Averting Autism - Antenatal Antioxidants? But Male, Female or Both?

 

 Salem College

 

Today’s post is the first of two new ones about preventing/minimizing future autism.  The second post will be about Dr Ramaekers’ idea of using Calcium Folinate, which he has already put into use in human parents seeking to avoid autism in their next child. 

Before we start, I should point out that while readers of this blog, and it seems Dr Ramaekers, likely wish that autism and its symptoms did not exist, there are some people, well paid to research autism, who think autism is a good thing. I really do wonder why such people receive any public funding and wonder what kind of University would employ such people. It is like researching deafness, but not wanting to treat it - better they stay home.

https://www.sciencedaily.com/releases/2020/08/200824091958.htm

Simon Baron-Cohen, PhD, Director of the Autism Research Centre at Cambridge, who co-led the study, added, "Some people may be worried that basic research into differences in the autistic and typical brain prenatally may be intended to 'prevent,' 'eradicate,' or 'cure' autism. This is not our motivation, and we are outspoken in our values in standing up against eugenics and in valuing neurodiversity. Such studies will lead to a better understanding of brain development in both autistic and typical individuals."

Even more odd is that Baron-Cohen's sister had a rare mutation of the GNAQ gene that led to intellectual disability and a reduced lifespan. Why would you not want to treat/prevent that?  Treating your sister would not have meant you did not value her, it would have been another sign that you loved her. 

A positive example is another autism researcher, Manuel Casanova, and his family, who set up a research effort for people who have a disorder related to the gene NGLY1.  Sadly, Manuel's grandson passed away, but the research goes on.   

If you can escape from intellectual disability, someone should make it happen.  That someone might be you.

 

I must admit I had never heard of Salem College.  It is an all-female college in Winston-Salem, North Carolina.  It is the source of another idea to avert autism, this time treating the future father with an anti-oxidant like NAC.  NAC was already on my list for future mothers.  When it comes to autism, it looks like little Salem College is going to be more useful than stuffy old Cambridge University.

I am rather surprised there still are all female colleges, but in the US, there are many.

My mother went to an all-female college at Cambridge University, back then they had no mixed colleges.  Only after 1948 could women even receive a degree at the end of their studies. Cambridge University still has three all-female colleges.

Clearly male post-conception antioxidant supplementation is not going to help.

We have already seen in the research that the future father can damage the DNA he passes on to his offspring.  This was done via epigenetic tags on his DNA caused by things like recreational drug use, or smoking tobacco.

The author of today’s paper look’s exclusively at autism risk from the father, but exactly the same therapy during pregnancy can reduce risk from the mother.  The maternal immune activation model is one of the most studied in autism. We also know that emotional stress during pregnancy increases autism risk.  Emotional stress leads to oxidative stress.

The only issue I had with this preventative approach is whether there are any negative effects from antioxidants during pregnancy.  There may well be none, since the body just adjusts production of its own antioxidants.

There was an interesting experiment I mentioned a while back about giving antioxidant or “detox” juices to healthy young people.  The anti-oxidants from the fruits just made the body reduce its own production of GSH/glutathione, so the net result of the detox juice was actually negative.  People in oxidative stress benefit from anti-oxidant therapy, everyone else is wasting their money.

There are highly conflicting reports as to whether autism tends to come from the mother’s half of the child’s DNA or from the father’s half.  In reality it does not matter, it can from either, both or neither.  What is important is to take whatever simple safe steps you can to avert future autism. 

Future parents taking NAC and Calcium Folinate, might as well join the idea of keeping pets at home during pregnancy to get exposure to the evolutionarily expected bacteria that are needed to calibrate the immune system of the fetus/baby. Humans have been living with dogs, and very importantly their bacteria, for 11,000 years.  Only very recently did humans come up with the idea of trying to kill 99.9% of bacteria in their homes. 

Dogs are humans' oldest companions, DNA shows

I really do not see anyone doing a placebo controlled clinical trial on any of this.  Nobody who agrees to participate will accept the risk of being in the placebo group.  You would have to create a control group out of people who did not want to join the trial.  The people who join the trial are self-selected and are more likely to be health conscious, or have a family history of autism or dys-something else.

Male preconception antioxidant supplementation may lower autism risk: a call for studies

Current research indicates that a sizable number of autism spectrum disorder (ASD) cases arise from de novo mutations (DNMs) occurring within the paternal germline, usually in an age-dependent manner. Andrologists have reported that somatic cells and gametes share the same pathologies that generate these DNMs—specifically, DNA hypomethylation caused by oxidative nucleoside base damage. Because many ASD researchers seek to identify genetic risk factors, teams are developing methods of assessing aberrant DNA patterns, such as parental gonadal mosaicism. Several studies propose antioxidant supplementation as a strategy to lower autism risk, and/or suggest connections between childhood neurodevelopmental disorders such as autism and paternally-derived DNMs. Actual data, however, are currently not available to determine whether male preconception antioxidant supplementation effectively lowers autism risk. The purpose of this paper is to (1) explore the mechanisms causing DNMs, specifically DNA hypomethylation; (2) explain how antioxidant supplementation may lower the risk of having a child with ASD; and, (3) advocate for the implementation of large prospective studies testing (2). These studies may very well find that male preconception supplementation with antioxidants prevents neurodevelopmental disorders in offspring, in much the same way that female prenatal consumption of folate was found to decrease the risk of birth defects. If this is indeed the case, the alarming rise in autism prevalence rates of the past few decades will slow—or even cease—upon the initiation of public awareness campaigns.

  

Antenatal antioxidants to avert autism?

Paternally derived de novo mutations (DNMs) caused by oxidative stress (OS) have been implicated in the development of autism spectrum disorders (ASDs). Whether preconception antioxidant supplementation can reduce the incidence of ASDs by reducing OS is an area of uncertainty and potentially important future scientific investigation.

The recently completed double blind, multicenter, randomized controlled Males, Antioxidants, and Infertility (MOXI) trial by the Reproductive Medicine Network (RMN), funded by the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD), investigated whether antioxidants improve male fertility, as measured by semen parameters and sperm DNA integrity at 3 months and pregnancy by 6 months of treatment [11]. The RMN investigators found that antioxidant treatment of the male partner does not improve semen parameters, sperm DNA integrity, or in vivo pregnancy rates in couples with male factor infertility, prompting the question whether antioxidant therapy should no longer be routinely recommended for infertile men [12]. It would be intriguing to evaluate the offspring from the participant couples of the MOXI trial for ASD. However, with only 13 live births in the antioxidant group and 21 live births in the placebo arm, the study would be vastly underpowered to demonstrate a benefit of antioxidants in the prevention of a condition with an incidence of 1 in 54 children.

The next post is about Dr Ramaeker's clinical trial of calcium folinate in children with autism and his comments about their parents and future siblings.

 

Lethargy and Autism

 

That alternative world, where you fix things when they are not working

I do sometimes forget the world that most people live in, when it comes to (not) understanding and (not) treating autism.

I decided to write this post on lethargy and autism, after being prompted by a friend who contacted me and told me that his son with autism is very lethargic (physically and mentally). I replied with the suggestion that he try a little scoop of Agmatine Sulphate.  Now his son is able to go for long walks, without constantly wanting to stop for a rest.  The Dad asked me to share his positive experience with Agmatine.

A few years ago, this boy was diagnosed by Dr Kelley with mitochondrial dysfunction.  People with mitochondrial dysfunction should indeed have poor exercise endurance, this is because they lack the enzymes needed in a process called oxidative phosphorylation (OXPHOS).  OXPHOS is the metabolic pathway in which cells use enzymes to oxidize nutrients, thereby releasing the chemical energy in the form of ATP.  If you run low on ATP you need to sit and take a rest.

You can run low on ATP for reasons other than a lack of these mitochondrial enzyme complexes. You also need enough glucose and oxygen.

Agmatine has numerous modes of action.  It affects the following (and more): -

·         Neurotransmitter receptors and receptor ionophores. Nicotinic, imidazoline I1 and I2, α2-adrenergic, glutamate NMDAr, and serotonin 5-HT2A and 5HT-3 receptors.

·         Ion channels. Including: ATP-sensitive K+ channels, voltage-gated Ca²⁺ channels, and acid-sensing ion channels (ASICs).

·         Membrane transporters. Agmatine specific-selective uptake sites, organic cation transporters (mostly OCT2 subtype), extraneuronal monoamine transporters (ENT), polyamine transporters, and mitochondrial agmatine specific-selective transport system.

·         Nitric oxide (NO) synthesis modulation. Both differential inhibition and activation of NO synthase (NOS) isoforms is reported.^[9][10]

·         Polyamine metabolism. Agmatine is a precursor for polyamine synthesis, competitive inhibitor of polyamine transport, inducer of spermidine/spermine acetyltransferase (SSAT), and inducer of antizyme.

·         Protein ADP-ribosylation. Inhibition of protein arginine ADP-ribosylation.

·         Matrix metalloproteases (MMPs). Indirect down-regulation of the enzymes MMP 2 and 9.

·         Advanced glycation end product (AGE) formation. Direct blockade of AGEs formation.

·         NADPH oxidase. Activation of the enzyme leading to H₂O₂ production.^[11]

 

I did make the chart below a couple of years ago to figure out why Agmatine would give such an energy boost, and see how all these substances fit in with each other.  My conclusion was that an increase in endothelial nitric oxide was a plausible explanation, since the effect is fast.

Agmatine increases the enzyme eNOS which the leads to nitic oxide (NO) being produced in endothelial cells, this triggers a series of steps that results in vascular relaxation, which means more blood flow.

More blood flow means more glucose and oxygen to fuel mitochondria to make ATP.

 

When I did a quick Google search for “Lethargy and Autism”, I was surprised to find an entirely different explanation from the “old world”, where autism is still untreatable, at the UK’s National Autistic Society.

 

Autistic fatigue - a guide for parents and carers

Exhaustion (fatigue) and then burnout can happen to anybody. Being autistic can make fatigue and burnout more likely, due to the pressures of social situations and sensory overload. If your child or the person you care for is experiencing fatigue or burnout, helping them to manage their energy levels is essential, as this guide explains. 

There are various things that can cause autistic fatigue. Autistic adults suggest several causes, including: 

·        sensory overload 

·        dealing with social situations 

·        masking or camouflaging their autistic traits

·        suppressing stimming 

·        a sense of not meeting other people’s/society’s expectations of them.

Changes in your routines or day-to-day life, such as a change of school or job, can increase anxiety and can be additional causes for autistic fatigue and burnout.

 

What can I do if the person I care for is experiencing autistic fatigue and burnout?

Use energy accounting

Energy accounting is a system used to set manageable limits on your energy levels so you do not deplete yourself to the point of burnout. 

Help your child or the person you care for to set a limit on how much energy they have in a day or week and estimate how much certain activities drain them. Also work out how much certain activities energise them. 

You can then try to plan and balance their activities and energy over a day or week to try and manage stress limits. Make sure you build in time for relaxation and recovery. 

 

Time off and rest/relaxation

Whether you use energy accounting or not, time off from work or school and other high-stress activities is key to managing stress levels. Ensuring time for activities/interests that re-energise and promote relaxation is key. This could be connecting with family and friends or enjoying hobbies or interests. 

 

Time without having to mask

Autistic people often feel the need to hide or mask their autistic traits in public, for example by suppressing the urge to stim. It can be important to factor times into your child’s day for things like stimming, somewhere they feel comfortable and able to do so.

  

Conclusion

Lethargy with autism in this blog is a biologically treatable condition.

Taking time off to rest is not a cure for lethargy, it is just a coping strategy.

Why just cope, when you can live to your full potential?

The bunny managed to figure this out. (fit alkaline batteries)

 

You would think that hyperactivity would be more often a problem than lethargy in those with autism, but that is another story.

Metyrosine, Intranasal Suramin and Visbiome/Viviomixx for Autism?

 

Our reader Natasa brought to my attention various things recently; this included the fact that intranasal delivery of Suramin for autism is being developed and the repurposing of an old drug called Metyrosine for autism.

I also noted a recent study that used a popular probiotic formerly called VSL#3, now called Visbiome/Viviomixx. This is interesting because it found that autistic people without GI dysfunction benefited.  The study had a high drop out rate and the improvement was not huge. Visbiome/Viviomixx is pricey for a probiotic, but not the price of two Ferraris like Metyrosine.

 

Suramin Nasal Spray -  PAX 102

Suramin is Dr Naviaux’s idea to treat autism and indeed several other conditions. Suramin is an existing drug approved outside the USA and made by Bayer.  Clearly Dr Naviaux’s new partner Paxmedica was not able to make a deal with Bayer, so they have to figure out themselves how to manufacture Suramin, which loses more time.  The good news is that they are working on intranasal delivery, the traditional way to delivery Suramin is by injection.

Research showed that the effect of Suramin is lost after a few weeks, so quite frequent injections would be needed.  Intranasal delivery has the advantage of avoiding injections and hopefully reduces the side effects of Suramin.

 

https://www.paxmedica.com/pipeline

 

  Metyrosine

  

 Metyrosine looks very interesting, until you see the price.

Metyrosine is yet another old generic drug, from 40 years ago, that can be used to lower blood pressure.  It inhibits the enzyme tyrosine hydroxylase and, therefore, catecholamine synthesis, which, as a consequence, depletes the levels of the catecholamines dopamine, adrenaline and noradrenaline in the body.

Metyrosine seems to have been forgotten about as a cheap hypertensive drug, but was repositioned as an ultra-expensive drug for a rare condition called Pheochromocytoma (PHEO).  PHEO is a rare tumor of the adrenal gland; these tumors are capable of producing and releasing massive amounts of catecholamines, metanephrines, or methoxytyramine, which result in the most common symptoms, high blood pressure, fast heart rate, and sweating.

Unfortunately, Metyrosine (brand name Demser) has become one of the world’s most expensive drugs, costing up to $30,000 a month.

Old posts on catecholamines:-

Secondary Monoamine Neurotransmitter Disorders in Autism – Treatment with 5-HTP and levodopa/carbidopa?

Catecholamines and Autism

Metyrosine for Autism

The proposed mechanism of action for the treatment of ASD is consistent with the assumption that an imbalance exists between catecholaminergic systems and the modulators of aminergic systems in the CNS and periphery.  Excess levels of nerve growth factor (NGF) and brain-derived NGF (BNGF), which are released into the catecholamine synaptic cleft, can cause branching and arborization of synaptic terminals, thus increasing the strength of catecholaminergic neurotransmission. Because growth factors are a component in these synapses, elevated levels of NGF and BNGF become chronic, along with elevated levels of dopamine and other catecholamines from these hypertrophic nerve terminals. The result may be a hypertrophy of the synaptic architecture, resulting in a persistent imbalance between aminergic systems and their offsets, which can lead to overstimulation of some CNS tracts and depletion of others. Consequently, increased dopamine activity within the CNS and the gut is associated with ASD, repetitive stereotyped behaviors, and defiant and anxiety disorders.  By reducing presynaptic catecholamine synthesis, storage, and release, Metyrosine/L1-79 may reduce the associated release of NGF and BNGF, rebalancing catecholaminergic mechanisms in the brain, gut, mesentery, and elsewhere. These effects are not mimicked by receptor-blocking agents that reduce postsynaptic depolarization without addressing the underlying hypertrophic dendritic architecture.  If this proposed mechanism of action in ASD is correct, reduced catecholamine synthesis, storage, and release should improve ASD symptoms. In the long term, reducing catecholamine release may enable the hypertrophic sympathetic nervous system to regress to a homeostatic configuration.

 

I suppose to get a unique patent, the developer has decided to use a different version of Metyrosine.

Their version, L1-79, is slightly different to Metyrosine

Metyrosine is the L-isomer of amethylparatyrosine.

L1-79 is a mixture of the L-isomer of amethylparatyrosine and the D-isomer amethylparatyrosine.

Metyrosine is already an approved agent, and the US Food and Drug Administration  guidance states that any stereoisomer of an approved agent can be considered to be the same agent, so the developer can treat their drug L1-79 as being an FDA approved drug (but not yet approved for autism as the use).

 

Effect of L1-79 on Core Symptoms of Autism Spectrum Disorder: A Case Series

Purpose:

This study examines the effects of the tyrosine hydroxylase inhibitor L1-79, a racemic formulation of a-methylparatyrosine, in patients with autism spectrum disorder (ASD) in a prospective case series. The L-isomer formulation of amethylparatyrosine, metyrosine, is approved for the management of patients with pheochromocytoma.

Methods:

Six male and 2 female patients aged 2.75 to 24 years with ASD were treated for 8 weeks at L1- 79 doses ranging from 90 to 400 mg thrice daily. Assessments at weekly intervals included the Aberrant Behavior Checklist eCommunity (ABC-C), Connor's Parent Rating Scale (CPRS), and Clinical Global Impressions (CGI) scale. The Autism Diagnostic Observation Schedule (ADOS) was administered at baseline and week 10. Findings: The ABC-C and CPRS scores improved between baseline and end of study for 7 of 8 participants; most participants' assessment scores decreased. At week 8, the CGI efficacy index was 05 for 6 of 8 participants, indicating modest improvement with at least partial resolution of symptoms and no medication adverse effects, and 09 for 2 participants, indicating minimal improvement and no change in status or care needs, without adverse effects. The mean ADOS scores improved by 31% for 4 of the 6 participants tested, with 1 patient experiencing a 47% improvement. Seven of the 8 participants previously taking psychotropic medications were stable without their legacy medications while receiving L1-79, and 1 patient resumed a single legacy medication at a lower dose. Three adverse events were reported; symptoms were mild and resolved without change in therapy.

Implications:

These results suggest L1-79 may be a tolerable and effective treatment for the core symptoms of ASD, which must be confirmed with double-blind studies.

 

The trial was very small, but if you look at the results, half of the participants were big-time responders.

If Metyrosine was still a cheap antihypertensive drug it would be very interesting.

Unfortunately, there is a clear trend to withdraw cheap generic drugs that can be repurposed and then bring them back as ultra expensive drugs for the new use.

Sadly, autism will need polytherapy, so you may need 5 drugs.  Nobody can afford 5 ultra-expensive drugs.

 

Viviomixx/ Visbiome for those without GI dysfunction 

Italians like probiotics and the study below is from Italy.  It uses the De Simone Formulation (DSF) which became well known as VSL#3, but following legal disputes is now marketed as Vivomixx in EU, Visbiome in USA.

The study does suggest that those without any GI dysfunction may benefit from this product. These people are in the “NGI group”, in the paper below.

We already know that some people with autism and GI dysfunction do benefit from this product, which is widely used by people with all kinds of GI dysfunction.  Clearly if you reduce GI dysfunction, behavior is likely to improve.

It is more potent than many probiotics.

Each packet contains 450 billions bacteria from eight probiotic strains:

·        Streptococcus thermophilus DSM24731

·        Bifidobacterium breve DSM24732

·        Bifidobacterium longum DSM24736

·        Bifidobacterium infantis DSM24737

·        Lactobacillus acidophilus DSM24735

·        Lactobacillus plantarum DSM24730

·        Lactobacillus paracasei DSM24733

·        Lactobacillus delbrueckii ssp. bulgaricus DSM24734

 

The beneficial effect was there, but not huge.

 

No differences between groups were detected on the primary outcome measure, the Total Autism Diagnostic Observation Schedule - Calibrated Severity Score (ADOS-CSS). An exploratory secondary analysis on subgroups of children with or without Gastrointestinal Symptoms (GI group, n= 30; NGI group, n=55) revealed in the NGI group treated with probiotics a significant decline in ADOS scores as compared to that in the placebo group, with a mean reduction of 0.81 in Total ADOS CSS and of 1.14 in Social-Affect ADOS CSS over six months. In the GI group treated with probiotics we found greater improvements in some GI symptoms, adaptive functioning, and sensory profiles than in the GI group treated with placebo. These results suggest potentially positive effects of probiotics on core autism symptoms in a subset of ASD children independent of the specific intermediation of the probiotic effect on GI symptoms. Further studies are warranted to replicate and extend these promising findings on a wider

 

Viviomixx/Visbiome is one of the expensive probiotics, but it is one of the serious ones. It looks like some people without GI issues are likely to benefit to some degree.  Is it worth the expense?  You would have to try it.

We have seen case histories of people with autism, and severe GI issues, greatly improving with VSL#3/ Viviomixx/Visbiome.

 

Effects of Probiotic Supplementation on Gastrointestinal, Sensory and Core Symptoms in Autism Spectrum Disorders: A Randomized Controlled Trial

Participants were randomly assigned to probiotics (De Simone Formulation) (n=42) or placebo (n=43) for six months. Sixty-three (74%) children completed the trial. No differences between groups were detected on the primary outcome measure, the Total Autism Diagnostic Observation Schedule - Calibrated Severity Score (ADOS-CSS). An exploratory secondary analysis on subgroups of children with or without Gastrointestinal Symptoms (GI group, n= 30; NGI group, n=55) revealed in the NGI group treated with probiotics a significant decline in ADOS scores as compared to that in the placebo group, with a mean reduction of 0.81 in Total ADOS CSS and of 1.14 in Social-Affect ADOS CSS over six months. 

In the GI group treated with probiotics we found greater improvements in some GI symptoms, adaptive functioning, and sensory profiles than in the GI group treated with placebo. These results suggest potentially positive effects of probiotics on core autism symptoms in a subset of ASD children independent of the specific intermediation of the probiotic effect on GI symptoms. Further studies are warranted to replicate and extend these promising findings on a wider population with subsets of ASD patients which share targets of intervention on the microbiota-gut-brain axis.

 

A novel and promising finding of our study is the significant decline in ADOS CSS scores (both Total and Social-Affect scores) in the NGI group treated with probiotics as opposed to those obtained in the placebo group. This result, although deriving from a secondary analysis, is particularly important from a clinical point of view, especially in the light of the abovementioned psychometric properties of the used tool. In fact, a mean reduction of 0.81 in Total ADOS CSS and of 1.14 in Social-Affect ADOS CSS over six months constitutes a clinically significant decrease of ASD symptoms (34). Not all previous trials with probiotics examined their effect taking into consideration the presence/absence of GI symptoms (25). Our result suggests that ASD children with and without GI symptoms could represent two different populations and that probiotics interventions could potentially provide different effects, likely due to distinct microbiota targets. Previous studies have already suggested that differences in microbiome (45, 46) are independent from GI dysfunction, and Luna et al. (45) argued that larger and well-designed studies are still needed to determine whether microbial composition may stratify ASD children beyond the GI symptoms. Within this framework, a positive impact of probiotics on autism severity in children without pre-existing GI symptoms supports the complexity of the microbiota-gut-brain axis warranting further studies on this subgroup of ASD subjects.

 

 

In the subgroup of children with GI symptoms we found a positive effect of probiotics not only on GI symptoms, but also on adaptive functioning, developmental pathways, and multisensory processing, the latter now reported by the DSM-5 (1) among core symptoms of ASD.

Taken together, these different results on NGI and GI groups of children suggest that the effects of probiotic supplementation in ASD children may be due to distinct mechanisms. The well-known neurobiological heterogeneity of ASD implies that each medication is likely to benefit only a subset within the spectrum of affected children, as suggested by results of pharmacological trials in this population (49, 50). The described positive effect on both GI and NGI children paves the way for the identification of those ASD subjects who can respond to probiotic supplementation beyond the presence of GI symptoms, and even beyond GI inflammatory status. In fact, in the current study, the supplementation with DSF compared with placebo resulted in no significant effects on the levels of plasma and fecal inflammatory biomarkers. In a previous investigation, we have reported that the values of these biomarkers were in the normal range already at baseline (51); thus, we do not confirm the two previous studies (52, 53) reporting some positive effects of probiotics on biomarkers of inflammation, and we could hypothesize that the effect of probiotics on adaptative functioning is not mediated by a reduction in systemic or intestinal inflammation.

 

Efficacy: Secondary Exploratory Analyses on GI and NGI Parallel Arms

One of the original aims of this study was to evaluate the effects of probiotics on ASD core symptoms, GI symptoms, and plasma and fecal inflammatory biomarkers in ASD children with and without GI symptoms. For this purpose the randomization was made independently in the GI and NGI groups, to obtain four parallel arms. At the end of recruitment, the sample size of each arm did not reach the target already determined for the whole sample; the GI group, already less numerous, was also affected by a bigger drop-out rate than the NGI one. Therefore, secondary exploratory analyses among subgroups were performed. The four parallel arms were well balanced for the total number of hours of rehabilitative treatments (GI placebo: 175± 91, GI Probiotic 156 ± 68, NGI placebo 134± 84, NGI probiotic 137 ± 129 p>0.05 for all the comparisons).

In the NGI group we found a significant decrease both in the primary outcome measure, Total ADOS-CSS scores (which decreased from 6.72 to 5.91 in the probiotic group and increased from 6.96 to 7.17 in the placebo group; mean change probiotic vs placebo, - 0.81 vs + 0.21 [95%CI, -0.76 to +0.20]; P = 0.026), and in Social-Affect ADOS-CSS (mean change probiotic vs placebo -1.14 vs -0.04 [95%CI, -1.01 to +0.06]; P = 0.027).

In the GI group, statistically significant effects were found in GI symptoms (Total GSI, Total 6-GSI, stool smell and flatulence mean scores), and in adaptive functioning (Receptive Skills, Domestic Skills and Coping Skills VABS-II subscales) for which probiotic therapy was associated with greater improvements than placebo (Table 3). In addition, in the GI group a significantly higher proportion of children in the probiotic group than in placebo group showed a normalization of Sensory Profile scores in the Multisensory Processing subscale (p= 0.013): the scores improved in 87% vs 28%, respectively, and got worse in 0% vs 42%, respectively (Tables S4, S5).

 

 

 

Several limitations must be noted. Firstly, the large dropout rates, although satisfactory considering the duration of the study, may have affected the trial’s ability to reliably detect significant differences between the two main treatment groups. This seems to have affected particularly the subjects within the GI group, in which almost half of participants dropped out, mostly in the placebo group (as reported in Figure 1). We could speculate that parents of these children had more expectations about the efficacy of the probiotic supplementation on GI symptoms than parents of children within the NGI group. For this reason, they could be disappointed when the treatment (or placebo) was not fully effective on GI symptoms of their children, dropping out of the trial without waiting for its possibile positive effects on core and developmental symptoms. Consequently, children who dropped out were substantially comparable to children who completed the trial in all clinical variables, with the exception of higher levels of GI symptoms. This discrepancy between the two groups could impact the study’s ability to detect other possible significant differences in the whole spectrum of GI symptoms. A second limit is that the use of the ADOS-CSS evaluation as an outcome measure in clinical trials has been recently disputed (43), mostly because it lacks sensitivity to detect changes in short time periods.

 

 

In conclusion, a six-month probiotic supplementation did not result in statistically significant changes in autism symptoms in the whole sample of ASD preschoolers. Nevertheless, for the first time at our knowledge, we have observed in children without GI symptoms treated with probiotics significant modification of core ASD symptoms measured by the ADOS-CSS scores (specifically Social-Affect domain) that are unrelated to the specific intermediation of the probiotic effect on GI symptoms. As far as children with GI symptoms, the six-month supplementation with DSF showed significant effects, when compared to placebo, in improving not only GI symptoms but also multisensory processing and adaptive functioning.

All these findings could pave the way for further studies on larger subgroups of ASD with the aim of improving precision medicine in ASD.

 

  

Conclusion

I am a big fan of affordable drug therapy.

There are some extremely clever one-off therapies that cost more than $1 million.  That seems OK, you give it to a baby who then may go on to have a normal life, but someone has to pay.

 

A $2.1 Million Drug for a Deadly Childhood Disease Is Approved by FDA

A potential cure for a lethal childhood disorder -- the first of its kind in the U.S. -- is hitting the market at a cost of $2.1 million, paving the way for more therapies that bring dramatic benefits for patients, along with challenges for health-care systems.

The U.S. Food and Drug Administration on Friday approved Novartis AG’s Zolgensma, a gene therapy targeting children under two years old who have a severe illness called spinal muscular atrophy. The Swiss drugmaker said it’s offering novel payment options, including spreading out the costs over time, refunds for patients whose treatment fails and discounts for insurers that provide swift coverage. 

What looks really unacceptable is repurposing a cheap existing approved drug and then charging a King’s ransom for it.

It is very expensive, and hugely risky, to develop a new drug, much less so to repurpose an old one.

Repurposing a cheap drug does cost money and somebody has to pay for this, and also the risk of it not being successful.

All the autism start-ups think they are entering a $2 billion a year market, but they neglect the fact that people with severe autism will likely need polytherapy.  They think people will pay $50,000 a year for a drug, but what if you really need 3 or 4 of these clever drugs?

Take Knut’s idea to repurpose Ponstan.  This NSAID is sold OTC in many countries for a few dollars.  Is it realistic to charge $50,000 for a slightly modified autism version?  In the case of Ponstan, this would be a preventative therapy for just a few years.

Metyrosine was probably another three dollar drug, before it stopped being used.  Now a one month supply costs $30,000.