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Showing posts with label NO. Show all posts
Showing posts with label NO. Show all posts

Friday, 13 January 2023

Methylene Blue - used for over a century in Psychiatry, also handy for your fish tank



According to the packaging:-

Effective against a range of fungal and bacterial infections

•          Increases the oxygen-carrying capacity of fish

•          Can be used as an antiseptic directly onto wounds

•          For use in tropical and cold water aquariums

 

Our reader Dragos recently let us all know about his success with very low doses of Methylene Blue (MB).  I think this came as a surprise to many, but actually there is nothing new about using this old pigment as a therapy in psychiatry.  Much is known about its modes of action.

 

What is Methylene Blue?

In 1876, German chemist Heinrich Caro synthesized methylene blue (MB) for the first time in history.  It was used as a dye for textiles. Around the same time, it was found that MB is capable of staining cells by binding to their structures, in addition, sometimes inactivating bacteria. This discovery prepared the way for biological or medical studies related to MB. Numerous scientists applied it to a variety of animal and bacterial studies, importantly Paul Ehrlich introduced it to humans in 1891 as an anti-malarial agent.

I was interested to see why it is used in aquariums, in particular the reference to increases the oxygen-carrying capacity of fish.

Methemoglobinemia (MetHb) is a rare blood disorder that affects how red blood cells deliver oxygen throughout your body.

A common way to treat  MetHb  in humans is to reduce methemoglobin levels using  Methylene blue (MB). Another common treatment, not surprisingly, is to give oxygen.

If you want to increase oxygen levels in the fish in your aquarium you put MB in the water.

More oxygen in your blood would improve exercise endurance meaning you would delay the point at which your mitochondria become unable to keep producing ATP efficiently.

I did some investigation and there is indeed a trend towards people using methyl blue to improve their sporting performance. It is mocked in some newspapers because it makes your tongue turn blue. It makes for good pictures on Instagram.     


The effect will be similar to those long distance cyclists who take beetroot juice, but the mechanism is different.

Be aware that just like beetroot may dye what comes out of your body bright red, MB may give you a hint of blue.

  

Improved Mitochondrial Function

One of the known effects of Methylene Blue (MB) is on the mitochondria.

In numerous papers it has been discussed how MB improves brain mitochondrial respiration.

In neurological disorders such as Alzheimer’s disease, traumatic brain injury, depression, stroke, Parkinson’s disease and some autism, mitochondria contribute to the disorder through decreased energy production and excessive production of reactive oxygen species (ROS).

This subject does get rather complex but in short methylene blue is able to perform alternative electron transport, bypassing parts of the electron transport chain.

In autism terms this means that some people diagnosed with a lack of Complex 1, 2, 3 or 4 in their mitochondria, might want to pay particular attention to how Methylene Blue might be helpful.

Improved mitochondrial function is another reason why sportsmen might want to use MB to enhance their performance.

As we have seen with other enhancing drugs like the Russian Meldonium, the US Diamox and the new US super ketone products, the military do end up using these products.  If you see a picture of a navy seal with a blue tongue you will know where it came from!

 

Methylene Blue inhibits Monoamine Oxidase (MAO)

MAOIs act by inhibiting the activity of monoamine oxidase, thus preventing the breakdown of monoamine neurotransmitters and thereby increasing their availability. There are two types of monoamine oxidase, MAO-A and MAO-B. MAO-A preferentially deaminates serotonin, melatonin, epinephrine, and norepinephrine. MAO-B preferentially deaminates phenethylamine and certain other trace amines; in contrast, MAO-A preferentially deaminates other trace amines, like tyramine, whereas dopamine is equally deaminated by both types.

Methyl blue is a reversible selective MAO-A inhibitor and so has antidepressant properties (it gives you more feel good serotonin). This interesting drug has several other pharmacological actions, including inhibition of nitric oxidase synthase (NOS), and guanylate cyclase and so its antidepressant properties should not be solely ascribed to inhibition of MAO-A. 

Inhibition of neuronal nitric oxide synthase and soluble guanylate cyclase prevents depression-like behaviour in rats exposed to chronic unpredictable mild stress

Beyond treating depression MAOIs (Monoamine oxidase inhibitors) have been found to be effective in the treatment of panic disorder, social phobia, mixed anxiety disorder and depression, bulimia, and post-traumatic stress disorder, as well as borderline personality disorder, and Obsessive Compulsive Disorder (OCD).

MAOIs appear to be particularly effective in the management of bipolar depression.

Methylene blue treatment for residual symptoms of bipolar disorder: randomised crossover study

Background: Residual symptoms and cognitive impairment are among important sources of disability in patients with bipolar disorder. Methylene blue could improve such symptoms because of its potential neuroprotective effects.

Aims: We conducted a double-blind crossover study of a low dose (15 mg, 'placebo') and an active dose (195 mg) of methylene blue in patients with bipolar disorder treated with lamotrigine.

Method: Thirty-seven participants were enrolled in a 6-month trial (trial registration: NCT00214877). The outcome measures included severity of depression, mania and anxiety, and cognitive functioning.

Results: The active dose of methylene blue significantly improved symptoms of depression both on the Montgomery-Åsberg Depression Rating Scale and Hamilton Rating Scale for Depression (P = 0.02 and 0.05 in last-observation-carried-forward analysis). It also reduced the symptoms of anxiety measured by the Hamilton Rating Scale for Anxiety (P = 0.02). The symptoms of mania remained low and stable throughout the study. The effects of methylene blue on cognitive symptoms were not significant. The medication was well tolerated with transient and mild side-effects.

Conclusions: Methylene blue used as an adjunctive medication improved residual symptoms of depression and anxiety in patients with bipolar disorder.

 

Methylene Blue activates oxidative stress response genes via Nrf2

One of the antioxidant effects of MB is activation of the redox switch Nrf2.  In the paper below it is also mentioned that MB has a beneficial against tau proteins. Amyloid and tau proteins clog up the brain in Alzheimer’s and as a result MB has been proposed as a therapy for dementia. 


Methylene blue upregulates Nrf2/ARE genes and prevents tau-related neurotoxicity

Methylene blue (MB, methylthioninium chloride) is a phenothiazine that crosses the blood brain barrier and acts as a redox cycler. Among its beneficial properties are its abilities to act as an antioxidant, to reduce tau protein aggregation and to improve energy metabolism. These actions are of particular interest for the treatment of neurodegenerative diseases with tau protein aggregates known as tauopathies. The present study examined the effects of MB in the P301S mouse model of tauopathy. Both 4 mg/kg MB (low dose) and 40 mg/kg MB (high dose) were administered in the diet ad libitum from 1 to 10 months of age. We assessed behavior, tau pathology, oxidative damage, inflammation and numbers of mitochondria. MB improved the behavioral abnormalities and reduced tau pathology, inflammation and oxidative damage in the P301S mice. These beneficial effects were associated with increased expression of genes regulated by NF-E2-related factor 2 (Nrf2)/antioxidant response element (ARE), which play an important role in antioxidant defenses, preventing protein aggregation, and reducing inflammation. The activation of Nrf2/ARE genes is neuroprotective in other transgenic mouse models of neurodegenerative diseases and it appears to be an important mediator of the neuroprotective effects of MB in P301S mice. Moreover, we used Nrf2 knock out fibroblasts to show that the upregulation of Nrf2/ARE genes by MB is Nrf2 dependent and not due to secondary effects of the compound. These findings provide further evidence that MB has important neuroprotective effects that may be beneficial in the treatment of human neurodegenerative diseases with tau pathology.

 

MB to treat inflammation and pain via sodium ion channels and iNOS

MB abates inflammation by suppressing nitric oxide production, and ultimately relieves pain in arthritis and colitis.  

MB suppresses the iNOS/NO-mediated inflammatory signaling by directly downregulating inducible NO synthase (iNOS).

Nitric oxide (NO) is a free radical which, in reactions with various molecules causes multiple biological effects, some good and some harmful.

It is produced by a reaction involving one of three enzymes iNOS, eNOS and nNOS.  i = inducible, n = neuronal and e = endothelial

iNOS is a major downstream mediator of inflammation.

eNOS is very helpful because it can widen blood vessels and so reduce blood pressure and increase blood flow.

nNOS is found in the brain and the peripheral nerve system where it has several important functions.  

MB may impede pain transmission by dampening neuronal excitability elicited by voltage-gated sodium channels (VGSCs).  You would then think that in people with seizures due to malfunctioning sodium channels, MB might be beneficial; for example Nav1.1 in Dravet syndrome. 

Methylene Blue Application to Lessen Pain: Its Analgesic Effect and Mechanism

Methylene blue (MB) is a cationic thiazine dye, widely used as a biological stain and chemical indicator. Growing evidence have revealed that MB functions to restore abnormal vasodilation and notably it is implicated even in pain relief. Physicians began to inject MB into degenerated disks to relieve pain in patients with chronic discogenic low back pain (CDLBP), and some of them achieved remarkable outcomes. For osteoarthritis and colitis, MB abates inflammation by suppressing nitric oxide production, and ultimately relieves pain. However, despite this clinical efficacy, MB has not attracted much public attention in terms of pain relief. Accordingly, this review focuses on how MB lessens pain, noting three major actions of this dye: anti-inflammation, sodium current reduction, and denervation. Moreover, we showed controversies over the efficacy of MB on CDLBP and raised also toxicity issues to look into the limitation of MB application. This analysis is the first attempt to illustrate its analgesic effects, which may offer a novel insight into MB as a pain-relief dye. 


Nicotinic acetylcholine receptors

The modulation of nicotinic acetylcholine receptors (nAChRs) has been suggested to play a role in the pathogenesis of various neurodegenerative diseases. 

MB acts as a non-competitive antagonist on α7 nAChRs.

Well known drugs that act in a similar way include the Alzheimer’s drug Memantine and Ketamine. Recall that intranasal Ketamine has been used in autism. 

Substances  with the opposite effect include nicotine, choline and of course

Amyloid beta, the marker of Alzheimer's disease.

Note that some people need to block α7 nAChRs and some people need to activate them. 

Methylene blue inhibits the function of α7-nicotinic acetylcholine receptors


FDA Drug Safety Communication: Serious CNS reactions possible when methylene blue is given to patients taking certain psychiatric medications

A list of the serotonergic psychiatric medications that can interact with methylene blue can be found here. 

  • Methylene blue can interact with serotonergic psychiatric medications and cause serious CNS toxicity.
  • In emergency situations requiring life-threatening or urgent treatment with methylene blue (as described above), the availability of alternative interventions should be considered and the benefit of methylene blue treatment should be weighed against the risk of serotonin toxicity. If methylene blue must be administered to a patient receiving a serotonergic drug, the serotonergic drug must be immediately stopped, and the patient should be closely monitored for emergent symptoms of CNS toxicity for two weeks (five weeks if fluoxetine [Prozac] was taken), or until 24 hours after the last dose of methylene blue, whichever comes first.
  • In non-emergency situations when non-urgent treatment with methylene blue is contemplated and planned, the serotonergic psychiatric medication should be stopped to allow its activity in the brain to dissipate. Most serotonergic psychiatric drugs should be stopped at least 2 weeks in advance of methylene blue treatment. Fluoxetine (Prozac), which has a longer half-life compared to similar drugs, should be stopped at least 5 weeks in advance.
  • Treatment with the serotonergic psychiatric medication may be resumed 24 hours after the last dose of methylene blue.
  • Serotonergic psychiatric medications should not be started in a patient receiving methylene blue. Wait until 24 hours after the last dose of methylene blue before starting the antidepressant.
  • Educate your patients to recognize the symptoms of serotonin toxicity or CNS toxicity and advise them to contact a healthcare professional immediately if they experience any symptoms while taking serotonergic psychiatric medications or methylene blue.



Conclusion 

Rather surprisingly, this therapy from the fish tank may have wide ranging effects on the autistic brain and in those with dementia, bipolar etc.

Possible benefits might include:

·        Improved production of ATP (energy) in the brain

·        Reduced oxidative stress in the brain

·        Reduced nitrosative stress

·        Reduced inflammation

·        Improved mood (due to increased serotonin)

·        Improved memory and cognitive function

·        Reduction in obsessive behaviors

In one of the papers, they comment that “methylene blue modulates functional connectivity in the human brain”.

It seems to work for Dragos.  You can also see that people on Reddit use it for issues like ADHD. 

 

Note the FDA warning:

Do not combine Methylene Blue with serotonergic psychiatric medications, because of the risk of serotonin syndrome (i.e., serotonin toxicity).



Thursday, 19 October 2017

Unstable Blood Flow in Autistic Brains?





Today’s post is complicated, but may be of interest to those people interested in Nitric Oxide therapies (Agmatine, Cocoa Flavanols, Beetroot, Taurine, Citrulline etc) and those who think they are treating earlier hypoxia/ischemia.
As usual, I am making simplifications, but the science behind the general ideas already exists. When it comes to the details regarding VEGF and autism, there are big gaps in the science. 
We have already seen that something as simple as improving blood flow appears to be therapeutic in some people with autism. Perhaps there should even be a post called “cold feet and autism”. 
One reader of this blog, Seth, has commented before that he sees autism as essentially vascular in nature.  Today’s research suggests it does indeed include microvascular abnormalities.
Rather than simply reduced blood flow, the problem, in at least some autism, appears to be unstable blood flow, which is much more complex.
I do take a leap in logic to suggest that this is likely linked to the known abnormalities in Vascular Endothelial Growth Factor (VEGF) and in VEGF receptor 1 (VEGFR-1).  It also appears that the VEGF anomalies that lead to angiogenesis may be part of the reason for the increased prevalence of chronic inflammatory diseases including asthma, atopic dermatitis, psoriasis, and rheumatoid arthritis.
Ideally you might want to normalize VEGF, even later in life. The use of anti-angiogenic drugs has been suggested.  Angiogenesis inhibitors were once seen as potential wonder drugs to treat cancer.
It does seem that just simply targeting vascular resistance is helpful for some people with autism.   
VEGF is regulated by many things, some are highly complex and are usually studied with regard to cancer, like Wnt signaling and Ras. Recall that both Wnt and Ras are relevant to autism. One simple thing that influences VEGF is nitric oxide (NO), but it is not a simple relationship. As highlighted by our reader Tyler, intermittent fasting (IF) can also be used to increase VEGF. Research suggests that intermittent fasting (IF) is actually a simple but potent tool to both prevent and treat metabolic disorders, including but not limited to type 2 diabetes.


In the case of autism, where both VEGF and NO are likely to be low, it does seem quite likely that by increasing the production of NO you will increase the expression of VEGF. So the amino acid L-citrulline is likely to increase VEGF.
In the rat study below, L-citrulline increased eNOS and VEGF; we presume NO also increased. 


Blood Flow in Autistic Brains
Now we get to the autism-specific research.


A team of scientists has found evidence that people with autism have unstable vessels in the brain which prevents the proper delivery of blood flow, according to research published in the Journal of Autism and Developmental Disorders
“In a typical brain, blood vessels are stable, thereby ensuring a stable distribution of blood,” said Patricia Whitaker-Azmitia, PhD, professor in the Department of Psychology and director of the Graduate Program in Integrative Neurosciences at Stony Brook University, N.Y.,  in a statement. “Whereas in the autism brain, the cellular structure of blood vessels continually fluctuates, which results in circulation that is fluctuating and, ultimately, neurologically limiting.”



Sustained angiogenesis may contribute to prolonged neuroplasticity in the ASD brain. We propose the sustained splitting angiogenesis is a necessary component to maintain the heightened neuronal activity reported in ASD patients. Many biological and functional indicators are increased in ASD including cerebral metabolic rate, regional synchronous electrical activity sensitivity to sound; cortical activity in deactivation centers at rest, low-level visuospatial processing, visual-tactile interactions; attention to low-level perceptual information and over-connected, redundant cortical networks. It can be suggested that sustained rearrangement of microvasculature permits excessive shorter and local connections to be maintained and prevents the growth of longer and more complex brain connections required for language and social interactions. Use of anti-angiogenic drugs may provide a novel treatment strategy for reducing neuronal activity in ASD patients by inhibiting vascular plasticity.








Brain tissue from children (left) and adults (right) with autism (top) but not controls (bottom) shows dividing cells lining blood vessels.


Angiogenesis and Lymphangiogenesis
It looks like, at least in today’s subgroup of autism, we want less angiogenesis but more lymphangiogenesis.  The ideal way to do this is via VEGF/VEGFRs.
Here it may be helpful to explain the meaning of some new terminology.

Angiogenesis is the physiological process through which new blood vessels form from pre-existing vessels
Angiogenesis is a normal and vital process in growth and development, as well as in wound healing and in the formation of granulation tissue. However, it is also a fundamental step in the transition of tumors from a benign state to a malignant one, leading to the use of angiogenesis inhibitors in the treatment of cancer.”
Lymphangiogenesis is the formation of lymphatic vessels from pre-existing lymphatic vessels in a method believed to be similar to angiogenesis (blood vessel development).

Lymphangiogenesis plays an important physiological role in homeostasis, metabolism and immunity. Impaired or excessive lymphatic vessel formation has been implicated in a number of pathological conditions including neoplasm metastasis, oedema, rheumatoid arthritis, psoriasis, lymphangiomatosis and impaired wound healing.”


Lymphatic system and the Brain 
As highlighted recently by our reader Tanya, a pretty basic gap in science’s understanding of how the brain works has just been addressed. It is all about where do the waste products produced in the brain go to.
Scientists have found evidence that the brain is connected to body’s central lymphatic system.
This then begs the question of what happens when this system does not work well. Is this a feature of some neurological disease? If that were the case, it would likely be associated with reduced lymphangiogenesis.

Running through your body is a network of channels and junctions called the lymphatic system, which siphons off waste and fluids like a biological sewer.
It was long thought the brain was excluded from this web of anatomical plumbing. After being spotted in mice brains two years ago, researchers have now confirmed the presence of lymphatic vessels in human brains, fueling speculation over the kinds of diseases they might be responsible for.




VEGF and VEGF receptors 
There are four types of VEGF and they act through three types of receptors. Confusingly, the receptors have been given multiple names.


In severe autism there is reduced VEGF, but we do not know which type(s) but there is increased expression of the receptor  VEGFR-1 also known as Flt-1. VEGFR-2 expression is normal, this is the best understood receptor.

This receptor VEGFR-1 is activated by VEGF-A and VEGF-B.  

Objective:

To study vascular endothelial growth factor (VEGF) and its soluble receptors sVEGFR-1 and -2 in autism.

Design and methods:

We measured serum levels of angiogenic molecules in 22 patients with severe autism and 28 controls.

Results:

Patients and controls had similar sVEGFR-2 levels, but VEGF levels were lower and sVEGFR-1 higher in patients with autism.

Conclusion:

The imbalance between VEGF and its receptor sVEGFR-1 may be involved in the pathophysiology of autism.


Hypoxia related autism 
It is well known that hypoxia-ischemia insults early in life can cause cognitive dysfunction and likely autism.  In the very recent paper below, it is suggested that altered VEGF signaling is the mechanism that causes the damage to the brain. 

Neurovascular dysfunction and the role of vascular endothelial growth factor (VEGF) have been explored in neurodevelopmental disorders including schizophrenia, bipolar disorder, major depressive and mood disorders, and autism. These disorders are correlated with hypoxia-ischemia insults during early life and are strongly associated with cognitive dysfunction. This review focuses on the hypoxia-regulated protein, VEGF, to discuss its crucial roles in brain development and function. These data implicate that alterations to VEGF signaling during early life can impair neural development, underlying the severe cognitive deficits observed in neurodevelopmental disorders.
Recent Findings
VEGF has been linked to neurological processes that influence learning and memory. VEGF is advancing towards being a novel biomarker and possible therapeutic for neurological disorders. Prenatal environmental enrichment positively impacted neurotrophic factors, brain structure, and memory in rodent models.
Summary
Understanding the molecular mechanisms of VEGF in neurodevelopment will create intervention strategies for at-risk children born to adverse early-life events. By proactively working with those in a pliable neurodevelopmental state, we hope to ameliorate cognitive deficits to increase their chance to develop into high-functioning adults with disabilities. 

Hypoxia-Induced Angiogenesis - Good and Evil


Hypoxia promotes vessel growth by upregulating multiple pro-angiogenic pathways that mediate key aspects of endothelial, stromal, and vascular support cell biology. Interestingly, recent studies show that hypoxia influences additional aspects of angiogenesis, including vessel patterning, maturation, and function.
VEGF, considered a master regulator of angiogenesis in its own right, causes endothelial cells to detach from the parent vessel and migrate into the neighboring stroma. Hypoxia is the principal regulator of VEGF expression, as it is a direct transcriptional target of both HIF-1α and HIF-2α.



Allergy and inflammation resulting from angiogenesis 
It appears that in some people another consequence of too much angiogenesis is allergy and other inflammatory disease; these are of course often comorbid with autism.  This suggests anti-angiogenic and pro-lymphangiogenic therapies.


Angiogenesis and lymphangiogenesis, the growth of new vessels from preexisting ones, have received increasing interest due to their role in tumor growth and metastatic spread. However, vascular remodeling, associated with vascular hyperpermeability, is also a key feature of many chronic inflammatory diseases including asthma, atopic dermatitis, psoriasis, and rheumatoid arthritis. The major drivers of angiogenesis and lymphangiogenesis are vascular endothelial growth factor- (VEGF-)A and VEGF-C, activating specific VEGF receptors on the lymphatic and blood vascular endothelium. Recent experimental studies found potent anti-inflammatory responses after targeted inhibition of activated blood vessels in models of chronic inflammatory diseases. Importantly, our recent results indicate that specific activation of lymphatic vessels reduces both acute and chronic skin inflammation. Thus, antiangiogenic and prolymphangiogenic therapies might represent a new approach to treat chronic inflammatory disorders, including those due to chronic allergic inflammation.



Figure 1: VEGF-binding properties and distinct VEGF receptor expression on lymphatic and blood vascular endothelium. VEGFs bind to the three VEGF receptor tyrosine kinases, leading to the formation of VEGFR dimers. Blood vascular endothelial cells express VEGFR-1 and VEGFR-2, whereas lymphatic endothelial cells express VEGFR-2 and VEGFR-3. VEGF-A—which binds both VEGFR-1 and VEGFR-2—can directly induce blood and lymphatic vascular remodeling. VEGF-C and -D bind VEGFR-3 and, after proteolytic processing, also VEGFR-2, thus inducing angiogenesis and lymphangiogenesis.


There is clear evidence that in humans, vascular remodeling occurs in many chronic inflammatory disorders. Even though different anti-inflammatory drugs are on the market, there is no specific therapy that interferes with the pathological vascular changes that occur during inflammation. Angiogenesis and lymphangiogenesis are tightly linked to chronic inflammation, and targeting the blood vessels and lymphatic vessels has been shown to be an effective strategy in different experimental mouse models of chronic inflammation. One has to keep in mind, however, that in most conditions the vascular activation likely represents a downstream event that maintains the inflammatory process, but not the pathogenetic cause of the respective disease, which often has remained unknown. Nonetheless, antiangiogenic and prolymphangiogenic therapies might represent new approaches to treat chronic inflammatory disorders, including those due to chronic allergic inflammation.


Conclusion
I did start this post by saying this subject is complicated.
From the previous post on nitric oxide, it looked like L-citrulline, L-norvaline, Agmatine and other NO increasing substances could be therapeutic. Cold hands and feet seem to be very common in autism.
It seems likely that the NO increasing therapies will likely also increase VEGF, which I think is a good thing.
From today’s post we see that rather than just a single VEGF we have five broad types (A,B,C, D and PIGF), but even just VEGF-A has various different forms. We do not have detailed research on autism and specific subtypes of VEGF. 
We have the four different VEGF receptors and we know VEGFR-1 is over expressed. We do not have a clever way to counter this. More VEGFR-3 expression would be helpful and that is again a case of changing the balance between inflammatory cytokines, which as we know is usually disturbed in autism.
The inflammatory cytokine IL-6 induces VEGF-C production which leads to both angiogenesis and lymphangiogenesis; this is why people with cancer and high IL-6 may have a poor prognosis.
Regarding VEGF and autism we clearly lack 95% of the science. Strange things are afoot and we are just guessing.
For the time being, I see increasing vascular permeability via eNOS as therapeutic, even though today’s post suggests that antiangiogenic therapies could be helpful, which may seem contradictory.
The kind of drugs that would reduce the activity of VEGFR-1/Flt-1 would be very expensive cancer drugs.  Hypoxia also downregulates VEGFR-1/Flt-1.
Inflammatory cytokines regulate VEGFR-3/Flt-4 and hence control of lymphangiogenesis.  Interferon gamma (IFNγ) upregulates VEGFR-3/Flt-4, while Interleukin 1 beta (IL1β) down regulates it. 
So more IFNγ and less IL1β might help.
Although expensive, interferon gamma (IFNγ) has been shown to be effective in treating severe atopic dermatitis. This would make sense since it induces lymphangiogenesis and the research suggests this should improve inflammatory disease.


CONCLUSIONS:


We conclude that rIFN-gamma appears to be a safe long-term therapy for patients with severe atopic dermatitis.



So perhaps interferon-gamma (IFNγ) for some autism? Quite possibly, just look for the ones with asthma, atopic dermatitis, psoriasis or juvenile arthritis.