SU‐E‐QI‐06: Design and Initial Validation of a Precise Capillary Phantom to Test Perfusion Systems

Wood, R; Iacobucci, Gary J.; Khobragade, P.; Ying, Linxuan; Snyder, Kenneth V.; Wack, David S.; Rudin, Stephen; Ionita, Ciprian N.

doi:10.1118/1.4888986

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“…The inaccurate results affects the treatment planning and strategies for managing the stroke. So, there is a critical need to standardize the protocols associated with the existing perfusion systems [11]. Driscoll et al [12] have developed a dynamic flow phantom to validate the fundamental quantitative parameters of the perfusion systems.…”

Section: Introductionmentioning

confidence: 99%

Initial testing of a 3D printed perfusion phantom using digital subtraction angiography

et al. 2015

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Perfusion imaging is the most applied modality for the assessment of acute stroke. Parameters such as Cerebral Blood Flow (CBF), Cerebral Blood volume (CBV) and Mean Transit Time (MTT) are used to distinguish the tissue infarct core and ischemic penumbra. Due to lack of standardization these parameters vary significantly between vendors and software even when provided with the same data set. There is a critical need to standardize the systems and make them more reliable. We have designed a uniform phantom to test and verify the perfusion systems. We implemented a flow loop with different flow rates (250, 300, 350 ml/min) and injected the same amount of contrast. The images of the phantom were acquired using a Digital Angiographic system. Since this phantom is uniform, projection images obtained using DSA is sufficient for initial validation. To validate the phantom we measured the contrast concentration at three regions of interest (arterial input, venous output, perfused area) and derived time density curves (TDC). We then calculated the maximum slope, area under the TDCs and flow. The maximum slope calculations were linearly increasing with increase in flow rate, the area under the curve decreases with increase in flow rate. There was 25% error between the calculated flow and measured flow. The derived TDCs were clinically relevant and the calculated flow, maximum slope and areas under the curve were sensitive to the measured flow. We have created a systematic way to calibrate existing perfusion systems and assess their reliability.

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Section: Introductionmentioning

confidence: 99%