Steven Bishay, W. Hudson Robb, Trent M. Schwartz, David S. Smith, Lok Hin Lee, Cynthia J. Lynn, Tammy L. Clark, Angela L. Jefferson, Jeremy L. Warner, Eben L. Rosenthal, Barbara A. Murphy, Timothy J. Hohman, Mary Ellen I. Koran
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引用次数: 0
摘要
背景和目的:癌症治疗后对神经系统的不良影响很常见,但用于诊断、监测或对患者进行风险分层的生物标志物仍未得到验证或临床应用。脑部氟脱氧葡萄糖正电子发射断层扫描(FDG PET)等简便易行的成像方法可以填补这一空白,并可作为脑部功能变化的生物标志物。我们利用 FDG PET 评估了头颈癌(HNCa)患者化疗后哪些脑区最容易发生糖代谢改变:方法:在68例HNCa患者化疗前后,作为标准治疗方法采集了真实世界的FDG PET图像。线性混合效应体表模型评估了化疗后以标准化摄取值比(SUVR)量化的脑葡萄糖代谢的变化,并与随访时间和患者人口统计学特征进行了协整:体素分析显示,化疗后,额叶内侧和颞叶两极皮层的葡萄糖代谢下降,治疗后SUVR下降约5%:这些研究结果为HNCa的标准化疗可导致神经元葡萄糖代谢下降提供了证据,为强调额叶和颞叶前部的脆弱性的文献做出了贡献,尤其是在HNCa中,这些区域可能特别容易受到间接辐射诱导的损伤。FDG PET有望成为评估这些变化的灵敏生物标记物。
Frontal and anterior temporal hypometabolism post chemoradiation in head and neck cancer: A real-world PET study
Background and Purpose
Adverse neurological effects after cancer therapy are common, but biomarkers to diagnose, monitor, or risk stratify patients are still not validated or used clinically. An accessible imaging method, such as fluorodeoxyglucose positron emission tomography (FDG PET) of the brain, could meet this gap and serve as a biomarker for functional brain changes. We utilized FDG PET to evaluate which brain regions are most susceptible to altered glucose metabolism after chemoradiation in patients with head and neck cancer (HNCa).
Methods
Real-world FDG PET images were acquired as standard of care before and after chemoradiation for HNCa in 68 patients. Linear mixed-effects voxelwise models assessed changes after chemoradiation in cerebral glucose metabolism quantified with standardized uptake value ratio (SUVR), covarying for follow-up time and patient demographics.
Results
Voxelwise analysis revealed two large clusters of decreased glucose metabolism in the medial frontal and polar temporal cortices following chemoradiation, with decreases of approximately 5% SUVR after therapy.
Conclusions
These findings provide evidence that standard chemoradiation for HNCa can lead to decreased neuronal glucose metabolism, contributing to literature emphasizing the vulnerability of the frontal and anterior temporal lobes, especially in HNCa, where these areas may be particularly vulnerable to indirect radiation-induced injury. FDG PET shows promise as a sensitive biomarker for assessing these changes.
期刊介绍:
Start reading the Journal of Neuroimaging to learn the latest neurological imaging techniques. The peer-reviewed research is written in a practical clinical context, giving you the information you need on:
MRI
CT
Carotid Ultrasound and TCD
SPECT
PET
Endovascular Surgical Neuroradiology
Functional MRI
Xenon CT
and other new and upcoming neuroscientific modalities.The Journal of Neuroimaging addresses the full spectrum of human nervous system disease, including stroke, neoplasia, degenerating and demyelinating disease, epilepsy, tumors, lesions, infectious disease, cerebral vascular arterial diseases, toxic-metabolic disease, psychoses, dementias, heredo-familial disease, and trauma.Offering original research, review articles, case reports, neuroimaging CPCs, and evaluations of instruments and technology relevant to the nervous system, the Journal of Neuroimaging focuses on useful clinical developments and applications, tested techniques and interpretations, patient care, diagnostics, and therapeutics. Start reading today!
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