Best adjuvant (assist) for chemotherapy | 1+1>487% |
Effectively improve chemotherapy effect, treatment, immunity.
Reduce side effects and recurrence.
Overview / Relation / Abstract / Role / Principle / Action / Mechanism / Function / Work |
Melanoma: Latest Research
Abstract / Summary / Overview of Apoptosis.
Why do cells undergo apoptosis?
The relationship between cancer cells and apoptosis.
Where are the weaknesses and symptoms of cancer cells?
Are cancer cells aggressive?
Extraordinary Solamargine (Role, Principle, Action, Mechanism, Function, Work)
Solamargine's major function mechanism:
Solamargine vs cancer
Best Chemotherapy Adjuvant. (1+1>478%)
Effectively improve chemotherapy effect and cure.
When cancer cells are less resistant to drugs, chemotherapy becomes more effective.
Extract : https://www.cancer.net/cancer-types/
Melanoma: Latest Research
You will read about the scientific research being done to learn more about melanoma and how to treat it.
Doctors are working to learn more about melanoma, ways to prevent it, how to best treat it, and how to provide the best care to people diagnosed with this disease. The following areas of research may include new options for patients through clinical trials. This section is not meant to be a complete list of new clinical trials because this field is changing rapidly. Always talk with your doctor about the best diagnostic and treatment options for you.
Enhanced prevention and early detection methods. There is ongoing research on better prevention and early detection strategies for melanoma. Both primary and secondary prevention are important. Primary prevention involves keeping melanoma from developing, such as reducing exposure of ultraviolet (UV) radiation from the sun and avoiding the use of indoor tanning devices. Secondary prevention includes methods of early detection. One promising area is the screening of people with a high risk of developing melanoma, as described earlier in this guide.
Targeted therapy. As discussed in Types of Treatment, targeted therapy is a treatment that targets specific genes or proteins. Research has identified a number of molecular pathways and activated or mutated genes in melanoma. Clinical trials are testing new drugs to inhibit the MAP kinase pathway and other pathways that melanoma might use to grow and spread. Strategies to prevent the melanoma from becoming resistant to treatment are also being tested, such as using combinations of drugs or exploring new schedules of giving drugs to patients.
Immunotherapy. As explained in Types of Treatment, immunotherapy is an important treatment option for melanoma. Researchers are studying new checkpoint inhibitors and immunotherapies directed at other parts of the immune system. These include TIM3 inhibitors, LAG3 inhibitors, OX40 agonists, CD137 agonists, GITR agonists, and IDO inhibitors. Also, a number of combinations of immunotherapies are being looked at, including all of the above agents with PD-1 or PD-L1 inhibitors, as well as combinations of targeted therapies with PD-1 or PD-L1 inhibitors. Recently, the combination of a LAG3 inhibitor, called relatlimab, and nivolumab was shown to delay tumor growth when compared with nivolumab alone in people with newly diagnosed, unresectable stage III or metastatic melanoma. A fixed-dose combination of these 2 drugs, called Opdualag, has been approved to treat unresectable stage III or stage IV melanoma in people aged 12 and older. It is considered an alternative standard of care treatment to using a single PD-1 inhibitor and to using a combination of ipilimumab and nivolumab.
Adoptive cell therapy (ACT), chimeric antigen receptor T-cell (CAR-T) therapy, and T-cell receptor (TCR) therapy. Another type of experimental immunotherapy involves altering a person’s white blood cells, known as lymphocytes, in a laboratory. In ACT, this may involve a surgical procedure to remove a tumor, isolate the white blood cells, and expand them outside the body. In CAR-T therapy and TCR therapy, white blood cells are removed from the body using a procedure called pheresis. The white blood cells are modified to better recognize cancer cells. This is done to increase their ability to fight the tumor. Then, the cells are given back to the patient, often in combination with chemotherapy, interleukin-2, and/or other immunotherapies.
Vaccines. Therapeutic vaccines that may improve the specific immune response to melanoma have been the focus of multiple clinical trials. Melanoma peptide vaccines are being evaluated in clinical trials for patients with both localized and advanced melanoma. Research has shown that vaccination can cause the immune system to fight melanoma, even in advanced disease, but these treatments are still considered experimental. The vaccines are made using certain proteins found only on a melanoma tumor and are given as an injection. The person’s immune system then recognizes the proteins and destroys melanoma cancer cells. To date, no vaccines have shown a clinical benefit in patients. Learn more about the basics of cancer vaccines.
Palliative care/supportive care. Clinical trials are underway to find better ways of reducing symptoms and side effects of current melanoma treatments to improve comfort and quality of life for patients.
Abstract / Summary / Overview of Apoptosis.
Overview of apoptosis
•Programmed cell death
•Apoptosis is a form of programmed cell death, or “cellular suicide.”
•Apoptosis is different from necrosis, in which cells die due to injury.
•Apoptosis removes cells during development, eliminates potentially cancerous and virus-infected cells, and maintains balance in the body.
Why do cells undergo apoptosis?
- Basically, apoptosis is a general and convenient way to remove cells that should no longer be part of the organism.
- Some cells are abnormal and could hurt the rest of the organism if they survive, such as cells with viral infections or DNA damage.
- Apoptosis is part of development
- In many organisms, programmed cell death is a normal part of development.
The relationship between cancer cells and apoptosis
Apoptosis can eliminate infected or cancerous cells.
When a cell’s DNA is damaged, it will typically detect the damage and try to repair it.
If the damage is beyond repair, the cell will normally send itself into apoptosis, ensuring that it will not pass on its damaged DNA.
When cells have DNA damage but fail to undergo apoptosis, they may be on the road to cancer.
However, “successful” cancer cells successfully evade the process of apoptosis.
This allows them to divide out of control and accumulate mutations (changes in their DNA).
Apoptosis is key to immune function
Apoptosis also plays an essential role in the development and maintenance of a healthy immune system.
Where are the weaknesses and symptoms of cancer cells?
The symptoms of cancer cells are in the nucleus.
The nucleus controls the outer cytoplasm, cell composition, cell viability, etc.
DNA mutations also mutate in the nucleus.
Therefore, to treat cancer cells, we must first enter the nucleus.
Let the “regulatory cell gene” mechanism enter the nucleus to regulate
Are cancer cells aggressive?
After the action of Solamargine, the aggressiveness of cancer cells is alleviated.
So after using Solamargine, many patients feel that I am half better.
Although the tumor does not disappear quickly, patients feel that the degree of aggressiveness is reduced.
Extraordinary Solamargine (Role, Principle, Action, Mechanism, Function, Work).
Solamargine's major function mechanism:
When Solamargine enter,
Solamargine activates receptors that are turned off by cancer cells, allowing cancer cells to modulate again.
Solamargine modulates the anti-modulates genes of cancer cells, making cancer cells less resistant.
Reduced drug resistance
When cancer cells are less resistant to drugs, chemotherapy becomes more effective.
Solamargine modulates the mutated genes in cancer cells and then initiates cancer cell apoptosis to achieve anti-cancer effects.
Solamargine combined with which chemotherapy drugs are more effective in treating cancer cells?
Solamargine vs cancer
Solamargine vs cancer
The picture shows the death of cancer cells.
The black and black parts are cancer cell nuclei.
Even if the nucleus ruptures, the cancer cells will die.
The figure shows that cancer cells can cause death.
The figure shows that cancer cells can cause death.
The figure shows that the death of lung cancer cells is relatively slow, and it will not be obvious until eight hours later.
The figure shows that the death of liver cancer cells is very obvious, even more obvious in eight hours.
The graph shows that breast cancer cells die faster. It was obvious from the beginning that breast cancer is easy to treat, and patients with breast cancer need not worry.
Best Chemotherapy Adjuvant. (1+1>487%)
Effectively improve chemotherapy effect and treatment.
ANTI-CANCER
Patent protection in 32 nations.
A comparison study showing Solamargine vs. other therapeutic drugs with respect to lung cancer cells.
A comparison study showing Solamargine vs. other chemotherapeutic drugs with respect to breast cancer cells.
SR-T100 combination therapy with effective result against breast cancer cells.
Combination Therapy | Research results for lung cancer cells.
A. Chemotherapy (100μM), 16% of cancer cell apoptosis.
B. Alone SM (4.8μM), 28% of cancer cell apoptosis.
C. SM (4.80μM) + Chemotherapy (40μM), 66% of cancer cells apoptosis.
D. SM (4.80μM) + Chemotherapy (100μM), 78% of cancer cell apoptosis.
SM has a clearing effect better than Chemotherapy.
The combined treatment of Solamargine and Chemotherapy significantly increased the apoptosis of lung cancer cells.
SM (4.8μM) + Chemotherapy (40μM), increased from 16% to 66% (up to 4.125 times).
SM (4.8μM) + Chemotherapy (100μM), increased from 16% to 78% (up to 4.875 times).
Reorganized from: BBRC. Action of Solamargine on TNFs and drug-resistant human lung cancer cells 2004.
The best solution for cancer cells.