Hardly a
week goes by without somebody mentioning to me a wonder treatment or even “cure”
for autism; the latest one being the GAPS diet.
What is not disputed is that autism has many sub-types (phenotypes). Researchers tell us 10-20% of cases referred to as autism have a known genetic defect (Fragile X, SLOS, Timothy syndrome etc.). 80% do not have a known genetic marker/cause.
By screening for hormonal dysfunction, it would be possible to identify phenotypes that would most likely benefit from therapies targeting those defects, like NNZ-25266.
I think all
such reports are worthy of investigation, but many lead to nowhere.
Why is this?
Why is this?
·
Medical
science has failed to adequately define autism, so we are not all talking about
the same autism
·
Many
people putting forward theories have not read even the most basic (and not
contested) autism research. Some are
even, apparently, qualified “doctors”.
Autism PhenotypesWhat is not disputed is that autism has many sub-types (phenotypes). Researchers tell us 10-20% of cases referred to as autism have a known genetic defect (Fragile X, SLOS, Timothy syndrome etc.). 80% do not have a known genetic marker/cause.
Autism can
be subdivided into regressive (when a child loses speech and other learnt
skills) and non-regressive (early onset).
Even this can be a subjective judgment, since it effectively relies on
parents to determine it, after the event.
Then you
have cases of autism which clearly have nothing to do with Kanner’s classic version. In this blog I showed how even cerebral
malaria in a child can lead to the onset of autism. This clearly is a case of brain damage caused
by malaria; but to the observer, months later, it would probably be classed as
regressive autism or childhood disintegrative disorder.
Testing for Autism
Researchers
and doctors keep repeating that there is no test for autism. This is not strictly true, but it does
explain why so many different conditions are all lumped together as “autism”.
In fact, if
you read the research closely, you will see that there are many tests for
autism; although they may not be perfect.
The only way
to know for sure that it is genuine autism is to examine the brain itself. The only way to do this 100% accurately is
via post-mortem analysis of the brain. Recently,
non-invasive methods have been developed to confirm the same findings of brain
malformation that occurred prior
to birth.
So the kind
of autism that relates to tissue held in brain banks is best understood. But what kind of autism would that be? Well, it refers mainly to children and young
adults who died prematurely. They died
from things like seizures or drowning.
What does that tell us? This
tells us that these people were most likely severely affected by autism. The mild, social difficulties, type of autism
is, fortunately, hardly likely to make it to the brain tissue bank.
If the person
interpreting the MRI of a child’s brain knows what to look for, they may very
well be able to identify this type of autism.
The expert here is Eric Courchesne.
A similar approach can followed using Electroencephalography (EEG) to identify autism; but it
would be smart to cross check this with Eric.
Regressive vs. Early-Onset
Then you
have the difference between regressive and non-regressive autism. Here again, from my Dean’s List of researchers,
we look at Paul Ashwood’s research to see that kids with regressive autism have
HIGHER levels of inflammatory markers
in their blood. These include cytokines
like interleukin 6, which can be inexpensively measured in most laboratories. This tells us that perhaps regressive autism
is an entirely different condition from non-regressive/early onset autism. As I would expect, increasing
cytokine levels were associated with more impaired communication and aberrant
behaviors.
Lab Testing
We have seen
earlier in this blog that some very expensive lab tests exist for autism, but their
usefulness and integrity is highly disputed.
There are, of course, many hundreds of other tests that are entirely validated
by medical science. Many of these tests
are cheap and available all over the world.
Hormonal Screening
We know from
the research that about 30% of people with autism have high blood serotonin. A standard
lab test is required.
We know that
many have high levels of insulin-like growth factor (IGF-1). A standard lab test is required.
Thyroid hormone
levels and in particular a blunted response of TSH to TRH (i.e. central
hypothyroidism) can help define further phenotypes.
The TRH test
is now not widely used, but TSH, FT3 and FT4 are cheap tests.
Growth
Hormone (GH) is also implicated in autism, along with IGF-1; there is a lab
test to measure pituitaryfunction to see how well GH is being produced. By screening for hormonal dysfunction, it would be possible to identify phenotypes that would most likely benefit from therapies targeting those defects, like NNZ-25266.
Pancreatic Dysfunction
It is reported
by Joan Fallon, of Curemark, that 50+% of kids diagnosed with “US autism” seem
to have a pancreatic dysfunction. This
can be tested for by measuring fecal chymotrypsin level. The test measures how well your pancreas is
working, and is a standard test for people with cystic fibrosis. Since the US diagnoses far more kids with
autism than other countries, it seems highly plausible that “US autism”
includes many more phenotypes than, say, “French autism”.
I was quoted
about $8 for a chymotrypsin test.
Ion-Channel Diseases
(Channelopathies)
Many diseases
like Parkinson’s disease, Spinocerebellar Ataxia and Timothy Syndrome are
caused by faulty calcium ion-channels.
The
Bumetanide autism therapy, undergoing trials in Europe, is based on another
channelopathy, this time a faulty chloride transporter NKCC1.
It is clear
from reports I have received, that Bumetanide therapy is totally ineffective in
some children with ASD, but in other children, like my son, it is effective.
So some
types of autism have certain channelopathies and other types have different ones
or, quite possibly, none at all.
Conclusion
My
conclusion today is pure conjecture. I
imagine that possibly as few as a quarter of cases of “US autism” are actually “real”
autism, that is with all the brain damage/malformation that is identified in those
post mortem brain studies and which forms the basis of 90% of autism research.
The other
three quarters may be something entirely different, just like the case of the
mosquito that bit the child, produced cerebral malaria and then later the full
symptoms of autism. Within the three quarters
may be food allergies, digestive enzyme deficiencies, gut disorders, mastocytosis,
blood brain barrier defects, undefined calcium ion-channel diseases etc.
This would
account for those occasional amazing “recoveries” and the apparent success, in some
cases, of diets like GAPS. Sadly, diet is
unlikely to 100% fix brain damage. If
you are lucky enough to totally “recover”, you cannot have had brain damage in
the first place. It is evident that in
some phenotypes of autism, diet can reduce autistic behaviours. This can only be proved in trials, if
biomarkers are established for that specific phenotype.
Most likely the
only biological thing all these “autisms” have in common is oxidative stress
and neuroinflammation; but only a non-medical scientist, like me, can say such
a thing.
Thanks for this.
ReplyDeleteI am myself back on the channelopathy theme. They are most likely all inter-related. It appears that a well known sodium channelopathy, affecting autism may indeed be treatable. In mice it works. The channel is Nav1.1, the gene is SCN1A and the drug is called Clonazepan/Rivotril. I know that Andersen-Tawil is a potassium channelopathy. Sodium, potassium and indeed calcium and magnesium are all inter-related. Magnesium can block calcium channels for example. Have you ever tried Verapamil? It is a very common calcium channel blocker that blocks some potassium channels. It will raise K+ levels in the blood, but if you have a potassium channelopathy it will likely have other effects.
Hi Peter,
DeleteI'm fascinated by your blog and the amount of research that you do. I have a question for you regarding the chloride channelopathy. Can a calcium channelopathy cause or trigger a chloride channelopathy?
It is known that a sodium channelopathy can trigger a second sodium channelopathy. Ion channels are interrelated so it is plausible that a calcium channelopathy could cause a chloride channelopathy, but I doubt anyone has proved it. The understanding of this area of science is in its infancy.
DeleteWonderful stuff here. Thanks for going to the trouble to do the writing.
ReplyDeleteHello Peter,
ReplyDeleteI am learning so much from you and i thank you.
I have a 3.1 year old daughter who is under ASD and i have noticed something like whenever she takes bath with rock salt(1 ts) mixed in water, her Autism symptoms improved. She will respond to her name and follow instructions and try to repeat words. I dont know why this is happening, may be you have something to tell me.
Thanks,
Many people use Epsom salts (MgSO4) in bath water and it is the Magnesium that is absorbed through the skin that causes the effect.
DeleteRock salt is normally just NaCl. Apparently when you swim in the sea you do not absorb sodium (Na) from the water.
I wonder if your rock sock salt has something other than NaCl in it, perhaps magnesium?
We tried epsom salt but it makes my daughter crazy(literally). So we started with rock salt and immediate improvement was noticed. We stopped and started again and everytime we see improvements. Improvements like following instructions, repeating words, eye contact, not staying alone. But few issues arises as well like improper voices, sleeping late at night,waking up early, separation anxiety. I think its sodium because i tried with baking soda and i get almost similar effect.
Deletehttps://en.wikipedia.org/wiki/Kala_namak
Deletethis is the salt.
Also, i thought it was the sulphate to which my daughter is reacting so had tried Magnesium chloride as well but not same effect as of rock salt.
DeleteTry table salt (pure NaCl), if that has no effect then it is the "impurities" in the rock salt. There are many.
Delete