A novel Electron Paramagnetic Resonance (EPR) oximetry technique will help clinicians directly measure oxygen and schedule treatments at times of high oxygen levels in cancer and stroke patients to improve outcomes, The EPR team at Dartmouth's Geisel School of Medicine has found.
Led by Harold Swartz, MD, PhD, the team published their groundbreaking progress on the decades-old conundrum of how to measure oxygenation in deep-sited tissue in a paper titled, "Deep-Tissue Oxygen Monitoring in the Brain of Rabbits for Stroke Research," published in Stroke.
"This is a major step forward," said first author Nadeem Khan, PhD, "It brings EPR oximetry technique to the forefront of biomedical research for clinical applications."
Oxygen is necessary to sustain life. A certain level of oxygen in a cell or tissue is necessary to maintain normal processes, such as the generation of energy by cells. Oxygen also plays a pivotal role in the development and treatment of various diseases. The effectiveness of several therapies also depends on the oxygen levels in a malignancy. For example, a very low level of oxygen in cancer (solid tumors) is known to develop aggressive phenotypes, varies with the growth of tumors, and also compromises the effectiveness of chemotherapy and radiation. Therefore, it is very important to directly measure oxygen levels to understand disease progression, develop strategies to improve oxygen levels, and optimize the efficacy of therapies.
Oxygen measurement in deep-sited tissue has been a challenge for several techniques, which has unfortunately limited the understanding of various pathologies in large animals and humans. To solve the problem, Dartmouth's EPR team developed implantable resonators made of thin nonmagnetic copper wire to facilitate direct and repeated measurement of tissue oxygenation at any depth from the surface. In their most recent experiment, which demonstrated the efficacy of in vivo EPR oximetry, they used a one-time implementation of the oxygen probes in the brain of a rabbit and successfully monitored oxygen levels for several weeks.
"Other than the implantation, which is done under anesthesia, the rest of the procedure for oxygen measurements is entirely non-invasive," explained Khan. "We anticipate that a better understanding of oxygen levels in stroke, for instance, will guide the development of strategies to significantly improve oxygen levels in the ischemic regions of the brain and thereby improve outcomes."
The investigators conclude that real-time monitoring of tissue oxygenation using implantable resonators will be a powerful tool in stroke and cancer research. In clinics, physicians will ultimately use the measurement of oxygen in tumors, or the brain, to guide decisions about best times for therapy. Development of "oxygen-guided" protocols to improve treatment outcome in patients will continue with the EPR team's latest National Cancer Institute funded multi-million dollar study, which will commence in March 2015 under the leadership of Dr. Swartz. A second line of research for the team is investigating the dynamics of cerebral oxygenation following stroke, making oxygenation of the brain a strategic therapy that will save vital brain tissue from dying.
Materials provided by Norris Cotton Cancer Center Dartmouth-Hitchcock Medical Center. Note: Content may be edited for style and length.
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