Glutamate Inhibitors to Treat Some Autism and ADHD

 A festive queue at the pharmacy for Glutamate Inhibitors

We have now established that much autism and indeed other disorders, from Down Syndrome to Schizophrenia, features a degree of excitatory/inhibitory (E/I) imbalance.

It is very likely that there are multiple underlying causes for this and so there may be multiple treatments.  We can even potentially use a treatment for one cause (ALS) to improve outcomes in others.  So we can (partially) solve a problem without fully understanding its origin, as frequently is the case in biology.

An E/I imbalance might cause anxiety in the adult with Asperger (treatable with Baclofen), contribute to MR/ID in the child with Down Syndrome and contribute to seizures and cognitive loss in someone with severe autism.

Very interestingly in the comments to a previous post, Agnieszka has pointed out why common penicillin type antibiotics (beta-lactams) improve many people’s autism.  This is very common observation and our other guest blogger Seth Bittker found the same in his son. Nat’s guest speaker at her autism conference also found this in his son.

The Glutamate Transporter 1 (GLT-1) is a protein that in humans is encoded by the SLC1A2 gene.   It is the principal transporter that clears the excitatory neurotransmitter glutamate from the extracellular space at synapses in the central nervous system. Glutamate clearance is necessary for proper synaptic activation and to prevent neuronal damage from excessive activation of glutamate receptors. Glutamate is an excitatory neurotransmitter, so it encourages neurons to fire.

By upregulating the GLT1 transporter you increase the inactivation of glutamate and so shift the Excitatory/Inhibitory balance towards inhibitory.

Agnieszka highlighted this paper from Johns Hopkins:-

Beta-lactam antibiotics offer neuroprotection by increasing glutamate transporter expression

Glutamate is the principal excitatory neurotransmitter in the nervous system. Inactivation of synaptic glutamate is handled by the glutamate transporter GLT1 (also known as EAAT2; refs 1, 2), the physiologically dominant astroglial protein. In spite of its critical importance in normal and abnormal synaptic activity, no practical pharmaceutical can positively modulate this protein. Animal studies show that the protein is important for normal excitatory synaptic transmission, while its dysfunction is implicated in acute and chronic neurological disorders, including amyotrophic lateral sclerosis (ALS), stroke, brain tumours and epilepsy. Using a blinded screen of 1,040 FDA-approved drugs and nutritionals, we discovered that many beta-lactam antibiotics are potent stimulators of GLT1 expression. Furthermore, this action appears to be mediated through increased transcription of the GLT1 gene. beta-Lactams and various semi-synthetic derivatives are potent antibiotics that act to inhibit bacterial synthetic pathways. When delivered to animals, the beta-lactam ceftriaxone increased both brain expression of GLT1 and its biochemical and functional activity. Glutamate transporters are important in preventing glutamate neurotoxicity. Ceftriaxone was neuroprotective in vitro when used in models of ischaemic injury and motor neuron degeneration, both based in part on glutamate toxicity. When used in an animal model of the fatal disease ALS, the drug delayed loss of neurons and muscle strength, and increased mouse survival. Thus these studies provide a class of potential neurotherapeutics that act to modulate the expression of glutamate neurotransmitter transporters via gene activation.

It actually gets more interesting and relevant to treatment.

Mutations in SLC1A2 which decrease expression of the GLT-1 protein are associated with amyotrophic lateral sclerosis (ALS). 

The drug riluzole approved for the treatment of ALS upregulates GLT-1.

This would suggest that Agnieszka, Seth and John Rodakis might want to pay a visit to the pharmacy and pick up some riluzole.  It is certainly worth investigating.

I did check and there is even a trial on Riluzole in autism and evidence of existing off-label use.  They have not of course made Agnieszka’s connection; they seem to be just trying it because nothing else seems to help. That really is trial and error and makes this blog look positively scientific by comparison.

A Pilot Study of Riluzole Versus Placebo in the Treatment of Children and Adolescents With ASD(RILISE)

Drug: Riluzole

50mg once daily (QD) for 12 weeks for participants 6-11 years old; 50mg twice daily (BID) for 12 weeks for participants 12-17 years old

Riluzole in Autistic Disorder

A reformulation of riluzole that originated at Yale University and is known by the code name BHV-0223 is under development for the treatment of generalized anxiety disorder and mood disorders  by Biohaven Pharmaceuticals.

  

Anyway, are there any other ways to inhibit Glutamate?

Yes, our reader Valentine just stumbled on one, tizanidine, but there are at least two others. 

α2 adrenergic agonists

Three other known inhibitors of glutamate happen to be α2 adrenergic agonists

·        Clonidine

·        Guanfacine

·        Tizanidine

All three of the above are already used in ADHD and sometimes in autism, but not to reduce glutamate.

I wrote a post about Clonidine use in autism a long time ago.

Clonidine, ADHD and Autism

Guanfacine is an ADHD drug known to inhibit glutamate release.

Guanfacine shown safe and effective in autism treatment

At five sites, children with ASD and moderate to severe hyperactivity were either given guanfacine or a placebo tablet for eight weeks, in a randomized and double-blind clinical trial. The research team collected information from parents and measured each child’s overall response. After eight weeks of treatment, extended release guanfacine was superior to placebo for decreasing hyperactivity and impulsiveness.

Our reader Valentina seems to have stumbled upon tizanidine, but finds it helpful for her son. Tizanidine is a α2 adrenergic agonists but also inhibits glutamate.  It is one of the drugs used off-label by Dr Chez in ADHD and autism

Pediatric safety of tizanidine: clinical adverse event database and retrospective chart assessment

Henney HR 3rd¹, Chez M.

CONCLUSION:

The overall safety of tizanidine in the pediatric group appeared good; however, the adverse event profile differed from that in adults. This difference most likely reflects the off-label use of tizanidine as adjunctive treatment for attention disorders and autism. The frequency and nature of adverse events in adults were consistent with the tizanidine prescribing information as reported for its approved indication, i.e. management of spasticity.

Conclusion

Ideally you would have a comparison of the four drugs:

·        Riluzole

·        Tizanidine

·        Clonidine

·        Guanfacine

We know clonidine is not an autism wonder drug, but then what is?

I think Riluzole is likely to be a good one, but very likely what works best will vary from person to person.

Perhaps a positive response to beta-lactam (penicillin) antibiotics is a biomarker for people who will respond to Riluzole? It should be.

Preventing Auto-Immune Disease and some Autism

Today’s post is another one filling in some gaps in this blog.

I think it is common sense to say that preventing a problem from developing is much wiser than trying to solve it later on.  This is a recurring issue in both life and medicine.

In the research we now see preventative measures developed to reduce the risk of cancer, we also see how some interventions are only effective when started very early.

In the case of autism we have seen than often it is caused by a myriad of factors that by themselves might have been harmless but when taken together are the multiples hits that caused the brain to develop differently.

Much research looks individually at these factors that increase the risk of autism.  In the wider media much disdain is directed to these findings as if each factor is THE cause of autism and how can so many things cause autism.  But by understanding these factors you can then set about countering them.

I did create my simplified schematic to explain classic autism a while back.  It is not perfect but it does illustrate much of what is going on.

I do get occasional questions about reducing the risk of autism.  For example, Monty now aged 13 with ASD, has a big brother and he wants to know.  Our reader, Kritika from India, has also raised this issue.  If you have autism in your family you may well decide you would like to minimize the risk of more cases.

In practical terms, you cannot change your genes or those inherited epigenetic markers.  Maybe this will change in future.  But there are things you can do.

We know that oxidative stress is a driver of much disease including autism.  This can be minimized by lifestyle changes and indeed with a little pharmacological help.

I was interested to see a study that used NAC to treat mothers who suffer unexplained pregnancy loss, the antioxidant showed a “significant increase in the take-home baby rate”.  I was really just looking for safety information.

N-acetyl cysteine for treatment of recurrent unexplained pregnancy loss 

Pregnancy could be associated with a state of oxidative stress that could initiate and propagate a cascade of changes that may lead to pregnancy wastage. This process of oxidative stress may be suppressed by the antioxidant effect of N-acetyl cysteine (NAC). The current study aimed to evaluate the effect of NAC therapy in patients diagnosed with unexplained recurrent pregnancy loss (RPL). The study was a prospective controlled study performed in the Women's Health Centre, Assiut University, Egypt. A group of 80 patients with history of recurrent unexplained pregnancy loss were treated with NAC 0.6 g + folic acid 500 microg/day and compared with an aged-matched group of 86 patients treated with folic acid 500 microg/day alone. NAC + folic acid compared with folic acid alone caused a significantly increased rate of continuation of a living pregnancy up to and beyond 20 weeks [P < 0.002, relative risk (RR) 2.9, 95% confidence interval (CI) 1.5-5.6]. NAC + folic acid was associated with a significant increase in the take-home baby rate as compared with folic acid alone (P < 0.047, RR 1.98, 95% CI 1.3-4.0). In conclusion, NAC is a well-tolerated drug that could be a potentially effective treatment in patients with unexplained RPL.

This then made be recall a US fertility clinic, that our reader Roger once mentioned in a comment.

http://www.preventmiscarriage.com/

http://www.preventautism.com/

“At Braverman Reproductive Immunology, we believe Autism Spectrum Disorder (ASD) and various pregnancy and infertility complications (listed below) appear to have the same cause. In fact, we have found that a large number of patients who present to our center with the below complications already have a child with ASD.

This discovery started us on the journey to see if ASD itself could be prevented while treating other associated conditions. We believe treatment for these common issues will not only prevent the pregnancy complications listed below, but may also prevent ASD in the group of patients that have already had a child with ASD.”

Dr Braverman does not mention oxidative stress, but perhaps he should.

So step one would be to reduce oxidative stress during pregnancy, via lifestyle changes and taking antioxidants.

Step two would be to avoid inflammation, Dr Braverman refers to the link to auto-immune disease and miscarriage/autism.

We know that maternal inflammation is one of the easiest ways to cause autism in mouse models (the MIA model - Maternal Immune Activation).

  

We have some research to show that the risk of auto-immune disease can indeed be reduced and indeed that the risk of progression from minor to more major auto-immune disease can also be minimized.

We even have a tiny study showing that immuno-modulatory therapy using a probiotic during pregnancy can reduce incidence of ADHD and autism. For me ADHD is just a case of autism-lite.

A possible link between early probiotic intervention and the risk of neuropsychiatric disorders later in childhood: a randomized trial

Background:

Recent experimental evidence suggests that gut microbiota may alter function within the nervous system providing new insight on the mechanism of neuropsychiatric disorders.

Methods:

Seventy-five infants who were randomized to receive Lactobacillus rhamnosus GG (ATCC 53103) or placebo during the first 6 mo of life were followed-up for 13 y. Gut microbiota was assessed at the age of 3 wk, 3, 6, 12, 18, 24 mo, and 13 y using fluorescein in situ hybridization (FISH) and qPCR, and indirectly by determining the blood group secretor type at the age of 13 y. The diagnoses of attention deficit hyperactivity disorder (ADHD) and Asperger syndrome (AS) by a child neurologist or psychiatrist were based on ICD-10 diagnostic criteria.

Results:

At the age of 13 y, ADHD or AS was diagnosed in 6/35 (17.1%) children in the placebo and none in the probiotic group (P = 0.008). The mean (SD) numbers of Bifidobacterium species bacteria in feces during the first 6 mo of life was lower in affected children 8.26 (1.24) log cells/g than in healthy children 9.12 (0.64) log cells/g; P = 0.03.

Conclusion:

Probiotic supplementation early in life may reduce the risk of neuropsychiatric disorder development later in childhood possible by mechanisms not limited to gut microbiota composition.

The issue, as with NAC during pregnancy, is whether immuno-modulatory therapy is safe.

The study on ADHD and autism was actually a study looking at whether a certain probiotic if given during pregnancy could reduce eczema later on in the child.

  

We also have the studied effect of having a pet dog at home.

House dust exposure mediates gut microbiome Lactobacillus enrichmentand airway immune defense against allergens and virus infection

 

Early-life exposure to dogs is protective against allergic disease development, and dog ownership is associated with a distinct milieu of house dust microbial exposures. Here, we show that mice exposed to dog-associated house dust are protected against airway allergen challenge. These animals exhibit reduced Th2 cytokine production, fewer activated T cells, and a distinct gut microbiome composition, highly enriched for Lactobacillus johnsonii, which itself can confer airway protection when orally supplemented as a single species. This study supports the possibility that host–environment interactions that govern allergic or infectious airway disease may be mediated, at least in part, by the impact of environmental exposures on the gastrointestinal microbiome composition and, by extension, its impact on the host immune response.

One of my views is that by early treatment of autism you may indeed reduce the risk of epilepsy.  The key here is “reduce the risk”, it does not mean there is no risk.  There are likely hundreds of causes of epilepsy, but if you can reduce the incidence by 30+% that would look like a big success to me.

I recall another study that looked at treating people with eczema to see if you could reduce the chance of progression to asthma.  Using Ketotifen the trial showed that it was indeed possible.

Prevention of asthma by ketotifen in infants with atopic dermatitis. 

To evaluate the prophylactic effect of ketotifen against the onset of asthma we selected 121 infants with atopic dermatitis, without any history suggestive of asthma (cough and/or wheezing). Sixty-one children received ketotifen twice daily. Those who weighed less than 14 kg received 0.8 mg; 14 kg or more, 1.2 mg. Sixty children, a placebo syrup indistinguishable from the active syrup. Both groups were followed for 1 year, with bimonthly evaluations. The criteria for onset of asthma were two different episodes of wheezing treated with bronchodilator drugs. Both groups were comparable regarding age, sex, weight, onset, and duration of atopic dermatitis and age at the onset of asthma. During the 1 year study, asthma was observed in eight children of the ketotifen group (13.1%) and in 25 children of the placebo group (41.6%) (P less than .001). Side effects were negligible and routine laboratory tests disclosed no significant alterations. Ketotifen is a very useful drug for prevention of asthma in children with atopic dermatitis and total IgE more than 50 IU/mL.

Somali Autism Clusters

This then takes me back to that issue I looked at long ago, which was the reason for the Somali immigrants to Sweden and US having so many children with autism.  This even got termed the Swedish Disease by the migrants, they claimed to have never seen autism back home in Somalia.

Then we have the hygiene hypothesis which in effect says that, within limits, a little dirt is good for you.

Hormonal Dysfunction

We know that gestational diabetes increases the risk of autism and we also known that the mother being hypothyroid increases the risk.  In some cases the hormone dysfunction is a consequence of the auto-immune dysfunction.

We also know the female hormone progesterone is extremely neuro-protective.  The level of this hormone is supposed to rise during pregnancy.

  

In past times hormones were given to some pregnant mothers, but this went out of fashion.  Perhaps this should be revisited?

Then we have the surge of the hormone oxytocin that the baby is supposed to receive at birth.  This surge may be relevant to the GABA switch when shortly after birth this neurotransmitter is supposed to switch from excitatory to inhibitory as the neurons mature. If the baby is born by Caesarian there will be no oxytocin surge for the baby.   

Preventing Regressive Autism Secondary to Mitochondrial Disease (AMD)

It is on open secret that doctors at Johns Hopkins have identified a variant of regressive autism called Autism secondary to Mitochondrial Disease (AMD).

It remains unclear how rare this is and absolutely nobody serious is going to research this, if they ever want to receive a research grant in the future.

We saw that in people with a genetic predisposition to mitochondrial dysfunction, an immune over-reaction to an insult like multiple vaccinations can trigger mitochondrial disease.  This will present itself as autism and quite possibly severe autism in a previously unaffected child.

Those doctors treating AMD use mild immuno-suppressing drugs before any future vaccinations.

How do you minimize the chance of AMD? 

The first thing is to never use paracetamol/acetaminophen in a baby or child, particularly just after vaccination.  This drug may kill the pain but it depletes GSH the body’s main antioxidant, just when it needs it most.   Use something like Ibuprofen.

Vaccines are given in multiples so as to save time and money and I suppose improve compliance. You might expect giving them one-by-one would actually make them more effective as well minimizing any collateral damage to a small percentage of kids.

Conclusion

As I keep reminding readers, I am not a doctor, but it would be nice if a few more doctors other than Braverman took preventing autism seriously.

I would like to know if progesterone is an effective therapy in the MIA model of autism.  In this model they trigger the mother’s immune system during pregnancy which leads to offspring with autism.  What would be the effect of giving progesterone?  Would it protect the pups?

Are progesterone levels reduced in mice that will become autistic?

So I suppose I would trial NAC and progesterone in the mother mouse.

For everyone else it is case of choosing whether or not to make lifestyle changes to reduce oxidative stress.  Improving gut bacteria can be done via probiotics, eating more (slightly dirty) fruit and vegetables, having a pet dog, spending some time in the nature.  

As for vaccine risk, however small it might indeed be, there will never be a serious investigation of this, for understandable reasons. 

ASD variants - (mis and missed) diagnoses. Calcium ion channel dysfunctions Cav1.1, 1.2, 1.3 and 1.4

This post serves to introduce some ideas relevant to a post that is will shortly arrive on calcium ion channel dysfunctions (Cav1.1, 1.2, 1.3 and 1.4).

As we have seen, nearly all behavioral and psychiatric disorders are just diagnosed based on observation.  Only in very rare cases is the underlying biological problem diagnosed.  So it is fair to say that these are not accurate medical diagnoses.

Under the wide umbrella term of ASD are likely hundreds of thousands of  discrete variants, since ASD generally results from the combination of multiple hits/dysfunctions.  A single one of these dysfunctions is usually not enough to trigger autism, but some may indeed trigger something else noticeable.  A small number of individual hits, like Fragile-X and Retts can trigger autism, but these are the exception.

Mis and Missed diagnoses

One reader of this blog received a diagnosis for his child as “late onset regressive autism or possible childhood disintegrative disorder”.  Neither of these options is very good, since you are talking about an entirely typical child who, after the age of four, begins to regress and lose his acquired skills.

After a long struggle, he found the biological diagnosis, which is mitochondrial disease.  After a few months of the Richard Kelley (from Johns Hopkins), therapy the regression was halted and now new skills are again being acquired.

This is another example of how unacceptable simple observational diagnoses are.  What would have happened if the reader had not stumbled upon this blog and then later sought out help from the leading experts (just look on my Dean’s list)?

Attention Deficit Disorder (ADHD)

ADHD is very commonly diagnosed in the US, much more so than in other countries.  More severe cases of ADHD look much like ASD, which is why I call them autism-lite.

Another group of ADHD may indeed be purely behavioral – too much time with smart phones, iPads and video games.  This is supported by the fact that the data on incidence of ADHD shows that a large group of children with ADHD, “grow out of it”, or were misdiagnosed in the first place.

However, it does look like there is another group of ADHD which is biological, but may be different to autism.  On this subject I will bring you the comments of Dr. Manuel Casanova, a neurologist and along with that, thoughtful and knowledgeable about autism. 

Then we have the recurring clinical trials on high EPA/DHA fish oil, which really do show an effect in most trials in ADHD, but fail in most trials in autism.  This will be developed further in the later post on calcium channels.  The suggested view is that either the vitamin A, or the omega 3 oil, is somehow helping and even perhaps some people have a problem absorbing some types of vitamin A.  I was always unconvinced by this. 

However, it has now been shown that the EPA in fish oil has an effect on certain L-type calcium channels.  If you had a mild dysfunction (channelopathy) of one of the L-type calcium channels, then a big enough dose of EPA might have an effect on them.  This becomes more interesting when you learn that some doctors in the US think that dyslexia is another autism-lite.

One suggested cause of dyslexia is visual deficit that makes reading difficult, but it also accompanied by a difficulty seeing in the dark.  This night blindness is known to be caused by vitamin A deficiency (or an inability to absorb it properly) and also by an ion channel dysfunction in Cav1.4.

It appears that the high EPA fish oil would increase vitamin A and also affect the function of Cav1.4.  The calcium ion channel Ca1.4 is widely expressed in your eyes.

Another interesting point is that it is thought that a dysfunction in one type of Calcium channel will often affect the function of others.  This is important because when you look at the effect of dysfunctions in these channels you will a listing including:-

·        Autism (Timothy Sydrome)

·        Mood disorder

·        Depression

·        Bipolar

As well as things like

·        Night blindness

·        Heart defects (Timothy Sydrome)

We also should note that many people (without autism) with sight problems claim improvement from taking high EPA fish oil.

Dyslexia

Dyslexia is the most common learning disability. It affects about 3 to 7 percent of people. While it is diagnosed more often in males, some believed it affects males and females equally. Up to 20 percent of the population may have some degree of symptoms

Dyslexia and attention deficit hyperactivity disorder (ADHD) commonly occur together; about 15 percent of people with dyslexia also have ADHD and 35 percent of those with ADHD have dyslexia.

The causes appear to be genetic and epigenetic. For example the gene KIAA0319

People usually think of dyslexia only in children, but that may be because many adults do not read very much.  Or do they "grow out of it".

ADHD

“It affects about 6–7% of children when diagnosed via the DSM-IV criteria and 1–2% when diagnosed via the ICD-10 criteria.  Rates are similar between countries and depend mostly on how it is diagnosed. ADHD is diagnosed approximately three times more in boys than in girls. About 30–50% of people diagnosed in childhood continue to have symptoms into adulthood.”

So it would seem that most people “grow out” of ADHD 

Dr. Manuel Casanova

Dr. Manuel Casanova is a neurologist and along with that is clever, thoughtful and knowledagable about autism.  He looks at measurable anatomical differences and how these may be related to behaviour.  So he is more into the consequences of unchangeable differences in brains.

If you start looking at ion channels and transporters as being key drivers in behaviour then you have the chance to make alterations.  We saw that the same applies to fine tuning the function and indeed structure of key neurotransmitter receptors.

In lay terms, Manuel is showing how brains are indeed “hardwired” differently in many cases of autism, ADHD and even dyslexia.  This might reinforce the old view that really it is “case closed” and nothing more can be done.

However the really clever scientists looking in greater depth show us that notwithstanding some structural variation, much of the problem lies in the aspects of the brain that can be modified and indeed some are constantly in a state of change, for example the shape of dendritric spines and indeed the very substructure of those  GABA_A receptors.

He groups dyslexia with ADHD and sees them as fundamentally different to autsim.  Having said that, Manuel tells us that attention disorders may be found in close to 30% of autistic individuals

 He has his own blog.

Dyslexia, Attention Deficit Hyperactivity Disorder and Autism

I suggest you read his full article, but here are some excerpts:-

“Claiming that there is comorbidity across neurodevelopmental disorders based on a single behavioral symptom negates many aspects of the individuality of each condition. In this regard, there are marked differences in the cognitive styles of dyslexic or ADHD individuals and those within the autism spectrum. Dyslexics enjoy a top-down cognitive style, tend to be holistically-oriented and have a gestalt processing bias (e.g., they see the forest but lose track of the individual trees). They are considered to have strong central coherence and excel in synthesizing sensory or cognitive experiences. Individuals within the autism spectrum enjoy a bottom-up cognitive style which makes them detail-oriented. Thus, contrary to dyslexic/ADHD subjects, ASD individuals see the tree but tend to lose sight of the forrest. In addition, they have a local processing bias with weak central coherence and appear to be good analyzers.”

“The above related differences in cognitive style appear to have anatomical correlates. As compared to neurotypicals, dyslexics tend to have smaller brain volumes with a concomitant striking increase in the size of their corpus callosum (the white matter projections that join homologous areas in both cerebral hemispheres). In addition, they have a simplification of their convolutional pattern and their cortical modules for information processing (minicolumns) are wider than expected. We find completely the opposite in patients within the autism spectrum.”

Yet more labels

Since we will be looking at calcium channels and one thing that does affect them is EPA, we should look at another label, dyspraxia, which also is reportedy  affected by fatty acids.

  

Fatty Acids in Dyslexia, Dyspraxia, ADHD and the Autistic Spectrum

Here is the link     Dyslexia, dyspraxia, ADHD and the autistic spectrum

What is Dyspraxia, also known as Developmental Coordination Disorder (DCD) ?

Dyspraxia, also known as Developmental coordination disorder (DCD), is is a chronic neurological disorder beginning in childhood that can affect planning of movements and co-ordination as a result of brain messages not being accurately transmitted to the body.

People with developmental coordination disorder sometimes have difficulty moderating the amount of sensory information that their body is constantly sending them, so as a result dyspraxics are prone to sensory overload and panic attacks.
Many dyspraxics struggle to distinguish left from right, even as adults, and have extremely poor sense of direction generally.

Moderate to extreme difficulty doing physical tasks is experienced by some dyspraxics, and fatigue is common because so much extra energy is expended while trying to execute physical movements correctly. Some (but not all) dyspraxics suffer from hypotonia, low muscle tone, which like DCD can detrimentally affect balance.

Gross motor control

Whole body movement, motor coordination, and body image issues mean that major developmental targets including walking, running, climbing and jumping can be affected. The difficulties vary from person to person and can include the following:

• Poor timing
• Poor balance (sometimes even falling over in mid-step). Tripping over one's own feet is also common.
• Difficulty combining movements into a controlled sequence.
• Difficulty remembering the next movement in a sequence.
• Problems with spatial awareness, or proprioception.
• Some people with developmental coordination disorder have trouble picking up and holding onto simple objects such as pencils, owing to poor muscle tone and/or proprioception.
• This disorder can cause an individual to be clumsy to the point of knocking things over and bumping into people accidentally.
• Some people with developmental coordination disorder have difficulty in determining left from right.
• Cross-laterality, ambidexterity, and a shift in the preferred hand are also common in people with developmental coordination disorder.
• Problems with chewing foods.

Fine motor control

Fine-motor problems can cause difficulty with a wide variety of other tasks such as using a knife and fork, fastening buttons and shoelaces, cooking, brushing one's teeth, styling one's hair, shaving, applying cosmetics, opening jars and packets, locking and unlocking doors, and doing housework.

Difficulties with fine motor co-ordination lead to problems with handwriting, which may be due to either ideational or ideo-motor difficulties. Problems associated with this area may include:

• Learning basic movement patterns.
• Developing a desired writing speed.
• Establishing the correct pencil grip
• The acquisition of graphemes – e.g. the letters of the Latin alphabet, as well as numbers.
• 
  

Associated disorders

People who have developmental coordination disorder may also have one or more of these co-morbid problems:

• Attention deficit hyperactivity disorder (ADHD) (inattention, hyperactivity, impulsive behaviour).
• Dyscalculia (difficulty with mathematics),
• Dysgraphia (an inability to write neatly and/or draw),
• Dyslexia (difficulty with reading and spelling),
• Hypotonia (low muscle tone)
• Sensory processing disorder
• Specific language impairment (SLI)
• Visual perception deficits

Dysjustabouteverything (DJE)

If you consider the early years of classic autism, you will see that, in many cases, it includes all of the above disorders, even hypertonia.

But some people are otherwise pretty much typical/normal, are diagnosed with a single disorder like dyscalculia.

The problem is that these are all just observational diagnoses.  Does something biological underlie and connect them?  I think it does.

An autistic person’s struggles with mathematics may be more to do with a problem of understanding the language used to explain it.  This is why, in many cases, they struggle to move beyond counting.  Special methods of teaching maths have been created for such people, but they only take you to an elementary level.

If you have Asperger’s, you have no problem with the language used to explain the concepts or to frame the questions.  Some people with Asperger’s excel at mathematics.

The same is true for dysgraphia, autistic people tend to have very scruffy handwriting, but does this mean that they have dysgraphia? 

Hypotonia is an interesting one.  Many parents report low muscle tone and indeed DAN doctors actually treat it (apparently with Creatine).  I think hypotonia, if present in autism, is likely to be connected to the disruption in the various growth factors that has occurred and this itself may related to GABA_B dysfunctions. (I mentioned this connection in an earlier post).  In Monty, aged 11 with ASD, when he was a baby he had Hypertonia.  He was big and all muscle.  As he got older he slid down from the 80-90^Th percentile to the 20^th percentile.  This fits one very distinct pattern of classic autism.

In the case of Monty, almost all the earlier signs of Dysjustabouteverything have now vanished.  Is this always the case?  Why would that happen in some people and not others?  Did his Polypill interventions play a role?

To investigate

What we need to know is whether there is a common link between all these various “dys-disorders”.

Probably in some (mis/over-diagnosed) people there is no link; but in others there may well be.

In some people there really is a link.  I did not tell you that my old “favourite”, hypokalemic periodic paralysis (HPP), can be caused by a Cav1.1 dysfunction.  HPP-lite is something called hypokalemic sensory overload.  In a little experiment I demonstrated that autistic sensory overload can be just hypokalemic sensory overload.  You just need 250 mg of potassium and a disturbing noise or light to illustrate it.  This is also a symptom of what they call Dyspraxia.

So Cav1.1 associates with HPP (hypokalemic periodic paralysis) and by my inference, sensory overload and some hypotonia;  Cav1.2 associates directly with autism (Timothy Syndrome) and bipolar; Cav1.3 associates with mood disorders, depression, bipolar; Cav1.4 associates with night blindness and perhaps some dyslexia.

A dysfunction in one L-type channel (Cav1.1, Cav1.2, Cav1.3 and Cav1.4) can apparently cause dysfunction in the others.  This surprised me.

So if you have autism, is not surprising if you appear afraid of the dark, feel depressed, experience sensory overload and are not very muscular.

The good news is that much of this appears to be treatable.

For the scientists among you:-

CACNB2    

Voltage-dependent L-type calcium channel subunit beta-2 is a protein that in humans is encoded by the CACNB2 gene

http://www.ebi.ac.uk/interpro/entry/IPR005444

Mutation in the CACNB2 gene are associated with Brugada syndrome, autism, attention deficit-hyperactivity disorder (ADHD), bipolar disorder, major depressive disorder, and schizophrenia.

I did forget to remind readers that I see the label schizophrenia as just another name for adult onset autism.

So it is no surprise that adults with autism have a 22 times higher chance of also being diagnosed with schizophrenia compared to non-ASD people.  Note bipolar, OCD etc; and this does not include all those adults with autism who get forgotten.

Source:  Adults with autism are at risk for host of health problems

Conclusion

I am not suggesting “medicalizing” people with dyslexia, or indeed most with ADHD. 

However, it might be useful for somebody affected to know if Cav1.1 to 1.4 were dysfunctional, then at critical moments, like exam time at school, you could indeed give them some extra help.

People with dyslexia, and I presume other “dys-disorders” do often get given extra time at school for exams.  People with ADHD are often entitled to financial benefits in developed countries, and it has been suggested that these countries are the ones with high incidence of diagnosis.  In the US 11% of children and 4.4% of adults have a diagnosis.   ADHD has been medicalized in the U.S. since the 1960s.  In the UK, 3.62% of boys and 0.85% of girls have an ADHD diagnosis.  In France less than 0.5% of children are taking medication for ADHD.

Here is a nice quote:-

Why Are ADHD Rates 20 Times Higher in the U.S. Than in  France?

“it makes perfect sense to me that French children don't need medications to control their behavior because they learn self-control early in their lives. The children grow up in families in which the rules are well-understood, and a clear family hierarchy is firmly in place.

In French families, as Druckerman describes them, parents are firmly in charge of their kids—instead of the American family style, in which the situation is all too often vice versa.”

In the case of ADHD, it looks like the French have got it right; but not sadly for autism.

Knowing many different nationalities, I can certainly confirm that French parenting is much tougher than the UK or US variety.  The UK variety is very similar to the US, but without the liberal use of drugs for ADHD or indeed autism.

In tough cases of ADHD, that even French parenting cannot control, perhaps it really is a calcium channelopathy.  Perhaps in these cases a mild calcium channel blocker like fish oil, or indeed Olive Leaf Extract may be potent enough, so you could use these daily without the need for any prescription medication.

In any case, Verapamil, if shown effective, looks a much safer bet than the usual ADHD stimulants like Ritalin.  If your ADHD was caused by calcium channel dysfunction, it would likely later appear elsewhere in your body; all those years on stimulants would not have helped you.

Recall that Verapamil can also be effective in bipolar.