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PET scan shows during treatment if radiation is shrinking lung tumor, U-M study shows
Finding suggests treatment could be changed early if tumor not respondingadded 7/19/07
Ann Arbor - Lung cancer patients may not need to wait till their radiation treatment is over to know if it worked. A PET scan several weeks after starting radiation treatment for lung cancer can indicate whether the tumor will respond to the treatment, according to a new study by researchers at the University of Michigan Comprehensive Cancer Center.Traditionally, PET, or positron emission tomography, has been used after radiation treatment for lung cancer to assess whether the tumor responded to treatment and whether the patients will have a chance of being cured. Using PET several weeks into treatment, researchers found a strong correlation between tumor responses during treatment and response three months after completion of the treatment. This could potentially allow doctors to change the radiation treatment plan before treatment ends to improve the outcome.
Results of the study appear in the July 20 issue of the Journal of Clinical Oncology.
"This demonstrates that PET scans can be performed earlier during the course of radiation treatment, which will allow us to modify the treatment regimen before the treatment is completed. Our sample size was small, but the results are very promising," says lead study author Feng-Ming Kong, M.D., Ph.D., assistant professor of radiation oncology at the U-M Medical School, and chief of radiation oncology service at the Ann Arbor VA Healthcare System.
In a pilot study of 15 people with early-stage non-small-cell lung cancer, researchers administered FDG-PET scans before beginning radiation therapy, three to four weeks into a six-week course of treatment, and three months after completing treatment. An FDG-PET scan uses radioactive labeled glucose, which is drawn to cells that are active. Tumors that are responding to radiation treatment show decreased FDG activity in the cells.
The concern in the past has been that radiation might stimulate the normal lung tissue surrounding the tumor to take up glucose, which might obscure the PET image of the tumor. Kong's study found this was not an issue.
"The confounding effect on normal tissue is actually less of an issue during treatment than it is after treatment, which is a big surprise. We always assumed the confounding effect would be worse during treatment," Kong says. She says this finding makes sense, as normal lung tissue is slow to react to the assault of radiation therapy and typically there is a delay before lung inflammations or other problems develop.
"Our results show that it is better to perform the PET scan during the course of treatment instead of months after treatment. It avoids the normal tissue confounding effect and offers the potential for the radiation oncologist to modify the doses if necessary," Kong says.
The researchers are continuing to study PET scans in a larger number of patients to verify the pilot findings. The next step is to assess whether changing the treatment regimen based on mid-treatment PET scan findings would lead to better tumor control and survival rates. If continued studies bear out the initial data, Kong is hopeful this work could eventually lead to a change in standard practice guidelines regarding PET for lung cancer.
Some 213,380 people will be diagnosed with lung cancer this year, and 160,390 people will die from the disease, according to the American Cancer Society. For information about lung cancer, visit the cancer center's lung cancer information page or call the U-M Cancer AnswerLine™ at 800-865-1125.
In addition to Kong, University of Michigan study authors are Kirk Frey, M.D., Ph.D., professor of neurology and radiology and chief of nuclear medicine; Leslie Quint, M.D., professor of radiology; Randall Ten Haken, Ph.D., professor of radiation oncology; James Hayman, M.D., M.B.A., associate professor of radiation oncology; Marc Kessler, Ph.D., associate professor of radiation oncology; Indrin Chetty, Ph.D., formerly of U-M and now at the University of Nebraska Medical Center; Daniel Normolle, Ph.D., associate professor of radiation oncology; Avraham Eisbruch, M.D., professor of radiation oncology; and Theodore Lawrence, M.D., Ph.D., Isadore Lampe Professor and chair of radiation oncology. Many others supported this project, including Benedict Fraass Ph.D., Gregory P. Kalemkerian M.D. and Dean Brenner M.D.
Funding for the study is from a Young Investigator Award of the American Society of Clinical Oncology, the Radiological Society of North America Seed Grant Program>, the Pardee Foundation and the National Institutes of Health.
Reference: Journal of Clinical Oncology, Vol. 25, No. 21, July 20, 2007
Written by Nicole Fawcett