Neurochemical grounds

July 5, 2017

Neurochemical grounds of addiction. W have a solution for you at AWAREmed health center

Neurochemical grounds of addiction: The exhausted GABA

In order to understand the neurochemical grounds of addiction, it is important that we first understand how GABA operates. And to do so, we are going to speaking to doctor Dalal Akoury MD, President, and founder of the AWAREmed health and wellness resource center. And the submission she brakes the understanding as follows.

The neurons
The central nervous system (CNS)
Inhibitory neurotransmitters
Excitatory neurotransmitters

Having discussed the first two previously, we are going to progress with the remaining as follows:

Neurochemical grounds of addiction: Inhibitory Neurotransmitters

Some neurotransmitters act like a brake on a car.
They inhibit or slow down the actions of the neurons.
These are called inhibitory neurotransmitters.
Other neurotransmitters act like an accelerator.
They increase the speed of the actions of the neurons. These are called excitatory neurotransmitters.
GABA is the major inhibitory neurotransmitter in the brain.

Neurochemical grounds of addiction: Excitatory Neurotransmitters

Excitatory neurotransmitters are vital to:
- Help us stay alerted
- Maintain our normal memory functions
- Maintain our co-ordination
- Maintain normal emotional responses
- Maintain our heart rate
- Maintain our blood pressure
Glutamate (a common amino acid) is the major excitatory neurotransmitter in the brain.

Which neurotransmitters are released?

If there is something that creates:
- Anxiety
- A feeling of panic
- Other stress
Excitatory neurotransmitters are released and a person can feel:
- Restlessness
- Higher than normal irritability
- Rapid heartbeats
- High blood pressure
- Insomnia
- Even seizures.

The role of GABA in the brain

Glutamate speeds things up and when they are going too fast, GABA slows them back down.
If there is a problem with the GABA in our brains, the neurons fire more and more, increasing the speed of the processes in the brain?

Neurochemical grounds of addiction: How GABA works

When GABA binds to a nerve cell receptor, it opens the nerve cell so that chloride ions present in the brain are allowed to move into the nerve cell to slow the activity of the cell, and the person normally experiences a calming feeling. For example, if our brain produces more excitatory neurotransmitters like norepinephrine or epinephrine (adrenaline) than normal, we can become anxious or have more stress than normal. And when the brain is working normally, it will produce more GABA thereby slowing down the actions in the brain and thus have a calming and relaxing effect on us.

Finally, this article will go a long way in helping you do the right thing with your life. In doing so certain professional decisions will have to be made and to do this, seeking for the expert opinion will be necessary. And that is where doctor Dalal Akoury and her team of experts come in. the lever of professionalism at this facility (AWAREmed health center) speaks for itself since doctor Akoury’s practice focuses on personalized medicine through healthy lifestyle choices that deal with primary prevention and underlying causes instead of patching up symptoms. This is what you need and calling her on telephone number 843 213 1480 should be your starting point for the total life transformation.

Neurochemical grounds of addiction: The exhausted GABA

Neurochemical roots of addiction

July 5, 2017

Neurochemical roots of addiction needs to be identified and corrected

Neurochemical roots of addiction: The depleted GABA

For a long time, various forms of addictions have been taken to be just as a result of social problems and sometimes even decisions or choices we make in life. Yes, this may be true but we need to take a moment and look into this problem more critically to find facts about the neurochemical basis of addiction. Doctor Dalal Akoury MD, President, and founder of the AWAREmed health and wellness resource center says that it’s good that modern addiction medicine now recognizes that substance dependency of any kind is a disease process of the brain that features lowered dopamine and glutamate neurotransmitter levels. Importantly, as more legitimate research is done in this field of addiction medicine whose experimental basis is beginning to gain ground, models of neurochemical roots of addiction in the future may also feature lowered levels of GABA as the disease progresses. To understand this neurotransmitter (GABA) it will be necessary that we try to define some of the terms associated with it and appreciate the roles and functions of GABA in totality.

The use of GABA

Because of our unique DNA and the way that each of us metabolizes drugs, each of us may have different amounts of GABA in the brain but we are still considered to be operating “normally.” Unfortunately, there are no accepted medical tests to determine if we have too much or too little GABA activity. It appears that people who are nutritionally deficit and dehydrated often have problems with the operation of GABA in their brains. Since almost all of our patients are nutritionally deficient and dehydrated when they arrive at our facility, we have always implemented the addition of GABA to the IV therapy given to patients. The purpose is to provide a more natural boost to the GABA in the brain and to allow the calming effect of GABA to make the detoxification process more comfortable. Let us now understand how GABA operates by defining these terms.

Neurochemical roots of addiction: The neuron

A neuron is another name for a nerve cell.
Nerve cells float in the fluid.
Each neuron has an axon a thread-like part of the cell that sends signals from the cell body and a dendrite a part of the cell that receives signals from other neurons.
The neurons are not touching and the space between the cells is called the synapse.
Electrical signals are sent through the synapse to a receptor, a place on a cell that can produce a certain effect like the production of adrenaline if someone is frightened.

Neurochemical roots of addiction: The central nervous system (CNS)

The CNS is composed of the brain and the spinal cord.
The CNS transmits signals to the rest of the body using chemical messengers called neurotransmitters.
Neurotransmitters are stored in vesicles—hollow sac-like structures inside the cells.
These neurotransmitters carry a message from a neuron to receptors on another neuron.
The action of the neurotransmitters on the receptors has been likened to a key being inserted in a lock.
When the key is turned the lock opens and the neurotransmitters activate the receptors which in turn create an effect in the body.
Then many of the neurotransmitters return to the releasing vesicles to be used again.

Finally, you can always talk to us by calling doctor Akoury on telephone number 843 213 1480 to help you with any concerns you may have.

Neurochemical roots of addiction: The depleted GABA

Neurons signals and addiction

May 13, 2017

Neurons signals and addiction. In fact, neurons are the primary communication unit of the brain and must not be contaminated with drugs

Neurons signals and addiction: The brain chemistry

The neuron is the primary unit of communication within the brain. A single neuron is extremely tiny. Experts are estimating that there are over 100 billion neurons in the human brain. With that, you can imagine just how complex and distinct your brain is from the person next to you. And because good communication is of two ways where we both listen (receive information) and at the same time we also speak (send information). The same is applicable to the brain’s communication system with the neurons having the ability to both send and receive communication signals. The dendrite is the portion of neuron signals that typically receives information (listens) while the axon is a portion of the neuron signals that sends out information (speaks).

Neurons signals and addiction: Neurotransmitters

When humans communicate with each other, we typically use words and gestures. The different parts of the brain communicate with each other using electrical signals. Neurons use electrical pulses to send their communication signals. These electrical impulses are called action potentials. When neuron fire, the action potential travels down the neuron’s axon where it ends. At the end of the axon is the axon terminal or pre-synapse. In this area, special chemical messengers called neurotransmitters and neuromodulators lay in wait. These are stored in specialized capsules called vesicles. The action potential causes the release of these chemical messengers into an open space between one neuron’s axon and the next neurons’ dendrites. This open space is the synaptic cleft. At the other side of the synaptic cleft is the post-synapse that is formed by the dendrites of connecting neurons. In the post-synapse, there are special receptors that receive the neurotransmitters.

Receptors and neurotransmitters function in a way that is similar to a keyhole and key. Receptors are like keyholes and neurotransmitters are like the keys. When neurotransmitters fit into the receptors it is called binding. Once a neurotransmitter is bound to a receptor, the key turns the lock. Once the lock opens, it communicates with the receiving neuron’s dendrites. In the post-synapse, there may be many different receptors (many different shaped keyholes). However, a particular neurotransmitter may be able to fit into (bind to) several different receptors types. This is similar to the way a single key can open several different locks. The particular receptor type determines the type of signal that is transmitted. Thus, the receptor type is often more critical to the communication than the particular neurotransmitter.

It may be easiest to visualize this communication as a single chain of events: First, a neuron sends an electrical impulse (action potential) down the axon. Next, the electrical impulse causes chemicals (neurotransmitters and neuromodulators) to be released into space between two neurons. Then these chemicals can signal the next neuron to send an electrical impulse and so on. This electrochemical process forms the brain’s communication system. In conclusion, it is evident that the functions of the brain in communication are very sensitive and any alteration caused by drugs addiction can have far-reaching effects. Therefore before we get there, we must do all it takes to prevent or correct as soon as it is necessary. For this reason, it will be prudent that you schedule an appointment with doctor Dalal Akoury MD a veteran addiction expert who is also the founder of AWAREmed Health and Wellness Resource Center for the commencement of your addiction recovery process.

Neurons signals and addiction: The brain chemistry

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Brain activities network flows

April 11, 2017

Brain activities network flows uninterrupted only when substances of abuse are kept at bay

Brain activities network flows: How drugs affect the brain?

Drugs and misuse of alcohol are the two primary reasons why many mental health problems are being seen today in the lives of young people. Because of that, it is important that we appreciate the brain activities network flows. Alcohol and drug abuse impacts on the brains health badly. Being a complex communication network of numerous neurons also known as nerve cells, doctor Dalal Akoury a veteran addiction expert explains that, in just a minute, the neurons can pass tonnes and tonnes of communication within the brain. Spinal column and the nerves. That is to say, the nerve network coordinates everything in the body system. According to the experts from AWAREmed Health and Wellness Resource Center which is an addiction treatment facility established by doctor Dalal Akoury, for us to understand brain communication network flows well, understanding the functions of these networks is very essential. Like for instance:

Brain activities network flows: Neurons

It will interest you to note that the human brain contains not less than100 billion neurons nerve cells working continuously remitting and receiving message signals. The flow is in a way that within a neuron, communications flows from the cell body down the axon through the axon terminal in the form of electrical impulses. The information is then sent to other neurons with the help of neurotransmitters. This flow needs the brain to be in good health without any impurities inform of drugs says doctor Akoury. As we progress into the discussion, drugs kill the brain and therefore, if you or anyone you know is struggling with drug addiction, your brain communication network flows will be ineffective and action needs to be taken immediately. You can talk to doctor Akoury today on telephone number 843 213 1480 for further direction.

Neurotransmitters
These are the brain chemical envoys or messengers that enables information to move from one neuron to another by creating chemical messengers known as neurotransmitters. From this point the axon terminal releases neurotransmitters that travel across the space also known as the synapse to nearby neurons. Then the transmitter attaches to receptors on the nearby neuron.

Receptors

These are brains chemical recipients/receivers whereby when the neurotransmitter approaches the nearby neuron, it attaches it to a special site on that neuron known as a receptor. For clarity, a neurotransmitter and its receptor functions the same way a key and lock operates. That is to say, a very specific mechanism makes sure that each receptor will forward the right message only after interacting with the right kind of neurotransmitter.

Transporters

The moment the neurotransmitters do their job, they are pulled back into their original neuron by transporters. This recycling process shuts off the signal between the neurons.

Finally, four networks are very essential in the proper functionality of the brain. Any attack on their well-being by way of alcohol and drug abuse immediately disrupts the brain communication network flows. You can make a decision now to keep a healthy brain by scheduling for an appointment with doctor Akoury for the commencement of your recovery process today.

Brain activities network flows: How drugs affect the brain?

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Brain unique functions and addiction

April 4, 2017

Brain unique functions and addiction have no relations and must not be compromised

Brain unique functions and addiction: Neurons and brain communication pathways

The study of some of the elements that cause health problems in our life can be very interesting. Understanding the brain unique functions and how it can be altered by addiction to various substances is very important. The brain communication pathways become the biggest victims whenever there is an attack resulting from drug abuse. The brain’s electro-chemical communication system is a communication system that sends information through a vast network of interconnecting neurons. Through this, the brain begins to develop a preferred or standard conduit of sending signals between neurons (neural pathways). Experts at AWAREmed Health and Wellness Resource Center under the able leadership of doctor Dalal Akoury MD President and founder of the facility can now confirm that in the past it was believed that the brain’s neural pathways will be completely formed by the time we reached adulthood.

Brain unique functions and addiction: Neurons adaptation to changing environments

Progressively the scientific findings have established that this is a continuous process and in fact, the human brain continues to create new neurons and form neural pathways throughout our entire lifespan. That is why neurons are seen as dynamic cells that are constantly adapting to changing circumstances. It, therefore, means that if an injury or damages happen to an individual’s brain (such as a stroke or injury) the neurons will make new communication route around the damaged area. Scientifically doctor Akoury reiterates that this ability of recreation of neurons is known as neuronal plasticity.

Brain unique functions and addiction: Neuronal plasticity

Doctor Akoury reiterates that neuroplasticity is responsible for the regulation of our learning processes which enables us to adapt to our surroundings conveniently. To better understand neuroplasticity let us consider using this illustration. The brain forms neural pathways in a way that is similar to the formation of a demarcated hiking pathway. The more we travel a path, the faster, easier, and more familiar that path becomes. As the routine continues it becomes more visible, smoother, and easier to travel on. And with time this becomes a preferred route for many. This is also how neural pathways are formed. With time the brain forms familiar neural pathways which then become habitual routes. And in the event that the familiar route is blocked the brain responds swiftly by forming a new route around the blockage.

From the illustration, suppose you walk through the bush each day to visit a friend. You use the same trail each time and one day as you travel along your familiar path, you discover a huge tree has fallen over. It’s blocking your passage. You will need to forge a new path to go around the tree. At first, this new path will be narrow, difficult, and slow. It might even be uncomfortable. However, with time, it will become a well-worn, comfortable path. It will be just as easy as the original path. This can be affected by the use of drugs in many ways and to avoid that, it is only logical that you schedule an appointment with doctor Akoury to help you in keeping your brain unique functions uninterrupted for continuity.

Brain unique functions and addiction: Neurons and brain communication pathways

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