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Friday, 18 September 2020

Betahistine is in the Pipeline for ADHD, but will it help Autism? Maybe for some, but not for others





 Will Betahistine provide a benefit?

Today’s post is the logical follow on from the post showing that the new drug compound E-100 gives a benefit in two models of autism.

Another Potential Autism Therapy - novel compound E100 from Krakow, a combined histamine H3 receptor blocker (H3R antagonist) and an acetylcholine esterase inhibitor (AChEI)



We saw that E-100 has two modes of action, thought to be complementary:-

·        Acetylcholinesterase inhibitor (AChEI)
·        Histamine H3 antagonists (H3R antagonist)

I think our reader Rene is thinking along the lines I suggested that you might achieve the same effects with existing generic drugs.  One combination would be Donepezil plus Betahistine.

Donepezil has long been studied in autism, a recent example is here:


The safety and efficacy of a novel combination treatment of AChE inhibitors and choline supplement was initiated and evaluated in children and adolescents with autism spectrum disorder (ASD). Safety and efficacy were evaluated on 60 children and adolescents with ASD during a 9-month randomized, double-blind, placebo-controlled trial comprising 12 weeks of treatment preceded by baseline evaluation, and followed by 6 months of washout, with subsequent follow-up evaluations. The primary exploratory measure was language, and secondary measures included core autism symptoms, sleep and behavior. Significant improvement was found in receptive language skills 6 months after the end of treatment as compared to placebo. The percentage of gastrointestinal disturbance reported as a side effect during treatment was higher in the treatment group as compared to placebo. The treatment effect was enhanced in the younger subgroup (younger than 10 years), occurred already at the end of the treatment phase, and was sustained at 6 months post treatment. No significant side effects were found in the younger subgroup. In the adolescent subgroup, no significant improvement was found, and irritability was reported statistically more often in the adolescent subgroup as compared to placebo. Combined treatment of donepezil hydrochloride with choline supplement demonstrates a sustainable effect on receptive language skills in children with ASD for 6 months after treatment, with a more significant effect in those under the age of 10 years.

I was not aware that a lot of money is being spent preparing to bring Betahistine to the US as a treatment for ADHD (Attention Deficit Hyperactivity Disorder).

Outside the US, Betahistine is cheap generic drug that is widely available.  It is used in adults for vertigo and tinnitus etc.  It is not approved for use in children, but that just means its use was never studied in children.  It was envisaged as a drug for older people.

In the US, Betahistine is not an approved drug, so if the promoter gets it approved for ADHD they will not have any cheap competition.  They might even make it in the form of nasal spray, which they say makes Betahistine much more bioavailable.  It would also make it look like a modern drug, rather than just an old drug sold for a high price.


48 mg Oral dose vs varying intranasal doses



The promoter’s idea is to use a lower dose of Betahistine intranasally and yet be more potent/effective than the oral tablet now used to treat vertigo.  They also want to use it to treat antipsychotic-induced weight gain, which seems to be a huge problem and a $600 million a year market they suggest.  It appears after this they want to use Betahistine to treat ADHD and depression.




Life on an anti-psychotic, without Betahistine

Betahistine might start as a drug for young adults with ADHD, but ADHD is normally seen as a childhood disorder (something like 7% of US school children have taken ADHD drugs) the promoter will have to carry out studies to show it is safe for pediatric use.  They are actually trialing quite high doses orally for ADHD.


Betahistine in autism, without ADHD

I am not sure that Betahistine, or E-100, is going to have a good overall effect in autism in humans.  E-100 does look good in two mouse models of autism.

Acting via the histamine H3 receptor, Betahistine will increase the levels of neurotransmitters histamineacetylcholinenorepinephrineserotonin, and GABA.  In any specific case of idiopathic autism, some of these effects may be beneficial, but quite possibly not all.

If you have GABA still working in reverse, as in some Bumetanide-responsive autism, increasing the level of GABA will cause agitation and aggression, just like taking Valium does.

The active metabolite of Betahistine is something called 2-PAA and the level peaks in your blood about an hour after taking the pill. There certainly is potential for a negative reaction, but it would fade gradually over the next few hours.  The half-life is 3.5 hours.

In the ADHD trials of Betahistine agitation was listed as a possible side effect. The promoter does say that overall the drug is very well tolerated.


Auris Medical Announces Closing of Two US Patent Acquisitions Related to the Use of Betahistine for the Treatment of Depression and ADHD

 Betahistine is a small molecule structural analog of histamine, which acts as an agonist at the H1 and as an antagonist at the H3 histamine receptors. Unlike histamine, it crosses the blood-brain-barrier. It is known to enhance inner ear and cerebral blood flow, increase histamine turnover and enhance histamine release in the brain, increase release of acetylcholine, dopamine and norepinephrine in the brain and to result in general brain arousal. Betahistine for oral administration is approved in about 115 countries, with the US being a notable exception, for the treatment of vertigo and Meniere’s disease. The compound has a very good safety profile, yet it is also known that its clinical utility is held back by poor bioavailability. Intranasal administration of betahistine has been shown to result in 4 to 26 times higher bioavailability.



Safety first



Betahistine, a potent histamine H3 receptor antagonist, is being developed for the treatment of attention deficit hyperactivity disorder (ADHD) that manifests with symptoms such as hyperactivity, impulsivity and inattention. This study describes the pharmacokinetics of betahistine in ADHD subjects at doses higher than 50 mg. These assessments were made during a randomized, placebo-controlled, single blind, dose escalation study to determine the safety, tolerability and pharmacokinetics of once daily doses of 50 mg, 100 mg and 200 mg of betahistine in subjects with ADHD. Plasma levels of 2-pyridylacetic acid (2-PAA), a major metabolite of betahistine were quantified using a validated LC-MS/MS method and used for pharmacokinetic analysis and dose proportionality of betahistine. A linear relationship was observed in Cmax and AUC0-4 of 2-PAA with the betahistine dose (R2 0.9989 and 0.9978, respectively) and dose proportionality coefficients (β) for the power model were 0.8684 (Cmax) and 1.007 (AUC0-4). A population pharmacokinetic model with first-order absorption of betahistine and metabolism to 2-PAA, followed by a first-order elimination of 2-PAA provides estimates of clearance that underscored the linear increase in systemic exposure with dose. There were no serious adverse events reported in the study, betahistine was safe and well tolerated at all the dose levels tested.


Pharmacokinetics and Dose Proportionality of Betahistine in Healthy Individuals


Betahistine dihydrochloride is widely used to reduce the severity and frequency of vertigo attacks associated with Ménière’s disease. Betahistine is an analogue of histamine, and is a weak histamine H1 receptor agonist and potent histamine H3 receptor antagonist. The recommended therapeutic dose for adults ranges from 24 to 48 mg given in doses divided throughout the day. Betahistine undergoes extensive first-pass metabolism to the major inactive metabolite 2-pyridyl acetic acid (2PAA), which can be considered a surrogate index for quantitation of the parent drug due to extremely low plasma levels of betahistine. The aim of the present investigation was to assess the pharmacokinetics and dose proportionality of betahistine in Arabic healthy adult male subjects under fasting conditions. A single dose of betahistine in the form of a 8, 16, or 24 mg tablet was administered to 36 subjects in randomized, cross-over, three-period, three-sequence design separated by a one week washout period between dosing. The pharmacokinetic parameters Cmax, AUC0–t, AUC0–∞, Tmax, and Thalf were calculated for each subject from concentrations of 2-PAA in plasma, applying non-compartmental analysis. The current study demonstrated that betahistine showed linear pharmacokinetics (dose proportionality) in an Arabic population over the investigated therapeutic dose range of 8–24 mg



Conclusion

I think Rene is right to be curious about whether the benefit of E-100 in autism models can be replicated today with cheap generic compounds.  Our readers who are doctors outside the US will be familiar with Betahistine, a cheap drug sitting on the shelf in their local pharmacy.

In my N=1 case of autism I am not so optimistic, because I did once follow up on another idea in the published literature.  That idea was to “fix” GABAA receptors with bumetanide/bromide and then “increase GABA”, in lay-speak. It was in this post from 2015:  “More GABA” for Autism and Epilepsy? Not so Simple







GABA is not supposed to cross the blood brain barrier (BBB), but when combined with niacin the Russians discovered it does, the result was the prodrug Picamilon (until recently sold in the US as a supplement). Some people with autism do take Picamilon.

In my case of autism, a single small dose of Picamilon had a pronounced negative effect, which I interpreted as GABA still acting as excitatory (it should be inhibitory).  It is possible that the niacin part of Picamilon was the problem.

Taurine is an agonist of GABAA receptors, so it will also act like “increasing GABA”



Very many people with autism take Taurine. Some people with autism who take Leucovorin (calcium folinate) also take Taurine to reduce its side effects.

Some people take Bumetanide and Taurine, which is surprising.

The original intended use of Leucovorin is for people undergoing chemotherapy, to reduce its side effects. Taurine is also used to reduce the side effects of chemotherapy. So not a surprise to see that Leucovorin is often together prescribed with Taurine, but that is in people fighting cancer.

In autism, there is no chemotherapy and so what is the rational to prescribe Taurine with Leucoverin?

Perhaps, by chance more than anything else, Taurine does reduce the aggression that is a common side effect of Leucovorin.  I hope it does.

My conclusion is that for plenty of people with autism, and particularly those who tolerate/use Taurine or Picamilon,  Betahistine’s effect on GABA should not cause a problem. When Betahistine gets FDA approval for pediatric use in ADHD, parents in the US will likely have little difficult getting a prescription for their child with autism. ADHD is highly comorbid with autism.

If Betahistine gives a benefit and is well tolerated, all you have to do is add Donepezil or Galantamine and you have something very similar to the research drug E-100, that shines in those two mouse models of autism.

I think the effect of Betahistine  increasing the levels of neurotransmitters histamineacetylcholinenorepinephrineserotonin, and GABA released from the nerve endings is likely to be occur from the first dose. It makes sense that the effect on your inner ear takes weeks/months to develop.

I think the ADHD version of betahistine will be a much more potent dose than current generic tablets and it will be achieved intranasally.

Betahistine was withdrawn from sale in the US many years ago because it was thought not to be effective;  the chart further below shows otherwise. 

If you are an adult outside the US, with some hearing loss, it looks like you might want to ask your doctor for a trial of Betahistine.  It is safe and very cheap.  While researched for Ménière's disease, you can have sudden onset reduction in hearing caused by an inflammatory response due to a virus or bacteria, that produces something very similar in the inner ear to what gets diagnosed as Ménière's disease, as I discovered myself. 

Sudden onset hearing loss (SOHL) is a 30 dB or greater hearing loss over less than 72 hours, it is usually idiopathic (you never get to know what caused it).  It is thought that most people do not go to their doctor – big mistake. If you treat SOHL immediately with steroids, hearing loss should be temporary. For people with the inner ear disease Ménière's, it looks like they should benefit from Betahistine, and then be able to hear sounds 6 decibels quieter.  Is Betahistine going to benefit SOHL that was not treated in time?  It might be worth finding out.

 


Betahistine, acting via H3 receptors, reduces the pressure of the fluid that fills the labyrinth in the inner ear; it also is thought to improve blood supply.  The diuretic acetazolamide, covered in this blog because of its effects on ion channels relevant to autism, is also used to reduce fluid build-up in the inner ear in Ménière's disease.

When I had sudden onset hearing loss (SOHL), it was initially misdiagnosed and steroid therapy started very late, so I added some acetazolamide from my autism stock pile.  It all worked out well.

If someone reading this post goes on to try Betahistine off-label for:-

·        ADHD
·        Depression
·        Autism
·        Weight gain associated with antipsychotics, particularly Olanzapine
·        Previously untreated, sudden onset hearing loss (SOHL)

it would be interesting to know your results.

Take note that Betahistine is also a mild agonist of H1 receptors, which explains why it may cause mild nausea (H1 blockers are used to reduce nausea) for a short while after taking it.  This side effect seems not to appear if Betahistine is taken with or after a meal. Betahistine may also reduce the H1 histamine receptor effect of any H1 antihistamine drugs being taken.

Ultimately the new E-100 drug may well be the best solution.  Hopefully the UAE researchers will persevere to human trials, but that is something that would need a lot of time and money and probably will not happen.











22 comments:

  1. This is very interesting .Hopefully it won’t be too long a wait .
    Peter have you heard of micro immune therapy and what are your thoughts on it .Someone just said it’s the best intervention for her child and they have done so many biomedical interventions .I think it’s produced by a company called labolife.Thanks

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    1. Micro immune therapy has been around for many years in Belgium and France. It uses sub-lingual dosing, you do not swallow the pills. If you swallow the pill it should not "work". I am not sure many young children will keep a powder under their tongue for long.

      The Labo Life people do publish studies, like the one below.

      Potential Role of the Micro-Immunotherapy Medicine 2LALERG in the Treatment of Pollen-Induced Allergic Inflammation
      https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7093691/

      I have no idea if it works.

      They have many different products for different diseases, including cancer.

      I would think some products will be more effective than others. You would hope there would be some independently funded research.

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    2. Thanks Peter for your reply

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  2. I could not be more excited about your post today. My daughters biggest deficit apart from social interaction is receptive speech, and I believe the two are tied together. I have scoured the internet for scientific information on receptive language - I couldn’t find even as little as an explanation of what possible mechanisms could be behind such issues. I will buy a full version of the paper you mentioned and contact the authors for more advice on how to proceed. One more question - are you aware of the ‘length of telomers in lab mice’ problem that has become public in recent years, and the issues this causes regarding safety of drugs? I was once again reminded about this when I read the possible side effects of Donepezil, which center around the heart, something that relates to do the mice and telomers and cells.

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    1. tpes, a telomere is an important piece of protective “insulation” at the end of each chromosome in your DNA. (you have 23 pairs of chromosomes in your DNA). Over time, due to each cell division, the telomere ends become shorter, eventually this may introduce "copying errors" into your DNA.

      Telomeres are highly susceptible to oxidative stress and we know that antioxidants can help prevent DNA damage. I suppose they help to protect telomeres.

      Shortened telomeres are a feature of diseases of the brain and to some extent are an inevitable feature of the aging process.

      Telomere Biology in Human and Measurement of Telomere Length
      https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7373805/#s2title

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    2. The problem I was referring to is the fact that by trying to make really good lab mice, the company which supplies almost all lab mice in the US has inadvertently made mice with very long telomeres. Drugs which test safe on them actually lead to issues in humans because long telomeres mean you can fix yourself on the celullar level, and this especially leads to issues where drugs effect the heart, because the heart is the human organ least capable of fixing itself and therefore most at risk when a drug is causing damage on the cellular level. https://www.google.com/amp/s/oncobites.blog/2020/07/29/modeling-aging-and-cancer-are-lab-mice-different-from-their-wild-cousins/amp/

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    3. tpes, I would not worry about this because drugs are extensively tested in humans. Most "autism" drugs are old generic medicines, for example Donepezil was approved in 2004 and is used in old people with short telomeres.

      Old people seem to experience drug side effects far more often than healthy young people.

      On a broader level, mouse models are useful, but can only ever tell part of the story. A drug might benefit a mouse model of autism, but only benefit humans if given at a very young age. Sometimes this would be before diagnosis, so not realistic. For example, Rapamycin gives a much bigger benefit in TSC (tuberous sclerosis complex) type autism when given very young.

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  3. Thanks for yet a great post Peter!
    I can't believe you are so knowledgeable about what's in progress in so many corners of the world, and I feel very spoiled to have it all served like this.
    If I ever get to acknowledge you and your work in print or in a presentation, how would you like me to do it?

    A speculation to the question mark on the Bumetanide + Taurine combo:
    Not all responders to Bumetanide will have a faulty GABA switch as neonatals. I rather think many have an unfavourable NKCC1/KCC2 ratio due to other (later) causes, such as neuroinflammation. In those cases, GABA agonists can be good, but perhaps even better with Bumetanide.

    /Ling

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  4. Here is an interesting new study on IL-17 production in the meninges and its effect in the brain on anxiety:

    Press Release:

    https://www.sciencedaily.com/releases/2020/09/200914131915.htm

    Paper:

    https://www.nature.com/articles/s41590-020-0776-4

    It was found that removing these meningeal IL-17a producing cells or else blocking the IL-17 receptors in the cortex made mice more resilient to anxiety.

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  5. Here is some other interesting research on IL-17A as it relates to COVID-19 and why children are far less susceptible to the disease upon exposure to SARS-2:

    Press Release:

    https://www.sciencedaily.com/releases/2020/09/200922092159.htm

    Paper:

    https://stm.sciencemag.org/content/early/2020/09/21/scitranslmed.abd5487

    This is interesting with respect to autism as IL-17A improves the sociability of mice in autism mouse models and the reports that people with autism are at higher risk of COVID-19 than the general population.

    Here is some research I studied carefully for a project I have been working on for a long time that discusses IL-17A's effects on calming a part of the somatosensory cortex (in mice) called S1DZ:

    https://hms.harvard.edu/news/cracking-fever-autism-mystery

    This region is analogous to the cortical somatosensory region 3A in humans (Brodmann Areas) which deals with proprioreception.

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    1. Tyler, that is interesting. I like the quote:-

      “It was amazing to discover that the same immune molecule, IL-17a, could have dramatically opposite effects depending on context: Promoting autism-like behaviors when it acts on the developing fetal brain and ameliorating autism-like behaviors when it modulates neural activity in the adult mouse brain,”

      It is rather like Sodium Valproate, give it to the pregnant mother and it can make the child autistic, but give it to the child and it can ameliorate some features of autism.

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    2. Well it is likely because too much of some sort of signalling molecule developmentally causes downregulation of the base number of receptors for that molecule which at some point become permanent. So in an adult brain, excess levels of a particular molecule might be beneficial (at least temporarily) because it overwhelms the lack of sensitivity in the number of receptors. The complicated part is you can have a selective part of the body and brain where this downregulation of receptor count occurs and giving an unselective drug will undoubtedly have many side effects.

      Also, I ran into this article today talking about another MS drug for remyelination I thought you might be interested in:

      https://www.theguardian.com/society/2020/sep/25/ms-treatment-step-closer-drug-shown-to-repair-nerve-coating-trial-multiple-sclerosis

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    3. Thanks Tyler. While Bexarotene is not safe for use in MS, as the article points out both Clemastine and Metformin can be beneficial and are safe/cheap.

      There really are many options today to treat MS, using off-label therapies. It is much simpler than trying to treat autism.

      Delete
  6. would you recommend betahistine for chronic fatigue syndrome?

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    1. ME/CFS is not a well understood condition. Fortunately, one very serious group is researching it.

      https://naviauxlab.ucsd.edu/science-item/chronic-fatigue-syndrome-research/

      One feature of CFS is depression, so anything with antidepressant properties might be helpful and that does include Betahistine.

      CFS is a metabolic syndrome, as explained in the above link, and ultimately the core problem should be treatable. Maybe will Suramin, or a new version (an analog).

      Current CFS therapies are each just treating one of the symptoms.

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    2. Zoo, Phoenix rising would be the best start to research treatment alternatives for ME/CFS. For depression I'd bet treating NLRP3 inflammasome could be successful. D-BHB sounds like a match on that + energy issues.

      /Ling

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  7. Hello Peter i heard ADHD drugs dont tend to work as well for Autistic kids that have ADHD as Co-Morbid? dont know how true that is, my son is five and they wont even diagnose yet until 6-7 in UK?

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  8. I'm trying to tie together the axis of e/i imbalance -> mitochondrial dysfunction or excessive fission -> ROS -> neuroinflammation. (With associated loops). I'm still not clear about the connection between e/i and mitochobdria. But I see there is some literature pointing to mitochondrial fission in itself leading to neuroinflammation.
    Just an example:
    https://stm.sciencemag.org/content/11/512/eaaz3714

    /Ling

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  9. We have 1.5g/kg IVIG scheduled on wednesday and I am freaking out like any parent would :-/. Hoping so so badly this eliminated her pandas...it feels like at least half of her ‘autism’ is actually pandas for the past 2 years.

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  10. Hey Peter, I found this board after being prescribed betahistine for intermittent and extremely minor hearing loss in my left ear then finding it is on clinical trial for ADHD then googling the two words like trying to fit two Lego pieces together by slamming them together. It seems I did find something really cool!

    I think I have ADHD, but I can't get it diagnosed because there aren't really any good psychiatrists where I live. I am thinking of taking some of this drug and doing a pseudo clinical research on myself. I mean, we know for sure that even 200mgs of betahistine is well tolerated, I just wanted to ask if it would really be fine.

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    1. Since you have already been prescribed this drug for your hearing, it makes perfect sense to see if you get the ADHD benefit.

      Most ADHD drugs are stimulants, like Ritalin or Adderall but other are not, like Stratterra. It seems that psychiatrists also use trial and error to see what helps.

      Delete

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