Blood as a neuromodulator

In the Journal of Neurophysiology, Chris Moore of the McGovern Institute for Brain Research at MIT reviews the evidence for his hemo-neural hypothesis:

Brain vasculature is a complex and interconnected network under tight regulatory control that exists in intimate communication with neurons and glia. Typically, hemodynamics are considered to exclusively serve as a metabolic support system. In contrast to this canonical view, we propose that hemodynamics also play a role in information processing through modulation of neural activity. Functional hyperemia, the basis of the fMRI BOLD signal, is a localized influx of blood correlated with neural activity levels. Functional hyperemia is considered by many to be excessive from a metabolic standpoint, but may be appropriate if interpreted as having an activity-dependent neuro-modulatory function. Hemodynamics may impact neural activity through direct and indirect mechanisms. Direct mechanisms include delivery of diffusible blood-borne messengers, and mechanical and thermal modulation of neural activity. Indirect mechanisms are proposed to act through hemodynamic modulation of astrocytes, which can in turn regulate neural activity. These hemo-neural mechanisms should alter the information processing capacity of active local neural networks. Here, we focus on analysis of neocortical sensory processing. We predict that hemodynamics alter the gain of local cortical circuits, modulating the detection and discrimination of sensory stimuli. This novel view of information processing, that includes hemodynamics as an active and significant participant, has implications for understanding neural representation and the construction of accurate brain models. There are also potential medical benefits of an improved understanding of the role of hemodynamics in neural processing, as it directly bears on interpretation of and potential treatment for stroke, dementia and epilepsy.

More like this

Blood flow in the brain is linked to neuronal activity. Therefore, various 'brain scanning' techniques can be used to observe neuronal activity in the brain. This has led to an astonishing revolution in knowledge of how the brain works. Of course, you knew that already. Also astonishing is that…
The 19th century histologists who discovered the neuron also found that the nervous system contains another type of cell. They assumed that the role of these other cells was to provide structural support for neurons, and so named them glia (meaning "glue"). Subsequently, investigators focused their…
To the extent that the cognitive sciences actually consider the brain, the focus is clearly on neurons. Even the name of the field "neuroscience" suggests that neurons take the center stage. However, neurons are vastly outnumbered by glia, a different type of cell that is now known to be…
Ever since I started to learn about brains, back in the mid 1980s, from some really brainy brain experts like Terry Deacon and Joe Marcus, I always knew that glial cells were important. But I now read in current material in Nature Neuroscience, that "A decade ago, glia were the neglected…

For some reason, I'm flashing on "Everything Louder Than Everything Else"... um, Meatloaf?

By David Harmon (not verified) on 18 Oct 2007 #permalink