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UC Davis researchers use heated nanoprobes to destroy breast cancer cells in mice
March 07, 2007Next step will be testing in cancer patients
(SACRAMENTO, Calif.) — In experiments with laboratory mice that bear aggressive human breast cancers, UC Davis researchers have used hot nanoprobes to slow the growth of tumors — without damage to surrounding healthy tissue. The researchers describe their work in the March issue of the Journal of Nuclear Medicine.
"We have demonstrated that the system is feasible in laboratory mice. The next step will be clinical testing in patients," said Sally DeNardo, a professor of internal medicine and radiology at UC Davis and lead author of the study.
Many researchers have studied heat as a potential treatment for cancer, but the difficulty of confining heat within the tumor and predicting an effective heat dose has limited its use. The UC Davis research, carried out in collaboration with scientists from Triton BioSystems in Boston, seeks to solve this problem.
The experimental system uses bioprobes created by wedding magnetized iron-oxide nanospheres to radiolabeled monoclonal antibodies. The bioprobes are cloaked in polymers and sugars that render them nearly invisible to the body's immune system.
DeNardo and her colleagues infused trillions of the probes — more than 10,000 can fit on the end of a straight pin — into the bloodstreams of laboratory mice bearing human breast tumors. Once in the bloodstream, the probes began to seek out and latch onto receptors on the surface of malignant cells.
Three days later, the team applied an alternating magnetic field to the tumor region, causing the magnetic nanospheres latched onto the tumor cells to change polarity thousands of times per second, instantaneously generating heat. As soon as the AMF stopped, the bioprobes cooled down.
Mice in the study received a series of AMF bursts in a single 20-minute treatment. Dosing was calculated using an equation that included tumor concentration of bioprobes, heating rate of particles at different amplitudes, and the spacing of AMF bursts.
Tumor growth rate slowed in the treated animals, a response that correlated closely with heat dose. No toxicity related to the bioprobes was observed.
"Using heat to kill cancer cells isn't a new concept," DeNardo said. "The biggest problems have been how to apply it to the tumor alone, how to predict the amount needed and how to determine its effectiveness. By combining nanotechnology, focused AMF therapy and quantitative molecular imaging techniques, we have developed a safer technique that could join other modalities as a treatment for breast and other cancers."
University of California, Davis-Health System
Many researchers have studied heat as a potential treatment for cancer, but the difficulty of confining heat within the tumor and predicting an effective heat dose has limited its use. The UC Davis research, carried out in collaboration with scientists from Triton BioSystems in Boston, seeks to solve this problem.
The experimental system uses bioprobes created by wedding magnetized iron-oxide nanospheres to radiolabeled monoclonal antibodies. The bioprobes are cloaked in polymers and sugars that render them nearly invisible to the body's immune system.
DeNardo and her colleagues infused trillions of the probes — more than 10,000 can fit on the end of a straight pin — into the bloodstreams of laboratory mice bearing human breast tumors. Once in the bloodstream, the probes began to seek out and latch onto receptors on the surface of malignant cells.
Three days later, the team applied an alternating magnetic field to the tumor region, causing the magnetic nanospheres latched onto the tumor cells to change polarity thousands of times per second, instantaneously generating heat. As soon as the AMF stopped, the bioprobes cooled down.
Mice in the study received a series of AMF bursts in a single 20-minute treatment. Dosing was calculated using an equation that included tumor concentration of bioprobes, heating rate of particles at different amplitudes, and the spacing of AMF bursts.
Tumor growth rate slowed in the treated animals, a response that correlated closely with heat dose. No toxicity related to the bioprobes was observed.
"Using heat to kill cancer cells isn't a new concept," DeNardo said. "The biggest problems have been how to apply it to the tumor alone, how to predict the amount needed and how to determine its effectiveness. By combining nanotechnology, focused AMF therapy and quantitative molecular imaging techniques, we have developed a safer technique that could join other modalities as a treatment for breast and other cancers."
University of California, Davis-Health System
Nanoscopic probes can track down and attack cancer cells
A researcher has developed probes that can help pinpoint the location of tumors and might one day be able to directly attack cancer cells.
Are nanobots on their way?
The first real steps towards building a microscopic device that can construct nano machines have been taken by US researchers. Writing in the peer-reviewed publication, International Journal of Nanomanufacturing from Inderscience Publishers, researchers describe an early prototype for a nanoassembler.
Breast Cancer Treatment Heats Up
In the March Journal of Nuclear Medicine, researchers demonstrate that miniscule bioprobes could be produced and used with molecularly targeted therapeutic heat to kill malignant breast cancer cells—without damaging nearby healthy tissue.
Nanomedicine: Grounds for optimism and a call for papers (p 673)
Issue 30 August 2003 Embargoed 0001 h (London time) 29 August 2003. 'Nanomedicine is a discipline whose time has come', states this week's editorial. Nanoscience and the implications for medicine has recently been the focus of the US National Institutes of Health who have highlighted three key areas for the future of nanomedicine: structures and devices whose small size-between 1 and 100 nm-confers novel properties that have applications in disease diagnosis, treatment, or prevention; the manufacture of devices to identify nanosize entities of medical importance; and nanoscale biological systems that might have clinical applications. The potential benefits of nanomedicine are outlined:
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