Air traffic controllers monitor the movements of thousands of flights — taking into account the types of aircraft used and the cargo carried — to destinations in real time. As well, in order to properly co-ordinate arrivals and departures, aircraft speeds must be constantly adjusted. Without this constant control adhering to clear navigation rules, chaos would invade the airspace.
My research in neurophysiology and neuroscience has shown me how the brain is a rich and complex biological system. Every day, it faces the same situation as an air traffic controller but on a completely different scale: it has to manage the incessant traffic of signals that pass between billions of neurons and co-ordinate their pace constantly.
How does the brain do this?
Most of the volume of our brain is occupied by wires called axons, which form a complex network called white matter. Like a maze of airways linking cities around the world, white matter manages communication and co-ordination between the various areas where populations of neurons process information. These areas are located in different parts of the brain, sometimes close to each other, sometimes far away: this is the principle of distributed computing.
The faster, the better!
The control of traffic in the brain is crucial — the faster the information travels through the brain, the more efficiently the different areas of the brain co-operate to allow the proper functioning of memory and other aspects of cognition.
To maintain this incessant traffic, specialised cells called oligodendrocytes act as controllers by enveloping the axons with a substance called myelin. This myelin is a lipid (or fat) insulator with a characteristic pale colour, hence the name “white matter.” It allows the electrical signals of neurons to travel long distances without slowing down or losing intensity. However, myelin also offers an advantage to information passing through white matter: it allows signals to arrive on time, neither too early nor too late.
Today we know that because of its plasticity, the geography of the brain is constantly changing. However, research published in recent years have shown that white matter changes not only during development but also adaptively later, for example, during learning.
The rules of neural traffic
This type of plasticity had been observed mainly in the synapses of grey matter. It has now been shown that the structure of white matter constantly adapts and reorganises itself. Through this form of plasticity, called adaptive myelination, the structure and properties of white matter are optimised. As a result, communication between neurons is maintained even when the brain’s size, activity and connections change. In fact, oligodendrocytes can adjust the amount of myelin to speed up or slow down the propagation of signals and maintain stable neuronal trafficking.
But how do white matter and its glial cells adapt to stabilise neuronal traffic and accomplish this incredible co-ordination challenge?
This question, like many concerning glial cells, is difficult to answer with traditional neuroimaging methods, but it’s of primary importance to a better understanding of neurodegenerative diseases. One example is multiple sclerosis, which causes myelin thinning and leads to a systemic disorganisation of the flow of information in the brain, causing profound cognitive and motor disorders.
Co-ordinated neuronal activity
A recent interdisciplinary study provides a better understanding of the rules governing the control of neuronal traffic in white matter. It is important to note that neuron activity — a series of Morse code-like impulses — is not random. Rather, neurons tend to activate in groups and synchronise, generating waves or oscillations called brain rhythms. Researchers believe that in order to communicate with each other, different areas of the brain must be able to align and co-ordinate these rhythms.
New results obtained from human brain imaging data, combined with mathematical models, show that white matter reorganises itself to optimise the alignment of these rhythms. To do this, it controls the speed at which these waves propagate through white matter by adjusting the amount of myelin present.
Oligodendrocytes therefore adapt the conductivity of axons to enable them to respond effectively to changing neuronal traffic demands and orchestrate the alignment between the oscillations present in different parts of the brain. They’re real cellular air traffic controllers!
Even the sick brain manages
Another surprising result is that the plastic properties of white matter also seem to allow the brain to adapt despite the presence of disease or injury. Indeed, it has been shown that white matter can reorganise in the presence of damage to preserve communication and synchronisation between neurons, even if connections become either absent or damaged, for example in the presence of cancer.
Some experiments in animals have shown that preventing glial cells from adapting in the presence of injury limits recovery and causes many cognitive and behavioural problems.
The plasticity of white matter appears to be a key element of brain resilience and could therefore represent an interesting option for developing new therapeutic approaches, particularly in stroke victims. These new results highlight the importance of glial cells and white matter plasticity in the functioning and flexibility of cognitive processes.