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Showing posts with label NLRP3. Show all posts
Showing posts with label NLRP3. Show all posts

Sunday, 11 December 2022

Pleiotropy - your new BFF? SGLT2 inhibitors and targeting the NLRP3 inflammasome to target neurological disorders from Autism to ALS and Alzheimer’s


Pleiotropy 

from Greek πλείων pleion, 'more'

and τρόπος tropos, 'way'


 

 

Today’s post introduces a new term – SGLT2.

Depending how old you are, you will be aware of the term BFF – Best Friend Forever.  These days you can have several BFFs, not just one. 

Pleiotropy (play-o-tropy) is a rather nice sounding word that was brought into use in science and medicine by a German geneticist Ludwig Plate in 1910. Pleiotropic effects of a drug are any beneficial secondary effects.

Statins are the classic example. They were developed to lower cholesterol, but many of the positive effects experienced by users have nothing to do with cholesterol, they lower inflammation (and more besides).  It is now thought that inflammation in your arteries triggers a protective layer of cholesterol to be deposited. As the decades pass, this protective layer grows and ends up causing all kinds of problems.

When you repurpose an old drug for a new use, you are taking advantage of its pleiotropic effects.  For readers of this blog pleiotropy is a friend, and quite possibly a BFF.

 

SGLT2

Today we look at repurposing a class of drugs that lowers blood sugar for those with type 2 diabetes to treat a wide range of brain disorders.

We also look at a cheap pain killer that can be used to disrupt an inflammatory pathway key to most brain disorders and even some cancers.

Our reader Eszter did recently highlight a very well written paper about the potential to repurpose SGLT2 inhibitors to treat autism. Eszter knows a lot about neurology, I should point out.

Eszter has previously commented on the interesting overlap between drugs that provide a benefit in Alzheimer’s and those that benefit some autism.  She will likely find the link at the very end of this post of interest.

 

Repurposing SGLT2 Inhibitors for Neurological Disorders: A Focus on the Autism Spectrum Disorder 

Autism spectrum disorder (ASD) is a neurodevelopmental disorder with a substantially increasing incidence rate. It is characterized by repetitive behavior, learning difficulties, deficits in social communication, and interactions. Numerous medications, dietary supplements, and behavioral treatments have been recommended for the management of this condition, however, there is no cure yet. Recent studies have examined the therapeutic potential of the sodium-glucose cotransporter 2 (SGLT2) inhibitors in neurodevelopmental diseases, based on their proved anti-inflammatory effects, such as downregulating the expression of several proteins, including the transforming growth factor beta (TGF-β), interleukin-6 (IL-6), C-reactive protein (CRP), nuclear factor κB (NF-κB), tumor necrosis factor alpha (TNF-α), and the monocyte chemoattractant protein (MCP-1). Furthermore, numerous previous studies revealed the potential of the SGLT2 inhibitors to provide antioxidant effects, due to their ability to reduce the generation of free radicals and upregulating the antioxidant systems, such as glutathione (GSH) and superoxide dismutase (SOD), while crossing the blood brain barrier (BBB). These properties have led to significant improvements in the neurologic outcomes of multiple experimental disease models, including cerebral oxidative stress in diabetes mellitus and ischemic stroke, Alzheimer's disease (AD), Parkinson's disease (PD), and epilepsy. Such diseases have mutual biomarkers with ASD, which potentially could be a link to fill the gap of the literature studying the potential of repurposing the SGLT2 inhibitors' use in ameliorating the symptoms of ASD. This review will look at the impact of the SGLT2 inhibitors on neurodevelopmental disorders on the various models, including humans, rats, and mice, with a focus on the SGLT2 inhibitor canagliflozin. Furthermore, this review will discuss how SGLT2 inhibitors regulate the ASD biomarkers, based on the clinical evidence supporting their functions as antioxidant and anti-inflammatory agents capable of crossing the blood-brain barrier (BBB).

 

Recently I was asked by one researcher reader where is the evidence to support my suggestion that Ponstan (Mefenamic Acid) can enhance cognition.  I was not sure that I would find evidence that relates to actual humans, but I did. This took me back to the time this blog looked into the NLRP3 inflammasome.

Just like the new generation of type 2 diabetes drugs have pleiotropic effects on the brain, so do Fenamate class NSAIDs, specifically Ponstan.

There are four SGLT2 inhibitors approved to treat type 2 diabetes

·        Invokana (canagliflozin)

·        Farxiga (dapagliflozin)

·        Jardiance (empagliflozin)

·        Steglatro (ertugliflozin)

To be effective inside the brain such a drug would need to be small and lipid (fat soluble) enough to get across the blood brain barrier.

If the idea of a diabetes drug helping brain disorders sounds strange, consider what we have already come across in previous posts in this blog.

  

Other Type 2 drugs with pleiotropic effects

 

Metformin

Metformin was discovered exactly 100 years ago, in 1922.  It is not a new drug and it is the world’s most common therapy for type 2 diabetes.

It has been suggested metformin can delay the onset of aging and also the onset and development of Alzheimer’s.

The use of metformin has repeatedly associated with the decreased risk of the occurrence of various types of cancers, especially of the pancreas and colon and hepatocellular carcinoma.

Metformin has been shown to raise IQ in children with Fragile-X syndrome by about 10%.

Some people with autism do take metformin, in others it provides no benefit.

 

Glitazones

Glitazones are a class of anti-diabetic drug that started to get popular from the year 2000. They  work by stimulating  peroxisome proliferator-activated receptor gamma (PPAR-γ) receptor. They will activate PGC-1 alpha, which we know is the key regulator of mitochondrial biogenesis. For some strange reason, glitazone drugs are not used to treat mitochondrial disease.

Glitazones have broad anti-inflammatory pleiotropic effects.

Pioglitazone has been researched in autism and I have used it for several years as a spring and summertime add-on therapy in Monty’s PolyPill.

 

Back to Eszter’s paper

 

I highlight some of the tables, which do summarize the beneficial effects.

 














Inflammatory signals promote inflammation by activating the microglia and astrocytes within the brain in ASD. SGLT2 inhibitors influence on the inflammation and neuroinflammation, SGLT2 inhibitors decrease the inflammatory factors levels, such as the M1 macrophages, STAT1 inflammatory transcription factor, cytokine interleukin-1β (IL-1β), tumor necrosis factor (TNF-α), and vascular cell adhesion protein (VCAM) in neurodevelopmental diseases

 


 

Distribution of the SGLT receptors in the CNS. 1. Brain cortex (pyramidal cells); 2. Purkinje neurons; 3. Hippocampus; 4. Hypothalamus; 5. Micro vessels; 6. Amygdala cells; 7. Periaqueductal gray; 8. Dorsomedial medulla.

 

Such a distribution of the SGLT2 receptors [114] could potentially be responsible for their intriguing neuroprotective qualities, which could be beneficial in several neurological disorders, including ASD [99]. The SGLT2 inhibitors’ proposed mechanisms are presented in Figure 3. The antioxidant effect of the SGLT2 inhibitors can be attributed to their stimulatory action on the nuclear factor erythroid 2 (Nrf2)- related factor 2 pathway [115]. This displays the antioxidant activity because of their genetic expression of the antioxidant proteins, including glutathione-s-transferase (GST), SOD, and NADPH quinone dehydrogenase-1 to protect against cellular apoptosis [116]. The anti-inflammatory characteristics of the SGLT2 inhibitors could be accredited to the downregulation of NF-KB, which decreases IL-1β and the TNF-α expression [117]. Empagliflozin has the highest selectivity for the SGLT2 receptors (2500-fold) when compared to dapagliflozin which has (1200-fold) selectivity, and canagliflozin (250-fold) [118,119]. Therefore, in the context of the neuroprotective effects associated with the SGLT1 and SGLT2 receptors’ inhibition, canagliflozin was hypothetically preferred over other SGLT2 inhibitors, due to its dual SGLT1/SGLT2 inhibition capability [120].

 

SGLT2 inhibitors have the potential to improve ASD patients’ behavioral and brain disruptions by increasing the cerebral brain derived neurotrophic factor and reducing the cerebral oxidative stress, including elevated the GSH and catalase activity, reduced MDA, amyloid β levels, plaque density, and acetylcholinesterase

 

ASD remains a global health dilemma, as it is a chronic condition, and is incurable, leading to a reduced quality of life. It is crucial to find the mutual molecular mechanisms of ASD and redefine the indications for the well-studied medication with numerous pleiotropic effects to find a solution. This review has disclosed the impact of the SGLT2 inhibitors in neurological diseases, which could relate to ASD as it shares multiple pathways and mutual biomarkers. SGLT2 inhibitors display several neuroprotective properties, highlighting their therapeutic potential for ASD patients, as these agents have the capability to inhibit the acetylcholinesterase enzyme, reduce the elevated levels of the oxidative stress in the brain, and restore the anabolism and catabolism balance. Moreover, clinical intervention studies are vital to determine whether the displayed methods are useful as the SGLT2 inhibitors have never been tested on ASD directly. Currently, our research team is conducting a preclinical experiment to assess the effects of canagliflozin on the VPA-induced ASD in Wistar rats.

  

Back to the NLRP3 Inflammasome

Ponstan (Mefenamic acid) is one of the few available drugs that is known to be a potent inhibitor of an inflammatory pathway called the NLRP3 inflammasome.  It is mainly present macrophages, a type of white blood cell in the immune system.  The role of macrophages includes gobbling up pathogens.  

In the brain the microglia are the resident macrophages.  The microglia have multiple functions in the brain and we know that in autism they can be stuck in an overactivated state and then do not fulfil their other functions.

In many diseases activation of the NLRP3 inflammasome in local macrophages occurs.  Inhibiting this process can disrupt the disease process.

My guess is that this is the mechanism by which Ponstan is improving cognition in some of the people with autism who are taking it.

In the paper below we see that people taking Ponstan to treat their prostate cancer (PCa) experience an improvement in their cognition.

 

Improve cognitive impairment using mefenamic acid non-steroidal anti-inflammatory therapy: additional beneficial effect found in a controlled clinical trial for prostate cancer therapy 

Inflammation is an essential component of prostate cancer (PCa), and mefenamic acid has been reported to decrease its biochemical progression. The current standard therapy for PCa is androgen deprivation therapy (ADT), which has side effects such as cognitive dysfunction, risk of Alzheimer’s disease, and dementia. Published results of in vitro tests and animal models studies have shown that mefenamic acid could be used as a neuroprotector. Objective: Examine the therapeutic potential of mefenamic acid in cognitive impairment used in a controlled clinical trial. Clinical trial phase II was conducted on patients undergoing ADT for PCa. Two groups of 14 patients were included. One was treated with a placebo, while the other received mefenamic acid 500 mg PO every 12hrs for six months. The outcome was evaluated through the Mini-Mental State Examination (MMSE) score at six months. At the beginning of the study, both groups had similar MMSE scores (mefenamic acid vs. placebo: 26.0±2.5 vs. 27.0±2.6, P=0.282). The mefenamic acid group improved its MMSE score after six months compared with the placebo group (27.7±1.8 vs. 25.5±4.2, P=0.037). Treatment with mefenamic acid significantly increases the probability of maintained or raised cognitive function compared to placebo (92% vs. 42.9%, RR=2.2, 95% CI: 1.16-4.03, NNT=2.0, 95% CI: 1.26-4.81, P=0.014). Furthermore, 42.9% of the placebo group patients had relevant cognitive decline (a 2-point decrease in the MMSE score), while in patients treated with mefenamic acid, cognitive impairment was not present. This study is the first conducted on humans that suggests that mefenamic acid protects against cognitive decline.

 

In the AEA mouse model of MS (multiple sclerosis) we see the role again of NLRP3 on cognition. 


Inhibition of the NLRP3-inflammasome prevents cognitive deficits in experimental autoimmune encephalomyelitis mice via the alteration of astrocyte phenotype 

Some studies have indicated that NLRP3 inflammasome activation is involved in mediating synaptic dysfunction, cognitive impairment, and microglial dysfunction in AD models, and that the inhibition of the NLRP3 inflammasome attenuates spatial memory impairment and enhances Aβ clearance in AD model.  However, there is no research on NLRP3 inflammasome in MS-related cognitive deficits. In our study, we found that microglia and NLRP3 inflammasome were activated in the hippocampus of EAE mice, while pretreatment with MCC950 inhibited the activation of microglia and NLRP3 inflammasome

 

Again, we see a benefit from inhibiting NLRP3 in Alzheimer’s. 


Novel Small-Molecule Inhibitor of NLRP3 Inflammasome Reverses Cognitive Impairment in an Alzheimer’s Disease Model

Aberrant activation of the Nod-like receptor family pyrin domain-containing 3 (NLRP3) inflammasome plays an essential role in multiple diseases, including Alzheimer’s disease (AD) and psoriasis. We report a novel small-molecule inhibitor, NLRP3-inhibitory compound 7 (NIC7), and its derivative, which inhibit NLRP3-mediated activation of caspase 1 along with the secretion of interleukin (IL)-1β, IL-18, and lactate dehydrogenase. We examined the therapeutic potential of NIC7 in a disease model of AD by analyzing its effect on cognitive impairment as well as the expression of dopamine receptors and neuronal markers. NIC7 significantly reversed the associated disease symptoms in the mice model. On the other hand, NIC7 did not reverse the disease symptoms in the imiquimod (IMQ)-induced disease model of psoriasis. This indicates that IMQ-based psoriasis is independent of NLRP3. Overall, NIC7 and its derivative have therapeutic prospects to treat AD or NLRP3-mediated diseases.

 

What about sepsis (blood poisoning)? 

Mitochondrial protective effects caused by the administration of mefenamic acid in sepsis

The pathophysiology of sepsis may involve the activation of the NOD-type receptor containing the pyrin-3 domain (NLPR-3), mitochondrial and oxidative damages. One of the primary essential oxidation products is 8-oxoguanine (8-oxoG), and its accumulation in mitochondrial DNA (mtDNA) induces cell dysfunction and death, leading to the hypothesis that mtDNA integrity is crucial for maintaining neuronal function during sepsis. In sepsis, the modulation of NLRP-3 activation is critical, and mefenamic acid (MFA) is a potent drug that can reduce inflammasome activity, attenuating the acute cerebral inflammatory process. Thus, this study aimed to evaluate the administration of MFA and its implications for the reduction of inflammatory parameters and mitochondrial damage in animals submitted to polymicrobial sepsis. To test our hypothesis, adult male Wistar rats were submitted to the cecal ligation and perforation (CLP) model for sepsis induction and after receiving an injection of MFA (doses of 10, 30, and 50 mg/kg) or sterile saline (1 mL/kg). At 24 h after sepsis induction, the frontal cortex and hippocampus were dissected to analyze the levels of TNF-α, IL-1β, and IL-18; oxidative damage (thiobarbituric acid reactive substances (TBARS), carbonyl, and DCF-DA (oxidative parameters); protein expression (mitochondrial transcription factor A (TFAM), NLRP-3, 8-oxoG; Bax, Bcl-2 and (ionized calcium-binding adaptor molecule 1 (IBA-1)); and the activity of mitochondrial respiratory chain complexes. It was observed that the septic group in both structures studied showed an increase in proinflammatory cytokines mediated by increased activity in NLRP-3, with more significant oxidative damage and higher production of reactive oxygen species (ROS) by mitochondria. Damage to mtDNA it was also observed with an increase in 8-oxoG levels and lower levels of TFAM and NGF-1. In addition, this group had an increase in pro-apoptotic proteins and IBA-1 positive cells. However, MFA at doses of 30 and 50 mg/kg decreased inflammasome activity, reduced levels of cytokines and oxidative damage, increased bioenergetic efficacy and reduced production of ROS and 8-oxoG, and increased levels of TFAM, NGF-1, Bcl-2, reducing microglial activation. As a result, it is suggested that MFA oinduces protection in the central nervous system early after the onset of sepsis.

  

Conclusion

One reader of this blog attributes her son’s autism to his sepsis (blood poisoning) at birth. It is pretty clear from one of today’s papers that perhaps babies with sepsis should be treated with Ponstan (Mefenamic acid) to prevent damage to their brain.  I was recently contacted by another parent where sepsis occurred at birth. 

I think the researchers make a strong case that the pleiotropic effects of SGLT2 inhibitors that benefit Alzheimer’s, Parkinson’s and ALS very likely will also be beneficial in some autism.  They plan to test canagliflozin on rats with valproic acid-induced autism.

I have to say to Eszter that I actually think inhibiting the NLRP3 inflammasome might be the Neurologist’s best friend forever (BFF), perhaps even better than an SGLT2 inhibitor.

What is for sure is that both (SGLTi and NLRP3i) should be subject of clinical trials in autism. I suggest going straight humans rather than rats.

I have had positive feedback so far on my suggestion that low dose (250 mg) Ponstan/Mefenamic acid could be an effective long term autism therapy.  We do have to mention that Knut Wittkowski has patented its use in autism; he proposed it as a preventive measure in 2-3 year olds to redirect severe non-verbal autism towards Asperger’s. I selected it to treat extreme sound sensitivity, but later witnessed its pleiotropic effects.

If anyone has experience on the use of an SGLT2 inhibitor in autism, I would be very interested to read about it.

We should add Ponstan to the long list of drugs in this autism blog that may be beneficial in MS (Multiple sclerosis). (ALA, Clemastine, NAG, Ibudilast, DMF, Ponstan etc).


P.S.

A last word from Google

Having noted my recent googling activity, I was today sent the following news item by Google. 

Harnessing the Brain’s Immune Cells to Stave off Alzheimer’s and Other Neurodegenerative Diseases

Researchers have identified a protein that could be leveraged to help microglia in the brain stave off Alzheimer’s and other neurodegenerative diseases

But how does SYK protect the nervous system against damage and degeneration? We found that microglia use SYK to migrate toward debris in the brain. It also helps microglia remove and destroy this debris by stimulating other proteins involved in cleanup processes. These jobs support the idea that SYK helps microglia protect the brain by charging them to remove toxic materials.

 






Wednesday, 10 October 2018

Ketone Therapy in Autism (Summary of Parts 1-6)




Open the above file via Google Drive, so it is big enough to read. Click the link below. You can also take links from it to the relevant blog post.

https://drive.google.com/file/d/1Jl_JMUrX7suXz0n_yJPCLPinrvdddBhI/view?usp=sharing

In the mini series of posts on ketones and autism we have come across a long list of effects that will benefit certain groups of people.



1.     Change in gut Bacteria


2.     Ketones as a brain fuel    


3.     Niacin Receptor HCA2/ GPR109A

4.     NAD sparing

5.     CtBP Activation by reducing NADH/NAD+ ratio

6.     NLRP3 Inflammasome inhibition

7.     Class 1 HDAC inhibition

8.     Increase BDNF

9.     Ramification of Microglia

10.PKA activation

11.PPAR gamma activation
It was interesting that the beneficial effect of the Ketogenic Diet in epilepsy is driven by changes the high fat diet makes to the bacteria in your gut and seems to have nothing really to do with ketones. Well it took a hundred years to figure that one out.
In the case of Alzheimer’s, you can see that more than one effect is potentially beneficial. People with Alzheimer’s do have low glucose uptake to the brain, but they also have elevated inflammatory cytokine IL-1B.
In Huntington’s it is the HDAC inhibition effect that seems to be what helps.  This brings us back to HDAC inhibition as a potentially transformative therapy with long lasting effects. It appears that the small number of people who achieve long lasting benefit from short term use of sulforaphane or EGCG may have experienced HDAC inhibition changing the expression of up to 200 genes.  In the case of sulforaphane from broccoli, some people have gut bacteria that produces large amounts of the enzyme myrosinase, which means they convert very much more of the glucoraphanin in broccoli to sulforaphane (an HDAC inhibitor).
It does look like a low dose of a potent HDAC inhibiting cancer drug is what is needed by certain single gene autisms and perhaps some idiopathic autism. This was covered in a dedicated post where we saw the long-lasting benefit of short-term use of Romidepsin. Vorinostat, a very similar drug, but which is taken orally, should be trialled in Shank 3, Pitt Hopkins and Kabuki, to see if the same transformative long-lasting effect can be reproduced.
In Multiple Sclerosis (MS) the effect on Niacin receptor HCA2/GPR109A should help a lot, but so should PKA activation.
In mitochondrial disease it was suggested that increased ketosis will help conserve NAD, which may be deficient. Also, using ketones as an alternative brain fuel may bypass problems that occur when glucose is supposed to be the fuel and thereby boost brain function. The most important effect is likely to be activation of PPAR gamma by C10, which increases the number of mitochondria and boosts the enzyme complex 1.
Many of the people with autism and an overactive immune system stand to benefit from activating CtBP, inhibiting the NLRP3 inflammasome, or activating HCA2/GPR109A.
I think there should be clinical trials using a potent HCA2 activator in autism comorbid with immune over-activation. 
We can see that some people who respond to BHB, experience an immune rebound on cessation, so this helps narrow down the likely beneficial mode of action.  In this immune sub-group, the idea to using other activators of HCA2/GPR109A would seem worthwhile. 

PPAR gamma activation should help those with mitochondrial dysfunction, but this effect is produced only by C10, not BHB or C8. For C10 you eat a ketogenic diet or add it as a supplement (e.g. cheaper MCT oil, or coconut oil).

As recently highlighted by our reader Agnieszka, perhaps the fever effect in autism can be explained by short-term ketosis. Fever is known to sometimes raise the level of ketones, particularly in children (it is called non-diabetic ketosis).  So if your child's autism improves during, or just after fever, test the level of ketones in their urine.


Conclusion

We may have shown the benefits of a high fat ketogenic diet, but there are very many different fats and they do not all produce the same effects.

There are many saturated fatty acids, they are numbered based on how many Carbon atoms they have.

So, C8, known as Caprylic acid has the formula  C8H16O2

Eating C8 looks to be a great way to increase the level of ketones in your blood.

Eating C10 should be good for people with mitochondrial dysfunction and people with diabetes.

Your food contains many other saturated fatty acids and your gut bacteria produce even more.


Common Name Systematic Name Structural Formula Lipid Numbers
Propionic acid Propanoic acid CH3CH2COOH C3:0
Butyric acid Butanoic acid CH3(CH2)2COOH C4:0
Valeric acid Pentanoic acid CH3(CH2)3COOH C5:0
Caproic acid Hexanoic acid CH3(CH2)4COOH C6:0
Enanthic acid Heptanoic acid CH3(CH2)5COOH C7:0
Caprylic acid Octanoic acid CH3(CH2)6COOH C8:0
Pelargonic acid Nonanoic acid CH3(CH2)7COOH C9:0
Capric acid Decanoic acid CH3(CH2)8COOH C10:0
Undecylic acid Undecanoic acid CH3(CH2)9COOH C11:0
Lauric acid Dodecanoic acid CH3(CH2)10COOH C12:0
Tridecylic acid Tridecanoic acid CH3(CH2)11COOH C13:0
Myristic acid Tetradecanoic acid CH3(CH2)12COOH C14:0
Pentadecylic acid Pentadecanoic acid CH3(CH2)13COOH C15:0
Palmitic acid Hexadecanoic acid CH3(CH2)14COOH C16:0
Margaric acid Heptadecanoic acid CH3(CH2)15COOH C17:0
Stearic acid Octadecanoic acid CH3(CH2)16COOH C18:0
Nonadecylic acid Nonadecanoic acid CH3(CH2)17COOH C19:0
Arachidic acid Eicosanoic acid CH3(CH2)18COOH C20:0

C4, familiar as Butyric acid, helps maintain the integrity of the intestinal barrier and the blood brain barrier.  Butyric acid, or butyrate, is also an HDAC inhibitor and it seems that in animal models, and some humans, a small amount can be beneficial but large amounts can have a negative effect. A small amount in humans seems to be about 500 mg a day.  There are earlier posts is this blog on butyrate.

C3, familiar as Propionic acid, is bad for you and too much propionic acid will by itself cause autistic behaviours. NAC counters the effect of propionic acid in mouse models.

All those people eating coconut oil are consuming a 99% mixture of fatty acids with 1% phytosterols.

Phytosterols like β-SitosterolStigmasterolAvenasterol and Campesterol likely explain why coconut oil actually reduces "bad" cholesterol, rather than increasing it, as predicted by the American Heart Association and others. This counters the negative effect of the Palmitic acid (C16).

Lauric acid (C12) is thought to increase HDL ("good") cholesterol and may have a beneficial effect on acne.

Myristic acid (C14) is also thought to increase HDL ("good") cholesterol.

Palmitic acid (C16) raises LDL ("bad") cholesterol and large amounts have other negative effects.

Oleic acid is also found in olive oil and is seen as a fat with beneficial effects.



Fatty acid content of coconut oil
Type of fatty acid pct
Caprylic saturated C8
7%
Decanoic saturated C10
8%
Lauric saturated C12
48%
Myristic saturated C14
16%
Palmitic saturated C16
9.5%
Oleic monounsaturated C18:1
6.5%
Other
5%
black: Saturated; grey: Monounsaturated; blue: Polyunsaturated


So the only "bad" part of coconut oil is the Palmitic acid (C16).

As for MCT oil, what is in that?


In pharmaceutical MCT oil, like the one sold by Nestle, the contents are:-


Shorter than C8      1%
C8 (Octanoic)      54%
C10 (Decanoic)   41%
Longer than C10    4%

What is the effect of those fatty acids with more than 10 carbon atoms?  Nobody likely knows.



Cooking with MCT Oil? 

This is what Nestle has in mind for dinner.


Mct Spaghetti With Meat Sauce






4 Tbsp. MCT Oil® (Medium Chain Triglycerides)
1 lb. very lean ground veal or beef
1 tsp. salt
1/2 tsp. pepper
1/4 cup chopped onion
3 Tbsp. chopped green pepper
1 cup MCT Tomato Sauce (see recipe on site)
2 cups cooked spaghetti

Heat MCT Oil; add veal, salt and pepper.
Cook until meat is brown.
Add onion, green pepper, and tomato sauce. Cook for 30 minutes over low heat.
Add cooked spaghetti, stir and serve.