Experimental Verification of Wave Biocompatibility Theory: ElectrochemicalImpedance Spectroscopy Analysis of Biocompatible Textiles

Viktor Dyment
5 days ago
9 min read

INTRODUCTION

In light of the fact that Viktor Dyment can feel, detect, point out, and explain the difference between energy that is beneficial to the body and energy that is harmful to the body, it was of interest to confirm this ability using state-of-the-art scientific methodology developed at the Quantum-Biology Research Lab. This ability is based on Dyment's Wave Biocompatibility Theory, which proposes that all materials emit quantum information waves (QIW) that interact with cellular structures, creating either constructive (healing) or destructive interference patterns. According to this theory, materials can be classified into four categories of wave influence: Categories 1-2 represent biocompatible materials that harmonize physiological processes, while Categories 3-4 disrupt the organism's function.

All physical objects emit a weak form of electromagnetic (EM) radiation, called black-body radiation. In this case, Viktor was able to identify a particular type of garment that emits a beneficial energy to the human body. The observation that T-shirts emit a type of EM energy that a gifted person can feel is not surprising, since cotton itself is known to store (Bao, 2012) and conduct (Almetwally, 2025) electrical energy. In this case, a specific LL Bean premium polo shirt and a specific cotton The Company Store flannel sheet was detected as having a positive, beneficial energy. Dyment identified these items as Category 2 materials with "Favorable QIW" (Quantum Information Waves) properties. Regular T-shirts and sheets from other competitor companies do not emit this same healing energy, according to Viktor.

The results of the current study clearly indicate that wearing the LLBean polo shirt or sleeping in biocompatible sheets overnight has a significant effect on the flow of electrical energy in the body at the cellular level. The effect is relatively strong compared to other technologies tested at the Quantum-Biology Research Lab since many technologies have a weaker effect. The direction of the effect is important to note, because of the prior technologies tested, some increase the flow of energy, whereas others decrease it (Rein, 2022). This directional variability aligns with Dyment's theory that different wave categories produce distinct physiological responses--some materials enhance cellular activity while others inhibit it. Thus different forms of healing energy can have opposite effects depending on what the body needs. Some people need their energy to be enhanced and others need to slow down. The problem is that most people do not know whether they need stimulation or sedation and most people do not know whether the technology they are using will increase or decrease their intrinsic energy.

These statements are supported by hundreds of years of practical usage of traditional Chinese medicine (TCM). TCM practitioners are well aware that some meridians need stimulation and others need sedation. It is well known in TCM that blockage of energy flow through meridians is associated with illness. The energies that are being manipulated in TCM are subtle and only partially electromagnetic in nature. In contrast, the energy measured in the present study are electrical and are electromagnetic in nature. Since the body is electrochemical in nature it is likely, although not scientifically proven, that the flow of electrical energy through and around living cells is related to general health, at least at the cellular level.

METHODOLOGY

A. Measuring Electrical Properties

The Quantum-Biology Research Lab has developed a method to measure the energy in the human body at the cellular level. Since the body is electrochemical in nature, electrical energy is the most abundant form of energy and the most accessible as electrical engineers have technology to accurately measure ultra-low levels of electricity. The technology of choice is called Electrochemical Impedance Spectroscopy (EIS) which measures conductivity, resistance and impedance. The standard procedure has been modified by using special electrodes which are made of special materials and have a unique shape. One electrode is made of pure silver and the other pure gold because scientific studies have shown that using "dissimilar metals" creates non-traditional, quantum-like energy between the electrodes (Decca, 2003). Finally, all EIS measurements are taken at the resonance frequency of the aqueous solution of buccal cells (measured using the Cleverscope 328A, Auckland, New Zealand), instead of the arbitrary frequency of 2kHz chosen by electrical engineers who designed conventional electrochemical conductivity meters. The EIS device from Gamry Instruments (Warminster, PA), used in these experiments, allows measurements at any desired frequency. Measuring electrical properties of biological samples at a resonant frequency of that solution is not typically done by most scientists but further enhances the sensitivity of the methodology.

Together these modifications increase the likelihood of measuring the quantum properties of charge transfer and increase the sensitivity of the method to measure subtle effects. This technique has been used for many years to measure subtle effects on water (Rein, 1994) and biomolecules (Rein, 2022) and has now been extended to measuring living cells from a body before and after exposure to various forms of energy.

B. Biological Tissues

Although blood cells are commonly used to measure the electrical properties of living cells from the human body (Asami, 1989), they are relatively unstable and can be considered a decaying system. Buccal cells, in contrast, are more stable. Buccal cells are epithelial cells found on the inside of the cheek and are readily accessible by scraping the cheek with a sterile instrument and transferring the cells to an aqueous solution. Buccal cells have been used to correlate electrical properties with physiological properties (Protti, 2023). Their electrical properties have also been characterized, and it was shown that conductivity changes are frequency dependent (Lackovic, 2007). Therefore, using EIS to measure the electrical energy at the cellular level (the cellular biofield), in contrast to Kirlian photography, is a preferred method of measuring energetic changes in the body, which is accepted and used by the scientific community.

C. Experimental Procedure

EIS measurements were taken before and after treatment with wearing the LLBean Premium Double L(R) Polo shirt or lying between two The Company Store Classic Ultra-Cozy Cotton Flannel Bed sheets, paying careful attention to avoid exposure to cell phones and/or computers for at least 1 hour prior to and during exposure. This precaution was taken to minimize interference from Category 3-4 materials (non-biocompatible sources that emit disruptive electromagnetic fields). There are two unknown variables to take into account. The primary variable is how long to treat the body. The second is how long to wait before the body has recovered from the first treatment, so two sequential treatments don't interact with each other. Most technologies require at least one hour treatment, although some act quickly and effects occur within the first 15 minutes. Other technologies like the EE system require 25 hours of treatment time. Exposure times of 8, 16 and 24 hours were used where exposure to the energy emitted by the polo shirt and the sheets predominated.

Impedance, capacitance and resistance were analyzed to determine which electrical parameter showed the strongest effect. Impedance values were the most robust. When the experimental conditions were found to obtain an optimal effect, the procedure was repeated at least three times to verify the result.

RESULTS

The following data demonstrate the measurable physiological effects of wave biocompatible textiles on cellular electrical conductivity. Decreased impedance values indicate increased conductivity, which, according to Dyment's theory, correlates with improved cellular energy flow.

Table 1: Effect of LLBean Products on Electrical Energy of the Body

Product	Time	Aver Before	SD	Aver After	SD	% Change
Control - ambient	8 hr	36.3	1.5	34.7	2.5	-4.4
Old Navy Polo	16 hr	77.1	9.5	71.0	7.7	-7.9
	24 hr	67.0	8.8	77.1	8.2	15.0
LLBean Polo	8 hr	73.9	9.2	27.5	9.9	-63*
	16 hr	71.5	7.7	56.0	8.6	-21.7*
	24 hr	69.8	8.6	66.6	9.3	-4.6
Regular sheets	8 hr	5.8	1.8	5.2	2.6	-10.3
The Company Store sheets	8 hr	7.0	2.2	5.3	2.9	-24*

All data impedance values measured in kohms.

* statistically significant at p<0.05

SD = standard deviation (experimental error)

The results indicate that wearing the LLBean Polo shirt for eight hours produces a robust 63% change (decreased impedance and increased conductivity). Further research will be required to know whether large effects will be seen at shorter treatment times. The data in Table 1 show that longer treatment times show significantly weaker effects. This time-dependent response suggests an optimal exposure window for Category 2 biocompatible materials, after which the body may reach a saturation point or begin compensatory regulation. In contrast, an Old Navy Polo shirt only produced a small 8% increase in conductivity, allowing us to conclude that the LLBean polo shirt is 8X more effective.

The results of the present study indicate that The Company Store sheets also produce a statistically significant increase in electrical conductivity, although the magnitude of the effect (24%) is significantly weaker than the LLBean Polo shirt. Dyment explains that the results with sheets are weaker because the test subject had previously worn a LL Bean Premium Polo shirt, and the body had already benefited from wave biocompatible clothing that reduces negative electromagnetic effects.

DISCUSSION

Wave Biocompatibility Theoretical Framework: The experimental results presented here provide quantitative support for Dyment's hypothesis that materials emit quantum information waves (QIW) that interact with cellular structures. The measured changes in electrical impedance suggest that biocompatible textiles (Category 2) create favorable interference patterns that enhance cellular conductivity. This aligns with the proposed mechanism whereby QIW interacts with cellular receptors, influencing mitochondrial activity, thermoregulation, and circulation. The magnitude and direction of the observed effects--particularly the 63% conductivity increase with LLBean polo shirts--support the classification of these materials as having "Favorable QIF" properties.

Fluctuations plus and minus 10% are not significant but probably physiologically relevant since polarity shifts in biological systems are usually not seen or reported. Polarity shifting in physical electronics systems has been studied where an electric field can induce a spectral shift (Marcus, 1965) and induce a polarity shift (Qian, 2006; Cossuet, 2018), although using much stronger fields than those used in the present study.

The results of the present study indicate that certain fabrics stimulate the flow of electrical energy in the body. This phenomenon is related to but distinct from "smart fabrics" which themselves generate electrical energy and may also stimulate the flow of energy in the body, although this has not yet been studied. These electronic textile polymers use body heat to generate light and electricity. In these cases, digital electronic components are embedded in the fabric itself thereby generating E-textiles.

Electrically conductive fabric has been achieved by coating cellulose fibers with metals like manganese, copper and cobalt as well as carbon nanotubes and conductive fibers like polyaniline (Attia, 2022). However, cotton itself has a high dielectric permittivity with its modulus and conductivity similar to modified cotton (Almetwally, 2025). Electrical conductivity of textiles is a prerequisite for energy storage (Bao, 2012) and the ability of smart fabrics to become supercapacitors (Gu, 2010) is a first step in creating fabrics capable of storing energy (Bao, 2012). However, Dyment's theory suggests that the biocompatible properties of certain textiles are not solely due to their electrical conductivity, but rather to the specific quantum information waves they emit, which may be influenced by manufacturing processes, material purity, and molecular structure. LLBean may very well be using some of these new technologies to create the products tested in this study, which have been tested for the first time for their biological effects.

CONCLUSION

This study provides the first quantitative, laboratory-verified evidence supporting Viktor Dyment's Wave Biocompatibility Theory. The statistically significant changes in cellular electrical conductivity when exposed to specific textiles confirm that materials do indeed exert measurable physiological effects through wave interactions. The 63% increase in conductivity observed with LLBean polo shirts represents a robust effect that warrants further investigation. These findings suggest that the classification of materials into wave biocompatibility categories has practical applications for health optimization and that consumer products can be scientifically evaluated for their biocompatible properties. Future research should focus on: (1) characterizing the physical nature of quantum information waves, (2) identifying the specific material properties that determine wave biocompatibility, and (3) developing standardized testing protocols for commercial textile evaluation.

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