Brain Wave & Yoga

Neurons communicate through electrochemical signals that are the basis for motor functions, thoughts, emotions, and behavior. These electrochemical signals—also called brainwaves—can be detected by placing sensitive sensors on the head/scalp. Brainwaves are functionally characterized as bandwidths and range from slow to fast, loud to subtle and simple to complex. Thus, our brainwaves change according to our behavior and the emotions that we display. Slower brainwave patterns indicate that the individual is tired, fatigued, sluggish, slow, or dreamy. Fast brainwave patterns are seen when an individual is alert, fast paced and generally in a hyper-moody behavior. While these are broad descriptions, there are brainwaves that are far more complex and reflecting various aspects of individuality. The list of brainwaves includes:

Delta Waves. These brainwaves are low frequency, high amplitude, deeply penetrating, slow brainwaves that are generated during deep meditation and dreamless sleep. The presence of delta waves indicates that the individual is no longer influenced by external impressions. Researchers note that people with health issues do better in this state, indicating the importance of deep sleep to the healing process. Delta wave activity is highest in infants and is the predominant brain wave in infants. Delta waves have been shown to decrease across the lifespan and especially in the older adults by which time deep sleep and delta waves may be entirely absent.

Theta Waves. These brainwaves are seen most often in dream sleep and also appear together with the delta waves in deep meditation. Theta waves appear during learning, memory acquisition, intuition, nightmares, and during emotional display. A person who daydreams presents a theta brainwave state. A person who is driving after a heavy meal or on a quiet freeway realizes that he/she is unable to recall the last five miles. This is theta wave in action. Individuals who ideate a lot can blame it on the theta waves. Theta waves are predominant on all those tasks that are done in an auto mode.

Alpha Waves. Being here and now or being in the present state marks the appearance of alpha brainwaves. They predominantly appear during the resting state and their appearance signals non-arousal, calmness, mind/body integration, and learning. A person who has completed a task and sits down to rest, takes time out to reflect, or takes a break from a meeting and walks in silence is often in an alpha state.

Beta Waves. These brainwaves are fast acting and dominate during the waking state and when we are alert, attentive, and engaged in mental activity. When the brain is stimulated or aroused, it generates beta waves that are characteristics of a mind that is engaged. Thus, an orator, a debater, a teacher, or a talk show host would all present beta waves in their brain when they are engaged in this form of activity.

These four brainwave states are common to the entire human species. Individuals of all ages experience these same brainwaves, which are consistent across race, cultures, countries, and boundaries. Thus, when we put the book down or switch off the TV, turn off the lights and close our eyes, our brainwaves shift from beta, to alpha, to theta and finally, when we fall into deep sleep, to delta.

But researchers have shown that even though one specific brainwave may predominate at any given time, depending on an individual’s activity, the remaining brainwaves will continue to be present albeit at low levels at all times. All the four brainwaves work in tandem and in sync with each other to determine an individual’s state of activity. However, as we age, the synchronicity with which these brainwaves function is lost. Sleep is also compromised in adulthood, which further aggravates the random behavior of the brainwaves, which partly explains why older adults are so forgetful. According to latest research studies, both delta and theta waves are out of sync in older people, which interrupt communication between the hippocampus-prefrontal cortex areas of our brains that are responsible for short and long-term memories.