Literature DB >> 26156231

Dynamic CT perfusion measurement in a cardiac phantom.

Benjamin P Ziemer1, Logan Hubbard1, Jerry Lipinski1, Sabee Molloi2.   

Abstract

Widespread clinical implementation of dynamic CT myocardial perfusion has been hampered by its limited accuracy and high radiation dose. The purpose of this study was to evaluate the accuracy and radiation dose reduction of a dynamic CT myocardial perfusion technique based on first pass analysis (FPA). To test the FPA technique, a pulsatile pump was used to generate known perfusion rates in a range of 0.96-2.49 mL/min/g. All the known perfusion rates were determined using an ultrasonic flow probe and the known mass of the perfusion volume. FPA and maximum slope model (MSM) perfusion rates were measured using volume scans acquired from a 320-slice CT scanner, and then compared to the known perfusion rates. The measured perfusion using FPA (P(FPA)), with two volume scans, and the maximum slope model (P(MSM)) were related to known perfusion (P(K)) by P(FPA) = 0.91P(K) + 0.06 (r = 0.98) and P(MSM) = 0.25P(K) - 0.02 (r = 0.96), respectively. The standard error of estimate for the FPA technique, using two volume scans, and the MSM was 0.14 and 0.30 mL/min/g, respectively. The estimated radiation dose required for the FPA technique with two volume scans and the MSM was 2.6 and 11.7-17.5 mSv, respectively. Therefore, the FPA technique can yield accurate perfusion measurements using as few as two volume scans, corresponding to approximately a factor of four reductions in radiation dose as compared with the currently available MSM. In conclusion, the results of the study indicate that the FPA technique can make accurate dynamic CT perfusion measurements over a range of clinically relevant perfusion rates, while substantially reducing radiation dose, as compared to currently available dynamic CT perfusion techniques.

Entities:  

Keywords:  CT; Dynamic perfusion; Myocardial perfusion; Phantom

Mesh:

Year:  2015        PMID: 26156231      PMCID: PMC6506264          DOI: 10.1007/s10554-015-0700-4

Source DB:  PubMed          Journal:  Int J Cardiovasc Imaging        ISSN: 1569-5794            Impact factor:   2.357


  36 in total

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Journal:  Int J Cardiovasc Imaging       Date:  2016-11-10       Impact factor: 2.357

2.  The role of acquisition and quantification methods in myocardial blood flow estimability for myocardial perfusion imaging CT.

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4.  Absolute cerebral blood flow: Assessment with a novel low-radiation-dose dynamic CT perfusion technique in a swine model.

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5.  Functional Assessment of Coronary Artery Disease Using Whole-Heart Dynamic Computed Tomographic Perfusion.

Authors:  Logan Hubbard; Benjamin Ziemer; Jerry Lipinski; Bahman Sadeghi; Hanna Javan; Elliott M Groves; Shant Malkasian; Sabee Molloi
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6.  Combining perfusion and angiography with a low-dose cardiac CT technique: a preliminary investigation in a swine model.

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Journal:  Int J Cardiovasc Imaging       Date:  2021-01-27       Impact factor: 2.357

7.  Timing optimization of low-dose first-pass analysis dynamic CT myocardial perfusion measurement: validation in a swine model.

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8.  Low-Radiation-Dose Stress Myocardial Perfusion Measurement Using First-Pass Analysis Dynamic Computed Tomography: A Preliminary Investigation in a Swine Model.

Authors:  Logan Hubbard; Shant Malkasian; Yixiao Zhao; Pablo Abbona; Jungnam Kwon; Sabee Molloi
Journal:  Invest Radiol       Date:  2019-12       Impact factor: 6.016

9.  Comprehensive Assessment of Coronary Artery Disease by Using First-Pass Analysis Dynamic CT Perfusion: Validation in a Swine Model.

Authors:  Logan Hubbard; Jerry Lipinski; Benjamin Ziemer; Shant Malkasian; Bahman Sadeghi; Hanna Javan; Elliott M Groves; Brian Dertli; Sabee Molloi
Journal:  Radiology       Date:  2017-10-23       Impact factor: 11.105

10.  Quantification of vessel-specific coronary perfusion territories using minimum-cost path assignment and computed tomography angiography: Validation in a swine model.

Authors:  Shant Malkasian; Logan Hubbard; Brian Dertli; Jungnam Kwon; Sabee Molloi
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