There are three parts of the brain that are the most important to kinesthetic and skill learning. The
basal ganglia,
cerebral cortex, and the
cerebellum all play equally important roles in the ability to learn new skills and master them. The basal ganglia are a collection of ganglia (clusters of neurons) that lie at the base of the forebrain. Through these types of technologies, we are now able to see and study what happens in the process of learning. In different tests performed the brain being imaged showed a greater blood flow and activation to that area of the brain being stimulated through different activities such as finger tapping in a specific sequence. It has been revealed that the process at the beginning of learning a new skill happens quickly, and later on slows down to almost a plateau. This process can also be referred to as The Law of Learning. The slower learning showed in the FMRI that in the cerebral cortex this was when the long term learning was occurring, suggesting that the structural changes in the cortex reflect the enhancement of skill memories during later stages of training. When a person studies a skill for a longer duration of time, but in a shorter amount of time they will learn quickly, but also only retain the information into their
short-term memory. Just like studying for an exam; if a student tries to learn everything the night before, it will not stick in the long run. If a person studies a skill for a shorter duration of time, but more frequently and long-term, their brain will retain this information much longer as it is stored in the
long-term memory. Functional and structural studies of the brain have revealed a vast interconnectivity between diverse regions of the cerebral cortex. For example, large numbers of axons interconnect the posterior sensory areas serving vision, audition, and touch with anterior motor regions. Constant communication between sensation and movement makes sense, because to execute smooth movement through the environment, movement must be continuously integrated with knowledge about one's surroundings obtained via sensory perception. The cerebral cortex plays a role in allowing humans to do this. The cerebellum is critical to the ability for a human or animal to be able to regulate movement. This area of the brain wraps around the brain stem and is very densely packed with neurons and neural connections. This part of the brain is involved in timing as well as movement. It assists in predicting events, especially in the formation, execution, and timing of conditioned responses. The cerebellum plays a very important role in all forms of kinesthetic learning and motor function. For a ballerina, it is important to be able to control their movements and time it exactly right for their routine. For a football player it is important to be able to regulate movement when running throwing, and being able to have control over where the ball goes as well as the timing of it. And all three of these important systems in the brain function together as a team, one not being more important than the other. They work together to allow for responding to sensory events, timing, controlling physical actions, and more. However, it is important to remember that unless a person is actively practicing, these parts of the brain won't help them get to their full potential. Alterations in the brain that occur during learning seem to make the nerve cells more efficient or powerful. Studies have shown that animals raised in complex environments have a greater volume of capillaries per nerve cell—and therefore a greater supply of blood to the brain—than the caged animals, regardless of whether the caged animal lived alone or with companions. Overall, these studies depict an orchestrated pattern of increased capacity in the brain that depends on experience. ==See also==