Saturday, August 10, 2013

How We Learn, Literally.






Brain neuron

Normal Neurotransmission:  

     The cells in the brain can send signals from one region of the brain to another.   Nerve cells communicate with each other at a region between them called a synapse.  At the synapse, signals move from the one neuron (sending cell) to another neuron (receiving cell).  The small space between the two cells, the synaptic cleft, is where communication takes place.  The cell that will send the message is loaded with sacs called vesicles that are filled with neurotransmitter molecules.  There are many types of neurotransmitters.  The cells that receive the message are coated with receptors specific for a particular neurotransmitter.   An electrical impulse triggers the vesicles to release their content into the synaptic cleft.  Once the neurotransmitter molecules are released into the synaptic cleft, they collide with and lock into the receptor molecules on the receiving cells.  When the neurotransmitter is docked, the receptor sets into motion a cascade of chemical reactions resulting in the production of a second messenger molecule.  Once the neurotransmitter has done its job it is released from the receptor and travels back to the sending cell through reuptake transporters.  It is either repackaged for reuse or broken down.  Back in the receiving cell, the second messenger initiates a nerve impulse which travels down the axon of the neuron.   Once the impulse reaches the end of the neuron, vesicles with neurotransmitter are stimulated and the process starts over again.  The receiving cell becomes a sending cell.  An impulse will stop if there are too few neurotransmitters to bind receptors or if the neurotransmitter is inhibitory in nature, preventing further reaction.   We are born capable of normal neurotransmission.
 

Synapse - vesicles release neurotransmitter
 
 
 
 
 
 
 
 

 
 
 
 
Plasticity

     Plasticity is the capacity of the nervous system to develop new neuronal connections.  This includes the ability to change and adapt, especially the ability of the central nervous system to acquire alternative pathways for sensory perception or motor skills.  Neuroplasticity defines the ability of the nervous system to change its capabilities by experience and plays a major role in compensating for the loss of neurons with age.

 
Nerve cell
 
 
 
 

     Following birth, the brain of a newborn is flooded with information from the baby's sense organs.  This sensory information must somehow make it back to the brain where it can be processed. To do so, nerve cells must make connections with one another, transmitting the impulses to the brain. like a basic telephone trunk line strung between cities, the newborn's genes instruct the "pathway" to the correct area of the brain from a particular nerve cell. For example, nerve cells in the retina of the eye send impulses to the primary visual area in the occipital lobe of the brain and not to the area of language production in the left posterior temporal lobe. The basic trunk lines have been established, but the specific connections from one house to another require additional signals.
 

     Over the first few years of life, the brain grows rapidly. As each neuron matures, it sends out multiple branches (axons, which send information out, and dendrites, which take in information), increasing the number of synaptic contacts and laying the specific connections from house to house, or in the case of the brain, from neuron to neuron. At birth, each neuron in the cerebral cortex has approximately 2,500 synapses. By the time an infant is two or three years old, the number of synapses is approximately 15,000 synapses per neuron. This amount is about twice that of the average adult brain. As we age, old connections are deleted through a process called synaptic pruning.

     Synaptic pruning eliminates weaker synaptic contacts while stronger connections are kept and strengthened. Experience determines which connections will be strengthened and which will be pruned; connections that have been activated (used) most frequently are preserved. Neurons must have a purpose to survive. Without a purpose, neurons die through a process called apoptosis in which neurons that do not receive or transmit information become damaged and die. Ineffective or weak connections are "pruned" in much the same way a gardener would prune a tree or bush, giving the plant the desired shape. It is plasticity that enables the process of developing and pruning connections, allowing the brain to adapt itself to its environment.

 

Plasticity of Learning and Memory

     It was once believed that as we aged, the brain's networks became fixed. In the past two decades, however, an enormous amount of research has revealed that the brain never stops changing and adjusting.  Learning is the ability to acquire new knowledge or skills through instruction or experience. Memory is the process by which that knowledge is retained over time. The capacity of the brain to change with learning is plasticity.  At least two types of modifications occur in the brain with learning.  First, one sees a change in the internal structure of the neurons, the most notable being in the area of synapses.  Second there is an increase in the number of synapses between neurons.

     Initially, newly learned data are "stored" in short-term memory, which is a temporary ability to recall a few pieces of information. Some evidence supports the concept that short-term memory depends upon electrical and chemical events in the brain as opposed to structural changes such as the formation of new synapses.  One theory of short-term memory states that memories may be caused by "reverberating" neuronal circuits.  This means an incoming nerve impulse stimulates the first neuron which stimulates the second, and so on, with branches from the second neuron synapsing with the first.   After a period of time, information may be moved into a more permanent type of memory, long-term memory, which is the result of anatomical or biochemical changes that occur in the brain (ie learning).

 

Injury-induced Plasticity

      During brain repair following injury, plastic changes are geared towards maximizing function in spite of the damaged brain. In studies involving rats in which one area of the brain was damaged, brain cells surrounding the damaged area underwent changes in their function and shape that allowed them to take on the functions of the damaged cells. Although this phenomenon has not been widely studied in humans, data indicate that similar (though less effective) changes occur in human brains following injury.




     We are a long way from being able to safely manipulate neural growth and behavior.  Perhaps the intricacies and complexities of the human neural networks make the task an impossible one. Or if not impossible, perhaps limited.  But there are now known ways to influence, beyond a doubt, improved function to some degree in some systems.  Intuitively we have known this for centuries.  This is why we have practiced anything to become “better”.  Only now we “know” more about why it is worthwhile to practice.  And perhaps we are learning ways to manipulate practice.  The list of clinical examples is long, showing how healing, performance, growth and development can all be enhanced through optimal neural learning.  Do the research if you find yourself intrigued.  If overwhelmed by the concept, well, just keep practicing.  Don’t worry about why it works.