Electromagnetic Information Transfer to Water – Inhibit Microorganism Growth

Anton SF
This post reviews some of the work by Heredia-Rojas et al. related to transferring antimicrobial information to water via an electronic amplifier (i.e. a bio-resonance therapy, BRT, device). In particular, the scientific papers that will be discussed include: 

A. “Entamoeba Histolytica And Trichomonas Vaginalis: Trophozoite Growth Inhibition by Metronidazole Electro-Transferred Water” (2011), 

B. “Antimicrobial Effect Of Amphotericin B Electronically-Activated Water Against Candida Albicans” (2012), and 

C. “Antimicrobial Effect Of Vancomycin Electro-Transferred Water Against Methicillin-Resistant Staphylococcus Aureus Variant” (2015),

 which look at parasite, fungus, and bacteria growth inhibition respectively.


What is the purpose of the studies?


There are different methods available that try to inhibit the growth of microorganisms – some of them rely on a conventional approach (e.g. using antimicrobial drugs), while others are classified as unconventional (e.g. using electric and magnetic fields). The studies reviewed in this post investigate whether it is possible for the electromagnetic signal derived from a biologically active substance that inhibits microbial (e.g. parasite, fungus, bacteria) growth to be transferred to water samples and then influence the microorganisms mentioned above. 


How were the studies conducted?


All three studies had a similar experimental set-up and included the following controls and test samples:

cells treated with pure water (negative control);


cells treated with “sham” electro-transferred water samples (i.e. transferring information from pure water to water as a control to account for any possible artifact effect induced by the electronic device on water samples);


cells treated with the biologically active substance (positive control);


cells treated with electronically transferred information from a biologically active substance.


A. Parasite Study


In the 2011 parasite study, the electronic information of metronidazole, a drug against parasites, was transferred to water using an electronic amplifier and tested against the growth of two types of parasites: Entamoeba histolytica andTrichomonas vaginalis. 


IC of Metronidazole against Entamoeba histolytica

Fig. 1. Effect of metronidazole electro-transferred water samples on the growth of Entamoeba histolytica trophozoites (HM1-IMSS strain). The amoebas were cultured in PEHPS medium, inoculated with 1 x 104 trophozoites/mL and incubated at 37oC. Nine tubes were used for each treatment regime and controls, giving a total of 36 cultures. The cell density was determined in triplicate and in a blind way by using a hemocytometer Neubauer chamber.



IC of Metronidazole against Trichonomas vaginalis

Fig. 2. Effect of metronidazole electro-transferred water samples on the growth of Trichomonas vaginalis trophozoites (GT-13 strain). The parasites were cultured in PEHPS medium, inoculated with 1 x 102 trophozoites/mL and incubated at 36.5oC. Nine tubes were used for each treatment regime and controls, giving a total of 36 cultures. The cell density was determined in a hemocytometer in triplicate and in a blind way.
 


B. Fungus Study


In the 2012 fungus study, the electronic information of amphotericin B, an antifungal drug, was transferred to water using an electronic amplifier and tested against the growth of Candida albicans.


IC of Amphotericin B against Candida albicans

Fig. 3. Effect of electronically-activated water on cultured Candida albicans growth. Vitability of C. albicans after exposure to electronically-transmitted amphotericin B to water in liquid medium was determined by a colorimetric technique. For the positive control, 125 μg·mL-1 of amphotericin B was used. Data represent mean ±SD of 8 replicates per treatment group from 3 independent experiments.



C. Bacteria Study


In the 2015 bacteria study, the electronic information of vancomycin, an antibiotic, was transferred to water using an electronic amplifier and tested against the growth of methicillin-resistant Staphylococcus aureus (MRSA).


IC of Vancomycin against MRSA

Fig. 4. Effect of electro-transferred water on MRSA growth inhibition on liquid culture medium. MRSA growth after exposure to electronically-transmitted vancomycin to water in liquid culture medium was determined spectrophotometrically. For the positive controls, 4.0 μg/mL of vancomycin was used. Data represent mean ±SEM.


What did the studies reveal?


For all the studies, it was found that the water “charged” with the bioactive substance significantly inhibited the growth of the microorganism under investigation. For instance, water “charged” with metronidazole reduced the growth of the parasites Entamoeba histolytica and Trichomonas vaginalis and water "charged" with antifungal amphotericin B significantly decreased the growth of cultured Candida albicans. Similarly, electronically activated water samples of the antibiotic vancomycin resulted in a significant reduction in the growth of methicillin-resistant Staphylococcus aureus (MRSA). 


What does this mean?


The evidence presented by Heredia-Rojas et al. suggests that it is possible to transfer antimicrobial information to water to inhibit the growth of microorganisms, though further experimental work is needed to fully understand the mechanism by which the electro-activated water mimics the activity of an antimicrobial agent. Nevertheless, these results support the future use of informational medicine and electromagnetic signatures, such as ICs, in the clinical realm.

In a time when bacterial diseases are increasingly resistant to conventional treatment, other methods of treatment need to be investigated to control microbial illnesses.
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Electromagnetic Information Transfer to Water – Inhibit Microorganism Growth
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SJ
Dec 03, 2018
This is great information - please keep up the information stream with all the latest advances - we NEED this!!!
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