TRH and Rifaximin – an alternative to intranasal TRH or oral Taltirelin/Ceredist?

I think this is going to be one of my smarter posts. It may be more for our doctor readers and our motivated home-based researchers. It does remain a hypothesis and while it looks plausible it is certainly not 100% proven – so typical Peter stuff.

Many parents with autism regularly treat their child with the antibiotic Rifaximin. This drug is also the go-to therapy for SIBO (small intestine bacterial overgrowth) and is a key part of the Nemechek autism protocol to increase butyric acid production in the gut (and reduce propionic acid).

Some parents report that their child with completely normal GI function responds well behaviorally to Rifaximin.

Rifaximin is taken orally and stays in the gut, it does not enter the blood stream.

Our long-time reader Maja mentioned that she still uses Rifaximin in her now adult daughter.

I then did a quick Google and was surprised to see Rifaximin linked to the hormone TRH.

And, most surprising, you can use Rifaximin to treat prostate inflammation, via its effect on TRH.

TRH was the subject of an experiment I did 12 years ago. I suggested that an existing Japanese drug, an orally available TRH super-agonist, could be repurposed at a low dose to treat autism.

 https://www.epiphanyasd.com/2014/05/the-peter-hypothesis-of-trh-induced.html

I then noted that a well-known, but a little controversial, doctor in the US used intranasal TRH to treat his patients with chronic fatigue syndrome.

Another doctor had grant funding from the US military to develop intranasal TRH to reduce suicides in veterans.

In my old post I started by wondering why my son and some others with severe autism respond so well to sensory stimulation like standing on the upper deck of a ferry boat in the open sea on a windy day, or sitting in an open-top bus, driving in a convertible car etc.

Without be able to do any testing I looked for “similar” situations that haven been studied. The closest I found was people jumping out of a plan (with a parachute) where one of the key changes was a surge in the level of the hormone prolactin.

How to replicate the open-top bus effect? One of my doctor relatives suggested sitting Monty in front of a fan. Over course I wanted better than that. I found that stimulating TRH receptors in the brain would release prolactin.  It was already known that TRH is disturbed in autism.

It seemed to me that a Japanese orphan drug developed to treat spinocerebellar degeneration (SCD) – a group of progressive neurodegenerative disorders characterized by ataxia (poor coordination, gait disturbance, speech difficulties) could be repurposed.

I did discuss with a Japanese doctor in Osaka and he prescribed it.

It is a very expensive drug, even when bought with a prescription, and it has a very short expiry date. The idea was to use a micro-dose, to avoid undesirable side effects and this would also make the price less scary. I thought it provided a benefit without side effects, but was impractical. At the full dose it is potent and is the only drug I have trialed that had a near immediate profound effect on myself. I suddenly had hyper-acute vision. The micro dose had no effect on me.

Since Ceredist (taltirelin) is a TRH analogue, it could in theory affect the hypothalamic–pituitary–thyroid (HPT) axis.

TRH normally stimulates TSH release from the pituitary, which then increases thyroid hormone (T4/T3) secretion. Taltirelin was designed for CNS activity rather than endocrine use. Its clinical development in Japan for spinocerebellar degeneration focused on neurological symptoms, not thyroid stimulation. Animal studies showed that taltirelin has much weaker TSH-releasing activity than native TRH, but much stronger central nervous system stimulant effects (improved motor coordination, wakefulness).

Human data at therapeutic doses for spinocerebellar degeneration, significant changes in thyroid hormone levels (TSH, T3, T4) have not been a common clinical issue. Monitoring thyroid function is not part of standard Ceredist treatment.

 

So what is TRH?

TRH (thyrotropin-releasing hormone) serves as a master regulator of energy metabolism, mood, arousal, cognition, and immune balance.

Core Endocrine Role

Produced in the hypothalamus (paraventricular nucleus), but also found in other brain regions and peripheral tissues.

Main function is to stimulate the anterior pituitary to release TSH (thyroid-stimulating hormone), this increases thyroid hormone (T3, T4) production in the thyroid gland.

A secondary effect promotes prolactin release from the pituitary. TRH is a significant stimulator, especially when dopamine inhibition is reduced.

 

Effects on Other Hormones

Growth hormone & insulin: Some modulatory effects reported in stress and metabolism, though less central.

ACTH/cortisol: Minor indirect effects; TRH can modulate stress responses via cross-talk with the HPA axis.

 

Mood and Behavior

Antidepressant effects - TRH has rapid mood-elevating and activating effects in both animals and humans, independent of thyroid hormones. Some clinical studies have tested TRH or TRH analogs as rapid-acting antidepressants.

Arousal & vigilance - it increases wakefulness, motivation, and locomotor activity.

Anxiety - can produce mild anxiogenic effects at high doses, but generally associated with improved mood and alertness.

 

Cognition

Neurotransmitter modulation - TRH interacts with cholinergic, dopaminergic, and glutamatergic systems.

Memory & learning - TRH and TRH-like peptides enhance memory consolidation and counteract cognitive decline in animal studies.

Neuroprotection - shown to reduce neuronal injury in models of ischemia and trauma.

 

Inflammation & Immunity

 Anti-inflammatory - TRH dampens pro-inflammatory cytokine production (e.g., TNF-α, IL-1β).

Microglia modulation - TRH reduces microglial over-activation, relevant in neuroinflammation.

Systemic effects: TRH analogs show protective roles in sepsis and multiple organ injury in animal studies, likely via immune regulation and mitochondrial support.

 

Here is the recent study that showed the common antibiotic Rifaximin increases TRH in the brain and in peripheral tissues. Rifaximin itself stays within the gut when taken by mouth, it does not enter the blood stream. It changes the gut microbiota which then sends a signal via vagus nerve to the brain (clever, isn’t it?).

Caveat – rats are not humans.

 

Rifaximin modulates TRH and TRH-like peptide expression throughout the brain and peripheral tissues of male rats

 

The TRH/TRH-R1 receptor signaling pathway within the neurons of the dorsal vagal complex is an important mediator of the brain-gut axis. Mental health and protection from a variety of neuropathologies, such as autism, Attention Deficit Hyperactivity Disorder, Alzheimer’s and Parkinson’s disease, major depression, migraine and epilepsy are influenced by the gut microbiome and is mediated by the vagus nerve. The antibiotic rifaximin (RF) does not cross the gut-blood barrier. It changes the composition of the gut microbiome resulting in therapeutic benefits for traveler’s diarrhea, hepatic encephalopathy, and prostatitis. TRH and TRH-like peptides, with the structure pGlu-X-Pro-NH₂, where “X” can be any amino acid residue, have reproduction-enhancing, caloric-restriction-like, anti-aging, pancreatic-β cell-, cardiovascular-, and neuroprotective effects. TRH and TRH-like peptides occur not only throughout the CNS but also in peripheral tissues. To elucidate the involvement of TRH-like peptides in brain-gut-reproductive system interactions 16 male Sprague–Dawley rats, 203 ± 6 g, were divided into 4 groups (n = 4/group): the control (CON) group remained on ad libitum Purina rodent chow and water for 10 days until decapitation, acute (AC) group receiving 150 mg RF/kg powdered rodent chow for 24 h providing 150 mg RF/kg body weight for 200 g rats, chronic (CHR) animals receiving RF for 10 days; withdrawal (WD) rats receiving RF for 8 days and then normal chow for 2 days.

Results

Significant changes in the levels of TRH and TRH-like peptides occurred throughout the brain and peripheral tissues in response to RF. The number of significant changes in TRH and TRH-like peptide levels in brain resulting from RF treatment, in descending order were: medulla (16), piriform cortex (8), nucleus accumbens (7), frontal cortex (5), striatum (3), amygdala (3), entorhinal cortex (3), anterior (2), and posterior cingulate (2), hippocampus (1), hypothalamus (0) and cerebellum (0). The corresponding ranking for peripheral tissues were: prostate (6), adrenals (4), pancreas (3), liver (2), testis (1), heart (0).

Conclusions

The sensitivity of TRH and TRH-like peptide expression to RF treatment, particularly in the medulla oblongata and prostate, is consistent with the participation of these peptides in the therapeutic effects of RF. 

 

It turns out that other researchers have looked at Rifaximin’s effects on the brain, but they never understood the mechanism.

 

Effects of Rifaximin on Central Responses to Social Stress—a Pilot Experiment

Probiotics that promote the gut microbiota have been reported to reduce stress responses, and improve memory and mood. Whether and how antibiotics that eliminate or inhibit pathogenic and commensal gut bacteria also affect central nervous system functions in humans is so far unknown. In a double-blinded randomized study, 16 healthy volunteers (27.00 ± 1.60 years; 9 males) received either rifaximin (600 mg/day) (a poorly absorbable antibiotic) or placebo for 7 days. Before and after the drug intervention, brain activities during rest and during a social stressor inducing feelings of exclusion (Cyberball game) were measured using magnetoencephalography. Social exclusion significantly affected (p < 0.001) mood and increased exclusion perception. Magnetoencephalography showed brain regions with higher activations during exclusion as compared to inclusion, in different frequency bands. Seven days of rifaximin increased prefrontal and right cingulate alpha power during resting state. Low beta power showed an interaction of intervention (rifaximin, placebo) × condition (inclusion, exclusion) during the Cyberball game in the bilateral prefrontal and left anterior cingulate cortex. Only in the rifaximin group, a decrease (p = 0.004) in power was seen comparing exclusion to inclusion; the reduced beta-1 power was negatively correlated with a change in the subjective exclusion perception score. Social stress affecting brain functioning in a specific manner is modulated by rifaximin. Contrary to our hypothesis that antibiotics have advert effects on mood, the antibiotic exhibited stress-reducing effects similar to reported effects of probiotic

 

Effects of the antibiotic rifaximin on cortical functional connectivity are mediated through insular cortex

It is well-known that antibiotics affect commensal gut bacteria; however, only recently evidence accumulated that gut microbiota (GM) can influence the central nervous system functions. Preclinical animal studies have repeatedly highlighted the effects of antibiotics on brain activity; however, translational studies in humans are still missing. Here, we present a randomized, double-blind, placebo-controlled study investigating the effects of 7 days intake of Rifaximin (non-absorbable antibiotic) on functional brain connectivity (fc) using magnetoencephalography. Sixteen healthy volunteers were tested before and after the treatment, during resting state (rs), and during a social stressor paradigm (Cyberball game—CBG), designed to elicit feelings of exclusion. Results confirm the hypothesis of an involvement of the insular cortex as a common node of different functional networks, thus suggesting its potential role as a central mediator of cortical fc alterations, following modifications of GM. Also, the Rifaximin group displayed lower connectivity in slow and fast beta bands (15 and 25 Hz) during rest, and higher connectivity in theta (7 Hz) during the inclusion condition of the CBG, compared with controls. Altogether these results indicate a modulation of Rifaximin on frequency-specific functional connectivity that could involve cognitive flexibility and memory processing.

  

Probing gut‐brain links in Alzheimer's disease with rifaximin

Gut‐microbiome‐inflammation interactions have been linked to neurodegeneration in Alzheimer's disease (AD) and other disorders. We hypothesized that treatment with rifaximin, a minimally absorbed gut‐specific antibiotic, may modify the neurodegenerative process by changing gut flora and reducing neurotoxic microbial drivers of inflammation. In a pilot, open‐label trial, we treated 10 subjects with mild to moderate probable AD dementia (Mini‐Mental Status Examination (MMSE) = 17 ± 3) with rifaximin for 3 months. Treatment was associated with a significant reduction in serum neurofilament‐light levels (P < .004) and a significant increase in fecal phylum Firmicutes microbiota. Serum phosphorylated tau (pTau)181 and glial fibrillary acidic protein (GFAP) levels were reduced (effect sizes of −0.41 and −0.48, respectively) but did not reach statistical significance. In addition, there was a nonsignificant downward trend in serum cytokine interleukin (IL)‐6 and IL‐13 levels. Cognition was unchanged. Increases in stool Erysipelatoclostridium were correlated significantly with reductions in serum pTau181 and serum GFAP. Insights from this pilot trial are being used to design a larger placebo‐controlled clinical trial to determine if specific microbial flora/products underlie neurodegeneration, and whether rifaximin is clinically efficacious as a therapeutic.

 

Rifaximin and the prostate

For some reason one of the main areas where Rifaximin triggers the production of TRH is in the prostate, in males. There are studies showing how Rifaximin can be used to treat prostatitis (prostate inflammation).

Symptom Severity Following Rifaximin and the Probiotic VSL#3 in Patients with Chronic Pelvic Pain Syndrome (Due to Inflammatory Prostatitis) Plus Irritable Bowel Syndrome

This study investigated the effects of long-term treatment with rifaximin and the probiotic VSL#3 on uro-genital and gastrointestinal symptoms in patients with chronic prostatitis/chronic pelvic pain syndrome (CP/CPPS) plus diarrhoea-predominant irritable bowel syndrome (D-IBS) compared with patients with D-IBS alone. Eighty-five patients with CP/CPPS (45 with subtype IIIa and 40 with IIIb) plus D-IBS according to the Rome III criteria and an aged-matched control-group of patients with D-IBS alone (n = 75) received rifaximin and VSL#3. The primary endpoints were the response rates of IBS and CP/CPPS symptoms, assessed respectively through Irritable Bowel Syndrome Severity Scoring System (IBS-SSS) and The National Institute of Health Chronic Prostatitis Symptom Index (NIH-CPSI), and performed at the start of therapy (V0) and three months after (V3). In IIIa prostatitis patients, the total NIH-CPSI scores significantly (p < 0.05) decreased from a baseline mean value of 21.2 to 14.5 at V3 , as did all subscales, and in the IIIb the total NIH-CPSI score also significantly decreased (from 17.4 to 15.1). Patients with IBS alone showed no significant differences in NIH-CPSI score. At V3, significantly greater improvement in the IBS-SSS and responder rate were found in IIIa patients. Our results were explained through a better individual response at V3 in IIIa prostatitis of urinary and gastrointestinal symptoms, while mean leukocyte counts on expressed prostate secretion (EPS) after prostate massage significantly lowered only in IIIa cases. 

Since SIBO is treated by rifaximin, some researchers linked SIBO with prostatitis: 

Chronic prostatitis and small intestinal bacterial overgrowth: is there a correlation?

Background: Clinical management of chronic inflammation of prostate and seminal vesicles is very complex. Among the causes of recurrent chronic prostatitis (CP), a possible malabsorption, such as lactose intolerance, in turn related to small intestinal bacterial overgrowth (SIBO), should be considered.

Methods: We have performed lactose and lactulose breath test (BT) in 42 patients with CP, in order to evaluate the prevalence of SIBO in this kind of patients and the concordance of the two tests.

Results: A positive lactulose BT was present in 33/42 patients and in 73% (24/33) was associated to lactose malabsorption. Five patients had positive response after lactulose, while only 4 had both negative tests.

Conclusions: Our data showed an association between lactose and lactulose BT positivity. They also indicated high prevalence of bacterial colonization of small bowel in patients with CP, possibly related to recurrence or chronicity of genitourinary tract inflammation. The research for these phenomena could be relevant in diagnostic route of infertile patients in whom slight gastro-enteric symptoms can be underestimated.

 

For those of you who still read books:

 

Betrayal by the Brain: The Neurologic Basis of Chronic Fatigue Syndrome, Fibromyalgia Syndrome, and Related Neural Network Disorders
This seminal work presents Dr. Goldstein's theory that CFS and fibromyalgia result from dysfunctions in neural networks. It integrates neuroscience research into the pathophysiology and treatment of these conditions.

A Companion Volume to Dr. Jay A. Goldstein's Betrayal by the Brain: A Guide for Patients and Their Physicians
Authored by Katie Courmel, this companion guide simplifies Dr. Goldstein's theories and treatment protocols for a broader audience, aiding patients and physicians in understanding and applying his methods.

 Tuning the Brain: Principles and Practice of Neurosomatic Medicine

In this book, Dr. Goldstein outlines the principles of neurosomatic medicine, a field he developed that combines neurology, psychiatry, and pharmacology to treat chronic illnesses.

In Tuning the Brain: Principles and Practice of Neurosomatic Medicine, Dr. Jay A. Goldstein discusses the use of thyrotropin-releasing hormone (TRH) in treating chronic fatigue syndrome (CFS) and related disorders. He describes TRH as a neuropeptide that can modulate neural network activity, particularly through the trigeminal nerve, which is involved in sensory processing. By stimulating this pathway, TRH may help "re-tune" the brain's response to sensory input, potentially alleviating symptoms associated with CFS and similar conditions.

The book outlines the principles of neurosomatic medicine, a field Dr. Goldstein developed that combines neurology, psychiatry, and pharmacology to treat chronic illnesses. It emphasizes the rapid modulation of neural networks through pharmacological means, aiming to restore normal sensory processing and alleviate symptoms.

 

Conclusion

It does look like Rifaximin has interesting effects beyond where it can reach itself.

Rifaximin → modifies gut microbiota → activates vagus nerve

Vagus nerve → signals to brainstem → hypothalamus → TRH release 

According to that rat study, TRH and TRH-like peptides are present in the prostate, and their levels change in response to rifaximin. The TRH (or TRH-like peptides) in the prostate is produced locally in the prostate tissue itself, not delivered there from the brain via the bloodstream. the level of production can be modulated by gut–brain signaling, such as after rifaximin treatment.

I have to say that this reminds me of using L-Reuteri probiotic bacteria to send a signal via the same vagus nerve to release oxytocin in the brain. Seems a better approach than intranasal oxytocin.

I think the study showing Rifaximin improves the response to social stress fits with Dr Goldstein’s use of intranasal TRH to “retune” the brain in the conditions he studied and the potential use to reduce suicide initiations. It is enough for me to see TRH as a possible common factor.

I think Goldstein and the US DoD scientists should have used the TRH super-agonist Taltirelin/Ceredist. It is 30x more potent and yet does not affect thyroid function. It also has a far longer half-life. The other alternative, we now see, would have been to use Rifaximin.

Goldstein has passed away and the US DoD gave upon TRH. Research indicates that intranasal esketamine can rapidly reduce suicidal thoughts. Esketamine was FDA approved in 2019.

Taltirelin was approved for use in humans in Japan in 2000 for spinocerebellar degeneration (SCD).

Note that spinocerebellar degeneration (SCD) has no drug therapy in the US/Europe, even though one has existed in Japan for 25 years. Looks pretty odd to me. In a perfect world low dose Taltirelin could be a useful add-on therapy for many neurological conditions and potentially even for prostatitis! Don’t hold your breath.

Taltirelin is now being researched in animal models of Parkinson’s and fatigue syndromes.

Unless you live in Japan and have a pal who is a doctor, I think autism parents are best off with Rifaximin.

As Maja just pointed out “Rifaximin is still very helpful. I repeat a ten-day course (2x400 mg) every two to three months”, in her adult daughter. We can never know for sure if increased TRH is mechanism, or reduced SIBO, or increased butyric acid, or something else. If it works, stay with it!

pH and Neuronal Excitability - Therapy in Autism, Epilepsy, Mitochondrial Disease and ASIC mutations. Plus GPR89A

 

Diamox or Meldonium would make it easier

 

Several times recently the subject of pH (acidity/alkalinity) has come up in my discussions with fellow parents. It is not a subject that gets attention in the autism research, so here is my contribution to the subject.

If your child has a blood gas test a day after a seizure and it shows high pH, this is not the result of the seizure, but a likely cause of it. Treat the elevated pH to avoid another seizure and likely also improve autism symptoms. It may be respiratory alkalosis which is caused by hyperventilation, due to stress, anxiety etc.

The regulation of pH inside and outside brain cells is a delicate balance with far-reaching consequences. Subtle shifts toward acidity (low pH) or alkalinity (high pH) can alter calcium handling, neuronal excitability, and ultimately drive seizures, fatigue, or even inflammation. This interplay becomes especially important in conditions like autism, epilepsy, and mitochondrial disease, where metabolism and excitability are already dysregulated.

You can measure blood pH quite easily, but within cells different parts are maintained at very different levels of pH and this you will not be able to measure. Blood pH is about 7.4 (slightly alkaline) the gogli apparatus is slightly acidic, whereas the lysome is very acidic (pH about 4.7).

 

pH and Calcium Balance

Calcium (Ca²⁺) is central to neuronal excitability. Small pH changes shift the balance between intracellular and extracellular calcium:

• Alkalosis (↑ pH): reduces extracellular calcium availability, destabilizes neuronal membranes, and promotes hyperexcitability and seizures.
• Acidosis (↓ pH): activates acid-sensing ion channels (ASICs), leading to Na⁺ and Ca²⁺ influx and further excitability.

Thus, both too much acidity and too much alkalinity can increase seizure risk, though through different mechanisms.

Your body should tightly regulate its pH. You can only nudge it slightly up or down. Even small changes can be worthwhile in some cases.

When extracellular (ionized) calcium enters neurons through ion channels it can drive inflammation, excitability, and mitochondrial stress. Calcium needs to be in the right place and in autism it often is not, for a wide variety of reasons.

 

 

Mitochondrial Disease and pH

Mitochondria produce ATP through oxidative phosphorylation. Dysfunction can impair this process and lead to accumulation of lactate (acidosis) or, paradoxically, reduced proton flux (relative alkalosis). In autism, mitochondrial dysfunction is reported in a significant minority (10–20%) of cases.

 

Hyperventilation and Alkalosis

Another often-overlooked contributor is hyperventilation. By blowing off CO₂, blood pH rises (respiratory alkalosis), leading to reduced ionized calcium and increased excitability. This is the reason why hyperventilation is used during EEG testing to provoke seizures in susceptible individuals.

 

Therapeutic Approaches - Adjusting pH

Several therapies—old and new—intentionally alter pH balance:

1. Sodium and Potassium Bicarbonate

• Mechanism: Buffers acids, increases systemic pH (alkalinization).
• Applications: Beneficial in some cases of autism and epilepsy, as reported in blogs and small studies.
• Note: Raises extracellular pH, which can reduce ASIC activation but may increase excitability if alkalosis is excessive.
• Beyond buffering, sodium bicarbonate (baking soda) has been shown to trigger anti-inflammatory vagal nerve pathways. This effect may be especially valuable in neuroinflammation seen in autism and epilepsy.

 

2. Acetazolamide (Diamox)

• Mechanism: A carbonic anhydrase inhibitor that causes bicarbonate loss in the urine, lowering blood pH (mild acidosis).
• Neurological Effects: Used as an anti-seizure drug, especially in patients with channelopathies and mitochondrial disorders.
• In Climbers: At altitude, the body tends toward alkalosis due to hyperventilation (blowing off CO₂). Diamox counteracts this by inducing a mild metabolic acidosis, which stimulates ventilation, improves oxygenation, and prevents acute mountain sickness (AMS). This is why mountaineers often describe Diamox as helping them “breathe at night” in the mountains.

3. Zonisamide

• Mechanism: Another carbonic anhydrase inhibitor, with both anti-seizure and mild acidifying effects.
• Benefit: Often used in refractory epilepsy.

 

ASICs: Acid-Sensing Ion Channels

ASICs are neuronal ion channels directly gated by protons (H⁺). Their activity is pH-sensitive:

• Low pH (acidosis): Activates ASICs → Na⁺/Ca²⁺ influx → excitability and seizures.
• High pH (alkalosis): Reduces ASIC activity, but destabilizes calcium balance in other ways.

 

ASIC Mutations

Mutations in ASIC genes can alter how neurons respond to pH shifts. In theory, modest therapeutic modulation of pH (via bicarbonate or acetazolamide) could normalize excitability in patients with ASIC mutations.

 

ASIC2 is seen as a likely autism gene. There is even an ASIC2 loss of function mouse model.

Give that mouse Diamox!

 

Meldonium vs Diamox — Two Paths to Survive Altitude

During the Soviet–Afghan war in the 1980s, Russian troops were supplied with meldonium, while American soldiers and climbers commonly used acetazolamide (Diamox) for altitude adaptation. The Mujahideen and Taliban need neither, because they have already adapted to the low oxygen level.

Meldonium is a Latvian drug made famous by the tennis star Maria Sharapova who was found to be taking it for many years. It is a very plausible therapy to boost the performance of your mitochondria and so might help some autism. I know some people have tried it.

Although both drugs were used to improve performance under hypoxia, they worked in almost opposite ways:

 

At high altitude without Diamox

• You hyperventilate to compensate for low oxygen.
• Hyperventilation ↓ CO₂ in the blood → respiratory alkalosis (↑ pH).
• The alkalosis suppresses breathing (since the brainstem senses “too alkaline, slow down”), which is why people breathe shallowly at night, leading to periodic apnea and low oxygen saturation.

With Diamox

• Diamox blocks carbonic anhydrase in the kidneys → you excrete more bicarbonate (HCO₃⁻).
• This causes a metabolic acidosis (↓ pH).
• The brainstem now senses blood as “acidic,” which stimulates breathing.
• So, you hyperventilate more, but this time it’s sustained, because the metabolic acidosis counterbalances the respiratory alkalosis.

The net effect

• Without Diamox: hyperventilation → alkalosis → suppressed breathing → poor oxygenation.
• With Diamox: hyperventilation + mild metabolic acidosis → balanced pH → sustained ventilation and better oxygen delivery.

 So, the key is that Diamox shifts the body’s set point for breathing, letting climbers breathe harder without shutting down from alkalosis.

The Irony

• Meldonium - indirect alkalinization to reduce stress on cells.
• Diamox - deliberate acidification to stimulate respiration.
• Both approaches improved function under low oxygen, but they pulled physiology in opposite pH directions.

 

Another irony is that not only is Meldonium banned in sport, but so is Diamox. Diamox is banned because it is a diuretic and so can be used to mask the use of other drugs.

Now an example showing the impact of when pH control within the cell is dysfunctional.

 

GPR89A - the Golgi “Post Office” gene that keeps our cells running

When we think about genes involved in neurodevelopment, most people imagine genes that directly control brain signaling or neuron growth. But some genes quietly do their work behind the scenes, keeping our cellular “factories” running smoothly. One such gene is GPR89A, a gene that plays a critical role in regulating Golgi pH — and when it malfunctions, the consequences can ripple all the way to autism and intellectual disability (ID).

 

The Golgi Apparatus: The Cell’s Post Office

To understand GPR89A, it helps to picture the cell as a factory:

• The endoplasmic reticulum (ER) is the protein factory, producing raw products — proteins and lipids.
• The Golgi apparatus is the post office, modifying, sorting, and shipping these products to their proper destinations.

Just like a real post office, the Golgi must maintain precise conditions to function. One key condition is pH, the acidity inside the Golgi.

 

GPR89A: The Golgi’s pH Regulator

Inside the Golgi, acidity is carefully balanced by:

• V-ATPase pumps, which push protons (H⁺) in to acidify the lumen.
• Anion channels like GPR89A, which allow negative ions (Cl⁻, HCO₃⁻) to flow in, neutralizing the electrical charge and keeping the pH just right.

Think of GPR89A as the electrical wiring in the post office: without it, the machinery may be overloaded or misfiring, even if the raw materials (proteins) are fine.

 

When Golgi pH Goes Wrong

If GPR89A is mutated:

1.     The Golgi cannot maintain its normal acidic environment.

2.     Enzymes inside the Golgi — responsible for adding sugar chains to proteins (glycosylation) — cannot work properly.

3.     Proteins may become misfolded, unstable, or misrouted. Some may be sent to the wrong destination, while others are degraded.

This is akin to a post office with wrong sorting labels: packages (proteins) either go to the wrong address or get lost entirely.

 

Consequences for the Brain

Proteins are not just passive molecules; many are receptors, ion channels, adhesion molecules, or signaling factors essential for brain development. Mis-glycosylated proteins can lead to:

• Disrupted cell signaling
• Impaired synapse formation
• Altered neuronal communication

The end result can manifest as intellectual disability, autism spectrum disorders, or other neurodevelopmental conditions, because neurons are particularly sensitive to these trafficking and signaling errors.

 

Could Modulating Blood pH Help?

Since Golgi pH depends partly on cellular bicarbonate and proton balance, I have speculated whether small changes in blood pH could indirectly influence Golgi function:

• Sodium/potassium bicarbonate
• Increases extracellular bicarbonate and buffering capacity.
• Might slightly influence intracellular pH and indirectly affect Golgi pH.
• Acetazolamide (Diamox):
• Inhibits carbonic anhydrase, altering H⁺ and bicarbonate handling in cells.
• Could theoretically shift intracellular pH including Golgi pH

 

Systemic pH changes are heavily buffered by cells, so the impact on Golgi pH is likely to be modest at best.

Neither approach has been validated in human studies for improving glycosylation. Currently, there is no established therapy for GPR89A mutations.

Because there is no treatment, a reasonable option is a brief, carefully monitored trial.

• Try both interventions (bicarbonate then Diamox) for a short period.
• Observe for any measurable benefit in function or clinical outcomes.
• If there is no benefit, stop the trial — nothing is lost.

This approach allows cautious exploration without committing to a long-term therapy that may be ineffective.

 

The Bigger Picture

Even though GPR89A itself is not classified as a major autism or ID gene, its role in Golgi ion balance and glycosylation highlights how basic cellular “infrastructure” genes can profoundly affect brain development.

GPR89A reminds us that neurodevelopment is not only about neurons or synapses but also about the tiny cellular logistics systems that make them function. Maintaining Golgi pH is not glamorous, but without it, the entire cellular supply chain collapses, illustrating a pathway from a single gene mutation → cellular dysfunction → potential autism and ID outcomes.

Manipulating blood pH with bicarbonate or Diamox is an intriguing idea, will it provide a benefit?

 

Conclusion

pH regulation is a critical but underappreciated factor in autism, epilepsy, and mitochondrial disease. Subtle shifts in acidity or alkalinity affect calcium handling, ASIC activation, and neuronal excitability. Therapeutic strategies—from bicarbonates to carbonic anhydrase inhibitors—show that intentionally modulating pH can be both protective and symptomatic. Understanding the individual’s underlying metabolic and genetic context (eg mitochondrial function, ASIC mutations etc) will help determine whether a person might benefit more from raising or lowering pH.

For people with inflammatory conditions like some autism, or even MS, the simple idea of using baking soda to activate the vagus nerve is interesting.

·      Sodium bicarbonate → slight systemic alkalization.

·      Alkalization → reduced acidosis-related inflammatory signals.

·      Sensory neurons detect the pH change → activate vagus nerve.

·      Vagus nerve triggers cholinergic anti-inflammatory pathway → lowers pro-inflammatory cytokines.

We saw this in an old post and the researchers even went as far as severing the vagus nerve to prove it.

Potassium bicarbonate is a better long-term choice than sodium bicarbonate (baking soda) since most people lack potassium and have too much sodium already. It is cheap and OTC.

Diamox, Meldonium and Zonisamide are all used long term.

If you mention any of this to your doctor, expect a blank look coming back! Unless he/she is a mountaineer or perhaps a Latvian sports doctor!

 

Home-made Liposomal EGCG — a cost effective therapy for Autism, Parkinson’s, and Alzheimer’s? Plus alternative antioxidants — Whey protein and Liposomal vitamin C

A $30 ultrasonic jewellery cleaner can be repurposed to make inexpensive liposomal supplements

 

Today’s post is really one for those who prefer not to use prescription drugs to treat autism, or those that are just unable to access them. It is also one our longtime reader Ling might regard as MacGyver-esque (from the TV series following the adventures of Angus MacGyver, a secret agent armed with remarkable scientific resourcefulness to solve any problem out in the field using any materials at hand).

It is about increasing the bioavailability of OTC supplements (EGCG in today’s case, but applicable to many others) to get closer to achieving their often elusive health benefits in autism.

There are some effective OTC autism therapies, but most are not. This is why repurposing existing prescription drugs is likely necessary.

 

Liposomal

One of the big things in the supplement world at the moment is to call products “liposomal” and triple the price. The theory is that a preparation contains the active drug/supplement inside very tiny, fat-like particles. This form is easier for the body to absorb and allows more drug/supplement to get to the target area of the body, such as the brain. Liposomal drugs may have fewer side effects and should, in theory, work better than other forms of the drug.

This fatty encapsulation helps protect the active compound from degradation in the digestive system and improves its absorption through the gut. It can also enhance delivery to target tissues (like the brain) because liposomes can sometimes cross biological barriers more easily.

This should mean higher effectiveness with lower doses and potentially fewer side effects compared to non-encapsulated forms.

 

If you are interested in the details:

https://en.wikipedia.org/wiki/Liposome

“A liposome is a small artificial vesicle, spherical in shape, having at least one lipid bilayer. Due to their hydrophobicity and/or hydrophilicity, biocompatibility, particle size and many other properties, liposomes can be used as drug delivery vehicles for administration of pharmaceutical drugs and nutrients, such as lipid nanoparticles in mRNA vaccines, and DNA vaccines. Liposomes can be prepared by disrupting biological membranes (such as by sonication).

Liposomes are most often composed of phospholipids, especially phosphatidylcholine, and cholesterol, but may also include other lipids, such as those found in egg and phosphatidylethanolamine, as long as they are compatible with lipid bilayer structure. A liposome design may employ surface ligands for attaching to desired cells or tissues.”

 

 

  

By making your own liposomal supplements you will save a lot of money, compared to commercial ones and have access to an undegraded product. If you customize the recipe/ingredients thoughtfully, and carefully control the processing, the result might replicate some of the benefits seen in university studies. You might wonder why compounding pharmacies are not already doing this - maybe some are.

You can pretty much buy everything you need on Amazon. Once you have figured out your ingredients and decided how big a batch to make, it is no more complex than baking a cake.

 

Liposomal vitamin C and whey protein as therapies for oxidative stress

Oxidative stress is a core feature of most autism, particularly in the early years, and a feature of aging for everyone. Vitamin C is a natural antioxidant, but it is a water soluble vitamin that your body automatically regulates and excretes via urine. If you take mega-doses of a standard supplement it just goes down the toilet, it does not reach the bloodstream.

Intravenous vitamin C causes a large increase in levels in the blood. This can be used to treat sepsis and even mast cell activation syndrome (MCAS). It has potential in oncology (cancer treatment) because at high concentrations, vitamin C can act as a pro-oxidant, generating hydrogen peroxide that is selectively toxic to tumor cells.  

It has also been used for Ehlers-Danlos syndrome, fibromyalgia and other conditions

Some practitioners consider IV vitamin C for autism because of its: 

• Antioxidant effects – reducing oxidative stress, which is elevated in many children with autism.
• Anti-inflammatory properties – calming neuroinflammation and microglial activation.
• Support for neurotransmitter synthesis – vitamin C is a cofactor in dopamine and norepinephrine production.
• Possible mast cell stabilization – relevant in children with autism and comorbid mast cell activation syndrome (MCAS).
• Histamine degradation support – helps recycle tetrahydrobiopterin (BH4), indirectly involved in histamine metabolism.

 

It has been found that liposomal vitamin C can achieve levels in the blood somewhere in between IV-vitamin C and regular vitamin C by food or supplements. 

High levels of vitamin C can cause side effects such as kidney stones.

Liposomal vitamin C is better tolerated than very high doses of standard vitamin C. It looks like things are likely to start going wrong above 3,000mg a day of liposomal.

Healthy people just need a good diet. If they have a poor diet then take a multivitamin.

Liposomal or IV therapy is only for people with real health issues.

People with MCAS plus autism certainly do have health issues.

Ehlers–Danlos syndrome (and milder subclinical versions) is linked to MCAS, ADHD, autism and Tourette’s. So that is another group to consider.

Fibromyalgia was put forward (by me) as a step towards autism in some females, in subsequent levels of their family tree.

So overall the idea of liposomal vitamin C has much more merit than a natural sceptic would have first thought. (There are loads of YouTube videos of people doing this, and likely many did not really need it.)

 

Whey protein as an antioxidant 

This topic was recently highlighted by our reader Stephen and it naturally fits into this post.

Back in 2013 when I was developing my son’s therapy I had to choose between NAC and whey protein to boost glutathione (GSH), the body’s key antioxidant. I chose NAC.

Here is a great paper to support the use of whey protein.

 

Improving Antioxidant Capacity in Children With Autism: A Randomized, Double-Blind Controlled Study With Cysteine-Rich Whey Protein 

Previous studies indicate that children with autism spectrum disorder (ASD) have lower levels of glutathione. Nutritional interventions aim to increase glutathione levels suggest a positive effect on ASD behaviors, but findings are mixed or non-significant. A commercially available nutritional supplement comprising a cysteine-rich whey protein isolate (CRWP), a potent precursor of glutathione, was previously found to be safe and effective at raising glutathione in several conditions associated with low antioxidant capacity. Therefore, we investigated the effectiveness of a 90-day CRWP intervention in children with ASD and examined whether intracellular reduced and oxidized glutathione improvements correlated with behavioral changes. We enrolled 46 (of 81 screened) 3-5-year-old preschool children with confirmed ASD. Using a double-blind, randomized, placebo-controlled design, we evaluated the effectiveness of daily CRWP (powder form: 0.5 g/kg for children <20 kg or a 10-g dose for those >20 kg), compared with placebo (rice protein mimicking the protein load in the intervention group), on glutathione levels and ASD behaviors assessed using different behavioral scales such as Childhood Autism Rated Scale, Preschool Language Scale, Social Communication Questionnaire, Childhood Behavioral Checklist and the parent-rated Vineland Adaptive Behavior Scale, 2nd edition (VABS-II). Forty children (CRWP, 21; placebo, 19) completed the 90-day treatment period. Improvements observed in some behavioral scales were comparable. However, the VABS-II behavioral assessment, demonstrated significant changes only in children receiving CRWP compared to those observed in the placebo group in the composite score (effect size 0.98; 95% confidence intervals 1.42-4.02; p = 0.03). Further, several VABS-II domain scores such as adaptive behavior (p = 0.03), socialization (p = 0.03), maladaptive behavior (p = 0.04) and internalizing behavior (p = 0.02) also indicated significant changes. Children assigned to the CRWP group showed significant increases in glutathione levels (p = 0.04) compared to those in the placebo group. A subanalysis of the VABS-II scale results comparing responders (>1 SD change from baseline to follow up) and non-responders in the CRWP group identified older age and higher levels of total and reduced glutathione as factors associated with a response. CRWP nutritional intervention in children with ASD significantly improved both glutathione levels and some behaviors associated with ASD. Further studies are needed to confirm these results.

 

This study used a special commercial product called Immunocal, a cysteine-rich whey protein isolate (CRWP) that serves as a potent glutathione precursor.

There are less expensive alternatives to Immunocal that still offer high-quality, undenatured, cysteine-rich whey protein, especially if your goal is to support glutathione production without paying premium prices. These products are typically marketed as cold-processed, non-denatured whey protein concentrates or isolates, and some are even made from the same raw material sources as Immunocal.

If you want to further increase absorption you can even make a liposomal version of a cysteine-rich whey protein!! 

Regular body builders’ whey protein is great to help build muscles and to maintain muscle mass in seniors, but it is not the ideal source of cysteine. It has degraded during the production process, that why there are fancy ones available.

I think Stephen would indeed be well advised to add a scoop of cysteine-rich whey protein isolate (CRWP) to his sons’ diets. It should have a more prolonged effect than NAC. For young children with autism NAC really needs to be given 3-4 times a day.

You can have too much cysteine. You do not need high dose of both NAC and CRWP.

 

Back to liposomal EGCG

If you read the reviews many people find commercial liposomal supplements no more effective than the much cheaper, regular ones. I wonder why. Most likely they were not well formulated, or they degraded by the time they were used. These products are not heat or light stable.

Many manufactured products like fish oil supplements no longer maintain the health benefit of the genuine article (fish, in this case). This is because the product degraded and sometimes can even have a negative behavioral effect. 

 

Many healthy natural products like catechins or curcuma have very low bioavailability

There is a long list of healthy products that should be therapeutic in autism including:

·        Green tea catechins like EGCG

·        Turmeric/Curcuma

·        Resveratrol

·        Cocoa

·        Many herbs (sage, oregano, rosemary, Bacopa monnieri, ginseng, lions mane, etc)

They generally have very low bioavailability and so they work great in the lab, but much less so in humans; unless you consume very large amounts, for example turmeric in an Indian diet.

 

EGCG

I have written about EGCG in the past and have highlighted the research from Spain, more specifically from the beautiful city of Barcelona (just avoid visiting during the peak summer months). The research showed a benefit in Fragile X and Rett syndrome. As usual, no customized intervention has yet been brought to the market.

https://www.epiphanyasd.com/search/label/EGCG?max-results=20

Yet another study showing the potential benefit of EGCG, was published recently, this time in Pakistan.

 

Cross-linking catechins with neuro-regulatory model for autism spectrum disorder: A management in rats’ experiment 

We found that BDNF levels returned to normal levels within the groups who received Catechins treatment at III, IV, and V concentrations (compared to Group II), showing Catechins could potentially treat autism-like symptoms. The BDNF values measured in nano-grams per millilitre were Group I (13.1±0.3), followed by Group II (5.1±0.2) and Group III (9.8±0.3), Group IV (8.0±0.3), and then Group V (10.1±0.3). The BDNF concentration measured in Groups III, IV and V surpassed the BDNF level of Group II (PPA-induced) per results from a post-hoc Tukey's test at p 

Catechins successfully decreased neuroinflammatory markers throughout the brain and establish protective brain mechanisms that potentially improve ASD-associated behavioral symptoms. Rats given 100, 200, and 400 mg/kg of various catechins showed increases in BDNF levels of up to 75%, 61%, and 77%, respectively, as opposed to only 39% for rats that received no treatment. The findings of a study suggested a continuous and expandable neuroprotective effect based on dose strength. The experimental results demonstrated that in ASD models, catechins offer a potent and dosage-dependent defense against neuroinflammatory injuries.

  

This study confirms that epigallocatechin gallate (EGCG), among catechins, shows great promise for managing neuroinflammation in ASD patients. The results indicate that catechins deliver substantial reductions in neuroinflammatory markers, as they serve as protective element that improves behavioral and cognitive manifestations of ASD. Future investigations must explore mechanisms of effect and find best-use dosages for catechins while establishing their safety and lasting effect durations.

 

Then I came across this paper where the university made their own liposomal version of EGCG and tried it on their model of Parkinsons’ disease. It also worked very well. Autism is not Parkinsons’ but both conditions feature activated microglia, the brain’s immune cells that are also tasked with synaptic pruning housekeeping duties.

 

Epigallocatechin-3-Gallate-Loaded Liposomes Favor Anti-Inflammation of Microglia Cells and Promote Neuroprotection

Microglia-mediated neuroinflammation is recognized to mainly contribute to the progression of neurodegenerative diseases. Epigallocatechin-3-gallate (EGCG), known as a natural antioxidant in green tea, can inhibit microglia-mediated inflammation and protect neurons but has disadvantages such as high instability and low bioavailability. We developed an EGCG liposomal formulation to improve its bioavailability and evaluated the neuroprotective activity in in vitro and in vivo neuroinflammation models. EGCG-loaded liposomes have been prepared from phosphatidylcholine (PC) or phosphatidylserine (PS) coated with or without vitamin E (VE) by hydration and membrane extrusion method. The anti-inflammatory effect has been evaluated against lipopolysaccharide (LPS)-induced BV-2 microglial cells activation and the inflammation in the substantia nigra of Sprague Dawley rats. In the cellular inflammation model, murine BV-2 microglial cells changed their morphology from normal spheroid to activated spindle shape after 24 h of induction of LPS. In the in vitro free radical 2,2-diphenyl-1-picrylhydrazyl (DPPH) assay, EGCG scavenged 80% of DPPH within 3 min. EGCG-loaded liposomes could be phagocytized by BV-2 cells after 1 h of cell culture from cell uptake experiments. EGCG-loaded liposomes improved the production of BV-2 microglia-derived nitric oxide and TNF-α following LPS. In the in vivo Parkinsonian syndrome rat model, simultaneous intra-nigral injection of EGCG-loaded liposomes attenuated LPS-induced pro-inflammatory cytokines and restored motor impairment. We demonstrated that EGCG-loaded liposomes exert a neuroprotective effect by modulating microglia activation. EGCG extracted from green tea and loaded liposomes could be a valuable candidate for disease-modifying therapy for Parkinson’s disease (PD).

 

Looks great, but you cannot buy their product. It then appeared that people are already making liposomal supplements at home.

Dig a little deeper to see what other clever ideas exist in the university research world that might make DIY versions better. 

 

Liposomal Formulations for an Efficient Encapsulation of Epigallocatechin-3-Gallate: An In-Silico/Experimental Approach

As a part of research project aimed to optimize antioxidant delivery, here we studied the influence of both salts and lipid matrix composition on the interaction of epigallocatechin-3-gallate (EGCG) with bilayer leaflets. Thus, we combined in silico and experimental methods to study the ability of neutral and anionic vesicles to encapsulate EGCG in the presence of Ca2+ and Mg2+ divalent salts. Experimental and in silico results show a very high correlation, thus confirming the efficiency of the developed methodology. In particular, we found out that the presence of calcium ions hinders the insertion of EGCG in the liposome bilayer in both neutral and anionic systems. On the contrary, the presence of MgCl2 improves the insertion degree of EGCG molecules respect to the liposomes without divalent salts. The best and most efficient salt concentration is that corresponding to a 5:1 molar ratio between Mg2+ and EGCG, in both neutral and anionic vesicles. Concerning the lipid matrix composition, the anionic one results in better promotion of the catechin insertion within the bilayer since experimentally we achieved 100% EGCG encapsulation in the lipid carrier in the presence of a 5:1 molar ratio of magnesium. Thus, the combination of this anionic liposomal formulation with magnesium chloride, avoids time-consuming separation steps of unentrapped active principle and appears particularly suitable for EGCG delivery applications.

 

The Mozafari method for Liposomal delivery

The latest methods used in universities to make liposomal products cannot be entirely replicated at home, but there is a well-known method developed by Dr Mohammad Mozafari that has been proved to increase bioavailability 2 to 8 times. The Mozafari method is used today by biohackers at home. Often they seem to skip some important steps.

We can fine tune his method, for example by noting the research showing that magnesium ions can help stabilize the liposomes and improve encapsulation of EGCG. Calcium ions have a very negative effect and so make sure no calcium (for example, from hard water) enters the process. YouTubers just use tap water. So use high-quality deionized (DI) water and add Magnesium Chloride (MgCl₂).

Anionic liposomes (negatively charged phospholipids) promote better EGCG insertion compared to neutral liposomes. With Mg²⁺, anionic liposomes reached 100% encapsulation efficiency experimentally. So it was actually perfect.

Magnesium chloride (MgCl₂) at about a 5:1 molar ratio relative to EGCG

(Example: for 500 mg EGCG ≈ 1.1 mmol, add ~5.5 mmol MgCl₂ — roughly 670 mg MgCl₂·6H₂O)

Both pH and temperature control are important and seem to get ignored by YouTubers.

Choose the right lipid. Here are the choices:

Most DIYers are using Lecithin (sunflower or soy), which contains phosphatidylcholine (PC), plus other substances you do not want. It is cheaper than pure PC.

If you are making liposomal vitamin C, glutathione, DHA or EGCG for therapeutic use (e.g., autism, MCAS, oxidative stress), pure PC gives superior performance.

Lecithin is zwitterionic, meaning it contains both positive and negative charges, but is overall electrically neutral. This dual nature is what makes lecithin perfect for encapsulating both water-soluble (like vitamin C) and fat-soluble (like curcumin) compounds in liposomes.

For closer to University-grade work we need to look at pure chemicals.

·        Phosphatidylcholine (PC) — neutral

·        Phosphatidylserine (PS) — anionic (negative charged)

·        CHEMS (Cholesteryl Hemisuccinate), a negatively charged cholesterol derivative.

·        Cholesterol

 

Component             Role  

PC                               Bilayer structure & fluidity         

PS                               Anionic charge, Mg²⁺ interaction          

Cholesterol               Stabilization (optional)    

CHEMS                      Additional anionic charge (optional)

 

Phosphatidylserine (PS) is itself therapeutic

PS naturally concentrates in the brain, especially in neuronal membranes.

It is known to support memory, attention, synaptic function, and neuroplasticity — ideal for neurodegenerative and developmental conditions.

PS is negatively charged (anionic), which helps form stable liposomes and can improve encapsulation of positively charged or hydrophilic molecules like EGCG.

PS has functional activity, beyond just being a carrier, PS itself may synergize with EGCG and other cognitive-enhancing compounds.

Adding cholesterol makes the liposome less leaky and more resistant to degradation. Without cholesterol, liposomes are more prone to oxidation, fusion, or breakdown over time

  

Example for 2 g Total Lipids:

Lipid Component	Weight (grams)	Percentage
PC	1.2 g	60%
PS	0.4 g	20%
Cholesterol	0.4 g	20%

 

• PC provides a stable bilayer and good liposome formation.
• PS introduces a negative charge that enhances electrostatic interaction with Mg²⁺ and EGCG.
• Cholesterol improves membrane rigidity and stability, helping prevent leakage.
• You can adjust cholesterol slightly depending on how rigid you want the membrane.
• Maintain MgCl₂ at ~5:1 molar ratio to EGCG in the aqueous buffer for optimal encapsulation, as per references.

EGCG is highly oxidation-sensitive.

Both vitamin C (ascorbic acid) and vitamin E (tocopherol) protect:

·        the lipids in the liposome from peroxidation,

·        the EGCG itself from degradation.

So it is wise to add both vitamin C and E.

• Vitamin E is lipid-soluble and embeds in the bilayer.
• Vitamin C is water-soluble and protects the aqueous core.

 

Here is the home version.

 

 

Equipment

• Glass beaker or jar
• Ultrasonic cleaner (sold to clean jewellery)
• Stirring rod
• pH strips or meter
• Dark glass storage bottle

 

Method

1.     Mix Vitamin E with PS

o    Combine PS powder and vitamin E oil or powder thoroughly in a small container.

2.     Prepare aqueous phase

o    Dissolve EGCG powder and magnesium chloride in ~20 mL PBS or distilled water with buffer salts.

o    Add vitamin C to this aqueous solution last and stir gently until dissolved.

3.     Hydrate lipids

o    Slowly add the aqueous phase (EGCG + MgCl₂ + vitamin C) to the PS + vitamin E mix.

o    Stir or vortex gently to disperse.

4.     Sonicate

o    Place the mixture in an ultrasonic cleaner bath for 20–30 minutes, stirring occasionally.

o    Solution should become milky/opalescent, indicating liposome formation.

 

How to Use Ultrasonic Cleaner for Liposomal EGCG

1.     Prepare your liposome suspension in a suitable sealed container—usually a small glass vial or bottle with a tight lid (e.g., amber glass bottle or glass vial).

2.     Fill the ultrasonic cleaner tank with clean water—enough so that when you place your container in it, the water level reaches just below the lid or about 2/3 up the container’s height. The water must not overflow into your liposome container

3.     Place your sealed bottle/vial into the ultrasonic bath, making sure it sits upright and stable.

4.     Turn on the ultrasonic cleaner for the recommended at medium power.

5.     During the process, keep an eye on the temperature—if the water or sample gets too warm (>40°C), pause and let it cool, since heat will degrade EGCG.

6.     After sonication, remove the bottle and store the liposomal EGCG in a dark, refrigerated place.

 

Important Tips

• Use sealed containers to avoid contamination or water ingress.
• Never put the liposomal suspension directly into the ultrasonic cleaner’s water bath.
• If your ultrasonic cleaner has a temperature control or timer, use those settings to protect the sample.
• Clean the ultrasonic tank well before and after use.

The final product will be stable for 7 days in the fridge.

You can freeze portion sized doses in a silicone ice cube tray. Later store in the freezer in a zip lock bag for 2-3 months. Defrost in the fridge, one by one, as you need it.

Keeping the temperature below 40°C is essential when sonifying delicate compounds like EGCG, vitamin C, and phospholipids (especially phosphatidylserine). They degrade or oxidize easily when exposed to excessive heat.

 

 1. Use a Cold Water Bath

• Fill the ultrasonic cleaner with cold water (4–10°C).
• Add ice cubes to keep it cold.
• Replenish ice as needed during sonication.

 

2. Monitor Temperature

• Use a probe thermometer or an infrared laser thermometer.
• Check the temperature of your sample, not just the water bath.

 

Ultrasonic waves create cavitation — rapid formation and collapse of microbubbles — which:

• Generates localized heat (tiny hot spots in the solution)
• Transfers energy into the liquid, raising the overall temperature gradually
• Can increase your solution temperature from room temp to 50–60°C in 10–15 minutes if not managed

Even if the water bath feels lukewarm, the inside of your beaker can be much hotter, especially in the center.

 

 Sensitive Ingredients at Risk

• EGCG starts to degrade above ~40°C
• Phospholipids can oxidize or become unstable
• Vitamin C rapidly degrades in heat and light

 

Best Practices to Avoid Overheating

Tip	Why
Use an ice-cold bath	Keeps temp under control during sonication
Sonicate in short bursts (30s ON, 30s OFF)	Prevents buildup of heat
Stir gently before and after sonication	Helps distribute heat and emulsify
Monitor temperature regularly	Keeps you in the safe zone (under 40°C)
Work with small batches (≤100 mL)	Easier to cool and control

 

Sonication is the process of using high-frequency sound waves—usually ultrasound—to agitate particles in a liquid. In making liposomes, sonication helps break down large lipid aggregates into smaller, uniform liposomes by creating tiny bubbles that collapse and generate energy, mixing and dispersing the components more thoroughly.

In simpler terms, sonication is like using sound waves to gently shake and break up the mixture so that the fat-like particles (liposomes) form smaller, more consistent droplets, which can improve how well the active ingredient (like EGCG) gets absorbed by your body.

  

Conclusion

Immunocal, a cysteine-rich whey protein isolate (CRWP) does show a benefit in autism. It is an OTC product that is sold online.

EGCG is the most abundant catechin in green tea.  When taken orally, EGCG has poor absorption even at daily intake equivalent to 12 cups of green tea.

EGCG does show merit in autism research studies, but to be effective in humans the bioavailability needs to be improved. Using liposomes to encase the EGCG is a promising approach.

Will the method proposed in this post be effective?

I asked Gemini AI to comment on the method and it replied: 

"The EGCG method you described is a fantastic example of a DIY approach that is grounded in sound scientific principles. By using specific lipids, optimizing the formulation with magnesium, and strictly controlling the process, it goes far beyond the simplistic and often ineffective methods seen online.

While it won't produce a pharmaceutical-grade product, it is highly likely to create a solution that contains a significant number of genuine, stable, and correctly sized liposomes. This makes it far more likely to be an effective delivery system than the typical DIY liposomal vitamin C, which is often just an unverified emulsion."

Some people do grow their own broccoli sprouts to make sulforaphane, others grow wheat sprouts for spermidine. Some people grow their own probiotic bacteria. Making tumeric balls is a simple way to get the benefits of tumeric. There are many home-made options, and I think the parent almost certainly benefits. 

You would think that some enterprising pharmacist in Barcelona would start producing small batches of liposomal EGCG, using research grade equipment. I think Rett syndrome and Fragile X syndrome parents would buy it. Not to mention those who have parents diagnosed with Parkinson's or Alzheimer's.