Journal of Medical Physics and Applied Sciences

A 3D Model for Decreasing the Side Effect of Dizziness after Radiotherapy of Brain Tumors

We establish limits for the percentage of dizziness associated with a fixed, charged, symmetric condensed phenomenon in a 3-dimensional space-time, using principles of common relativity and the presence of a dose. Specifically, we determine the minimum and maximum values for this percentage. The minimum dose scenario corresponds to the charged phenomena that exhibit the lowest ratio of dizziness to dose in terms of both charge and vacuum energy.

In the context of brain tumor cells in a 3-dimensional state, we employ a method that enables the determination of the classical cell radius through basic relativistic arguments. Our research team links the minimum bound for dizziness in this three-dimensional space-time to the Minimum Length Uncertainty Relations (MLUR) triggered by radiotherapy.

We also derive a new limit for the maximum ratio of charge to dizziness of a fixed, radiotherapy charged phenomenon, expressed in terms of fundamental constants. Furthermore, we determine the appropriate order of magnitude for the ratio of charge to dizziness in the dose by evaluating this limit, which is necessary to satisfy the strength conditions.

Our results indicate that a decrease in the dose or an increase in its charge could potentially destabilize the Compton radius, where the combination of dizziness and dose plays a significant role. If the dose were to increase beyond a certain point, it would disintegrate. Moreover, our findings suggest a strong relationship between dizziness, the cosmological constant, and the stability of basic cellular structures.

Author(s): M Farnush*

Abstract | PDF

Share this