According to the research conducted by the U.S. Department of Energy's Brookhaven National Laboratory and colleagues at Stony Brook University , the IRCCS Neuromed Medical Center in Italy, and Georgetown University it was found that improvements in the existing radiation therapy led to more effective treatment. This then could be widely used in the hospital scenario.
These improved techniques were initially tested on rats and the results of the study are published in the Proceedings of the National Academy of Sciences. The technique, microbeam radiation therapy (MRT), previously used a high-intensity synchrotron x-ray source such as a superconducting wiggler at Brookhaven's National Synchrotron Light Source (NSLS) to produce parallel arrays of very thin (25 to 90 micrometers) planar x-ray beams (picture the parallel panels of window blinds in the open position) instead of the unsegmented (solid), broad beams used in conventional radiation treatment. Previous studies conducted at Brookhaven and at the European Synchrotron Radiation Facility (ESRF) in Grenoble, France demonstrated MRT's ability to control malignant tumors in animals with high radiation doses while subjecting adjacent normal tissue to little collateral damage.
But the technique has limitations. For one thing, only certain synchrotrons can generate its very thin beams at adequate intensity, and such facilities are available at only a few research centers around the world. 'The new development seeks a way out of this situation,' explained Brookhaven scientist Avraham Dilmanian, lead author of the new study. In this paper, the scientists report results that demonstrate the potential efficacy of significantly thicker microbeams, as well as a way to 'interlace' the beams within a well-defined 'target' inside the subject to increase their killing potential there, while retaining the technique's hallmark feature of sparing healthy tissue outside that target. First, they exposed the spinal cords and brains of healthy rats to thicker (0.27 to 0.68 millimeter) microbeams at high doses of radiation and monitored the animals for signs of tissue damage.
For interlacing, the gaps between the beams in each array were chosen to be the same as the thickness of each beam, so the beams from one array would fill the gaps in the other to produce the equivalent of an unsegmented beam in the target volume only. 'In this way we are effectively delivering an unsegmented broad beam type of dose to just the target region -- which could be a tumor, or a non-tumerous target we want to ablate -- while exposing the surrounding tissue to segmented radiation from which it can recover,' Dilmanian said. The MRI scans showed that at a particular dose of radiation, the new configuration could produce major damage to the target volume but virtually no damage beyond the target range.
'The dose of radiation delivered to the target volume would have been enough to ablate a malignant tumor,' Dilmanian said. 'These results show that thick microbeams generated by special x-ray tubes in hospitals could eventually be used to destroy selective targets while sparing healthy tissue,' Dilmanian said. Said collaborator Eliot Rosen, a radiation oncologist at Lombardi Comprehensive Cancer Center, Georgetown University, 'This form of microbeam radiation therapy could improve the treatment of many forms of cancer now treated with radiation, because it can deliver a more lethal dose to the tumor while minimizing damage to surrounding healthy tissue. It may also extend the use of radiation to cases where it is now used only judiciously, such as brain cancer in patients under three years of age, because of the high sensitivity of young brain tissue to radiation.' And according to collaborators David Anschel, a neurologist at Stony Brook University and Brookhaven Lab, and Pantaleo Romanelli, a neurosurgeon from NEUROMED Medical Center, the technique may also have applications in treating a wide range of benign and malignant brain tumors and other functional brain disorders such as epilepsy and Parkinson's disease.