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Tuesday, 29 March 2016

Verapamil use in Autism – Request for Case Reports from Parents


  
 By Agnieszka Wroczyńska, MD, PhD, 
Medical University of Gdansk, Poland



In June 2014 my son with severe autism was given verapamil as an emergency mast cell stabilizer according to Peter’s blog, as we run out of other medication ordered from abroad. This turned out to be a life changing moment for him and my family. Two days later his chronic diarrhea resolved completely and soon after we also saw improvements in other symptoms and behaviors.

Several months, blog entries and papers read later my son still uses verapamil and now also other medications targeting autism, most of them being included into Peter’s PolyPill. He is still significantly affected by ASD, but his quality of life improved much, thanks to this blog.

Recently I have visited a very open-minded pediatrician, the first one who suspected medical issues behind challenging behaviours in my son and she asked me about papers on verapamil use in ASD, possibly to include it into her clinical practice. Unfortunately I have nothing to recommend although the use of calcium channel blockers for autism had been suggested long before my son was born as in this paper written in 2004: “These findings hint at a potential mechanism that might underlie autism. Future studies will focus on the genetic analysis of Cav1.2 and other calcium channels in the disorder and the potential application of calcium channel blocker therapy” [1]. This did not happen and no clinical trials were done.

Calcium signalling role in ASD is well backed by science [2-5] as Peter described in many excellent posts here, but not a single case report of such treatment was published. That’s why I would like to invite readers who use or used verapamil (short or long term with or without effects) to jointly publish an article on this treatment in a peer-reviewed medical journal as a case series description.  

According to what Peter suggested before, I wrote a questionnaire including basic clinical data and - if available - tests results suggested by Peter and Nat, as a first step to this article. I would really appreciate your contribution, comments or questions about this idea.

There is no deadline date so you are welcome to join if you start verapamil treatment for you or your child in the future. You may consider to do some lab tests according to the questionnaire then.

If you have not used verapamil, but would like to join this idea in other way, please feel free to contact me.

Before the collective article is ready let me quote a recent paper on another class of calcium channel blocking drugs in autism: “Given the excellent toxicity profile of dihydropyridine LTCC blockers, long-term off-label treatment of patients with ASD appears justified based on our robust in vitro findings.” [6]


If you have not used verapamil, but would like to join this idea in other way or just discuss autism treatment without participating in this case series report, please feel free to contact me.


Thank you!

  

Agnieszka Wroczyńska, MD, PhD
Medical University of Gdansk, Poland
verapamil.asd@gmail.com





The questionnaire can be downloaded from here:

The questionnaire filled with my son’s details as an example:







Friday, 25 March 2016

“Type 3” Diabetes in Alzheimer’s, but maybe also in some Autism



Intranasal insulin, for cognitive enhancement in Alzheimer’s and …



Today’s post was sparked by another little experiment of mine; no, not intranasal insulin.

Recently I have been using a reduced number of therapies on Monty, aged 12 with ASD.  Some people think there are just too many pills.

I wrote many posts last year about something called PPAR gamma (Peroxisome proliferator-activated receptor gamma, PPAR-γ or PPARG, also known as the glitazone receptor).

As you can read in Wikipedia:-

PPAR-gamma has been implicated in the pathology of numerous diseases including obesity, diabetes, atherosclerosis, and cancer. PPAR-gamma agonists have been used in the treatment of hyperlipidaemia andhyperglycemia. PPAR-gamma decreases the inflammatory response of many cardiovascular cells, particularly endothelial cells. PPAR-gamma activates the PON1 gene, increasing synthesis and release of paraoxonase 1 from the liver, reducing atherosclerosis.
Many insulin sensitizing drugs (namely, the thiazolidinediones) used in the treatment of diabetes target PPARG as a means to lower serum glucose without increasing pancreatic insulin secretion.

What we found out in earlier posts that PPAR-gamma can be used to reduce microglial activation, which should turn down the body’s “immunostat”.  A key feature of many people’s autism appears to be an over-activated immune system, reflected by activated microglia.


PPAR-gamma agonists as regulators of microglial activation and brain inflammation.


The present review summarizes the several lines of evidence supporting that PPAR-gamma natural and synthetic agonists may control brain inflammation by inhibiting several functions associated to microglial activation, such as the expression of surface antigens and the synthesis of nitric oxide, prostaglandins, inflammatory cytokines and chemokines. 
Although most of the evidence comes from in vitro observations, an increasing number of studies in animal models further supports the potential therapeutic use of PPAR-gamma agonists in human brain diseases including multiple sclerosis, Parkinson's disease and Alzheimer's disease.



Experiment

The potent PPAR-gamma agonist drugs like Rosiglitazone, have side effects which I think make them unsuitable for autism.  I use a flavanol called Tangeritin, in the form of a supplement called Sytrinol.

For two months we have not used Sytrinol, but yesterday Monty had one pill after lunch.

The piano lesson was great and then Monty had three hours with his Assistant, doing academic work and then some more piano practice.

Before she went home, Monty’s Assistant spent ten minutes telling me, and Monty’s big brother, just how great the afternoon had been.

“Monty was amazing today”

“When he was doing math, it was like he wasn’t autistic”

(we live in a country where autism means strict definition autism, what in the US is called severe autism)

“Did you hear how he played the piano?”

I told Monty’s brother to make a mental note of this and tell it to Mum/Mom later.

The next day the effect of Sytrinol was not as profound.

This actually is a recurring theme, the effect of various interventions is the greatest at the beginning  and then, as the body’s feedback loops get involved, the effect reduces.  

The same is true with cinnamon, another food-based intervention, that also helps people with diabetes.  The effect in (some) autism is greatest when you start.

It would be great if it was possible to keep the full initial effect of both Sytrinol and Cinnamon, and avoiding the dampening reaction caused by feedback loops.

I think if this is possible, it will be via targeting the therapy directly at the brain, rather than the entire body.  This can be achieved via the intranasal route, as used with oxytocin.

What to put in the spray?  This would be a very personalizable solution, since different people have different dysfunctions and to varying degrees.  Some possibilities might include:-

·        Insulin  (read on to learn why)
·        IGF-1
·        T3 thyroid hormone
·        TRH
·        Type 2 iodothyronine deiodinase (D2) 
·        Oxytocin
  
Fine tuning Cognition

It is difficult to be certain what therapy is responsible for what effect.

I recently told one researcher/parent that interventions in autism seem to take effect very quickly and so you can pretty rapidly run through a series of mini-trials to see what helps, what makes things worse and what does nothing.  Being a researcher, his view is that you need to try things for much longer.

One problem of trials lasting months is that external factors may then change, that cause behavior to change and distort the result. This is why I try to avoid trials from May to October, the allergy season.

Many people do find that some supplements help a lot for a week or two and then make things worse.  This includes things like some B vitamins and carnitine.  For other people continued use keeps giving a positive effect.


Previous Experience with Sytrinol

Monty’s assistant at school last year thought Sytrinol made him cleverer.

She also thought the PAK inhibiting propolis (BIO 30) had a similar effect.  This propolis is quite expensive and I concluded the effect was small and this might be because it just was not potent enough. 

One reader of this blog is using a much more potent PAK inhibitor, FRAX486, and some people in the US use Ivermectin.

Ivermectin is an anti-parasite drug which also happens to be a PAK inhibitor.  It is not suitable for long term use.



 Why would Sytrinol improve cognition?

I have written a lot about PPAR gamma in the past, so today has a new angle on the subject.

I did a quick check on PPAR gamma and cognition.

I was surprised what I found.

  


  

PPARγ Recruitment to Active ERK during Memory Consolidation Is Required for Alzheimer's Disease-Related Cognitive Enhancement



Cognitive impairment is a quintessential feature of Alzheimer's disease (AD) and AD mouse models. The peroxisome proliferator-activated receptor-γ (PPARγ) agonist rosiglitazone improves hippocampus-dependent cognitive deficits in some AD patients and ameliorates deficits in the Tg2576 mouse model for AD amyloidosis. Tg2576 cognitive enhancement occurs through the induction of a gene and protein expression profile reflecting convergence of the PPARγ signaling axis and the extracellular signal-regulated protein kinase (ERK) cascade, a critical mediator of memory consolidation. We therefore tested whether PPARγ and ERK associated in protein complexes that subserve cognitive enhancement through PPARγ agonism. Coimmunoprecipitation of hippocampal extracts revealed that PPARγ and activated, phosphorylated ERK (pERK) associated in Tg2576 in vivo, and that PPARγ agonism facilitated recruitment of PPARγ to pERK during memory consolidation. Furthermore, the amount of PPARγ recruited to pERK correlated with the cognitive reserve in humans with AD and in Tg2576. Our findings implicate a previously unidentified PPARγ–pERK complex that provides a molecular mechanism for the convergence of these pathways during cognitive enhancement, thereby offering new targets for therapeutic development in AD.


Cognitive Enhancementwith Rosiglitazone Links the Hippocampal PPAR gamma and ERK MAPK Signaling Pathways



Pathogenesis of Alzheimer’s and Diabetes

The pathogenesis of a disease is the biological mechanism (or mechanisms) that lead to the diseased state.

I am not suggesting that autism leads to Alzheimer’s.  (We do though know that most people with Down Syndrome will develop early Alzheimer’s in their 40s or 50s)

Many complex diseases like Alzheimer’s, cancer and indeed autism have multiple biological mechanisms behind them.

By studying the molecular pathways involved in one disease it may help understand another disease.  This is why some readers of this blog follow the cancer/oncology research.

For some time I have been intrigued at the overlap between diabetes and autism.  What is good for autism really does seem to be good for diabetes and vice versa.


Alzheimer’s Disease as Type 3 Diabetes

I was surprised to learn that some clinicians now consider Alzheimer’s Disease as Type 3 Diabetes.           

You will recall that Type 1 diabetes is when your pancreas packs up making insulin and then you have to inject yourself with supplementary insulin.

Type 2 diabetes occurs in late middle age, often linked to obesity, and is characterized by high blood sugar, insulin resistance (insulin sensitivity), and relative lack of insulin.

Insulin resistance (IR) is generally regarded as a pathological condition in which cells fail to respond to the normal actions of the hormone insulin. The body produces insulin. When the body produces insulin under conditions of insulin resistance, the cells in the body are resistant to the insulin and are unable to use it as effectively, leading to high blood sugar. Beta cells in the pancreas subsequently increase their production of insulin, further contributing to a high blood insulin level. This often remains undetected and can contribute to a diagnosis of Type 2 diabetes.  Despite the ill-effects of severe insulin resistance, recent investigations have revealed that insulin resistance is primarily a well-evolved mechanism to conserve the brain's glucose consumption by preventing muscles from taking up excessive glucose.[

Eventually Type 2 diabetes may progress to Type 1 diabetes mellitus, where the body's own immune system attacks the beta cells in the pancreas and destroys them. This means the body can no longer produce and secrete insulin into the blood and regulate the blood glucose concentration. We saw how the use of Verapamil can stop beta cells being destroyed.

Some clinicians/researchers propose that diabetes of the brain should be called Type 3 diabetes.

The research does support the view that Alzheimer’s does incorporate this brain-specific type of diabetes.  But I know wonder if this applies to some autism.




Alzheimer’s disease (AD) has characteristic histopathological, molecular, and biochemical abnormalities, including cell loss; abundant neurofibrillary tangles; dystrophic neurites; amyloid precursor protein, amyloid-β (APP-Aβ) deposits; increased activation of prodeath genes and signaling pathways; impaired energy metabolism; mitochondrial dysfunction; chronic oxidative stress; and DNA damage. Gaining a better understanding of AD pathogenesis will require a framework that mechanistically interlinks all these phenomena. Currently, there is a rapid growth in the literature pointing toward insulin deficiency and insulin resistance as mediators of AD-type neurodegeneration, but this surge of new information is riddled with conflicting and unresolved concepts regarding the potential contributions of type 2 diabetes mellitus (T2DM), metabolic syndrome, and obesity to AD pathogenesis. Herein, we review the evidence that (1) T2DM causes brain insulin resistance, oxidative stress, and cognitive impairment, but its aggregate effects fall far short of mimicking AD; (2) extensive disturbances in brain insulin and insulin-like growth factor (IGF) signaling mechanisms represent early and progressive abnormalities and could account for the majority of molecular, biochemical, and histopathological lesions in AD; (3) experimental brain diabetes produced by intracerebral administration of streptozotocin shares many features with AD, including cognitive impairment and disturbances in acetylcholine homeostasis; and (4) experimental brain diabetes is treatable with insulin sensitizer agents, i.e., drugs currently used to treat T2DM. We conclude that the term “type 3 diabetes” accurately reflects the fact that AD represents a form of diabetes that selectively involves the brain and has molecular and biochemical features that overlap with both type 1 diabetes mellitus and T2DM.

Altogether, the results from these studies provide strong evidence in support of the hypothesis that AD represents a form of diabetes mellitus that selectively afflicts the brain

The human and experimental animal model studies also showed that CNS impairments in insulin/IGF signaling mechanisms can occur in the absence of T1DM or T2DM

Altogether, the data provide strong evidence that AD is intrinsically a neuroendocrine disease caused by selective impairments in insulin and IGF signaling mechanisms, including deficiencies in local insulin and IGF production.

At the same time, it is essential to recognize that T2DM and T3DM are not solely the end results of insulin/IGF resistance and/or deficiency, because these syndromes are unequivocally accompanied by significant activation of inflammatory mediators, oxidative stress, DNA damage, and mitochondrial dysfunction, which contribute to the degenerative cascade by exacerbating insulin/ IGF resistance.

Some of the most relevant data supporting this concept have emerged from clinical studies demonstrating cognitive improvement and/or stabilization of cognitive impairment in subjects with early AD following treatment with intranasal insulin or  a PPAR agonist



Repurposing Diabetes Drugs for Brain Insulin Resistance in Alzheimer Disease


 Although many classes of drugs are now approved for management of diabetes, a primary focus of efforts to treat insulin-signaling dysfunction in AD has been the administration of exogenous insulin. There is abundant anecdotal evidence that insulin administration in people with diabetes may acutely affect mood, behavior, and cognitive performance.

Results of recent pilot studies of intranasal insulin in mild cognitive impairment (MCI) and AD have been encouraging. The most notable of these studies was a doubleblind, randomized trial of 104 older adults with MCI or AD who received placebo, low-dose (20 IU), or high-dose (40 IU) intranasal insulin for 4 months

In 2012, the U.S. National Institutes of Health allocated $7.9 million for a pivotal trial of intranasal insulin called the Study of Nasal Insulin in the Fight Against Forgetfulness (SNIFF; ClinicalTrials identifier: NCT01767909). This multicenter phase 2/3 study will be conducted by the ADCS. It is expected to recruit 250 participants with AD or MCI and to randomize them for 12 months to intranasal insulin or placebo, followed by an open-label extension of 6 months in which all participants will receive intranasal insulin. The study should be completed in late 2014.  The Study of Nasal Insulin in the Fight Against Forgetfulness (SNIFF)

In preclinical studies, TZDs improved biomarkers of AD as well as memory and cognition (31). The first pilot studies in humans were also generally encouraging, including a study by Watson et al. (32) that showed improved memory and modulation of amyloid-b levels in CSF compared with placebo after 6 months of treatment with rosiglitazone. On the basis of these preliminary studies, the maker of rosiglitazone sponsored two adequately powered phase 3 studies of rosiglitazone in AD as monotherapy or as adjunctive therapy to acetylcholinesterase inhibitors in mild to-moderate AD. These larger trials failed to replicate the positive findings of the smaller pilot studies (33).

Many explanations have been proposed for why rosiglitazone does not appear to be effective as a treatment for AD in cognitively impaired adults. Perhaps the most convincing explanation is that rosiglitazone has only modest blood-brain barrier penetration, and in fact, rosiglitazone is actively pumped out of the brain by an endogenous efflux system (34). Therefore, rosiglitazone should be expected to have only a mild insulin-sensitizing effect in the human brain.





   


Conclusion

The type 2 diabetes drugs like Rosiglitazone/Pioglitazone have been trialed in both autism and Alzheimer’s.  The results in autism with pioglitazone were positive, in Alzheimer’s they used Rosiglitazone, due to the adverse side effects of pioglitazone, and the results were very mixed.  Rosiglitazone has only modest blood-brain barrier penetration so it looks a poor choice.

In the autism trial they measured "autism" rather than cognitive function.

Effect of pioglitazone treatment on behavioral symptoms in autistic children 

In a small cohort of autistic children, daily treatment with 30 or 60 mg p.o. pioglitazone for 3–4 months induced apparent clinical improvement without adverse events. There were no adverse effects noted and behavioral measurements revealed a significant decrease in 4 out of 5 subcategories (irritability, lethargy, stereotypy, and hyperactivity). Improved behaviors were inversely correlated with patient age, indicating stronger effects on the younger patients.
Conclusion  Pioglitazone should be considered for further testing of therapeutic potential in autistic patients.

One to watch is the effect of the standard type 2 diabetes treatment Metformin on cognition in Alzheimer’s.  Nobody really knows the mode of action of Metformin.

Intranasal insulin is very interesting and not just in Alzheimer’s.


Intranasal insulin improves memory in humans


Intranasal Insulin as a Treatment for Alzheimer’s Disease: A Review of Basic Research and Clinical Evidence





I will add it to my growing list of therapies for mild cognitive impairment, in case I need it in the future.

·        Nerve growth factor (NGF) eye drops
·        Lions Mane Mushrooms (that increase NGF)
·        Cocoa Flavanols (increase cerebral blood flow)
·        Intranasal insulin or just Tangeritin/Sytrinol

I do not know if intranasal insulin would be a safe long-term therapy for children, but it would be a good diagnostic tool.  Once large numbers of older people start using intranasal insulin for cognition, we will find out how well it is tolerated.  Older people seem far more prone to side effects than younger people.


For now I think Tangeritin/Sytrinol is the best choice.












Tuesday, 22 March 2016

GABA, bumetanide, ketogenic diet, channelopathies, histamine … and all other things autism





A Guest Post by UK Charity Treating Autism



If you are a reader of this blog and interested in all things autism, especially those things regularly discussed here, you may want to find yourself in London on the weekend of 18-19 June, attending a conference organised by a UK charity Treating Autism. The location is Brunel University campus - a stone’s throw from Heathrow airport, or a fun tube ride from Eurostar St Pancras station.

If you can only attend one day make sure it is Sunday 19th, as this day will feature presentations on most promising treatment approaches in autism including the one on bumetanide for autism titled ‘Reducing symptoms of autism by addressing dysfunctional GABA: A chloride concentration story’ by none other than Dr Lemonnier himself.

Prof Dr Athanasios Evangeliou of Papageorgiou Hospital Thessaloniki will be giving not one but two presentations: ‘Autism, epilepsy and metabolic disorders’ (am) and ‘Alternative” treatments for Autism in mainstream clinical settings’ (pm). He will be discussing many different things, amongst them the merits of screening evaluations and identification of metabolic biomarkers in autism with therapeutic relevance, such as for example biotin, B complex vitamins, branched chain amino acids and ketogenic diet. (To jog your memory a little see here and here.)

John Rodakis of NofOne Research Foundation will be flying over from the States to update us on the latest sulforaphane and suramin autism trials, Dr Coutinho from Oxford Uni will reveal their latest findings on maternal autoantibodies in autism, and there will be a very special presentation by a very special reader and a regular contributor to comment section of this blog – as I am not saying more J you will have to find out by clicking on this link http://treatingautism.org.uk/event/the-treating-autism-international-conference-2016/

Hope to see you there!!


(A big Thanks to Peter for allowing me to share this!)










Saturday, 19 March 2016

Autism Biology, Comorbidity, Mortality and Better use of Existing Research



Karolinska Institutet, the Medical University of Stockholm, viewed from garden next door


It is sometimes disappointing how the level of understanding of Autism, even among supposed experts, is so very low.

As readers of this blog are aware there is already a vast wealth of research in autism, highlighting many biological differences and comorbid medical conditions.  Not surprisingly this is reflected in life expectancy.

Autistica, a UK Autism charity, is trying to raise $15 million to fund five years of research into why there is premature death in autism.

This would be a complete waste of money, since the answers already exist in the literature if this “Autism Research” charity employed people who actually could/did read the research.

This subject dates back to a Swedish study from last year that is languishing behind a pay wall, so no open access to it.


The rather skimpy abstract:


  
The rather underwhelming press release from the Karolinska Institute:-







Courtesy of SFARI we have this graphic and highlights.







·        Autistic adults with a learning disability were found to die more than 30 years before non-autistic people.

·        The study found that on average people with autism died over 18 years earlier than non-autistic people.

·        Autistic adults with a learning disability are 40 times more likely to die prematurely due to a neurological condition, with epilepsy the leading cause of death

·        Autistic adults without a learning disability are 9 times more likely to die from suicide



 Autistica did produce a report that is based on the Swedish study:-





Is there anything new here?


Epilepsy

People might rather not discuss it, but there are numerous examples of well-known people who had a child with severe autism, MR/ID and epilepsy, and it all ended pretty much as suggested in the Swedish Study.  A fatal seizure (SUDEP), or an accident like drowning following a seizure.

The logical thing to do is to prevent epilepsy developing in the first place, which some readers of this blog are already endeavoring to do.   This is not fantasy, just hard to prove it worked.


Suicide

We have seen that anxiety can be a key problem for people with Asperger’s. 

We heard from a UK pediatrician who found an off-label treatment, Baclofen, which was effective in most cases.  We also were told why he/she did not want to continue prescribing it do to the lack of any clinical trials supporting its use.

We saw how Prozac, the anti-anxiety pill frequently prescribed in autism has the known side effect of increasing suicidal thoughts.

We saw a long time ago in my hypothesis on TRH, that the US military is developing a TRH nasal spray to reduce the suicide rate in soldiers returning from combat.  A homemade version of this nasal spray was used for years by a US doctor/author to treat various neurological disorders.

We do not need to worry about suicide and people with Strict Definition Autism (SDA), but they are highly prone to accidents like drowning, caused by a combination of being allowed to wander off unsupervised and not knowing how to swim confidently.


Medical Comorbidities

Autism has a long list of known medical comorbidities and not surprisingly they will show up as a cause of death.

By accurately treating a person’s autism, you will at the same time be treating some of their comorbid conditions.

For example, if you have a problem with calcium channels (like Cav1.2) in your brain, you should not be surprised to have problems in other parts of the body where they are heavily expressed, so the heart and pancreas for Cav1.2.

The medical comorbidities are indeed a valuable tool to identify the possible biological dysfunctions underlying a person’s autism.  Then you can treat them at the same time, with the same drug.


Bipolar and Schizophrenia

In the case of autism’s adult-onset big brothers, namely bipolar and schizophrenia, there is a reduction in life expectancy of 10-20 years.

By comparison, type 1 diabetes on average reduces life expectancy by 20 years.  But you do not have to be Mr/Ms Average; if you control your condition well and also improve insulin sensitivity (ALA, NAC, Cinnamon, Sulforaphane, Cocoa flavanols etc.) the future can be bright.

People with Bipolar or Schizophrenia have a high suicide risk, in common with Asperger’s, but they also have high levels of substance abuse, starting with smoking and alcohol and going up the scale.

The core biological dysfunctions in both Bipolar and Schizophrenia are studied and some evidence-based therapies exist, lying forgotten in the literature.


Sweden as a Model

The autism mortality statistics in this post are based on Swedish data.  Sweden is not typical.  Sweden is possibly the best country in the world to live in if you have a physical or mental disability.  It is remarkable inclusive and the less able are well looked after.  So if the data existed for other countries, it would very likely look even worse. 



Conclusion

I think quasi-science organizations, like Autistica, are not helping and just add to the public misunderstanding of autism.  It is highly complex, but a great deal is already understood.  

Better use should be made of what is already known. It cannot be adequately explained in tabloid TV, or a few sound bites.

Why don’t researchers/Institutes like the Karolinska Institute, Stockholm, pay up a couple of thousand dollars and make their excellent research open access? 

As we saw when we looked at Down Syndrome, life expectancy is a case of out of sight is out of mind.

What do Autistica think the age at death of someone with autism+MR/ID +epilepsy was in 1960?







In the Down Syndrome chart above, you just had to stop locking them up in institutions as babies, for them to have a better prognosis.

Since the 1970s, society no longer locks up toddlers with autism either, so now they live longer.  To live as long as other people, they need some help from science.

If you treat the underlying dysfunctions in people with autism, bingo they will live longer.  You do not need $15 million to figure that out.  You do need an open mind.