ANALEMMA BRAINWAVE STUDY

ANALEMMA BRAINWAVE STUDY

In 2019, the Analemma team collaborated with a clinical laboratory specialising in neurotherapy to conduct a series of smaller experiments studying the effect of coherent water on the human brain.

Why did we opt for the brain?

The initial connection was evident in water. The brain, being our most water-dependent organ, consists of roughly 75% water, surpassing any other organ in the body. It seemed logical that coherent water would primarily reach this water-abundant tissue mass, providing us with a direct means to assess its influence. The second connection lay in the brain's functionality. Comprised of neurons, cells generating electrical currents for intercellular communication, the brain achieves coherence when its various regions communicate effectively. Conversely, when communication is hindered or disorderly, coherence is lost. This prompted the self-imposed inquiry: would organised (coherent) water affect the order (coherence) of the brain?

Before delving into the complexities, let's understand the essence of brainwaves.

When neurons communicate, they emit electrical pulses, essentially engaging in a conversation. During certain tasks or states, numerous neurons synchronize their activity, conveying similar messages.


Brainwaves, in essence, represent the amalgamation of these synchronised electrical pulses emitted by clusters of neurons. Remarkably, their intensity allows us to detect them through electrodes placed on the scalp.

There are four primary types of brainwaves, each categorised by its frequency. From the slow-paced delta waves associated with deep sleep to the fast-paced beta waves indicative of intense cognitive activity, these waves span a spectrum of mental states. Utilising techniques like quantitative electroencephalography (qEEG), neuroscientists can investigate real-time brain activity, observing how the mind and body respond to various stimuli. This approach also enables the assessment of how different substances impact brain function, aligning with the objectives of our 2019 research study.

 

What was measured?

During the experiments, qEEG electrodes were strategically positioned on 19 areas of the head to gauge brainwave activity across various brain regions. The analysis focused on two primary parameters:

1) POWER

Brainwave power provides insights into the level of activity across different frequencies in distinct brain regions during different tasks. For example, in healthy individuals, delta brainwaves exhibit heightened activity during sleep, spanning across the entire brain.

2) COHERENCE

Coherence serves as a metric for assessing the effectiveness of communication between different brain regions at particular frequencies. Optimal coherence indicates that distant brain areas are effectively communicating at that specific frequency, irrespective of overall power levels.

 

RESEARCH

Case Study 1:

Enhanced Delta Coherence
DOUBLE-BLIND PLACEBO-CONTROLLED TWIN STUDY

Two identical twins, both 19 years old, were each given a glass of water. Neither the twins nor the physician administering the water were aware of its type. Baseline qEEG measurements were taken before they drank the water, and within 10 minutes of consumption, a second qEEG measurement was conducted.

The visual representations below depict the delta coherence maps of the twins. The circles denote 19 specific brain locations, with colours indicating brainwave coherence relative to reference values from a healthy population. Blue signifies coherence levels below average, green denotes normal levels, and red indicates above-average levels.

The disparity in delta coherence levels between the twins is striking. Initially, both twins exhibited below-average coherence across most brain locations (depicted in blue). However, while the placebo had no discernible impact on brainwave coherence, consumption of Analemma water led to an immediate elevation in delta coherence. This resulted in predominantly average coherence levels across most brain locations (illustrated in green), a notable effect observed just 10 minutes after ingestion.


Case Study 2:

Reduced Delta Power: Investigating Immediate and Long-Term Effects

In our second case study, they delved into the delta brainwave patterns of a 68-year-old woman afflicted with a neurological disorder characterised by heightened delta activity. Typically, delta brainwaves are most active during deep sleep in healthy individuals. However, in this neurological condition, delta activity remains abnormally elevated even during waking hours. Given this significant shift in delta activity, we utilised it as a biomarker to evaluate the impact of Analemma water on her brain function.

Initially, we assessed the immediate effects of Analemma water using a methodology similar to the twin experiment.

Furthermore, the Analemma team conducted an analysis of the long-term effects of Analemma water. The participant continued her consumption of Analemma water for 51 consecutive days, during which her delta activity was measured on Days 1, 2, 9, 37, and 51.

 

RESULTS

RESULT 1 - Analemma water immediately affects delta power

The image below shows delta power maps of the 68 year-old participant before and after consuming Analemma water.

Only 10 minutes after drinking a glass of Analemma water, her delta brainwave power (1-3.5 Hz range) went from predominantly above average (red), into predominantly average (green).

RESULT 2 - Analemma water affects delta power long-term

The image below shows delta power maps of the 68 year-old participant during 51 days of continuous consumption of Analemma water.

The brain maps indicate that during this period, the participant’s delta brainwave activity gradually decreased, going from above average levels (red) measured on Day 1 toward average activity (yellow-to-green) by Day 51. It is important to note that these measurements were obtained in normal conditions (i.e. the participant didn’t consume Analemma water before the qEEG), indicating that the effect persisted over time.

As mentioned, delta brainwaves shouldn’t be active during waking hours. Certain neurological conditions, such as the one this woman was diagnosed with, are marked by increased drowsiness during the day and this is correlated with increased delta brainwaves. This is why this result is so incredible, as it points to an important positive effect on overall brain activity. Remarkably, when the study was finalised, the participant herself reported feeling less tired and more energised.

Brainwave patterns serve as robust indicators of healthy brain functionality. Although this investigation involved a limited number of participants, it unveiled tangible impacts of Analemma water on brain activity.

Throughout these trials, Analemma water exhibited its most notable influence on low-frequency delta brainwaves. The balanced activity of delta waves holds significance for facilitating restful sleep at night and maintaining alertness during the day. Furthermore, diminished coherence of delta brainwaves has been linked to various mood and behavioural disorders.

Within this context, our findings indicate a beneficial impact of consuming Analemma water on delta coherence. While the twin experiment served as merely an initial case study, it underscores the pivotal role of coherent water in fostering equilibrium and organisation within the brain. In an era where daily stressors can significantly impact our overall health and well-being, promoting order and harmony in the brain becomes paramount – and coherent water might represent a step in the right direction.

Moreover, this study encompassed additional experiments, exploring the potential of Analemma water in mitigating the adverse effects of cellphone radiation.

 

CLICK HERE TO PURCHASE YOUR ANALEMMA


Older post Newer post