A new paper was recently published by
researchers at the City University of New York (CUNY) may have implications far
beyond myelin disorders such as multiple sclerosis. The study demonstrated that
glucose is not merely a fuel source for the developing brain, but also acts as
a developmental signal controlling myelin formation.
We know that myelination can be
delayed, or just impaired, in many types of autism.
Modern imaging increasingly suggests that some neurodevelopmental disorders involve altered developmental timing of white matter maturation, rather than structural defects.
That fits very well with:
- delayed milestones
- asynchronous development
- regression windows
- partial catch-up trajectories
The technology available includes:
Conventional MRI — shows gross white matter and myelination
patterns; useful for detecting delayed myelination, hypomyelination, or
structural white matter abnormalities.
Diffusion Tensor
Imaging (DTI) — advanced MRI
technique measuring white matter connectivity and tract integrity indirectly
through water diffusion.
Advanced myelin
imaging (MTI, Myelin Water Imaging, MRS)
— more specialized scans that estimate myelin content or metabolic function
related to myelin and brain energy use.
Researchers
Discover a New Link Between Brain Sugar Levels and Myelin Development
Oligodendrocytes make myelin, and you
need a lot of them.
An oligodendrocyte progenitor cell
(OPC) is an immature brain cell that can divide and later mature into an
oligodendrocyte, the cell responsible for producing myelin around nerve fibers.
The paper showed that high local
glucose levels stimulated oligodendrocyte progenitor cells to divide and
increase their numbers rather than mature immediately into myelin-producing
cells.
While lower glucose states and
alternative fuels such as ketone bodies supported maturation into
myelin-producing oligodendrocytes. Importantly, when glucose-derived acetyl-CoA
production was impaired, oligodendrocytes were still able to mature and eventually
produce myelin by switching to ketone-derived metabolic pathways.
In essence:
·
Glucose was
especially important for expanding the number of OPCs.
·
Ketones can
support later oligodendrocyte maturation and myelin production when glucose
pathways were impaired.
·
Ketones cannot
replace glucose
·
Ketones can
augment a glucose deficient brain
While the study focused on
myelination, it may also provide a useful framework for thinking about autism
and neurodevelopmental disorders.
One conceptual model I use to
understand autism is what I call the “3W framework”, or the What When and Where
of autism:
- What dysfunction?
- Where in the brain?
- When during development?
This new research fits remarkably well
within this framework.
WHAT dysfunction?
Autism is unlikely to represent one
single biological abnormality. Two autistic individuals may share behavioral
features while having very different underlying neurobiology.
Potential dysfunctions may include:
- Synaptic dysfunction
- Mitochondrial abnormalities
- Redox dysregulation
- Neuroinflammation
- ER stress
- Myelination abnormalities
- Developmental timing abnormalities
- Excitation/inhibition imbalance
This new paper introduces another
important candidate dysfunction -
metabolic regulation of oligodendrocyte development and myelination.
The important insight is that
metabolism itself appears to regulate developmental state transitions.
The study showed that glucose-derived
acetyl-CoA regulates histone acetylation and developmental gene expression in
OPCs. In other words, metabolism is not simply supplying energy to the brain.
It is helping instruct cells when to proliferate and when to mature.
This is a major conceptual shift.
In autism research, metabolism has
traditionally been viewed mainly through the lens of energy deficiency or
mitochondrial dysfunction. However, this paper supports a newer idea emerging
across neuroscience:
Metabolism may act as a developmental
signaling system.
This may help explain why some
autistic individuals show:
- Delayed rather than absent development
- Uneven cognitive profiles
- Fluctuating developmental trajectories
- Temporary regressions
- Later partial catch-up
These patterns are difficult to
explain using static “brain damage” models but fit more naturally with
dysregulated developmental timing.
WHERE in the
brain?
The same dysfunction can produce very
different outcomes depending on where it occurs.
Abnormal myelination in:
- Frontal regions may affect executive
function and social cognition
- Temporal regions may affect language
processing
- Cerebellar circuits may affect sensory
prediction and motor timing
- White matter tracts may affect long-range
synchronization and processing speed
- Brainstem regions may affect autonomic
regulation and arousal
This may explain why autism presents
so heterogeneously.
Importantly, systemic treatments are too
blunt. Most interventions affect the entire brain simultaneously. A therapy
that improves one network may destabilize another.
This may partly explain why:
- Some individuals improve dramatically
with metabolic interventions
- Others show little effect
- Some worsen paradoxically
The “Where” dimension is likely critically important but remains difficult to target clinically.
WHEN during
development?
This may be the most important insight
of all.
The developing brain is not static.
Different developmental stages require different metabolic and signaling
environments.
The paper demonstrated that:
- High glucose states supported OPC
proliferation
- Alternative metabolic fuels supported
oligodendrocyte maturation and myelin synthesis
This implies that metabolic
requirements change across developmental stages.
That concept may have profound
implications for autism.
Many developmental disorders show:
- Delayed milestones
- Asynchronous development
- Developmental plateaus
- Regression windows
- Later partial catch-up
The traditional assumption has often
been that cells or circuits are permanently defective.
However, this paper suggests that some
neurodevelopmental disorders may involve delayed or dysregulated developmental
transitions rather than irreversible failure.
The study is particularly interesting
because the mice initially showed reduced myelination but later partially
compensated through alternative metabolic pathways involving ketone-derived
acetyl-CoA.
This resembles the developmental
trajectories seen in many neurodevelopmental disorders, where:
- Development is delayed rather than absent
- Skills may emerge late
- Periods of apparent stagnation may later
resolve
- Regression may sometimes reflect failure
of compensation during periods of rising developmental demand
This may help explain why some
therapies only appear effective during certain developmental windows.
A treatment beneficial during one
phase of development may be ineffective or even counterproductive during
another.
Implications for
autism therapies
This paper does not prove that autism
is a myelination disorder, nor does it prove that ketogenic therapies are
effective for autism.
However, it strengthens several
emerging ideas:
- Metabolism may regulate developmental
timing
- Myelination may be metabolically
sensitive
- Alternative fuels such as ketones may
support some developmental processes
- Neurodevelopmental disorders may involve
impaired metabolic flexibility
- Therapeutic timing may matter enormously
The future of autism therapy may
eventually require understanding:
- What dysfunction is present
- Where it is occurring in the brain
- When during development intervention is
most effective
The era of searching for a single
universal autism treatment may eventually give way to developmentally timed,
biologically targeted interventions tailored to specific neurobiological
profiles.
This new myelination research may
represent an important step toward that future.
Note that this paper from CUNY does
not mention autism, it is just about the myelination process.
The use of
ketones in autism
A small number of people with autism
appear to respond very well to ketone ester supplements. These products are
still relatively niche, expensive, and can be difficult to obtain outside the
United States. One of the best known examples is KetoneAid KE4.
Ketone esters can produce a
substantial and measurable increase in blood levels of the ketone beta-hydroxybutyrate
(BHB), often sustained for several hours. This differs significantly from many
cheaper “ketone” products, particularly ketone salts, which typically produce
much smaller and shorter-lived increases in BHB.
Why some autistic individuals respond
positively to ketones remains unclear, but several mechanisms are plausible:
- Alternative brain energy supply
- Improved mitochondrial efficiency
- Reduced glucose dependence
- Changes in redox balance
- Effects on neuronal excitability
- Altered inflammation and signaling
pathways
- Possible support for myelination and
oligodendrocyte function
The new study showed that
oligodendrocyte lineage cells can switch from glucose-derived acetyl-CoA to
ketone-derived acetyl-CoA during later stages of myelin formation. This
suggests ketones may play a more important developmental and signaling role in
the brain than previously appreciated.
Importantly, ketones do not replace
glucose entirely. The study demonstrated that glucose signaling remained
necessary for oligodendrocyte progenitor cell (OPC) proliferation during early
developmental stages, while ketones could support later maturation and myelin
synthesis under some conditions.
This may help explain why ketones
appear beneficial in some neurological and developmental conditions involving:
- impaired glucose utilization
- mitochondrial dysfunction
- epilepsy
- white matter abnormalities
- metabolic inflexibility
However, responses in autism are
highly variable. Some individuals show improvements in:
- alertness
- cognition
- endurance
- behavior
- seizures
- language attempts
while others show little benefit or
even worsening.
This variability likely reflects the
biological heterogeneity of autism itself. Different individuals may have
different underlying dysfunctions involving metabolism, redox balance,
mitochondrial function, neuroinflammation, myelination, or neuronal signaling.
At present there is still very little
formal clinical research on ketone esters in autism, and most evidence remains
anecdotal or exploratory. Nevertheless, the growing understanding of brain
metabolism and developmental myelination suggests this may become an
increasingly important research area in the future.
