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Showing posts with label Cav1.2. Show all posts
Showing posts with label Cav1.2. Show all posts

Thursday 23 October 2014

GERD/Reflux, Autism, Head Banging and mGlu5






This brief post addresses one further issue as to why people with autism can often suffer from various nasty gastrointestinal (GI) problems. 

First a recap.


Mast Cell Activation

We have already seen that some people’s GI problems are caused by mast cell activation/degranulation.  These cells are activated by allergens (certain foods in this case) and then they release histamine and other pro-inflammatory agents like IL-6.  Degranulation of mast cells can itself cause pain, but the main problem is the resulting damage/inflammation caused by the IL-6 and histamine.

The effective therapy is a mast cell stabilizer.  These include Verapamil (better known as a calcium channel blocker), Cromolyn Sodium, Ketotifen, Azelastine and to a lesser extent most anti-histamines like Claritin, Zyrtec etc.  Quercetin, the flavonoid, also has an effect.


Pancreatic Dysfunction

We also saw that L-type calcium channel (Cav1.2) dysfunction in the pancreas may disrupt the production of certain digestive enzymes.  The lack of these enzymes will disrupt the digestive process and likely affects other processes elsewhere in the body.  Verapamil blocks the Cav1.2 channel.


Ulcerative Colitis

We saw that inflammation and colitis, as diagnosed by an endoscopy, is another comorbidity of autism; this may be in part caused by the mast cell degranulation, but it does fit with the broader hypothesis of the over-activated immune system.  We saw how the potassium ion channel Kv1.3 was the mechanism behind some useful immuno-suppressive therapies, including those TSO parasites.  For those who are skeptical, here is another recent study, I just found:-

  

Kv1.3 should then be a target to treat ulcerative colitis and, I believe, autism itself. Some Kv1.3 blockers exist today; one is Verapamil, another is Curcumin, for those who prefer supplements to drugs.




Before I forget to write this down somewhere, it appears that Kv1.3 can also be modulated by PKA and PKC, which decrease its activity. 


We have already come across protein kinase B (PKB) and there will be a post soon of PKA, PKB and PKC.  This all links back to oxidative stress, neuroinflammation and even those dendritic spines.

  
Reflux

Today’s post is about reflux, sometimes known as gastroesophageal reflux disease (GERD) or gastro-oesophageal reflux disease (GORD).  Reflux is when the acid from the stomach rises through the esophagus/oesophagus to the mouth.

Many adults suffer from reflux from time to time and there are many OTC and prescription drug treatments. It can cause pain and discomfort, and would be particularly troubling if you could neither verbalize, nor understand your symptoms.


Why this post?

You may wonder why I have jumped from broccoli (the previous post) to reflux.  There is a reason.

I was recently listening to a conversation between doctors about a head-banging child and then came “it’s not autism; he’s got reflux, that is why he was banging his head.”

That sounded very odd to me.

It turns out many people with autism suffer from reflux, so you could say it is a comorbidity.  But why might that be?


mGlu5 receptors and disease

In an earlier, rather complicated, post I introduced the glutamate receptor, mGlu5.  This receptor is at the centre of research into Fragile X at MIT.  Fragile X is the most common single gene cause of autism.  It has been shown that mGlu5 dysfunction appears in many types of autism and indeed schizophrenia (adult-onset autism).
   
I then chanced upon a recent paper on mGLu5 and came across this section:-

Through contributions to synaptic plasticity, mGlu5 receptors have been implicated in neuronal processes such as learning and memory as well as disorders including Fragile X Syndrome (FXS), tuberous sclerosis, autism, epilepsy, schizophrenia, anxiety, neuropathic pain, addiction, Alzheimer’s disease, Parkinson’s disease, L-DOPA-induced dyskinesias, and gastroesophageal reflux disease


That was quite a surprise, but yet another good lesson of why the comorbidities should all be carefully researched.
 
The full paper, for anyone with time on their hands is:- 



Conclusion

If you have autism, you may have an mGlu5 dysfunction.  This will become treatable once the needed PAMs (Positive Allosteric Modulators) and NAMs (Negative Allosteric Modulators) have been brought to market.  A great deal of research is ongoing.

In the meantime, mGlu5 dysfunction is quite possible elsewhere in the body.  mGlu5 dysfunction is associated with some very rare disorders, but the common ones are diabetes and reflux.

The head-banging boy very possibly had both autism and reflux; he did develop diabetes.

For more on autism and diabetes, a short, thought provoking, but technical, paper:-


Interestingly, we saw earlier that Verapamil seems to offer protection against type 1 and 2 diabetes. This time it is its calcium channel blocking role that is the mechanism.



No big surprise that Verapamil is an ingredient of the autism Polypill.




Verapamil drug may reverse diabetes-related death of pancreatic beta cells


Wednesday 16 July 2014

Verapamil for a Broader sub-group of Autism and even Diabetes?



This blog is about science rather than medicine, and believe me there is a much bigger difference than you might hope for.
Many aspects of the research literature indicate the potential of certain calcium channel blockers, like Verapamil, to be useful in treating autism.  As we have seen, there are many different causes of autism and what treatment works in one type may be totally ineffective in another type.

For almost a year Monty, now age 11 with ASD, has taken Verapamil to control the behavioural effects of allergy that are driven by so called “mast cell degranulation”.  His pollen allergy makes his summertime behaviour dramatically worse; a reaction that is almost entirely reversed by Verapamil.

In my page in this blog on Allergies and Autism I raised the question as to whether Verapamil would be effective in treating the many people with autism who have food allergies leading to gastrointestinal (GI) problems.  Many people with autism have symptoms like Irritable Bowel Syndrome (IBS) or Inflammatory Bowel Disease (IBD) and these are widely associated with worsening autistic behaviours.  Monty has no GI issues or food intolerance.  I was very interested to receive some lengthy comments from a mother with a son who does have autism plus GI problems.  She found Verapamil highly effective in treating both his GI problems and the autism.  This is rather significant, since while I do receive the odd comment that H1 antihistamines have an unexpected beneficial effect on autism, which supports some of my own findings and theories, the issue of GI problems is very common in autism.  Could a pill called Verapamil be the little wonder for them as well?  The science does indeed support this, even if current medicine does not.

 

How can medicine be so disconnected from science?  It does seem to happen far more often than it should.

I did wonder if I was missing something about Verapamil.  It is an L-type calcium channel blocker and in autism there is a known genetic dysfunction (CACNA1C) that affects the calcium channel (Cav1.2) blocked by Verapamil.  It also turns out that Verapamil has been shown to be a highly effective mast cell stabilizer.  I did a little more digging and found something very surprising, the effect of Verapamil on the pancreas.  The pancreas makes all kinds of enzymes as well as insulin.  In some people with an auto-immune dysfunction the body destroys its own insulin producing cells and diabetes results.  In some people with autism (also an auto-immune condition) the pancreas seems not produce some of the other enzymes and there are various DAN-type treatments for this; and the new CUREMARK drug CM-AT seems to target this dysfunction.

Science has remarkably shown that Verapamil had the potential to reverse diabetes, if intervention is early.  Given that type 1 and type 2 diabetes are becoming increasingly common and account for a substantial part of national healthcare costs, it seem odd that medicine has not taken full note.



It appears that older people on Verapamil for hypertension, strangely do not develop type 2 diabetes, which supports the claim for Verapamil.

There is no mystery as to why this is happening.  Calcium channels are widely expressed in pancreas, just as they are in the heart and the brain.  The effect of aberrant calcium channel signalling does no good for the brain in autism and in some other people, with a tendency to auto-immune problems, it would appear to be the pancreas that suffers.

You will recall that autism is amongst, other things, an auto-immune condition.  If you look at the extended family you will likely notice other auto-immune conditions like diabetes, thyroid problems, and arthritis.  (I would myself add fibromyalgia and even some types of chronic headaches to this list)

Recall that several drugs that help autism have a beneficial effect in diabetes and that the key type 2 drug for diabetes seems to have a positive effect on autism.

PPAR alpha, beta and gamma in Autism, Heart Disease and Diabetes


In the above post we saw that PPAR gamma (PPARγ) is a nuclear hormone receptor which modulates insulin sensitivity.  The following autism study looked at the effect of a common diabetes drug, pioglitazone (Actos), an FDA-approved PPARγ agonist used to treat type 2 diabetes, with a good safety profile. 
 

Pioglitazone is currently in Phase 2 trials for autism.

Another comorbidity of autism that is an auto-immune condition is asthma.  Here again, Verapamil was shown many years ago to hold promise.

Verapamil in the prophylaxis of bronchial asthma

A single oral dose of verapamil 80 mg was shown significantly to inhibit histamine-induced bronchoconstriction in 8 out of 16 asthmatic subjects (maximum increase in PD20FEVHi 416%). There was still significant protection (Δ PD20FEV1Hi>100%) in the responders 5 h after the oral dose.

I also noted in earlier posts that anti-oxidants seem to reduce the insulin required by diabetics and also improves one of the big problems that occurs along with diabetes that is peripheral neuropathy.  These antioxidants, like ALA, NAC, Thioctacid etc are also chelators of heavy metals.  While the planned study of chelators in autism in the US was effectively “banned”, a large study was carried out on heart patients.  Chelation was shown to be remarkably beneficial, but chelation is really just a shock dose of antioxidants.

Effect of Disodium EDTA Chelation Regimen on Cardiovascular Events in Patients With Previous Myocardial Infarction The TACT Randomized Trial


My take on this is that in many medical conditions, oxidative stress is present and therefore any antioxidant will be beneficial, but some more so than others.  In the well-researched world of asthma they concluded that the most potent, safe antioxidant was NAC (N-acetylcysteine).  NAC is my choice for autism.


Conclusion

If you have autism and suffer from chronic GI problems, Verapamil might well offer significant relief.

If you have unexplained autism flare-ups, like aggression, in summer this may well be driven by a pollen allergy, Verapamil is likely to help.

If your older relative has hypertension already and looks likely to be heading towards type 2 diabetes, maybe suggest they talk to their doctor about Verapamil;  it may well treat both.

Incidentally, if you have a child with autism and suffer yourself from chronic headaches or fibromyalgia, you might want to try some Verapamil yourself.

Verapamil is a very cheap generic drug; one tablet cost a couple of cents/pence. 


Opinion

I continue to be surprised how far medicine is behind science.

In the case of autism there is now a great deal of “actionable” research that is available for anyone to read.  This blog is about autism, but it seems that in many other areas of medicine the same is true, for example diabetes and types of cancer.   

The idea is that you should wait for clinical trials.  But who do you think is going to do them? There is no financial incentive for drug firms to do trials on old generic drugs for new uses.  Prepare for a long wait.

The medical practitioners involved with autism, mainly psychiatrists if anyone, show little interest in any novel treatment that has not yet been approved.  With such little interest from clinicians, novel treatments will remain well kept secrets for decades to come.

The “alternative” practitioners dealing with autism, like DAN doctors, are mainly in the US; but they are not fully grounded in science and seem overly interested in unorthodox expensive lab tests and costly supplements.

So you really do have to figure out autism for yourself, if you want to control it.  



Tuesday 13 May 2014

“Spray Fire in my Head” and how putting it out with Verapamil links Histamine, IL6, Mast cells, Calcium Channel Cav1.2, and even the Vagus Nerve


After 18 months of researching autism, things are falling nicely into place.  For regular readers of this blog, it may seem that we have uncovered a bewildering number of issues/dysfunctions that need to be addressed by the science.  In fact, when you look closer still, you will see that many of these issues are interrelated and you do not need to treat each one.  Also, it is clear that many different methods can be used to treat the same dysfunction.  The best methods though would be the simplest, safest, cheapest and the ones that address multiple issues at once.

One such little gem is Verapamil, an extremely cheap calcium channel blocker that has been widely used for 30 years for other conditions. 


Spray Fire in my Head

Monty, aged 10 with ASD, suffers from allergies like many children.  I noticed that his pollen allergy provoked a dramatic increase in his autistic behaviors.  Last year I spent time developing a treatment for these summertime autism flare-ups, to avoid summertime misery for all of us.

My final secret weapon was not a commonly known allergy drug; in fact almost nobody would even consider it for this purpose, except those who read the old research.

Where we live, last the weekend the air was full of tree pollen and it was 280 C/ 820 F; so I was expecting a response from Monty.

He soon had red eyes, briefly rolled about on the floor and declared “spray fire in my head”.

In anticipation of the pollen season, for the last few weeks I have been giving him some mast cell stabilizing treatments, but clearly they were not sufficient; so I mixed up some extra verapamil, and as expected, a few minutes later peace was fully restored.

I have told you about channelopathies in previous posts.  Verapamil blocks the calcium channel called Cav1.2, but I did not tell you that in addition to this Cav1.2 channel affecting behavior and heart disease, it also appears to directly affect allergies and even the vagus nerve.

It would seem that one cheap little pill can address all of these issues.


The take-home points from the literature are these:-

Verapamil is very widely prescribed calcium channel blocker, used to lower blood pressure; but in the literature it is shown that:-
  • Verapamil inhibits mast cells and is shown to successfully treat asthma
  • Verapamil is more potent than the allergy drug Azelastine (the best mast cell stabilizing anti-histamine drug available)
  • Verapamil will reduce histamine release and therefore inflammatory cytokine Interleukin-6 (IL6), already elevated in autism
  • Verapamil activates the Gene for IL6
  • Verapamil alters the balance between parts of the autonomic nervous system's function, with a shift toward decreased sympathetic tone and increased parasympathetic (vagus nerve) tone
  • Autism is associated with an atypical autonomic response to anxiety that is most consistent with sympathetic over-arousal and parasympathetic under-arousal.  So increasing the parasympathetic (vagus nerve) tone is desirable.
  
Verapamil, Allergies and Asthma

Pollen allergies are a common trigger for asthma, and since every year many people die from asthma, the underlying science is well researched/understood.

  
Discussion
This study has demonstrated, for the first time, that mast cell tryptase potentiates the contractile response to histamine in human isolated airways. Moreover, this potentiation occurs only in tissues derived from patients whose bronchi exhibit a contractile response to antigen, i.e. which are sensitized. The potentiation was not observed in nonsensitized tissue. The mechanism underlying the tryptase-induced potentiation is related to Ca2+ flux through voltage-dependent channels, since it was inhibited by verapamil.

Inhibition of rat mast cell degranulation by verapamil.

Abstract
Calcium antagonists, e.g. verapamil, prevent exercise-induced asthma. This protective effect may proceed from inhibition of contraction of bronchial smooth muscle, release of mediators by primary effector cells, e.g. mast cells, or both. Therefore, we studied the inhibitory effect of increasing concentrations of verapamil on both in vitro antigen-induced degranulation and ionophore A23187-induced release of labelled serotonin by rat peritoneal mast cells. There was a dose-dependent inhibition by verapamil of both ovalbumin-induced degranulation of mast cells passively sensitized by incubation with mice IgE-rich serum and ionophore-induced release of tritiated serotonin by mast cells previously incubated with (3H)-5HT; the 50% inhibiting concentration was 1.4 X 10(-4) mol I-1 and 5.2 X 10(-5) mol I-1, respectively. An attractive explanation of our results is that verapamil inhibits the antigen-induced release of mediators by mast cells through its calcium antagonist effect. Our results also suggest that the preventing effect of calcium antagonists on asthma may be multi-factorial since other authors have clearly shown that these drugs inhibit contraction of guinea-pig tracheal smooth muscle in vitro.

COMPARATIVE STUDY OF AZELASTINE AND VERAPAMIL IN THE MODIFICATION OF OVALBUMIN SENSITIZED LUNGPARENCHYMAL TISSUES OF GUINEA PIGS IN VITRO

The inhibition of mediator released by Azelastine may help to explain their protective action in anaphylaxis. Our observations are in agreement that Azelastine exerts inhibitory effect on synthesis and release of chemical mediators from mast cell (Chand et al., 1983), including the leukotrienes (Hamasaki et al., 1996).

 Azelastine is a second-generation antihistamine approved for treatment ofallergic conditions. This randomized, double-blind, placebo- and active-controlled, parallel group clinical trial evaluated the efficacy and safety of Azelastine in patients with moderate to-severe seasonal allergic conditions (Shah et al., 2009).  Reussi et al. (1980) have demonstrated the inhibition of release of chemical mediators from mast cells by Ca++ channel blocker in animals in vivo and demonstrate the inhibition of antigen-induced brocho-constriction by Verapamil in sheep, allergic to ascaris sum antigen but Verapamil failed to block in the same non-sensitized animal. It is speculated that calcium channel blocker protect against the allergic broncho-constriction predominantly by preventing the release of chemical mediators from the mast cells.

Fig. 2. Graph shows dose dependent inhibitory effect of Azelastine and Verapamil with the treatment of EC50 ovalbumin. Line in the box indicates the ovalbumin EC50 induced contraction (Control). Each point represent mean of six observationsSyed Saud Hasan et al. 49  On the other hand Henderson et al. (1983) found significant inhibition of allergic response with Nifedipine and Lee at al. (1983) also supported the finding, which observed inhibition of mediator release from human lung in vitro by Verapamil.

   Verapamil in concentration 10-10 g/ml did not exhibit any inhibition but as the concentration increases to 10-9 g/ml showed marked inhibition in contractile effect of ovalbumin EC50 (0.3x10-6). Further increases in concentration of Verapamil i.e. 10-8 g/ml completely antagonized the ovalbumin induced contraction. Azelastine in concentration of 10-9 g/ml (1ng/ml) did not exhibit any inhibition as the concentration increase to 10-8 g/ml showed mark inhibition i.e. 20% contraction to EC50 (0.3x10-6) ovalbumin, when compared before treatment with Azelastine and the concentration 10-7 g/ml antagonized the effect of EC50 (Table and Figure 2).







CONCLUSION It can be inferred from the observations that response produced by antigen can be controlled better with Verapamil than Azelastine and emerging with similar activity regardless of exact mechanism involved.




Verapamil and the IL-6 Gene


Conclusions—The results demonstrate that CCB of all 3 subclasses are capable of activating NF-IL6 and NF-kB. CCB may thus directly regulate cellular functions by affecting the activity of transcription factors independent of changes of intracellular calcium concentrations, an observation that is of interest considering the biological effects induced by CCB.

A major result of our investigations is the discovery of the activation of  transcription factors resulting from CCB treatment. In general, CCB are postulated to exert their biological effects by decreasing the intracellular concentration of calcium ions.1–4 Experimentally, this effect is usually achieved at micromolar concentrations of the drugs. However, accumulating evidence suggests that CCB, used at therapeutically effective doses (ie, at the nanomolar range), activate calcium in dependent signal transduction pathway(s) altering gene expression.14–17 Here, we show that CCB directly activate the transcription factors NF-IL6 and NF-kB in human VSMC, independent of intracellular calcium levels. This is supported by the existence of multiple regulatory regions within the intracellular part of the L-type calcium channel. It remains to be investigated, however, along which signal transduction pathway this action of CCB occurs.


Verapamil and the Vagus Nerve

Two of the most popular subjects on this blog are “autism and allergies” and “autism and the vagus nerve”.

The vagus nerve connects many parts of the body and seems to be a conduit for inflammatory signaling within the body.  It is deeply involved the process leading to arthritis and epilepsy; by stimulating this nerve with electrical signals, both epilepsy and arthritis can be reduced markedly in certain people.  It is often suggested that the GI problems in many autistic people and linked to aberrant behaviors via the vagus nerve, what some call the “gut brain connection”.

To understand what is going on and why is does affect autism we need to introduce something new, the autonomic nervous system.  For those who already know about this, the interesting finding is that:-

Verapamil alters the balance between parts of the autonomic nervous system's function  with a shift toward decreased sympathetic tone and increased parasympathetic (vagus nerve) tone.

The source of this statement is:


and their sources were:-




We learned in an earlier post about autism and the Vagus Nerve that it seems to link many strange things in autism.

We learned from Professor Porges that, for example, the neural mechanism for making eye contact is shared with those needed to listen to the human voice; people with autism struggle with both.  Anything that can “wake up” the vagus nerve system could be interesting.
  

In the complicated science we will see that the vagus nerve is also called the parasympathetic nervous system.  The paper below shows how this parasympathetic (Vagus) system is out of balance with the opposing sympathetic nervous system, this then leads to anxiety commonly found in autism.


Assessment of anxiety symptoms in autism spectrum disorders (ASD) is a challenging task due to the symptom overlap between the two conditions as well as the difficulties in communication and awareness of emotions in ASD. This motivates the development of a physiological marker of anxiety in ASD that is independent of language and does not require observation of overt behaviour. In this study, we investigated the feasibility of using indicators of autonomic nervous system (ANS) activity for this purpose. Specially, the objectives of the study were to 1) examine whether or not anxiety causes significant measurable changes in indicators of ANS in an ASD population, and 2) characterize the pattern of these changes in ASD. We measured three physiological indicators of the autonomic nervous system response (heart rate, electrodermal activity, and skin temperature) during a baseline (movie watching) and anxiety condition (Stroop task) in a sample of typically developing children (n = 17) and children with ASD (n = 12). The anxiety condition caused significant changes in heart rate and electrodermal activity in both groups, however, a differential pattern of response was found between the two groups. In particular, the ASD group showed elevated heart rate during both baseline and anxiety conditions. Elevated and blunted phasic electrodermal activity were found in the ASD group during baseline and anxiety conditions, respectively. Finally, the ASD group did not show the typical decrease in skin temperature in response to anxiety. These results suggest that 1) signals of the autonomic nervous system may be used as indicators of anxiety in children with ASD, and 2) ASD may be associated with an atypical autonomic response to anxiety that is most consistent with sympathetic over-arousal and parasympathetic under-arousal.



The following explanation of the Autonomic Nervous System is edited from Wikipedia.


Autonomic Nervous System (ANS)

The autonomic nervous system (ANS) is the part of the peripheral nervous system that acts as a control system that functions largely below the level of consciousness to control functions,] including heart rate, digestion, respiratory rate, salivation, perspiration, pupillary dilation, micturition (urination), sexual arousal, breathing and swallowing. Most autonomous functions are involuntary but they can often work in conjunction with the somatic nervous system which provides voluntary control.

The ANS is divided into three main sub-systems:

PSNS is often considered the "rest and digest" or "feed and breed" system
SNS is often considered the "fight or flight" system
ENS consists of a mesh-like system of neurons that governs the function of the gastrointestinal system

Depending on the circumstances, these sub-systems may operate independently of each other or interact co-operatively.

In many cases, PSNS and SNS have "opposite" actions where one system activates a physiological response and the other inhibits it. The modern characterization is that the sympathetic nervous system is a quick response mobilizing system and the parasympathetic is a more slowly activated dampening system.

In general, ANS functions can be divided into sensory (afferent) and motor (efferent) subsystems. Within both, there are inhibitory and excitatory synapses between neurons. Relatively recently, a third subsystem of neurons that have been named 'non-adrenergic and non-cholinergic' neurons (because they use nitric oxide as a neurotransmitter) have been described and found to be integral in autonomic function, in particular in the gut and the lungs

Neurotransmitters and pharmacology

At the effector organs, sympathetic ganglionic neurons release noradrenaline (norepinephrine), along with other cotransmitters such as ATP, to act on adrenergic receptors, with the exception of the sweat glands and the adrenal medulla:
  • Acetylcholine is the preganglionic neurotransmitter for both divisions of the ANS, as well as the postganglionic neurotransmitter of parasympathetic neurons.
  • Nerves that release acetylcholine are said to be cholinergic. In the parasympathetic system, ganglionic neurons use acetylcholine as a neurotransmitter to stimulate muscarinic receptors.
  • At the adrenal medulla, there is no postsynaptic neuron. Instead the presynaptic neuron releases acetylcholine to act on nicotinic receptors. Stimulation of the adrenal medulla releases adrenaline (epinephrine) into the bloodstream, which acts on adrenoceptors, producing a widespread increase in sympathetic activity.


 Circulatory system

Heart

Target
β1, (β2): increases
M2: decreases

Other

Target
α2: aggregates
---
β2: inhibits

Endocrine system


Target
α2: decreases insulin secretion from beta cells, increases glucagon secretion from alpha cells
M3:[ increases secretion of both insulin and glucagon.[16][17]
N (nicotinic ACh receptor): secretes epinephrine and norepinephrine


Nerve "Wiring Diagram"

The PSNS (parasympathetic nerve system) is wired together via the Vagus Nerve
The SNS (sympathetic nerve system) is wired together via the splanchnic nerves.





Autonomic nervous system, showing splanchnic nerves in middle, and the vagus nerve as "X" in blue. The heart and organs below in list to right are regarded as viscera.
The viscera are mainly innervated parasympathetically by the vagus nerve and sympathetically by the splanchnic nerves.



Conclusion

For those of you that made it this far, here are my conclusions.

People who have autism and any kind of allergy, be it pollen, food intolerance, asthma or anything similar, might consider asking their doctor to let them trial a very low dose of Verapamil for a couple of days.  The effect is almost instant and so there is no point trialing it for weeks.  Verapamil will lower your blood pressure, in a dose dependent fashion.  The effective autism dose for a severe allergy case is about 1mg/kg.  The half-life varies person to person, so you might need two doses a day, or you might need three.

If you know an adult with severe asthma, look hard and you may see some very mild signs of autism (need for order, anxiety, lack of flexibility etc).

It appears that in all these cases, the gene CACNA1C is misbehaving to varying degrees in different parts of the body.  This gene produces the calcium channel Cav1.2.

You could check if you have the mutated gene, but I do not see the point.  It would only tell you what might happen.  To know what actually has happened, you would need to use proteomics

This emerging science will ultimately be able to provide biomarkers for neurological conditions like autism, depression, bipolar etc, so that the neurologist will know, with certainly, what specific dysfunctions each individual person has.  At that point, behavioral assessments and psychiatry will finally be consigned to history and people will get “smart drugs”, to treat precisely diagnosed neurological dysfunctions.