External low energy electromagnetic fields affect heart dynamics: surrogate for system synchronization, chaos control and cancer patient’s health

External low energy electromagnetic fields affect heart dynamics: surrogate for system synchronization, chaos control and cancer patient’s health

All cells in the human body, including cancer cells, possess specific electrical properties crucial for their functions. These properties are notably different between normal and cancerous cells. Cancer cells are characterized by autonomous oscillations and damped electromagnetic field (EMF) activat...

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Bibliographic Details
Main Authors: Frederico P. Costa, Jack Tuszynski, Antonio F. Iemma, Willian A. Trevizan, Bertram Wiedenmann, Eckehard Schöll
Format: Article
Language:English
Published: Frontiers Media S.A. 2025-01-01
Series:Frontiers in Network Physiology
Subjects:
non-thermal electromagnetic fields
radiofrequency
cancer treatment
cancer cells
oscillations
resonance
Online Access:https://www.frontiersin.org/articles/10.3389/fnetp.2024.1525135/full
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Summary:All cells in the human body, including cancer cells, possess specific electrical properties crucial for their functions. These properties are notably different between normal and cancerous cells. Cancer cells are characterized by autonomous oscillations and damped electromagnetic field (EMF) activation. Cancer reduces physiological variability, implying a systemic disconnection that desynchronizes bodily systems and their inherent random processes. The dynamics of heart rate, in this context, could reflect global physiological network instability in the sense of entrainment. Using a medical device that employs an active closed-loop system, such as administering specifically modulated EMF frequencies at targeted intervals and at low energies, we can evaluate the periodic oscillations of the heart. This procedure serves as a closed-loop control mechanism leading to a temporary alteration in plasma membrane ionic flow and the heart’s periodic oscillation dynamics. The understanding of this phenomenon is supported by computer simulations of a mathematical model, which are validated by experimental data. Heart dynamics can be quantified using difference logistic equations, and it correlates with improved overall survival rates in cancer patients.
ISSN:2674-0109

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