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Showing posts with label Fragile X. Show all posts
Showing posts with label Fragile X. Show all posts

Wednesday, 30 November 2022

Repurposing Anti-parasite drugs to treat Cancer and Autism?

 

I should start this post by highlighting that generally cancer and autism are not caused by parasites.

I have to be a little careful because we now know that certain types of virus and bacteria are involved in the initial trigger to initiate some types of cancer. This is why many females are now offered human papillomavirus (HPV) vaccines to minimize the chance of several different cancers. I noticed recently that in the US this vaccine is advertised on TV.  I used to know a woman who like most people had the HPV virus as a child, but did not have this vaccine.  She developed a rare oral cancer that the vaccine would have protected against and died very young. We saw in a previous post how a specific gut bacteria blocks the initiation of childhood leukemia.

The pharmaceutical industry does not seem to like the idea of repurposing existing drugs to treat a different disease.  There are some exceptions; it is OK to treat females with acne, using the diuretic drug Spironolactone.  Nobody seems to object to the treatment of intractable headaches with drugs actually approved to lower blood pressure (Verapamil, Amlodipine etc).

When investigating cancers you have to look at the specific underlying mechanisms, just as you do with autism.

As we saw long ago in this blog, it has been suggested to classify autism as either over-active pro-growth signaling pathways, or under-active pro-growth signaling pathways. Most is the over-active type.

Cancer is very clearly another example of over-active pro-growth signaling pathways, so it is not surprising that there is an overlap between therapies for autism and cancer.  The difference is that they are far more likely to be effective in autism. 

So, a cheap anti-parasite drug for kids like Mebendazole, which just happens to also be a Wnt inhibitor,  may slow down the growth of some cancers, but it is sadly not curative.  In an autistic brain where Wnt signalling might be overactive, a lower dose of Mebendazole, might well provide a long-term benefit.   

My old posts that mention Wnt signaling are here:-

https://www.epiphanyasd.com/search/label/Wnt 

Wnt signaling interestingly plays a role in how your hair will go gray/grey. If you reduce Wnt signaling, your hair will go gray and so this is an inevitable side effect of a potent Wnt inhibitor. 

Premature graying might indeed indicate reduced Wnt activity.

 

Pyrantel pamoate

Our reader Dragos recently fined tuned his adult son’s anti-aggression therapy and he recently shared his latest innovation:-

 

"you have to give him 20mg of propranolol 2-3 times a day, pyrantel pamoate 750mg in the evening for 2-3 days, and you will see that his anger will disappear, stay on propranolol. After 3 weeks repeat with antiparasitic, you will see that I was right, you don't use psychotropic drugs"

 

Propranolol is a normally used to lower blood pressure, but it does this in a way that also reduces anxiety.  At the low doses used by Dragos, it has been used to treat actors with stage fright. It can be used before exams or driving tests, to calm the person down.

Propranolol has been trialed in autism. Some people use a low dose and some use a higher dose.

Pyrantel pamoate is used to treat hookworms and other parasites that can be picked up by young children. It works by paralyzing the worms. This is achieved by blocking certain acetylcholine receptors in the worm.

As is very often the case, pyrantel pamoate likely has other modes of action that are entirely different. Is it a Wnt inhibitor like the other hookworm treatment Mebendazole?

I did a  quick search on google and it gave me the wrong pamoate. 

Pyrvinium pamoate is able to kill various cancer cells, especially CSC. The drug functions through the reduction of WNT- and Hedgehog-dependent signaling pathways (Dattilo et al., 2020). 

Pyrvinium pamoate is yet another anti-parasitic drug, but not the one Dragos is using.

So pyrantel pamoate may not be a Wnt inhibitor, unlike many anthelmintic drugs, but it is used by the “anti-parasitic re-purposer in chief” Dr Simon Wu.  He publishes his findings/thoughts, which is good to see.  He likes to combine different anti-parasitic drugs.

I did look up the effect of pyrantel pamoate on gene expression.  There is data, but you really need to see the source material to know whether anything is valid.

Inhibiting GSTP1 (glutathione S-transferase pi 1) is suggested and that is a feature in common with an anti-parasite drug class called Thiazolides (e.g.  Nitazoxanide).  That would make pyrantel pamoate a potential therapy for triple-negative breast cancer, where the cancer cells rely on vigorous activity by the enzyme glutathione-S-transferase Pi1 (GSTP1).  Cancer cells are highly vulnerable to oxidative stress, and as we know glutathione is the main way the body extinguishes it. Glutathione S-transferases P1 protects breast cancer cell from cell death.  So you want to inhibit GSTP1.

Pyrantel has many other suggested effects even reducing expression of the gene FXR2 (fragile X mental retardation,2) and increasing expression of the gene MTSS1 (metastasis suppressor 1).

Pyrantel is even suggested as an epilepsy drug.

 

Drug repositioning in epilepsy reveals novel antiseizure candidates

Epilepsy treatment falls short in ~30% of cases. A better understanding of epilepsy pathophysiology can guide rational drug development in this difficult to treat condition. We tested a low-cost, drug-repositioning strategy to identify candidate epilepsy drugs that are already FDA-approved and might be immediately tested in epilepsy patients who require new therapies.

Expanding on these analyses of epilepsy gene expression signatures, this study generated a list of 184 candidate anti-epilepsy compounds. This list of possible seizure suppressing compounds includes 129 drugs that have been previously studied in some model of seizures and 55 that have never been studied in the context of seizures. 91 of these 184 compounds are already FDA approved for human use, but not for treating seizures or epilepsy. We selected four of these drugs (doxycycline, metformin, nifedipine, and pyrantel tartrate) to test for seizure suppression in vivo.

Pyrantel tartrate is an antiparasitic agent that acts by inhibiting fumarate reductase, and by directly acting on acetylcholine receptors at the neuromuscular junction of infecting helminths. Pyrantel tartrate is FDA approved for use in domestic animals and has been used to treat human parasitic infections.73 Unlike nifedipine and metformin (for which some rodent studies and human reports relate to seizures), a March 2018 PubMed search for “pyrantel and epilepsy” and “pyrantel and seizure” found no manuscripts that studied pyrantel in seizures. Thus, pyrantel tartrate represents a truly novel antiseizure drug candidate yielded by our screen.

 

All in all it is not surprising that Dr Yu is prescribing pyrantel pamoate.

Digging any deeper is beyond the scope of a blog post.

What is clear is that pyrantel pamoate and mebendazole are unlikely to be equally effective in Dragos’ son.

Other anti-parasite drugs work very differently.

In the chart the mode of action of some common drugs  is presented.

 

Anthelminticsfor drug repurposing: Opportunities and challenges

 

Mode of action of albendazole (ABZ), ivermectin (IVM), levamisole (LV), mebendazole (MBZ), niclosamide (NIC), flubendazole (FLU), rafoxanide (RAF), nitazoxanide (NTZ), pyrvinium pamoate (PP), and eprinomectin (EP).

  

Suramin is now quite well known as a potential autism therapy and two different groups are trying to commercialize it.  Suramin is the original anti-purinergic drug (APD), it blocks purinergic receptors that have names like P2Y2.

When I looked at PAK1 a long time ago, which was put forward as a treatment pathway for neurofibromatosis, some schizophrenia and some autism I came across Ivermectin as an existing alternative to the research drug FRAX486, or the expensive BIO 30 propolis from New Zealand.

A decade later and the world goes crazy when the idea of using Ivermectin to treat COVID 19 gets well publicized.  The good news is that now we know that regular use of Ivermectin is not as dangerous as people thought it would be.  Many people have been using the veterinary version in the US, Brazil and elsewhere. 

The supporting research:- 

Effect of Pyrantel on gene expression.

 https://maayanlab.cloud/Harmonizome/gene_set/pyrantel-5513/CMAP+Signatures+of+Differentially+Expressed+Genes+for+Small+Molecules

 

decreases expression of:-

FXR2   fragile X mental retardation, autosomal homolog 2

(and many more)

 

Increases expression of

MTSS1 metastasis suppressor 1

BNIP1 BCL2/adenovirus E1B 19kDa interacting protein 1

BRAF B-Raf proto-oncogene, serine/threonine kinase

(and many more)

 

https://maayanlab.cloud/Harmonizome/gene_set/Pyrantel+Pamoate/CTD+Gene-Chemical+Interactions

Glutathione S-transferase P is an enzyme that in humans is encoded by the GSTP1 gene.

Pyrantel Pamoate Gene Set

Dataset          CTD Gene-Chemical Interactions

2 genes/proteins interacting with the chemical Pyrantel Pamoate from the curated CTD Gene-Chemical Interactions dataset.

GPR35    G protein-coupled receptor 35

GSTP1   glutathione S-transferase pi 1

 

Triple-negative breast cancer target is found

They discovered that cells from triple-negative breast cancer cells rely on vigorous activity by an enzyme called glutathione-S-transferase Pi1 (GSTP1). They showed that in cancer cells, GSTP1 regulates a type of metabolism called glycolysis, and that inhibition of GSTP1 impairs glycolytic metabolism in triple-negative cancer cells, starving them of energy, nutrients and signaling capability. Normal cells do not rely as much on this particular metabolic pathway to obtain usable chemical energy, but cells within many tumors heavily favor glycolysis.

  

"Inhibiting GSTP1 impairs glycolytic metabolism," Nomura said. "More broadly, this inhibition starves triple-negative breast cancer cells, preventing them from making the macromolecules they need, including the lipids they need to make membranes and the nucleic acids they need to make DNA. It also prevents these cells from making enough ATP, the molecule that is the basic energy fuel for cells." 

 

Anthelmintics for drug repurposing: Opportunities and challenges 

It has been demonstrated that some of the anthelmintics are able to inhibit critical oncogenic pathways, such as Wnt/β-catenin, signal transducer and activator of transcription proteins 3 (STAT3), and nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB; therefore, their application for cancer treatment has been considered.

 

Repositioning of Anthelmintic Drugs for the Treatment of Cancers of the Digestive System

 

Anthelmintics for drug repurposing: Opportunities and challenges

 

Mode of action of albendazole (ABZ), ivermectin (IVM), levamisole (LV), mebendazole (MBZ), niclosamide (NIC), flubendazole (FLU), rafoxanide (RAF), nitazoxanide (NTZ), pyrvinium pamoate (PP), and eprinomectin (EP).

 

Thiazolides inhibit growth and induce glutathione-S-transferase Pi (GSTP1)-dependent cell death in human colon cancer cells


More research on the repurposing anti-parasite drugs: 


Antiparasitic and Antifungal Medications for Targeting Cancer Cells Literature Review and Case Studies Frederick T. Guilford, MD; Simon Yu, MD

Chronic inflammation is a new catch phrase for the explanation of all chronic degenerative diseases, from asthma, arthritis, heart disease, auto-immune disease, and irritable bowel disease to cancer. Occult infections from oncovirus, bacterial, and fungal infections as well as from lesser known parasitic infections are driving forces in the cellular evolution and degeneration of cancer cells. An approach using currently available medications that target both fungal and parasitic metabolism appears to interfere with the metabolic synergy that is associated with tumor growth and aggressiveness 

 

The Antitumor Potentials of Benzimidazole Anthelmintics as Repurposing Drugs 

 

Repurposing Drugs in Oncology (ReDO)—mebendazole as an anti-cancer agent 

 

A Pinworm Medication Is Being Tested As A Potential Anti-Cancer Drug


 Conclusion

I did suggest long ago that Mebendazole, as a Wnt inhibitor, might be a cheap and effective treatment for some autism.  I had envisaged that it would need to be given daily, as it is in the cancer trials.

Dragos’ use of pyrantel pamoate, for an average of 4 days a month is interesting.  It is cheap, safe and practical.

One key issue with antiparasitic drugs is how much is absorbed into the blood stream.  If 100% of the drug stays in the gut, its benefit will be limited.

About 20% of Mebendazole ends up in the blood stream and if you take it often this figure is reported to increase.

The combo of propranolol + pyrantel pamoate is an interesting option to treat self-injury and aggressive behavior.  It works for Dragos and undoubtedly will for some others.

Is the inhibition of Wnt signalling the reason why pyrantel pamoate is effective for Dragos’ son?  There is no evidence to support that.

Are antiparasitic drugs going to be widely adopted to treat any unrelated conditions, cancer included, I very much doubt it.

Cancer is better avoided, than treated.  It is a much more achievable objective.

The Fragile X researcher Randi Hagerman takes metformin, as her chemoprevention therapy. She is the medical director of MIND Institute at the University of California, Davis.

You can raise IQ in people with Fragile X by 10-15% using Metformin.  I guess Randi had been reading up on Metformin and came across the anti-cancer effects.

If I had to suggest an anti-parasite drug for Randi to try in Fragile X, I would suggest the PAK inhibitor Ivermectin, made (in)famous by Donald Trump and Jair Bolsonaro during Covid. The research drug FRAX 486 is called FRAX for Fragile X. It is a PAK inhibitor that never made it to market.  Ivermectin is an existing drug that is also a PAK inhibitor.  Worth a try, Randi?

I expect Dr Yu might try and increases his chances and make a combo with a second anti-parasitic drug.

Metformin is one of several anti-cancer choices, it depends which type of cancer is of concern. For RAS-dependent cancer I think Atorvastatin is the best choice. 

If you read the research, like me and Randi, chemoprevention is the obvious choice for older adults. Dementia prevention is equally obvious.

Parkinson’s prevention may be achieved by blocking Cav1.3 (amlodipine etc)

Alzheimer’s prevention may be achieved using low dose fenamates (Ponstan etc).

For vascular dementia and Alzheimer’s prevention/treatment spermidine (in the form of modified wheatgerm) is promising.

Anti-parasite drugs for cancer and autism? Yes, it sounds mad. But is it?

What is for sure is that your pediatrician will think you have gone mad!

Our reader MG in Hong Kong will have got some new ideas to think about.






Sunday, 11 July 2021

Leaky ATP from either Mitochondria or Neurons in Fragile X and Autism

 


 

For leaky ATP, Popeye might want to try Dexpramipexole and

Suramin, or even the already approved Mirapex


If you are old enough to be a parent, you will have encountered problems with some kind of leak.  A leaky roof, a leaky pipe, a leaky washing machine, an air-conditioning unit... The list goes on, the older you get.

I have been preoccupied by fixing a leak recently.  We have a large roof terrace and, in the winter, water started leaking from the ceiling in the floor below.  I improvised a system to catch all the water, but still I had to find the source of the leak.

I did finally find the source of the problem and most importantly without digging up 95% of the terrace.  Now I have to put the 5% back together again.

Leaks are often extremely difficult to locate, because water always finds the easiest path and the dripping you see might have originated from a leak far away.  Nobody wants to fix leaks, because it can be a pretty thankless task and you can cause plenty of damage in the process, without solving the problem.  So, as with fixing autism, I ended up doing much of the fixing myself.  The damage had actually been there since the house was built, hidden under ceramic tiles.

I recently read about leaky ATP in Fragile-X, where ATP leaks from the mitochondria into the cell.

This fits neatly into Professor Naviaux’s belief that ATP is leaking from the cell into the extracellular space, as the basis for his concept of the cell danger response, as a unifying and treatable feature of most autism.

Sounds complicated?

Just think of it as bunch of leaks you need to fix.

 

 What is ATP? 

ATP has many functions:- 

·        It is the fuel your cells need to function.

·        It is a signalling molecule within a cell and importantly between different cells.

·        It is used to make your DNA

  

Mitochondria

Each cell in your brain contains many mitochondria and these are where ATP is produced. Mitochondria die and are replaced, whereas if the host brain cell dies, it is lost forever. Cell death in the brain is bad news.


The ATP – ADP Cycle 

You can think of ATP as a fully charged battery.  Once the energy has been used up the flat battery is called ADP and it goes back for recharging in the mitochondria.  It is a continuous cycle.

ADP is powered back to ATP through the process of releasing the chemical energy available in food; this is constantly performed via aerobic respiration in the mitochondria. This process is also called OXPHOS and has been covered in previous posts.  In most mitochondrial disease the problem is that one of the four mitochondrial enzyme complexes is insufficient; this means that the ATP-ADP cycle is restricted.  There is then insufficient energy to power the brain in times of peak energy requirement.  This can cause loss of myelination and ultimately cell death.

 



  

ATP in Fragile X

It looks like in Fragile X the mitochondria in the brain do not work properly. ATP is leaking from the mitochondria and this stops synapses from maturing. 

A synapse is just the junction between one neuron and its neighbour.

The immature synapse manifests as autistic behavior.  When you plug the leak with Dexpramipexole, a drug trialed for ALS and now asthma, dendritic spines mature and autistic behavior is reduced.

To what extent this leakage occurs in idiopathic autism is unknown, but we know that impaired dendritic spine formation/morphology is a key feature of most autism and that it can be modified, although the sooner you start the better the result will be.

It looks to me that some people diagnosed with mitochondrial disease based on blood tests may actually have leaking ATP which then affects metabolic pathways and shows up with odd blood test results, that is then misdiagnosed as mitochondrial disease.  Note that many people diagnosed with mitochondrial disease show no response to therapy.

In Professor Naviaux’s theory, the ATP leak is from the cell membrane, like the outer wall of the cell.  He thinks that ATP is leaking and this then sends a false danger signal to the rest of your brain.  This is his Cell Danger Response (CDR).  Because the brain thinks it is under attack it is set in a permanent pro-inflammatory state, this gets in the way of basic functions the developing brain needs to complete.  This might explain why the microglia (the brain’s immune cells) are found to be permanently activated in autism; this then means that they do not carry out their regular brain housekeeping activities very well, like pruning synapses.

Naviaux wants to plug the leaks in the cell wall using Suramin, which is an old anti-parasite drug made by Bayer, the giant German company.

The link between the Fragile X research from Yale and Naviaux’s work at UCSD is that ATP needs to be kept in the right place for the brain to function correctly.

Leaky ATP will cause you big problems.

 

 

Now for the supporting research

 

Leaky ATP in Fragile X

 

Fragile X syndrome traits may stem from leaky mitochondria

The persistent leak influences which metabolic pathway the cell uses to generate energy, the team discovered by using a technique called mass spectrometry. For example, fragile X neurons produce more enzymes associated with glycolysis — a pathway commonly used by immature cells — than do typical neurons. Previous studies have shown altered mitochondrial metabolism in people with other forms of autism2.

Adding dexpramipexole to the cells of fragile X mice decreased production of lactate dehydrogenase and other enzymes linked to glycolysis, suggesting that closing the leak causes the neurons to start to use different, more mature metabolic pathways.

Giving injections of dexpramipexole to fragile X model mice lessened their hyperactivity, repetitive behaviors and excessive grooming — traits that are reminiscent of those seen in people with autism and in those with fragile X syndrome. Mice that received the dexpramipexole injections also had neurons with more mature dendritic spines and decreased levels of protein synthesis.

Dexpramipexole has been tested in people with the neurological disease amyotrophic lateral sclerosis and found safe, but it is unclear how it would affect young people if taken over sustained periods of time.

 

ATP Synthase c-Subunit Leak Causes Aberrant Cellular Metabolism in Fragile X Syndrome

Loss of the gene (Fmr1) encoding Fragile X mental retardation protein (FMRP) causes increased mRNA translation and aberrant synaptic development. We find neurons of the Fmr1-/y mouse have a mitochondrial inner membrane leak contributing to a "leak metabolism." In human Fragile X syndrome (FXS) fibroblasts and in Fmr1-/y mouse neurons, closure of the ATP synthase leak channel by mild depletion of its c-subunit or pharmacological inhibition normalizes stimulus-induced and constitutive mRNA translation rate, decreases lactate and key glycolytic and tricarboxylic acid (TCA) cycle enzyme levels, and triggers synapse maturation. FMRP regulates leak closure in wild-type (WT), but not FX synapses, by stimulus-dependent ATP synthase β subunit translation; this increases the ratio of ATP synthase enzyme to its c-subunit, enhancing ATP production efficiency and synaptic growth. In contrast, in FXS, inability to close developmental c-subunit leak prevents stimulus-dependent synaptic maturation. Therefore, ATP synthase c-subunit leak closure encourages development and attenuates autistic behaviors.

 

Highlights 

·        ATP synthase c-subunit leak in Fragile X causes aberrant metabolism

·        Changes in ATP synthase component stoichiometry regulate protein synthesis rate

·        Inhibition of the leak normalizes synaptic spine morphology and Fragile X behavior

 

In Brief

Lack of FMRP in Fragile X neurons is associated with a leak in the ATP synthase, the blockade of which normalizes cellular and behavioral disease phenotypes.




 

Now they fix the leak using Dexpramipexole (Dex) and cyclosporine A (CsA)



 



 

We have found that the mitochondrial inner membrane leak of FX neurons and cells is caused by abnormal levels of ATP synthase c-subunit. The c-subunit leak causes persistence of a mitochondrial leak metabolic phenotype characterized by high glycolytic flux, high lactate levels, and increased levels of glycolytic and TCA enzymes. The leak also aberrantly elevates overall and specific protein synthesis; a decrease in c-subunit level or pharmacological inhibition of the ATP synthase leak reduces protein synthesis rates and decreases the levels of leak metabolism enzymes. In Fmr1/y synapses, stimulation-dependent protein synthesis is absent. This is correlated with a lack of stimulus induced EF2 phosphorylation and a lack of synthesis of the ATP synthase b-subunit. These abnormalities are readily reversed by ATP synthase leak inhibitors, suggesting that leak closure is required for the ATP-dependent phosphorylation of EF2 adjacent to mitochondria. EF2 phosphorylation may regulate the change in subsets of proteins synthesized and may be correlated with- the overabundant synthesis of enzymes supporting a high flux glycolytic/TCA cycle ‘‘leak’’ metabolism indicative of metabolic immaturity. Consistent with the hypothesis that the c-subunit leak is also a major cause of synapse immaturity, we find that inhibition of the ATP synthase leak allows the maturation of synapses and normalizes autistic behaviors.

 

 

 

Closing Leaky Mitochondria Halts Behavioral Problems in Fragile X, Study Suggests


“In Fragile X neurons, the synapses fail to mature during development. The synapses remain in an immature state and this seems to be related to their immature metabolism,” she said.

The investigators tested whether closing the leak to boost the efficiency of ATP production would lessen behavioral abnormalities.

They first saw that nerve cells treated with an ATP synthase inhibitor named dexpramipexole (Dex) — a form of the common Parkinson’s therapy Mirapex ER (pramipexole) and previously tested as a treatment for amyotrophic lateral sclerosis — increased the levels of ATP.

Two-day treatment with Dex also reversed autistic-like behaviors, namely excessive time spent grooming and compulsive shredding of the animals’ nests. The treatment also reduced hyperactivate behaviors.

“We find that inhibition of the ATP synthase leak allows for the maturation of synapses and normalizes autistic behaviors in a mouse model of [fragile X],” the team wrote.

Jonas and her team now intend to further test the effectiveness of this and other leak-closing therapies for improving learning.

The lab is conducting a study assessing the role of leaky membranes in memory formation. Findings could pave the way for novel therapeutics for fragile X and autism, as well as for Alzheimer’s disease.

 

 

 

Dr Naviaux and Suramin for Autism

 

I have covered Suramin in previous posts.  There is a presentation below by Prof Naviaux that is for lay people, it is good to hear directly from the man himself.

 

Autism Treatment, the cell danger response and the SAT1 trial

https://youtu.be/pqd_BoCeRUw




In essence he says that when cells are stressed, they leak ATP and this creates the cell danger response.  If you have suramin in your bloodstream, it plugs the ATP channels and stops it leaking out of the cell and so blocks the cell danger response.



It is the cell danger response that is causing the symptoms we see as autism.

  

Conclusion

Who to call to fix an ATP leak?

If it is a case of Fragile X, there looks to be potential solution, but you will definitely not find it at your local doctor’s office.

For a mouse with Fragile X, you might choose Dexpramipexole.  Dexpramipexole was developed as a therapy for ALS (motor neuron disease), but failed in phase 3 trials and is now being developed for asthma.

For a human, the logical place to start would be the already approved Mirapex, which is currently used to treat Parkinson's disease and restless legs syndrome.

Mirapex - a miracle for Fragile X?

Clearly somebody should make a clinical trial of the existing drug.

I expect what will happen is that the Yale researchers will come up will a new drug that can be patented as a novel therapy for Fragile X.  This way they get to make some money, but a decade is wasted.

Is leaky ATP from mitochondria an issue in broader autism, beyond Fragile X? That is still unknown, but the Yale researchers seem to think their work has potential application in both autism and Alzheimer’s.

In the case of broader autism, Dr Naviaux and his partner Kuzani have some competition from Paxmedica.  Both groups seek to monetize Dr Naviaux’s published research.

It looks like the German giant Bayer does not want to help either group.  Instead of just tapping into Bayer’s existing production of Suramin, Kuzani and Paxmedica will have to figure out how to produce Suramin.

This all helps us to understand why there still are no approved therapies for core Autism or indeed Fragile X and yet there is a mountain of research.  Too many barriers and interests to overcome.

If you want to fix leaky ATP any time soon, you will be doing it mainly by yourself.  This has been my experience with most other kinds of leak!

 




 

Friday, 11 June 2021

Game Changer or Fine Tuning? It depends on severity of Autism

 


There are so many possible autism interventions discussed in this blog, it clearly is not always easy to know their relative merit.

There are so many people now diagnosed with autism it is no longer such a meaningful term.  The most extreme autism I think I will have to start calling really severe autism.  A scale of 1 to 100 would be much more helpful than the current levels 1, 2 or 3. I suppose Elon Musk and Greta are level 1.

One reader did recent describe the effects of bumetanide in his child as being game changing.  I think it is an excellent description to use.  For our reader Roger, Leucovorin was a game changer.

Another reader wrote to me to give an update about his three year old

“After 3 months of bumetanide treatment I've seen improvement on his cognition, like, he is now able to finish an apple and take the end to the trash by himself or enter in his room, turn the lights on, take some toy, turn lights off and close the door or eat his lunch by himself. He is smarter now.”

This reader is well on his way to finding the additional elements for his son’s personalized polytherapy and the way he is going about it is likely to yield optimal results. Most of what you need is tucked away in this blog somewhere.  It is a case of who dares wins.

Using my scale of 1 to 100, with Elon and Greta in low single digits and many people referred to at the blog of the US National Council of Severe Autism mainly at 80-100, we can put interventions into a bit more perspective.

It is still far from perfect because most people with really severe autism reach a plateau in development at a very young age.  This matters because as a three year old they do not look/behave so differently to a typical child, but by the time they reach 18 years old, the difference is gigantic.

If you could delay the onset of this developmental plateau for a decade the result would be transformative.  Based on the longitudinal studies to adulthood, it looks like about 80% of severe autism reaches a plateau at the level of a 2-3 year old.  The other 20% continue to learn, but at a slower rate than typical children. 

In the case of the autism which is <10, like Greta and Elon, very small issues can still become very troubling.  There was inevitably bullying at school from mild to severe, there likely was (and still is) anxiety, perhaps an eating disorder, perhaps some self harming or even suicidal thoughts.

If you fine tune the brain a little to reduce anxiety and improve social/emotional responsiveness, you can trim someone’s score from a 15 to a 9 and make them feel much better.  Job done.

For someone with an IQ of 50 (i.e. severe intellectual disability), non-verbal, non-literate, who is sometimes aggressive and exhibits autistic behaviors, you are going to need much more than fine tuning, you need a game changer.  Then you can go on and fine tune things to give further incremental improvement.

One doctor reader did suggest to me that, in effect, five moderately effective interventions might equal one game changer.

In the case of autism that I deal with, the most important step was raising cognitive function, not treating what people consider to be autism.  I think that this applies to almost all people with a score 50 to 100.  Even if it was never actually diagnosed, the barrier to progress is low cognitive function and a severely reduced ability to learn and acquire new skills.  This has to be fixed and for many people the tools already exist.

 

Improving cognitive function

Game Changer

·      Bumetanide  (also Azosemide, KBr and, possibly, Betaine with the same effect of lowering chloride inside neurons)

Fine tuning

·      Atorvastatin, reducing cognitive inhibition

·      Micro-dose Clonazepam, shift E/I imbalance

·      Low-dose Roflumilast, raising IQ

 

Reducing autistic behaviors

Fine tuning

·      NAC

·      Sulforaphane

·      Verapamil

·      Oxytocin

·      BHB

·      Pentoxifylline

·      Agmatine

·      Clemastine

·      DMF

·      Leucovorin (Calcium Folinate)

 

Interventions with a slow course of action

Some interventions, for example pro-myelinating therapies (like clemastine and Tyler’s N-acetylglucosamine), or pro-autophagy therapies, may take a long time to show effect. I think you may need to first see very tangible results from other therapies, which are much easier to assess.

As Roger will want to point out, in the case of Cerebral Folate Deficiency Leucovorin was the game changer.

In the case of other metabolic autisms, a single therapy may also be the game changer, like the Greek boy for whom high dose biotin resolved his previously severe autism.

In the case of Fragile-X, there seem to be potential game changers galore.  The latest is plugging the leaky membrane in mitochondria that is allowing ATP to leak out, using a research drug dexpramipexole, or potentially the related and already approved variant Mirapex ER (pramipexole).  Mirapex is used to treat the symptoms of Parkinson Disease and Restless Legs Syndrome. 

If our occasional reader and bio-statistician Knut Wittkowski is correct, Mefenamic Acid (the NSAID Ponstan) could be a real game changer, if taken around 2-3 years of age.  He suggests this will block the progression to severe non-verbal autism. Knut has been upsetting YouTube with some of his interviews about Covid-19 and his deal with Q-Biomed to develop Mefenamic Acid fell through. You can buy Ponstan very cheaply, outside of the US, even as a pediatric syrup.

Hopefully, Dr Naviaux's Suramin will be a game changer for some.  More of that in the coming post on leaky ATP.


Conclusion

I am told where we live that Monty’s autism is “fixed”, or by one autism Grandad we know, “he’s 80% fixed”.

If you started life with (really) severe autism, even 80% fixed means you are still pretty autistic, much more so than Elon and Greta, but far less so than the now adult “children” over at the National Council for Severe Autism, who have really severe autism and often had a very early plateau in development.

Monty has finished his year-end exams.  Overall, the grades of his NT classmates are pretty terrible, maybe due to Covid disruptions.  I told Monty’s assistant that if he can come somewhere in the middle, without her doing the tests for him or having extra time, that is a great result, regardless of the grade itself.  In all his subjects he comes in the middle. In the English educational system, Monty is now a C student, maybe even with the odd B or D; so not something to boast about.  What really is amazing  is this person could not figure out  9 – 2 = 7,  at the age of 9 years old, prior to starting bumetanide and his Polypill therapy.  Now he is nearly 18 years old.

If you find that your young child is a genuine bumetanide responder, but later struggle to source it, take a close look at what untreated severe autism looks like by adulthood.  Then you may choose to redouble your efforts to get hold of your game changer. Some readers are getting it from Egypt, Pakistan, Nigeria, China, Austria and many from Mexico and Spain.  In Brazil you can buy it only in a compounding pharmacy. The lucky ones get it at their local pharmacy, which is what should be possible for everyone and one day that might even happen.

There are countless fine-tuning therapies that may be potentially effective in a particular person.  They are certainly worth having; you just have to look at what is available and cost effective.

There will soon be a post about leaky ATP in Fragile X and autism.

Two readers have highlighted the research suggesting that Betaine might have a similar effect to Bumetanide.  It does not block the NKCC1 transporter, but it may reduce the mRNA that produces them, so the net effect may potentially be similar.  At much lower doses, Betaine is a common autism supplement.  This will be covered in the next post.