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Showing posts with label Ibuprofen. Show all posts
Showing posts with label Ibuprofen. Show all posts

Thursday, 24 May 2018

An Autism Case History - EpiphanyASD in a Pill





It is not quite that easy!


Initials:                        LT
Age:                           14 years old

Year
of Birth:              2003

Sex:                            Male

Date:                           24 May 2018

Diagnosis      
LT was diagnosed with autism in January 2007, at a multi-disciplinary assessment in London, at the age of 3 years 6 months.  At that time, LT was non-verbal but had some emerging vocalization. No tics, no seizures, no unusual physical features, no self-injury, no sleep disorder, no feeding disorder. Toilet trained. Very limited attention span. No imaginative play. Liked to jump.

IQ not tested.
No CARS (Childhood Autism Rating Scale) assessment.
TEACCH and PECS were recommended as therapy.
Further medical testing or referrals – none recommended (standard practice in the UK) 

LT has an older brother who is intelligent, multilingual and highly social.
Comorbidities
GI disease:                   None
Epilepsy:                       None
Asthma:                        Yes, mild asthma from early childhood
Allergy:                         Pollen
Sleep disorder:             None 

General Health          
Very healthy and almost never ill. When visiting his GP at the age of 14 the doctor commented how she had not seen him for three years, whereas she has seen his older brother twice a year.

Born via a planned caesarean section, without complications, APGAR score was 10.


Growth                      
Body is well proportioned, no obvious macro/microcephaly. No physical features of any syndromes/metabolic anomalies.

However, LT was initially on the 90th percentile for height and dropped to the 20th by the time he was 5 years old. He was a very muscular baby.  At the age of 10 his bone age (X ray of left hand) was estimated to be two years delayed.  IGF-I was normal, FT3 was slightly above the reference range.

At birth he fitted the research description of hyperactive pro-growth signaling pathways, even though there was no macrocephaly.

Regression at age 8              
Aged 8, a big regression took place with self-injurious behavior (SIB) and aggression to others. He would slam his head into walls, other people, car windows, punch himself etc, but he was still small enough to be physically controlled/restrained by larger adults. He could not be controlled by smaller/older adult family members.

This aggression could occur immediately on waking until finally falling asleep at night, it was not predictable.  At that time in the afternoons, LT had a male 1:1 assistant with experience from a school for severe autism and in the mornings a very firm-minded tall female 1:1 assistant. LT’s father imposed a policy of zero acceptance of any SIB, to avoid it becoming a permanent acquired behavior. SIB was physically blocked.
The regression was triggered by the departure of his long time full-time 1:1 female assistant. It was an emotional trauma.  Occasional visits from her just made the situation worse.  In response no drugs were used, just a consistent firm behavioral approach. Over a ten month period the situation slowly stabilized, but skills were lost and bad habits (SIB) were acquired.  LT subsequently did see his assistant again and sees her regularly to this day.
Throughout this time his classmates and teacher at school were remarkably understanding. He was never excluded from school. His assistant ensured nobody at school got hurt.
Since assistants will inevitably come and go, from the age of 8 LT has had two part-time assistants rather than one full time.  As and when subsequent assistants have left, he has not had any troubling emotional reaction. 

Summer-time raging and loss of cognitive function
Summertime raging with self injurious behavior and aggression to others developed from the age of 9.

Later it became clear that in addition there was a loss of cognitive function during the summer months. This became evident once it was possible to teach mental math, from aged 9 onwards.  For example, at the age of 11, simple verbal tasks like 7 x 8 = ?, that had previously been mastered, could not be answered in the summer months.

The raging and cognitive loss were ultimately treatable.

Winter-time raging

Summertime raging was resolved and then winter-time raging developed. This was traced back to the cytokines released to signal reabsorption of milk teeth roots (a proves that takes months) and the eruption of permanent teeth. It was not tooth ache, i.e. pain. LT has retarded bone age and apparently this applied to his teeth development as well.

He lost his later milk teeth always in the winter.

The winter time raging did not respond to his summertime therapy, but responded very well to a low dose of ibuprofen. Summertime raging does not respond to Ibuprofen 

PANS-like episode aged 13
At Christmas time, following a minor viral infection, LT developed acute onset profound verbal tics. LT does not have Tourette’s type autism and had never exhibited such behavior previously. The tics were treated as a PANS/PANDAS flare-up with 5 days of prednisone. Over a two week period the tics faded away and have never returned.

Intellectual disability 
IQ was never measured, LT’s ABA consultant said there was no point, but the very much more rigorous ABBLS was completed, see below. Evidently, prior to pharmacological treatment at the age on 9, there was a 5 year developmental delay.
With hindsight, IQ pre-treatment was probably in a similar range to Down Syndrome (DS) meaning less than 70.

At the age of 14, LT’s academic performance now puts him in the top half of his class of 12 year old neurotypical peers. His grades are mainly As, with maths and computing being particular strengths. 

Other testing:    No genetic testing, MRI or EEG.

Family History:          

LT has a 7 years younger, very distant cousin who is non-verbal with autistic disorder. They have shared great great great maternal grandparents. The cousin has parents who are both doctors and were high academic achievers as medical students.

The father’s family has a large number of Cambridge-educated doctors on both the grandmother's and grandfather's side; one gave his name to the scale still used to assess severity of Ulcerative Colitis and helped develop the first H2 anti-histamine drug. The father and uncle are engineering graduates from top universities. One distant cousin was a math’s protégé at Oxford University.  One distant cousin has bipolar. One uncle has type-1 diabetes.

The mother is an academic alpha female in a stressful creative profession. The maternal grandmother was a teacher and grandfather was an army Colonel.
The maternal grandmother and her children all had premature hair greying, which may be linked to Bcl-2 expression and Wnt signaling, both implicated in autism. Thickness and greying of hair share biological mechanisms, which overlap with those controlling development of dendritic spines. LT and his father have very dense hair, mother has thin hair.
Maternal grandparents both smoked and the grandfather has COPD (Chronic Obstructive Pulmonary Disease). Oxidative stress is a core feature of COPD, because anti-oxidant genes are silenced; these effects are known to be heritable via epigenetic tags. 
The family fits the high IQ  type of autism (some autism genes are linked to intelligence and some bipolar genes are linked to creativity, which helps explain why some actors/artists are bipolar) with oxidative stress raised during pregnancy, anti-oxidant response possibly weakened, no oxytocin surge during delivery and no microbiota transfer at birth (C-section delivery).  No pets at home during pregnancy (a good source immuno-stabilizing bacteria).  No obesity in the family.

Education
LT has attended the same mainstream international school, following the English curriculum, since the age of 3. Class sizes are very small, about 12 pupils. From the age of 4 he has had a 1:1 assistant eight hours a day, throughout the year.
LT commenced a parent-managed ABA (Applied Behavioral Analysis) inspired home program shortly after diagnosis.  Both parents attended a 2 day training program to learn the use of PECS (Picture Exchange Communication System).  PECS was applied and shortly thereafter LT became partly verbal at the age of 4, speaking single words.
1:1 assistants were recruited mainly from the local University and trained to apply ABA, with elements from Floortime and the Canadian Hanen Program. There was some supervision from US-trained Behavioral Consultants that would fly in for training. A large collection of specialist training material was acquired from the US. 
Extensive use was made of professional (i.e. expensive) special needs language teaching software (Laureate Learning) from the age of 4 until 8 years old.
Later, web-based reading software (Headsprout) was used and years later special maths teaching software (Math Wizz). Neither are made for special needs, but both are very compatible with an ABA approach.
LT spent an extra year in kindergarten and in primary/junior school was held back 2 years at the age of 9, following a request from the parents.
In primary school (English system) he went Year 1, Year 2, Year 3 (started bumetanide) then back to Year 2, then Year 3, Year 4, Year 5, Year 6 and currently attends Year 7 in secondary/high school
The equivalent in the US system would have been, he went K, 1st, 2nd, then 1st, 2nd 3rd, 4th etc.
From the age of 13, LT attended school full time, prior to that he attended only the morning and then went home after lunch to work 1:1 with his assistant for three hours.
During school holidays LT has a 1:1 home learning program.
LT learnt to read and write at home as result of the unrelenting efforts of his assistant. He started to learn maths from the age of 8, prior to that he could not master the basic concepts, or understand the relevant vocabulary.
From the age of 9, LT has been able to keep up with his new peer group at school, two years his junior.
At the age of 14, in a class with 12 year old neurotypical children, LT takes the same assessments as the rest of the class and his grades currently place him in the top half of the class. He is now particularly good at things like arithmetic, algebra, coordinates, spelling and has neat handwriting (very unusual in autism). He is still clearly autistic and his speech is limited to what he wants to say; there is no small talk.
LT started to learn the piano aged 8. He progressed from an extremely basic level and a desire to hit his teacher to his current level 4 of the popular Faber Music piano course (there are just 5 levels). When he plays in public people are very surprised, he does not play like someone with any cognitive impairment. His peers as school have asked “how can he play like that?” 

Motor Skills
Like many people with classic autism LT had problems with both fine and gross motor skills as an infant. After a great deal of 1:1 therapy, motor skills are now normal.
LT started to learn to ski at the age of 5 with a special needs instructor. Progress was initially slow, but 9 years and one broken collar bone later, LT can confidently ski on red slopes and deal with all the various types of lifts you encounter in the Alps.
Stamina improved considerably after starting to take Agmatine, which is evident at school where they are timed to run 2.5 km (1.5 miles) and when swimming.

Behavioral Treatment (age 3- 8)
From diagnosis aged three, until nine years old, therapy was exclusively based on behavioral interventions. Extensive use of ABA (Applied Behavioral Analysis) and VB (Verbal Behavior) with 40 hours a week with a 1:1 Assistant.
At the aged of 9, LT had mastered almost all the skills in the very extensive ABBLS (Assessment of Basic Language and Learning Skills) assessment. The language skills and other basic learner skills that are tracked by this tool are those that are acquired by most typically developing children by the time they reach four to five years of age. LT’s elder brother had acquired these while he was three years old.
LT’s skill acquisition to the age of eight was seen by the ABA consultants as nothing unusual in someone with classic autism. There was slow but continuous progress. 
All learning was taking place at home with school attended mainly for socialization.

Pharmacological Treatment (age 9 onwards)
In late 2012 a small clinical trial was published by Ben Ari and his clinical associate Lemmonier; it showed the benefit of the NKCC1/2 blocker bumetanide in autism. This paper was studied by LT’s father and contact has been maintained for several years with Dr Ben Ari, who originated and patented this therapy.
Bumetanide (1mg per day) was commenced just before Christmas December 2012, unknown to the school, or LT’s assistants.
On returning to school in January 2013 the Head Teacher summoned LT’s father and asked what had happened to LT. He was “so joyous” and “like a different child”.
At the suggestion of his original ABA consultant, LT’s father had been asking LT every school day for 5 years “what did you have for lunch at school today?”. The usual answer would be no answer, the wrong answer, but sometimes a brief correct answer. From now on LT would say precisely what he had eaten “peas, potatoes and chicken – cake for dessert”. The assistant was there to confirm what had really been eaten for lunch. 
LT’s 1:1 assistant at that time described the effect of bumetanide as making him “more present”. Since his assessment at the age of 3, it was always noted that LT had a very short attention span and would not be able to focus on the class teacher for more than a couple of minutes. LT was never hyperactive, quite the opposite. He was physically present but not mentally.
Later on it would be realized that the most potent effect of long term bumetanide use in strictly defined autism (SDA) is enhanced cognition, which leads to accelerated acquisition of new skills.  IQ has long been seen as the best predictor of more favorable outcomes in autism.  
Bumetanide use has continued for five years, with occasional pauses to confirm it still works.  Different doses were tested and currently the dose is 2mg once a day.
When stopping bumetanide for a week and returning to his web-based maths learning program, LT was unable to complete previously mastered tasks, no matter how many times he tried. Having recommenced bumetanide, the same maths problems were attempted a week later and could be solved. 
Blood potassium levels were checked regularly at the beginning, but were always high normal (5.0 mmol/L).  Bumetanide is taken with 250mg of K+ per 1mg of bumetanide. Diet is rich in potassium, with bananas and other fruit.
Dehydration, another potential problem, is entirely self-regulated with LT drinking more water. Total consumption is 2.5 to 3 liters per day.
Diuresis occurs mainly within one hour of taking bumetanide and has never caused a problem at home or school. LT takes his bumetanide at least an hour before leaving home for school.
Bumetanide’s suggested mode of action is lowering intracellular chloride via blocking NKCC1 cotransporters in the brain.  Bumetanide crosses the blood brain barrier very poorly and many researchers are dubious it can have any effect. Bumetanide is a partial solution.
A new drug is being developed by Dr Ben Ari that will cross the blood brain barrier more effectively than bumetanide and have less effect on NKCC2, so producing less diuresis.
An alternative strategy discussed in the literature is to improve the pharmacokinetics of bumetanide, by slowing its excretion via OAT3 (organic anion transporter 3) and thus increasing plasma concentration. There are many OAT3 inhibitors, the best known and most potent is probenecid, used to treat gout by increasing the excretion of uric acid. Some foods are OAT3 inhibitors. One readily available substance is chlorogenic acid (more precisely 1,3- and 1,5-dicaffeoylquinic acid) which is sold as a coffee-based weight loss supplement. Interestingly, coffee, but not caffeine, has been shown to reduce the risk of gout.
Little is known about exactly how bumetanide is transported/excreted across the blood brain barrier.
Bumetanide’s autism benefit appears to be from lowering intracellular chloride and hence making GABAA become more inhibitory. Excitatory-Inhibitory (E/I) imbalances are widely believed to be at the core of autism.  An E/I imbalance during so-called Critical Periods, will result in permanent changes to the developing brain, nonetheless it appears that correcting an E/I imbalance in later years can still be highly beneficial, though not curative. 
Another experimental therapy also makes GABAA become more inhibitory. This uses very low doses of clonazepam to modify the behavior of GABAA receptors that contain the α3 sub unit.  In LT the effective dose of clonazepam is just 0.03mg, which might be considered sub-clinical, but as predicted by Professor Catterall, it does have a beneficial effect (a bumetanide-like effect). It has no side effects and there is no tolerance develops at this tiny dose, after four years of use.
At the time low dose clonazepam was introduced, LT would go swimming at 5pm most days. He was not really interested to do much independently in the water, he was very passive. This passive behavior was notably changed once the effective clonazepam dose had been found. He became more like a typical child playing in a swimming pool. Instead of sitting on the steps he wanted/demanded interaction/play with the attending adult.  The effect was not as profound as that seen in the first months of bumetanide, but noticeable nonetheless.
After 4 years of bumetanide the effect was still there, but there was a desire to accelerate skill acquisition to keep up with neurotypical school peers.
A new strategy was adopted to further reduce intracellular chloride, this time using a method first documented in the 1850s, when potassium bromide (KBr) was used to treat epilepsy. Reading old case studies from Great Ormond Street Hospital in London it appeared to LT's father that some children with epilepsy, MR/ID and undiagnosed autism improved behaviorally and developed age-appropriate play when treated with KBr. Lack of age-appropriate play is a hallmark of autism.  Modern research shows that bromide ions compete with chloride ions to enter cells and the result is a lower intracellular concentration of Cl-. The limiting factor in the use of KBr is that it increases mucous secretions and so causes acne (and can make asthma worse), in a dose dependent fashion. At a low dose of 400mg per day there is a cognitive gain without significant spots. KBr is still used at high doses to treat pediatric epilepsy in Germany and Austria. Some leading US neurologists regret they cannot prescribe it; technically they could ask the FDA for permission on a patient by patient basis.

Another strategy to reduce intracellular chloride is to target chloride ions that enter neurons via the AE3 exchanger, this is possible using Acetazolamide (Diamox). This therapy does seem to work for some people, but was not tolerated by LT, it caused reflux.
KBr has a very long half-life and so it takes 4-5 weeks to reach the maximum effect. 
Bumetanide took about two weeks to lower chloride and show behavioral and cognitive improvements.
Low dose clonazepam takes three days, as was predicted by its half-life.
The cognitive loss in severe autism has parallels with that in Down Syndrome (DS). Bumetanide has been patented as a therapy for DS by Ben Ari, based on the results from mouse studies.
In mouse models of Down Syndrome both a negative allosteric modulator and a selective inverse agonist of α5 sub-unit of the GABAA receptor improve cognition. 
Mouse research has shown that poor learners have greater GABRA5 expression than good learners and that in mice GABRA5 expression can be normalized by eating cinnamon, or its metabolite sodium benzoate (NaB); this makes a poor learner become a good learner, at least in mice.
So it may be that increasing the effect of α3 sub-unit of the GABAA and reducing the effect of the α5 sub-unit of the GABAA can both improve cognition. For the moment the latter remains unproven. NaB is an approved food additive, E211. Ceylon cinnamon, which is safe for long term consumption, is metabolized to NaB. People who are histamine intolerant have to avoid DAO inhibitors such as cinnamon and NaB. 

Summertime raging and loss of cognitive gains
From the aged of 8 it became apparent that summer provoked behavioral deterioration. At this point there was no obvious allergy, but behavior improved when moving to the mountains in summer. At first, OTC mast cell stabilizers were investigated; some common H1 antihistamines are partial mast cell stabilizers. Rupatadine, azelastine, ketotifen, loratadine and cetirizine were all tried, as was the flavonoid quercetin.
Some of the above did indeed help reduce the summertime self injury, but not to a satisfactory level.
A final solution was found in a small dose of the Cav1.2 blocker, verapamil. 
When mast cells degranulate, one step requires activation of an L-type calcium channel. This is why most mast cell stabilizers are actually calcium channel blockers.
It should be noted that mutation in the CACNA1C gene, which encodes the Cav1.2 ion channel, leads to a severe kind of autism called Timothy Syndrome. Because Cav1.2 is widely expressed in the heart those affected have a very poor prognosis.
In addition, verapamil blocks the potassium ion channel Kv1.3.  Potassium channels, Kv1.3 and KCa3.1, have been suggested to control T-cell activation, proliferation, and cytokine production. Kv 1.3 is widely regarded as a therapeutic target for immunomodulation in autoimmune diseases.  Research has shown that peptides from parasitic worms that suppress the body's immune response do so by blocking Kv1.3. A drug therapy based on these peptides is being developed.
Verapamil also upregulates autophagy, which is impaired in many neurological disorders, such as Huntington’s. Lack of autophagy has been linked to the synaptic pruning deficits found in autism.
Verapamil has a short half-life of about 3 hours. Only a small dose is required to prevent the onset of SIB and the preceding agitation (described by LT as “spray the fire in my head”).
From the age of 10, LT’s summertime raging has been treated with 40-80 mg of Verapamil split into 2-3 doses from May until late November.
On the occasions that he has missed his 1pm dose in the peak allergy period, he has repeatedly developed aggression and self-injury by 4 or 5pm.
When he has taken verapamil there has never been any aggression and or self-injury.
Once self-injury was removed as a concern, learning progressed during the long summer school holidays. It became clear that during summer cognition was reduced as if bumetanide was no longer working.
It has been shown that the expression KCC2, the cotransporter that allows Cl- to leave neurons is affected by inflammatory cytokines like IL-6. It therefore appears plausible that the histamine and IL-6 released directly and indirectly by mast cell degranulation was causing an increase in neuronal Cl- and thus undoing the good work being done by bumetanide. Inflammation also increases α5 GABAA receptor activity and can thus reduce cognitive function.
At this point, the bumetanide dose was raised from 1mg once a day to 2mg in the morning and on occasion 1mg in the late afternoon.
The combination of an increased dose of bumetanide and the use of verapamil, cetirizine and azelastine has produced a very favorable result (no SIB and minimal summertime cognitive decline). Perhaps of note is that cetirizine is an eosinophil stabilizer, which may also be helpful and not just for asthma.
OTC therapies that have a helpful effect in summer are L-histidine, curcumin and L. reuteri DSM 17938 (sold as Biogaia Protectis). The amino acid histidine is a precursor to histamine and it seems that the body’s feedback loops can be tricked into not degranulating mast cells by slightly increasing the level of circulating histidine. The immunomodulatory effects of L. reuteri DSM 17938 have been well studied; the effect however does not continue after prolonged use. Curcumin is a very widely studied natural substance that performs much better in vitro than in vivo, due to very poor bioavailability. Modified versions of curcumin have been developed and there is a marginal benefit. Histidine is extremely cheap and easy to administer. Modified curcumin and L. reuteri are quite expensive.
It is reported by others that at a higher dose verapamil is as effective as an H1 antihistamine in treating allergy. 

IPR3
It appears that aberrant calcium channel signaling is a key feature of much autism. Gargus has suggested that IP3R is a nexus for different dysfunctions that lead to autism. IP3R controls the release of calcium stored within cells (the endoplasmic reticulum).
Excessive calcium within cells is known to be damaging. L-type calcium channels that remain open will raise intracellular calcium and the same is true with IP3R. Caffeine can be used to inhibit calcium release via IP3R.
Gargus has not proposed an IP3R therapy.  


RORα

RORα is another proposed nexus where different dysfunctions  that lead to autism may converge. One potential RORα agonist is estradiol.  We know that in much autism there is elevated testosterone and reduced estradiol; we also know that estrogen receptor beta is under-expressed. Estradiol is known to be highly neuroprotective and may help protect females from developing autism. Females lacking in estradiol, for example in Turner Sydrome, may exhibit features of autism. A logical therapy would be to either use estrogens, or reduce testosterone (effectively the same thing). Ideally you would do this just in the brain; a brain selective pro-drug of estradiol, called DHED, actually exists. Less ideal therapies range from estradiol itself, to phytoestrogens or a high soy diet, to drugs reducing testosterone, like spironolactone; these will have effects beyond the brain.

Wintertime raging
Having solved summertime raging, wintertime raging appeared. As expected, verapamil had no effect.
Ultimately the likely trigger was traced back to the very slow loss of milk teeth and eruption of permanent teeth. Both reabsorption of roots and the eruption new teeth is signaled using pro-inflammatory cytokines.
Moderate use of Ibuprofen, as and when behavior began to deteriorate, resolved the problem. Ibuprofen has no effect on summertime raging.

PANS-like episode aged 13
PANS (Pediatric Acute-onset Neuropsychiatric Syndrome) and PANDAS (Pediatric Autoimmune Neuropsychiatric Disorders Associated with Streptococcal Infections) are infection-induced autoimmune conditions that disrupt a patient’s normal neurologic functioning, resulting in a sudden onset of Obsessive Compulsive Disorder (OCD) and/or tics and cognitive loss.
The import part is acute-onset; behavior changes overnight.
LT exhibits the classic traits of autism including stereotypy/stimming but never tics, which are a feature of Tourette’s-type autism.
Just before Christmas LT was recovering well from what presented as mild viral infection that had not warranted any medical intervention. He suddenly developed very loud verbal tics.
It is well known in PANS that delayed treatment severely affects prognosis. The sooner the patient is treated, the more complete recovery will be. Diagnosis is based on a very specific set of laboratory tests, only available in the US.
LT was treated from the third day of the tics as if he had PANS flare-up. He was treated with 40mg of prednisone for 5 days, requiring no taper.
Over a two week period the tics faded away. There have been no more tics.

Use of antioxidants
A recurring feature in autism research is oxidative stress. Two clinical trials have shown the benefit of the antioxidant NAC (N-acetylcysteine) in autism.
In LT the effect of NAC is the immediate disappearance of stereotypy and a type of anxiety. Without NAC, LT always wants to know what is happening next, to the point of obsession.
Oxidative stress has been shown to vary throughout the day and LT’s therapy is tailored to match it. Oxidative stress causes a cascade of further disruptions and causes many of the side effects of type-1 diabetes, for example.
LT takes 2,400 mg of NAC per day (a dose slightly lower than in the clinical trials). He has 600mg immediate release NAC at 7am, 600mg sustained release at 7am and then 600 mg sustained release at 1pm and 5pm. 
There have been no side effects after more than 4 years. 

Anti-inflammatory
Numerous studies (e.g. Ashwood) show elevated pro-inflammatory cytokines and reduced  anti-inflammatory cytokines as a feature of autism; but specific subgroups exist. Activated microglia is another feature of autism, which also suggests chronic inflammation.
Numerous anti-inflammatory strategies have been researched.
Atorvastatin has potent anti-inflammatory effects that are very well studied. It also affects the autism/cancer proteins RAS, PTEN and BCL2.
RASopathies are associated with MR/ID and indeed autism. Mutations in PTEN generally cause loss of function in PTEN and are associated with macrocephaly, enlarged corpus callosum, MR/ID and autism. Loss of function of PTEN is also found in some cancers, for example prostate cancer.
Because autism is polygenic and hundreds of genes are over/under expressed, it is not necessary to have a mutation to have misexpression. The mutation is just the extreme case (be it Cav1.2 or PTEN).
The effect of Atorvastatin is visible from the first dose and fades away the next day if therapy is stopped. The effect is very specific, it releases cognitive inhibition; it is as if the person with autism has the desire and capability to do something, but some barrier prevents him from doing it.
In broader severe autism, this is very important, Why does a child with autism who can verbalize never speak?
At the age of 9, LT was having piano lessons at home twice a week. He would practice the piano only if his assistant or father sat beside him. He never played independently.
After taking 10mg Atorvastatin for the first time, the next day LT went himself to his piano and started playing, without any prompting of any kind. He then began to practice on a daily basis.
As a child aged 3, LT had the habit of coming to the entry of the room with the television and watching from around the corner of the wall. He wanted to watch but could not enter the room. At the time it was thought he somehow just liked the visual sensation of peering around corners.
When he later moved to a multi-level house, LT would not come downstairs by himself; he would wait at the top of the stairs for someone to lead him down, every morning.  With atorvastatin not only did this behavior disappear, but it reappeared the day after Atorvastatin was withdrawn.
During one test withdrawal of the treatment, he got “stuck” in the kitchen and could not leave the room.

Sulforaphane Nrf2 and HDAC
In 2014, and again in 2017, Talalay/Zimmerman published research that sulforaphane from broccoli showed a benefit in autism. Sulforaphane is an HDAC inhibitor and thus has potential epigenetic properties, like some cancer drugs. Sulforaphane may also activate the Nrf2 redox “switch” and so be protective in conditions associated with oxidative stress.
LT’s father did contact the researchers and shortly after the first research was published LT started to take a broccoli sprout supplement. It did produce a very obvious effect and within 30 minutes; LT was laughing so much, be went to look at himself in the bathroom mirror. The more general effect was an unmissable increase in speech.
After three years of use the positive effect of sulforaphane/broccoli is no longer visible, even trying alternative brands.
In the 2017 clinical trial the authors found one responder retained the benefit of sulforaphane after the trial ended. They suggest an epigenetic switch may have been activated.  

Mitochondria and Microvasculature
A distinct type of autism has been characterized by Kelley at Johns Hopkins, Autism Secondary to Mitochondrial Disease (AMD). Kelley suggests that almost all regressive autism is caused by mitochondrial dysfunction and usually deficiency of the rate-limiting complex 1.
By stabilizing the mitochondria with antioxidants and then trying to stimulate more complex 1, a gradual improvement can occur.
Mitochondrial disease effectively starves the brain and body of energy (ATP), so lack of exercise endurance is exhibited in people with a genuine mitochondrial dysfunction.
One feature of autism is that growth factors (BNDF, IGF-1, NGF, VEGF etc) are disturbed, but the disturbance varies greatly by the type of autism.  Vascular endothelial growth factor (VEGF) in particular and its receptors are known to be disturbed and this has implications for microvasculature. Studies suggest that unstable, rather than reduced blood flow occurs in autistic brains.
In sports medicine, exercise endurance is a key target and it can be raised by improving the energy production from mitochondria and by improving the circulation of blood throughout the body by targeting eNOS (Endothelial Nitric Oxide Synthase) and NO (Nitric Oxide).
In Mild Cognitive Impairment (MCI) studies have shown the benefit of improved cerebral blood flow using cocoa flavanols to indirectly affect NO and hence improve memory.
Studies show that eNOS and NO can be safely increased by Agmatine and NO can be increased  using L-citrulline, which then produced more L-arginine. These supplements are widely used by sportsmen and women.
A small dose of Agmatine (1 g) has a near immediate substantial effect on LT, making him far more energetic.  It moved him from being rather passive physically, to being active. This has been very evident from his performance at school during physical activities, where it has been widely noted. At home LT started trampolining before breakfast and late in the evening.

Sensory Overload and Sensory Gating
An apparent over-sensitivity to sensory stimuli is a common observation in autism and is often the precursor to behavioral problems. In some younger children these can be trivial, but in more severe autism it can produce profound behavioral problems that never fade away.
Hypokalemic sensory overload and hypokalemic periodic paralysis are described in the literature. LT had sound sensitivity as a young child, in particular an inability to cope with the sound of crying. Tests were carried out to establish whether LT’s tolerance to the sound of crying improved after oral potassium. He consistently tolerated a high volume of a recording of this sound, when played 20 minutes after 250mg of potassium. Following ABA, he was purposefully exposed to this sound and taught to understand why people cry and modify his response, to the extent that his response changed to laughter, which again has to be modified towards empathy. 
Aged 10, LT developed a phobia to traveling in elevators/lifts. This was because the elevator he regularly used to visit his Grandparents was the old-fashioned type, with an internal sliding gate that you close by hand, which is extremely noisy.  He refused to use the elevator from that point on.  People with autism very easily form habits, or are allowed to form them, following the path of least resistance.  Elevators are a part of modern life and hard to avoid.
After a few weeks of this behavior, LT was given 500mg of potassium and half an hour later willingly entered the elevator and coped with the ride. The behavior has never recurred.
Sensory gating is another common issue in autism and schizophrenia, the individual is not able to filter out repetitive background sounds, like a clock ticking or the sound of a noisy eater. Sensory gating can be measured by looking at the P50 response on an EEG. α7 nicotinic acetylcholine receptor (α7 nAChR) agonists, like nicotine, can correct impaired P50 gating. A low dose of a PDE4 inhibitor is another suggested therapy
LT does exhibit was presents as impaired P50 gating. It is really only evident when his pharmacological therapy is halted for a few days. Then he finds all kinds of unavoidable noises very annoying, even the sound of a person sitting next to him eating. 

Typical Psychiatric Drugs
LT has never been treated with any of the usual antipsychotics, stimulants, anti-depressants, or anti-anxiety drugs sometimes prescribed in autism. His use of clonazepam is at a dose far below its standard clinical use.

Current status
In September 2017 LT moved to secondary/high school where some of the teachers recall how he used to be 10 years previously. Initially there was some trepidation and the view by some that a boy with classic autism should not be there. The school does have a boy with Asperger’s. However, LT surprised his new teachers, achieving grades placing him in the top half of his class. He is now extremely attentive in class, no attention deficit anymore, and has clearly not reached his intellectual limit. He has likely already far surpassed his intellectual limit, had he remained untreated.
As the end of the first year of high school approaches, LT continues to keep up academically with his peers. His agmatine-boosted physical performance has been maintained and he competes very well in long distance running and swimming.
LT is still intellectually far away from the trajectory followed by his older brother, but LT is keeping up academically with many of his classmates who are neurotypical, with average IQs.
A significant number of people diagnosed very young with autism do indeed make dramatic progress by the age of 6.  Zappella proposed his Dysmaturational Syndrome that he says applies to about 6% of early childhood autism, but they all have Tourette’s type autism (with tics).   There is an additional group without tics that also achieve what Fein calls Optimal Outcome, essentially they lose their autism diagnosis. In total it is 10-15% of cases that seem to “get better” all by themselves, regardless of intervention. As more diagnosis takes place even before 2 years of age and autism threshold grows ever wider, Optimal Outcome may become even more common.  
The definition of autism has been greatly watered down in recent years (DSM3 to DSM5). LT started with DSM3-type autism and by the age of 8 he still had it. DSM5 autism includes very much milder variants, some of which are trivial.
Each therapy used by LT has been found to be reversible based on careful withdrawal trials.



People with strictly defined autism (SDA) start to acquire skills with a delay compared to NT peers and thereafter acquire skills at a slower rate and hence fall ever further behind, making inclusion at school a delusion. The aim is to have similar skills to NT peers to make inclusion effective.
People with SDA often leave high school with an educational level of a 7 to 10 year old.

From the age of 12, LT ceased having any autism-specific learning curriculum; he just follows the curriculum of his mainstream school.  

Anecdotal Evidence
LT’s piano teacher exclusively teaches people with disabilities (mainly severe autism and a few with Asperger’s) and so has great experience of the disorder. She says while she has taught people who learnt to play as well as LT does today, this has never happened before with a child who started in his kind of condition at 8/9 years old.
The American ABA consultant (with Ph.D. and 20 years of experience) knowing LT from the age of 8, before he started bumetanide, told the family that of all her clients, LT is the one she sees the least but has improved the most and how strange that is. 


Current Therapy

The current therapy, called the Autism PolyPill, may be found in the link below.  

https://epiphanyasd.blogspot.com/p/polypill-for-autism.html

Autism is a highly heterogeneous condition, but there appear to be broad sub-types. At least some people with an autism diagnosis respond to each individual therapy in the PolyPill. Some people respond to almost the entire combination of therapies; other people respond to none.


Future Therapy

Some other interesting therapies remain to be investigated and it is clear that more improvement is possible because short term therapy with the flavones nobiletin and tangeretin produces a marked change in cognition and behaviour. The effect only lasts two or three days.  Tangeretin is a PPAR gamma agonist, among other properties. It reduces cholesterol when used long term, but its autism benefit is transient.  

The ketone Beta-Hydroxy Butyrate (BHB) also looks interesting; it has epigenetic properties amongst its other effects. 






Friday, 3 June 2016

Mefenamic acid (Ponstan) for some Autism


Caution:-

Ponstan (Mefenamic Acid) contains a warning:-
Caution should be exercised when treating patients suffering from epilepsy.

At lower doses Ponstan is antiepileptic, but at high doses it can have the opposite effect.  This effect depends on the biological origin of the seizures.
In an earlier post I wrote about a paper by Knut Wittkowski who applied statistics to interpret the existing genetic data on autism. 


“Autism treatments proposed by clinical studies and human genetics are complementary” & the NSAID Ponstan as a Novel AutismTherapy




His analysis suggested the early use of Fenamate drugs could potentially reduce the neurological anomalies that develop in autism as the brain develops.  The natural question arose in the comments was to whether it is too late to use Fenamates in later life.

Knut was particularly looking at a handful of commonly affected genes (ANO 2/4/7 & KCNMA1) where defects should partially be remedied by use of fenamates.

I recently received a comment from a South African reader who finds that his children’s autism improves when he gives them Ponstan and he wondered why.  Ponstan (Mefenamic Acid) is a fenamate drug often used in many countries as a pain killer, particularly in young children.

Ponstan is a cheap NSAID-type drug very widely used in some countries and very rarely used in other countries like the US.  It is available without prescription in some English-speaking countries (try a pharmacy in New Zealand, who sell online) and, as Petra has pointed out, it is widely available in Greece.

I did some more digging and was surprised what other potentially very relevant effects Ponstan has.  Ponstan affects GABAA receptors, where it is a positive allosteric modulator (PAM).  This may be very relevant to many people with autism because we have seen that fine-tuning the response of the sub-units that comprise GABAA receptors you can potentially improve cognition and also modulate anxiety. 

Anxiety seems to be a core issue in Asperger’s, whereas in Classic Autism, or Strict Definition Autism (SDA) the core issue is often actually cognitive function rather than “autism” as such.

In this post I will bring together the science showing why Ponstan should indeed be helpful in some types of autism.

Professor Ritvo from UCLA read Knut’s paper and also the bumetanide research and suggested that babies could be treated with Ponstan and then, later on, with  Bumetanide.

Autism treatments proposed by clinical studies and human genetics are complementary



I do not think the professor or Knut are aware of Ponstan’s effect on GABA.

The benefits from Ponstan may very well be greater if given to babies at risk of autism, but there does seem to be potential benefit for older children and adults, depending on their type of autism.

Professor Ritvo points out that that Ponstan is safely used in 6 month old babies, so trialing it in children and adults with autism should not be troubling.

Being an NSAID, long term use at high doses may well cause GI side effects.  An open question is the dosage at which Ponstan modulates the calcium activated ion channels that are implicated in some autism and also what dosage affects GABAA receptors.  It might well be lower than that required for Ponstan’s known ant-inflammatory effects.


Ponstan vs Ibuprofen

Ibuprofen is quite widely used in autism.  Ibuprofen is an NSAID but also a PPAR gamma agonist.  Ponstan is an NSAID but has no effect on PPAR gamma.

Research shows that some types of autism respond to PPAR gamma agonists.

So it is worth trying both Ponstan and Ibuprofen, but for somewhat different reasons.

They are both interesting to deal with autism flare-ups, which seem common.

Other drugs that people use short term, but are used long term in asthma therapy,  are Singulair (Montelukast) and an interesting Japanese drug called Ibudilast.  Singulair is a Western drug for maintenance therapy in asthma.  Ibudilast is widely used in Japan as maintenance therapy in Asthma, but works in a different way.  Ibudilast is being used in clinical trials in the US to treat Multiple Sclerosis.  Singulair is cheap and widely available, Ibudilast is more expensive and available mainly in Japan.


Pre-vaccination Immunomodulation

In spite of there being no publicly acknowledged link between vaccinations and autism secondary to mitochondrial disease (AMD), I read that short term immunomodulation is used prior to vaccination at Johns Hopkins, for some babies.

Singulair is used, as is apparently ibuprofen.  Ponstan and Ibudilast would also likely be protective.   Ponstan might well be the best choice; it lowers fevers better than ibuprofen.

For those open minded people, here is what a former head of the US National Institutes of Health, Bernadine Healy, had to say about the safe vaccination.  Not surprisingly she was another Johns Hopkins trained doctor, as is Hannah Poling’s Neurologist father.

The Vaccines-Autism War: Détente Needed

“Finally, are certain groups of people especially susceptible to side effects from vaccines, and can we identify them? Youngsters like Hannah Poling, for example, who has an underlying mitochondrial disorder and developed a sudden and dramatic case of regressive autism after receiving nine immunizations, later determined to be the precipitating factor. Other children may have a genetic predisposition to autism, a pre-existing neurological condition worsened by vaccines, or an immune system that is sent into overdrive by too many vaccines, and thus they might deserve special care. This approach challenges the notion that every child must be vaccinated for every pathogen on the government's schedule with almost no exception, a policy that means some will be sacrificed so the vast majority benefit.”


So if I was an American running the FDA/CDC I would suggest giving parents the option of paying a couple of dollars for 10 days of Ponstan prior to these megadose vaccinations and a few days afterwards.  No harm or good done in 99.9% of cases, but maybe some good done for the remainder.

The fact the fact that nobody paid any attention to the late Dr Healy on this subject tells you a lot.



Fenamates (ANO 2/4/7 & KCNMA1)

Here Knut is trying to target the ion channels expressed by the genes ANO 2/4/7 & KCNMA1. 

·        ANO 2/4/7 are calcium activated chloride channels. (CACCs)


·        KCNMA1 is a calcium activated potassium channel.  KCNMA1encodes the ion channel KCa1.1, otherwise known as BK (big potassium).  This was the subject of post that I never got round to publishing.
  
Fenamates are an important group of clinically used non-steroidal anti-inflammatory drugs (NSAIDs), but they have other effects beyond being anti-inflammatory.  They act as CaCC inhibitors and also stimulate BKCa channel activity.


But fenamates also have a potent effect on what seems to be the most dysfunctional receptor in classic autism, the GABAA receptor.




The fenamate NSAID, mefenamic acid (MFA) prevents convulsions and protects rats from seizure-induced forebrain damage evoked by pilocarpine (Ikonomidou-Turski et al., 1988) and is anti-epileptogenic against pentylenetetrazol (PTZ)-induced seizure activity, but at high doses induces seizures (Wallenstein, 1991). In humans, MFA overdose can lead to convulsions and coma (Balali-Mood et al, 1981; Young et al., 1979; Smolinske et al., 1990). More recent data by Chen and colleagues (1998) have shown that the fenamates, flufenamic, meclofenamic and mefenamic acid, protect chick embryo retinal neurons against ischaemic and excitotoxic (kainate and NMDA) induced neuronal cell death in vitro (Chen et al., 1998a; 1998b). MFA has also been reported to reduce neuronal damage induced by intraventricular amyloid beta peptide (Aβ1-42) and improve learning in rats treated with Aβ1-42 (Joo et al., 2006). The mechanisms underlying these anti-epileptic and neuroprotective effects are not well understood but together suggest that fenamates may influence neuronal excitability through modulation of ligand and/or voltage-gated ion channels. In the present study, therefore, we have investigated this hypothesis by determining the actions of five representative fenamate NSAIDs at the major excitatory and inhibitory ligand-gated ion channels in cultured hippocampal neurons


This study demonstrates for the first time that mefenamic acid and 4 other representatives of the fenamate NSAIDs are highly effective and potent modulators of native hippocampal neuron GABAA receptors. MFA was the most potent and at concentrations equal to or greater than 10 μM was also able to directly activate the GABAA gated chloride channel. A previous study from this laboratory reported that mefenamic acid potentiated recombinant GABAA receptors expressed in HEK-293 cells and in Xenopus laevis oocytes (Halliwell et al., 1999). Together these studies lead to the conclusion that fenamate NSAIDs should now also be considered a robust class of GABAA receptor modulators.


Also demonstrated for the first time here is the direct activation of neuronal GABAA receptors by mefenamic acid. Other allosteric potentiators, including the neuroactive steroids and the depressant barbiturates share this property, with MFA at least equipotent to neurosteroids and significantly more potent than the barbiturates. The mechanism(s) of the direct gating of GABAA receptor chloride channels by MFA requires further investigation using ultra-fast perfusion techniques but may be distinct from that reported for neurosteroids (see, Hosie et al., 2006). Mefenamic acid induced a leftward shift in the GABA dose-response curve consistent with an increase in receptor affinity for the agonist. This is an action observed with other positive allosteric GABAA receptor modulators, including the benzodiazepine agonist, diazepam, the neuroactive steroid, allopregnanolone, and the intravenous anesthetics, pentobarbitone and propofol (e.g. Johnston, 2005). To our knowledge, a unique property of MFA was that it was significantly (F = 10.35; p≤ 0.001) more effective potentiating GABA currents at hyperpolarized holding potentials (especially greater than −60mV). Further experiments are required however to determine the underlying mechanism(s).

The highly effective modulation of GABAA receptors in cultured hippocampal neurons suggests the fenamates may have central actions. Consistent with this hypothesis, mefenamic acid concentrations are 40–80μM in plasma with therapeutic doses (Cryer & Feldman, 1998); fenamates can also cross the blood brain barrier (Houin et al., 1983; Bannwarth et al., 1989) Coyne et al. Page 5 Neurochem Int. Author manuscript; available in PMC 2008 November 1. NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript and in overdose in humans are associated with coma and convulsions (Smolinske et al., 1990). In animal studies, mefenamic acid is anticonvulsant and neuroprotective against seizureinduced forebrain damage in rodents (Ikonomidou-Turski et al., 1988). The present study would suggest that the anticonvulsant effects of fenamates may be related, in part, to their efficacy to potentiate native GABAA receptors in the brain, although a recent study has suggested that activation of M-type K+ channels may contribute to this action (Peretz et al., 2005) Finally, Joo and co-workers (2006) have recently reported that mefenamic acid provided neuroprotection against β-amyloid (Aβ1-42) induced neurodegeneration and attenuated cognitive impairments in this animal model of Alzheimer’s disease. The authors proposed that neuroprotection may have resulted from inhibition of cytochrome c release from mitochondria and reduced caspase-3 activation by mefenamic acid. Clearly it would also be of interest to evaluate the role of GABA receptor modulation in this in vivo model of Alzheimer’s disease. Moreover, considerable evidence has emerged in the last few years indicating that GABA receptor subtypes are involved in distinct neuronal functions and subtype modulators may provide novel pharmacological therapies (Rudolf & Mohler, 2006). Our present data showing that fenamates are highly effective modulators of native GABAA receptors and that mefenamic acid is highly subtype-selective (Halliwell et al., 1999) suggests that further studies of its cognitive and behavioral effects would be of value.

  

Note in the above paper that NSAIDs other than mefenamic acid also modulate GABAA receptors.

Just a couple of months ago a rather complicated paper was published, again showing that NSAIDs modulate GABAA receptors and showing that this is achieved via the same calcium activated chloride channels (CaCC) referred to by Knut.

NSAIDs modulate GABA-activated currents via Ca2+-activated Cl channels in rat dorsal root ganglion neurons






"Schematic displaying the effects of CaCCs on GABA-activated inward currents and depolarization. GABA activates the GABAA receptor to open the Cl  channel and the Cl efflux induces the depolarization response (inward current) of the membrane of dorsal root ganglion (DRG) neurons. Then, voltage dependent L-type Ca2+ channels are activated by the depolarization, and give rise to an increase in intracellular Ca2+. CaCCs are activated by an increase in intracellular Ca2+ concentration which, in turn, increases the driving force for Cl efflux. Finally, the synergistic action of the chloride ion efflux through GABAA receptors and NFA-sensitive CaCCs causes GABA-activated currents or depolarization response in rat DRG neurons."


Note in the complex explanation above the L-type calcium channels, which are already being targeted by Verapamil, in the PolyPill.



Mefenamic Acid and Potassium Channels

We know that Mefenamic acid also affects Kv7.1 (KvLQT1).

A closely related substance called meclofenamic acid is known to act as novel KCNQ2/Q3 channel openers and is seen as having potential for the treatment of neuronal hyper-excitability including epilepsy, migraine, or neuropathic pain.



The voltage-dependent M-type potassium current (M-current) plays a major role in controlling brain excitability by stabilizing the membrane potential and acting as a brake for neuronal firing. The KCNQ2/Q3 heteromeric channel complex was identified as the molecular correlate of the M-current. Furthermore, the KCNQ2 and KCNQ3 channel  subunits are mutated in families with benign familial neonatal convulsions, a neonatal form of epilepsy. Enhancement of KCNQ2/Q3 potassium currents may provide an important target for antiepileptic drug development. Here, we show that meclofenamic acid (meclofenamate) and diclofenac, two related molecules previously used as anti-inflammatory drugs, act as novel KCNQ2/Q3 channel openers. Extracellular application of meclofenamate (EC50  25 M) and diclofenac (EC50  2.6 M) resulted in the activation of KCNQ2/Q3 K currents, heterologously expressed in Chinese hamster ovary cells. Both openers activated KCNQ2/Q3 channels by causing a hyperpolarizing shift of the voltage activation curve (23 and 15 mV, respectively) and by markedly slowing the deactivation kinetics. The effects of the drugs were stronger on KCNQ2 than on KCNQ3 channel  subunits. In contrast, they did not enhance KCNQ1 K currents. Both openers increased KCNQ2/Q3 current amplitude at physiologically relevant potentials and led to hyperpolarization of the resting membrane potential. In cultured cortical neurons, meclofenamate and diclofenac enhanced the M-current and reduced evoked and spontaneous action potentials, whereas in vivo diclofenac exhibited an anticonvulsant activity (ED50  43 mg/kg). These compounds potentially constitute novel drug templates for the treatment of neuronal hyperexcitability including epilepsy, migraine, or neuropathic pain. Volt




BK channel

KCNMA1encodes the ion channel KCa1.1, otherwise known as BK (big potassium). BK channels are implicated not only by Knut’s statistics, but numerous studies ranging from schizophrenia to Fragile X. 

Usually it is a case of too little BK channel activity.

The BK channel is implicated in some epilepsy.

  

Pharmacology

BK channels are pharmacological targets for the treatment of several medical disorders including stroke and overactive bladder. Although pharmaceutical companies have attempted to develop synthetic molecules targeting BK channels, their efforts have proved largely ineffective. For instance, BMS-204352, a molecule developed by Bristol-Myers Squibb, failed to improve clinical outcome in stroke patients compared to placebo. However, BKCa channels are reduced in patients suffering from the Fragile X syndrome and the agonist, BMS-204352, corrects some of the deficits observed in Fmr1 knockout mice, a model of Fragile X syndrome.
BK channels have also been found to be activated by exogenous pollutants and endogenous gasotransmitters carbon monoxide and hydrogen sulphide.
BK channels can be readily inhibited by a range of compounds including tetraethylammonium (TEA), paxilline and iberiotoxin.



Achieving a better understanding of BK channel function is important not only for furthering our knowledge of the involvement of these channels in physiological processes, but also for pathophysiological conditions, as has been demonstrated by recent discoveries implicating these channels in neurological disorders. One such disorder is schizophrenia where BK channels are hypothesized to play a role in the etiology of the disease due to the effects of commonly used antipsychotic drugs on enhancing K+ conductance [101]. Furthermore, this same study found that the mRNA expression levels of the BK channel were significantly lower in the prefrontal cortex of the schizophrenic group than in the control group [101]. Similarly, autism and mental retardation have been linked to haploinsufficiency of the Slo1 gene and decreased BK channel expression [102].
Two mutations in BK channel genes have been associated with epilepsy. One mutation has been identified on the accessory β3 subunit, which results in an early truncation of the protein and has been significantly correlated in patients with idiopathic generalized epilepsy [103]. The other mutation is located on the Slo1gene, and was identified through genetic screening of a family with generalized epilepsy and paroxysmal dyskinesia [104]. The biophysical properties of this Slo1 mutation indicates enhanced sensitivity to Ca2+ and an increased average time that the channel remains open [104107]. This increased Ca2+ sensitivity is dependent on the specific type of β subunit associating with the BK channel [106, 107]. In association with the β3 subunit, the mutation does not alter the Ca2+-dependent properties of the channel, but with the β4 subunit the mutation increases the Ca2+ sensitivity [105107]. This is significant considering the relatively high abundance of the β4 subunit compared to the weak distribution of the β3 subunit in the brain [12, 13,15, 106, 107]. It has been proposed that a gain of BK channel function may result in increases in the firing frequency due to rapid repolarization of APs, which allows a quick recovery of Na+ channels from inactivation, thereby facilitating the firing of subsequent APs [104]. Supporting this hypothesis, mice null for the β4 subunit showed enhanced Ca2+ sensitivity of BK channels, resulting in temporal lobe epilepsy, which was likely due to a shortened duration and increased frequency of APs [108]. An interesting relevance to the mechanisms of BK channel activation as discussed above, the Slo1 mutation associated with epilepsy only alters Ca2+ dependent activation originated from the Ca2+ binding site in RCK1, but not from the Ca2+bowl, by altering the coupling mechanism between Ca2+ binding and gate opening [100]. Since Ca2+dependent activation originated from the Ca2+ binding site in RCK1 is enhanced by membrane depolarization, at the peak of an action potential the binding of Ca2+ to the site in RCK1 contributes much more than binding to the Ca2+ bowl to activating the channel [84, 109].
Although these associations between specific mutations in BK channel subunits and various neurological disorders have been demonstrated by numerous studies, it is also important to point out certain caveats with these studies, such as genetic linkage between BK channels and different diseases do not necessary show causation as these studies were performed based on correlation between changes in the protein/genetic marker and overall phenotype. Furthermore, studies performed using a mouse model also can fail to indicate what may happen in higher-order species, and this is especially true for BK channels, where certain β subunits are only primate specific [110].


  

Possible role of potassium channel, big K in etiology of schizophrenia.

Schizophrenia (SZ), a common severe mental disorder, affecting about 1% of the world population. However, the etiology of SZ is still largely unknown. It is believed that molecules that are in an association with the etiology and pathology of SZ are neurotransmitters including dopamine, 5-HT and gamma-aminobutyric acid (GABA). But several lines of evidences indicate that potassium large conductance calcium-activated channel, known as BK channel, is likely to be included. BK channel belongs to a group of ion channels that plays an important role in regulating neuronal excitability and transmitter releasing. Its involvement in SZ emerges as a great interest. For example, commonly used neuroleptics, in clinical therapeutic concentrations, alter calcium-activated potassium conductance in central neurons. Diazoxide, a potassium channel opener/activator, showed a significant superiority over haloperidol alone in the treatment of positive and general psychopathology symptoms in SZ. Additionally, estrogen, which regulates the activity of BK channel, modulates dopaminergic D2 receptor and has an antipsychotic-like effect. Therefore, we hypothesize that BK channel may play a role in SZ and those agents, which can target either BK channel functions or its expression may contribute to the therapeutic actions of SZ treatment.




Conclusion

It appears that Ponstan and related substances have some interesting effects that are only now emerging in the research.

People with autism, and indeed schizophrenia, may potentially benefit from Ponstan and for a variety of different reasons.

I think it will take many decades for any conclusive research to be published on this subject, because this is an off-patent generic drug.

As with most NSAIDS, it is simple to trial Ponstan.

Thanks to Knut for the idea, Professor Ritvo for his endorsement of the idea and our reader from South Africa for sharing his positive experience with Ponstan.