The fight against cancer is slowly but surely approaching the threshold of victory with the help of a group of researchers fighting on the front line. Researchers around the world have joined forces to fight cancer. Some of them focused on its behavior, to destroy it and act preventively in its further development. In contrast, others focused on influencing their growth by preventing its expansion to a certain size and reducing the number. Then, cancer can begin to conquer the rest, a healthy organism, and metastasize in all parts of the body.
How to get rid of cancer
Cancer is complicated to beat once it appears in our body due to many “zombie” cells. These cells live forever as long as the patient’s body is alive. Cancerous cells possess six features of a carcinogenic mutation that continuously divide in large numbers and uncontrollably. These cells are not subject to cell age and apoptosis’s natural law. These cells continue to grow, threatening normal cells and their food sources. They lose their physiological function and endanger, and at the same time weaken the organism.
Getting rid of these cells is not easy since they are made of normal cells and surround them. Any cytostatic drug that aims to destroy cancer cells will also affect normal cells, with the accompanying effects of chemotherapy and radiation. Researchers worldwide are united in finding weapons with fewer side effects to fight cancer cells and selectively destroy them. The classic treatments are surgery, chemotherapy, and radiation, but targeted therapy that destroys exclusively cancerous cells will have much fewer negative effects on the human body in performing its basic task.
Studies on cancer and its treatment
In 1980, a group of scientists investigated certain types of cancer’s geographical representation. They found that in some parts of the world, cancer incidence is very low. The discovery raised the question of whether there is a connection with the environment. The studies were completed. It was discovered that an increased number of cancer cases directly related to soil composition. In those areas where the concentration of alkali metals was increased, cancer prevalence was reduced. In 1920, scientists suggested that cesium chloride as an alkali may be an effective anti-cancer agent. Still, ten years later, further research has shown that this compound has minimal effect on tumor growth.
This was the case until 1984 when a pervasive study on humans and rats was started by Dr. Braver, which proved that cesium chloride reduces the size of tumors, reduces the pain caused by cancer, and kills cancerous cells without affecting normal cells. The popularity of Cesium Chloride as an anti-carcinogenic agent has revived.
Cesium Chloride and its activity
No one has fully understood the mechanism of action and the key to Cesium Chloride’s success. Dr. In his study, Brever suggested high Ph mechanisms. Cesium was absorbed in large quantities by cancer cells but not healthy ones. Cesium Chloride by cancer cells changes their environment from acidic to basic, which is an unbearable environment for cancer cells. Under such conditions, cancer cells’ activities become reduced, and at increased Ph values, cancer cells experience severe damage and die.
ATP energy and its effect on cancer
Due to normal metabolic activities, normal cells receive a standard supply of oxygen and other ingredients from the blood. Cells take up glucose due to aerobic conditions to produce an ATP unit of cellular energy, which supplies the cell with power for its physiological tasks. In demanding conditions, during strenuous exercise, the cellular metabolic need increases the supply of white grains and does not meet the sufficient oxygen needs. The cells go into the anaerobic mode, still producing ATP but less efficient. This process’s product is the accumulation of lactic acid, which creates a low Ph environment, known as acidosis. The human body has a defense mechanism that is immediately triggered by the onset of acidosis.
The accumulated lactic acid is converted back to glucose in a highly concentrated oxygen environment reused by the cells. This activity, also known as the cortical cycle, is performed and consumes 6 ATP per one lactate molecule. The switch for lactic acid metabolism is not efficient enough for energy consumption. Still, it maintains and generates energy used by cells regardless of relatively small ATP and deficient oxygen levels. When the internal level of oxygen returns to normal, the body must pay a debt of energy spent on converting lactic acid into glucose in the amount of 6 ATP per one molecule of lactic acid.
How cancer works
Cancer cells function in the same way as in the above-mentioned condition. These cells multiply very quickly. To meet the needs of their development, these cells promote the development of microcapillaries that supply blood, a process known as angiogenesis. In addition to angiogenesis attempts, these cells develop and multiply too quickly. It is often the case that these new capillaries cannot satisfy the tumor’s needs in the development and its spread. It is not uncommon that due to insufficient supply in the center tumor, many cells die. For this reason, cancer cells are highly adapted to anaerobic metabolism, which produces a high concentration of hydrogen ions, creating an acidic environment.
Carcinogenic cells and lactic acid
Cancer cells draw ATP mainly from the anaerobic state or the lactic acid cycle at their very high multiplication rate. This is a very inefficient ATP production system. Lactic acid will be sent back to the liver through the cortical cycle to be converted back into glucose and re-feed the cancer cells. For each glucose molecule, 2 ATPs are produced by the lactic acid circuit to feed the cancer cell, to the detriment of the 6 ATPs consumed. The total loss is 4 ATP molecules per molecule of glucose.
The Milky Way
This magic circle explains the loss of strength typical of many people with cancer. The cation, mainly Cesium Chloride, helps break this vicious circle by creating an alkaline environment, balancing the excess hydrogen ions reduces the formation of lactic acid.
Cancer cells live in an acidic environment, which suits them, while normal cells cannot survive in such an environment. As cancer cells expand and grow, so does the production of lactic acid, the high concentration of which is unnatural for normal cells. Cesium chloride absorption is higher by cancerous cells than normal cells. The high concentration of this compound in cancer cells changes the Ph environment from a low Ph value or an acidic state to a high Ph state or an alkaline environment. Cancer cells do not function normally in an alkaline environment. Thus, their functions are reduced, and at a higher level, this condition results in cancer cells’ death.
Tests and studies
In early studies at the American University in Washington, studies were performed on rats implanted with cancer cells in the abdomen. These cells were allowed to develop for the next 8 days, after which the rats were divided into two groups; one was used as a control group while the other was treated with an alkali metal. The control group died after 13 days, while the other remained alive with minor cancer signs.
Surviving rats were killed, and a post-mortem autopsy determined that the tumor size was equal to one-eighth of the tumor size in the control rats. Similar research was done in Platteville by giving injections Cesium Chloride intraperitoneal. 97% cure was reported in the treated group, with a drastic tumor shrinkage level.
Testing on humans
Dr. H. Nieper first started human testing in Hanover, Germany, and Dr. X Santori in Washington, USA. Very satisfactory results have been reported. The studies included taking 2 grams of Cesium Chloride three times a day with meals along with high doses of vitamins C and A and zinc. The treated patients recovered from the pain caused by cancer. Even better results were published during the tumor examination because the tumor was drastically reduced.
Indirect measurements were performed by measuring uric acid in urine. Cell extinction and reversals can be monitored indirectly through uric acid and its levels, as cell death is shown in some other elements produced by the body, including uric acid. In the treated patients, uric acid concentration was increased after the treatment with Cesium Chloride, which was one of the proofs that the cancer cells started to die.
Cell pH values and cancer
A high Ph environment is not conducive to healthy cells either. Human cells survive in a constant internal environment, a condition known as homeostasis. The optimal Ph range is between 7.35 and 7.45. The body’s system will automatically blanch this value if it is violated. The biggest problem with many treatments with high Ph values is the exposure of the whole organism to these conditions that are not natural in our physiological processes. Cesium Chloride supplement produces targeted high Ph values that affect cancer cells. Greater absorption of this preparation into cancer cells negatively affects cancer while normal cells continue to function.
Cesium chloride is a safe, non-toxic supplement as long as it is taken in permitted doses. Theoretically, a high concentration of cations in the blood can disturb the body’s electrolyte balance. The effect of this homeostatic disorder is related to nerve cells, muscle cells, and most importantly, to the heart.
Because Cesium is a cation, the addition of a high amount of this compound disrupts the balance of cations in the body. Selenium in the blood to a condition called hypokalemia. It is recommended when using this preparation of Cesium Chloride to increase potassium intake for the above reasons. As long as this compound is used within the permitted limits and regular electrolyte recordings are performed, side effects are infrequent.