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Showing posts with label Rita Levi-Montalcini. Show all posts
Showing posts with label Rita Levi-Montalcini. Show all posts

Wednesday, 22 February 2023

Treating Rett syndrome, some autism and some dementia via TrkA, TrkB, BDNF, IGF-1, NGF and NDPIH. And logically why Bumetanide really should work in Rett

Source: Rett Syndrome: Crossing the Threshold to Clinical Translation

 

Today’s post is on the one hand very specific to Rett syndrome, but much is applicable to broader autism and other single gene autisms.

Today’s post did start out with the research showing Bumetanide effective in the mouse model of Rett syndrome. This ended up with figuring out why this should have been obvious based on what we already know about growth factors that are disturbed in autism and very much so in Rett.

We even know from a published human case studies that Bumetanide can benefit those with Fragile X and indeed Down syndrome, but the world takes little notice.

If Bumetanide benefits human Rett syndrome would anyone take any notice?  They really should.

To readers of this blog who have a child with Rett, the results really are important.  You can even potentially link the problem symptoms found in Rett to the biology and see how you can potentially treat multiple symptoms with the same drug.

One feature of Rett is breathing disturbances, which typically consist of alternating periods of hyperventilation and hypoventilation.

Our reader Daniel sent me a link to paper that suggest an old OTC cough medicine could be used to treat the breathing issues.

The antitussive cloperastine improves breathing abnormalities in a Rett Syndrome mouse model by blocking presynaptic GIRK channels and enhancing GABA release


Rett Syndrome (RTT) is an X-linked neurodevelopmental disorder caused mainly by mutations in the MECP2 gene. One of the major RTT features is breathing dysfunction characterized by periodic hypo- and hyperventilation. The breathing disorders are associated with increased brainstem neuronal excitability, which can be alleviated with antagonistic agents.

Since neuronal hypoexcitability occurs in the forebrain of RTT models, it is necessary to find pharmacological agents with a relative preference to brainstem neurons. Here we show evidence for the improvement of breathing disorders of Mecp2-null mice with the brainstem-acting drug cloperastine (CPS) and its likely neuronal targets. CPS is an over-the-counter cough medicine that has an inhibitory effect on brainstem neuronal networks. In Mecp2-null mice, CPS (30 mg/kg, i.p.) decreased the occurrence of apneas/h and breath frequency variation. GIRK currents expressed in HEK cells were inhibited by CPS with IC50 1 μM. Whole-cell patch clamp recordings in locus coeruleus (LC) and dorsal tegmental nucleus (DTN) neurons revealed an overall inhibitory effect of CPS (10 μM) on neuronal firing activity. Such an effect was reversed by the GABAA receptor antagonist bicuculline (20 μM). Voltage clamp studies showed that CPS increased GABAergic sIPSCs in LC cells, which was blocked by the GABAB receptor antagonist phaclofen. Functional GABAergic connections of DTN neurons with LC cells were shown.

These results suggest that CPS improves breathing dysfunction in Mecp2-null mice by blocking GIRK channels in synaptic terminals and enhancing GABA release.

  

Cloperastine (CPS) is a central-acting antitussive working on brainstem neuronal networks The drug has several characteristics. 1) It affects the brainstem integration of multiple sensory inputs via multiple sites including K+ channels, histamine and sigma receptors. 2) Its overall effect is inhibitory, suppressing cough and reactive airway signals. 3) With a large safety margin, it has been approved as an over-the-counter medicine in several Asian and European countries.  

With the evidence that DTN cells receive GABAergic recurrent inhibition, we tested whether the inhibitory effect of CPS was caused by enhanced GABAergic transmission. Thus, we recorded the evoked firing activity of DTN cells before and during bath application of CPS in the presence of 20 μM bicuculline. Under this condition, CPS failed to decrease the excitability of DTN neurons (F(1,9) = 0.41, P > 0.05; two‐way repeated measures ANOVA) (n=9) (Fig. 8), indicating that the inhibitory effect relies on GABAA synaptic input 

 

It appeared to me that the breathing issues might be considered as another consequence of the excitatory/inhibitory (E/I) imbalance that is a core feature of much severe autism.

In the case of Rett the lack of BDNF will make any E/I imbalance worse and that by treating the E/I imbalance we will produce the inhibitory effect from GABAa receptors that is needed to ensure correct breathing.  Note that in bumetanide responsive autism there is no inhibitory effect from GABAa receptors, the effect is excitatory.

I did wonder if arrhythmia (irregular heartbeat) is present in Rett, since the breathing problems in Rett are also seen as being caused by a dysfunction in the autonomic nervous system. Arrhythmia is actually a big problem for girls with Rett syndrome.  Regular readers of this blog might then ask about Propranolol, does that help?  It turns out to have been tried and it is not so helpful.  What is effective is another drug we have come across for autism, the sodium channel blocker Phenytoin.  Phenytoin is antiepileptic drug (AED) and it works by blocking voltage gated sodium channels.

Low dose phenytoin was proposed as an autism therapy and a case study was published from Australia. In a separate case study, phenytoin was used to treat self-injury that was triggered by frontal lobe seizures.

When you treat arrhythmia in Rett girls with Phenytoin does it have an impact on their breathing problems?

If you treat the girls with Phenytoin do they still go on to develop epilepsy?

What about if you add treatment with Bumetanide to reduce symptoms of autism? 

Lots of questions looking for answers.

 

What is Rett Syndrome?

Rett syndrome was first identified in the 1950s by Dr Andreas Rett as a disorder that develops in young girls.  Only as recently as 1999 was it determined that the syndrome is caused by a mutation in the MECP2 gene on the X chromosome.  The X chromosome is very important because girls have two copies, but boys have just one.  Rett was an Austrian like many other early researchers in autism like Kanner and Asperger. Even Freud was educated in Vienna. Eugen Bleuler lived pretty close by in Switzerland and he coined the terms schizophrenia, schizoid and autism. 

Rett syndrome is a rare genetic disorder that affects brain development, resulting in severe mental and physical disability.

It is estimated to affect about 1 in 12,000 girls born each year.

Rett is a rare condition, but among these rare conditions it is quite common and so there is a lot of research going on to find treatments.  The obvious one is gene therapy to get the brain to make the missing MeCP2 protein.

Rett syndrome is thankfully rare in absolute terms, but it is one of the best known development conditions that is associated with autism symptoms.

While Rett syndrome may not officially be an ASD in the DSM-5, the link to autism remains. Many children are diagnosed as autistic before the MECP2 mutation is identified and then the diagnosis is revised to RTT/Rett. 

Fragile X  syndrome (FXS), on the other hand, is the most common inherited cause of intellectual disability (ID), as well as the most frequent single gene type of autism.

In the meantime, the logical strategy is to treat the downstream consequences of the mutated gene. Much is known about these downstream effects and there overlaps with some broader autism and indeed dementia.

One area known to be disturbed in Rett, some other autisms and dementia is growth factors inside the brain. The best known growth factors are IGF-1 (Insulin-like Growth Factor 1), BDNF (brain-derived neurotrophic factor) and my favorite NGF (Nerve growth factor).

Without wanting to get too complicated we need to note that BDNF acts via a receptor called TrkB.  You can either increase BDNF or just find something else to activate TrkB, as pointed out to me by Daniel.

For readers whose children respond to Bumetanide they are benefiting from correcting elevated levels of chloride in neurons. Too much had been entering by the transporter NKCC1 and too little exiting via KCC2.

One of the effects of having too little BDNF and hence not enough activation of TrkB is that chloride becomes elevated in neurons.  If you do not activate TrkB you do not get enough KCC2, which is what allows chloride to exit neurons.

To what extent would TrkB activation be an alternative/complement to bumetanide in broader autism?

To what extent would TrkB activation be success in treating some types of chronic pain (where KCC2 is known to be down regulated)?

Low levels of BDNF are a feature of Rett and much dementia.

So you would want to:

·        Increase BDNF

·        Activate TRKB with something else

·        Block NKCC2 to compensate for the lack of KCC2

Note that BDNF is not reduced in all types of autism, just in a sub-group.

I note that there already is solid evidence in the research:-

Restoration of motor learning in a mouse model of Rett syndrome following long-term treatment with a novel small-molecule activator of TrkB

Reduced expression of brain-derived neurotrophic factor (BDNF) and impaired activation of the BDNF receptor, tropomyosin receptor kinase B (TrkB; also known as Ntrk2), are thought to contribute significantly to the pathophysiology of Rett syndrome (RTT), a severe neurodevelopmental disorder caused by loss-of-function mutations in the X-linked gene encoding methyl-CpG-binding protein 2 (MeCP2). Previous studies from this and other laboratories have shown that enhancing BDNF expression and/or TrkB activation in Mecp2-deficient mouse models of RTT can ameliorate or reverse abnormal neurological phenotypes that mimic human RTT symptoms. The present study reports on the preclinical efficacy of a novel, small-molecule, non-peptide TrkB partial agonist, PTX-BD4-3, in heterozygous female Mecp2 mutant mice, a well-established RTT model that recapitulates the genetic mosaicism of the human disease. PTX-BD4-3 exhibited specificity for TrkB in cell-based assays of neurotrophin receptor activation and neuronal cell survival and in in vitro receptor binding assays. PTX-BD4-3 also activated TrkB following systemic administration to wild-type and Mecp2 mutant mice and was rapidly cleared from the brain and plasma with a half-life of 2 h. Chronic intermittent treatment of Mecp2 mutants with a low dose of PTX-BD4-3 (5 mg/kg, intraperitoneally, once every 3 days for 8 weeks) reversed deficits in two core RTT symptom domains – respiration and motor control – and symptom rescue was maintained for at least 24 h after the last dose. Together, these data indicate that significant clinically relevant benefit can be achieved in a mouse model of RTT with a chronic intermittent, low-dose treatment paradigm targeting the neurotrophin receptor TrkB. 

Early alterations in a mouse model of Rett syndrome: the GABA developmental shift is abolished at birth

Genetic mutations of the Methyl-CpG-binding protein-2 (MECP2) gene underlie Rett syndrome (RTT). Developmental processes are often considered to be irrelevant in RTT pathogenesis but neuronal activity at birth has not been recorded. We report that the GABA developmental shift at birth is abolished in CA3 pyramidal neurons of Mecp2−/y mice and the glutamatergic/GABAergic postsynaptic currents (PSCs) ratio is increased. Two weeks later, GABA exerts strong excitatory actions, the glutamatergic/GABAergic PSCs ratio is enhanced, hyper-synchronized activity is present and metabotropic long-term depression (LTD) is impacted. One day before delivery, maternal administration of the NKCC1 chloride importer antagonist bumetanide restored these parameters but not respiratory or weight deficits, nor the onset of mortality. Results suggest that birth is a critical period in RTT with important alterations that can be attenuated by bumetanide raising the possibility of early treatment of the disorder.

    

The GABA Polarity Shift and Bumetanide Treatment: Making Sense Requires Unbiased and Undogmatic Analysis

 

GABA depolarizes and often excites immature neurons in all animal species and brain structures investigated due to a developmentally regulated reduction in intracellular chloride concentration ([Cl]i) levels. The control of [Cl]i levels is mediated by the chloride cotransporters NKCC1 and KCC2, the former usually importing chloride and the latter exporting it. The GABA polarity shift has been extensively validated in several experimental conditions using often the NKCC1 chloride importer antagonist bumetanide. In spite of an intrinsic heterogeneity, this shift is abolished in many experimental conditions associated with developmental disorders including autism, Rett syndrome, fragile X syndrome, or maternal immune activation. Using bumetanide, an EMA- and FDA-approved agent, many clinical trials have shown promising results with the expected side effects. Kaila et al. have repeatedly challenged these experimental and clinical observations. Here, we reply to the recent reviews by Kaila et al. stressing that the GABA polarity shift is solidly accepted by the scientific community as a major discovery to understand brain development and that bumetanide has shown promising effects in clinical trials.

 

Back in 2013 a case study was published showing Bumetanide worked for a boy with Fragile X syndrome. A decade later and still nobody has looked to see if it works in all Fragile X. 

Treating Fragile X syndrome with the diuretic bumetanide: a case report

https://pubmed.ncbi.nlm.nih.gov/23647528/

We report that daily administration of the diuretic NKCC1 chloride co-transporter, bumetanide, reduces the severity of autism in a 10-year-old Fragile X boy using CARS, ADOS, ABC, RDEG and RRB before and after treatment. In keeping with extensive clinical use of this diuretic, the only side effect was a small hypokalaemia. A double-blind clinical trial is warranted to test the efficacy of bumetanide in FRX.

 

What do Rett syndrome and Fragile X have in common? 

In a healthy mature neuron the level of chloride needs to be low for it to function correctly (the neurotransmitter GABA to be inhibitory).

 


Rett and Fragile X are part of a large group of conditions that feature elevated levels of chloride in neurons.

 


Elevated chloride in neurons is treatable.

 

Is Bumetanide a cure for Rett syndrome, or Fragile X?

No it is not, but it is a step in that direction because it reverses a key defect present in at least some Rett and some Fragile X.

In the mouse model of Rett, bumetanide corrected some, but not all the problems caused by the loss of function of the MECP2 gene.

 

Moving on to IGF-1

IGF-1 is a growth hormone with multiple functions throughout aging. Production of IGF-1 is stimulated by GH (growth hormone).

The lowest levels occur in infancy and old age and highest levels occur around the growth spurt before puberty.

Girls with Turner syndrome, lack their second X chromosome and this causes a lack of growth hormones and female hormones. They end up with short stature and with features of autism. Treatment is possible with GH or indeed IGF-1.

In dementia one strategy is to increase IGF-1.  This same strategy is also being applied to single gene autisms like Rett and Pitt Hopkins.

Trofinetide and NNZ-2591 are improved synthetic analogues of peptides that occur naturally in the brain and are related to IGF-1. Trofinetide is being developed to treat Rett and Fragile X syndromes, NNZ-2591 is being developed to treat Angelman, Phelan-McDermid, Pitt Hopkins and Prader-Willi syndromes.

 

NGF (nerve growth factor)

Nerve growth factor does what it says (boosting nerve growth), plus much more. NGF plays a key role in the immune system, it is produced in mast cells, and it plays a role in how pain in perceived.

NGF acts via NGF receptors, not surprisingly, but also via TrkA receptors. We saw earlier in this post that BDNF acts via TrkB receptors.

Once NGF binds to the TrkA receptor it triggers a cascade of signalling via  the Ras/MAPK pathway and the PI3K/Akt pathway.  Both pathways relate to autism and Ras itself can play a role in intellectual disability. 

These are also cancer pathways and indeed NGF seems to play a role.  Beta cells in the pancreas produce insulin and these beta cells have TrkA receptors. In type 1 diabetes these beta cells die.  Beta cells need NGF to activate their TrkA receptors to survive.

Clearly for multiple reasons you need plenty of NGF.

Lack of NGF would be one cause of dementia and that is why Rita Levi-Montalcini choose to self-treat with NGF eye drops for 30 years. Rita won a Nobel prize for discovering NGF.

In Rett syndrome we know that the level of NGF is very low in the brain.

Logical therapies for Rett would seem to include:

·        NGF itself, perhaps taken as eye drops, but tricky to administer

·        A TrkA agonist, that would mimic the effect of NGF

·        The traditional medicinal mushroom  Lion’s Mane (Hericium erinaceus) 

We should note that effect of NGF acting via TrkA is mainly in the peripheral nervous system, not the brain.

It has long been known that Lions’ Mane (Hericium erinaceus) increases NGF but it was not clear why.  This has very recently been answered.

The active chemical has been identified to be N-de phenylethyl isohericerin (NDPIH).

The opens the door to synthesizing NDPIH as drug to treat a wide range of conditions from Alzheimer’s to Rett. 


Mushrooms Magnify Memory by Boosting Nerve Growth  

Active compounds in the edible Lion’s Mane mushroom can help promote neurogenesis and enhance memory, a new study reports. Preclinical trials report the compound had a significant impact on neural growth and improved memory formation. Researchers say the compound could have clinical applications in treating and preventing neurodegenerative disorders such as Alzheimer’s disease.

Professor Frederic Meunier from the Queensland Brain Institute said the team had identified new active compounds from the mushroom, Hericium erinaceus.

“Extracts from these so-called ‘lion’s mane’ mushrooms have been used in traditional medicine in Asian countries for centuries, but we wanted to scientifically determine their potential effect on brain cells,” Professor Meunier said.

“Pre-clinical testing found the lion’s mane mushroom had a significant impact on the growth of brain cells and improving memory.

“Laboratory tests measured the neurotrophic effects of compounds isolated from Hericium erinaceus on cultured brain cells, and surprisingly we found that the active compounds promote neuron projections, extending and connecting to other neurons.

“Using super-resolution microscopy, we found the mushroom extract and its active components largely increase the size of growth cones, which are particularly important for brain cells to sense their environment and establish new connections with other neurons in the brain.” 

 

Hericerin derivatives activates a pan‐neurotrophic pathway in central hippocampal neurons converging to ERK1/2 signaling enhancing spatial memory

The traditional medicinal mushroom Hericium erinaceus is known for enhancing peripheral nerve regeneration through targeting nerve growth factor (NGF) neurotrophic activity. Here, we purified and identified biologically new active compounds from H. erinaceus, based on their ability to promote neurite outgrowth in hippocampal neurons. N-de phenylethyl isohericerin (NDPIH), an isoindoline compound from this mushroom, together with its hydrophobic derivative hericene A, were highly potent in promoting extensive axon outgrowth and neurite branching in cultured hippocampal neurons even in the absence of serum, demonstrating potent neurotrophic activity. Pharmacological inhibition of tropomyosin receptor kinase B (TrkB) by ANA-12 only partly prevented the NDPIH-induced neurotrophic activity, suggesting a potential link with BDNF signaling. However, we found that NDPIH activated ERK1/2 signaling in the absence of TrkB in HEK-293T cells, an effect that was not sensitive to ANA-12 in the presence of TrkB. Our results demonstrate that NDPIH acts via a complementary neurotrophic pathway independent of TrkB with converging downstream ERK1/2 activation. Mice fed with H. erinaceus crude extract and hericene A also exhibited increased neurotrophin expression and downstream signaling, resulting in significantly enhanced hippocampal memory. Hericene A therefore acts through a novel pan-neurotrophic signaling pathway, leading to improved cognitive performance.

 

Since the discovery of the first neurotrophin, NGF, more than 70 years ago, countless studies have demonstrated their ability to promote neurite regeneration, prevent or reverse neuronal degeneration and enhance synaptic plasticity. Neurotrophins have attracted the attention of the scientific community in the view to implement therapeutic strategies for the treatment of a number of neurological disorders. Unfortunately, their actual therapeutic applications have been limited and the potential use of their beneficial effects remain to be exploited. Neurotrophins, for example, have poor oral bioavailability, and very low stability in serum, with half-lives in the order of minutes  as well as minimal BBB permeability and restricted diffusion within brain parenchyma. In addition, their receptor signaling networks can confer undesired off-target effects such as pain, spasticity and even neurodegeneration. As a consequence, alternative strategies to increase neurotrophin levels, improve their pharmacokinetic limitations or target specific receptors have been developed. Identification of bioactive compounds derived from natural products with neurotrophic activities also provide new hope in the development of sustainable therapeutical interventions. Hericerin derivative are therefore attractive compounds for their ability to promote a pan-neurotrophic effect with converging ERK1/2 downstream signaling pathway and for their ability to promote the expression of neurotrophins. Further work will be needed to find the direct target of Hericerin capable of mediating such a potent pan-neurotrophic activity and establish whether this novel pathway can be harnessed to improve memory performance and for slowing down the cognitive decline associated with ageing and neurodegenerative diseases.



 

What this means is that there are 2 good reasons why Lion’s Mane should be helpful in Rett syndrome, both increasing BDNF and NGF.

  

Conclusion

Interestingly, one of the above papers is co-authored by a researcher from the European Brain Research Institute, founded by Rita Levi-Montalcini, the Nobel laureate who discovered NGF (Nerve growth factor). My top pick to test next in Rett syndrome would be NGF. Administration would have to follow Rita’s own example and be in the form of eye drops or follow the Lion’s Mane option, that has recently been further validated.

Rett syndrome is very well documented and many researchers are engaged in studying it.

As with broader autism, the problem is translating all the research into practical therapy today.

Clearly polytherapy will be required.

More than one type of neuronal hyperexcitability seems to be in play.

It looks like one E/I imbalance is the bumetanide responsive kind, that can be treated and will reduce autism symptoms and improve learning skills.  Then we have the hypoventilation/apnea for which Cloperastine looks a fair bet.  For the arrhythmia we have Phenytoin.  If there are still seizures after all that therapy it looks like sodium valproate is the standard treatment for Rett.

Sodium valproate is also an HDAC inhibitor and so has possibly beneficial epigenetic effects as a bonus.

I have always liked the idea of the Lion’s Mane mushrooms as a means to increase NGF (Nerve growth factor).  In today’s post we saw that it is the NDPIH from the mushrooms that acts to increase both BDNF and NGF.  You would struggle to buy NDPIH but you can buy these mushrooms. I did once buy the supplement version of these mushrooms and it was contaminated, so I think the best bet is the actual chemical or the actual mushroom.  One reader did write in once who is a big consumer of these mushrooms.

 


Lion's Mane Mushroom

Source: Igelstachelbart Nov 06

 

A Trk-B agonist that can penetrate the blood brain barrier would look a good idea.  There are some sold by the nootropic people.

7,8-dihydroxyflavone is such an agonist that showed a benefit in the mouse model.

 

7,8-dihydroxyflavone exhibits therapeutic efficacy in a mouse model of Rett syndrome

Following weaning, 7,8-DHF was administered in drinking water throughout life. Treated mutant mice lived significantly longer compared with untreated mutant littermates (80 ± 4 and 66 ± 2 days, respectively). 7,8-DHF delayed body weight loss, increased neuronal nuclei size and enhanced voluntary locomotor (running wheel) distance in Mecp2 mutant mice. In addition, administration of 7,8-DHF partially improved breathing pattern irregularities and returned tidal volumes to near wild-type levels. Thus although the specific mechanisms are not completely known, 7,8-DHF appears to reduce disease symptoms in Mecp2 mutant mice and may have potential as a therapeutic treatment for RTT patients.

Rett syndrome also features mitochondrial dysfunction and a variant of metabolic syndrome.  We have quite a resource available from broader autism, not much of it seems to have been applied in Rett.

You can see that in Rett less oxygen is available due to breathing issues and yet more oxygen is required due to “faulty” mitochondria. 

“Intensified mitochondrial O2 consumption, increased mitochondrial ROS generation and disturbed redox balance in mitochondria and cytosol may represent a causal chain, which provokes dysregulated proteins, oxidative tissue damage, and contributes to neuronal network dysfunction in RTT.”

https://www.frontiersin.org/articles/10.3389/fphys.2019.00479/full#:~:text=Rett%20syndrome%20(RTT)%2C%20an,inner%20membrane%20is%20leaking%20protons.

 

We have seen in this blog that 2 old drugs exist to increase oxygen levels in blood.  The Western world has Diamox (Acetazolamide) and the former soviet world has Mildronate/Meldonium. Mildronate also was suggested to have some wider potential benefit to mitochondria.

Rett is proposed as a neurological disorder with metabolic components, so based on what we have seen in this blog, you would think along the lines of Metformin, Pioglitazone and a lipophilic statin (Atorvastatin, Simvastatin or Lovastatin). 

The Anti-Diabetic Drug Metformin Rescues Aberrant Mitochondrial Activity and Restrains Oxidative Stress in a Female Mouse Model of Rett Syndrome


Statins improve symptoms of Rett syndrome in mice


The ultimate Rett cure will be one of the new gene therapies given to a baby before any significant progression of the disorder has occurred.

For everyone else, it looks like there is scope to develop a pretty potent individualized polytherapy, just by applying the very substantial knowledge that already exists in the research.

Good luck to Daniel and all the others seeking answers.



 


Saturday, 5 December 2020

Suramin in China, where things can move fast – blocking Enterovirus-71 rather than treating Autism

The new Chinese and old Colonial, side by side in central Shanghai

  

I do not speak Chinese, but fortunately Google does.

I was sent some interesting links to some articles from China about Suramin, the potential autism therapy which many autism parents are eagerly awaiting.  Prepare for a long wait, but hopefully less long in China.

My original post on Suramin for autism can be found  in the link below:-


Suramin, the Purinome and Autism

 

 

I have never had a banner appear on my computer trying to sell me a Rolls Royce until today.  This is more proof, if I needed it, of how much China has changed since my first visit there as a teenager.  Back then there were a lot of bicycles; I still remember many were Flying Pigeon brand – not a name you forget. I just looked them up and since 1950, more than 500 million Flying Pigeon bicycles have been made - that is a lot bicycles.

I even went to see a factory still producing steam locomotives in Datong in the 1980s. They gave you a personal certificate of your visit, which I still have somewhere. 

Last year I was again in China and travelled on their ultra-modern high speed trains.  These run on purpose-built tracks, often running to totally new vast railway stations.  The network is massive with 36,000 km (22,000 miles) in total length and trains running at speeds up to 220 mph / 350 km/h.  The ride is perfectly smooth and the tickets are not so expensive.   The old train lines I used many years ago still exist and you can still take the “hard sleeper” to travel long distances overnight for little money, but not quite as cheap as it once was.  

 


 Things move fast in China, hopefully so will Suramin

Suramin is an approved drug, but it is almost impossible to get hold of, unless you are in a limited number of African countries affected by African Sleeping Sickness and River Blindness.  Suramin is made by the German giant Bayer and the brand name (below) is not very original.

 



I think the clever idea is the intranasal version now being developed in the US.

But why not just put this old drug from 1916 in a metered pump dispenser, in the same way the Alzheimer’s researchers put insulin in a nasal spray?  In autism, Vasopressin and Oxytocin are just popped into nasal sprays.  A few years in this blog I mentioned Dr Jay Goldstein who was treating people with TRH intranasally (he wrote a great book called Tuning the Brain – I actually bought it).

Tuning the brain eventually got Jay Goldstein into trouble. Though long “retired”, he has just published another book on ME/CFS.  Goldstein also used Ketamine eye drops and nasal spray.

I guess if he would have been among the first put this old Suramin drug in a nasal spray and see what happens. It quite possibly would help ME/CFS, as suggested by Dr Naviaux himself.

We saw in a post in 2014 that Professor Rita Levi-Montalcini had the clever idea of using home-made NGF eye drops to stave off decline in old age.  She was the first one to discover the existence of Nerve Growth factor (NGF). She became the first Nobel laureate to reach the age of 100.  The NGF eye drops did not do her any harm.

Your eyes are part of the Central Nervous System (CNS) and so an ideal entry point to target the brain. For nasal sprays the route to the CNS is via the trigeminal nerves and not much actually gets through (see below).  Due to the blood brain barrier many drugs taken orally cannot reach the brain.

 

Nose-to-Brain Delivery

The route of transfer of compounds through the nasal respiratory epithelium to the brain is via the trigeminal nerves 

A key advantage of the nose-to-brain route is the possibility of reducing plasma exposure, as has been demonstrated thus eliminating peripheral side effects.

 Simply dissolving the drug molecule in an aqueous phase has been used to administer molecules via the nose-to-brain route. The vast majority of clinical studies, which report pharmacological effects, have involved a solution of the drug in aqueous media delivered using a nasal delivery device

Oxytocin has also been delivered to the brain via the nasal route using a solution with a Cmax of 0.003% of a 10 μg dose being found in the brain. A solution of the human immunodeficiency virus replication inhibitor DB213 delivered the drug to the rat brain with a Cmax that was estimated at no more than 0.007% of the administered dose.

The addition of functional excipients to these solution formulations improves brain delivery via the nasal route. 

 

It may well be that Rita and Jay got it right by choosing eye drops over a nasal spray. Suramin eye drops? Not as crazy as it may sound.  Perhaps in China?

   

Back to China

 For several years there has been research looking at treating hand foot and mouth disease using Suramin.

Hand, foot, and mouth disease is common in children under five years old, but anyone can get it.

The illness is usually not serious, but it is very contagious. It spreads quickly at schools and day care centres.

 

Hand, foot, and mouth disease is caused by viruses that belong to the Enterovirus family.

Common causes of hand, foot, and mouth disease are:

  • Coxsackievirus A16 is typically the most common cause of hand, foot, and mouth disease in the United States. Other coxsackieviruses can also cause the illness.
  • Coxsackievirus A6 can also cause HFMD and the symptoms may be more severe.
  • Enterovirus 71 (EV-A71) has been associated with cases and outbreaks in East and Southeast Asia. Although very rare, EV-A71 has been associated with more severe diseases, such as encephalitis. 


Enterovirus 71 (EV-A71)


Suramin inhibits EV71 infection

Highlights

·        Suramin inhibits the proliferation of EV71 virus.

·        Suramin directly blocks the attachment of EV71 virion to host cell.

·        Suramin can be used as a potential clinical therapeutic against EV71 infection.

 

Abstract

Enterovirus-71 (EV71) is one of the major causative reagents for hand-foot-and-mouth disease. In particular, EV71 causes severe central nervous system infections and leads to numerous dead cases. Although several inactivated whole-virus vaccines have entered in clinical trials, no antiviral agent has been provided for clinical therapy. In the present work, we screened our compound library and identified that suramin, which has been clinically used to treat variable diseases, could inhibit EV71 proliferation with an IC50 value of 40 μM. We further revealed that suramin could block the attachment of EV71 to host cells to regulate the early stage of EV71 infection, as well as affected other steps of EV71 life cycle. Our results are helpful to understand the mechanism for EV71 life cycle and provide a potential for the usage of an approved drug, suramin, as the antiviral against EV71 infection.

 

 

The approved pediatric drug suramin identified as a clinical candidate for the treatment of EV71 infection - Suramin inhibits EV71 infection in vitro and in vivo

 Enterovirus 71 (EV71) causes severe central nervous system infections, leading to cardiopulmonary complications and death in young children. There is an urgent unmet medical need for new pharmaceutical agents to control EV71 infections. Using a multidisciplinary approach, we found that the approved pediatric antiparasitic drug suramin blocked EV71 infectivity by a novel mechanism of action that involves binding of the naphtalentrisulonic acid group of suramin to the viral capsid. Moreover, we demonstrate that when suramin is used in vivo at doses equivalent to or lower than the highest dose already used in humans, it significantly decreased mortality in mice challenged with a lethal dose of EV71 and peak viral load in adult rhesus monkeys. Thus, suramin inhibits EV71 infection by neutralizing virus particles prior to cell attachment. Consequently, these findings identify suramin as a clinical candidate for further development as a therapeutic or prophylactic treatment for severe EV71 infection.

 

 

Kangzhi Pharmaceutical has the rights to develop Suramin for hand foot and mouth disease in China and beyond. 

 

Kangzhi Pharmaceutical has developed a new indication for "Suramin Sodium" and is committed to the development of drugs for hand, foot and mouth disease 


Currently, there are no specific antiviral drugs for enteroviruses in the world, and support and symptomatic treatment are the main ones. Clinically, there is an urgent need to develop specialized drugs to treat patients with hand, foot and mouth disease who have been infected. Now that Kangzhi Pharmaceutical's suramin sodium for injection has been approved for clinical trials, it is undoubtedly a gospel for children with hand-foot-mouth disease and is expected to break the dilemma of treatment of hand-foot-mouth disease.

Kangzhi Pharmaceutical has been focusing on children's health for a long time. Under the guidance of "Children's Health Strategy" and "Excellent Strategy", the company insists on investing about 5% of its annual sales in research and development. In 2013, the company took the lead in establishing a post-doctoral scientific research station with children's drug research and development as the main direction in China, and was recognized as "Hainan Children's Drug Preparation Engineering Technology Research Center" in 2016. In order to solve the problem of no medicine for hand, foot and mouth disease, Kangzhi Pharmaceutical has invested heavily in the research and development of suramin sodium for injection.  

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 For a long time, the anti-fever drug "Ruizhiqing (Nimesulide)" is Kangzhi Pharmaceutical's leading product in the children's medicine market. The company's revenue accounted for as high as 70% at one time. However, this product had previously suffered from side effects. Controversial, Kangzhi Pharmaceutical has no longer listed this product as a core competitive advantage in its financial report. Instead, it has given key exposure to another long-developed new drug for the treatment of hand, foot and mouth disease. ——Suramin Sodium for Injection.

It is understood that hand, foot and mouth disease is an infectious disease that is generally susceptible to infants and children under 5 years old. It continues to be prevalent at a fixed period every year. There is no specific medicine for targeted treatment. According to the statistics of the my country Center for Disease Control, the number of cases of hand, foot and mouth disease in China in 2018 was 2,533,310.

Obviously, if Kangzhi Pharmaceutical's new hand, foot and mouth disease drug can be successfully listed, it will become a major "cash cow" product of the company. By then, both performance and stock price will be effectively boosted. However, since this product was exposed by Kangzhi Pharmaceutical, the outside world only knows that this product will be "the world's first new medicine for the treatment of hand, foot and mouth disease", but its final market is still far away.

"The company has obtained the approval for the clinical trial of the drug, and the product has successfully completed the phase I clinical trial and will start the phase II clinical trial. If the clinical trial is successful and the marketing authorization is obtained, suramin sodium will become the world's first treatment for hand, foot and mouth. New medicine for disease.” In the 2019 financial report, Kangzhi Pharmaceutical introduced the latest development of suramin sodium.

As early as 2015, after Kangzhi Pharmaceuticals spent 18 million yuan to buy the patented technology of "Institutions and Methods for Treating Viral Diseases" of the Shanghai Pasteur Institute of the Chinese Academy of Sciences, and planned to invest 50 million yuan in suramin Subsequent research and development of sodium.

In 2018, after the application for the clinical trial of suramin sodium was submitted, it was quickly reviewed and approved according to the special review route. At that time, Hong Liping, vice chairman and vice president of Kangzhi Pharmaceuticals, said in an interview: "Suramin sodium for injection is approved for clinical trials, which is an important achievement of Kangzhi Pharmaceuticals in the development of new drugs. The company deeply feels the responsibility. With the help of the current national policy to encourage the spring breeze of clinically urgently needed therapeutic drugs, we will actively promote the development of clinical trials of the drug and promote the market of new drugs as soon as possible to help children with hand, foot and mouth disease get rid of the disease as soon as possible.

According to the company's secretary of the board of directors on the Shenzhen Stock Exchange, the clinical trial of suramin sodium is divided into 3 phases, and only phase 1 has been completed. The time of the clinical trial is uncertain.

It is reported that the new indication of suramin sodium for the treatment of hand, foot and mouth disease developed by Kangzhi Pharmaceutical has previously applied for an international invention patent through the PCT, and has successively obtained invention patent authorization in China, Japan, Singapore and the United States. The new Indonesian patent authorization will help to further leverage the advantages of independent intellectual property rights, promote the research of hand-foot-mouth disease treatment drugs, benefit the world's hand-foot-mouth disease patients, and enhance the core competitiveness of Kangzhi Pharmaceutical.

  

Conclusion 

It looks like there will eventually be at least 3 pharmaceutical companies selling Suramin.

  Bayer (Germany)

  Kangzhi Pharmaceutical (China)

  Paxmedica (USA), or really which ever Big Pharma they sell out to 

This is all good news for autism and hand foot and mouth disease. 

People do not like injections, nor side effects caused by your drug needlessly going everywhere in your body.

The nasal spray, or eye drops, look a good idea for autism and ME/CFS.

Hopefully the Chinese will move fast, like their trains, and bring their Suramin to the market.

 


In 2008 Arnold Schwarzenegger signed a bill to bring high speed rail to California.  The total system length would have been approximately 800 miles (1,300 km).  Where are we 12 years later?

The British are no better with their high-speed rail, but it is a very densely populated country. China's new rail lines were not built where the old lines ran. Spain actually has really good high-speed trains, that are not so expensive and a great way to get around the country.

Where are those autism drugs, "fast-tracked" for approval by the FDA? In the same place as Arnie’s model train set (going nowhere fast).