The X-rays used to make mammograms reveal calcium deposits associated with breast cancer even in tumours too small to be felt. But surgeons can't use X-rays while operating. Instead, radiologists place guide wires into tumours hours or even the day before surgery. The wires don't mark depth well and can shift. Patients find them both uncomfortable and unsettling.
As an alternative, the researchers created spheres of silica and filled them with perfluoropentane, a gas that has been used before in short-lived contrast materials for medical imaging. The rigid silica shells help the new material last longer.
"These little gas-filled microbubbles stick to human breast tissue for days and can be seen with ultrasound," said William Trogler, professor of chemistry. "If doctors placed them in early stage breast cancer, which is difficult to see during surgery, they could help surgeons remove all of it in the first operation."
In the past few years, radiologists have tried implanting radioactive "seeds" instead of wires to mark tumours, but the seeds last only a few hours and must be inserted with a large-bore needle, which is painful. In addition, only one abnormal region can be marked, but patients with a form of breast cancer called ductal in situ carcinoma often have several. The seeds also expose both patient and staff to radiation, can't been imaged in three dimensions and create radioactive medical waste.
At just two micrometers in diameter – half the width of a strand of spider silk – small silica microbubbles can be precisely injected into clusters of abnormal cells using a thin needle. Radiologists would be able to inject the durable material days before surgery. And ultrasound scans reveal the position of the bubble in three dimensions on the operating table.
"Instead of just using a Geiger-counterlike device to say you're getting closer to the radioactive seed, you could actually see where to carve," said Andrew Kummel, professor of chemistry. The increased precision should help surgeons avoid the need for second surgeries.
"By outlining the tumour more completely in multiple directions, the particles could potentially help surgeons remove non-palpable tumours in a single operation," said Sarah Blair, a surgeon at Moores UCSD Cancer Center. "They will definitely make the operation more comfortable for patients."
The researchers think the ultrasound pressure waves burst the microbubbles. "They're thin, fragile balls of porous glass, like Christmas tree ornaments," Kummel said. "The shell is just one two-hundredth of the diameter of the ball. When it breaks, the gas squirts out. Doppler ultrasound detects that movement."
Nano-scale silica microbubbles, which the team reports in this paper as well, are too small to remain in place, but might drain from a cancerous site to help identify which lymph nodes are most likely to contain stray cells that could help the cancer spread.
MEDICA.de; Source: University of California -- San Diego