Source: Joon Kyu Park, CC BY-SA 3.0
<https://creativecommons.org/licenses/by-sa/3.0>, via Wikimedia Commons
Today’s post
is a follow up to the recent one that showed Memantine was beneficial to people
with level 1 autism, normal IQ, with ADHD and anxiety/depression.
Our reader
Hoang, highlighted a recent trial in Korea that used the OTC supplement
L-serine, which has a biological effect that is the opposite of Memantine. The
trial is part of series looking at treating those with severe autism with ID
(intellectual disability).
High-dose
L-serine has been tested in children with severe autism and intellectual
disability, and the main benefits were seen in those under 7 years old. While
it may work by boosting NMDA receptor activity through conversion to D-serine,
other brain-supporting roles of L-serine—like helping neuron membranes and
reducing stress on brain cells—could also contribute. Older children may not
respond as well, possibly because their brains are less plastic or they convert
less L-serine to D-serine. Researchers should now explore whether direct
D-serine dosing might help older kids, but safety must be considered.
The
Trials and Target Group
The trials
of AST-001, a syrup formulation of L-serine, focused on children with severe
autism and intellectual disability (ID). The phase 2 study included children
aged 2–11, but the most pronounced improvements were in those under 7 years
old. The benefit did not entirely disappear after age 7, but it was smaller and
harder to measure.
Dosing was
weight-tiered:
|
Weight
(kg) |
Dose
(g, twice a day) |
|
10–13 |
2 |
|
14–20 |
4 |
|
21–34 |
6 |
|
35–49 |
10 |
|
>50 |
14 |
The outcomes
measured were adaptive behavior (Vineland Adaptive Behavior Scales II) and
clinical global impressions, with high-dose L-serine showing a statistically
significant improvement over placebo.
How
L-Serine Might Work
1. NMDA
Receptor Modulation
L-serine can
be converted in the brain to D-serine, a co-agonist of NMDA receptors, which
are critical for learning, memory, and social behavior. This mechanism aligns
with the idea that boosting NMDA signaling could help in some autism. This is
the exact opposite of what Memantine does.
2. Other
Neuroprotective Roles
However,
L-serine also supports:
- Phospholipid and myelin
synthesis, crucial for neuron structure
- One-carbon metabolism and
methylation, which help maintain healthy brain chemistry
- Reducing cellular stress,
oxidative damage, and excitotoxicity
- L-serine is the precursor to
glycine. This matters because glycine is also an NMDA co-agonist
(alongside D-serine). In some brain regions glycine—not D-serine—is the
primary co-agonist.
So, the
clinical effect might not be solely through NMDA receptor modulation.
Why
Benefits Are Seen Mainly in Children Under 7
Several factors may explain the age effect:
1.
Brain
Plasticity – Younger brains are more adaptable, so interventions may show
stronger effects.
2.
Conversion
to D-serine – L-serine is converted to D-serine by serine racemase, and this
may be less efficient in older children.
3.
Ceiling
Effects – In older children with long-standing autism and ID, neural circuits
may have already stabilized in ways that make observable behavioral
improvements harder.
It is
unclear whether older children truly cannot benefit, or if the benefit is
harder to measure with standard adaptive behavior scales.
Could
D-Serine Directly Help Older Children?
A hypothesis
is that older children might need higher levels of D-serine than their bodies
can produce from L-serine. In theory:
- Direct D-serine supplementation
might overcome this bottleneck.
- Safety is the main concern, as
excessive D-serine can stress kidneys or neurotransmitter systems.
No large
trials have tested this yet in older children with autism.
About the
Researcher
Dr Yoo-Sook
Joung led the AST-001 trials. She is a psychiatrist with an interest in
autism interventions and has explored approaches like animal-assisted therapy.
While not a basic science researcher, her clinical insights have helped design
practical trials in children with severe autism and ID.
Takeaways
- High-dose L-serine shows
promising results in children under 7 with severe autism and ID. The low
dose was not effective.
- Benefits may involve NMDA
receptor modulation, but other neuroprotective effects are likely
relevant.
- Older children may require
alternative approaches (e.g., D-serine), but evidence is lacking.
- Safety and careful dosing are
essential; trials so far show good tolerability, with diarrhea being the
most common side effect.
Here is the
associated research leading up the recent trial
AST-001 is an L-isomer of serine that has protective effects
on neurological disorders. This study aimed to establish a population
pharmacokinetic (PK) model of AST-001 in healthy Korean to further propose a
fixed-dose regimen in pediatrics. The model was constructed using 648 plasma
concentrations from 24 healthy subjects, including baseline endogenous levels
during 24 h and concentrations after a single dose of 10, 20, and
30 g of AST-001. For the simulation, an empirical allometric power model
was applied to the apparent clearance and volume of distribution with body
weight. The PK characteristics of AST-001 after oral administration were well
described by a two-compartment model with zero-order absorption and linear
elimination. The endogenous production of AST-001 was well explained by
continuous zero-order production at a rate of 0.287 g/h. The simulation
results suggested that 2 g, 4 g, 7 g, 10 g, and 14 g
twice-daily regimens for the respective groups of 10–14 kg, 15–24 kg,
25–37 kg, 38–51 kg, 52–60 kg were adequate to achieve sufficient
exposure to AST-001. The current population PK model well described both
observed endogenous production and exogenous administration of AST-001 in
healthy subjects. Using the allometric scaling approach, we suggested an
optimal fixed-dose regimen with five weight ranges in pediatrics for the
upcoming phase 2 trial.
AST-001, a novel syrup formulation of L-serine, was developed for the treatment of autism spectrum disorders (ASD) in pediatric patients. This study aimed to establish a pharmacokinetic (PK)-pharmacodynamic (PD) model to elucidate the effect of AST-001 on adaptive behavior in children with ASD. Due to the absence of PK samples in pediatric patients, a previously published population PK model was used to link the PD model by applying an allometric scale to body weight. The time courses of Korean-Vineland Adaptive Behavior Scale-II Adaptive Behavior Composite (K-VABS-II-ABC) scores were best described by an effect compartment model with linear drug effects (Deff, 0.0022 L/μg) and linear progression, where an equilibration half-life to the effect compartment was approximately 15 weeks. Our findings indicated a positive correlation between the baseline K-VABS-II-ABC score (E0, 48.51) and the rate of natural progression (Kprog, 0.015 day−1), suggesting enhanced natural behavioral improvements in patients with better baseline adaptive behavior. Moreover, age was identified as a significant covariate for E0 and was incorporated into the model using a power function. Based on our model, the recommended dosing regimens for phase III trials are 2, 4, 6, 10, and 14 g, administered twice daily for weight ranges of 10–13, 14–20, 21–34, 35–49, and >50 kg, respectively. These doses are expected to significantly improve ASD symptoms. This study not only proposes an optimized dosing strategy for AST-001 but also provides valuable insights into the PK-PD relationship in pediatric ASD treatment.
Aim
This study examined the efficacy of AST‐001 for the core
symptoms of autism spectrum disorder (ASD) in children.
Methods
This phase 2 clinical trial consisted of a 12‐week
placebo‐controlled main study, a 12‐week extension, and a 12‐week follow‐up in
children aged 2 to 11 years with ASD. The participants were randomized in a
1:1:1 ratio to a high‐dose, low‐dose, or placebo‐to‐high‐dose control group
during the main study. The placebo‐to‐high‐dose control group received placebo
during the main study and high‐dose AST‐001 during the extension. The a
priori primary outcome was the mean change in the Adaptive Behavior
Composite (ABC) score of the Korean Vineland Adaptive Behavior Scales II
(K‐VABS‐II) from baseline to week 12.
Results
Among 151 enrolled participants, 144 completed the main
study, 140 completed the extension, and 135 completed the follow‐up. The mean
K‐VABS‐II ABC score at the 12th week compared with baseline was significantly
increased in the high‐dose group (P = 0.042) compared with the
placebo‐to‐high‐dose control group. The mean CGI‐S scores were significantly
decreased at the 12th week in the high‐dose (P = 0.046) and low‐dose (P = 0.017)
groups compared with the placebo‐to‐high‐dose control group. During the extension,
the K‐VABS‐II ABC and CGI‐S scores of the placebo‐to‐high‐dose control group
changed rapidly after administration of high‐dose AST‐001 and caught up with
those of the high‐dose group at the 24th week. AST‐001 was well tolerated with
no safety concern. The most common adverse drug reaction was diarrhea.
Conclusions
Our results provide preliminary evidence for the efficacy of
AST‐001 for the core symptoms of ASD.
The what,
when and where of treating autism
The human
brain is a work in progress up until your mid 20s.
It is near
adult-sized at the age of 5, but many key developmental processes remain.
As brain
development goes through it various steps, it requires certain genes to be
activated to produce specific proteins. This is why in some single gene autisms
babies are born appearing entirely typical, because at that point they are
typical. Shortly thereafter when the gene cannot produce enough of its protein
(haploinsufficiency) things start developing off-track. The human body is
highly adaptable and the brain keeps on changing, but now on a different track.
Many
dysfunctions in autism are localized to just one part of the brain and indeed
you can have the opposite dysfunction in different parts of the brain at the
same time. Some dysfunctions can be just transitory, or indeed just extreme in
one particular developmental window.
When it
comes to NMDA activity we know that very often in autism and schizophrenia it
is disturbed. But, it can be too much or too little (hyper/hypo) and very
likely this changes over time and varies in different parts of the brain.
Viewed in
this broader context, it is not odd to see an intervention that is most
effective up to the age of seven.
Conclusion
If you know
a child with severe autism and intellectual disability, who is under 7 years
old, maybe suggest to the parents to investigate following our proactive reader
Hoang and make a trial of the OTC supplement L-Serine. You can buy it inexpensively
on-line, just search “L serine bulk powder.” In the US 1kg costs about $50.
Just follow the dosage in the trials.
L-serine is
very safe.
Using
D-serine is more problematic. In clinical studies for schizophrenia and
cognitive disorders, doses ranged from 30 mg/kg/day to 120 mg/kg/day in divided
doses. D-serine is mostly safe at moderate doses, but very high doses carry
risks of kidney stress and excitotoxicity.
Modest
amounts of L-serine can be found in eggs, chicken, milk etc. The body then
converts this to D-serine using an enzyme called serine racemase and vitamin
B6. Once these are used up, no more D-serine can be produced “naturally.” This
is why schizophrenia researchers use D-serine itself. D-serine is also sold as
a bulk OTC supplement.
If the child
was actually an undiagnosed Memantine-responder, you would expect to see the
following if they took high dose L-serine:
·
↑
irritability
·
↑
sensory overload
·
↑
hyperactivity
·
↑
emotional volatility
·
↑
stereotypy
·
↑
anxiety
Because a
memantine responder is a child whose biology is defined by NMDA receptor
overactivity, where excessive glutamate signalling drives irritability, sensory
overload, anxiety, and cognitive stress and memantine works precisely because
it reduces this hyper-NMDA state.
L-serine
does the opposite, it increases D-serine and so enhances NMDA activity and so
in an L-serine responder it improves:
·
learning
and cognitive processing
·
social
attention and engagement
·
adaptive
behaviour
·
overall
developmental trajectory
In this
group, the core bottleneck is not excessive glutamatergic activity but
insufficient NMDA co-agonism, especially in early development when social
circuits and sensory-integration networks are still forming.
What does “insufficient NMDA co-agonism” mean?
NMDA
receptors do not work like simple on/off switches.
They need
two keys to open:
·
Glutamate
– the main excitatory neurotransmitter
·
A
co-agonist – either D-serine or glycine
If glutamate
is present but the co-agonist is missing or too low, the NMDA receptor cannot
fully activate, even though the neuron is trying to fire normally.
This
situation is called NMDA hypofunction caused by insufficient co-agonism
In plain
terms, the glutamate system is not actually weak. The receptor is not working
properly because the “second key” is missing.
Neural
circuits needed for learning, plasticity, and social behaviour do not work
properly, because the key is missing. Go find it!
Why does
this matter in autism with ID?
Several
studies (postmortem, CSF, MR spectroscopy) show that in many children with
severe autism + language delay + ID, D-serine levels are reduced in key brain
areas (prefrontal cortex, temporal cortex, hippocampus).
Possible
reasons:
·
Low
activity of serine racemase (the enzyme converting L-serine → D-serine)
·
Higher
breakdown of D-serine by DAO (D-amino acid oxidase)
·
Developmentally
immature astrocytes (which supply D-serine early in life)
·
Genetic
factors affecting NMDA co-agonist pathways
When
D-serine is low, NMDA receptors cannot activate normally even if glutamate
levels are normal or high.
The
result:
Cognitive
delay, poor adaptive behaviour, weak learning reinforcement, sensory
disturbances, and poor social reciprocity.
How does L-serine help?
·
L-serine
is the precursor to D-serine.
By giving
large doses of L-serine
·
The
brain produces more D-serine
D-serine
binds the NMDA co-agonist site
·
NMDA
receptors can finally reach normal activation
·
Neural
circuits can strengthen and rewire more effectively
·
Behaviour
improves, especially in younger children where plasticity is high
This is why
L-serine produces the opposite clinical effect of memantine:
- Memantine helps when NMDA activity is too high
- L-serine helps when NMDA activity is too low because of a missing co-agonist
