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Showing posts with label AMD. Show all posts
Showing posts with label AMD. Show all posts

Wednesday 18 January 2017

The Clever Ketogenic Diet for some Autism


I have covered the Ketogenic Diet (KD) in earlier posts. 

There are more and more studies being published that apply the KD to mouse models of autism.

Calling the KD a diet does rather under sell it.  The classic therapeutic ketogenic diet was developed for treatment of pediatric epilepsy in the 1920s and was widely used into the next decade, but its popularity waned with the introduction of effective epilepsy drugs.

There are various exclusion diets put forward to treat different medical conditions; some are medically accepted but most are not, but that does not mean they do not benefit at least some people.

When it comes to the ketogenic diet (KD) the situation is completely different, this diet is supposed to be started in hospital and maintained under occasional medical guidance. The KD was developed as a medical therapy to treat pediatric epilepsy.  It is very restrictive which is why it is used mainly in children, since they usually will (eventually) eat what is put in front of them.

The KD was pioneered as a medical therapy by researchers at Johns Hopkins in the 1920s, over the years they have shown that most of the benefit of the KD can be achieved by the much less restrictive Modified Atkins Diet (MAD).  The first autism mouse study below suggests something similar “Additional experiments in female mice showed that a less strict, more clinically-relevant diet formula was equally effective in improving sociability and reducing repetitive behavior”.


What about the KD in Autism?

Most people with autism, but without epilepsy, will struggle to get medical help to initiate the KD.  Much research in animal models points to the potential benefit of the KD.




·        Drug treatments are poorly effective against core symptoms of autism.


·        Ketogenic diets were tested in EL mice, a model of comorbid autism and epilepsy.


·        Sociability was improved and repetitive behaviors were reduced in female mice.


·        In males behavioral improvements were more limited.


·        Metabolic therapy may be especially beneficial in comorbid autism and epilepsy.


The core symptoms of autism spectrum disorder are poorly treated with current medications. Symptoms of autism spectrum disorder are frequently comorbid with a diagnosis of epilepsy and vice versa. Medically-supervised ketogenic diets are remarkably effective nonpharmacological treatments for epilepsy, even in drug-refractory cases. There is accumulating evidence that supports the efficacy of ketogenic diets in treating the core symptoms of autism spectrum disorders in animal models as well as limited reports of benefits in patients. This study tests the behavioral effects of ketogenic diet feeding in the EL mouse, a model with behavioral characteristics of autism spectrum disorder and comorbid epilepsy. Male and female EL mice were fed control diet or one of two ketogenic diet formulas ad libitum starting at 5 weeks of age. Beginning at 8 weeks of age, diet protocols continued and performance of each group on tests of sociability and repetitive behavior was assessed. A ketogenic diet improved behavioral characteristics of autism spectrum disorder in a sex- and test-specific manner; ketogenic diet never worsened relevant behaviors. Ketogenic diet feeding improved multiple measures of sociability and reduced repetitive behavior in female mice, with limited effects in males. Additional experiments in female mice showed that a less strict, more clinically-relevant diet formula was equally effective in improving sociability and reducing repetitive behavior. Taken together these results add to the growing number of studies suggesting that ketogenic and related diets may provide significant relief from the core symptoms of autism spectrum disorder, and suggest that in some cases there may be increased efficacy in females.






·        The BTBR mouse has lower movement thresholds and larger motor maps relative to control mice.


·        The high-fat low-carbohydrate ketogenic diet raised movement thresholds and reduced motor map size in BTBR mice.


·        The ketogenic diet normalizes movement thresholds and motor map size to control levels.


Autism spectrum disorder (ASD) is an increasingly prevalent neurodevelopmental disorder characterized by deficits in sociability and communication, and restricted and/or repetitive motor behaviors. Amongst the diverse hypotheses regarding the pathophysiology of ASD, one possibility is that there is increased neuronal excitation, leading to alterations in sensory processing, functional integration and behavior. Meanwhile, the high-fat, low-carbohydrate ketogenic diet (KD), traditionally used in the treatment of medically intractable epilepsy, has already been shown to reduce autistic behaviors in both humans and in rodent models of ASD. While the mechanisms underlying these effects remain unclear, we hypothesized that this dietary approach might shift the balance of excitation and inhibition towards more normal levels of inhibition. Using high-resolution intracortical microstimulation, we investigated basal sensorimotor excitation/inhibition in the BTBR T + Itprtf/J (BTBR) mouse model of ASD and tested whether the KD restores the balance of excitation/inhibition. We found that BTBR mice had lower movement thresholds and larger motor maps indicative of higher excitation/inhibition compared to C57BL/6J (B6) controls, and that the KD reversed both these abnormalities. Collectively, our results afford a greater understanding of cortical excitation/inhibition balance in ASD and may help expedite the development of therapeutic approaches aimed at improving functional outcomes in this disorder.





Background

Gastrointestinal dysfunction and gut microbial composition disturbances have been widely reported in autism spectrum disorder (ASD). This study examines whether gut microbiome disturbances are present in the BTBRT + tf/j (BTBR) mouse model of ASD and if the ketogenic diet, a diet previously shown to elicit therapeutic benefit in this mouse model, is capable of altering the profile.

Findings

Juvenile male C57BL/6 (B6) and BTBR mice were fed a standard chow (CH, 13 % kcal fat) or ketogenic diet (KD, 75 % kcal fat) for 10–14 days. Following diets, fecal and cecal samples were collected for analysis. Main findings are as follows: (1) gut microbiota compositions of cecal and fecal samples were altered in BTBR compared to control mice, indicating that this model may be of utility in understanding gut-brain interactions in ASD; (2) KD consumption caused an anti-microbial-like effect by significantly decreasing total host bacterial abundance in cecal and fecal matter; (3) specific to BTBR animals, the KD counteracted the common ASD phenotype of a low Firmicutes to Bacteroidetes ratio in both sample types; and (4) the KD reversed elevated Akkermansia muciniphila content in the cecal and fecal matter of BTBR animals.

Conclusions

Results indicate that consumption of a KD likely triggers reductions in total gut microbial counts and compositional remodeling in the BTBR mouse. These findings may explain, in part, the ability of a KD to mitigate some of the neurological symptoms associated with ASD in an animal model.





·        We evaluated, throughout a systematic review, the studies with a relationship between autism and ketogenic diet.


·        Studies points to effects of KD on behavioral symptoms in ASD through the improve score in Childhood Autism Rating Scale (CARS).


·        Reviewed studies suggest effects of KD especially in moderate and mild cases of autism.


·        KD in prenatal VPA exposed rodents, as well in BTBR and Mecp2 mice strains, caused attenuation of some autistic-like features.



Autism spectrum disorder (ASD) is primarily characterized by impaired social interaction and communication, as well as restricted repetitive behaviours and interests. The utilization of the ketogenic diet (KD) in different neurological disorders has become a valid approach over time, and recently, it has also been advocated as a potential therapeutic for ASD. A MEDLINE, Scopus and Cochrane search was performed by two independent reviewers to investigate the relationship between ASD and the KD in humans and experimental studies. Of the eighty-one potentially relevant articles, eight articles met the inclusion criteria: three studies with animals and five studies with humans. The consistency between reviewers was κ = 0.817. In humans, the studies mainly focused on the behavioural outcomes provided by this diet and reported ameliorated behavioural symptoms via an improved score in the Childhood Autism Rating Scale (CARS). The KD in prenatal valproic acid (VPA)-exposed rodents, as well as in BTBR and Mecp2 mice strains, resulted in an attenuation of some autistic-like features. The limited number of reports of improvements after treatment with the KD is insufficient to attest to the practicability of the KD as a treatment for ASD, but it is still a good indicator that this diet is a promising therapeutic option for this disorder.



Conclusion

Since very many parents do not want to use drugs to treat autism, it is surprising more people do not try the ketogenic diet (KD) or at least the KD-lite, which is the Modified Atkins Diet (MAD).
I think you have to be pretty rigid about the MAD, if you go MAD-lite you will likely achieve little; rather like thinking you have a Mediterranean diet because you buy the occasional bottle of olive oil.
Many children with epilepsy who started out on the KD continue in adulthood with the Modified Atkins Diet (MAD).
There is anecdotal evidence that people with mitochondrial disease benefit from the KD.
All in all, it is hard to argue that the KD/MAD should not be the first choice for those choosing to treat autism by diet. It really does have science and clinical study to support it.

In some people with autism it appears that when you eat is as important as what you eat.  There can be strange behaviors just after eating, presumably caused by a spike in blood sugar, or for others before breakfast. 

In regressive autism (AMD) Dr Kelley, from Johns Hopkins, wrote that:- 


Another important clinical observation is that many children with mitochondrial diseases are more symptomatic (irritability, weakness, abnormal lethargy) in the morning until they have had breakfast, although this phenomenon is not as common in AMD as it is in other mitochondrial diseases.  In some children, early morning symptoms can be a consequence of compromised mitochondrial function, whereas, in others, a normal rise in epinephrine consequent to a falling blood glucose level in the early morning hours can elicit agitation, ataxia, tremors, or difficulty waking.  In children who normally sleep more than 10 hours at night, significant mitochondrial destabilization can occur by the morning and be evident in biochemical tests, although this is less common in AMD than in other mitochondrial disorders.  When early morning signs of disease are observed or suspected, giving uncooked cornstarch (1 g/kg; 1 tbsp = 10g) at bedtime effectively shortens the overnight fasting period.  Uncooked cornstarch, usually given in cold water, juice (other than orange juice), yogurt, or pudding, provides a slowly digested source of carbohydrate that, in effect, shortens overnight fasting by 4 to 5 hours.



I still find it rather odd that none of Dr Kelley's work on treating regressive autism has been published in any scientific or medical journal.  After all, he was a leading staff member at one of the world's leading hospitals.  He is no quack.  It is extremely wasteful of knowledge and clinical insights that could help improve the lives of something greater than 0.2% of the world's young children.  That is a lot of people.












Tuesday 8 March 2016

Meldonium/Mildronate for Athletic Performance, but seemingly also for Mitochondria, Neuroinflammation, Cognition and Alzheimer’s





What you see is what you get,
not what you see is what he took.



Today’s post is another very short one.

You may have seen that Maria Sharapova, the tennis player has got into trouble for taking a Latvian drug called Meldonium/Mildronate for the last decade.


Like many people, I did a quick check on this drug to see what it does and if you could innocently not know that it is performance enhancing.  Well it does lots of performance enhancing things like increasing blood flow and increasing your capacity to exercise.


What drew my attention was its effect on mitochondria, cognition and even as a potential Alzheimer’s Therapy.

I should point out that Bumetanide, the most effective Autism therapy my son uses, is also a banned substance under the World Doping Agency rules.  Bumetanide and other diuretics are used as masking agents by athletes taking performance enhancing drugs.  


Mildronate

Mildronate is a Latvian drug, widely prescribed across the former Soviet Union.

For people with autism who respond to carnitine therapy, or with a diagnosed mitochondrial disorder it looks very interesting.  There really are no approved treatments that reverse such disorders, just to stop them getting worse.

Mildronate also shows some promise for both Parkinson’s and Alzheimer’s disease in animal models.


Mildronate improves cognition and reduces amyloid-β pathology in transgenic Alzheimer's disease mice

 

Mildronate, a carnitine congener drug, previously has been shown to provide neuroprotection in an azidothymidine-induced mouse model of neurotoxicity and in a Parkinson's disease rat model. The aim of this study was to investigate the effects of mildronate treatment on cognition and pathology in Alzheimer's disease (AD) model mice (APP(SweDI)). Mildronate was administered i.p. daily at 50 or 100 mg/kg for 28 days. At the end of treatment, the animals were behaviorally and cognitively tested, and brains were assessed for AD-related pathology, inflammation, synaptic markers, and acetylcholinesterase (AChE). The data show that mildronate treatment significantly improved animal performance in water maze and social recognition tests, lowered amyloid-β deposition in the hippocampus, increased expression of the microglia marker Iba-1, and decreased AChE staining, although it did not alter expression of proteins involved in synaptic plasticity (GAP-43, synaptophysin, and GAD67). Taken together, these findings indicate mildronate's ability to improve cognition and reduce amyloid-β pathology in a mouse model of AD and its possible therapeutic utility as a disease-modifying drug in AD patients.





This review for the first time summarizes the data obtained in the neuropharmacological studies of mildronate, a drug previously known as a cardioprotective agent. In different animal models of neurotoxicity and neurodegenerative diseases, we demonstrated its neuroprotecting activity. By the use of immunohistochemical methods and Western blot analysis, as well as some selected behavioral tests, the new mechanisms of mildronate have been demonstrated: a regulatory effect on mitochondrial processes and on the expression of nerve cell proteins, which are involved in cell survival, functioning, and inflammation processes. Particular attention is paid to the capability of mildronate to stimulate learning and memory and to the expression of neuronal proteins involved in synaptic plasticity and adult neurogenesis. These properties can be useful in neurological practice to protect and treat neurological disorders, particularly those associated with neurodegeneration and a decline in cognitive functions.

The obtained data give a new insight into the influence of mildronate on the central nervous system. This drug shows beneficial effects in the regulation of cell processes necessary for cell integrity and survival, particularly by targeting mitochondria and by stabilizing the expression of proteins involved in neuroinflammation and neuroregeneration. These properties can be useful in neurological practice to protect and treat neurological disorders, such as Parkinson’s disease, diabetic neuropathies, and ischemic stroke. Moreover, because mildronate improves learning and memory, one may suggest mildronate as a multitargeted neuroprotective/ neurorestorative drug with its therapeutic utility as a memory enhancer in cognitive impairment conditions, such as neurodegenerative diseases, schizophrenia, and other pathologies associated with a decline in awareness.



Mildronate, a representative of the aza-butyrobetaine class of drugs with proven cardioprotective efficacy, was recently found to prevent dysfunction of complex I in rat liver mitochondria. The present study demonstrates that mildronate also acts as a neuroprotective agent. In a mouse model of azidothymidine (anti-HIV drug) neurotoxicity, mildronate reduced the azidothymidine-induced alterations in mouse brain tissue: it normalized the increase in caspase-3, cellular apoptosis susceptibility protein (CAS) and iNOS expression assessed by quantitative and semi-quantitative analysis. Mildronate also normalized the changes in cytochrome c oxidase (COX) expression, reduced the expression of glial fibrillary acidic protein (GFAP) and cellular infiltration. The present results show that the neuroprotective action of mildronate results at least partially from anti-neurodegenerative (anti-apoptotic) and anti-inflammatory mechanisms. It might be suggested that the molecular conformation of mildronate can facilitate its easy binding to mitochondria, and regulate the expression of different signal molecules, hence maintaining cellular signaling and survival.



Conclusion

If any of the Russian readers of this blog have trialed Mildronate in their child with autism secondary to mitochondrial disease (AMD), please let us know the result.


Perhaps Dr Kelley should try mildronate, it clearly falls into his area of interest.




Wednesday 15 October 2014

Regressive Autism and Mitochondria - Part 1


This blog is mainly about classic early-onset autism and the biology underlying it.

There are many other disorders that also result in autistic behaviours, some of which are much better understood than classic autism.  Today’s post is about Mitochondrial Disease which appears to be the precursor to most cases of regressive autism, according to Dr Richard Kelley, at Johns Hopkins and the Kennedy Krieger Institute.

In well-resourced centers for autism, by which I mean large teaching hospitals in the US, cases of autism are often fully investigated.  First they rule out mitochondrial disease and common known single gene causes like Fragile X.  Next comes the chromosome microarray. The microarray (often referred to as CMA) may identify a genetic cause in 15-20% of individuals with an ASD. 

In the rest of the world no such testing takes place, unless you are very lucky.

If the supplement Carnitine makes you feel better, read on, because you quite likely have some mitochondrial dysfunction and have Asperger’s secondary to Mitochondrial Disease.

If you are interested in regressive autism and particularly if you live outside the US, this post could be very relevant.

In short, medical testing can establish whether mitochondrial disease is present.  If it is present, it may be the underlying cause of the regressive autism, or perhaps just an aggravating factor.  If steps are taken quickly, further damage can be limited and the final outcome much improved.

Some of the therapies are the same as for classic autism, like anti-oxidants but some are the opposite.

Certain common drugs should be avoided like types of painkiller (Tylenol/ acetaminophen/paracetamol and aspirin), statins, steroids, valproic acid, risperidone (Risperdal), haloperidol, and some SSRIs; all are inhibitors of complex I / toxic to mitochondria.

There is at least one emerging drug therapy to treat the mitochondria, as opposed to just limit further damage.

The following extensive extracts are all from a paper by Dr Richard Kelley, at the Kennedy Krieger Institute and the neighboring Johns Hopkins Hospital.  I suggest reading the full original paper.  It is the most useful paper related to autism that I have come across, and that is thousands of papers.


Autism secondary to Mitochondrial Disease (AMD)



Most children with autism secondary to mitochondrial disease (“AMD”) experience a single episode of injury, while a few suffer two or more periods of regression during a characteristic window of vulnerability between 12 and 30 months. The subsequent natural history of AMD is typical for regressive autism, with most children showing partial recovery between 3 and 10 years. The principal clinical differences between AMD and non-regressive autism are, variably, a mild myopathy, abnormal fatigue, and, occasionally, minor motor seizures in the years following the first episode of injury. Others with biochemically defined AMD experience a period of only developmental stagnation lasting several months or more between ages 12 and 30 months and show overall better recovery than those who experience a severe autistic regression during this period of neurological fragility. More noteworthy, but uncommonly identified, are sibs of AMD individuals who have all the biochemical features of AMD with no or only minimal developmental or behavioral abnormalities, such as ADHD or obsessive-compulsive disorder.

While permanent developmental losses in AMD can be substantial, especially in the few individuals who suffer more than one episode of regression, recovery can be almost complete in some children when treatment is started early after the first episode of regression, and a partial response to metabolic therapy remains possible indefinitely. Treatment of AMD includes augmentation of residual complex I activity with carnitine, thiamine, nicotinamide, and antothenate, and protection against free radical injury with several antioxidants, including vitamin C, vitamin E, alpha-lipoic acid, and coenzyme Q10 (CoQ10).

Although a deficiency of mitochondrial complex I may be the most common identifiable cause of regressive autism, the relatively mild biochemical abnormalities often are missed by “routine” metabolic testing. In some cases, all test results are in the normal range for the laboratory, but abnormal ratios of metabolites offer clues to the diagnosis.

The identification of patients with AMD has now become routine Kennedy Krieger Institute, in part because of its specialization in both ASD and metabolic diseases and in part because of the availability of onsite biochemical testing.

Natural History of Autism with Mitochondrial Disease. The natural history of AMD and the events surrounding the period of regression are as important as the biochemical abnormalities in establishing the diagnosis. Before regression, all affected children have had normal or even advanced language and cognitive development and no neurological abnormalities apart from mildly delayed gross motor milestones and hypotonia in a few. Regression often can be dated to a specific event, most often a simple childhood illness, such as otitis media, streptococcal pharyngitis, or viral syndrome, or, rarely, an immunization, most often the MMR vaccine or the former DPT. The common feature of all identified precipitants is inflammation. Regression occurs either acutely during the illness or within 14 days of immunization with the MMR attenuated virus vaccine. Regression is otherwise typical for autism and includes acute or subacute loss of language, onset of perseverative behaviors, and loss of eye contact and other social skills. Although neurological regression in many mitochondrial diseases and other metabolic disorders often occurs because of illness-associated fasting, most children with AMD continue to eat normally during the crisis. Moreover, regression during an illness can occur whether or not there is fever. The nature of the regression and its timing suggest that mitochondrial failure is caused by immune-mediated destabilization of mitochondria as part of a TNF-alpha/caspase-mediated apoptosis cascade [5]. Because “steady state” loading of complex I in brain is close to 50% [6,7], if a child had a 50% reduction in complex I activity due to  aplo insufficiency for a complex I null mutation, just a 5 or 10% further reduction in mitochondrial activity could cause neurons to cross the threshold for energy failure and cell death. 

The well-defined role of nutritional factors in modulating the inflammatory response and the shift from animal fats to vegetable-derived fats in western diets are important factors to consider in the cause and treatment of AMD. The increase in the consumption of pro-inflammatory omega-6 fatty acids in infancy and early childhood over the last generation has been particularly striking. The established role of inflammation in causing mitochondrial destabilization [8,9] could explain an increasing incidence of regressive autism in individuals who have otherwise asymptomatic variants of complex I deficiency, which may have specific adaptive function in host defense and cognitive development [10]. In this respect, AMD, which in our experience is the cause of most regressive autism, could be another inflammatory disorder among several that have seen a markedly increased incidence over the last 20 to 30 years: asthma, inflammatory bowel disease, atopic dermatitis, eosinophilic gastroenteritis, and type I diabetes [11]. The recognition of inflammation as an apparently common cause of regression in AMD recommends the use of anti-inflammatory agents, including ibuprofen and leukotriene receptor inhibitors (i.e. montelukast, zafirlukast), to prevent further injury in children with AMD. For example, the recently reported increased risk for post-MMR autistic regression in children given pro-oxidant acetaminophen [12] could also be interpreted as an increased risk for developmental regression in those who were not given ibuprofen. Moreover, the effect of the gradual elimination of aspirin use in children between the 1980s and 1990s following the Reye syndrome epidemic 6 may have contributed to the rise in the incidence of autism, although, epidemiologically, aspirin elimination alone is not likely to be a major factor in the rising incidence of regressive autism.
  
Although most patients with AMD have a discrete episode of acute or subacute language loss and social regression, some will manifest only relative stagnation of development for a period of several months to a year or more. At least 90% of such events––developmental regression or stagnation––occur in a window of vulnerability between 12 and 30 months.

  
The goals for treatment of AMD due to complex I deficiency are:

1)    Augment residual complex I activity

2)    Enhance natural systems for protection of mitochondria from reactive oxygen species

3) Avoid conditions known to impair mitochondrial function or increase energy demands, such as prolonged fasting, inflammation, and the use of drugs that inhibit complex I.


Combining the first and second parts of the treatment plan, the following is a typical prescription for treating AMD:

L-Carnitine 50 mg/kg/d                Alpha Lipoic acid 10 mg/kg/d
Coenzyme Q10 10 mg/kg/d       Pantothenate 10 mg/kg/d
Vitamin C 30 mg/kg/d                  Nicotinamide 7.5 mg/kg/d (optional)
Vitamin E 25 IU/kg/d                    Thiamine 15 mg/kg/d (optional)



Immediate behavioral improvement with carnitine treatment in a child with regressive autism makes complex I deficiency the most likely cause

Another important clinical observation is that many children with mitochondrial diseases are more symptomatic (irritability, weakness, abnormal lethargy) in the morning until they have had breakfast, although this phenomenon is not as common in AMD as it is in other mitochondrial diseases.

When early morning signs of disease are observed or suspected, giving uncooked cornstarch (1 g/kg; 1 tbsp = 10g) at bedtime effectively shortens the overnight fasting period. Uncooked cornstarch, usually given in cold water, juice (other than orange juice), yogurt, or pudding, provides a slowly digested source of carbohydrate that, in effect, shortens overnight fasting by 4 to 5 hours. 

the MMR vaccine has been temporally associated, if rarely, with regression in AMD and other mitochondrial diseases when given in the second year. Doubtless some of these regressions are coincidental, since the usual age for giving the MMR falls within the typical window of vulnerability for AMD regression. In some children, however, MMR-suspected regression has coincided with the peak inflammatory response on days 8 to 10 post-immunization, as measured by IL-10 levels [28]. Unfortunately, the falling rates of immunization with MMR in the United States and other countries all but guarantees that major outbreaks of measles, mumps, and rubella will occur in the near future


Nutritional Factors Diet is another variable to consider in the treatment of AMD. Vegetable oils that are “pro-inflammatory” due to low levels of omega-3 (n-3) fatty acids and increased amounts of linoleic acid and other omega-6 (n-6) fatty acids today predominate in infant formulas and most prepared foods, largely because 13 of nutritional recommendations to avoid animal fats containing saturated fatty acids and cholesterol. The serious consequences of this trend are now being felt. A study in 2000 [29] showed that two- to four-month old breast-fed infants had more than twice the level of docosahexaenoic acid (C22:6n-3) and higher levels of most other n-3 fatty acids compared to formula-fed infants, although immunological consequences of the difference could not be demonstrated using limited immunological assays in that particular study. While the average child may suffer no obvious ill effects from diets deficient in n-3 fatty acids, the possible proinflammatory effect of these diets could be a contributing factor to infection-induced regressive autism in a child who has a metastable mitochondrial disorder. Moreover, in view of a recent study that associated decreased synthesis of cholesterol with rare cases of non-regressive autism [30], the early termination of breast-feeding and the major shift in infant diets toward low-cholesterol vegetable fats could be contributing factors to the apparent rise in the incidence of both regressive and non-regressive autism. Indeed, studies over the last two decades have shown that absence or early termination of breast-feeding is associated with higher rates of autism [31]. The simplest way to assure a adequate amount of C22:6n-3 and related fatty acids for children on typical vegetable-oil enriched diets is to provide an oil supplement, such as flaxseed oil, which is enriched in the precursors for C20 and C22 n-3 fatty acids, or salmon oils, which contain substantial amounts of DHA and EPA and a relatively low mercury content compared to many other fish species. C. Medications Certain behavior medications used in the treatment of ASD are inhibitors of complex I and, therefore, warrant consideration in treating children with AMD. Although these medications appear to have little effect on overall energy metabolism in individuals with normal mitochondria, clinically significant compromise of mitochondrial function can occur when complex I is impaired and relatively high doses of the more inhibitory drugs are prescribed. The complex I-inhibiting drugs most likely to be used in the treatment of ASD include both typical and atypical neuroleptics, such as risperidone (Risperdal), haloperidol, and some SSRIs. Although these medications are used most often in older children who are beyond the vulnerable period for autistic regression, this theoretical risk should be considered when prescribing older generation neuroleptics, such as haloperidol and related drugs, with a higher risk for development of tardive dyskinesias.

These older neuroleptics have been shown to inhibit complex I activity in direct proportion to their propensity to cause tardive dyskinesia [32]. However, there is no evidence that the newer “atypical” neuroleptics, such as risperidone and quetiapine, which have a low risk for extrapyramidal damage, are contraindicated in children with AMD and other mitochondrial diseases. Indeed one of the commonly used atypical neuroleptics, risperidone, has been shown to possibly against mitochondrial injury via modulation of damaging stress induced calcium influxes into mitochondria [33].



Novel Mitochondrial Drugs

Edison Pharmaceuticals is developing treatments for mitochondrial disease.

EPI - 743
  
EPI-743 is a drug candidate in clinical development primarily focused on inherited mitochondrial diseases. EPI-743 is administered orally, passes into the brain, and works by regulating key enzymes involved in the synthesis and regulation of energy metabolism.
Through expanded access protocols and prospective clinical trials, EPI-743 has been dosed for more than a cumulative 130,000 patient dosing days (as of November, 2013), and has recorded a favorable human safety profile. Subjects with over 15 discrete diseases have been treated. 



Genetic Dysfunctions

The prevalence of mitochondrial disorders (excluding autism) is estimated to be about 1:8500


and yet it is estimated that 1 in 200 people have a defective gene linked to a mitochondrial disorder. 


This implies a multiple hit mechanism, like we saw with cancer in an earlier post.  It also shows the potential to be misled by genetic information.  Just because the defect is there does not mean it will actually cause anything to happen, further rare events may also be needed to trigger it.

Alternatively, maybe there are far more people with a mitochondrial disease than the above studies suggest.  They are not including people with regressive autism, for one.  Something like 1 in 200 people have regressive autism.

  
What happened to Dr Richard Kelley?

If you have read the full paper by Dr Kelley you are probably wondering what else he has to say about autism.  He is an extremely rare mainstream clinician who actually does know about the subject.

You might also be wondering how come such a doctor can write about vaccination triggering mitochondrial disease and then autism, albeit in rare cases.

Perhaps this is why he does not write further about autism?

Dr.Kelley's research has focused on the elucidation of the biochemical basis of genetic disorders. Through the application of various techniques of biochemical analysis but especially mass spectrometry, Dr. Kelley has discovered the biochemical cause, and thereby the genetic etiology, of more than a dozen different diseases.

People do write about autism and mitochondrial disease, but some of these researchers are from the fringe and are not taken very seriously by the mainstream.