I encountered a
fascinating paper in this week's Science magazine on a possible
sleep function that I have never seen described before
- flushing toxins out of the brain. The lead author hails from
the Division of Glial Disease and Therapeutics, Center for Translational
Neuromedicine, Department of Neurosurgery, University of Rochester Medical
School. That probably says a lot about the focus of the paper and that is
the movement of interstitial fluid (ISF) as it circulates through the
interstitial spaces around neurons and removes toxic waste products
including β-amyloid (Aβ) Since the brain lacks
a lymphatic system convective exchange between CSF and ISF
controls this turnover. One author named the system the glymphatic system since the system is dependent on
astrocytic aquaporin-4 (APQ-4) channels for establishing the
convective movement of ISF and this is homologous to peripheral
lymphatic movement and removal of toxic byproducts from peripheral
tissue by the lymphatic system. The authors also note that the observation that (Aβ) protein
has been observed to be at a higher concentration in the daytime as opposed to
during sleep. To explain this one hypothesis was
that production was greater in the daytime. They tested
the alternate hypothesis that glymphatic clearance is greater at
night.
The basic experiment for
the paper involved teaching mice to sleep on a two-photon microscope.
That allows imaging of dye moving through living tissue. The
researcher would inject mice with green dye at sleep onset and red dye
upon awakening. They could determine that during sleep a much higher
volume or CSF flowed through the brain. They also injected labelled (Aβ)
protein and showed that the brain of a sleeping mouse cleared these
proteins twice as fast. The art below shows the experiment and the 60%
increase in channels carrying CSF during sleep. I
would encourage anyone interested to read the original in
color as Science has outstanding graphics. To download my original PowerPoint slide use this link.
The authors went on to demonstrate that the increase in
interstitial space was a sleep related phenomenon because it could be induced
by natural sleep and anesthesia but not circadian rhythm. In looking for
a mechanism they postulated that adrenergic mechanisms associated with arousal like
locus ceruleus derived noradrenergic signaling was involved. They
demonstrated that adrenergic antagonists could induce the expected increase in
tracer influx and interstitial volume so that it was similar to what was seen
in the sleep state.
Implications for psychiatry? To some
extent, those of us interested in neuroscience and not forgetting what we
learned in PChem will always be interested in article at the interface between
the biochemical and the biophysical. Despite having this elegant system
coupled with our arousal state and metabolic state none of this information was
around during the recent Decade of the Brain. The authors discuss the
sensitivity of neurons to various toxic products and proteins and the
implications for neurodegenerative diseases. I can start with insomnia
and build from there. People with addictions can have sustained insomnia
and associated impairment in cognition the next day. Delirium also
affects the sleep-wake cycle and some experts have suggested that two different
types of delirium can be distinguished based on EEG spectra. The obvious
questions are is the insomnia associated with these states literally toxic to
the patient by restricting ISF clearance? Another key correlate
mentioned by the authors is the decrease in ISF with age. Does that
account for the predisposition to delirium and protracted delirium as people
age? And finally what about the toxicity of medication? We are used
to receptor based explanations of why certain medications have sustained or
unexpected toxicity. How much of that is due to a collapsed ISF and
restricted clearance to the CSF?
Brain energetics is also an interesting
question specifically the AQP-4 channels. Most psychiatrists are familiar
with the renal aquaporin channels when considering renal water metabolism.
The fact that you have these channels on astrocytes and that removing
them reduces (Aβ) clearance by 65% is fascinating and seems like another
potential intervention point for brain disease. What needs to happen to
keep these AQP-4 channels healthy and what happens when they are not?
There are many more questions that come to
mind based on the mechanism these authors have elucidated. I hope that
papers like these are translated into both clinical research and our thinking
about newer and more innovative ways to think about whole brain function and
think about all of the mechanisms instead of just the usual receptors.
George Dawson, MD, DFAPA
Xie L, Kang H, Xu Q, Chen MJ, Liao Y,
Thiyagarajan M, O'Donnell J, Christensen DJ, Nicholson C, Iliff JJ, Takano T,
Deane R, Nedergaard M. Sleep drives metabolite clearance from the adult brain.
Science. 2013 Oct 18;342(6156):373-7. doi: 10.1126/science.1241224. PubMed
PMID: 24136970
Footnote: I decided to update (12/13/2013) this post by adding this interesting piece of news. According to Altmetric, this paper received the 4th highest rating of online interest in scientific papers. For the Top 100 papers click on the link.
Footnote: I decided to update (12/13/2013) this post by adding this interesting piece of news. According to Altmetric, this paper received the 4th highest rating of online interest in scientific papers. For the Top 100 papers click on the link.