h a l f b a k e r yAlas, poor spelling!
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injectable bells against cancer
little shapes have a resonant acoustic frequency. These are injected into tumors with a needle rather than surgery. Then outside the body acoustic waves activate the little shapes destroying tumor tissue | |
Tumor liquefying (and possibly removal) without surgery.
Make tiny, injectable shapes with an acoustic resonant frequency.
Inject the tiny shapes into a tumor.
Wiggle the shapes with acoustic waves from outside the body to shatter/liquefy tumor tissue.
Pull the liquefied tumor out with a
syringe to minimize risk of metastasis (spread)
Minimally invasive cancer treatment. Might work particularly well with breast cancer as this is nearer the surface for injections and acoustics.
Edit: as has been pointed out in the annotations you could just inject a tumor with a toxin, or possibly hot cheese to kill it. This brings up another possibility: protein dissolving enzymes. These could be tuned to produce different length protein fragments. Study could reveal fragments that alert the immune system to the cancer, causing the body to fight the cancer more effectively.
ultrasound powers microparticles at bloodstream "The gold body of the nanorobots responds to ultrasound, which gives them the ability to swim around rapidly without chemical fuel."
http://jacobsschool...release.sfe?id=2550 [beanangel, Jun 06 2018]
[link]
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But this is pointless, even if it would work. |
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Insofar as you can inject these things into a cancer, you can
inject a short-lived toxin to kill cancer cells. Your bells are
just a rather convoluted version of an indiscriminately
cytotoxic drug. |
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The problem with treating cancer is in actually delivering
agents specifically to cancer cells, and this idea does not
achieve anything in that direction. |
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// tiny, injectable shapes with an acoustic resonant frequency // |
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That would be dependant on the velocity of sound in the relevant tissue, which is strongly affected by its density. |
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The typically velocity of sound in seawater, which is a reasonable equivalent to eukaryotic tissue, is about 1500 m s^-1 |
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40kHz ultrasonic transducers are an off-the-shelf item, along with their driver circuitry. |
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So applying v = f * lambda, this gives a wavelength of 1500/40000 which is 3.7 mm. A lot larger than any mammalian cell ... |
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I know! How about injectable cheese balls? If they were hot
enough, you could just fondue the cancer cells to death.
Golly gee, I spent 7 seconds coming up with that - maybe I
should post it rather than letting all that effort go to waste. |
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How about protein dissolving enzymes? because these could be tuned to produce different protein fragments study might reveal fragments that alert the immune system to the cancer, causing the body to fight the cancer more effectively. |
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[beany], I know you mean well. |
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At the [link] they power nanobots in the bloodstream with
ultrasound. Vibrating away tumors looks more likely. |
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Sure you've got the bells... but what about the whistles? What about them? |
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"We'll be supplementing your Whyte cells with some Mackay cells
..." |
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