Neuroplasticity is the ability of the brain to change throughout life. This means that your brain can physically and functionally change itself based on what you do or experience.
Why do we have it and how does it work?
Neuroplasticity is the brain's ability to rewire itself in response to experience, changing not only its structure but also its function.
What is Neuroplasticity? Neuroplasticity is basically the power of the brain to change over time. Scientists have known for quite some time that the brain can indeed grow new neurons. In addition, a severely damaged brain can also enhance the communication within one brain cell and another. This is what's called neuroplasticity.
How does neuroplasticity affect brain health? It can impact almost every area of the brain from cognitive function to physical health to mood regulation. In fact, many diseases and disorders have been linked to neuroplastic changes in the brain. Therefore, if you suffer from any of these diseases or disorders, it would be beneficial to treat them with natural supplements. These naturally formulated supplements work with the body's own processes and hormones to help restore optimal brain health.
Neurotransmitters: Neurotransmitters are chemical messengers that travel from one part of the brain to another. There are many different neurotransmitters that pass information from the nerve endings in the body to the brain. Neurotransmitters come in different forms such as epinephrine, norepinephrine, serotonin, dopamine, and GABA. The estrogen and progesterone that we produce naturally control the levels of these hormones throughout our bodies.
Estrogen: Women produce estrogen when they are in their childbearing years and menopause. However, in some people, estrogen production decreases after menopause. This decrease is one of the reasons that some women find that they have more mood swings and depression than others. For this reason, many researchers have been investigating what is neuroplasticity and how estrogen may play a role in protecting the brain against dementia.
Thyroid Hormones: One of the major hormones that affect brain function is the thyroid hormone. The thyroid gland produces both thyroxine and estradiol, which are both important hormones that control brain function. When these hormones are not produced properly, the brain cells can become overactive or oversecrete, causing many side effects including memory loss, decreased mental abilities, and brain shrinkage. In addition, high levels of cortisol have been found in those who suffer from depression and memory loss. One study found that high levels of cortisol were related to poor spatial skills in children, which is likely related to poor thyroid hormone functions.
Testosterone: Men produce testosterone when they are in puberty. Production of testosterone declines after menopause, which is when estrogen levels in the body begin to drop. In addition, there is a decline in the amount of DHEA, which is an estrogen metabolite. With these two hormones, the brain becomes more plastic and is better able to adapt to disease and environment. This allows the brain to maintain and improve its spatial memory function even after menopause and after hypogonadism is treated.
Adrenal Glands: The adrenal glands are located on top of the kidneys. The adrenal cortex produces hormones that regulate brain health and motivation. After stress or physical trauma, the adrenal glands help reduce feelings of anxiety and depression, which is linked to the cognitive decline seen in people with dementia. The research is beginning to show that these hormones may be activating pathways in the brain that control cognition and behavior.
What is Neuroplasticity? There are many different ways that aging humans use neuroplasticity to prevent dementia and Alzheimer's disease. These processes help the brain adapts to the environment and disease, which may protect against both Alzheimer's and dementia. However, it is important to note that all of these processes can go haywire at any point. It is not uncommon for them to go haywire together.
Stress and Cortisol Are Two Stress Regulators: One of the most intriguing theories on what is neuroplasticity deals with how stress and cortisol regulate brain plasticity. When people are under stress for long periods of time, they often go into a state of chronic arousal. This arousal, or fear response, is what scientists refer to as the fight or flight response. During this state, the adrenal glands produce and release large amounts of cortisol, which is the hormones of choice when one is confronted with extreme fear. It has been shown that cortisol increases the risk of depression, cardiovascular disease, and hypertension, and it also heightens the probability that the individual will develop Alzheimer's or dementia.
Another sign of what is neuroplasticity and what can lead to dementia is depression. When individuals are depressed, they often find themselves unable to think or focus. They also have a decreased production of certain brain chemicals, such as serotonin, another neurotransmitter, and norepinephrine, an adrenal gland stimulant. These changes can result in diminished memory, concentration, mood swings, and other mental disturbances.
Neuroplasticity is important in the formation and plasticity of the human brain, but it can also have dire consequences when it comes to preventing dementia and other mental disorders. When individuals are faced with stress and environmental threats, they can experience a state of chronic arousal, which can prematurely age them. However, there is hope because many effective supplements, such as Brain Boosters, are now available that can help restore the brain's plasticity and provide individuals with the tools they need to prevent the onset of dementia and other brain-related problems.
Solution: Neuroplasticity can be understood from two perspectives. First, as a biological phenomenon, it generally refers to any structural or functional change throughout the central nervous system. Second, as a term of art in neuroscience and psychology, it refers to a capability of the brain to reorganize itself by forming new neuronal connections throughout life