Lymphocyte Activity: Blood Test Results

Disclaimer & Warning

The information presented on this page is for educational and informational purposes only. It reflects findings from our sound research and independent laboratory analyses, but is not intended to provide medical advice, diagnosis, or treatment. The content should not be used as a substitute for professional healthcare guidance, nor do we recommend self-diagnosis or self-treatment based on this information.

If you are experiencing symptoms, have existing health concerns, are pregnant, or are in poor health, you should consult a qualified doctor or healthcare practitioner for appropriate evaluation and care. We expressly disclaim responsibility for any adverse effects, misuse, or misinterpretation of the information provided. 

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Lymphocyte Activity and MyReset

Immune cells, particularly lymphocytes, often become sensitised and overreactive when exposed to toxins and allergens. The MyReset Soundscape Journeys may help reduce excessive immune reactivity, restoring balance between defence and tolerance. In this study, sound application was associated with lower lymphocyte activity in response to multiple toxins, indicating reduced sensitivity. This suggests that the sound may act as a modulator of immune stress, helping the body to shift out of hyper-reactivity and conserve energy for repair and recovery.

Lymphocyte Activity in Response to Toxins

This section presents the results of specialised testing that measures lymphocyte reactivity when exposed to low levels of environmental and chemical toxins. Elevated activity indicates sensitisation of the immune system to a given substance. Results were recorded before and after sound application, allowing comparison of baseline immune reactivity with post-sound modulation. The graphs illustrate how sound may influence the immune system’s sensitivity to toxic exposures.

Toxins Tested

• Mercury (Inorganic) - a heavy metal commonly derived from industrial emissions, contaminated water, and dental amalgams. Known to disrupt enzymes and induce oxidative stress.
• Mercury (Organic, e.g. methylmercury) - typically acquired through contaminated fish and seafood; crosses the blood–brain barrier and impairs neurological development.
• Nickel - a metal used in alloys, coins, jewellery, and industrial applications; associated with skin sensitisation, allergic reactions, and DNA binding.
• Palladium - a rare metal used in dentistry, electronics, and catalytic converters; exposure can provoke immune reactions and allergenic responses. 
• Benzoquinone – a reactive benzene metabolite that damages mitochondrial enzymes; linked to fatigue and impaired energy production.
• Trimethylbenzenes - solvents and fuel additives that affect liver detoxification, oxidative stress balance, and neurological health.
• Butanols (Butanol isomers) - solvents used in paints, coatings, and industrial processes; associated with dizziness, neurotoxicity, and liver stress.
• Propanols (Isopropanol/Propanol isomers) - alcohol solvents found in cleaning agents and disinfectants; toxic at high exposures, stressing the liver and kidneys.
• Nitrosopyrrolidine - a nitrosamine formed in food processing and tobacco smoke; strongly carcinogenic and capable of forming DNA adducts.
• Benzoate - a preservative in foods and drinks; while often tolerated, it can be metabolised to benzoic acid, contributing to hypersensitivity and DNA modification in sensitised individuals.

Interpreting the Results of Sound on Lymphocyte Activity

The values represent lymphocyte activity for each toxin. Baseline readings (before sound) indicate the degree of immune sensitisation or reactivity to a given compound. The post-sound results show how vibrational therapy may influence immune responsiveness and sensitivity to toxins.

• Values ≤100 = normal, no significant sensitisation
• 100–200 = borderline sensitisation
• >200 = definite sensitivity or reactivity

Broader Implications

These findings demonstrate that toxins from metals, solvents, preservatives, and combustion byproducts can leave measurable imprints on immune cell activity and sensitivity. By comparing lymphocyte responses before and after sound, the graphs illustrate the possibility of modulating immune reactivity and potentially reducing toxic impact. This approach provides a novel perspective on how environmental exposures, immune sensitivity, and vibrational therapies intersect to shape overall health outcomes.

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Toxin Reactivity and Sound

This testing assessed the patient’s lymphocyte reactivity in response to a panel of environmental and chemical toxins. Results were recorded before and after sound application, allowing comparison of baseline sensitisation with post-sound modulation. The patient presents with fatigue, lethargy, and growth delays, all of which may be linked to impaired detoxification, energy production, and toxin-related immune dysregulation.

Toxins Tested and Patient Results

Metals:

• Mercury (Inorganic) - 210 → 170
• Mercury (Organic) - 190 →  45
•  Nickel - 240 → 185
• Palladium - 170 → 100

Reactive Chemicals and Solvents:

• Benzoquinone - 340 → 200
• Trimethylbenzene(s) - 230→ 90
• Butanol(s) - 80→ 80
• Propanol(s) - 140 → 130

Nitrosamine and Preservatives:

• Nitrosopyrrolidine - 270→ 155
• Benzoate - 220 → 150

(All values represent lymphocyte reactivity scores: ≤100 = normal, 100–200 = borderline, >200 = definite sensitivity.)

Interpretation

• Before sound: The patient showed multiple elevated results, with Mercury (Inorganic 210, Organic 190), Nickel (240), Palladium (170), and especially Benzoquinone (340) all in the borderline-to-definite sensitivity range. These findings are consistent with heavy metal and solvent exposures impacting mitochondrial enzymes, detoxification pathways, and inflammatory signalling - mechanisms strongly associated with fatigue, low energy, and delayed growth.
• After sound: A marked reduction in sensitivity was observed across most toxins. Notably, Palladium dropped from 170 to 100 (normal range), Benzoquinone from 340 to 200 (borderline), and both forms of Mercury decreased significantly. Nitrosopyrrolidine also imporved markedly (270 to 155), shifting from definite sensitivity to borderline reactivity. These results suggest that sound application may have modulated immune reactivity or supported cellular balance, improving the systems tolerance to toxic stressors.
• Exceptions: Butanol remained unchanged in the normal range, and Propanol showed only a slight reduction from 140 to 130 (borderline range). These stable valuse indicate consistent low-level reactivity that should be tracked with ongoing monitoring.

Broader Implications

These results illustrate how toxins - particularly metals (Mercury, Nickel, Palladium) and benzene derivatives (Benzoquinone, Trimethylbenzenes), and Nitrosamines - may contribute to chronic fatigue, lethargy, and impaired growth by damaging DNA, disrupting mitochondrial energy metabolism, and straining immune regulation.

The post-sound improvements highlight the potential of vibrational interventions to reduce toxic sensitivity and support recovery of metabolic and developmental processes.