximately five millivolts on or about the eleventh day. In the slow-growing tumors potential differences began to emerge on the third or fourth day, but reached their maximum of approximately three millivolts on the tenth or eleventh day.”
In the control animals there were no significant fluctuations in voltage. “It is clear from these findings that the crest of atypical growth in the host organism produced measurable and reproducible electro-metric correlates.”
READ full ARTICLE >> CLICK HERE
DOWNLOAD PDF ARTICLE
|