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Related Concept Videos

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Electromagnetic information transfer through aqueous system.

Alberto Foletti1,2, Mario Ledda2, Maria Grazia Lolli2

  • 1a Clinical Biophysics International Research Group , Lugano , Switzerland.

Electromagnetic Biology and Medicine
|July 14, 2017
PubMed
Summary

The electromagnetic information transfer through aqueous system (EMITTAS) procedure shows promise for treating various conditions. This biophysical approach leverages unique electromagnetic signatures for personalized, self-administered treatments, promoting self-regulation and regeneration.

Keywords:
Aqueous systemelectromagneticinformationtherapywater

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Area of Science:

  • Biophysics
  • Electromagnetism in Biology
  • Integrative Medicine

Background:

  • Biological systems utilize endogenous electromagnetic signals for internal synchronization and adaptive responses.
  • Each adaptive response is associated with a unique electromagnetic signature, suggesting a basis for biophysical interventions.
  • Previous in vitro studies reported beneficial effects of the electromagnetic information transfer through aqueous system (EMITTAS) procedure.

Purpose of the Study:

  • To evaluate the clinical potential of the EMITTAS procedure as a biophysical approach for managing common illnesses.
  • To investigate the role of aqueous systems in recording, storing, and transferring biological information for therapeutic purposes.
  • To explore the capacity of EMITTAS to trigger self-regulation and self-regeneration.

Main Methods:

  • Application of a biophysical procedure integrating the EMITTAS procedure for various clinical conditions.
  • Self-administration of a recorded aqueous system by patients for home-based treatment.
  • Focus on endogenous electrodynamic activities and electromagnetic signatures for personalized therapy.

Main Results:

  • Significant and long-lasting improvements reported in patients with articular pain, low-back pain, neck pain, anxiety, depression, and other conditions.
  • Demonstrated efficiency, effectiveness, and personalization of the biophysical EMITTAS procedure in clinical management.
  • Evidence suggesting aqueous systems can store and transfer biologically relevant information for therapeutic outcomes.

Conclusions:

  • The EMITTAS procedure offers a potentially beneficial, efficient, effective, and personalized approach to managing common illnesses.
  • Aqueous systems are crucial for capturing and transmitting therapeutic biological information, enabling self-regulation and regeneration.
  • This biophysical strategy supports a paradigm shift towards self-administered, information-based medical treatments.