The Magical Mechanism of Chlorine Dioxide
Understanding How Chlorine Dioxide Can Heal Many Diseases
When exploring the complex mechanisms of ROS within the human body, it is impossible not to mention the widely studied drug metformin. Research indicates that the benefits of metformin extend well beyond the traditional treatment of type 2 diabetes, with potential in areas such as weight loss, cancer prevention, anti-aging, anti-inflammatory effects (for treating autoimmune diseases), and even antiviral responses. Although there is some controversy in the findings, some reports suggest that metformin may increase ROS levels in the body (contrary to the numerous studies that suggest metformin helps reduce ROS, thereby reducing oxidative stress damage. I firmly disagree with this point; oxidative stress is a long-term result, and many reports have reached a consensus by treating the free radical damage theory as evidence).
Considering the potential anti-cancer effects of increased ROS levels (which can trigger systemic anti-tumor immune responses) and the role in promoting tissue regeneration, we can hypothesize that the mechanism by which metformin treats various diseases may involve using ROS to clear damaged cells (contributing to anti-aging and anti-cancer effects), promote tissue regeneration, and modulate immune responses (anti-inflammatory).
Further speculation suggests that directly supplementing chlorine dioxide at the site of lesions (mimicking exogenous ROS supply) may play three key roles: first, it may indiscriminately clear abnormal cells, including senescent and cancerous cells, and may also affect some normal cells; second, it may promote the regeneration of damaged tissues; and last, it may regulate the immune system, restoring immune balance. Below, I will detail how I have proven these three magical mechanisms of chlorine dioxide through experimentation.
4.1 The Non-Selective Cell Elimination Mechanism of Chlorine Dioxide
As a potent oxidizing agent, chlorine dioxide at certain concentrations can easily kill a wide range of viruses, bacteria, and even larger parasites. Therefore, when delivered to any part of the body, it can also readily kill various cells, implying that chlorine dioxide can eliminate cells indiscriminately.
To verify this mechanism, I conducted experiments on the cytotoxic effects of chlorine dioxide on cancer cells in vitro: if the concentration of chlorine dioxide reaches 1mg/mL, it can kill all cancer cells in a culture dish (including two types of
normal cells) (Figure 3).
Additionally, I administered subcutaneous injections of chlorine dioxide at concentrations of 7.5mg/mL and 15mg/mL into the backs of mice. This resulted in a distinct area of damage around the injection site, where the chlorine dioxide completely destroyed the hair follicles, leading to total hair loss in the affected area. Despite the severe damage, the procedure was overall safe for the mice and did not cause irreversible permanent harm. Thirty-one days after the subcutaneous injection, the damaged area had fully regenerated,
and the hair had successfully regrown (Figure 4).
Later, in my experiments using intratumoral injections of chlorine dioxide to treat cancer, I confirmed that intratumoral injection of chlorine dioxide could completely ablate any type of solid tumor.
The non-selective cell elimination mechanism of chlorine dioxide is crucial for treating certain proliferative diseases characterized by dysfunctional cell growth, such as localized senescent diseases (excess senescent cells) and cancer (excess cancer cells). It is akin to a skilled technician removing a faulty part from a machine and replacing it with a functioning one, restoring the machine to operation. Similarly, for localized senescent diseases and cancer, we can deliver chlorine dioxide directly to the affected area. Relying on its strong oxidative action, chlorine dioxide indiscriminately kills the cells it contacts, effectively clearing out the damaged cells. Inevitably, some normal cells will be harmed in the process, but such damage is reversible. After chlorine dioxide clears the cells, the body can fill the physical void left behind with healthy cells.
I emphasize the non-selective nature of chlorine dioxide in cell elimination because this characteristic is critical. Typically, the body can clear some senescent cells on its own, likely through the immune system. However, it usually cannot initiate a normal regenerative process to fill the voids left by these cells. Naturally, these spaces are often occupied by other functional cells in the vicinity. Take androgenetic alopecia, for example; when hair follicles age and fall out, they are usually not replaced by new follicles of the same size but by increasingly smaller ones. The larger space left by the fallen follicles is often invaded by surrounding sebaceous gland cells. Therefore, to treat hair loss, it is necessary to clear the normal sebaceous gland cells that have taken over the space originally belonging to the hair follicles. Hair transplantation is effective precisely because it is based on this logic. Chlorine dioxide lays the groundwork for treating hair loss through its mechanism of non-selectively clearing cells.
In the field of cancer treatment, existing drugs inevitably encounter the problem of drug resistance, rendering even approved drugs ineffective at combating cancer over the long term. This means many patients with advanced cancer find themselves in a situation with no effective treatment options. The issue of drug resistance primarily stems from the diversity of cancer. Most novel cancer drugs are designed to target specific cancer cell markers or biological pathways, but not all cancer cells consistently exhibit these targets or are affected by these pathways. Hence, drug resistance is a common challenge for current cancer treatments. If there were a drug capable of effectively destroying any type of cancer cell, regardless of how they mutate or exhibit heterogeneity, such a drug could eliminate cancer cells indiscriminately. This would spare cancer patients from the issue of drug resistance, allowing them to continue using the drug indefinitely. Therefore, by directly injecting chlorine dioxide into tumors, we can continuously eliminate cancer cells, potentially turning cancer into a manageable chronic condition.
4.2 The Mechanism of Chlorine Dioxide in Promoting Tissue Regeneration
The human body possesses an innate tissue regeneration system that automatically heals wounds with new tissues, provided the injury is not too extensive. Small wounds heal perfectly, with the new tissue comprised entirely of young cells. However, larger wounds or tissue loss may encounter complications such as infection by pathogens, coverage by necrotic tissue, or the proliferation of non-functional cells or connective tissue, making tissue regeneration especially critical in the later stages of disease treatment.
Existing research has demonstrated that the exogenous supplementation of ROS can promote tissue regeneration. We are now using chlorine dioxide to mimic the role of ROS, giving us reason to believe that the direct delivery of chlorine dioxide can enhance tissue regeneration.
In experiments, I treated the tail wounds of mice with chlorine dioxide, hydrogen peroxide (a type of ROS), and saline. The results showed that chlorine dioxide, like hydrogen peroxide, accelerated wound healing (Figure 5).
The potential reasons for chlorine dioxide’s promotion of tissue regeneration could be related to the following three aspects:
(1) Chlorine dioxide acts as an antimicrobial agent, protecting the wound from microbial infections.
(2) As an oxidant, chlorine dioxide effectively clears away scabs or proliferating connective tissue at the wound site.
(3) Chlorine dioxide may mimic the role of ROS, modulating the immune system and reducing inflammatory responses, thus facilitating normal tissue regeneration.
The mechanism by which chlorine dioxide promotes tissue regeneration is crucial for treating various diseases. Particularly when chlorine dioxide is delivered directly to the affected area, it can swiftly eliminate cells within and around the target zone. Once the clearance process is complete, it leaves behind spaces that need to be filled with regenerated healthy cells. Thus, chlorine dioxide not only enhances tissue regeneration but also strengthens its cell-clearing action, collectively aiding the recovery process from diseases.
4.3 The Mechanism of Immune Response Regulation by Chlorine Dioxide
Maintaining a balanced immune system is critical. An overly strong immune response can trigger autoimmune diseases, for which effective treatments are currently lacking. Conversely, a weak immune response increases the risk of cancer and other age-related diseases, which also present significant treatment challenges.
Although there is some controversy in the research findings, certain studies suggest that increasing the levels of ROS in the body may help suppress excessive immune responses and reduce inflammation. For instance, metformin can inhibit inflammation by increasing ROS levels, which may alleviate autoimmune diseases. Moreover, conclusive evidence indicates that tumor ablation therapies, such as Photodynamic Therapy (PDT), generate ROS and trigger systemic antitumor immune responses, thereby inhibiting tumor growth in other parts of the body.
These studies indicate that ROS has a bidirectional role in regulating immune responses. Based on this, we can speculate that chlorine dioxide might mimic the function of ROS. When delivered directly to the lesion site, chlorine dioxide could modulate the immune response, suppressing inflammation in inflammatory diseases and eliciting systemic antitumor immune responses in cancer therapy.
Under my guidance, many individuals have tried using chlorine dioxide topically to treat various autoimmune skin diseases, achieving remarkable results. Some have even completely cured various skin issues, including alopecia areata, eczema, psoriasis, and vitiligo. Additionally, in my personal experiments, I have successfully treated my arthritis by injecting a high-concentration chlorine dioxide solution (15mg/mL) directly into the joint cavity ten times. These experiences demonstrate chlorine dioxide’s ability to suppress inflammatory responses.
In another study, I treated cancer by injecting chlorine dioxide directly into tumors, which showed that this approach could stimulate a systemic immune response, effectively inhibiting tumors in other parts of the body that were not injected. This further confirms chlorine dioxide’s ability to modulate the immune system.
Metformin is hailed as a “wonder drug” mainly because of its multiple therapeutic effects: controlling blood sugar, aiding weight loss, fighting cancer, delaying aging, reducing inflammation, and promoting tissue regeneration. I speculate that these effects are likely related to its ability to increase ROS levels in the body. Chlorine dioxide, which can mimic the function of ROS, might be more effective in treating these diseases when delivered directly to the affected area.
Globally, drug regulation is very strict. Currently, I may be the only one pushing for chlorine dioxide to enter clinical trials as a new drug. Before chlorine dioxide is ultimately approved, we may face significant challenges, and the process could be quite lengthy. For readers of this book, if you wish to treat diseases beyond the skin surface, you might not be able to try treatment without medical supervision, even if you understand the mechanism of action of chlorine dioxide. I suggest that, in the absence of chlorine dioxide, considering oral metformin as an alternative treatment option could be beneficial.
If taken orally by a human with an autoimmune disease (bring treated by an opthalmologist and rheumatologist (and drugs): how many drops, and what is the recommended activator? (I've used it in the past. Activated with citric acid.)
I have it in stock for many years. In a dark blue bottle. Wondering whether it has significantly degraded too...
Thank you for your time, and your knowledge.