Department of Physics and Astronomy, University of Pennsylvania, 209 South 33rd Street, Philadelphia, PA 19104, USA.
Neurocrit Care. 2010 Apr;12(2):173-80. doi: 10.1007/s12028-009-9305-x.
This study assesses the utility of a hybrid optical instrument for noninvasive transcranial monitoring in the neurointensive care unit. The instrument is based on diffuse correlation spectroscopy (DCS) for measurement of cerebral blood flow (CBF), and near-infrared spectroscopy (NIRS) for measurement of oxy- and deoxy-hemoglobin concentration. DCS/NIRS measurements of CBF and oxygenation from frontal lobes are compared with concurrent xenon-enhanced computed tomography (XeCT) in patients during induced blood pressure changes and carbon dioxide arterial partial pressure variation.
Seven neurocritical care patients were included in the study. Relative CBF measured by DCS (rCBF(DCS)), and changes in oxy-hemoglobin (DeltaHbO(2)), deoxy-hemoglobin (DeltaHb), and total hemoglobin concentration (DeltaTHC), measured by NIRS, were continuously monitored throughout XeCT during a baseline scan and a scan after intervention. CBF from XeCT regions-of-interest (ROIs) under the optical probes were used to calculate relative XeCT CBF (rCBF(XeCT)) and were then compared to rCBF(DCS). Spearman's rank coefficients were employed to test for associations between rCBF(DCS) and rCBF(XeCT), as well as between rCBF from both modalities and NIRS parameters.
rCBF(DCS) and rCBF(XeCT) showed good correlation (r (s) = 0.73, P = 0.010) across the patient cohort. Moderate correlations between rCBF(DCS) and DeltaHbO(2)/DeltaTHC were also observed. Both NIRS and DCS distinguished the effects of xenon inhalation on CBF, which varied among the patients.
DCS measurements of CBF and NIRS measurements of tissue blood oxygenation were successfully obtained in neurocritical care patients. The potential for DCS to provide continuous, noninvasive bedside monitoring for the purpose of CBF management and individualized care is demonstrated.
本研究评估了一种混合光学仪器在神经重症监护病房中非侵入性经颅监测的效用。该仪器基于漫反射相关光谱(DCS)测量脑血流(CBF),以及近红外光谱(NIRS)测量氧合和脱氧血红蛋白浓度。在诱导血压变化和二氧化碳动脉分压变化期间,与同时进行的氙增强计算机断层扫描(XeCT)相比,对前额叶的 DCS/NIRS 测量的 CBF 和氧合进行比较。
本研究纳入了 7 名神经重症监护病房患者。通过 DCS 测量的相对 CBF(rCBF(DCS)),以及通过 NIRS 测量的氧合血红蛋白(DeltaHbO(2))、脱氧血红蛋白(DeltaHb)和总血红蛋白浓度(DeltaTHC)的变化,在 XeCT 基线扫描和干预后扫描期间,通过光学探头连续监测。将来自光学探头下 XeCT 感兴趣区域(ROI)的 CBF 用于计算相对 XeCT CBF(rCBF(XeCT)),然后将其与 rCBF(DCS)进行比较。采用 Spearman 秩相关系数检验 rCBF(DCS)与 rCBF(XeCT)之间、以及两种模态与 NIRS 参数之间的相关性。
整个患者队列中,rCBF(DCS)和 rCBF(XeCT)显示出良好的相关性(r(s)=0.73,P=0.010)。rCBF(DCS)与 DeltaHbO(2)/DeltaTHC 之间也观察到中度相关性。NIRS 和 DCS 均能区分氙气吸入对 CBF 的影响,而这种影响在患者之间存在差异。
在神经重症监护病房患者中成功获得了 DCS 测量的 CBF 和 NIRS 测量的组织血氧饱和度。DCS 有可能提供连续的、非侵入性的床边监测,用于 CBF 管理和个体化护理。
