Learning Breakthrough

A January article in the online Journal, Behavioral Medicine Report and a study published in the Journal “Nueron” describe new understandings about the synaptic connections that underlie what we commonly call "neuroplasticity.”

In an informative article, Study Shows Map of Brain Connectivity Changes During Development, Christophey Fisher, PhD, points to two important issues:

“Connected highways of nerve cells carry information to and from different areas of the brain and the rest of the nervous system. Scientists are trying to draw a complete atlas of these connections – sometimes referred to as the “connectome” – to gain a better understanding of how the brain functions in health and disease.”

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“Another surprise was that when growing dendrites go searching for potential partners, they reach out to axon boutons that had previously connected with other dendrites – “as if they were attracted to a restaurant that already has a line at the door, rather than trying a brand new one,” says Cline.”

These observations reinforce the work that Frank Belgau describes in Chapter 26 of his book A LIFE IN BALANCE. The Learning Breakthrough Program is based on Belgau’s model about the entrainment potential of synaptic responses (trainability). His design of a variable difficulty balance challenge combined with repetitive perceptual motor skills activities gives us a real world training tool to effect neuroplasticity changes.

For detailed technical information refer to Dynamic Formation of Functional Networks by Synchronization.

How juggling rewires your brain | COSMOS magazine.

PARIS: Neuroscientists have discovered that learning to juggle causes changes in white matter, the nerve strands which help different parts of the brain communicate with each other.

University of Oxford researchers recruited 48 healthy young adults who were unable to juggle and put them in a functional magnetic resonance imaging (fMRI) scanner to get a cross-section map of their brain.

Half the volunteers then underwent a six-week training period to learn how to juggle, during which they were also encouraged to practice for 30 minutes a day.

At the end, they were all able to perform at least two cycles of the classic three-ball "cascade." They were then scanned again, as were their 24 non-juggling counterparts.

Among the juggling group, imaging showed important changes in white matter, the bundle of long nerve fibres that carry electrical signals between nerve cells and connect different areas of the brain. So-called grey matter consists of areas of nerve cells where the brain processes information.

The findings, published online on Sunday by Nature Neuroscience, are important, for they suggest the brain remains "plastic" - or mobile and adaptable - beyond childhood.

via How juggling rewires your brain | COSMOS magazine.

Here's another great example of neuroplasticity impacts derived from motor skills training. Cortical expressions of proprioceptive responses over time are around us every day and form the basis of the EXPERIENTIAL part of neuroplastic changes. The implications for athletic performance and rehab are tremendous and the article below gives some good insight.

Motor Learning and Neuroplasticity in Rehabiliation.

Here’s a brief summary of an excellent paper by Boudreau et al from Manual Therapy. Patrick Ward and I had a brief discussion about this paper and since we found great benefit in its contents, I thought I would share some of it with you.

The purpose of this paper was to summarize several important aspects of motor-skill training for enhancing musculoskeletal rehabilitation.

Cortical Neuroplasticity: a dynamic feature of life that encompasses functional or morphological change in properties of neurons (connection strength, represenational patterns, neuron reorganization.

• Positive changes: improvements in motor performance


• Negative changes: decreases in performance, such as in the presence of chronic pain (low back pain resulting in decreased cortical spinal drive in lumbar musculature and subsequent shift in somatosensory representation)

This video shows Dr. Frank Belgau relating the connection between neural network efficiency and resolution of neurons being mathematically connected to the number of neurons involved in the difficulty of a task. This concept is at the core of Learning Breakthrough's "variable difficulty balance platform" which Dr. Belgau credits as his most important single contribution to the world of learning treatments. It is the main reason that Learning Breakthrough has succeeded where other treatments have not. Don't get confused that the exercises of imitators is what makes a program like this work. Its the balance challenge, delivered over time and in a precise manner that generates the sought after neuroplasticity gains.