Dr. Robert F. Mullen
Director/ReChanneling

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“Dr. Mullen is doing impressive work helping the world. He is the
pioneer of proactive neuroplasticity utilizing DRNI—deliberate,
repetitive, neural information.” — WeVoice (Madrid)

Neuroplasticity is evidence of our brain’s constant adaptation to learning. Scientists refer to the process as structural remodeling of the brain. It is what makes learning and registering new experiences possible. All information notifies our neural network to realign, generating a correlated change in behavior and perspective. 

What is significant is our ability to dramatically accelerate learning by consciously compelling our brain to repattern its neural circuitry. Deliberate, repetitive, neural information (DRNI) empowers us to proactively transform our thoughts and behaviors, creating healthy new mindsets, skills, and abilities. 

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Reactive neuroplasticity is our brain’s natural adaption to information. Information includes thought, behavior, experience, and sensation. Active neuroplasticity is cognitive pursuits such as engaging in social interaction, teaching, aerobics, and creating. Proactive neuroplasticity is the most effective means of learning and unlearning because the regimen of deliberate, repetitive neural input of information accelerates and consolidates the brain’s restructuring. 

Neurons, the core components of our brain and central nervous system, convey information through electrical activity. The input of information causes a receptor neuron to fire. Each firing stimulates a presynaptic or sensory neuron that, depending upon the integrity of the information, forwards it via an axon or connecting pathway to a synapse. The signal is picked up by the postsynaptic neuron’s hairlike dendrites that forward the information to the nucleus of the cell body. Continuous electrical energy impulses engage millions of participating neurons, causing a cellular chain reaction in multiple interconnected areas of our brain.  

A Brief History

The science of neuroplasticity was identified in the 1960s from research into the rejuvenation of brain functioning after a massive stroke. Before that, researchers believed that neurogenesis, or the creation of new neurons, ceased shortly after birth. Our brain’s physical structure was assumed to be permanent by early childhood. 

Today, we recognize that our neural pathways are not fixed but dynamic and malleable. The human brain retains the capacity to continually reorganize pathways and create new connections and neurons to expedite learning.

Neurons do not act by themselves but through neural circuits that strengthen or weaken their connections based on electrical activity. The deliberate, repetitious, input of information impels neurons to fire repeatedly, causing them to wire together. The more repetitions, the more robust the new connection. This is Hebbian Learning.

Hebbian Learning

Synaptic connections consolidate when two or more neurons are activated contiguously. Neural circuits are like muscles, the more repetitions, the more durable the connection. Hebb’s rule of neuroplasticity states, neurons that fire together wire together. When multiple neurons wire together, they create more receptor and sensory neurons. Repeated firing strengthens and solidifies the pathways between neurons. The activity of the axon pathway is heightened, causing the synapses to accelerate neurotransmissions of pleasurable and motivating hormones.

We not only prompt our neural network to restructure by deliberately inputting information, but through repetition, we cause circuits to strengthen and realign, speeding up the process of learning and unlearning. 

What happens when multiple neurons wire together? Every input of information, intentional or otherwise, causes a receptor neuron to fire. Each time a neuron fires, it reshapes and strengthens the axon connection and the neural bond. Repeated neural input creates multiple connections between receptor, sensory, and relay neurons, attracting other neurons. An increase in learning efficacy arises from the sensory neuron’s repeated and persistent stimulation of the postsynaptic cell. Postsynaptic neurons multiply, amplifying the positive or negative energy of the information. Energy is the size, amount, or degree of that which passes from one atom to another. The activity of the axon pathway heightens, prompting the synapses to increase and accelerate the release of hormones that generate the commitment, persistence, and perseverance useful to recovery or the pursuit of personal goals and objectives.

The consequence of DRNI over an extended period is obvious. Multiple firings substantially accelerate and consolidate learning. In addition, DRNI activates long-term potentiation, which increases the strength of the nerve impulses along the connecting pathways, generating more energy. Deliberate, repetitive, neural information generates higher levels of BDNF (brain-derived neurotrophic factors) proteins associated with improved cognitive functioning, mental health, and memory. 

We know how challenging it is to change, to remove ourselves from hostile environments, and to break habits that interfere with our optimum functioning. We are physiologically hard-wired to resist anything that jeopardizes our status quo. Our brain’s inertia senses and repels changes, and our basal ganglia resist any modification in behavior patterns. DRNI empowers us to assume accountability for our emotional well-being and quality of life by proactively controlling the input of information.

Neural Reciprocity

Neural restructuring does not happen overnight. Recovery-remission is a year or more in recovery utilizing appropriate tools and techniques. Meeting personal goals and objectives takes persistence, perseverance, and patience. Substance abuse programs recommend nurturing a plant or tropical fish during the first year before contemplating a personal relationship. The successful pursuit of any ambition varies by individual and is subject to multiple factors. However, once we begin the process of DRNI, progress is exponential. Our brain reciprocates our efforts in abundance because every viable input of information engages millions of neurons with their own energy transmission. 

DRNI plays a crucial role in reciprocity. The chain reaction generated by a single neural receptor involves millions of neurons that amplify energy on a massive scale. The reciprocating energy from DRNI is vastly more abundant because of the repeated firing by the neuron receptor. Positive energy in, positive energy multiplied millions of times, positive energy reciprocated in abundance. 

Conversely, negative energy in, negative energy multiplied millions of times, negative energy is reciprocated in abundance. 

Proactive Neuroplasticity YouTube Series

Our brain does not think; it is an organic reciprocator that provides the means for us to think. Its function is the maintenance of our heartbeat, nervous system, and blood flow. It tells us when to breathe, stimulates thirst, and controls our weight and digestion.

Neurotransmissions

Because our brain does not distinguish healthy from toxic information, the natural neurotransmission of pleasurable and motivational hormones happens whether we feed it self-destructive or constructive information. That’s one of the reasons breaking a habit, keeping to a resolution, or recovering is challenging. The power of DRNI is that a regimen of positive, repetitive input can compensate for decades of irrational, self-destructive thoughts and behaviors, and provide the mental and emotional wherewithal to effectively pursue our personal goals and objectives. 

We receive neurotransmissions of GABA for relaxation, dopamine for pleasure and motivation, endorphins to boost our self-esteem, and serotonin for a sense of well-being. Acetylcholine supports neuroplasticity, glutamate enhances our memory, and noradrenalin improves concentration. In addition, information impacts the fear and anxiety-provoking hormones, cortisol and adrenaline. When we input negative information, our brain naturally releases neurotransmitters that support that negativity. 

Conversely, every time we provide positive information, our brain releases hormones that make us feel viable and productive, subverting the negative energy channeled by the things that impede our potential. 

Constructing Our Information

Deliberate neural information is differentiated by goal, objectives, and content, which determine the integrity of the information and its correlation to durability and learning efficacy. The most effective information is calculated and specific to our intention. Are we challenging the negative thoughts and behaviors of our dysfunction? Are we reaffirming the character strengths and virtues that support recovery and transformation? Are we focused on a specific challenge? What is our end goal – the personal milestone we want to achieve? 

The process is theoretically simple but challenging, due to the commitment and endurance required for the long-term, repetitive process. We do not don tennis shorts and advance to Wimbledon without decades of practice with racket and balls; philharmonics cater to pianists who have spent years at the keyboard. DRNI requires a calculated regimen of deliberate, repetitive, neural information that is not only tedious but also fails to deliver immediate tangible results, causing us to readily concede defeat and abandon hope in this era of instant gratification.

Fortunately, the universal law of compensation anticipates this. The positive impact of proactive neuroplasticity is exponential due to the abundant reciprocation of positive energy and the neurotransmission of hormones that generate motivation, persistence, and perseverance. Proactive neuroplasticity utilizing DRNI dramatically mitigates symptoms of physiological dysfunction and discomfort and advances the pursuit of goals and objectives.

To quote Noble Prize-winning author, André Gide “There are many things that seem impossible only so long as one does not attempt them.”

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