Treating autism has many parallels
with treating other complex neurological conditions like dementia or MS. You
need to treat multiple individual features of the disease and then you will the
greatest effect, this is called polytherapy.
· Mast cell activation is a common feature in both autism and Alzheimer’s.
· Neuroinflammation is a fundamental part of autism and Alzheimer’s. It looks like both menthol and vitamin D may have a role to play.
· Impaired cholesterol metabolism in the brain is a key feature of Alzheimer’s and occurs in some autism. It can be either too much, or too little.
An interesting new idea in Alzheimer’s
research is to use a potent mast cell stabilizer called Masitinib. It is
interesting because this drug has already been commercialized to treat pets.
Masivet UK (Kinavet US) Cancer Treatment Tablets for Dogs
There is great deal in this blog about
mast cells and autism.
Many readers give their child cromolyn
sodium, which is an excellent mast cell stabilizer, but it poorly crosses the
blood brain barrier. While cromolyn sodium is effective for conditions where
mast cell activity is predominantly peripheral, its limited CNS action makes it
less suitable for addressing neuroimmune dysregulation in autism, or other
brain-related conditions.
Ketotifen is another mast cell
stabilizer and it does cross the blood brain barrier better. It has also been
widely used in autism. It is cheap in some countries but expensive in others.
One known feature of mast cell
activation is an impaired blood brain barrier (BBB), so some of these drugs may
be more effective than expected.
Studies suggest that masitinib can
cross the BBB, particularly in conditions where the BBB is disrupted (inflammation,
neurodegenerative diseases, or neuroimmune disorders).
Masitinib works by inhibiting tyrosine
kinases involved in mast cell activation
and degranulation. By reducing mast cell activity, it may help to mitigate
neuroinflammatory processes implicated in conditions like autism, Alzheimer's
disease, and indeed multiple sclerosis (MS).
For those that want an up to date
summary of mast cell activation in autism there is an excellent new paper.
The
role of mast cells (MCs) in Autism Spectrum Disorder
Highlights
·
Increased MC
activity may be linked to the development of ASD.
·
MC mediators
influence neuroinflammatory pathways that are altered in ASD.
·
MCs can interact
with other immune and neuronal cells contributing to ASD symptoms.
·
The role of MC in
gut permeability and microbiota dysbiosis may also underly gastrointestinal
comorbidities in ASD.
·
Targeting MC
activity offers promising therapeutic avenues in treatment of ASD.
ASD
represents a multifaceted condition influenced by genetic, environmental, and
immune-related factors. MCs have emerged as pivotal players in the immune
processes associated with ASD, impacting neuroinflammation, autoimmunity and
gastrointestinal health. They interact with other immune cells, release
mediators that influence neurological processes, and help maintain the
integrity of the blood-brain and gut barriers. Evidence of alterations in these
processes in ASD patients, supported by extensive data from relevant animal
models, has highlighted disruptions in these processes among individuals with
ASD, underscoring the critical role of MCs in ASD pathology.
Current
ASD treatments primarily aim at managing symptoms rather than addressing
underlying mechanisms. However, targeting MC activity may represent a promising
innovative approach for intervention. The development of novel MC inhibitors
could significantly enhance our understanding of ASD pathobiology while
potentially offering therapeutic benefits for a defined subset of individuals
with ASD, improving their symptoms and quality of life.
Alzheimer’s research is very well
funded and so we already have results from the use of Masitinib in humans.
Abstract
Background
Masitinib
is an orally administered tyrosine kinase inhibitor that targets activated
cells of the neuroimmune system (mast cells and microglia). Study AB09004
evaluated masitinib as an adjunct to cholinesterase inhibitor and/or memantine
in patients with mild-to-moderate dementia due to probable Alzheimer’s disease
(AD).
Methods
Study
AB09004 was a randomized, double-blind, two parallel-group (four-arm),
placebo-controlled trial. Patients aged ≥50 years, with clinical diagnosis of
mild-to-moderate probable AD and a Mini-Mental State Examination (MMSE) score
of 12–25 were randomized (1:1) to receive masitinib 4.5 mg/kg/day (administered
orally as two intakes) or placebo. A second, independent parallel group
(distinct for statistical analysis and control arm), randomized patients (2:1)
to masitinib at an initial dose of 4.5 mg/kg/day for 12 weeks that was then
titrated to 6.0 mg/kg/day, or equivalent placebo. Multiple primary outcomes
(each tested at a significance level of 2.5%) were least-squares mean change
from baseline to week 24 in the Alzheimer’s Disease Assessment Scale - cognitive
subscale (ADAS-cog), or the Alzheimer’s Disease Cooperative Study Activities of
Daily Living Inventory scale (ADCS-ADL). Safety for each masitinib dose level
was compared against a pooled placebo population.
Results
Masitinib (4.5 mg/kg/day) (n=182)
showed significant benefit over placebo
(n=176) according to the primary endpoint of ADAS-cog, −1.46 (95% CI
[−2.46, −0.45]) (representing an overall improvement in cognition) versus 0.69
(95% CI [−0.36, 1.75]) (representing increased cognitive deterioration),
respectively, with a significant between-group difference of −2.15 (97.5% CI
[−3.48, −0.81]); p<0.001. For the ADCS-ADL primary endpoint, the
between-group difference was 1.82 (97.5% CI [−0.15, 3.79]); p=0.038
(i.e., 1.01 (95% CI [−0.48, 2.50]) (representing an overall functional
improvement) versus −0.81 (95% CI [−2.36, 0.74]) (representing increased
functional deterioration), respectively). Safety was consistent with
masitinib’s known profile (maculo-papular rash, neutropenia, hypoalbuminemia).
Efficacy results from the independent parallel group of titrated masitinib 6.0
mg/kg/day versus placebo (n=186 and 91 patients, respectively) were
inconclusive and no new safety signal was observed.
Conclusions
Masitinib (4.5 mg/kg/day) may benefit
people with mild-to-moderate AD. A confirmatory study has been initiated to
substantiate these data.
Not surprisingly there is a similar
study in MS.
Efficacy
and Safety of Masitinib in Progressive Forms of Multiple Sclerosis
Discussion
Masitinib
(4.5 mg/kg/d) can benefit people with PPMS and nSPMS. A confirmatory phase 3
study will be initiated to substantiate these data.
Masitinib has already been patented to
treat ALS the motor neuron disease.
Masitinib for autism?
I think the people who respond to
cromolyn sodium, but feel it lacks potency would be the ones who might benefit.
You either consult Prof Theoharides,
or the local vet (It’s a doggy medication).
Low dose Efavirenz to activate CYP46A1 to reduce brain cholesterol
Our reader Katya did raise the idea, a
few months ago, of low dose Efavirenz to lower cholesterol in the brain.
Elevated cholesterol in the brain is a
feature of some specific variants of autism.
Elevated brain cholesterol is a
contributing factor in many cases of Alzheimer's, but it is not a universal
feature. It depends which version of the APOE gene the person carries.
The brain has a lot of cholesterol in
it and all of it was produced there.
The brain cannot rely on peripheral
cholesterol transport due to the blood-brain barrier. The enzyme CYP46A1
ensures local cholesterol balance in the brain, by facilitating clearance of
excess cholesterol to maintain healthy neuronal and synaptic functions.
Proper cholesterol metabolism,
facilitated by CYP46A1, supports synaptic remodeling, plasticity, and repair,
which are critical for cognitive function.
Dysregulated cholesterol levels in the
brain can impair synapse function, and CYP46A1 helps prevent these disruptions.
Efavirenz is a drug used in the
treatment of HIV. Interestingly, at subtherapeutic doses, it has been shown to
activate CYP46A1 and so increase cholesterol clearance from the brain.
Background
Efavirenz
is an anti-HIV drug, and cytochrome P450 46A1 (CYP46A1) is a CNS-specific
enzyme that metabolizes cholesterol to 24-hydroxycholesterol (24HC). We have
previously shown that allosteric CYP46A1 activation by low-dose efavirenz in a
transgenic mouse model of Alzheimer’s disease (AD) enhanced both cholesterol
elimination and turnover in the brain and improved animal performance in memory
tests. Here, we sought to determine whether CYP46A1 could be similarly
activated by a low-dose efavirenz in human subjects.
Methods
This
pilot study enrolled 5 subjects with early AD. Participants were randomized to
placebo (n = 1) or two daily efavirenz doses (50 mg and
200 mg, n = 2 for each) for 20 weeks and evaluated for
safety and CYP46A1 target engagement (plasma 24HC levels). A longitudinal mixed
model was used to ascertain the statistical significance of target engagement. We
also measured 24HC in CSF and conducted a unique stable isotope labeling
kinetics (SILK) study with deuterated water to directly measure CYP46A1
activity changes in the brain.
Results
In
subjects receiving efavirenz, there was a statistically significant
within-group increase (P ≤ 0.001) in the levels of plasma 24HC from
baseline. The levels of 24HC in the CSF of subjects on the 200-mg dose of
efavirenz were also increased. Target engagement was further supported by the
labeling kinetics of 24HC by deuterated water in the SILK study. There were no
serious adverse effects in any subjects.
Conclusions
Our
findings suggest efavirenz target engagement in human subjects with early AD.
This supports the pursuit of a larger trial for further determination and
confirmation of the efavirenz dose that exerts maximal enzyme activation, as
well as evaluation of this drug’s effects on AD biomarkers and clinical
symptomatology.
It looks like 50mg a day of efavirenz
is an effective option to reduce levels of cholesterol in the brain.
Interestingly it is not effective in people already taking a high dose of
atorvastatin. This should not be a surprise since atorvastatin will have
already lowered cholesterol in the brain.
So to lower cholesterol in the brain
you could use the 50mg of efavirenz, or if that was not possible then 40mg of
atorvastatin would be an option. The trial showed using both drugs
together was pointless.
First
patient completes new trial to test Alzheimer’s medication
13 March 2025
The
existing HIV medication Efavirenz may potentially also be effective for
Alzheimer’s patients, Vrije Universiteit Amsterdam neuroscientist Rik van der
Kant and Amsterdam UMC neurologist Jort Vijverberg discovered. This fall, a
clinical trial has begun at Amsterdam UMC, and the first patient has just
completed the trial.
Participants
are still being recruited. The research is led by Rik
van der Kant and Jort Vijverberg (Amsterdam UMC - Alzheimer Center
Amsterdam). Van der Kant has been researching new drugs for Alzheimer’s disease
for years, using groundbreaking technology that allows him to test hundreds of
potential medications simultaneously.
Promising
step
“I discovered that cholesterol buildup in brain cells of Alzheimer’s patients
directly leads to an accumulation of the toxic proteins Tau and Amyloid,” Van
der Kant explains. “Efavirenz turned out to be suitable for reversing this
buildup. It's very special and unique to be able to do all of this ourselves,
within the walls of Amsterdam UMC." Vijverberg is also hopeful. “We are
very curious to see how this medication will work in Alzheimer's patients. Of
course, we still have to see the results, but I consider it a promising step in
the right direction.”
The Alzheimer’s APOE
story
Apolipoprotein E (APOE) plays a
critical role in lipid transport and cholesterol homeostasis in the brain. It
facilitates the redistribution of cholesterol and other lipids between cells
for membrane repair, synaptogenesis, and other neuronal functions.
In the brain, APOE interacts with
specific receptors, such as the low-density lipoprotein receptor (LDLR), to
regulate cholesterol and amyloid-beta (Aβ) clearance.
APOE Variants:
There are three major alleles of the
APOE gene: ε2, ε3, and ε4, which encode the respective protein isoforms.
APOE
ε2: Rare and protective against AD.
APOE
ε3: The most common variant with neutral risk for AD.
APOE
ε4: A strong genetic risk factor for AD.
APOE ε4's Impact
on Cholesterol and Aβ
Reduced Cholesterol Transport: APOE ε4
is less efficient in binding and redistributing cholesterol compared to APOE ε3
or ε2. This inefficiency can lead to local cholesterol dysregulation in the
brain, particularly in neurons and astrocytes.
APOE ε4 is less effective in promoting
Aβ clearance via receptor-mediated pathways (e.g., LDLR, LRP1).
The isoform is associated with an increased tendency of Aβ peptides to aggregate, contributing to plaque formation.
Cholesterol
Accumulation and AD Pathogenesis:
Elevated cholesterol levels in
neuronal membranes can favour the activity of β- and γ-secretases, enzymes
involved in Aβ production.
The inefficient lipid transport by
APOE ε4 exacerbates cholesterol accumulation in affected brain regions,
creating a feedback loop that promotes amyloidogenic processing.
Vitamin D in
Alzheimer’s and Maternal Immune Activation Autism
Vitamin D’s role in Alzheimer’s disease has been widely studied, with growing evidence suggesting it may influence risk and progression, but it is not a cure or primary treatment.
Vitamin D appears to have a supportive
role in brain health, potentially lowering the risk or slowing progression of
Alzheimer’s disease by reducing inflammation, aiding amyloid clearance, and
protecting neurons. However, vitamin D alone is not a standalone treatment for
AD. Ensuring adequate vitamin D status is a simple, low-risk strategy that
could contribute positively as part of a broader approach to brain health and
dementia prevention.
In Japan researchers have recently
found that they can prevent autism caused by maternal immune activation simply
by giving a vitamin D supplement during pregnancy. This was in a mouse model,
but what about its use as yet another method to prevent/reduce some human
autism?
Autism
spectrum disorder (ASD), a neurodevelopmental disorder of unknown etiology with
limited treatment options, has emerged as a significant public health concern.
Studies have demonstrated that prenatal vitamin D deficiency is a risk factor
for ASD development in offspring; however, the underlying mechanism remains
unclear. In this project, vitamin D was administered orally to pregnant mice
with/without the subsequent administration of polyriboinosinic
polyribocytidylic acid (Poly(I:C)), which induced the maternal immune
activation (MIA). Our results showed that vitamin D supplementation during
pregnancy alleviated MIA-induced ASD-like behaviors in offspring. Moreover, vitamin D supplementation
reduced the MIA-induced elevation of interleukin-6 (IL-6) and IL-17a levels in
both the maternal ileum and fetal brains. It also suppressed signal
transducer and activator of transcription 3 (Stat3) activation and the elevated
expression of serum amyloid A1 and A2 (SAA1/2) in the ileum of MIA-affected
pregnant mice. This study
revealed that vitamin D may reduce the expression of IL-17a by inhibiting the
IL-6/Stat3/SAA signaling pathway, thereby improving ASD-like behavior in
offspring mice, and provide a new theoretical support for the prevention and
treatment of ASD by scientific dietary interventions and nutritional supplement
during pregnancy.
Menthol for Alzheimer’s and some Autism?
I recall one reader, I think is was
Natasa in London, mentioned that menthol should be a helpful autism therapy for
some people. I see today that Nestle even holds an old patent on its use for
autism.
The surprise is that just inhaling the smell of menthol has an anti-inflammatory effect in the mouse model of Alzheimer’s.
Surprise
Link Between Menthol And Alzheimer's Found in Mice
In recent years, scientists discovered something strange: When mice with Alzheimer's disease inhale menthol, their cognitive abilities improve.
It
seems the chemical compound can stop some of the damage done to the brain
that's usually associated with the disease.
In
particular, researchers noticed a reduction in the interleukin-1-beta (IL-1β)
protein, which helps to regulate the body's inflammatory response – a response
that can offer natural protection but one that leads to harm when it's not
controlled properly.
The
team behind the study, published in April 2023, says it shows the potential for
particular smells to be used as therapies for Alzheimer's. If we can figure out which odors
cause which brain and immune system responses, we can harness them to improve
health.
"The results suggest that odors and immune modulators may play an important role in the prevention and treatment of Alzheimer's and other diseases related to the central nervous system."
Patent
- Treatment or prevention of autism disorders using menthol, linalool and/or
icilin
Current Assignee: Societe des Produits Nestle SA
Compositions
for treatment or prevention of autism disorders are provided, and the
compositions contain a therapeutically effective amount of a compound selected
from the group consisting of Menthol, Linalool, Icilin and combinations
thereof. Methods for treatment or prevention of autism disorders are also
provided, and the methods include administering such compositions.
Menthol has shown promising effects in
modulating inflammatory pathways, including those involving IL-1β and the NLRP3
inflammasome.
Menthol and IL-1β
- Menthol inhibits the production and
release of pro-inflammatory cytokines, including IL-1β, which is a key
mediator in various inflammatory conditions.
- Menthol primarily acts through transient
receptor potential melastatin 8 (TRPM8) channels. Activation of TRPM8 can
indirectly reduce inflammation by modulating neural and immune pathways.
Menthol and the
NLRP3 Inflammasome
- Studies indicate that menthol may
inhibit the activation of the NLRP3 inflammasome, a multiprotein complex
responsible for IL-1β maturation and release.
- Menthol's ability to suppress oxidative
stress and calcium influx, both of which are critical for NLRP3
activation, contributes to its anti-inflammatory effects.
- These properties make menthol
a potential therapeutic candidate for diseases where the NLRP3
inflammasome plays a role, such as neurodegenerative diseases, autoimmune
conditions, and metabolic disorders.
Conclusion
It looks like keeping an eye on research across a broad range of neurological conditions is a wise idea, if you want to treat autism.