This is extremely welcoming. It was always a thing too far out to be practical and that has finally changed.
This may never actually cure cancer or more than specific cancers or sickle cell anemia but it stands to allow victims to come under a permanent stalemate at least which is as good as a cure as we discovered with AIDS.
It is potentially a major revolution for all blood related disease which indirectly cancer is and mst other disease.
After all even simple infectious agents can be tagged and stopped in this manner by simply having a session at a blood machine...
Cytophone detects and blasts circulating cancer cells
This may never actually cure cancer or more than specific cancers or sickle cell anemia but it stands to allow victims to come under a permanent stalemate at least which is as good as a cure as we discovered with AIDS.
It is potentially a major revolution for all blood related disease which indirectly cancer is and mst other disease.
After all even simple infectious agents can be tagged and stopped in this manner by simply having a session at a blood machine...
Cytophone detects and blasts circulating cancer cells
Matt Kennedy
The Cytophone laser/ultrasound-based device in action detecting circulating tumor cells in the blood of patients with melanoma(Credit: Ekaterina Galanzha et al., Science Translational Medicine)
A
team from the University of Arkansas for Medical Sciences (UAMS) has
developed a non-invasive tool which not only detects circulating tumor
cells (CTCs) in the bloodstream, but can blast them away at the same
time. Dubbed the Cytophone, it employs a laser which heats the CTCs,
subsequently detecting them via ultrasound before turning up the heat
again to kill them.
CTCs
are the means by which metastasis (secondary malignant growths) occurs,
so detecting and responding to them quickly is key to halting – or at
least inhibiting – the spread of cancer. This isn't the first time
lasers have been used by researchers to detect cancer, nor to attack it,
but this – according to the the team – is the first demonstration of a
non-invasive method of detecting CTCs directly in the bloodstream of
melanoma patients.
But
the Cytophone is more than just a detection device, it can blast these
cells as well. In the detection phase, the laser penetrates the blood
vessel, heating the dark melanin nanoparticles in the CTCs. Because they
heat more quickly than surrounding particles, the rapid thermal
expansion of these nanoparticles generates a unique sound which is
detected via an ultrasound transducer on the skin surface. To destroy
the CTCs, the laser further heats them, creating nano bubbles which
eventually destroy the tumor cell. This hunter/killer capability means
that the Cytophone has the potential to act as a dual therapeutic and
diagnostic (theranostic) tool.
Led by Dr Vladimir Zharov, the team found that its device was a thousand times more sensitive than other methods when it came to detecting CTCs in the blood of melanoma patients. Even when a tumor was unable to be detected on the skin – due to size or after surgical removal – the Cytophone was able to detect CTCs that traditional methods might easily miss.
"The only methods that are available to detect CTCs are mainly based on drawing blood from the patient," says Zharov. "An average blood sample taken from a patient consists of only a few milliliters, which may or may not contain any CTCs. In contrast, the Cytophone can monitor a person's entire five-liter blood supply, potentially locating every CTC in it. No needle is used, and no blood is removed."
Led by Dr Vladimir Zharov, the team found that its device was a thousand times more sensitive than other methods when it came to detecting CTCs in the blood of melanoma patients. Even when a tumor was unable to be detected on the skin – due to size or after surgical removal – the Cytophone was able to detect CTCs that traditional methods might easily miss.
"The only methods that are available to detect CTCs are mainly based on drawing blood from the patient," says Zharov. "An average blood sample taken from a patient consists of only a few milliliters, which may or may not contain any CTCs. In contrast, the Cytophone can monitor a person's entire five-liter blood supply, potentially locating every CTC in it. No needle is used, and no blood is removed."
While
the initial study was conducted on patients with melanoma, the
Cytophone has potential applications for other cancer cells that have no
pigment. The research showed the device had the ability to detect
non-pigmented CTCs by first injecting patients with magnetic and gold
nanoparticles with a unique biological coating which would help tag the
CTCs. The Cytophone can also spot cancer-related blood clots, the second
leading cause of death in cancer patients according to the researchers.
However,
the potential applications for the Cytophone aren't just
cancer-related. It could also be adapted to detect sickle cells (to
prevent sickle cell crisis) or used to aid in the selection of the most
effective of a range of drugs by monitoring any disease-associated
markers in the blood and noting which ones decreased the most.
The
team at UAMS isn't resting just yet, and is currently developing a
simpler, portable, wearable Cytophone – using advanced, smaller lasers –
to be distributed to cancer clinics across the USA and used in a wider
clinical trial with even more melanoma patients. It remains to be seen
if the Cytophone is to become a stand-alone treatment, or used in
combination with conventional treatment methods.
The research is described in a paper published this week in the journal Science Translational Medicine.
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