PET Imaging Adds Valuable Information to Brain Metastasis Monitoring
After radiosurgery concurrent with nivolumab in 59-year-old patient with melanoma BM (patient 1; Supplemental Tables 3 and 5), F-18 FET PET at follow-up 12 weeks after treatment initiation (bottom row) shows significant decrease of metabolic activity (TBRmean, ?28%) compared with baseline (top row), although MRI changes were consistent with progression according to iRANO criteria. Reduction of metabolic activity was associated with stable clinical course over 10 mo. CE = contrast-enhanced. Image created by N. Galldiks et al., Research Center Juelich, Juelich, Germany.
May 5, 2021 For patients with brain metastases, amino acid positron emission tomography (PET) can provide valuable information about the effectiveness of state-of-the-art treatments. When treatment monitoring with contrast-enhanced magnetic resonance imaging (MRI) is unclear, adding 18F-FET PET can help to accurately diagnose recurring brain meta
E-Mail
IMAGE: After radiosurgery concurrent with nivolumab in 59-year-old patient with melanoma BM (patient 1; Supplemental Tables 3 and 5), F-18 FET PET at follow-up 12 weeks after treatment initiation (bottom row). view more
Credit: Image created by N. Galldiks et al., Research Center Juelich, Juelich, Germany.
Reston, VA For patients with brain metastases, amino acid positron emission tomography (PET) can provide valuable information about the effectiveness of state-of-the-art treatments. When treatment monitoring with contrast-enhanced magnetic resonance imaging (MRI) is unclear, adding 18F-FET PET can help to accurately diagnose recurring brain metastases and reliably assess patient response. This research was published in The
Journal of Nuclear Medicine.
Clifton, NJ (PRWEB) May 03, 2021 Integrated Medical Communications is proud to announce the inaugural issue of a magazine focused on the most up-to-date
Review outlines ways to effectively deliver radiotherapy to optimize benefit and minimize risk
A comprehensive review by University of North Carolina researchers and colleagues highlights the optimal ways that focused, high-dose radiation can be delivered to various types of tumors while sparing normal tissue and mitigating long-term side effects. The review was reported as a special issue in the
International Journal of Radiation Oncology, Biology, Physics on May 1, 2021.
This analysis was based on an exhaustive review of data and the literature published largely in the past decade. It updates an earlier review that primarily focused on the effects of conventional radiation therapy on normal tissue. This new review also includes important analyses of how well high-dose radiation can destroy small tumors, such as small brain lesions, lung lesions, and cancers that metastasize to other parts of the body.
E-Mail
IMAGE: UNC Lineberger Comprehensive Cancer Center s Lawrence Marks, MD, and colleagues have published a comprehensive review that highlights the optimal ways that focused, high-dose radiation can be delivered to various types. view more
Credit: UNC Health
CHAPEL HILL, North Carolina A comprehensive review by University of North Carolina researchers and colleagues highlights the optimal ways that focused, high-dose radiation can be delivered to various types of tumors while sparing normal tissue and mitigating long-term side effects. The review was reported as a special issue in the
International Journal of Radiation Oncology, Biology, Physics on May 1, 2021.
This analysis was based on an exhaustive review of data and the literature published largely in the past decade. It updates an earlier review that primarily focused on the effects of conventional radiation therapy on normal tissue. This new review also includes important analyses of how well high-dose ra