Wave Biocompatibility of Materials: A Hypothesis Description, Proposed Experiments and Observations

 Core Hypothesis

Viktor Dyment proposes a theory suggesting that environmental materials (clothing fabrics, bedding, metal alloys, dental materials) exert measurable physiological effects on the human organism through wave interactions at the cellular structure level.

According to this theory, materials can be classified into four categories of wave influence:

• Categories 1-2: Biocompatible materials that harmonize physiological processes

• Categories 3-4: Materials that cause disruptions in the organism's function

Reported Observations

1. Thermographic Effects of a Metal Alloy

To confirm his observations and prove his discovery, Dyment reported the development of a special metal alloy that, when worn as a ring, induces measurable tissue temperature changes detectable by thermographic imaging. According to his observations:

• Temperature changes can reach more than 15°F (8°C) within 30 minutes

• The effect is particularly pronounced in individuals with circulatory impairments

• Video documentation is available at healthfrequency.com

2. Influence of Fabrics on DNA Electrical Conductivity

Based on Dyment's hypothesis that materials fall into distinct wave categories, researcher Glen Rein, PhD, conducted comparative measurements of DNA electrical conductivity. He tested DNA samples in contact with two fabric types:

1. Category 3 fabric: "Average" clothing material, Dr. Rein had previously worn

2. Category 2 fabric: L.L.Bean Men's Premium Double L® Polo, identified by Dyment as "wave biocompatible"

Dr. Rein's measurements revealed differences he described as "amazing"—approximately a 500% (5-fold) variance in conductivity between the two fabric categories, consistent with Dyment's predictions about wave biocompatibility distinctions.

3. Clinical Observations

Dyment reports observations of improvement in the following conditions when using his alloy:

• Microcirculatory impairments

• Thermoregulation problems

• Certain urological dysfunctions

Proposed Mechanism

The theory postulates the existence of "quantum information waves" (QIW) that:

• Are emitted by all materials

• Interact with cellular structures through receptors

• Influence mitochondrial activity, thermoregulation, and circulation

• Can create constructive or destructive interference

A "Health Frequency Formula" with four equations describing interaction categories has been proposed for quantitative assessment.

Alloy Composition

1. A noble gold jewelry alloy comprising gold, platinum, silver, rhodium, and iron.

2. It has been developed through his practical knowledge and skills of empirical optimization (24 experimental compositions over 2 years). General composition ranges are referenced in patent application US 2013/0259736 A1.

Critical note: Precise ratios and manufacturing protocols are essential for safe use and efficacy. Deviations from optimized parameters may result in adverse health effects. Detailed specifications are available for collaborative research, subject to the execution of appropriate confidentiality agreements.

Requirements for Verification

Scientific verification of these observations requires:

1. Controlled Thermography Experiments:

• Double-blind testing (neither subject nor operator knows which alloy is being used)

• Placebo control (ring of identical weight and shape made from ordinary metal)

• Standardized conditions (room temperature, limb position, acclimatization time)

• Statistically significant sample size (30+ participants)

• Repeated measurements

2. Independent Replication:

• Reproduction of effects in independent laboratories

• Publication of detailed measurement protocols

• Provision of alloy samples for testing

3. Mechanistic Studies:

• Physicochemical characterization of the alloy

• Measurement of proposed "wave" emissions using standard instruments

• Testing of alternative explanations (thermal conductivity, pressure, magnetic properties)

Alternative Explanations

Observed thermographic changes could potentially be explained by:

• Blood flow redistribution from the ring pressure on the veins

• Thermal conductivity properties of the metal

• Psychophysiological response (placebo effect)

• Changes in hand position during measurement

Rigorous experimental control is necessary to exclude these factors.

Proposed Experimental Protocol

Objective

To verify the thermographic effects of a specialized metal alloy on tissue temperature and microcirculation under controlled, double-blind conditions.

Materials and Equipment

      • Biocompatible wear.

Test Materials:

• Experimental ring: specialized gold alloy (proprietary composition)

• Control ring: standard gold alloy of identical weight, dimensions, and surface finish

• Both rings coded (A/B) to maintain blinding

Equipment:

• Medical-grade thermographic camera (e.g., FLIR thermal imaging system)

• Calibrated digital thermometer

• Environmental monitoring: room thermometer, hygrometer

• Timer

• Data recording system

Participants:

• Sample size: minimum 30 volunteers

• Inclusion criteria: adults 18-75 years

• Two subgroups: healthy controls (n≥15) and individuals with documented circulatory impairments (n≥15)

• Exclusion criteria: acute inflammation, fever, recent physical exercise

Experimental Design

Double-blind randomized crossover design:

• Neither participant nor thermographer knows which ring is experimental vs. control

• Each participant tested with both rings in a randomized order

• Minimum 48-hour washout period between sessions

• Assignment code held by an independent third party

Protocol Steps

Pre-measurement phase (15 minutes):

1. Participant acclimates in a temperature-controlled room (20-22°C, 40-60% humidity)

2. Remove jewelry and wash hands with room-temperature water

3. Sit comfortably with both hands resting on the table at heart level

4. Baseline thermographic scan of both hands

5. Record baseline digital temperature (middle finger, both hands)

Measurement phase (30 minutes):

1. Place the coded ring on the middle finger of the dominant hand (t=0)

2. Maintain a consistent hand position throughout

3. Thermographic imaging at: t=1, 5, 10, 15, 20, 30 minutes

4. Record digital temperature at the same intervals

5. Document any subjective sensations (tingling, warmth, etc.)

Post-measurement phase (15 minutes):

1. Remove ring

2. Monitor temperature recovery for 15 minutes

3. Record any delayed effects

Second session (after ≥48 hours):

• Repeat the entire protocol with the alternate ring

Data Collection

Primary outcome measures:

• Temperature change (°F/°C) from baseline at each time point

• Area of temperature change (cm²)

• Pattern of heat distribution (thermographic maps)

Secondary outcome measures:

• Time to first detectable change

• Maximum temperature differential

• Rate of temperature increase or decrease

• Symmetry effects (temperature changes in the non-ring hand)

• Recovery time after ring removal

Environmental controls:

• Constant room temperature (±1°C)

• Consistent lighting conditions

• Standardized hand positioning (photographic reference)

• No food/drink/smoking 2 hours before testing

Statistical Analysis

• Primary comparison: temperature change experimental vs. control ring at t=30 minutes

• Within-subject paired comparisons (crossover design)

• Between-group analysis: healthy vs. circulatory impairment subgroups

• Statistical significance: p < 0.05 (two-tailed)

• Effect size calculation (Cohen's d)

• Individual response analysis (responders vs. non-responders)

Success Criteria

The hypothesis will be considered supported if:

1. Mean temperature increase with experimental ring significantly exceeds control (p < 0.05)

2. Effect size is clinically meaningful (>5°F / 2.8°C difference)

3. The effect is reproducible in >70% of participants

4. The effect is larger in the circulatory impairment subgroup

Safety and Ethics

• Informed consent from all participants

• Right to withdraw at any time

• Medical screening before participation

• Monitoring for adverse reactions

• Ethics review board approval recommended

Independent Replication

For verification, this protocol should be:

• Replicated by at least two independent laboratories

• Published with raw data and thermographic images

• Made available for meta-analysis

Current Status

As of October 2025:

• Observations are documented in video format at healthfrequency.com

• No publications exist in peer-reviewed scientific journals

• Controlled studies with independent verification have not been conducted

• The theory has not received recognition in the scientific community

Conclusion

The wave biocompatibility hypothesis represents an unconventional interpretation of material interactions with biological systems. Dyment's thermographic observations merit verification under controlled conditions.

To advance this work, it is necessary to:

1. Conduct strictly controlled experiments with independent verification

2. Publish detailed protocols and numerical data

3. Enable replication by other researchers

4. Submit results for peer review in scientific journals

Only after successful completion of these stages can conclusions be drawn about the validity of the theory.

Note: This protocol is designed to test the specific claim of thermographic effects. It does not test mechanistic hypotheses (such as quantum information waves) but instead establishes whether a reproducible physiological effect exists that warrants further investigation.