用于连续监测新生儿脑血流和氧合的无纤维可穿戴光纤传感器。
Wearable fiber-free optical sensor for continuous monitoring of neonatal cerebral blood flow and oxygenation.
机构信息
Department of Biomedical Engineering, University of Kentucky, Lexington, KY, USA.
Biostatistics and Bioinformatics Shared Resource Facility, Markey Cancer Center, University of Kentucky, Lexington, KY, USA.
出版信息
Pediatr Res. 2024 Jul;96(2):486-493. doi: 10.1038/s41390-024-03137-z. Epub 2024 Mar 19.
BACKGROUND
Unstable cerebral hemodynamics places preterm infants at high risk of brain injury. We adapted an innovative, fiber-free, wearable diffuse speckle contrast flow-oximetry (DSCFO) device for continuous monitoring of both cerebral blood flow (CBF) and oxygenation in neonatal piglets and preterm infants.
METHODS
DSCFO uses two small laser diodes as focused-point and a tiny CMOS camera as a high-density two-dimensional detector to detect spontaneous spatial fluctuation of diffuse laser speckles for CBF measurement, and light intensity attenuations for cerebral oxygenation measurement. The DSCFO was first validated against the established diffuse correlation spectroscopy (DCS) in neonatal piglets and then utilized for continuous CBF and oxygenation monitoring in preterm infants during intermittent hypoxemia (IH) events.
RESULTS
Significant correlations between the DSCFO and DCS measurements of CBF variations in neonatal piglets were observed. IH events induced fluctuations in CBF, cerebral oxygenation, and peripheral cardiorespiratory vitals in preterm infants. However, no consistent correlation patterns were observed among peripheral and cerebral monitoring parameters.
CONCLUSIONS
This pilot study demonstrated the feasibility of DSCFO technology to serve as a low-cost wearable sensor for continuous monitoring of multiple cerebral hemodynamic parameters. The results suggested the importance of multi-parameter measurements for understanding deep insights of peripheral and cerebral regulations.
IMPACT
The innovative DSCFO technology may serve as a low-cost wearable sensor for continuous bedside monitoring of multiple cerebral hemodynamic parameters in neonatal intensive care units. Concurrent DSCFO and DCS measurements of CBF variations in neonatal piglet models generated consistent results. No consistent correlation patterns were observed among peripheral and cerebral monitoring parameters in preterm neonates, suggesting the importance of multi-parameter measurements for understanding deep insights of peripheral and cerebral regulations during IH events. Integrating and correlating multiple cerebral functional parameters with clinical outcomes may identify biomarkers for prediction and management of IH associated brain injury.
背景
不稳定的脑血流动力学使早产儿面临高风险的脑损伤。我们为新生儿小猪和早产儿设计了一种创新的、无纤维的、可穿戴的弥散散斑对比血流氧饱和度(DSCFO)设备,用于连续监测脑血流(CBF)和氧合。
方法
DSCFO 使用两个小的激光二极管作为聚焦点,以及一个微小的 CMOS 相机作为高密度二维探测器,用于检测 CBF 测量的弥散激光散斑的自发空间波动,以及脑氧合测量的光强度衰减。DSCFO 首先在新生小猪中与已建立的弥散相关光谱(DCS)进行了验证,然后在间歇性低氧血症(IH)事件中用于监测早产儿的连续 CBF 和氧合。
结果
在新生小猪中,DSCFO 和 DCS 对 CBF 变化的测量之间存在显著的相关性。IH 事件引起了早产儿 CBF、脑氧合和周围心肺生命体征的波动。然而,在周围和大脑监测参数之间没有观察到一致的相关模式。
结论
这项初步研究表明,DSCFO 技术具有作为一种低成本的可穿戴传感器,用于连续监测多个脑血流动力学参数的可行性。结果表明,多参数测量对于理解外周和大脑调节的深入了解非常重要。
影响
创新的 DSCFO 技术可作为新生儿重症监护病房中多个脑血流动力学参数的连续床边监测的低成本可穿戴传感器。在新生小猪模型中,DSCFO 和 DCS 对 CBF 变化的同时测量产生了一致的结果。在早产儿中,周围和大脑监测参数之间没有观察到一致的相关模式,这表明在 IH 事件中,多参数测量对于理解外周和大脑调节的深入了解非常重要。整合和关联多个大脑功能参数与临床结果可能有助于识别与 IH 相关脑损伤的预测和管理的生物标志物。
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