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Showing posts with label Lenalidomide. Show all posts
Showing posts with label Lenalidomide. Show all posts

Wednesday, 8 July 2020

Immune modulatory treatments for autism spectrum disorder


Need a wizard, or your local doctor?

I was intrigued to come across a recent paper on immune modulatory treatments for autism by a couple of doctors from Massachusetts General Hospital for Children.  The lead author has interests in:

·      Autism spectrum disorders
·      Psychopharmacology
·      Developmental Disabilities
·      Williams syndrome
·      Angelman syndrome
·      Down syndrome

Apparently, he is an internationally-recognized expert in the neurobiology and neuropsychopharmacology of childhood-onset neuropsychiatric disorders including autistic disorder.  Sounds promising, hopefully we will learn something new.

The paper is actually a review of existing drugs, with immunomodulatory properties, that have already been suggested to be repurposed for autism. The abstract was not very insightful, so I have highlighted the final conclusions and listed the drugs, by category, that they thought should be investigated further.

All the drugs have already been covered in this blog and have already been researched in autism.

One important point raised in the conclusion relates to when the drugs are used.  Autism is a progressive condition early in life and there are so-called “critical periods” when the developing brain is highly vulnerable.

For example, Pentoxifylline has been found to be most effective in very young children.  This does not mean do not give it to a teenager with autism, it just means the sooner you treat autism the better the result will be.  This is entirely logical.

Some very clever drugs clearly do not work if given too late, for example Rapamycin analogs used in people with TSC-type autism.

Multiple Critical Periods for Rapamycin Treatment to Correct Structural Defects in Tsc-1-Suppressed Brain

Importantly, each of these developmental abnormalities that are caused by enhanced mTOR pathway has a specific window of opportunity to respond to rapamycin. Namely, dyslamination must be corrected during neurogenesis, and postnatal rapamycin treatment will not correct the cortical malformation. Similarly, exuberant branching of basal dendrites is rectifiable only during the first 2 weeks postnatally while an increase in spine density responds to rapamycin treatment thereafter.  

Back to today’s paper.


The identification of immune dysregulation in at least a subtype ASD has led to the hypothesis that immune modulatory treatments may be effective in treating the core and associated symptoms of ASD. In this article, we discussed how currently FDA-approved medications for ASD have immune modulatory properties.

“Risperidone also inhibited the expression of inflammatory signaling proteins, myelin basic protein isoform 3 (MBP1) and mitogen-activated kinase 1 (MAPK1), in a rat model of MIA. Similarly, aripiprazole has been demonstrated to inhibit expression of IL-6 and TNF-α in cultured primary human peripheral blood mononuclear cells from healthy adult donors.”

We then described emerging treatments for ASD which have been repurposed from nonpsychiatric fields of medicine including metabolic disease, infectious disease, gastroenterology, neurology, and regenerative medicine, all with immune modulatory potential. Although immune modulatory treatments are not currently the standard of care for ASD, remain experimental, and require further research to demonstrate clear safety, tolerability, and efficacy, the early positive results described above warrant further research in the context of IRB-approved clinical trials. Future research is needed to determine whether immune modulatory treatments will affect underlying pathophysiological processes affecting both the behavioral symptoms and the common immune-mediated medical co-morbidities of ASD. Identification of neuroimaging or inflammatory biomarkers that respond to immune modulatory treatment and correlate with treatment response would further support the hypothesis of an immune-mediated subtype of ASD and aid in measuring response to immune modulatory treatments. In addition, it will be important to determine if particular immune modulating treatments are best tolerated and most effective when administered at specific developmental time points across the lifespan of individuals with ASD.


Here are the drugs they listed:-

1.     Metabolic disease

Spironolactone
Pioglitazone
Pentoxifylline

Spironolactone is a cheap potassium sparing diuretic. It has secondary effects that include reducing the level of male hormones and some inflammatory cytokines.

Pioglitazone is drug for type 2 diabetes that improves insulin sensitivity.  It reduces certain inflammatory cytokines making it both an autism therapy and indeed a suggested Covid-19 therapy.

Pentoxifylline is a non-selective phosphodiesterase (PDEinhibitor, used to treat muscle pain.  PDE inhibitors are very interesting drugs with a great therapeutic potential for the treatment of immune-mediated and inflammatory diseases.  Roflumilast and Ibudilast are PDE4 inhibitors that also may improve some autism.  The limiting side effect can be nausea/vomiting, which can happen with non-selective PDE4 inhibitors.

I did try Spironolactone once; it did not seem to have any effect.  It is a good match for bumetanide because it increases potassium levels.

I do think that Pioglitazone has a helpful effect and there will be another post on that.

PDE inhibitors are used by readers of this blog. Maja is a fan of Pentoxifylline, without any side effects. Roflumilast at a low dose is supposed to raise IQ, but still makes some people want to vomit. The Japanese drug Ibudilast works for some, but nausea is listed as a possible side effect.


2.     Infectious disease

Minocycline
Vancomycin
Suramin

Minocycline is an antibiotic that crosses in to the brain.  It is known to stabilize activated microglia, the brain’s immune cells.  It is also known that tetracycline antibiotics are immunomodulatory.

Vancomycin is an antibiotic used to treat bacterial infections, if taken orally it does not go beyond the gut.  It will reduce the level of certain harmful bacteria including Clostridium difficile.

Suramin is an anti-parasite drug that Dr Naviaux is repurposing for autism, based on his theory of cell danger response.
  

3.     Neurology

Valproic acid

Valproic acid is an anti-epileptic drug.  It also has immunomodulatory and HDAC effects, these effects can both cause autism when taken by a pregnant mother and also improve autism in some people.

Valproic acid can have side effects. Low dose valproic acid seems to work for some people. 


4.     Gastroenterology

Fecal microbiota transplant (FMT)

FMT is currently used to treat recurrent Clostridium difficile infection and may also be of benefit for other GI conditions including IBD, obesity, metabolic syndrome, and functional GI disorders.

Altered gut bacteria (dysbiosis) is a feature of some autism which then impairs brain function.  Reversing the dysbiosis with FMT improves brain function.  


5.     Oncology

Lenalidomide
Romidepsin
  
Lenalidomide is an expensive anti-cancer drug that also has immunomodulatory effects.

Romidepsin is a potent HDAC inhibitor, making it a useful cancer therapy.  HDAC inhibitors are potential autism drugs, but only if given early enough not to miss the critical periods of brain development. 


6.     Pulmonology

N-acetylcysteine

Many people with autism respond well to NAC. You do need a lot of it, because it has a short half-life.


7.     Nutritional medicine and dietary supplements

Omega-3 fatty acids
Vitamin D
Flavonoids

Nutritional supplements can get very expensive.  In hot climates, like Egypt, some dark skinned people cover up and then lack vitamin D.  A lack of vitamin D will make autism worse.

Some people with mild brain disorders do seem to benefit from some omega-3 therapies.

Flavonoids are very good for general health, but seem to lack potency for treating brain disorders.  Quercetin and luteolin do have some benefits. 


8.     Rheumatology

Celecoxib
Corticosteroids
Intravenous immunoglobulin (IVIG)


Celecoxib is a common NSAID that is particularly well tolerated (it affects COX-2 and only marginally COX-1, hence its reduced GI side effects).

NSAIDS are used by many people with autism.

Steroids do improve some people’s autism, but are unsuitable for long term use.  A short course of steroids reduces Covid-19 deaths – a very cost effective therapy.

IVIG is extremely expensive, but it does provide a benefit in some cases. IVIG is used quite often to treat autism in the US, but rarely elsewhere other than for PANS/PANDAS that might occur with autism.


9.     Regenerative medicine

Stem cell therapy

I was surprised they gave stem cell therapy a mention. I think it is still early days for stem cell therapy.


Conclusion

I have observed the ongoing Covid-19 situation with interest and in particular what use has been made of the scientific literature.

There are all sorts of interesting snippets of data. You do not want to be deficient in Zinc or vitamin D, having high cholesterol will make it easier for the virus to enter your cells.  Potassium levels may plummet and blood becomes sticky, so may form dangerous clots. A long list of drugs may be at least partially effective, meaning they speed up recovery and reduce death rates. Polytherapy, meaning taking multiple drugs, is likely to be the best choice for Covid-19.

Potential side effects of some drugs have been grossly exaggerated, as with drugs repurposed for autism.  Even in published research, people cheat and falsify the data. In the case of hydroxychloroquine, the falsified papers were quickly retracted.

The media twist the facts, to suit their narrative, as with autism.  This happens even with Covid-19. Anti-Trump media (CNN, BBC etc) is automatically anti-hydroxychloroquine, and ignores all the published research and the results achieved in countries that widely use it (small countries like China and India). 

Shutting down entire economies when only 5-10% of the population have been infected and hopefully got some immunity, does not look so smart if you are then going to reopen and let young people loose.  They will inevitably catch the virus and then infect everyone else. Permanent lockdown restrictions, if followed by everyone, until a vaccine which everyone actually agreed to take, makes sense and living with the virus makes sense, but anything in between is not going to work. After 3 months without any broad lockdown, and allowing young people to socialize, most people would have had the virus and then those people choosing to shield could safely reemerge. The death rate with the current optimal, inexpensive treatment, as used in India or South Africa is very low, in people who are not frail to start with. Time to make a choice.  Poor people in poor countries cannot afford to keep going into lockdown, they need to eat.

What hope is there for treating a highly heterogeneous condition like autism, if it is not approached entirely rationally and without preconceptions and preconditions?  In a pandemic we see that science does not drive policy and translating science into therapy is highly variable.  The science is there for those who choose to read it.

I frequently see comments from parents who have seen some of the research showing that autism has an inflammatory/auto-immune component.  They ask why this has not been followed up on in the research.  It has been followed up on.  It just has not been acted upon.

Why has it not been acted on?

This missing stage is called “translation”.  Why don’t doctors translate scientific findings into therapy for their patients?

What is common sense to some, is “experimental” to others. “Experimental” is frowned upon in modern medicine, but innovation requires experimentation.

Many people’s severe autism is unique and experimental polytherapy/polypharmacy is their only hope.

The cookie cutter approach is not going to work for autism. 

Thankfully, for many common diseases the cookie cutter approach works just fine.

Do the authors of today’s paper, Dr McDougle and Dr Thom, actually prescribe to their young patients many of the drugs that they have written about?  I doubt it and therein lies the problem.  

Time for that wizard, perhaps? 

A few years ago I did add the following tag line, under the big Epiphany at the top of the page. 

An Alternative Reality for Classic Autism - Based on Today's Science

You can choose a different Autism reality, if you do not like your current one.  I am glad I did. I didn't even need a wizard.  

There are many immuno-modulatory therapies for autism that the Massachusetts doctor duo did not mention, but it is good that they made a start.








Thursday, 20 March 2014

Dr Chez’s Trial of Lenalidomide, a TNF- α and IL-6 Inhibitor in Autism


 

An interesting trial of a TNF- α and IL-6 inhibitor in autism has been brought to my attention.  It was by Michael Chez, the neurologist from Sacramento, who has made several appearances on this blog.
By coincidence, a copy of his book arrived this week.  The book is called “Autism and its Medical Management”, Chez is one of the few mainstream doctors who does try and treat autism.  The book is rational, readable and in no way radical, so you could show it to your family doctor without upsetting him/her.  Chez does particularly focus on distinguishing regressive from non-regressive autism, as do I. His view is that it is regressive autism, even if it was regression from slightly abnormal.  The important part is that some learned skills, like language, were lost sometime after 12 months of age.  He believes that regressive autism has a different basis to non-regressive autism; he has his own ideas about this, but he admits there is no concrete proof.

The book is a few years old and Chez has published much work in the intervening few years.    
The paper I was referred to is:-


Lenalidomide, an analogue of thalidomide, has the potential to invoke significant changes in TNF-α and other immunomodulatory cytokines.  If thalidomide sounds familiar, it is the drug from the 1950s, that turned out to be very unsafe for use in pregnant women and around the world 10,000 babies were born with malformation of the limbs.

Lenalidomide has been used to successfully treat both inflammatory disorders and cancers in the past 10 years. There are multiple mechanisms of action.  It is extremely expensive, according to NICE:-

“Lenalidomide 25 mg capsules cost £4368 per 21 capsules (excluding VAT; ‘British national formulary’ [BNF] edition 55). Dosage is continued or modified based upon clinical and laboratory findings. For example, if lenalidomide is continued for ten 28-day cycles without dose reduction, the cost would be £43,680.”
 
Dr Chez does not mention the cost of Lenalidomide, but he uses a tiny dose of 2.5 mg; This would cost £20, or $30, a day.  This might also explain the small number (7) of participants in the trial.
 
“2.2. Drug and Dosing. Lenalidomide 2.5mgs was given daily
for 12 weeks. This low dose was selected to minimize the risk
of adverse effects. In addition, because this was a pilot study,
the goal was to test the lowest dose that could potentially lead to improvements.”
 
The drug did reduce TNF-α levels and there were some behavioral improvements, but nothing dramatic.  Perhaps a higher dosage would have had a greater effect?
 
There were only seven participants and the data on the seven is not complete; also the dose of Lenalidomide was very low.  I think it is really only fair to conclude that the trial is interesting but that a much cheaper drug would need to be found and tested on a much larger number of participants.

“Despite the limitations, to our knowledge, this open-label study represents the first attempt to treat autism by specifically targeting elevated innate inflammatory cytokine levels. Safety monitoring and pharmacokinetic data were successfully completed during this pilot study and exploratory observations of clinical and cytokine changes suggest a trend towards improvement. Correlating treatment outcomes with cytokine level changes may be a target in future autism spectrum treatment, especially in those with known maternal or postnatal immunological risk factors. Larger blinded and placebo-controlled studies assessing cytokine measurement and cytokine-targeted treatment in autism patients with TNF-α or other inflammatory cytokine elevation are warranted.”

To his credit, unlike the researchers in Athens who trialed Neuroprotek in a recent post, Chez went about his pilot study in a scientific manner and collected both the biological and the behavioral data.  In other words, he measured the before and after levels of the inflammatory cytokines and the before and after behavioral rating scales.  Well done Dr Chez.