Incidence-Specific Cure Guidance

Radiation Denaturation Guidance

Radiotherapy is one approach often employed towards to treatment of cancer. The hope generally is that the radiation will kill the cancer cells by causing bonds breakages that are non-reconstitutable. At least two variants of the approach are employed: Irradiation with X-rays, Irradiation with time-set embedded radioactive pellets.

Both approaches have advantages and disadvantages. The object of use, of course, is as already stated, though the former is noninvasive while the latter is invasive. Yet both also have the same shortcoming, the irradiation is based on high energy radiation -- the X-rays is characterized as hard X-rays.

Furthermore, there is no assurance of the treatment being efficacious. For somes cases the approach works and for others no advantage; after all, the willy-nilly rupture of bonds tends to enable the constituting of all new type of biologics, which are cancers of different types; and then treatment gets discontinued as usually the resulting outcome is the virulence of the cancer.

Denaturation Radiation, RadioDenaturation, offers a better alternative because RadioDenaturation entails the use of Soft X-rays in contrast with Radiotherapy that uses hard X-rays. Soft X-rays is particularly noted for being readily converted by biologics into heat. So irradiating biologics with soft X-rays simply heats up the biologics, mostly. Moreover, soft X-rays do not readily rupture chemical bonds. Admittedly the efficacy of Radiodenaturation derives obtains, of course, only because of the capacity to identify the Defect Stressor biologic. After all, as already observed, having knowledge of the defective biologic offers opportunity for cancer treatment with noninvasive approaches.

Indeed, knowledge of the Defect Stressor enables the determination of the bond energies and vibration frequencies of the "...UDU.." bio-condensation reaction bonds which can be given general representation:

 

Eq. 1

in which the letter 'D' represents the defective biologic.

So then, by targeting the bonds associated with the Defect Stressor biologic, the irradiation can be "tuned" to deposit all its energy on those select bonds and thereby effect preferential denaturation. Upon the denaturation two outcomes are possible: First the cancer loses it capacity to hide from the immune cells, which now recognize the biologics as harmful and destroy the cancer, Second the Defect Stressor on cooling resets itself into a normal Quaternary Conformation and the whole cancer resets, and clears away. While the latter is preferred, the former is just as effective.

The identifying of the Defect Stressor of any cancer Incidence is therefore a significant step towards the cure of the cancer by Denaturation Radiation, RadioDenaturation; and the Computing Center positions all radiation therapy of cancer incidences on that thrust of treatment.