About Our technology or how we create sound patterns.
“Your genes are a musical score. Play them right.”
Thank you for continuing to explore our project. As mentioned earlier, the core structure of DNA consists of nucleotides, which are further divided into four types: adenine, thymine, guanine, and cytosine.
Through years of research, we have learned to modulate signals from adenine, thymine, guanine, and cytosine within a specific frequency spectrum that the nervous system can interpret. We developed software capable of converting nucleotide letter codes into sound patterns, while preserving the precise codon reading sequence. This became the foundation of the DNA|Sound Pattern project, and a single gene’s nucleotide sequence became the basis for the DSP|SET product.
A DNA sound pattern is a product that interprets the nucleotide sequence in a DNA molecule as a sound wave, matching it to specific brain-recognizable frequencies. Thus, the sequence of DNA bases is “translated” into a sequence of sounds, creating a unique product.
The encoding mechanism is an exceptionally efficient part of memory formation, for which the nervous system is perfectly adapted
Below we provide an example of a gene segment where each nucleotide (A, T, G, C) is assigned a specific frequency:
A — Hz ↑
T — Hz ←
G — Hz ↓
C — Hz →
CAA TGG CCT CAA ACT CAT GCT GCT CCT
→↑↑ ←↓↓ →→← →↑↑ ↑→← →↑← ↓→← ↓→← →→←
On which frequencies does DNA|Sound Pattern operate?
The DSP|Video SET, freely available on platforms like YouTube, TikTok, and Telegram, is a video clip containing universal DNA sound patterns, which include modulated sharp waves and ripple rhythms.
- Sharp waves are short-duration (50–120 ms) high-amplitude oscillations in the local field potential of the hippocampus. They are associated with memory consolidation processes, where information is transferred from short-term to long-term memory. They may also play a role in memory reactivation during sleep.
- Ripple rhythms are high-frequency oscillations ranging from 100–250 Hz, with peaks up to 500 Hz, which accompany sharp waves. They are linked to the synchronous activity of pyramidal neurons and interneurons. Ripple rhythms play a key role in strengthening synaptic connections and organizing information in neural networks. They are also associated with memory reactivation during both sleep and wakefulness.
Why these specific frequencies?
Sharp waves and ripples are often observed together: sharp waves provide a “framework” for high-frequency ripples, which, in turn, ensure precise synchronization of neural activity. This combination is crucial for efficient information transfer and storage in the brain.
DSP|AUDIO SET available to club members
DSP|Audio Set is an easy-to-use audio product containing DNA sound patterns that operate on various brainwave rhythms (delta, theta, alpha, beta, gamma). This product is available exclusively to members of a private club, where each individual can select the rhythm best suited for their needs.
- Delta waves (0.5–4 Hz) – Associated with deep sleep, physical recovery, and regenerative processes. Neural connections in this range may form during rest and recovery.
- Theta waves (4–8 Hz) – Linked to drowsiness, daydreaming, creativity, and emotional processing. Neural connections in this range may form in relation to learning and memory.
- Alpha waves (8–12 Hz) – Connected to a relaxed state, meditation, and calm wakefulness. Neural connections in this range may strengthen during rest and relaxation.
- Beta waves (12–30 Hz) – Associated with active wakefulness, focus, logical thinking, and problem-solving. Neural connections in this range form during intense mental activity.
- Gamma waves (30–100 Hz) – Linked to high cognitive activity, information processing, memory, and awareness. Neural connections in this range may form during intense mental work and information integration.
Why do we use different rhythms?
The formation of neural connections (neuroplasticity) occurs through synchronization of neuronal activity at different frequencies. Depending on which DSP|SET you use, club members can choose the required rhythm for more effective application of our product.
For example:
- Learning new skills and memorization are often associated with theta and gamma activity,
- While structural recovery and memory consolidation are linked to delta and theta ranges.
«For each DSP|SET, you will find descriptions and recommendations for rhythm selection, but at the same time, you have the opportunity to experiment with different rhythms and choose the most effective usage pattern for yourself.»
DSP|AUDIO SET RELAX — convenient-to-use sound patterns that, in addition to basic rhythms, include relaxing music to distract your conscious mind and help you look within yourself as deeply as you desire. This product makes meditation easy and is ideal for those just beginning their journey of self-discovery and self-improvement.
What problem does DNA|Sound Pattern solve?
The main task of the product is to transmit modulated DNA signals with sets of nucleotide sequences without distortion or attenuation, using data obtained by us from global genome databases.
«Genome databases (or genomic databases) are organized global repositories of genetic information containing data on DNA sequences, genes, mutations and other features of genomes of various organisms.»
Thus, each DSP|SET acts as an accumulator of nucleotide sequences, creating a dynamic structure that enters the sensory system as an input signal. Through repetition, it forms new or strengthens existing neural connections, influencing your biochemical processes and improving physical and mental health.
It is important to understand that if you don’t feel changes, it means this section of the neural circuit is functioning correctly, since the modulated signal contains accurate information about the nucleotide sequence.
To summarize, the process of changing or forming new neural connections reaches completion through repetition of the input signal, which compares:
- The structure of neural activity caused by the input signal
- With the excitation structure arising in operational neurons
When both dynamic structures match, the testing cell produces an output signal; otherwise, the tuning process continues through repetition.
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We hope the information you’ve reviewed wasn’t too complex and has helped you reflect on yourself – something we’re truly pleased about. Allow us to conclude our project description with practical recommendations for using our product.