Sadleir R J, Tang Te
Department of Biomedical Engineering, University of Florida, Gainesville, FL 32601, USA.
Physiol Meas. 2009 Jan;30(1):63-79. doi: 10.1088/0967-3334/30/1/005. Epub 2008 Dec 15.
Intraventricular haemorrhage is a common cause of death in premature human infants. As preventative measures and treatments become available, a method for monitoring and detection is required. Electrical impedance tomography (EIT) is a viable monitoring method compared to modalities such as ultrasound, MRI or CT because of its low cost and contrast sensitivity to blood. However, its sensitivity to blood may be obscured by the low conductivity skull, high conductivity cerebrospinal fluid (CSF) and shape changes in the head and body. We estimated the sensitivity of three 16-electrode and impedance measurement configurations to bleeding using both idealized spherical and realistic geometry three-dimensional finite element models of the neonatal head. Sensitivity distribution responses to alterations in skull composition as well as introduction of conductivity anomalies were determined. Of the three patterns tested, a measurement scheme that employed electrodes at locations based on the 10-20 EEG layout, and impedance measurements involving current return over the anterior fontanelle produced superior distinguishabilities in regions near the lateral ventricles. This configuration also showed strongly improved sensitivities and selectivities when skull composition was varied to include the anterior fontanelle. A pattern using electrodes placed in a ring about the equator of the model had similar sensitivities but performed worse than the EEG layout in terms of selectivity. The third pattern performed worse than either the Ring or EEG-based patterns in terms of sensitivity. The overall performance of the EEG-based pattern on a spherical homogeneous model was maintained in a sensitivity matrix calculated using a homogeneous realistic geometry model.
脑室内出血是人类早产儿常见的死亡原因。随着预防措施和治疗方法的出现,需要一种监测和检测方法。与超声、MRI或CT等方式相比,电阻抗断层成像(EIT)因其成本低且对血液具有对比度敏感性,是一种可行的监测方法。然而,其对血液的敏感性可能会被低导电性的颅骨、高导电性的脑脊液(CSF)以及头部和身体的形状变化所掩盖。我们使用新生儿头部的理想化球形和真实几何三维有限元模型,估计了三种16电极和阻抗测量配置对出血的敏感性。确定了对颅骨成分变化以及电导率异常引入的敏感性分布响应。在测试的三种模式中,一种基于10-20脑电图布局在特定位置使用电极,并在前囟门上进行电流回流的阻抗测量方案,在侧脑室附近区域产生了更好的区分能力。当颅骨成分变化以包括前囟门时,这种配置还显示出敏感性和选择性的显著提高。一种在模型赤道周围放置电极环的模式具有相似的敏感性,但在选择性方面比脑电图布局表现更差。第三种模式在敏感性方面比基于环或脑电图的模式表现更差。基于脑电图的模式在球形均匀模型上的整体性能在使用均匀真实几何模型计算的敏感性矩阵中得以保持。