I have the impression that neurobiology is the single field in biology where many people with sometimes rather selective knowledge of the field have strong opinions about how it should work (i.e. how the brain should work). I don’t want to say that these opinions are worthless. In contrary, I enjoy them as an inspiring read. As a common sign, these theories present their new approach as a game-changer that offers a – until now – overlooked point of view on the brain. Nobody should be surprised by this, since, despite all efforts, an understanding of how specific information processing in the brain could look like is somewhat completely dark, and the most likely explanation for this lack of progress in understanding is a generally misguided paradigm in neurobiology, and the solution would be a paradigm change.
One example for a strong opinion I came across roughly two years ago, was the blog neuroelectrodynamics.blogspot.ch. (The author of the blog is apparently a professional neuroscientist.) On his blog, he highlights the importance of spike shape and propagation direction, and the possibility that these details of ion currents may lead to computations in neurons that are far more sophisticated than computations possible for simple firing rate models. It’s an interesting read, because it questions common places in neuroscience, although some of these opinions (firing rate models) are not necessarily part of the way most neuroscientists think of information processing anymore.
Another example I found recently in the web is this homepage written in german: www.straktur.de It’s also available in english, but I have the feeling that it has been translated using Google Translate …
It stems from a mathematician who emphasizes the role of Glia cells; more precisely, he hypothesizes that Glia cells, responsible for nourishing neurons, evaluate the performance of neurons and support them accordingly. A dysfunctional neuron would therefore simply be discarded by cutting the support coming from Glia cells. By this, optimized information processing would arise naturally from this simple energy constraint (and this is where you can see the handwriting of a mathematician) – a basically interesting idea.
The author doesn’t really explain how the Glia cells might be able to evaluate the performance of surrounding neurons, but for simple circuits, one can imagine that this is possible.
At least for me, those kind of opinions are sometimes much more inspiring than a typical Nature/Neuron/Cell paper, because the presented opinion is strong, wants to convince he reader, questions the authorities in the field and presents its theory as the holy grail, reminding you that there is something bigger out there (the holy grail) and that there is still a lack of understanding when it comes to specific information processing in neurons (or glia).