After providing all the funding for The Brain from Top to Bottom for over 10 years, the CIHR Institute of Neurosciences, Mental Health and Addiction informed us that because of budget cuts, they were going to be forced to stop sponsoring us as of March 31st, 2013.

We have approached a number of organizations, all of which have recognized the value of our work. But we have not managed to find the funding we need. We must therefore ask our readers for donations so that we can continue updating and adding new content to The Brain from Top to Bottom web site and blog.

Please, rest assured that we are doing our utmost to continue our mission of providing the general public with the best possible information about the brain and neuroscience in the original spirit of the Internet: the desire to share information free of charge and with no adverstising.

Whether your support is moral, financial, or both, thank you from the bottom of our hearts!

Bruno Dubuc, Patrick Robert, Denis Paquet, and Al Daigen





Tuesday, 19 September 2023
Mechanisms underlying anatomical the tracing methods

Today I’d like to tell you about the cellular mechanisms underlying the tracing methods used to visualize the paths that axons follow from one structure in the brain to another. The use of these methods in animal models is based on the ability that neurons have to move molecules along the microtubules in their axons. This process is essential to the normal functioning of neurons and is known as axonal transport. It works by means of motor proteins that, when supplied with a bit of energy, constantly change form to drive all kinds of molecules carried in vesicles, a bit like a porter with a load on his back. There are some animations on the Internet that illustrate this process, and it’s pretty impressive!

So when researchers inject certain markers, such as fluorescent proteins, into a part of the brain, they can enter the neurons and be carried along by axonal transport, thus revealing the entire path of the axon, which sometimes runs long distances through various brain structures to its destination. The entire basis of neuroanatomy was established in this way, using anterograde tracing methods, in which the markers are transported from the neuronal cell body to the tip of the axon, and retrograde tracing methods, in which they are carried in the opposite direction.

From the Simple to the Complex | Comments Closed

Monday, 28 August 2023
The sodium-potassium pump : an essential protein

Today I’d like to tell you about the sodium-potassium pump. This protein is found in the membranes of neurons and of many other kinds of cells, and its role is to re-establish the ion-concentration gradients necessary for the transmission of nerve impulses as well as for other functions elsewhere in the body. Scientists long wondered how the sodium-potassium pump managed to transport sodium ions in the first phase of its work and potassium ions in the second without transporting the wrong kind of ions by mistake (see this animation). It was not until 2009 that scientists were able to observe this protein’s overall structure, and not until 2013 that they were able to demonstrate the answer to this question: the pump changes its conformation (shape) between these two phases. (more…)

From the Simple to the Complex | Comments Closed

Monday, 31 July 2023
Visualization and mental imagery

The process of mental imagery was first demonstrated in experiments such as those by Shepard and Metzler , in the early 1970s, in which the subjects had to decide whether 3D images of arrangements of cubes matched a physical model. To complicate this task, the images in question had been rotated in space. The researchers soon realized that the more the images had been rotated, the longer it took for the subjects to determine whether or not they matched the model, which meant that the subjects were turning the cubes “in their heads” to see whether there was a match. (more…)

Body Movement and the Brain, From Thought to Language | Comments Closed

Wednesday, 21 June 2023
Sophisticated cleaning systems in our brain

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The human brain continuously consumes 20 to 25% of all the energy used by the human body and therefore inevitably produces large amounts of potentially toxic wastes, estimated to roughly equal the brain’s own weight over the course of a year. To eliminate all of this waste, the brain uses its own waste-clearance system, called the glymphatic system to indicate that it uses glial cells to perform the same function in the brain that the lymphatic system performs in the rest of the body. Previously, scientists had long thought that the brain cleansed itself by passive diffusion of cerebrospinal fluid from its ventricles. But that would be a very slow process for an organ as active as the brain. (more…)

From the Simple to the Complex | Comments Closed

Monday, 29 May 2023
How psychedelic drugs modulate brain activity

For many decades, the officially illegal status of psychedelic drugs such as LSD made research about them difficult. But more recently, studies done using various forms of brain imaging and in accordance with sound scientific practices have begun to show how these substances modulate brain activity to produce their surprising, varied effects. Broadly speaking, psychedelic drugs alter the functional connectivity between various parts of the brain while modulating the power of certain brain waves. The results are typical of the many cases in which molecules of a neuromodulating substance (in this case, an exogenous one) minimize the effects of certain natural neuromodulating systems by binding to their receptors—in the case of LSD, the receptors for dopamine and serotonin. (more…)

The Emergence of Consciousness | Comments Closed