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Showing posts with label MCT. Show all posts
Showing posts with label MCT. Show all posts

Wednesday 3 October 2018

Ketones and Autism Part 6 - Capric Acid (C10) for Mitochondrial Disease, in Particular Complex 1, plus more on Metformin



Capric Acid (C10) is so named because it smells like a goat (Goat in Latin = Caper)
Photographer: Armin Kübelbeck, CC-BY-SA, Wikimedia Commons

Rather than Goaty acid, C10 is called Capric acid, or indeed Decanoic acid (after its 10 carbon atoms). Today’s post is indirectly again about ketones, because if you eat a Ketogenic Diet (KD) you are likely to consume a fair amount of Capric acid (C10).
I have written a lot in this blog about mitochondria, even though I do not think my son has mitochondrial dysfunction. Clearly many people with autism do have a lack of one or more of the critical mitochondrial enzyme complexes that allow glucose to be converted to ATP (usable energy), by the clever process OXPHOS (Oxidative phosphorylation).

The “rate limiting” enzyme is usually Complex 1, meaning that is the one it is most important not to be short of.
Another favourite, but obscure, subject of this blog is PPAR gamma.

Peroxisome proliferator-activated receptors (PPARs) are a group of proteins that function as transcription factors regulating the expression of certain genes. Transcription factors are particularly important because they trigger numerous effects.
PPAR gamma plays a key role in fat storage and glucose metabolism, but has other functions. 

Activation of PPAR-gamma by Capric acid (C10) has been shown to increase the number of mitochondria, increase the mitochondrial enzyme citrate synthase, increase complex I activity in mitochondria, and increase activity of the antioxidant enzyme catalase. 
So, if you have autism and impaired mitochondrial function, C10 may well give a benefit because it can increase the peak power available to your brain.


The Ketogenic diet (KD) is an effective treatment with regards to treating pharmaco-resistant epilepsy. However, there are difficulties around compliance and tolerability. Consequently, there is a need for refined/simpler formulations that could replicate the efficacy of the KD. One of the proposed hypotheses is that the KD increases cellular mitochondrial content which results in elevation of the seizure threshold. Here, we have focussed on the medium-chain triglyceride form of the diet and the observation that plasma octanoic acid (C8) and decanoic acid (C10) levels are elevated in patients on the medium-chain triglyceride KD. Using a neuronal cell line (SH-SY5Y), we demonstrated that 250-μM C10, but not C8, caused, over a 6-day period, a marked increase in the mitochondrial enzyme, citrate synthase along with complex I activity and catalase activity. Increased mitochondrial number was also indicated by electron microscopy. C10 is a reported peroxisome proliferator activator receptor γ agonist, and the use of a peroxisome proliferator activator receptor γ antagonist was shown to prevent the C10-mediated increase in mitochondrial content and catalase. C10 may mimic the mitochondrial proliferation associated with the KD and raises the possibility that formulations based on this fatty acid could replace a more complex diet. We propose that decanoic acid (C10) results in increased mitochondrial number. Our data suggest that this may occur via the activation of the PPARγ receptor and its target genes involved in mitochondrial biogenesis. This finding could be of significant benefit to epilepsy patients who are currently on a strict ketogenic diet. Evidence that C10 on its own can modulate mitochondrial number raises the possibility that a simplified and less stringent C10-based diet could be developed.

Capric Acid (C10) as a PPARγ agonist

As shown in the above study the mechanism by which C10 benefits the mitochondria is via PPARγ agonism.

Here is another study confirming that C10 is indeed a PPARγ agonist.


Background: Mechanism of action of medium chain fatty acid remains unknown.

Results: Our results show that decanoic acid (C10) binds and activates PPARγ.

Conclusion: Decanoic acid acts as a modulator of PPARγ and reduces blood glucose levels with no weight gain.

Significance: This study could lead to design of better type 2 diabetes drugs.


Other PPARγ agonists
PPARγ agonists have been covered previously in this blog and we know that glitazones, a class of drugs for diabetes, do improve some types of autism. Glitazones are PPARγ agonists.

Metformin, a very widely used drug for type 2 diabetes, works differently to Glitazones, but I did suggest a while back it should help some types of autism. Last year it was indeed found to be beneficial in Fragile X.


 "Basically, it's something like a wonder drug," Sonenberg said.
The study suggests that metformin might also be used to treat other autism spectrum disorders, said Ilse Gantois, a research associate in Sonenberg's lab at McGill.
"We mostly looked at the autistic form of behaviour in the Fragile X mouse model," explained Gantois, who is co-lead author with McGill researchers Arkady Khoutorsky and Jelena Popic. "We want to start testing other mouse models to see if the drug could also have benefits for other types of autism."

Metformin is very cheap and has been used in humans for 60 years. It is another example of re-purposing a drug from Grandpa’s medicine cabinet to treat Grandson’s autism. 

Metformin has been trialled to combat obesity in idiopathic autism caused by antipsychotics. It did help with weight gain, but no comments were made about behavioural improvements, but then those studied were on antipsychotic drugs, which might mask such effects. 
Glitazone-type drugs appear more problematic than Metformin.

There are natural PPAR gamma agonists and they are often used to lower cholesterol, lower blood sugar and improve insulin sensitivity.
Sytrinol, a product containing flavanols tangeretin and nobiletin does indeed have a positive effect on some people’s autism, but for most people (but not all) the effect is lost after a few days.

Our doctor reader Maja, did suggest combining it with a PPARα agonist to see if the effect might be maintained.
This combination has indeed been researched for type 2 diabetes.               

The effect of dual PPAR alpha/gamma stimulation with combination of rosiglitazone and fenofibrate on metabolic parameters in type 2 diabetic patients.


There actually is another natural substance that is an agonist of both PPARγ and PPARα, Berberine, the alkaloid long used in Chinese medicine.
In the research it is suggested that BRB localizes in mitochondria, inhibits respiratory electron chain and activates AMPK”, which is not what you would want. But this may not be correct.

People who like supplements might want to follow up on Berberine.
Berberine is used by many people with diabetes and a few with autism, for all kinds of reasons, from mercury to GI problems.

Berberine is a potent agonist of peroxisome proliferator activated receptor alpha.


Although berberine has hypolipidemic effects with a high affinity to nuclear proteins, the underlying molecular mechanism for this effect remains unclear. Here, we determine whether berberine is an agonist of peroxisome proliferator-activated receptor alpha (PPARalpha), with a lipid-lowering effect. The cell-based reporter gene analysis showed that berberine selectively activates PPARalpha (EC50 =0.58 mM, Emax =102.4). The radioligand binding assay shows that berberine binds directly to the ligand-binding domain of PPARalpha (Ki=0.73 mM) with similar affinity to fenofibrate. The mRNA and protein levels of CPT-Ialpha gene from HepG2 cells and hyperlipidemic rat liver are remarkably up-regulated by berberine, and this effect can be blocked by MK886, a non-competitive antagonist of PPARalpha. A comparison assay in which berberine and fenofibrate were used to treat hyperlipidaemic rats for three months shows that these drugs produce similar lipid-lowering effects, except that berberine increases high-density lipoprotein cholesterol more effectively than fenofibrate. These findings provide the first evidence that berberine is a potent agonist of PPARalpha and seems to be superior to fenofibrate for treating hyperlipidemia.


                                                                                                                                     

Sources of Capric Acid (C10)
Goat milk is a good source of capric acid.
Capric acid is 8-10% of coconut oil and 4% of palm kernel oil

Capric acid is a large component (about 40%) of the less expensive MCT oil supplements.


1.2. Fatty acid composition in goat milk fat Average goat milk fat differs in contents of its fatty acids significantly from average cow milk fat, being much higher in butyric (C4:0), caproic (C6:0), caprylic (C8:0), capric (C10:0), lauric (C12:0), myristic (C14:0), palmitic (C16:0), linoleic (C18:2), but lower in stearic (C18:0), and oleic acid (C18:1) (Table 1). Three of the medium chain fatty acids (caproic, caprylic, and capric) have actually been named after goats, due to their predominance in goat milk. They contribute to 15% of the total fatty acid content in goat milk in comparison to 5% in cow milk (Haenlein, 1993). The presence of relatively high levels of medium chain fatty acids (C6:0 to C10:0) in goat milk fat could be responsible for its inferior flavour (Skjevdal, 1979). 

             
Conclusion
If someone responds well to coconut oil or cheaper MCT oil the reason may have more to do with PPAR gamma and improved mitochondrial function than anything to do with ketones and what they do.
Cheaper MCT oils are mainly a mixture of C8 and C10. To maximize the production of the ketone BHB you really want just C8, but if what you really need is a PPAR gamma agonist, to perk up your mitochondria, it is the C10 you need.
You may indeed benefit from both ketones and agonizing PPAR gamma, in which case you either follow the Ketogenic Diet, or supplement BHB, C8 and C10.
I think this explains why some people with autism reportedly respond well to teaspoon-sized doses of cheaper MCT oil or small amounts of coconut oil.
If you have Complex 1 mitochondrial dysfunction then a dose of Capric acid (C10) is likely to help.
Berberine may, or may not be, as effective as C10. I doubt we will ever know. I think C10 is the better option. 
I wonder when the Canadian researchers will publish their results showing whether Metformin is beneficial beyond Fragile X syndrome. They do not really know why it helps, but that is a repeating theme in medicine.  It is a cheap safe drug, so it would be a pity to waste time finding out if it could be repurposed for some autism.



Thursday 17 May 2018

Statins, SLOS and Hypocholesteraemia – Going Nowhere Fast


Today’s post is about cholesterol, statins and autism. There is a well-documented condition associated with autism called SLOS (Smith-Lemli-Opitz Syndrome). It is caused by mutations in the DHCR7 gene encoding the enzyme that catalyzes the final step in cholesterol biosynthesis.

Toe syndactyly (webbed toes), one symptom of SLOS



Reduced activity of the enzyme 7DHCR typically leads to low levels of cholesterol, but markedly increased levels of precursor 7DHC (and its isomer, 8DHC) in blood and tissues. Typical SLOS manifestations include intellectual disability, growth retardation, minor craniofacial anomalies, microcephaly and 2-3 toe syndactyly (webbed toes).
SLOS is rare, but some cases do get missed because you can have a DHCR7 mutation and have normal levels of cholesterol and have normal cognitive function.

Cholesterol and the blood brain barrier (BBB)
You do have a lot of cholesterol in your brain, but it does not cross the blood brain barrier (BBB), it was made in the brain.  Eating more cholesterol can have no direct effect on cholesterol levels in the brain.
The standard treatment for SLOS has long been oral cholesterol supplementation, but there is no conclusive research to show it helps. There is plenty of anecdotal evidence.

Simvastatin and SLOS
Simvastatin is a drug widely used drug to treat people with elevated cholesterol.
There has been anecdotal evidence that Simvastatin improves SLOS and recently a very thorough study was carried out to establish whether or not it really has a benefit.
In reality the study was comparing:

Simvastatin + cholesterol supplement  vs  cholesterol supplement

The study was carried out by researchers including Dr Richard Kelley (“Dr Mitochondria”) and Dr Elaine Tierney (“Dr Cholesterol”)


Currently, most SLOS patients are treated with dietary cholesterol supplementation. Although cholesterol therapy reduces serum 7-DHC concentrations to a degree, significant amounts of 7-DHC persist even after years of therapy.  Anecdotal case studies and case series support the idea that cholesterol supplementation benefits the overall well-being of SLOS patients; however, the effects of dietary cholesterol supplementation on cognitive or behavioral aspects of this disorder have not been reported by others or substantiated in a limited controlled trial. The efficacy of dietary cholesterol supplementation is probably limited by the inability of dietary cholesterol to cross the blood–brain barrier. Moreover, increased concentrations of 7-DHC or 7-DHC-derived oxysterol could have toxic effects. Specialists have hypothesized that, in patients with mild to classic SLOS, many aspects of the abnormal behavioral and cognitive phenotype could be the result of altered sterol composition in the central nervous system. Thus, interventions that ameliorate the central nervous system biochemical disturbances in SLOS are critical to understanding the pathological processes that underlie this inborn error of cholesterol synthesis and to developing effective therapies to treat the neurological deficits.

Expression of DHCR7 is regulated by SREBP2, which, when activated by low levels of cholesterol in the endoplasmic reticulum, increases the transcription of most genes of the cholesterol synthetic pathway. Having shown that DHCR7 expression is increased in SLOS fibroblasts treated with simvastatin,31 we hypothesized that the paradoxical increase in serum cholesterol could be the result of increased expression of a DHCR7 allele with residual enzymatic function, and we demonstrated that many DHCR7 alleles encode an enzyme with residual activity. Furthermore, both in vitro experiments with human  fibroblasts and in vivo experiments using hypomorphic Dhcr7T93M/delta mice support the hypothesis that increased expression of DHCR7 alleles with residual enzymatic activity can significantly improve plasma and tissue sterol concentrations. Because residual DHCR7 activity varies among patients with SLOS, this hypothesis could explain the paradoxical increase in cholesterol in some patients and the adverse reactions observed in others.

In this study we also evaluated the potential of simvastatin to alter specific aspects of the SLOS behavioral phenotype. Our secondary outcome measures were the CGI-I and ABC-C irritability scores. Although we observed no significant effect on the CGI-I, we did observe significant improvement in the ABC-C irritability score (Figure 4). This article therefore represents the first controlled study to demonstrate improved behavior in subjects with SLOS in response to a therapeutic intervention.




In summary, this study represents the first controlled trial of simvastatin therapy in SLOS and the first controlled trial demonstrating the potential of drug therapy to modulate sterol composition and to improve behavior in SLOS. We have established that treatment with simvastatin is relatively safe, can decrease DHC levels, and can improve at least one aspect of the behavioral phenotype. These data support continued efforts to identify and rigorously evaluate potential therapies that may have clinically meaningful benefits for patients with SLOS.










Plasma sterol levels

Cholesterol and dehydrocholesterol (7DHC + 8DHC) levels were measured at baseline (B), washout (W, 14 mo) as well as at 1, 3, 6, 9 and 12 months in both the placebo and simvastatin treatment phase. Plasma cholesterol levels (A, B) and DHC (C, D) decreased significantly during the simvastatin phase compared to the placebo phase. The plasma DHC/Total Sterol ratio (E, F), which was the primary outcome measure of this study, also decreased significantly. Data expressed as mean ± SEM.


Hypocholesterolemia (low cholesterol) and some Autism
Ten years ago, Tierney and Kelley published research showing that about 20% of autism is associated with very low cholesterol levels (less than the 5th centile for typical young people) but in their sample of 100, none had an abnormally increased level of 7DHC consistent with the diagnosis of SLOS or abnormal level of any other sterol precursor of cholesterol.


Tierney went on to patent cholesterol as a therapy for autism.


The present invention relates to the field of autism. More specifically, the present invention provides methods for treating individuals with autism spectrum disorder. Accordingly, in one aspect, the present invention provides methods for treating patients with autism spectrum disorder. In one embodiment, a method for treating an autism spectrum disorder (ASD) in a patient comprises the step of administering a therapeutically effective amount of cholesterol to the patient. In more specific embodiments, the ASD is autism, Asperger's disorder, pervasive developmental disorder-not otherwise specified (PDD-NOS), Rett's syndrome and childhood disintegrative disorder. In one embodiment, the patient has autism. 


Tierney has a clinical trial registered that was to start in 2009.


Three sites (Kennedy Krieger Institute [KKI], Ohio State University [OSU], and the National Institutes of Health [NIH]) will collaborate to accomplish the objectives of this study. In addition to defining the frequency of altered cholesterol homeostasis in ASD, 60 youths (20 at each site) with ASD plus hypocholesterolemia will enter a 12-week, double-blind, placebo-controlled trial immediately followed by a 12-week open-label cholesterol trial to test the efficacy of dietary cholesterol supplementation. Outcome measures will include standard tests of behavior, communication, and other autism features.


It appears that the study has not been completed.


Dr. Elaine Tierney and her colleagues are studying different metabolic disorders that can present with autism spectrum disorder through the Autism Metabolic Research Program at Kennedy Krieger. In 2000 and 2001, this group of researchers identified that Smith-Lemli-Opitz-Syndrome (SLOS) is associated with autism spectrum disorder. Since SLOS is known to be caused by a defect in the body's biosynthesis of cholesterol, SLOS may provide clues to the biochemistry of other autism spectrum disorders (ASD).

Dr. Tierney and colleagues published a paper in 2006, in the American Journal of Medical Genetics Part B (Neuropsychiatric Genetics), in which they describe finding that a subgroup of children with ASD have abnormally low cholesterol levels. The children's low cholesterol levels were apparently due to a limited ability to make cholesterol. This finding, in concert with their work with SLOS, has led them to believe that cholesterol may play a role in the cause of some cases of autism spectrum disorder. Dr. Tierney and colleagues at Kennedy Krieger, the National Institutes of Health and Ohio State University are performing a double-blind placebo-controlled study of cholesterol in individuals with ASD.

Cholesterol as a marker of inflammation
Nowadays, hypercholesterolemia and inflammation are considered as “partners in crime”.  Statins do lower bad cholesterol, but they also have broad anti-inflammatory effects.


Arteries do clog up with cholesterol, but a big part of why this happens is inflammation. Cholesterol deposits are initially a protective mechanism, like a band-aid. Treat the inflammation and cholesterol will not need to be deposited.
An altered immune response is a feature of many people’s autism, and you can measure it.
As Paul Ashwood’s research has shown, there are different immune sub-groups that people with autism fall into, and so you could treat each cluster with a specific therapy.

Cholesterol and Thyroid Hormones
Your thyroid produces hormones that control your metabolism. Metabolism is the process your body uses to convert food and oxygen into energy.

Your body converts the circulating pro-hormone T4 into the active hormone T3 locally. So, in your brain T4 has to be converted to T3. If you lack enough T4 coming from your thyroid gland or the special enzyme called D2 you are going to feel lethargic.
Your body needs thyroid hormones to make cholesterol and to get rid of the cholesterol it doesn’t need. When thyroid hormone levels are low (hypothyroidism), your body doesn’t break down and remove LDL (“bad”) cholesterol as efficiently as usual. Elevated LDL cholesterol will show up in your blood tests.
Hyperthyroidism has the opposite effect on cholesterol. It causes cholesterol levels to drop to abnormally low levels.
So best to check thyroid function and cholesterol levels.



Conclusion
My main interest is autism with a tendency to big heads (hyperactive growth signalling pathways) and an overactive immune system. This is the opposite of SLOS and hypocholesterolemia (low cholesterol).
For the 20% with low cholesterol, I think this is a very important biomarker.

.Is supplemental cholesterol the answer? I am not so sure it is.
Hopefully one day soon Dr Tierney, at Kennedy Krieger, will publish her results of cholesterol as a therapy for people with autism and low cholesterol.
For me it is good to see that Simvastatin was well tolerated in a 12 month long trial in children from 4 to 18 years of age. I have the very similar drug, Atorvastatin, in my Polypill.
Interestingly, in a paper that I will cover in later post, increasing HDL (good cholesterol), a feature of Atorvastatin and Simvastatin, was one marker of behavioral improvement in the Ketogenic Diet.