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Cureus
Oct, 2024;16 (10): e72587.

Induced Native Phage Cocktails for Multi-microbial Activation Syndrome in Treatment-Resistant Illnesses.

David A Jernigan
Author Information
  1. David A Jernigan: Bioregulatory Medicine, Biologix Center for Optimum Health, Franklin, USA.
PMID: 39474589 DOI: 10.7759/cureus.72587

Abstract

The global population is plagued by chronic illnesses of many types due to, in part, the activation of virulence of many latent microbes leading to chronic multi-system illness, stimulating the new term, multi-microbial activation syndrome (MMAS). Treatment-resistant infections across the entire microbial spectrum are now largely untreatable using the previously successful pharmaceutical and natural medicine options. The heavy-handed methods of long-term chemotherapeutic antibiotics, antifungals, and antiviral drugs, whose adverse effects could be worse than the original illness, are presently essentially useless in the long run, as microbes have developed rapid adaptive mutations, becoming drug-resistant. The introduction of induced native phage therapy opened a completely new treatment category that has the potential to complement or replace aggressive drug therapies of many classes. Since its introduction, many advancements have been made to the technology. The most recent development in this new treatment genre is the ability to formulate induced native phage cocktails that use a wide spectrum of induction signatures within the formulation to stimulate various types of beneficial phages already living within the phageome of the body, to target a wide range of pathogenic microbes and associated advantageous physiological targets. The ability to address the MMAS commonly seen in various chronic illnesses simultaneously within the same formulation enables greater clinical outcomes without harm to the microbiome or to the tissues and systems of the body.

Keywords

biofilm biospectral emission sequencing endotoxin induced native phage therapy inducen-ld/rf inducen-res lyme disease multi-microbial activation syndrome respiratory tract infections

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