A new study reports that many children
with autism have elevated levels of microbially-derived metabolites (MDMs) in
their urine. The authors propose that this pattern is so common that it defines
a distinct subtype of autism, which they call ASD-MDM (Autism Spectrum Disorder
associated with Microbially-Derived Metabolites).
The authors claim that approximately 90% of autistic children have ASD-MDM and also suggest that ASD-MDM is a distinct subtype of autism. But that would mean almost all autism is ASD-MDM, so it would not really be a focused sub-type.
It is striking that there are 22 authors listed, but only 52 ASD children studied. There are some familiar names among the 22.
The study is interesting and deserves attention. However, like many autism studies, it raises as many questions as it answers.
What did the
researchers find?
The researchers measured a range of
metabolites produced by gut bacteria and yeasts in the urine of 52 children
with autism and 47 typically developing controls.
The metabolites fell into three broad
categories:
- Phenylalanine and tyrosine-derived
metabolites such as p-cresol and p-cresol sulfate
- Tryptophan-derived metabolites such as
indoxyl sulfate and various indole compounds
- Yeast-associated metabolites such as
arabinitol
Many of these compounds were
significantly elevated in the autism group.
The most convincing findings involved
p-cresol, p-cresol sulfate, phenylacetylglutamine and indoxyl sulfate. These
metabolites have been reported repeatedly in previous autism studies and are
among the best-replicated metabolic findings in the autism literature.
Using a scoring system based on the
number of metabolites exceeding the range seen in any control child, the
authors reported that approximately 78–90% of children with autism had at least
one markedly elevated microbial metabolite.
What is new?
The most important contribution of
this study is not the individual metabolites. We have known about elevated
p-cresol for many years. It has been covered extensively in previous posts and
in Stephen’s comments.
The novelty lies in combining multiple
microbial metabolites into a single framework and proposing that they
collectively define a biological subtype of autism.
This is an attractive idea.
Autism is clearly not a single
disorder. Two people can receive the same diagnosis while having entirely
different underlying biology. One person may have a monogenic disorder, another
a mitochondrial dysfunction, another a channelopathy, and another an immune-mediated
condition.
The notion that a substantial subgroup
of autistic children may have a characteristic pattern of microbial metabolites
is therefore entirely plausible.
Reasons for
caution
The authors make some ambitious claims
regarding diagnosis and screening. Several limitations should be kept in mind.
First, the study was very small,
involving just under one hundred participants. This is adequate for a pilot
study, but much too small to establish a diagnostic test with confidence.
Second, the control group was unusual.
The autism group was predominantly male, which is expected, but the control
group contained more females than males. This creates the possibility that some
of the observed differences may be influenced by sex-related differences rather than autism alone. Comparing autistic boys with very restricted diets to typical girls with rich varied diets, springs to mind.
Sex Distribution of Study Participants ASD Group Typically Developing (TD) Controls Male 41 20 Female 11 27 Total 52 47 Male (%) 79% 43% Female (%) 21% 57% Male:Female Ratio 3.7:1 0.74:1
Third, the study collected no
information on diet or medication use. This is a major limitation. Many
autistic children have restricted diets, gastrointestinal problems, food
selectivity, supplements or medications that can influence both the microbiome and
the metabolome. Without these data, it is difficult to determine how much of
the observed metabolic profile is attributable to autism itself.
Diet is one of the strongest known
determinants of microbial metabolism. Many young autistic children,
particularly those with more severe autism, consume highly restricted diets
consisting of a small number of preferred "safe foods", often
ultra-processed foods and very little dietary fiber. Such eating patterns can
profoundly alter both the composition of the gut microbiome and the metabolites
it produces. A boy whose diet consists largely of chicken nuggets, fries, white
bread and sweetened drinks may be expected to have a very different microbiome
from a girl consuming a varied diet rich in fruit, vegetables and fiber,
regardless of whether either child has autism.
Super
Size Me was a 2004 documentary by Morgan Spurlock in which he ate only food
from McDonald's for 30 days.
The
rules included:
Every
meal had to come from McDonald's.
If
asked whether he wanted to "super size" a meal, he had to accept.
He
tried to eat three meals a day.
He
reduced his exercise to match the average American activity level.
By
the end of the month he reported:
·
Weight gain of
about 11 kg (24 lb)
·
Increased
cholesterol
·
Abnormal liver
function tests
·
Reduced energy
·
Mood changes
If
it had been 2026, they would have analyzed changes to his microbiome and looked
at his urine metabolites. You can imagine the results.
The
film became very influential and helped draw attention to the health effects of
fast food.
Fourth, the study did not directly
examine the gut microbiome. Instead, it measured microbial metabolites excreted
in urine. Elevated urinary metabolites may reflect altered microbial activity,
but can also be influenced by intestinal permeability, liver metabolism,
sulfation capacity and kidney function. The study therefore provides direct
evidence of altered metabolite profiles, but only indirect evidence of gut
dysbiosis.
Finally, this was largely a study of classic childhood autism rather than the full autism spectrum. The participants were predominantly male and had an average CARS score of 41, consistent with substantial autistic symptoms (A CARS score above about 37 is generally considered severe autism). The findings therefore cannot automatically be generalized to those with Level 1 or 2 autism, or those diagnosed later in life. It remains possible that elevated microbial metabolites are particularly common in children with more severe autism and gastrointestinal dysfunction.
Only urine was
tested
An important limitation of this study
is that the researchers did not directly examine the gut microbiome itself.
They analyzed urine samples and measured concentrations of metabolites thought
to be produced by gut bacteria or yeasts, such as p-cresol sulfate, p-cresol
and indoxyl sulfate. This approach was chosen because these metabolites may
provide a functional readout of microbial activity and can be measured using a
simple, non-invasive urine test. However, elevated urinary metabolites do not
necessarily prove the presence of gut dysbiosis, since their levels can also be
influenced by diet, intestinal permeability, liver metabolism, sulfation
capacity and kidney excretion.
A stronger study would have combined
urinary metabolomics with stool microbiome sequencing, dietary assessments,
medication histories and measurements of gastrointestinal symptoms. Such an
integrated approach would have helped determine whether the abnormal
metabolites truly arose from altered microbial populations and whether specific
bacteria or fungi were responsible. Therefore, while the study provides
convincing evidence that many autistic children have abnormal patterns of
microbial metabolites, it provides only indirect evidence that gut dysbiosis
itself is the underlying cause, and its conclusions should be interpreted
accordingly.
Cause or
consequence?
This is perhaps the most important
question.
The paper often implies the following
sequence:
Gut
dysbiosis → microbial metabolites → autism
But the reverse sequence is also
possible:
Autism
→ altered diet, gut motility and gastrointestinal function → microbial
metabolites
The study cannot distinguish between
these possibilities.
To demonstrate causation, researchers
would need to identify elevated metabolites before autism symptoms emerge and
show that those metabolites predict later diagnosis.
That would be a much stronger result.
Why this matters
Despite the limitations, this study
fits remarkably well with a growing body of evidence suggesting that
gut-derived metabolites can influence brain function.
P-cresol is particularly noteworthy
because it has been associated with mitochondrial dysfunction, immune
activation, impaired intestinal barrier function and behavioural abnormalities
in animal models.
The repeated appearance of p-cresol
and related compounds across many studies suggests that these findings should
not be dismissed.
What remains unclear is whether these
metabolites are merely biomarkers or whether they actively contribute to
symptoms.
The broader
perspective
Readers of this blog will know that I
have never viewed autism as a single condition with a single treatment. Instead,
I view autism as a behavioural diagnosis that sits on top of multiple
underlying biological disorders.
Some people may have:
- Mitochondrial dysfunction
- Ion channel dysfunction
- Folate pathway abnormalities
- Neuroinflammation
- Gastrointestinal dysfunction
- Microbial metabolite abnormalities
and often several of these at the same
time.
The goal should not be to debate
whether autism is genetic or environmental, neurological or gastrointestinal.
The goal should be to identify the
specific abnormalities present in each individual and address them where
possible.
This study adds weight to the argument
that microbial metabolism deserves investigation as part of that process.
The clinically
important question
The most interesting question is not
whether microbial metabolites can help diagnose autism.
The
most important question is whether reducing abnormal metabolites improves
symptoms.
If a child has markedly elevated
p-cresol sulfate or indoxyl sulfate, can we normalize those levels?
If we do, does language improve? Does
anxiety improve? Do gastrointestinal symptoms improve? Does adaptive
functioning improve?
Those are the questions that matter to
families.
The authors point to previous studies
of microbiota transfer therapy that reported reductions in p-cresol sulfate
accompanied by improvements in gastrointestinal and autism-related symptoms.
Whether those findings can be replicated in larger controlled studies remains
to be seen.
A look at the
detailed results
Looking more
closely at Tables 4 and 5
The paper presents two sets of
metabolite data that are easy to confuse. Table 4 contains results from the
initial semi-quantitative (untargeted) metabolomics analysis, while Table 5
contains results from the subsequent quantitative (targeted) analysis using
authentic chemical standards.
Readers should focus primarily on Table
5, because it represents the validation phase of the study. Table 4 was
designed to identify potentially interesting metabolites, but untargeted
metabolomics is prone to both measurement error and occasional metabolite
misidentification. In contrast, the metabolites in Table 5 were measured
directly against known standards, allowing both their identity and
concentration to be determined with much greater confidence.
In simple terms, Table 4 generated the
hypotheses, while Table 5 tested them.
One of the most interesting aspects of
the paper is that some dramatic findings from Table 4 became much less
impressive in Table 5. Several tryptophan-derived metabolites appeared to
increase by more than 1000% in the discovery phase, but these effects were
greatly reduced or no longer statistically significant when measured using
quantitative methods. This is not unusual and illustrates why validation
studies are so important.
On the other hand, some findings survived the
transition from discovery to validation. Most notably, p-cresol, p-cresol
sulfate, phenylacetylglutamine and indoxyl sulfate remained significantly
elevated in the autism group. These are therefore the metabolites that deserve the
greatest attention.
The overall picture from comparing
Tables 4 and 5 is that the evidence for widespread abnormalities in microbial
metabolism remains convincing, but the evidence for some individual metabolites
is weaker than the headline figures from the discovery phase might suggest. The
quantitative data in Table 5 provide the most reliable basis for interpreting
the study and assessing its clinical relevance.
Useful
observations from Tables 4 and 5
1. p-Cresol
survives both discovery and validation
The strongest finding is not a new
metabolite but an old one.
In Table 4:
- p-Cresol increased by 151%
- p-Cresol sulfate increased by 54%
In Table 5:
- p-Cresol increased by 76%
- p-Cresol sulfate increased by 139%
Many findings became weaker during
quantitative validation, but p-cresol and p-cresol sulfate remained
significant. This strengthens the case that elevated p-cresol metabolism is a
genuine feature of a subgroup of autistic children.
2.
Phenylacetylglutamine may deserve more attention
Phenylacetylglutamine (PAGln) is
increasingly recognized as a microbiome-derived metabolite with important
biological effects.
In Table 4:
- 64% increase
- 32% of ASD children exceeded the highest
control value
In Table 5:
- 80% increase
- Highly significant (p = 0.002)
Compared with p-cresol, PAGln receives
relatively little attention in autism research but may prove to be an important
marker of altered aromatic amino acid metabolism.
3. Tryptophan
metabolism appears abnormal in many children
Although the individual metabolites
differed between the two analyses, the overall signal remained.
The study reports:
- 64% of ASD children with elevated
tryptophan metabolites in Table 4
- 42% in Table 5
This suggests that altered microbial
metabolism of tryptophan may be common in autism. This is particularly
interesting because tryptophan is the precursor of serotonin, melatonin and
kynurenine pathway metabolites.
4. Indoxyl
sulfate deserves attention
Indoxyl sulfate is another well-known
microbial metabolite.
In Table 5:
- 171% increase
- Statistically significant (p = 0.03)
Like p-cresol sulfate, it has been
linked to inflammation, oxidative stress and mitochondrial dysfunction. It may
be one of the more biologically important findings in the study.
5. The
abnormalities are highly heterogeneous
Perhaps the most important finding is
that no individual metabolite identified most autistic children.
For example:
- p-Cresol sulfate: 21% above the control
range
- p-Cresol: 19%
- Hydroxybenzoic acid: 17%
- Indole-3-acryloyl glycine: 17%
- Arabinitol: 10%
Different children had different
abnormalities. This strongly supports the view that autism consists of multiple
biological subtypes rather than a single disorder with a single biochemical
signature.
6. The yeast
findings are relatively weak
The paper devotes considerable
attention to yeast metabolites, but the quantitative data are less convincing.
Only arabinitol remained significant
in Table 5. Other proposed yeast markers, including citramalic acid, tartaric
acid and tricarballylic acid, were not statistically significant.
The results
support the existence of a yeast-associated subgroup, but not a major role for
yeast in most autistic children.
7. The
quantitative data support a lower prevalence than the headline claim
The paper's headline message is that
approximately 90% of autistic children have elevated microbial metabolites.
However, the quantitative data
suggest:
- 57% with elevated phenylalanine-related
metabolites
- 42% with elevated tryptophan-related
metabolites
- 16% with elevated yeast metabolites
- 78% with at least one elevated microbial
metabolite
The validated figure is therefore
closer to 78% than 90%.
8. A possible
aromatic amino acid subtype of autism
Taken together, the clearest pattern
involves metabolites derived from phenylalanine, tyrosine and tryptophan.
These amino acids are precursors for
important neurotransmitters including:
- Dopamine
- Noradrenaline
- Serotonin
- Melatonin
The study therefore suggests that a substantial subgroup
of autistic children may have altered microbial metabolism of aromatic amino
acids. This broader observation may
ultimately prove more important than any individual metabolite measured in the
study.
What matters clinically?
The most important question raised by
these findings is not whether they can be used to diagnose autism. The more
important question is whether these metabolites are merely biomarkers or
whether they contribute directly to symptoms.
If elevated p-cresol sulfate,
p-cresol, phenylacetylglutamine or indoxyl sulfate prove to be biologically
active drivers of symptoms, then they become potential treatment targets. This
would fit with a growing body of evidence suggesting that at least some forms
of autism involve treatable metabolic and physiological abnormalities.
From a personalized medicine
perspective, the most valuable contribution of this study is not the proposed
diagnostic test but the identification of potentially actionable metabolic
pathways that may define a distinct subgroup of autistic individuals.
Conclusion
This study provides further evidence
that abnormal microbial metabolites are common in autism and may define a
biologically meaningful subtype.
The findings are intriguing and
broadly consistent with decades of research on p-cresol and other gut-derived
compounds.
However, the study does not prove that
gut dysbiosis causes autism, nor does it establish a clinically validated
screening test.
What it does provide is another
reminder that autism is heterogeneous and that meaningful progress is likely to
come from identifying and treating specific biological abnormalities rather
than assuming that all autistic people share the same underlying pathology.
For those interested in personalized
medicine, that is perhaps the most important message of all.
How might altered
microbial metabolism of aromatic amino acids be treated?
The study suggests that a substantial
subgroup of autistic children have abnormal microbial metabolism of the
aromatic amino acids phenylalanine, tyrosine and tryptophan, leading to
elevated levels of compounds such as p-cresol, p-cresol sulfate, phenylacetylglutamine
and indoxyl sulfate. While no proven treatment exists specifically for this
metabolic pattern, several approaches could potentially be helpful.
The most obvious strategy is to modify
the gut microbiome itself through dietary changes, prebiotics, probiotics,
synbiotics or, in selected cases, Microbiota Transfer Therapy (MTT). The goal
would be to reduce production of potentially harmful metabolites and encourage
a healthier microbial ecosystem.
Another approach is to increase
populations of beneficial bacteria that preferentially ferment dietary fiber
into short-chain fatty acids such as butyrate rather than producing aromatic
metabolites.
Improving intestinal barrier function
may also reduce absorption of microbial metabolites into the bloodstream.
Compounds such as butyrate and some probiotics have been proposed for this
purpose.
Since several of the metabolites
identified in the study are sulfate conjugates, supporting sulfation and
glutathione pathways through interventions such as NAC or taurine may also
deserve further investigation.
Because p-cresol and related compounds
have been linked to oxidative stress and mitochondrial dysfunction,
mitochondrial support therapies may help reduce downstream effects even if they
do not address the underlying source of the metabolites.
Finally, gastrointestinal motility
should not be overlooked. Chronic constipation increases the time available for
bacterial fermentation of amino acids and may contribute to the production of
p-cresol and related compounds. Treating constipation and other
gastrointestinal problems may therefore be an important part of the solution.
At present, the evidence is strongest
for identifying these metabolites as biomarkers rather than proven treatment
targets. The key question for future research is whether reducing elevated
microbial metabolites leads to meaningful improvements in autism symptoms,
gastrointestinal function and quality of life.
