The findings come from cell biologist Dmitri Lapotko, who leads a Rice University lab called The Nanobubble Lab. Lapotko has found that when colloidal gold nanoparticles inside the body meet with a quick zap from a near-infrared laser, they burst and create a short-lived bubble that can blow up the cells around it.
Here’s what happened. The bubbles first blew up many of the cancer cells. Those that remained got another payload from the nanoparticles: chemotherapy drugs. With cell membranes damaged by the micro-explosion, the pharmaceutical payloads went directly into the cell cytoplasm. The remaining particles, clustered in the cancerous area, also served to magnify the X-rays delivering radiation.
Lapotko has dubbed the treatment regimen quadrapeutics for its four component parts: nanoparticles, laser, drugs and radiation.
“We literally bring surgery, chemotherapies and radiation therapies inside cancer cells,” Lapotko said in a news release.
The method proved so deadly against head and neck squamous cell carcinomas that in a single treatment with just 3 percent of the normal drug dose and 6 percent of the standard radiation dose effectively eliminated tumors within a week. Equally important, the nanoparticles are too small to damage healthy cells around the area targeted with the laser detonator.
“Surgeons often cannot fully remove tumors that are intertwined with important organs. Chemotherapy and radiation are commonly used to treat the residual portions of these tumors, but some tumors become resistant to chemoradiation. Quadrapeutics steps up when standard treatments fail,” said Lapotko.
Lapotko’s method benefits from previous work, much of it at Rice, with gold nanoparticles and lasers. But the focus on the destructive power of bubbles that can be produced locally and on demand is unique. The bubbles allow the nanoparticles to bring both chemical weapons (drugs) and conventional weapons (bombs) to the cancer’s hideout.
Will nanobubbles fight cancer in real patients as well as they did in mice? MD Anderson Cancer Center will likely conduct clinical trials of the quadrapeutics method in the coming months. The approach can be applied to various types of cancer that form solid tumors, Lapotko says.
Curiously, in his work producing and popping nanobubbles, Lapotko also stumbled across a bloodless and effective way to detect malaria. It turns out that the parasite’s waste contains a nanocrystal that will also create a nanobubble when heated with a laser pulse. Listening for the signature pop alerts lab clinicians to the presence of the malaria parasite. Gold bullet indeed!
Photos: Ed Uthman / Wikimedia Commons, Rice University, © Looney Tunes; featured image Dimtri Lapotko / Rice University