Detector system comparison using relative CNR for specific imaging tasks related to neuro-endovascular image-guided interventions (neuro-EIGIs)

Neuro-EIGIs require visualization of very small endovascular devices and small vessels. A Microangiographic Fluoroscope (MAF) x-ray detector was developed to improve on the standard flat panel detector’s (FPD’s) ability to visualize small objects during neuro-EIGIs. To compare the performance of FPD and MAF imaging systems, specific imaging tasks related to those encountered during neuro-EIGIs were used to assess contrast to noise ratio (CNR) of different objects. A bar phantom and a stent were placed at a fixed distance from the x-ray focal spot to mimic a clinical imaging geometry and both objects were imaged by each detector system. Imaging was done without anti-scatter grids and using the same conditions for each system including: the same x-ray beam quality, collimator position, source to imager distance (SID), and source to object distance (SOD). For each object, relative contrasts were found for both imaging systems using the peak and trough signals. The relative noise was found using mean background signal and background noise for varying detector exposures. Next, the CNRs were found for these values for each object imaged and for each imaging system used. A relative CNR metric is defined and used to compare detector imaging performance. The MAF utilizes a temporal filter to reduce the overall image noise. The effects of using this filter with the MAF while imaging the clinical object’s CNRs are reported. The relative CNR for the detectors demonstrated that the MAF has superior CNRs for most objects and exposures investigated for this specific imaging task.

[1]  Stephen Rudin,et al.  New head equivalent phantom for task and image performance evaluation representative for neurovascular procedures occurring in the Circle of Willis , 2012, Medical Imaging.

[2]  Anthony R. Benedetto The Physics of Medical X-ray Imaging , 1991 .

[3]  Stephen Rudin,et al.  Design considerations for a new high resolution Micro-Angiographic Fluoroscope based on a CMOS sensor (MAF-CMOS) , 2013, Medical Imaging.

[4]  Ciprian N. Ionita,et al.  Graphics processing unit (GPU) implementation of image processing algorithms to improve system performance of the control acquisition, processing, and image display system (CAPIDS) of the micro-angiographic fluoroscope (MAF) , 2012, Medical Imaging.

[5]  Stephen Rudin,et al.  Endovascular coil embolization of a very small ruptured aneurysm using a novel microangiographic technique: technical note , 2012, Journal of NeuroInterventional Surgery.

[6]  S. Rudin,et al.  A theoretical and experimental evaluation of the microangiographic fluoroscope: A high-resolution region-of-interest x-ray imager. , 2011, Medical physics.

[7]  Stephen Rudin,et al.  Endovascular image-guided interventions (EIGIs). , 2007, Medical physics.

[8]  Stephen Rudin,et al.  Use of the Microangiographic Fluoroscope for Coiling of Intracranial Aneurysms , 2011, Neurosurgery.

[9]  Stephen Rudin,et al.  Region-of-interest micro-angiographic fluoroscope detector used in aneurysm and artery stenosis diagnoses and treatment , 2012, Medical Imaging.

[10]  R J Jennings,et al.  A patient-equivalent attenuation phantom for estimating patient exposures from automatic exposure controlled x-ray examinations of the abdomen and lumbo-sacral spine. , 1990, Medical physics.