Methylene Blue

An Alternative and a Paradox.

This one is going to annoy people, because it ends on a confusing note.

There has been a lot of talk recently about Methylene Blue, including from people I respect and trust (Levy, Yoho etc.) about its benefits as an alternative therapeutic. That is going to be the primary basis of this article as I will summarize and synthesize that material.

But we will end on an important, but confusing note, about its manufacturing.

Let’s start with the good stuff first.

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Let’s first start off with its similarities to HCQ-hydroxychloroquine and come up to speed with how it works.

Methylene blue and hydroxychloroquine share some similarities in their applications, particularly in the treatment of malaria and certain autoimmune diseases. Both compounds have a history of being used as antimalarial drugs, though their mechanisms of action differ.

Biochemical Mechanism of Action:

• Methylene blue works by interfering with the malaria parasite's ability to metabolize and reproduce. It targets the parasite's redox system, which is crucial for its survival and proliferation.

• Hydroxychloroquine, derived from quinine, operates differently. It raises the pH in parts of the parasite’s cell, which inhibits its ability to process hemoglobin. This disrupts the life cycle of the parasite.

Analogy for Methylene Blue

Imagine the malaria parasite as a burglar trying to enter and rob a house (the red blood cell). Methylene blue acts like a security system that interferes with the burglar’s tools (the redox system of the parasite). Just as a burglar might use specific tools to break into a house, the malaria parasite uses its redox system to survive and grow inside the red blood cell. Methylene blue effectively disables these tools, preventing the burglar (parasite) from carrying out its plan.

Analogy for Hydroxychloroquine

In contrast, hydroxychloroquine works more like changing the locks on the doors of the house (altering the pH inside the parasite's cell). The burglar (malaria parasite) might still get in, but finds it impossible to open any doors inside the house, preventing it from accessing valuables (hemoglobin in red blood cells). This inhibits the parasite's ability to survive and reproduce within the blood cell.

Both drugs, through different mechanisms, make the environment hostile for the malaria parasite, thus preventing its growth and spread.

Mark Sloan has written a very good book on the subject. Here I have created a short book summary of his book.

The Ultimate Guide To Methylene Blue Short Book Summary Lies Are Unbekoming

175KB ∙ PDF file

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Next let’s go through a comprehensive Q&A sourced from this source material¹ of 5 articles, 2 podcasts and a book.

30 Questions and Answers

1. What is Methylene Blue and what was its original purpose? Methylene Blue, chemically known as methylthioninium chloride, was initially synthesized in 1876 as an industrial dye. Its primary use was for staining fabrics, particularly cotton, in a vibrant blue hue. This synthetic compound marked a significant advancement in the textile industry, allowing for more vivid and lasting coloration of materials.

2. How was Methylene Blue first used in medicine? In the realm of medicine, Methylene Blue found its first significant application in the late 19th century. It was utilized for staining bacteria and human tissues, making them more visible under a microscope. This feature was pivotal for scientific research, aiding in the understanding of cellular structures and microbial organisms. Methylene Blue's transition from a textile dye to a tool in medical microscopy was a noteworthy leap, illustrating the versatility of this compound.

3. How does methylene blue's history as a textile dye relate to its modern medical applications? Methylene blue's journey from a textile dye to a medically significant compound is a testament to the evolving understanding of chemistry and its applications. Initially synthesized in 1876 for the textile industry, its intrinsic properties, such as its ability to bind to biological tissues, soon caught the attention of the medical community. This transition illustrates how substances developed for one purpose can find unexpected utility in entirely different fields, especially when their fundamental characteristics align with biological processes. Methylene blue's staining capability, crucial in textiles, became invaluable in microscopy for cell visualization, leading to its subsequent discovery as a therapeutic agent.

4. In what ways does methylene blue differ from other antimalarial drugs like quinine? Methylene blue and quinine, both used as antimalarial drugs, differ in their mode of action and chemical structure. Quinine, derived from the bark of the cinchona tree, works by inhibiting the replication of the malaria parasite within red blood cells. Methylene blue, on the other hand, has a unique mechanism that involves interrupting the metabolic processes of the parasite, making it particularly effective against strains resistant to other treatments. Additionally, methylene blue's role as an electron transfer agent in the mitochondria presents a different approach to combating malaria compared to quinine's more direct interference with the parasite's life cycle.

5. Can methylene blue be used as a preventive measure against certain diseases? While the primary use of methylene blue is therapeutic, its properties suggest potential as a preventive measure, especially in diseases related to oxidative stress and mitochondrial dysfunction. Its ability to efficiently donate and accept electrons could help maintain cellular health and prevent the onset of diseases where oxidative damage is a key factor. However, the use of methylene blue as a preventive treatment would require thorough research to establish its efficacy and safety in long-term, low-dose applications.

6. What are the neurological applications of Methylene Blue? Methylene Blue has demonstrated a special affinity for the nervous system. Historically, it was used as an antipsychotic medication for about 50 years from the late 19th century. Its effectiveness in treating depression, memory problems, and other neurological conditions has been noted. Due to its ability to cross the blood-brain barrier efficiently and its antioxidant properties, Methylene Blue is being explored for potential therapeutic use in neurodegenerative diseases like Alzheimer's and Parkinson’s.

7. Can Methylene Blue be used as an antidote for certain types of poisoning? Remarkably, Methylene Blue serves as an antidote for certain poisonings. It is an effective treatment for cyanide poisoning and has shown promise in protecting against brain damage following carbon monoxide poisoning. Its role as an antidote is attributed to its ability to interact with specific metabolic and chemical pathways that are disrupted during poisoning.

8. How does Methylene Blue function in treating infections and conditions like ARDS? Methylene Blue's role in treating infections, including life-threatening ones like septic shock, is significant. Its antimicrobial properties make it effective against various pathogens. In the case of Acute Respiratory Distress Syndrome (ARDS) and hypoxemia caused by COVID-19, Methylene Blue helps by improving oxygenation and mitigating the impact of the infection on the lungs. It stabilizes mitochondrial function, essential for cellular energy production, which is critical in fighting infections.

9. What is methemoglobinemia and how does Methylene Blue treat it? Methemoglobinemia is a condition where the oxygen-carrying capacity of the blood is compromised due to the conversion of normal hemoglobin into methemoglobin. In this state, hemoglobin cannot effectively release oxygen to body tissues. Methylene Blue is used as a first-line treatment for methemoglobinemia. It works by reducing methemoglobin back to hemoglobin, thus restoring the blood's capacity to carry and release oxygen.

10. How does Methylene Blue act as an antioxidant? As an antioxidant, Methylene Blue functions by donating and accepting electrons. This ability allows it to neutralize reactive oxygen species (free radicals), which are harmful byproducts of cellular metabolism that can cause oxidative stress and damage cells. Methylene Blue's antioxidant property is central to its therapeutic applications, as it helps in reducing cellular damage and promoting healing.

11. What makes Methylene Blue effective in enhancing metabolism and facilitating healing? Methylene Blue's effectiveness in enhancing metabolism and facilitating healing stems from its ability to optimize mitochondrial function. Mitochondria are the powerhouses of cells, and Methylene Blue helps them produce energy more efficiently, with less production of harmful byproducts. This increased metabolic efficiency aids in healing processes and improves overall cellular function.

12. What are the implications of methylene blue's ability to bypass problems in the electron transport chain? Methylene blue's ability to act as an alternative electron carrier in the mitochondrial electron transport chain has significant therapeutic implications. In conditions where the electron transport chain is compromised, methylene blue can facilitate the continuation of ATP production, essential for cellular energy. This property is particularly beneficial in treating conditions marked by mitochondrial dysfunction, such as certain neurodegenerative diseases, where it helps to sustain cellular function despite underlying mitochondrial issues.

13. How does methylene blue's antioxidant property contribute to its therapeutic effects? The antioxidant property of methylene blue plays a crucial role in its therapeutic effects. By neutralizing reactive oxygen species (ROS) and reducing oxidative stress, methylene blue helps protect cells from damage that can lead to various pathological conditions. This action is particularly beneficial in diseases where oxidative stress is a significant contributor, such as neurodegenerative disorders, certain cardiovascular diseases, and conditions arising from toxin exposure.

14. What makes methylene blue an effective treatment for viral infections, particularly COVID-19? Methylene blue's effectiveness against viral infections, including COVID-19, stems from its ability to disrupt viral replication and its potent antiviral properties. For COVID-19 specifically, methylene blue has been shown to interfere with the virus's ability to bind to host cells and replicate. This, coupled with its immunomodulatory effects and potential to mitigate the cytokine storm associated with severe COVID-19 cases, makes it a promising candidate for treatment.

15. What is the safety profile of Methylene Blue based on its clinical use? Methylene Blue has been used clinically for over a century and has an excellent safety profile. The main side effect is a temporary blue discoloration of urine and rarely, skin. It is generally well-tolerated, and adverse reactions are uncommon when used within the recommended dosages. However, caution is advised when used with certain medications, like SSRIs, due to potential interactions.

16. How does Methylene Blue interact with the nervous system? Methylene Blue's interaction with the nervous system is significant due to its ability to penetrate the blood-brain barrier effectively. This trait, combined with its antioxidant properties, makes it a promising candidate for treating various neurological disorders. It targets dysfunctional mitochondria in nerve cells, which can lead to improved neuronal function and potentially slow down neurodegenerative processes.

17. Can Methylene Blue be considered effective in treating drug-resistant malaria? Methylene Blue was one of the first antimalarial drugs used in medicine and is re-emerging as a treatment for drug-resistant malaria. Its ability to kill the malaria-causing parasite Plasmodium falciparum, including drug-resistant strains, makes it a valuable tool in the fight against this disease.

18. How does Methylene Blue protect against brain damage from carbon monoxide poisoning? Methylene Blue protects against brain damage from carbon monoxide poisoning by improving the efficiency of mitochondrial respiration. Carbon monoxide disrupts the body's oxygen use, and Methylene Blue helps to counteract this by ensuring that cells can still produce energy effectively, even in reduced oxygen conditions. This mechanism helps to minimize the potential brain damage that can occur from carbon monoxide poisoning.

19. What role does Methylene Blue play in the treatment of septic shock? In the treatment of septic shock, Methylene Blue functions by stabilizing blood pressure and improving oxygenation. Septic shock is characterized by a drop in blood pressure and severe infection, often leading to organ failure. Methylene Blue's ability to improve mitochondrial function plays a crucial role in enhancing the body's response to infection and stabilizing the patient's condition.

20. What is oxidative stress and how does Methylene Blue help manage it? Oxidative stress occurs when there is an imbalance between the production of free radicals and the body's ability to neutralize them with antioxidants. This imbalance can lead to cellular damage, inflammation, and various diseases. Methylene Blue helps manage oxidative stress by functioning as a potent antioxidant, neutralizing harmful free radicals, and protecting cells from damage.

21. How does the molecular structure of Methylene Blue influence its effectiveness? The molecular structure of Methylene Blue, which allows it to be both fat- and water-soluble, is crucial for its effectiveness. This dual solubility enables Methylene Blue to easily penetrate cell membranes and disperse throughout the cellular environment. Its small size also facilitates its widespread distribution in the body, allowing it to reach and act on various tissues, including the brain.

22. Are there any contraindications or cautionary notes for using Methylene Blue? While Methylene Blue is generally safe, there are contraindications and cautionary notes for its use. It should be used cautiously in individuals taking SSRIs due to the potential risk of serotonin syndrome. High doses can lead to the formation of methemoglobin, and extreme doses may cause additional side effects. It is also important to ensure the use of pharmaceutical-grade Methylene Blue to avoid contaminants.

23. How has Methylene Blue been used in the context of COVID-19? Methylene Blue has been used in the treatment of COVID-19, particularly in managing severe cases that progress to ARDS and septic shock. Its antioxidant properties and ability to improve mitochondrial function have made it beneficial in stabilizing patients with severe respiratory distress and hypoxemia caused by the virus. Additionally, Methylene Blue has been shown to have direct antiviral effects against SARS-CoV-2, the virus that causes COVID-19.

24. What are the implications of Methylene Blue's use in neurodegenerative diseases? The implications of Methylene Blue's use in neurodegenerative diseases are significant. Due to its neuroprotective properties and ability to enhance mitochondrial function, Methylene Blue shows promise in treating conditions like Alzheimer's and Parkinson's disease. By improving cellular energy production and reducing oxidative stress in the brain, it could potentially slow the progression of these diseases.

25. How does the concept of orthomolecular medicine relate to the use of Methylene Blue? Orthomolecular medicine, as described by Linus Pauling, focuses on restoring natural substances in the body to prevent or treat medical conditions. While Methylene Blue is not produced naturally in the body, its actions closely align with orthomolecular principles. It restores efficient cellular function and redox balance, much like how essential nutrients do, providing substantial health benefits despite being a synthetic substance.

26. What are the limitations or challenges in the current research on methylene blue? Current research on methylene blue faces several limitations. One of the primary challenges is the lack of large-scale, randomized clinical trials that would provide robust data on its efficacy and safety across various conditions. Additionally, there is a need for more in-depth understanding of its mechanisms of action, especially in complex diseases. Another challenge is overcoming the perception of methylene blue as merely a dye or laboratory tool, rather than a serious therapeutic agent, which can hinder research funding and interest.

27. What are the environmental impacts of methylene blue production and usage? The environmental impact of methylene blue production and usage is a concern, particularly in terms of potential water pollution. Its use as a dye in industries can lead to the release of methylene blue into water bodies, affecting aquatic ecosystems. However, efforts are underway to develop greener synthesis methods and wastewater treatment technologies to mitigate these impacts. Additionally, the potential repurposing of methylene blue in environmentally friendly applications, like energy storage in batteries, indicates a shift towards more sustainable uses.

28. In what ways could methylene blue revolutionize current medical practices? Methylene blue could revolutionize current medical practices by offering a multi-faceted approach to treatment, particularly in areas where conventional treatments are limited. Its potential in neurology, for instance, offers new avenues for treating conditions like Alzheimer's and Parkinson's disease. Furthermore, its ability to act as an alternative electron carrier in mitochondria presents a novel approach to managing mitochondrial dysfunction. The versatility and broad applicability of methylene blue, coupled with its safety profile, positions it as a potential game-changer in various therapeutic areas.

29. How does public perception of methylene blue as a treatment option compare to its scientific basis? Public perception of methylene blue as a treatment option often lags behind its scientific basis, primarily due to its origin as a dye and limited awareness of its medical applications. While the scientific community recognizes its potential based on a growing body of research, the general public may still view it as a laboratory reagent rather than a serious medicinal compound. Bridging this gap requires continued research, education, and communication about methylene blue's therapeutic benefits and mechanisms of action.

30. What future potential does Methylene Blue hold in medical science? The future potential of Methylene Blue in medical science is vast. Its broad spectrum of applications, from treating infections and neurodegenerative diseases to its role as an antidote in poisonings, positions it as a valuable tool in various medical fields. Ongoing research into its mechanisms and potential new applications could further expand its use, offering new therapeutic avenues for complex medical conditions.

Conditions and Diseases

Methylene blue has been researched and used for various conditions and diseases. Its effectiveness varies depending on the condition and the context of its use. Here's a list of conditions and diseases where methylene blue has shown potential effectiveness:

1. Malaria: Historically, it was one of the first drugs used to treat malaria and continues to be researched for this application.

2. Methemoglobinemia: It's FDA-approved for treating this condition, where hemoglobin is unable to release oxygen effectively to body tissues.

3. Urinary Tract Infections: It has been used for its antiseptic properties in the urinary tract.

4. Cyanide Poisoning: As an antidote due to its ability to interact with the body's chemistry in response to cyanide.

5. Alzheimer's Disease and Dementia: Shows promise in slowing down cognitive decline and improving brain function.

6. Bipolar Disorder: Has been studied for its potential benefits in mood stabilization.

7. Depression: Exhibits potential as an antidepressant, particularly due to its impact on cellular metabolism and nitric oxide levels.

8. Neuropathic Pain: Used in pain management, especially for chronic neuropathic pain.

9. Oral Mucositis: Offers relief in inflammation and pain management for chemotherapy and radiotherapy-induced oral mucositis.

10. Arthritis: Shows anti-inflammatory properties and is being researched for pain relief in arthritis.

11. Migraine Headaches: Due to its role in modulating nitric oxide, it may be beneficial in treating migraines.

12. Low Back Pain: Has been investigated for alleviating pain associated with spinal issues.

13. Cardiovascular Health: Potential in improving heart function and treating conditions related to cardiovascular health.

14. Cancer: Used in photodynamic therapy for treating certain types of cancer, exploiting its ability to target cancer cells' metabolism.

15. Autism Spectrum Disorders: Early research suggests it may benefit metabolic function in autism, though more research is needed.

16. Viral Infections: Including potential activity against COVID-19 and other viruses.

17. Cognitive Enhancement: Used as a nootropic for improving memory and brain function.

Mechanism of Action

Methylene blue's mechanism of action in various diseases is multifaceted, primarily revolving around its impact on cellular metabolism, oxidative stress, and nitric oxide levels. Here's a breakdown of its mechanism of action for the listed conditions:

1. Alzheimer's Disease and Dementia: Methylene blue helps enhance mitochondrial function and energy production in brain cells. It also reduces the buildup of abnormal proteins that are characteristic of Alzheimer’s, like tau tangles and amyloid plaques. By improving cellular respiration and reducing oxidative stress, it may help slow cognitive decline.

2. Bipolar Disorder: The mood-stabilizing effects in bipolar disorder are believed to be related to methylene blue's impact on the brain's energy metabolism and its antioxidant properties. It may modulate neurotransmitters and brain chemicals involved in mood regulation.

3. Depression: Methylene blue's potential as an antidepressant is linked to its ability to improve mitochondrial function and enhance cellular energy production. It also modulates nitric oxide levels, which are implicated in the pathophysiology of depression.

4. Neuropathic Pain: It is thought to alleviate pain by blocking the pain pathways and reducing inflammation at the cellular level. It may also have a direct analgesic effect on nerve cells.

5. Oral Mucositis: Methylene blue can reduce inflammation and pain associated with oral mucositis. It's believed to work through its antimicrobial properties, reducing infection risk in damaged oral tissues, and through its anti-inflammatory effects.

6. Arthritis: Its anti-inflammatory properties help in reducing pain and swelling in arthritis. Methylene blue may modulate the immune response and inhibit enzymes that contribute to inflammation.

7. Migraine Headaches: Methylene blue influences the synthesis and activity of nitric oxide, which plays a role in the vasodilation seen in migraine headaches. By modulating nitric oxide, it may help in reducing migraine frequency and severity.

8. Low Back Pain: The drug is believed to reduce pain by its anti-inflammatory action and possibly by affecting the nerve signals in the affected spinal region.

9. Cardiovascular Health: Methylene blue can improve heart function by enhancing mitochondrial efficiency, reducing oxidative stress, and modulating nitric oxide levels, which are crucial in cardiovascular health.

10. Cancer: In photodynamic therapy, methylene blue selectively accumulates in cancer cells and generates reactive oxygen species when exposed to light, leading to cell death. Its ability to target cancer cells' altered metabolism also plays a role.

11. Autism Spectrum Disorders: The theory is that methylene blue improves mitochondrial function in the brain, which is often impaired in autism. By enhancing cellular respiration and reducing oxidative stress, it may improve neurological function in individuals with autism.

The Paradox

We have now arrived at the potentially confusing part. The paradox.

On one hand, it is recognized for its industrial applications, such as a paint stripper, degreaser, and fabric dye. On the other hand, it is utilized in medical treatments, provided it is used correctly.

Agent131711 wrote this recently.

Methylene Blue is TOXIC WASTE. From Sewer to Arm: a Miracle Treatment? (substack.com)

He makes this point:

There are different methods of investigating. My research looks at ingredients and manufacturing processes. Their research looks at clinical trials and outcomes. My research tells me, “If it’s a carcinogen, containing mercury, lead and literal poison, I don’t give a f*ck what the clinical trials say, I don’t want those ingredients in my body”. Their research says, “This trial shows people used this product and they recovered from their illness in 3 days!”. To which reply, “I don’t give a flying f*ck if they recovered in 3 minutes, that doesn’t change the fact that they just ingested a chemical, which is known to cause fertility issues, internal bleeding and cancer”.

Here is a summary of his article and his investigations into its manufacturing. He writes long, well researched and thought-provoking articles, and is worth considering for a paid subscription.

Methylene Blue Is Toxic Waste

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I am hoping that someone with more biochemical knowledge than myself helps us wade through the paradox in the comments.

But I guess, one way I think about this is that if I was old, and with Alzheimer’s and MB was proven to help, and assuming there was nothing better, then I would accept the cancer and fertility risk (what fertility?!) in exchange for the benefits.

But against a lesser condition with cleaner or better alternatives e.g. high dose Vitamin C, I’m likely to go in a different direction.

Informed consent means knowing both sides of the ledger, even if it is annoying, frustrating and confusing.

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5 Articles

Dr. Francisco Gonzalez-Lima - The Surprising Health Benefits of Methylene Blue (substack.com)

292. METHYLENE BLUE (MB) FOR MEMORY, MOOD, PARKINSON'S, AND MORE (substack.com)

Methylene Blue: A molecule made for this time? (substack.com)

Resolving Colds to Advanced COVID with Methylene Blue (orthomolecular.org)

How Methylene Blue's Antioxidants Can Slow Cognitive Decline | Riordan Clinic

Book

The Ultimate Guide to Methylene Blue: Remarkable Hope for Depression, COVID, AIDS & other Viruses, Alzheimer’s, Autism, Cancer, Heart Disease, Cognitive ... Targeting Mitochondrial Dysfunction) eBook : Sloan, Mark: Amazon.com.au: Kindle Store

Two Podcasts

Antioxidant Power of Methylene Blue

A Second Look at Methylene Blue

Comments

[Unbekoming]

I am pinning the critical comment of Dr Robert Yoho, as I consider him both a teacher and mentor, so I take the critique seriously.

I personally don't think Agent is a psyop, but I'm open to eating humble pie if I reach a different conclusion.

It was his work that helped me finally come to terms with geoengineering. I was able to verify all the claims he made on that subject.

His approach is different, angry and unorthodox, but I'm happy to judge it on its individual merits. I know his position on Vit D3 (hurts my brain to think about it), I don't know his position on IVM, and regardless I consider that separate to his MB work.

He is highly suspicious of Big Supplement and wouldn't be the first person to reach that conclusion. It's largely an unregulated space, with large amounts of money. I have no doubt that it houses its own collection of untruths. I'm not claiming that MB is one of those lies, but I think his points on the matter are worthy of consideration and discussion.

If anyone has very specific critiques of the specific points he is making about MB, I would love to hear them, but the claim that he is wrong about A doesn't mean he is wrong about B.

His primary argument is the same argument that we have been making about aluminum adjuvants in vaccines. It is toxic and any amount is not good. That is the essence of his argument here with MB. I'm not saying it's a winning argument that trumps all else, but it is a legitimate point to be considered.

That being said, a reader (thanks Tony) emailed me privately with the following valuable point that is worth sharing:

Methylene Blue paradox not a paradox at all.

It's called the Therapeutic Index - the ratio of the therapeutic dose of a drug to a fatal dose. Pretty much all drugs are poisons. Cannabis is a rare exception, there is no known fatal dose. If you are going to refuse to take a drug because it's also a poison, then you'd have to stop taking therapeutic drugs entirely. It's like saying you can't possibly use a knife in the kitchen because they kill people. It's all in how you approach the tool.

I was hesitant to publish the article but I'm now glad I did, as I think all this back and forth is valuable for everyone. It helps us all improve our thinking skills on a subject (supplements) that can easily become a "holy cow".

[Robert Yoho MD (ret)]

"Agent131711" is certainly a psyop working against our interests. Later on in his post, he puts a clip in about the toxicity of ivermectin. The narrator's tones are dramatic and frightening. Anyone conscious over the past 3 years knows that ivermectin toxicity is unheard of and that billions (yes) of doses have been given worldwide with negligible rumors about any toxicity. It is the true standard of care for Covid/long hauler's/viral illness/ etc. I recommend you immediately send out a disclaimer that the "Agent" source is bogus and that you retract it. Thomas Levy is the most credible reference. Here is my post; thanks for referencing it. https://robertyoho.substack.com/p/292-methylene-blue-mb-for-memory We don't know everything about MB but we sure have a lot of people who have responded to it.