Measurement of myocardial blood flow by ultrafast computed tomography.

Wolfkiel, Christopher J.; Ferguson, James Henry; Chomka, Eva V.; Law, William R.; Labin, I N; Tenzer, Marc L.; Booker, M; Brundage, Bruce H.

doi:10.1161/01.cir.76.6.1262

Cited by 135 publications

(60 citation statements)

References 19 publications

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“…For the purpose of constructing timedensity curves, a rapid multi-section scan acquisition was performed at a single level, immediately prior to, and following the rapid, automated injection (60 mL at 20 mL?s -1 ; Angiomat 6000, Liebal-Flarsheim Company, Cincinnati, OH, USA) of radio-opaque contrast material (Omnipaque 300 mgI?mL -1 , Nycomed, Amersham, UK). In each study [15][16][17][18][19][20]6-mm sections were obtained. The acquisition time for each section was 100 ms.…”

Section: Computed Tomography Protocolmentioning

confidence: 99%

Quantifying pulmonary perfusion in primary pulmonary hypertension using electron-beam computed tomography

Jones

Hansell²,

Evans

2004

Eur Respir J

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Traditionally, a gravitational distribution of pulmonary perfusion has been described in normal subjects. How this may vary in patients with primary pulmonary hypertension (PPH), which is characterised by vascular obstruction due to intimal thickening, smooth muscle cell proliferation and episodes of thrombosis in small and medium sized pulmonary arteries, is unclear. In this study the potential of electronbeam computed tomography in quantifying the distribution of pulmonary perfusion in patients with PPH was investigated.Contrast-enhanced sections were obtained during inspiration in the supine position at baseline and during administration of the vasodilator adenosine in five healthy subjects and five patients with PPH. Under each experimental condition, regions of interest were placed along the nondependent-to-dependent axis and values for relative perfusion derived.In healthy individuals, a marked nondependent-to-dependent gradient in perfusion was observed. By contrast, in PPH, perfusion values were significantly lower and were uniform across the lung section, although the administration of adenosine resulted in increased perfusion in all regions of interest.Electron-beam computed tomography provides physiological and structural information about the pulmonary circulation in subjects with pulmonary vascular disease. Traditionally, a gravitational distribution of pulmonary perfusion has been described in normal subjects, determined by the interrelationship between hydrostatic, alveolar and interstitial pressures [1,2]. More recently, animal studies, employing techniques with high spatial resolution, have suggested that the influence of gravity is less important than the structure of the pulmonary vascular tree in determining regional blood flow in the lungs [3]. Similar findings in humans have been confirmed by a study employing electronbeam computed tomography (EBCT) to quantify regional pulmonary perfusion [4]. EBCT allows the fast (millisecond) acquisition of the data necessary for cardiac imaging. Pulmonary regional blood flow can be calculated by applying an appropriate model to changes in lung density detected, following the passage of contrast. EBCT has been used previously in both animal and clinical studies of perfusion [5][6][7], the results obtained showed a good correlation with those found from microsphere-based investigations.Primary pulmonary hypertension (PPH) is characterised by the restriction of the pulmonary vascular bed, secondary to a combination of intimal thickening, vascular smooth muscle cell proliferation and episodes of thrombosis, in small-and medium-sized arteries. Studies of pulmonary perfusion patterns in PPH, excluding those aimed at differentiating between PPH and chronic thromboembolic disease, are scarce. However, investigations using computed tomography (CT) have shown that patients with systemic sclerosis and secondary pulmonary hypertension have a reduced density gradient between the dependent and nondependent parts of the lung, compared with similar patients ...

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Section: Computed Tomography Protocolmentioning

confidence: 99%

Quantifying pulmonary perfusion in primary pulmonary hypertension using electron-beam computed tomography

Jones

Hansell²,

Evans

2004

Eur Respir J

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“…EBCT measures of perfusion, both in this and in previous animal studies, have tended to be slightly lower in comparison to values obtained using other techniques, possibly due to the limitations of the technique outlined above and the fact that measurement of tissue perfusion with EBCT is based on microsphere algorithms. Consequently, any loss of indicator from the tissue results in an underestimation of the absolute value of perfusion [15,25,26].…”

Section: Discussionmentioning

confidence: 99%

“…Using EBCT and following the Sapirstein principle, perfusion can be calculated using equations derived from conventional microsphere approaches to blood flow analysis [15,16].…”

Section: Calculation Of Perfusion Using Electron-beam Computed Tomogrmentioning

confidence: 99%

“…Blood flow per unit volume of lung parenchyma can then be calculated by dividing the absolute blood flow per mL of lung tissue (blood, parenchyma and air) by the fraction of parenchyma in the ROI. Measurement of cardiac output using EBCT is based on the Stewart-Hamilton equation, with iodinated contrast medium in the aorta used as an indicator [16,18]:…”

Section: Calculation Of Perfusion Using Electron-beam Computed Tomogrmentioning

confidence: 99%

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Pulmonary perfusion quantified by electron-beam computed tomography: effects of hypoxia and inhaled NO

Jones¹,

Hansell²,

Evans³

2003

Eur Respir J

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Patients with acute lung injury may benefit from the manipulation of pulmonary blood flow using inhaled nitric oxide (iNO) to optimise ventilation/perfusion matching. Current techniques for studying changes in regional pulmonary perfusion are difficult to apply clinically. This study therefore investigated the potential of electronbeam computed tomography (EBCT) to quantify the effects of hypoxia and iNO on regional pulmonary perfusion in five healthy subjects.Contrast-enhanced sections were obtained sequentially under conditions of normoxia, hypoxia (fractional concentration of oxygen in inspired gas (FI,O 2 ) 0.12) and hypoxia, with iNO (14.8 parts per million (ppm)) administered during inspiration in the supine position. Regions of interest were placed along the nondependent to dependent axis and values for relative perfusion derived.Under normoxic conditions a vertical gradient of perfusion existed, which became less apparent due to increased perfusion in nondependent regions after the induction of hypoxia (FI,O 2 0.12). Under physiological circumstances, the distribution of pulmonary blood flow is regulated by a local action of alveolar oxygen tension on precapillary pulmonary vessels. Thus, the reflex of hypoxic pulmonary vasoconstriction (HPV) ensures that blood flow is diverted away from areas of damaged lung, thereby preserving the matching of ventilation (V9) and perfusion (Q9) [1,2]. In contrast, patients with acute lung injury (ALI) demonstrate diminished HPV leading to adverse changes in V9/Q9 matching, manifesting clinically as refractory hypoxaemia [3]. The favourable manipulation of V9/Q9 therefore assumes considerable therapeutic significance. In this context, nitric oxide (NO), an endothelially derived vasodilator that modulates vascular tone in health and disease [4], has been demonstrated to be a selective pulmonary vasodilator when administered by inhalation both in experimental animals [5,6] and humans [7], improving physiological variables (specifically pulmonary artery pressure (Ppa) and arterial oxygen tension) in patients with ALI [4]. The effects of NO on HPV in terms of the modulation of changes in regional pulmonary blood flow induced by hypoxaemia are, however, unknown.Although techniques for studying regional pulmonary perfusion have been difficult to apply clinically, a gravitational distribution of pulmonary perfusion has been described in normal subjects, determined by the interrelationship between hydrostatic, alveolar and interstitial pressures [8,9]. Moreover, animal studies employing high spatial-resolution techniques suggest that the influence of gravity is less important than the structure of the pulmonary vascular tree in determining regional blood flow in the lung [10,11]. The authors have recently employed electron-beam computed tomography (EBCT) to quantify regional pulmonary perfusion in normal subjects placed in the supine and prone positions, demonstrating that a gravitational gradient of pulmonary perfusion existed in both supine and prone positions [12]....

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“…The development of TR-DCECT has enabled the quantitative assessment of blood perfusion in the brain, [26][27][28][29] heart 30,31 and in other organs. In essence, a TR-DCECT exam requires the repetitive scanning of the volume of interest while a contrast agent is administered.…”

Section: Introductionmentioning

confidence: 99%

Characterization of statistical prior image constrained compressed sensing. I. Applications to time‐resolved contrast‐enhanced CT

Thériault-Lauzier

Chen

2012

Medical Physics

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Purpose: Prior image constrained compressed sensing (PICCS) is an image reconstruction framework that takes advantage of a prior image to improve the image quality of CT reconstructions. An interesting question that remains to be investigated is whether or not the introduction of a statistical model of the photon detection in the PICCS reconstruction framework can improve the performance of the algorithm when dealing with high noise projection datasets. The goal of the research presented in this paper is to characterize the noise properties of images reconstructed using PICCS with and without statistical modeling. This paper investigates these properties in the clinical context of timeresolved contrast-enhanced CT. Methods: Both numerical phantom studies and an Institutional Review Board approved human subject study were used in this research. The conventional filtered backprojection (FBP), and PICCS with and without the statistical model were applied to each dataset. The prior image used in PICCS was generated by averaging over FBP reconstructions from different time frames of the time-resolved CT exam, thus reducing the noise level. Numerical studies were used to evaluate if the noise characteristics are altered for varying levels of noise, as well as for different object shapes. The dataset acquired in vivo was used to verify that the conclusions reached from numerical studies translate adequately to a clinical case. The results were analyzed using a variety of qualitative and quantitative metrics such as the universal image quality index, spatial maps of the noise standard deviations, the noise uniformity, the noise power spectrum, and the model-observer detectability. Results:The noise characteristics of PICCS were shown to depend on the noise level contained in the data, the level of eccentricity of the object, and whether or not the statistical model was applied. Most differences in the characteristics were observed in the regime of low incident x-ray fluence. No substantial difference was observed between PICCS with and without statistics in the high fluence domain. Objects with a semi-major axis ratio below 0.85 were more accurately reconstructed with lower noise using the statistical implementation. Above that range, for mostly circular objects, the PICCS implementation without the statistical model yielded more accurate images and a lower noise level. At all levels of eccentricity, the noise spatial distribution was more uniform and the modelobserver detectability was greater for PICCS with the statistical model. The human subject study was consistent with the results obtained using numerical simulations. Conclusions: For mildly eccentric objects in the low noise regime, PICCS without the noise model yielded equal or better noise level and image quality than the statistical formulation. However, in a vast majority of cases, images reconstructed using statistical PICCS have a noise power spectrum that facilitated the detection of model lesions. The inclusion of a statistical model in the PICCS framewor...

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Measurement of myocardial blood flow by ultrafast computed tomography.

Cited by 135 publications

References 19 publications

Quantifying pulmonary perfusion in primary pulmonary hypertension using electron-beam computed tomography

Quantifying pulmonary perfusion in primary pulmonary hypertension using electron-beam computed tomography

Pulmonary perfusion quantified by electron-beam computed tomography: effects of hypoxia and inhaled NO

Characterization of statistical prior image constrained compressed sensing. I. Applications to time‐resolved contrast‐enhanced CT

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