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Thursday, 21 September 2023

Big heads, the Car wash, Transcranial pulse stimulation, GABA alpha 5 and Potassium channel Kv3.1


Today’s post is a review of some interesting new research that relates to the scope of this blog.  It ranges from training young people with autism/ID to work at the car wash, to more complex science.

Let’s start with the easiest paper. Somewhat bizarrely it was carried out in Japan by researchers from India. I am a fan of teaching kids to wash cars but I was surprised to see that it would be covered in a published research study.

One often forgotten item to teach teenagers and young adults with autism or ID is how to safely use public transport, so they might travel independently to and from any future job. We have had a lot of success with this recently. Monty, now aged 20, can get all the way from home to various different locations across the city using public transport, including changing buses and with journey times more than one hour.

 

Increasing car washing competency in adolescents with autism and intellectual disabilities: Researching visual task evaluation

This study looked at how well visual task evaluation helped teenagers with autism and intellectual disabilities become more competent at car washing. For disabled people to promote their independence and employment chances, car washing skills are crucial. The goal of this study was to ascertain whether training techniques that include visual task evaluation can improve car washing proficiency in teenagers with autism and intellectual disabilities. 30 participants, ranging in age from 12 to 18, participated in a pre-test/post-test design. Randomly chosen groups of participants were put into the evaluation group for the visual task or the control group. According to the findings, the visual task evaluation group outperformed the control group in terms of car washing ability. Adolescents with autism and intellectual disabilities can learn skills more quickly and become more independent by including visual task evaluation into their teaching strategies. These results demonstrate the potential for such treatments to enhance their quality of life and employment chances.

 

Car washing with a pressure washer is great fun for most people and washing a car thoroughly has many individual steps to master, so it is good practice.

  

Head size

It has been known for decades that big heads (macrocephaly) and small heads (microcephaly) are a tell-tale sign of a neurodevelopment problem. Normally, big heads are linked to intellectual disability, but very small heads are also a warning sign.

Readers may recall the Zika virus epidemic in Brazil in 2015. This mosquito-borne virus caused pregnant women to give birth to children with microcephaly. Zika virus infection caused intellectual disability in babies. The severity of the intellectual disability varied from mild to severe. Babies with Zika virus infection may have difficulty learning and communicating. They may also have problems with problem-solving and abstract thinking. Hearing and vision can be impaired and growth is retarded.  

Head size parts autism into two major subtypes

Essentially opposite paths in fetal brain development may explain two major subtypes of autism. In one of these subtypes, an unusually high number of excitatory neurons in a key brain region leads to large heads, or macrocephaly, which affects roughly 20 percent of people with autism; in the other, a decreased number of the same cells in that area leads to more typical head sizes, a new study finds. 

This fundamental biological difference suggests that “therapeutic avenues may be drastically different for these subtypes,” says lead investigator Flora Vaccarino, professor of neuroscience at Yale University. “That in turn could explain why drug treatments for autism so far are failing.”

 

The opposite brain development paths found in this research may both lead to autism because they are each a case of imbalance, says investigator Alexej Abyzov, associate professor of biomedical informatics at the Mayo Clinic in Rochester, Minnesota. 

The full paper:- 

Modeling idiopathic autism in forebrain organoids reveals an imbalance of excitatory cortical neuron subtypes during early neurogenesis

Idiopathic autism spectrum disorder (ASD) is highly heterogeneous, and it remains unclear how convergent biological processes in affected individuals may give rise to symptoms. Here, using cortical organoids and single-cell transcriptomics, we modeled alterations in the forebrain development between boys with idiopathic ASD and their unaffected fathers in 13 families. Transcriptomic changes suggest that ASD pathogenesis in macrocephalic and normocephalic probands involves an opposite disruption of the balance between excitatory neurons of the dorsal cortical plate and other lineages such as early-generated neurons from the putative preplate. The imbalance stemmed from divergent expression of transcription factors driving cell fate during early cortical development. While we did not find genomic variants in probands that explained the observed transcriptomic alterations, a significant overlap between altered transcripts and reported ASD risk genes affected by rare variants suggests a degree of gene convergence between rare forms of ASD and the developmental transcriptome in idiopathic ASD.

 

Head circumference at birth is a useful measurement, but what really matters is how it changes over time.  Hyperactive pro-growth signaling affects more than just brain growth, it also affects muscle development, which is easy to notice.  I have highlighted the graphic below several times in this blog and in my book.  It is a good summary of what is going on.

 


Kv3.1

Regular readers will know that I like ion channels. The reason is that dysfunctions in these channels really should be treatable.  Usually we are looking for channel blockers, but today with Kv3.1 we are looking for channel enhancers.

Ion channel enhancers increase the activity of ion channels without directly opening them. They do this by increasing the number of open channels, increasing the opening time of each channel, or decreasing the closing time of each channel.

  

At the heart of the study is a type of inhibitory neuron called GABAergic interneurons, which connect brain regions, playing vital roles in coordinating high-frequency brain activity. As a potential source of the excitatory/inhibitory imbalance in ASD and schizophrenia, evidence now points to malfunction of a type of potassium channel, Kv3.1, special to GABAergic interneurons. Denton and his team will aim to develop Kv3.1 enhancers and test their efficacy in restoring the balance of neural activity in a mouse model of ASD. In latter stages of this work, they’ll focus on key brain areas, using various lab techniques to carefully fill in neurological details surrounding any targeted drug effects.

“This grant creates opportunities for developing critically needed tool compounds to explore the role of Kv3.1 potassium channels in autism spectrum disorder and schizophrenia,” said Denton, professor of Anesthesiology and Pharmacology. “These are some of the most challenging and costly disorders going, and we’re excited to have this opportunity to take this work forward.”

 

Japanese researchers from the RIKEN Brain Science Institute are also thinking along the lines of targeting Kv3.1 to “correct aberrant developmental trajectories”. 

Kv3.1 channels regulate the rate of critical period plasticity 

The emergent function of fast-spiking PV-cell circuits during postnatal life may hold the key to a deeper understanding of critical periods in brain development (Reh et al., 2020) and the etiology of related mental illnesses as well (Do KQ and Hensch, 2015). The human neocortex notably shows a decrease in Kv3.1b channel protein in schizophrenia, a deficit that is restored by anti-psychotic drugs (Yanagi et al., 2014). Moreover, individuals with a KCNC1 loss-of-function variant can present intellectual disability without seizure and epilepsy (Poirier et al., 2017Park et al., 2019). Our work points toward a prophylactic psychiatry that may target these particular channels to correct aberrant developmental trajectories.

 

As with head size, the “when” is also important with correcting Kv3.1.  The idea is to intervene at a very early age to redirect the developmental trajectory, rather than just to improve today’s functioning.

The logical question is what drugs will Professor Denton come up with to explore the benefit of targeting Kv3.1.  Perhaps someone can beat him to it and save us all a couple of decades?

If you look up Kv3.1 or the gene that encodes it called KCNC1 you can read all about it.

https://www.genecards.org/cgi-bin/carddisp.pl?gene=KCNC1

 

As expected, there is no shortage of channel blockers – Nifedipine (used a calcium channel blocker), Miconazole (an antifungal), Capsaicin (an active component of chili peppers), Fluoxetine (better known as Prozac, which is vitamin P to many people) plus many more.

Professor Denton is hunting for a channel enhancer.  Keep an eye on what he comes up with. He has $2.7 million over 4 years to play with. 

 

Transcranial pulse stimulation

Many autism parents do not like drug therapies, but often like the idea of zapping the brain from outside. I liked the idea of Photo biomodulation (PBMT) a form of light therapy that utilizes light sources including lasers or LEDs.

 

Low Level Laser Therapy (LLLT) for Autism – seems to work in Havana


Home/Clinic based Photobiomodulation/Laser Therapy in Autism - acting on Light Sensitive Ion Channels, Mitochondria, Lymph Nodes and more


 

You could potentially do Low Level Laser Therapy (LLLT) at home.

Professor Manual Casanova is a fan of transcranial magnetic stimulation (TMS).

Today’s paper below is about transcranial pulse stimulation, which I suppose we can just call TPS.

Transcranial pulse stimulation (TPS) is a non-invasive brain stimulation technique that uses pulsed electrical or magnetic fields to stimulate the brain. It is a relatively new technique, but it has the potential to be used for a variety of purposes, including:

  • Treating neurological disorders such as Parkinson's disease, Alzheimer's disease, and depression
  • Enhancing cognitive function, such as memory and attention
  • Improving mood and well-being
  • Reducing pain
  • Promoting neuroplasticity, the ability of the brain to change and adapt

 


 

Effects of transcranial pulse stimulation on autism spectrum disorder: a double-blind, randomized, sham-controlled trial

 

Transcranial pulse stimulation has been proven effective to improve cognition, memory and depressive symptoms of Alzheimer’s disease, but supporting evidence on other neurological diseases or neuropsychiatric disorders remains limited. This study aimed to investigate the effects of transcranial pulse stimulation on the right temporoparietal junction, which is a key node for social cognition for autism spectrum disorder, and to examine the association between transcranial pulse stimulation and executive and social functions. This double-blinded, randomized, sham-controlled trial included 32 participants (27 males), aged 12–17 years with autism spectrum disorder. All eligible participants were randomized into either the verum or sham transcranial pulse stimulation group, on a 1:1 ratio, based on the Childhood Autism Rating Scale screening score. Sixteen participants received six verum transcranial pulse stimulation sessions (energy level: 0.2–0.25 mJ/mm2; pulse frequency: 2.5–4.0 Hz, 800 pulse/session) in 2 weeks on alternate days. The remaining 16 participants received sham transcranial pulse stimulation. The primary outcome measure included Childhood Autism Rating Scale score changes, evaluated by parents, from baseline to 3-month follow-ups. Secondary outcomes included a self-reported questionnaire responded to by parents and cognitive tests responded to by participants. A licensed mental health professional evaluated clinical global impression severity, improvement, efficacy and total score. Results revealed significant interactions in Childhood Autism Rating Scale and other secondary outcomes. Significant group and time effects were found in most secondary outcomes. Additionally, significant differences were found between the transcranial pulse stimulation and sham transcranial pulse stimulation groups in Childhood Autism Rating Scale and clinical global impression improvement and total score immediately after 2 weeks of transcranial pulse stimulation intervention (all P < 0.05), and effects were sustainable at 1- and 3-month follow-up, compared with baseline. The effect size of Childhood Autism Rating Scale (d = 0.83–0.95) and clinical global impression improvement (d = 4.12–4.37) were large to medium immediately after intervention and sustained at 1-month post-stimulation; however, the effects were reduced to small at 3-month post-stimulation (d = 2.31). These findings indicated that transcranial pulse stimulation over right temporoparietal junction was effective to reduce the core symptoms of autism spectrum disorder, as evidenced by a 24% reduction in the total Childhood Autism Rating Scale score in the verum transcranial pulse stimulation group. Additionally, the clinical global impression total score was reduced by 53.7% in the verum transcranial pulse stimulation group at a 3-month follow-up, compared with the baseline. Participants in the verum transcranial pulse stimulation group had shown substantial improvement at 1- and 3-month follow-ups, compared with baseline, although some of the neuropsychological test results were deemed statistically insignificant. Future replication of this study should include a larger sample derived from multi-nations to determine transcranial pulse stimulation as an alternative top-on treatment option in neuropsychiatry

 

TPS looks pretty impressive, based on the above study. TPS is available today, but it does need a lot of visits to the therapist. The effects are not permanent so you would have to keep going back for more.

People are doing transcranial direct current stimulation (tDCS) at home. 

People are zapping their brains at home to improve focus and clear brain fog. But is it safe?


For any kind of zapping therapy to be viable, it would have to be possible to do it yourself at home.

 

Targeting alpha 5 subunit of GABAA receptors

Some earlier posts in this blog did get rather complicated.  One field that I looked at in rather painful detail was the GABAA receptor. Some readers of this blog have children whose autism is entirely caused by a defect in this receptor, many other readers just see the effects of a GABAA malfunction caused by a problem with NKCC1/KCC2 expression resulting from the GABA developmental switch failing to occur.

I looked to me that targeting alpha 3 and alpha 5 subunits could well enhance cognition.

Alpha 3 is targeted by low dose Clonazepam, thanks to Professor Catterall.

Alpha 5 was targeted to treat Down syndrome, using a new drug called Basmisanil (an inverse agonist of alpha 5 subunit of GABAA). That work failed. I wrote about Cardiazol/ Pentylenetetrazol (PTZ) a drug that was widely used in the 1930s in mental hospitals to trigger seizures that were supposed to treat people with schizophrenia.  At much lower doses, it found a new purpose decades ago as an ingredient in cough medicine. 

The alpha 5 subunit is one of several subunits that can make up a GABAA receptor. GABAA receptors containing the alpha 5 subunit are thought to be involved in cognitive function, learning and memory, and mood regulation.

PTZ has been shown to block the action of GABA at alpha 5-containing GABAa receptors in animal studies.  

Variable Expression of GABRA5 and Activation of α5 -  a Modifier of Cognitive Function in Autism?

 

Sodium Benzoate and GABRA5 - Raising Cognitive Function in Autism 

Cardiazol, a failed Schizophrenia treatment from the 1930s, repurposed at low doses as a Cognitive Enhancer in Down Syndrome and likely some Autism

 

The logical human trial would be to use the cough mixture, Cardiazole that is already used in children. 

“We actual have quite a few readers from India and that is the only other country using this drug.  In India the producer is Nicholas Piramal and the brand name is Cardiazol Dicodid, it cost 30 US cents for 10ml.  So for less than $1, or 70 rupees, you might have a few months of cognitive enhancement, that is less than some people pay for 1 minute of ABA therapy.

If a few drops of this children’s cough medicine improves cognition please lets us all know.”

 

Back to recent research on alpha 5 that caught my attention.

 

An alpha 5-GABAa receptor positive allosteric modulator attenuates social and cognitive deficits without changing dopamine system hyperactivity in an animal model for autism

 Autism Spectrum Disorders (ASD) are characterized by core behavioral symptoms in the domains of sociability, language/communication, and repetitive or stereotyped behaviors. Deficits in the prefrontal and hippocampal excitatory/inhibitory balance due to a functional loss of GABAergic interneurons are proposed to underlie these symptoms. Increasing the postsynaptic effects of GABA with compounds that selectively modulate GABAergic receptors could be a potential target for treating ASD symptoms. In addition, deficits in GABAergic interneurons have been linked to dopamine (DA) system dysregulation, and, despite conflicting evidence, abnormalities in the DA system activity may underly some ASD symptoms. Here, we investigated whether the positive allosteric modulator of α5-containing GABAA receptors (α5-GABAARs) SH-053-2’F-R-CH3 (10 mg/kg) attenuates behavioral abnormalities in a rat model for autism based on in utero VPA exposure. We also evaluated if animals exposed to VPA in utero present changes in the ventral tegmental area (VTA) DA system activity using in vivo electrophysiology and if SH-053-2’F-R-CH3 could attenuate these changes. In utero VPA exposure caused male and female rats to present increased repetitive behavior (self-grooming) in early adolescence and deficits in social interaction in adulthood. Male, but not female VPA rats, also presented deficits in recognition memory as adults. SH-053-2’F-R-CH3 attenuated the impairments in sociability and cognitive function in male VPA-exposed rats without attenuating the decreased social interaction in females. Male and female adult VPA-exposed rats also showed an increased VTA DA neuron population activity, which was not changed by SH-053-2’F-R-CH3. Despite sex differences, our findings indicate α5-GABAARs positive allosteric modulators may effectively attenuate some core ASD symptoms

 

Fine tuning alpha 5, perhaps you need more, perhaps less?

 

Neurobiology and Therapeutic Potential of α5-GABA Type A Receptors

Despite being a genetically heterogeneous disorder, the potential utility for mechanism-based GABAAR pharmacologic treatment with ASDs is supported by shared pathologies both in patients and related mouse models.


  

PAM α5 GABAAR Therapeutic Applications

Neurodevelopmental Disorders

Mouse models of neurodevelopmental disorders that present with insufficient inhibitory tone show improvement with positive modulators of GABAAR signaling. In the Scn1a+/− mouse model of Dravet syndrome, a severe childhood epileptic encephalopathy syndrome with hyperactivity and autism behaviors, abnormal social behaviors and fear memory deficits were rescued following treatment with a benzodiazepine, clonazepam (Han et al., 2014). In an ASD mouse model with reduced GABAAR-mediated inhibition, the BTBR T+tf/J mouse, the α2,3 and 5 PAM L-838,417, improved deficits in social interaction, repetitive behaviors, and spatial learning (Han et al., 2014).

 

Postweaning positive modulation of α5GABAA receptors improves autism‐like features in prenatal valproate rat model in a sex‐specific manner 

Autism spectrum disorder (ASD), as a common neurodevelopmental disorder that encompasses impairments in social communication and interaction, as well as repetitive and restrictive behavior, still awaits an effective treatment strategy. The involvement of GABAergic neurotransmission, and especially a deficit of GABA A receptors that contain the α5 subunits, were implicated in pathogenesis of ASD. Therefore, we tested MP‐III‐022, a positive allosteric modulator (PAM) selective for α5GABAA receptors, in Wistar rats prenatally exposed to valproic acid, as an animal model useful for studying ASD. Postweaning rats of both sexes were treated for 7 days with vehicle or MP‐III‐022 at two doses pharmacokinetically determined as selective, and thereafter tested in a behavioral battery (social interaction test, elevated plus maze, spontaneous locomotor activity, and standard and reverse Morris water maze). Additional rats were used for establishing a primary neuronal culture and performing calcium imaging, and determination of hippocampal mRNA levels of GABRA5, NKCC1, and KCC2. MP‐III‐022 prevented impairments in many parameters connected with social, repetitive and restrictive behavioral domains. The lower and higher dose was more effective in males and females, respectively. Intriguingly, MP‐III‐022 elicited certain changes in control animals similar to those manifested in valproate animals themselves. Behavioral results were mirrored in GABA switch and spontaneous neuronal activity, assessed with calcium imaging, and also in expression changes of three genes analyzed. Our data support a role of α5GABAA receptors in pathophysiology of ASD, and suggest a potential application of selective PAMs in its treatment, that needs to be researched in a sex‐specific manner. Lay Summary In rats prenatally exposed to valproate as a model of autism, a modulator of α5GABAA receptors ameliorated social, repetitive and restrictive impairments, and, intriguingly, elicited certain autism‐like changes in control rats. Behavioral results were mirrored in GABA switch and spontaneous neuronal activity, and partly in gene expression changes. This shows a role of α5GABAA receptors in pathophysiology of ASD, and a potential application of their selective modulators in its treatment.

 

Note the researchers actually know about the GABA switch and so measured mRNA levels of NKCC1 and KCC2.

Note also that the lower dose of MP‐III‐022 was more effective in males and the higher dose in females.

We even have the recent associated PhD thesis from Anja Santrač:-

 

The influence of positive modulation of GABAA receptors containing the alpha5 subunit on behavioral changes of mice and rats in models of autistic disorders

The role of α5 GABAA receptors in learning and memory is well known. Therefore, we decided to examine the effect of the selective positive allosteric modulator (PAM) MP-III-022 on learning and memory of healthy animals, as well as GABRA5 expression. After demonstrating the needed tolerability and potential procognitive effects, the ligand would be used in an animal model of autism spectrum disorders (ASD). ASD is a neurodevelopmental disorder that encompasses impairments in social communication and interaction, as well as repetitive and restrictive behavior, still without an effective treatment. In this context, animal models that imitate specific disease’s symptoms are an excellent tool of translational research. Some of the most frequently used models are BTBR T+ tf/J mouse strain (BTBR) and valproate prenatal model (VPA). Our experiments have shown that the variability of α5GABAA receptors’ roles depends on its level of expression and localization, on the type and protocol of cognitive tasks, the timing of testing and intensity of pharmacological modulation. Obtained results proved potential beneficial effects of MP-III-022 in cognitive tasks. The BTBR model failed to express sufficient face validity, while VPA demonstrated adequate face validity and in part construct validity. Thus, we decided to subacutely apply MP-III-022 to juvenile VPA rats. In control animals, treatment led to GABRA5 decrease and to impairments similar to ones seen in ASD, suggesting the possible role of this receptor in the pathogenesis of the disease. Most importantly, our results demonstrated the potential of α5 GABAA receptor PAMs in secondary prevention and treatment of ASD, with the caveat that the drug development program would require adaptations tailored to sex-specific differences revealed.

 

Good job Anja. For our Serbian speaking readers, here is the link to her thesis:-

https://nardus.mpn.gov.rs/bitstream/handle/123456789/21424/Disertacija_13513.pdf?sequence=1&isAllowed=y

Perhaps we should connect her with Professor Ben-Ari?

  

Conclusion

Fine tuning alpha 5 subunits of GABAA receptors really should be followed up.  I think you need both options - a little bit more and a little bit less. It did not work for Roche in Down syndrome, but the potential remains.

Kv3.1 is another focused target for research, that very likely will become actionable. 

Transcranial pulse stimulation, like all the other zapping therapies, looks interesting, but it needs to be packaged in way that can actually be implemented every day at home.

In the meantime, at least getting your kid to wash the car is something we can all do.







Monday, 4 September 2023

The therapeutic effects of apigenin are pleiotropic. Is its effect on sound sensitivity mediated via potassium channels?

Chamomile, a good source of Apigenin

 

Today we return to flavonoids, those healthy chemicals found in fruits, vegetables, flowers etc.

In particular, the focus is on apigenin, found in things like chamomile, parsley, oregano and in medicinal herbs like Bacopa monnieri.

 

Why the interest in Apigenin?

I did discover a while back that sound sensitivity in some autism responds almost immediately to low dose Ponstan (Mefenamic acid), which is a widely used as a pain reliever.

I was recently informed by a reader who responds well to Ponstan (250mg once a day) that he gets exactly the same relief from sound sensitivity from taking the flavonoid Apigenin (500mg a day). 

Both Ponstan and Apigenin are OTC in many countries. In countries like Greece Ponstan is extremely cheap.  In the US Ponstan is very expensive and supplements tend to be cheap. 

For adults with sound sensitivity drinking chamomile tea might be a good source of 50 mg of Apigenin (you would need about 20g of chamomile flowers). Using the dried flowers likely gives better results than ready-made tea bags.

 

Pleiotropic effects

Both Ponstan and apigenin have numerous beneficial effects.  I noted in my earlier posts on Ponstan that it seems to offer protection from Alzheimer’s. Perhaps surprisingly, people who take Ponstan are much less likely to develop Alzheimer’s. Nobody has studied apigenin in human Alzheimer’s, but in animal studies, apigenin has been shown to improve cognitive function, reduce amyloid plaques, and protect neurons from damage.

 

Other Flavonoids used in Autism

Dr Theoharides wrote a lot about flavonoids to treat autism and mast cell disorders.  His product Neuroprotek is a combination of three flavonoids: luteolin, quercetin, and rutin, which are found in plants such as celery, onions, and citrus fruits.

Epigallocatechin gallate (EGCG) is a flavonoid found in green tea. The Spanish like doing research on EGCG and they believe it has promise as an autism therapy. One of the effects is to modify the gut microbiome. EGCG has also been shown to accumulates in mitochondria making it an interesting therapeutic candidate for neurodegenerative diseases involving neuronal apoptosis triggered by mitochondrial oxidative stress. It has been studied in Down syndrome, Rett syndrome and some other models of autism.

 

A very detailed overview is available in the paper below:-

The Emerging Role of Flavonoids in Autism Spectrum Disorder: A Systematic Review

Although autism spectrum disorder (ASD) is a multifaceted neurodevelopmental syndrome, accumulating evidence indicates that oxidative stress and inflammation are common features of ASD. Flavonoids, one of the largest and best-investigated classes of plant-derived compounds, are known to exert antioxidant, anti-inflammatory, and neuroprotective effects. This review used a systematic search process to assess the available evidence on the effect of flavonoids on ASD. A comprehensive literature search was carried out in PubMed, Scopus, and Web of Science databases following the PRISMA guidelines. A total of 17 preclinical studies and 4 clinical investigations met our inclusion criteria and were included in the final review. Most findings from animal studies suggest that treatment with flavonoids improves oxidative stress parameters, reduces inflammatory mediators, and promotes pro-neurogenic effects. These studies also showed that flavonoids ameliorate the core symptoms of ASD, such as social deficits, repetitive behavior, learning and memory impairments, and motor coordination. However, there are no randomized placebo-controlled trials that support the clinical efficacy of flavonoids in ASD. We only found open-label studies and case reports/series, using only two flavonoids such as luteolin and quercetin. These preliminary clinical studies indicate that flavonoid administration may improve specific behavioral symptoms of ASD. Overall, this review is the first one to systematically report evidence for the putative beneficial effects of flavonoids on features of ASD. These promising preliminary results may provide the rationale for future randomized controlled trials aimed at confirming these outcomes.

 

It seems that the many flavonoids have numerous beneficial effects - this is why it is important to include them in your diet.

 

Sytrinol

Years ago, I wrote about Sytrinol, a dietary supplement that is made from citrus peel extract. It contains polymethoxylated flavones (PMFs), which are a type of flavonoid. It mainly contains nobiletin and tangeritin, flavones that are found in citrus fruits, such as lemons, oranges, and grapefruits. They have been shown to have a number of health benefits, including lowering cholesterol, reducing inflammation, and protecting cells from damage.

The idea was of interest because these flavones are known to activate PPAR-gamma, which seemed potentially beneficial in autism.  Readers did confirm Sytrinol provided a cognitive benefit, but it only lasts a few days and is then lost.

 

Sources of Apigenin

Apigenin is sold as a supplement.

Chamomile is one of the oldest, most widely used and well documented medicinal plants in the world and has been recommended for a variety of healing applications for centuries. Apigenin is thought to be one of the most potent substances found within it.

Bacopa monnieri is another rich source of flavonoids being a good source of luteolin and apigenin. An extract of Bacopa monnieri, a nootropic herb, has been used to evaluate its neuroprotective effect in a valproic acid (VPA) model of ASD. The results showed that B. monnieri extract may attenuate VPA-induced damage by restoring antioxidant enzymes and reducing inflammatory cytokines in the hippocampus and prefrontal cortex.

 

The biological effects of Apigenin

 What does the Google AI (artificial intelligence) program Bard have to say:-

 

Apigenin is a flavonoid that is found in a variety of plants, including chamomile, parsley, celery, and citrus fruits. It has several potential health benefits, including:

Antioxidant. Apigenin is an antioxidant, which means it can help protect cells from damage caused by free radicals. Free radicals are unstable molecules that can damage DNA, proteins, and other cellular structures.

Anti-inflammatory. Apigenin has anti-inflammatory properties, which can help reduce inflammation in the body. Inflammation is a contributing factor to many diseases, including heart disease, cancer, and arthritis.

Cancer prevention. Apigenin has been shown to have cancer-fighting properties in both animal and human studies. It may help prevent cancer by blocking the growth and spread of cancer cells.

Brain health. Apigenin may be beneficial for brain health. It has been shown to improve cognitive function in animal studies, and it may also help protect against Alzheimer's disease and other neurodegenerative diseases.

Heart health. Apigenin may help improve heart health. It has been shown to lower blood pressure and cholesterol levels, and it may also help protect against heart arrhythmias.

Hormone modulation. Apigenin may modulate the production of hormones, such as estrogen and testosterone. This could have benefits for women's health, such as reducing the risk of breast cancer and improving menopausal symptoms.

Immune health. Apigenin may boost the immune system. It has been shown to increase the production of white blood cells, which help fight infection.

Other benefits. Apigenin may also have other health benefits, such as relieving anxiety, promoting sleep, and strengthening bones.

When you push Bard a little bit you get more:


Apigenin and ion channels, Bard?

Apigenin is a flavonoid that has been shown to interact with a variety of ion channels in the body. These include:

Voltage-gated calcium channels. Apigenin has been shown to inhibit the activity of voltage-gated calcium channels, which are involved in the regulation of many cellular processes, including muscle contraction, cell growth, and cell death.

Transient receptor potential vanilloid 4 (TRPV4) channels. TRPV4 channels are activated by heat and inflammation, and they play a role in pain perception, thermoregulation, and inflammation. Apigenin has been shown to activate TRPV4 channels, which could have potential implications for the treatment of pain and inflammation.

Nicotinic acetylcholine receptors (nAChRs). nAChRs are ligand-gated ion channels that are activated by acetylcholine. They are involved in a variety of functions, including learning, memory, and muscle contraction. Apigenin has been shown to potentiate the activity of nAChRs, which could have potential implications for the treatment of Alzheimer's disease and other neurodegenerative diseases.

Potassium channels: Potassium channels are responsible for the efflux of potassium ions from cells. Apigenin has been shown to activate some types of potassium channels, which can have cardioprotective effects.

Gamma-aminobutyric acid (GABA)A receptors. GABAA receptors are ligand-gated ion channels that are activated by GABA. They are involved in the regulation of anxiety, sleep, and epilepsy. Apigenin has been shown to modulate the activity of GABAA receptors, which could have potential implications for the treatment of anxiety and epilepsy.

 

Which potassium channels, Bard? 

Apigenin has been shown to activate some types of potassium channels, including:

Small conductance calcium-activated potassium channels (SK channels): SK channels are activated by calcium ions and play a role in regulating cell excitability. Apigenin has been shown to activate SK channels in a number of cell types, including neurons, smooth muscle cells, and cardiac cells.

Large conductance calcium-activated potassium channels (BK channels): BK channels are also activated by calcium ions and play a role in regulating cell excitability and blood pressure. Apigenin has been shown to activate BK channels in some cell types, but the effects are less well-studied than the effects on SK channels.

Transient receptor potential vanilloid 4 (TRPV4) channels: TRPV4 channels are activated by a variety of stimuli, including heat, inflammation, and mechanical stress. Apigenin has been shown to activate TRPV4 channels in some cell types, but the effects are less well-studied than the effects on SK and BK channels.

 

The effect of mefenamic acid on potassium channels, Bard? 

Mefenamic acid has been shown to have effects on a variety of ion channels, including potassium channels.

In vitro studies have shown that mefenamic acid can activate certain types of potassium channels, such as small conductance calcium-activated potassium channels (SK channels) and large conductance calcium-activated potassium channels (BK channels). This activation of potassium channels can lead to a decrease in the excitability of cells, which can be beneficial in conditions where excessive cell excitability is a problem, such as epilepsy and arrhythmias.

 However, mefenamic acid can also inhibit certain types of potassium channels, such as ATP-sensitive potassium channels (KATP channels). This inhibition of KATP channels can lead to an increase in the excitability of cells, which can be harmful in conditions where excessive cell excitability is a problem, such as heart arrhythmias.

The effects of mefenamic acid on potassium channels are complex and depend on the type of channel, the concentration of mefenamic acid, and the cell type. More research is needed to fully understand the mechanisms by which mefenamic acid interacts with potassium channels and the implications for its potential therapeutic applications.

 

Apigenin in Down syndrome

 

Plant Compound Apigenin Reduces Cognitive Deficits in Mouse Model of Down Syndrome

Mice treated with apigenin had better memory and developmental milestone scores.

The plant compound apigenin improved the cognitive and memory deficits usually seen in a mouse model of Down syndrome, according to a study by researchers at the National Institutes of Health and other institutions.

Apigenin is found in chamomile flowers, parsley, celery, peppermint, and citrus fruits. The researchers fed the compound to pregnant mice carrying fetuses with Down syndrome characteristics and then to the animals after they were born and as they matured.

The findings raise the possibility that a treatment to lessen the cognitive deficits seen in Down syndrome could one day be offered to pregnant women whose fetuses have been diagnosed with Down syndrome through prenatal testing. The study appears in the American Journal of Human Genetics.

Down syndrome is a set of symptoms resulting from an extra copy or piece of chromosome 21. The intellectual and developmental disabilities accompanying the condition are believed to result from decreased brain growth caused by increased inflammation in the fetal brain.

Apigenin is not known to have any toxic effects, and previous studies have indicated that it is an antioxidant that reduces inflammation. Unlike many compounds, it is absorbed through the placenta and the blood brain barrier, the cellular layer that prevents potentially harmful substances from entering the brain.

Compared to mice with Down symptoms whose mothers were not fed apigenin, those exposed to the compound showed improvements in tests of developmental milestones and had improvements in spatial and olfactory memory. Tests of gene activity and protein levels showed the apigenin-treated mice had less inflammation and increased blood vessel and nervous system growth.

 

Apigenin as a Candidate Prenatal Treatment for Trisomy 21: Effects in Human Amniocytes and the Ts1Cje Mouse Model

Human fetuses with trisomy 21 (T21) have atypical brain development that is apparent sonographically in the second trimester. We hypothesize that by analyzing and integrating dysregulated gene expression and pathways common to humans with Down syndrome (DS) and mouse models we can discover novel targets for prenatal therapy. Here, we tested the safety and efficacy of apigenin, identified with this approach, in both human amniocytes from fetuses with T21 and in the Ts1Cje mouse model. In vitro, T21 cells cultured with apigenin had significantly reduced oxidative stress and improved antioxidant defense response. In vivo, apigenin treatment mixed with chow was administered prenatally to the dams and fed to the pups over their lifetimes. There was no significant increase in birth defects or pup deaths resulting from prenatal apigenin treatment. Apigenin significantly improved several developmental milestones and spatial olfactory memory in Ts1Cje neonates. In addition, we noted sex-specific effects on exploratory behavior and long-term hippocampal memory in adult mice, and males showed significantly more improvement than females. We demonstrated that the therapeutic effects of apigenin are pleiotropic, resulting in decreased oxidative stress, activation of pro-proliferative and pro-neurogenic genes (KI67, Nestin, Sox2, and PAX6), reduction of the pro-inflammatory cytokines INFG, IL1A, and IL12P70 through the inhibition of NFκB signaling, increase of the anti-inflammatory cytokines IL10 and IL12P40, and increased expression of the angiogenic and neurotrophic factors VEGFA and IL7. These studies provide proof of principle that apigenin has multiple therapeutic targets in preclinical models of DS.

 

Conclusion 

I am still delighted to have found a treatment for my son’s sound sensitivity, which got much more extreme almost overnight a couple of years ago.

I had already established long ago that he got short term sound sensitivity relief from taking a potassium supplement.  Some readers found a potassium supplement provided long term relief.

I thought that Ponstan might provide a good longer term solution and indeed it worked from the first pill.  This low dose therapy also works for other people with sound sensitivity, even one adult who has no autism.  The effective adult dose is 250 mg once a day.

Unlike other fenamate class drugs, like Diclofenac, Ponstan seems to be free from GI side effects at this low dose in most people.

Apigenin is an interesting alternative for those who do not tolerate Ponstan well, or who cannot access it.

A common link between what seems to improve sound sensitivity:

                    Oral potassium

                    Ponstan (Mefenamic acid)

                    Apigenin

is potassium ion channels. 

If you ask Google’s AI program Bard, he will tell you:

“It is possible that all 3 substances could affect the same potassium ion channel in some cell types, but this has not been definitively shown. More research is needed to fully understand the effects of these substances on potassium ion channels.”

Technically Bard is genderless, but he is a reflection of the programmers behind the software. In our house he is called Bart anyway.

Bart does make mistakes, contradicts himself in the same answer and he gives you different answers if you ask the same question more than once. He is also prone to mixing things up, just like humans do.