Well, killing 99% of cancer cells is quite useless, the 1% left will now thrive and if they survived because they were different (and not just luckily escaping the treatment) you now have 100% of cancer cells you can’t treat anymore.
Better case, the 1% “lucky” cancer cells just re-invade.
Best case scenario is that your immune system takes care of the final 1%. Worse case scenario is exactly as you described and you get mets that are resistant to therapy.
I thought the issue is your immune system wouldn’t know to take care of the final 1%. As that’s the issue with cancer: it isn’t an antigen. It is something made by the body so it’s already coated in a natural sheep’s clothing to escape being detected by the immune system. Hence why breakthroughs in marking the cells is so important so at least an outside force can treat it.
Well, killing 99% of cancer cells is quite useless, the 1% left will now thrive and if they survived because they were different (and not just luckily escaping the treatment) you now have 100% of cancer cells you can’t treat anymore.
Better case, the 1% “lucky” cancer cells just re-invade.
It could extend the life of the patient with a few years.
Maybe, or just extending the suffering for a couple of months. Hope it gets better!
Best case scenario is that your immune system takes care of the final 1%. Worse case scenario is exactly as you described and you get mets that are resistant to therapy.
I thought the issue is your immune system wouldn’t know to take care of the final 1%. As that’s the issue with cancer: it isn’t an antigen. It is something made by the body so it’s already coated in a natural sheep’s clothing to escape being detected by the immune system. Hence why breakthroughs in marking the cells is so important so at least an outside force can treat it.