Abstract
This study explored using a novel diffuse correlation spectroscopy (DCS) flow-oximeter to noninvasively monitor blood flow and oxygenation changes in head and neck tumors during radiation delivery. A fiber-optic probe connected to the DCS flow-oximeter was placed on the surface of the radiologically/clinically involved cervical lymph node. The DCS flow-oximeter in the treatment room was remotely operated by a computer in the control room. From the early measurements, abnormal signals were observed when the optical device was placed in close proximity to the radiation beams. Through phantom tests, the artifacts were shown to be caused by scattered x rays and consequentially avoided by moving the optical device away from the x-ray beams. Eleven patients with head and neck tumors were continually measured once a week over a treatment period of seven weeks, although there were some missing data due to the patient related events. Large inter-patient variations in tumor hemodynamic responses were observed during radiation delivery. A significant increase in tumor blood flow was observed at the first week of treatment, which may be a physiologic response to hypoxia created by radiation oxygen consumption. Only small and insignificant changes were found in tumor blood oxygenation, suggesting that oxygen utilizations in tumors during the short period of fractional radiation deliveries were either minimal or balanced by other effects such as blood flow regulation. Further investigations in a large patient population are needed to correlate the individual hemodynamic responses with the clinical outcomes for determining the prognostic value of optical measurements.
Highlights
Head and neck cancer accounts for about 3 to 5% of all cancers in the United States [1]
Recent investigations using polarographic electrode, magnetic resonance imaging (MRI), dynamic computed tomography (CT) and 133Xe clearance method have shown that tumor hemodynamic parameters changed over the period of radiation therapy and less-perfused tumors responded poorly [13,14,15,16,17,18]
Based on the source-detector (S-D) separation of 2.5 cm set in our fiber-optic probe, we included only Stage III-IVb SCCHN with a cervical tumor node larger than 2 cm detected by CT/positron emission tomography (PET)/MRI scan and either clinically palpable or ultrasound defined
Summary
Head and neck cancer accounts for about 3 to 5% of all cancers in the United States [1]. Radiation therapy is a principal modality in the treatment of head and neck cancers. Studies using polarographic electrode have exhibited an increase of positive response to radiation therapy in tumors with high pretreatment oxygenation compared to poorly oxygenated tumors [8,9,10,11,12]. In these studies some well-oxygenated tumors failed to respond while some hypoxic tumors responded well, possibly due to the changes in tumor oxygen status during radiation treatment. Functional assessment of tumor oxygenation and blood flow changes during radiation therapy may help understand radiation pathology and holds potential for the prediction of therapy outcomes
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