Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-24T16:46:22.019Z Has data issue: false hasContentIssue false

Angiographic tool to detect pulmonary arteriovenous malformations in single ventricle physiology

Published online by Cambridge University Press:  10 May 2024

Stephen B. Spurgin*
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
Yousef M. Arar
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
Thomas M. Zellers
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
Jijia Wang
Affiliation:
Department of Applied Clinical Research, University of Texas Southwestern Medical Center, Dallas, TX, USA
Nicolas L. Madsen
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
Surendranath R. Veeram Reddy
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
Ondine Cleaver
Affiliation:
Department of Molecular Biology and Center for Regenerative Science and Medicine, University of Texas Southwestern Medical Center, Dallas, TX, USA
Abhay A. Divekar
Affiliation:
Department of Pediatrics, Southwestern Medical Center, Dallas, TX, USA Pediatric Cardiology, Children’s Medical Center, Dallas, TX, USA
*
Corresponding author: S. B. Spurgin; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

Individuals with single ventricle physiology who are palliated with superior cavopulmonary anastomosis (Glenn surgery) may develop pulmonary arteriovenous malformations. The traditional tools for pulmonary arteriovenous malformation diagnosis are often of limited diagnostic utility in this patient population. We sought to measure the pulmonary capillary transit time to determine its value as a tool to identify pulmonary arteriovenous malformations in patients with single ventricle physiology.

Methods:

We defined the angiographic pulmonary capillary transit time as the number of cardiac cycles required for transit of contrast from the distal pulmonary arteries to the pulmonary veins. Patients were retrospectively recruited from a single quaternary North American paediatric centre, and angiographic and clinical data were reviewed. Pulmonary capillary transit time was calculated in 20 control patients and compared to 20 single ventricle patients at the pre-Glenn, Glenn, and Fontan surgical stages (which were compared with a linear-mixed model). Correlation (Pearson) between pulmonary capillary transit time and haemodynamic and injection parameters was assessed using angiograms from 84 Glenn patients. Five independent observers calculated pulmonary capillary transit time to measure reproducibility (intraclass correlation coefficient).

Results:

Mean pulmonary capillary transit time was 3.3 cardiac cycles in the control population, and 3.5, 2.4, and 3.5 in the pre-Glenn, Glenn, and Fontan stages, respectively. Pulmonary capillary transit time in the Glenn population did not correlate with injection conditions. Intraclass correlation coefficient was 0.87.

Conclusions:

Pulmonary angiography can be used to calculate the pulmonary capillary transit time, which is reproducible between observers. Pulmonary capillary transit time accelerates in the Glenn stage, correlating with absence of direct hepatopulmonary venous flow.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided that no alterations are made and the original article is properly cited. The written permission of Cambridge University Press must be obtained prior to any commercial use and/or adaptation of the article.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Pulmonary arteriovenous malformations frequently develop after superior cavopulmonary anastomosis (Glenn surgery). Reference Cloutier, Ash and Smallhorn1Reference Mathur and Glenn4 Remarkably, these pulmonary arteriovenous malformations can resolve after total cavopulmonary anastomosis (Fontan completion), which has led to the “hepatic factor” hypothesis: the liver makes an unknown substance that maintains the normal vascular architecture of the lungs. Reference Srivastava, Preminger and Lock3,Reference Kim, Bae, Lee, Lim, Lee and Lee5 To maintain normal function, this factor must travel quickly from the liver, through the heart, and to the lungs (critically, without traversing the systemic capillaries)—which we term “direct hepatopulmonary blood flow.” Surgical and interventional strategies to restore direct flow of hepatic venous blood to affected lungs have been successful to resolve pulmonary arteriovenous malformations. Reference McElhinney, Kreutzer, Lang, Mayer, del Nido and Lock6Reference McElhinney, Marx, Marshall, Mayer and Del Nido9 However, while all non-pulsatile Glenn patients lose direct flow of “hepatic factor” to their lungs, not all Glenn patients develop clinically significant pulmonary arteriovenous malformations. Reference Spearman and Ginde10

Pulmonary arteriovenous malformation screening of Glenn patients is fraught with technical difficulty. Intracardiac mixing prevents use of peripheral arterial oxygen saturation or the partial pressure of dissolved oxygen. Direct measurement of oxygen saturation from the pulmonary veins is not always technically feasible. Additionally, the common screening modality (peripherally injected bubble contrast echocardiography) is prone to false positives and unable to detect capillary recruitment or proliferation of small calibre vessels. Reference Asada, Morishita, Kawai, Kajiyama and Ikeda11Reference Tonelli, Naal, Dakkak, Park, Dweik and Stoller14 Meanwhile, the confirmatory test used in patients with hereditary haemorrhagic telangiectasia (CT) has a spatial resolution of 0.15 mm, which may not be able to detect shunts that are due to diffuse microvascular dilation, to a diameter of 0.10 mm.

In light of these unresolved issues with the current tools for detection, and cognizant of the importance of detection for prognosis and clinical management, we sought to develop a screening tool that could detect changes in the pulmonary microvascular architecture. We used pulmonary angiography to define a pulmonary capillary transit time, tracking the flow of contrast through the normal pulmonary vasculature or through the shortcuts that pulmonary arteriovenous malformations provide. This pulmonary capillary transit time tool, applied to single ventricle patients with Glenn anatomy, was studied to determine pulmonary vascular changes that may occur in the absence of direct hepatopulmonary venous flow.

Materials and methods

Study Cohort

Single ventricle patients who underwent clinically indicated cardiac catheterisation including a pulmonary artery angiogram at our institution between February 2021 and February 2023 were included in the study. For these patients, both current and prior angiograms were reviewed. Baseline clinical and catheterisation data (haemodynamic measurements, blood gases, and injection parameters) for all patients were analysed, in accordance with UTSW IRB 2020-0047.

A group of twenty patients with biventricular circulation and normal hepatopulmonary blood flow served as controls (pulmonary artery stenosis, n = 11; pulmonary valve stenosis, n = 9). Twenty patients with univentricular hearts and pulmonary angiograms available from all three surgical stages were selected for longitudinal analysis.

Angiograms from eighty-four Glenn-stage patients (including the 20 from the prior stage-to-stage analysis) were utilised to evaluate for correlation between pulmonary capillary transit time and injection conditions, haemodynamic measurements, or additional clinical factors. Pulmonary capillary transit times for this group were calculated by the lead author. From this group, twenty sequentially enrolled angiograms were evaluated by the lead author as well as four paediatric interventional cardiologists (YA, TZ, SR, AD) to measure the reproducibility of the visually calculated pulmonary capillary transit time.

Definition of pulmonary capillary transit time

We defined pulmonary capillary transit time as the number of cardiac cycles between initial opacification of the distal pulmonary arteries to the earliest opacification of the major pulmonary veins (Fig. 1). The degree of opacification was not taken into account. All patients were sedated and mechanically ventilated as part of the procedure, and angiographic technique was at the discretion of the attending cardiologist. However, angiograms were only selected for analysis if the contrast was injected centrally, not in a distal pulmonary artery (Supplementary Table S1). Consequently, there is a short delay between the start of injection and the start of the pulmonary capillary transit time. In the Fontan cases wherein one lung had preferential flow of contrast from the superior vena cava, separate injections in the superior vena cava and Fontan conduit were used to calculate pulmonary capillary transit time for each individual lung.

Figure 1. Definition of the pulmonary capillary transit time. Pulmonary capillary transit time is defined as the number of cardiac cycles taken for contrast to traverse the pulmonary capillary bed. This is calculated by using either the number of frames (of the angiogram) or in seconds. Calculation of the transit time starts when the contrast reaches the distal major branches of the pulmonary arteries, and stops when the first visible contrast is present in the pulmonary veins.

Cardiac cycle time was obtained from simultaneous electrocardiogram recordings. When simultaneous electrocardiogram was not available, direct observation of the motion of the cardiac silhouette was used (average of five cardiac cycles; frame rate of the angiogram divided by number of frames per beat, multiplied by 60 to obtain beats per minute). Pulmonary capillary transit time was calculated for left and right lungs separately, and the average was then used for subsequent grouping and analysis.

Statistical analysis

Descriptive statistics (i.e., mean, standard deviation, median, min, and max) were employed for summarising demographic, haemodynamic, and clinical variables. The two-sample t test was used to compare continuous variables. Analysis of variance was used to compare the continuous variables between several groups with Tukey Honestly Significant Difference being the multiple comparison adjustment method. The relationships between pulmonary capillary transit time and injection pressure, dose, rate, and rise were investigated by the Pearson correlation coefficient. For comparing the pulmonary capillary transit time in the longitudinal analysis, a linear-mixed model was used to incorporate the correlation between repeated measurements from the same patient. Intraclass correlation coefficient based on the two-way random effects model was used to investigate the agreement between the five readers. The p values for pairwise intraclass correlation coefficient were not adjusted. The level of significance was set at 5%. All the analyses were conducted using SPSS v29 (IBM Corp., Armonk, NY), GraphPad Prism 10.0.0 (Dotmatics, La Jolla, CA), or SAS 9.4 (SAS Inc., Cary, NC).

Results

Pulmonary capillary transit time is accelerated during the Glenn stage

The clinical characteristics of our Glenn cohort are listed in Table 1. We found that the mean pulmonary capillary transit time of the control group (with normal cardiopulmonary vascular connections and biventricular hearts) was 3.25 (95% CI 2.9–3.6) cardiac cycles. Similar to the control group, the mean pulmonary capillary transit time of the pre-Glenn and the Fontan groups were 3.53 and 3.48 cardiac cycles, respectively (Fig. 2a). However, the mean pulmonary capillary transit time of the Glenn patients was 2.37 (95% CI 2.01–2.73) cardiac cycles, significantly faster than all other individual groups (p < 0.001). A detailed comparison of clinical characteristics at each stage is available in Supplementary Table S2.

Figure 2. Loss of direct hepatopulmonary blood flow leads to reversible acceleration of pulmonary capillary transit time (PCTT). (a) There is no significant difference in the PCTT between patients with normal cardiopulmonary vascular connections and single ventricle patients in the Pre-Glenn or Fontan stage. However, the PCTT in patients with Glenn anatomy is significantly accelerated. (b) Tracking individual patients (from A) through each surgical stage shows accelerated PCTT in the Glenn that reverts to normal after restoration of direct hepatopulmonary blood flow. Two patients whose PCTT did not decrease from Pre-Glenn to Glenn are highlighted in red, and one patient whose PCTT did not increase from Glenn to Fontan is highlighted in blue. (c) Stage-to-stage difference for the individual patients shown in (B).

Table 1. Study cohort characteristics

HLHS = Hypoplastic Left Heart Syndrome; DORV = Double Outlet Right Ventricle; AVCD = Atrioventricular Canal Defect; TA = Tricuspid Atresia; PA = Pulmonary Atresia; DILV = Double Inlet Left Ventricle; BTTS = Blaylock Taussig Thomas Shunt; PDA = patent ductus arteriosus; PA = pulmonary artery.

Among 84 glenn patients recruited to the study, the majority were male, situs solitus, and with a single right ventricle. Initial palliation procedures were variable.

When individual patients were analysed longitudinally, we found that 90% (18/20) of patients had a faster pulmonary capillary transit time in the Glenn stage, compared to the pre-Glenn stage (Fig. 2b,c). Using a linear-mixed model, incorporating the correlation between repeated measurements from the same patient, we found that there is a significant decrease from pre-Glenn to Glenn (p < 0.0001) and a significant increase from Glenn to Fontan (p = 0.0002) (Table 2).

Table 2. Transit time acceleration in the Glenn stage

Using a linear-mixed model, the longitudinal analysis of pulmonary capillary transit time in single ventricle palliation reveals a statistically significant acceleration during the Glenn stage.

In our Glenn patients, there was no association between pulmonary capillary transit time and either injection pressure, contrast dose, rate of injection, or rate of rise (Supplementary Figure S1). Additionally, there was no association between pulmonary capillary transit time and catheter size (p = .55) or catheter type (p = .24) (Supplementary Figure S2). Similarly, in the Glenn cohort, neither peak pulmonary artery pressure, mean pulmonary artery pressure, transpulmonary gradient, or ventricular end-diastolic pressure correlated with pulmonary capillary transit time (Table 3). Five independent reviewers calculated pulmonary capillary transit time for twenty Glenn angiograms, which yielded an intraclass correlation coefficient of 0.87 (95% CI 0.7–0.95, p < 0.001), indicating good agreement between viewers (Supplementary Table S3).

Table 3. Relation of pulmonary capillary transit time (PCTT) and patient-specific factors during the Glenn stage

PA = pulmonary artery; PV = pulmonary vein; PCW = pulmonary capillary wedge; Qp = pulmonary blood flow; Qs = systemic blood flow; PVR = pulmonary vascular resistance (Woods units); SVR = systemic vascular resistance (Woods units); RUPV = right upper PV; RLPV = right lower PV; LUPV = left upper PV; LLPV = left lower PV.

Basic physical parameters, angiographic and haemodynamic conditions, and readouts of successful alveolar gas exchange were examined using Pearson correlation for their relation to the PCTT. Parameters were highlighted in red if there was a significant correlation with PCTT. All pressure measurements are in mm Hg.

Discussion

This study provides the first published evidence that the pulmonary capillary transit time varies with the stage of single ventricle palliation. Our results validate the traditional teaching that, in the absence of pulmonary arteriovenous malformations, contrast takes at least three cardiac cycles to travel through the pulmonary capillary bed. In 90% of patients, pulmonary capillary transit time accelerates in the Glenn stage. The pre-Glenn data presented in our study provides evidence that the pulmonary vasculature was in fact normal prior to the changes that occur in the Glenn stage. The acceleration of pulmonary capillary transit correlates with the absence of direct hepatopulmonary venous flow in this surgical stage.

Pulmonary arteriovenous malformation detection is difficult and subject to variable limitations in the Glenn population. Diagnostic modalities of pulmonary arteriovenous malformation detection may be understood as attempts either to visualise the lesion (CT, MRI, or pulmonary angiography) or to detect the effects of pulmonary arteriovenous shunting (pulmonary venous desaturation, contrast echocardiography, 99mTc macroaggregated albumin scan). The pulmonary capillary transit time represents a combination of these two strategies, as we visualise an effect of pulmonary arteriovenous shunting.

Peripherally injected contrast echocardiography remains the standard screening method for pulmonary arteriovenous malformations in patients with normal, fully septated hearts. Reference Faughnan, Mager and Hetts15 Contrast echocardiography has been used previously to show reversibility of pulmonary arteriovenous malformations after reintroduction of hepatopulmonary venous flow, by comparing patients in the Glenn and Fontan stages. Reference Kim, Bae, Lee, Lim, Lee and Lee5 Work in Fontan patients, however, has shown that the significant majority of Fontan patients have a positive contrast echocardiogram. Reference Chang, Alejos and Atkinson12 We suspect that their remarkably high positive rate is affected by the use of a distally placed end-hole catheter for bubble contrast injection (applying direct force to either deform bubbles so that they can pass through the pulmonary capillaries, or simply reduce the time spent in the capillary bed, where collapse occurs). However, their work does highlight the need for a new diagnostic modality that can track changes secondary to presence or absence of hepatic factor.

While our work is the first to quantify transit time as a pulmonary arteriovenous malformation detection method in paediatric cardiology, a single study in adult patients with hepatopulmonary syndrome defines a similar “pulmonary transit time” (time in seconds from initial injection and opacification of the main pulmonary artery to that of the left atrium). Reference Zhao, Tsauo and Zhang16 Intriguingly, they report a diagnostic utility comparable to contrast echocardiography. However, they include in their transit time the portion that takes place in the large arteries, and—critically—do not index to the cardiac cycle, thereby preventing application of their methods to paediatric patients with single ventricle heart disease and highly variable heart rate.

By requiring a central (rather than peripheral) injection site, we reduce the likelihood of falsely accelerating the pulmonary capillary transit time. By not starting the transit time until contrast reaches the distal pulmonary vessels, we focus analysis on the intra-parenchymal pulmonary arteriovenous malformations. Indeed, in ex vivo studies of isolated, perfused lungs, the distal capillary bed was shown to be responsible for the major variations in pulmonary transit time. Reference Clough, Haworth and Hanger17

In a regional analysis of individual lung lobes, transit time (using MRI) has been shown to reflect changes in regional pulmonary vascular resistance. Reference Moore, Cerne and Pathrose18 The fact that whole lung pulmonary capillary transit time does not correlate with pulmonary vascular resistance or transpulmonary gradient is likely due to the limited ability to pick up the subtle regional drops in pulmonary vascular resistance that would result from pulmonary arteriovenous malformations.

While visual calculation of the pulmonary capillary transit time is reliable and fast, we plan to develop an automated analysis for further ease of application. We anticipate that machine learning coupled with shadow tracking will prove effective against a background of respiratory and cardiac motion. Quantification of MR or CT-derived transit times will also be helpful, especially as their use increases for pre-Glenn evaluation. Reference Brown, Gauvreau and Powell19,Reference James, Tandon and Nugent20 Finally, as more data is gathered, we hope to use pulmonary capillary transit time as a measure to predict outcomes secondary to the myriad pulmonary vascular changes after the Glenn and Fontan surgeries.

Limitations

For clinical application, a direct comparison between our pulmonary capillary transit time and bubble contrast echocardiography will be necessary. Due to the variability of both anatomy and clinical management, collaboration with other centres will be necessary to power discovery of the patient-specific factors that increase risk of pulmonary arteriovenous malformation development.

Conclusions

Pulmonary capillary transit time is a simple, rapid, and reproducible method to assess changes in the pulmonary vascular architecture. Our results confirm the traditional teaching that the contrast takes at least three cardiac cycles to traverse the normal pulmonary vasculature. Our longitudinal study of pulmonary capillary transit time in single ventricle patients reinforces the hepatic factor hypothesis and shows a measurable effect of hepatic factor loss in even “normal” Glenn patients.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1047951124000933.

Acknowledgements

We would like the members of both the Cleaver Lab and the Leducq ReVAMP Network for their input and guidance.

Financial support

This work was supported financially by the Pediatric Scientist Development Program (NICHD K12-HD000850) and the Leducq Foundation Transatlantic Network of Excellence grant “ReVAMP — Recalibrating Mechanotransduction in Vascular Malformations” (2022–2027).

Competing interests

None.

Ethical standard

The authors assert that this work complies with the ethical standards of the relevant national guidelines and with the Helsinki Declaration of 1975, as revised in 2008, and has been approved by the University of Texas Southwestern Independent Review Board, UTSW IRB 2020-0047.

References

Cloutier, A, Ash, JM, Smallhorn, JF, et al. Abnormal distribution of pulmonary blood flow after the Glenn shunt or Fontan procedure: risk of development of arteriovenous fistulae. Circulation 1985; 72: 471479. DOI: 10.1161/01.cir.72.3.471.10.1161/01.CIR.72.3.471CrossRefGoogle Scholar
McFaul, RC, Tajik, AJ, Mair, DD, Danielson, GK, Seward, JB. Development of pulmonary arteriovenous shunt after superior vena cava-right pulmonary artery (Glenn) anastomosis. Report of four cases. Circulation 1977; 55: 212216. DOI: 10.1161/01.cir.55.1.212.10.1161/01.CIR.55.1.212CrossRefGoogle ScholarPubMed
Srivastava, D, Preminger, T, Lock, JE, et al. Hepatic venous blood and the development of pulmonary arteriovenous malformations in congenital heart disease. Circulation 1995; 92: 12171222. DOI: 10.1161/01.cir.92.5.1217.10.1161/01.CIR.92.5.1217CrossRefGoogle ScholarPubMed
Mathur, M, Glenn, WW. Long-term evaluation of cava-pulmonary artery anastomosis. Surgery 1973; 74: 899916.Google ScholarPubMed
Kim, SJ, Bae, EJ, Lee, JY, Lim, HG, Lee, C, Lee, CH. Inclusion of hepatic venous drainage in patients with pulmonary arteriovenous fistulas. Ann Thorac Surg 2009; 87: 548553. DOI: 10.1016/j.athoracsur.2008.10.024.10.1016/j.athoracsur.2008.10.024CrossRefGoogle ScholarPubMed
McElhinney, DB, Kreutzer, J, Lang, P, Mayer, JE Jr., del Nido, PJ, Lock, JE. Incorporation of the hepatic veins into the cavopulmonary circulation in patients with heterotaxy and pulmonary arteriovenous malformations after a Kawashima procedure. Ann Thorac Surg 2005; 80: 15971603. DOI: 10.1016/j.athoracsur.2005.05.101.10.1016/j.athoracsur.2005.05.101CrossRefGoogle ScholarPubMed
Shah, MJ, Rychik, J, Fogel, MA, Murphy, JD, Jacobs, ML. Pulmonary AV malformations after superior cavopulmonary connection: resolution after inclusion of hepatic veins in the pulmonary circulation. Ann Thorac Surg 1997; 63: 960963. DOI: 10.1016/s0003-4975(96)00961-7.10.1016/S0003-4975(96)00961-7CrossRefGoogle ScholarPubMed
Pike, NA, Vricella, LA, Feinstein, JA, Black, MD, Reitz, BA. Regression of severe pulmonary arteriovenous malformations after Fontan revision and “hepatic factor” rerouting. Ann Thorac Surg 2004; 78: 697699. DOI: 10.1016/j.athoracsur.2004.02.003.10.1016/j.athoracsur.2004.02.003CrossRefGoogle ScholarPubMed
McElhinney, DB, Marx, GR, Marshall, AC, Mayer, JE, Del Nido, PJ. Cavopulmonary pathway modification in patients with heterotaxy and newly diagnosed or persistent pulmonary arteriovenous malformations after a modified Fontan operation. J Thorac Cardiovasc Surg 2011; 141: 1362–70.e1. DOI: 10.1016/j.jtcvs.2010.08.088.10.1016/j.jtcvs.2010.08.088CrossRefGoogle ScholarPubMed
Spearman, AD, Ginde, S. Pulmonary vascular sequelae of palliated single ventricle circulation: arteriovenous malformations and aortopulmonary collaterals. J Cardiovasc Dev Dis 2022; 9: 309. DOI: 10.3390/jcdd9090309.Google Scholar
Asada, D, Morishita, Y, Kawai, Y, Kajiyama, Y, Ikeda, K. Efficacy of bubble contrast echocardiography in detecting pulmonary arteriovenous fistulas in children with univentricular heart after total cavopulmonary connection. Cardiol Young 2020; 30: 14. DOI: 10.1017/S104795111900324X.10.1017/S104795111900324XCrossRefGoogle ScholarPubMed
Chang, RK, Alejos, JC, Atkinson, D, et al. Bubble contrast echocardiography in detecting pulmonary arteriovenous shunting in children with univentricular heart after cavopulmonary anastomosis. J Am Coll Cardiol 1999; 33: 20522058. DOI: 10.1016/s0735-1097(99)00096-0.10.1016/S0735-1097(99)00096-0CrossRefGoogle ScholarPubMed
Forde, KA, Fallon, MB, Krowka, MJ, et al. Pulse oximetry is insensitive for detection of hepatopulmonary syndrome in patients evaluated for liver transplantation. Hepatology 2019; 69: 270281. DOI: 10.1002/hep.30139.10.1002/hep.30139CrossRefGoogle ScholarPubMed
Tonelli, AR, Naal, T, Dakkak, W, Park, MM, Dweik, RA, Stoller, JK. Assessing the kinetics of microbubble appearance in cirrhotic patients using transthoracic saline contrast-enhanced echocardiography. Echocardiography 2017; 34: 14391446. DOI: 10.1111/echo.13662.10.1111/echo.13662CrossRefGoogle ScholarPubMed
Faughnan, ME, Mager, JJ, Hetts, SW, et al. Second international guidelines for the diagnosis and management of hereditary hemorrhagic telangiectasia. Ann Intern Med 2020; 173: 9891001. DOI: 10.7326/M20-1443.10.7326/M20-1443CrossRefGoogle ScholarPubMed
Zhao, H, Tsauo, J, Zhang, X, et al. Pulmonary transit time derived from pulmonary angiography for the diagnosis of hepatopulmonary syndrome. Liver Int 2018; 38: 19741981. DOI: 10.1111/liv.13741.10.1111/liv.13741CrossRefGoogle Scholar
Clough, AV, Haworth, ST, Hanger, CC, et al. Transit time dispersion in the pulmonary arterial tree. J Appl Physiol 1985; 85: 565574. DOI: 10.1152/jappl.1998.85.2.565.10.1152/jappl.1998.85.2.565CrossRefGoogle Scholar
Moore, JE, Cerne, JW, Pathrose, A, et al. Quantitative assessment of regional pulmonary transit times in pulmonary hypertension. J Magn Reson Imaging 2023; 57: 727737. DOI: 10.1002/jmri.28343.10.1002/jmri.28343CrossRefGoogle ScholarPubMed
Brown, DW, Gauvreau, K, Powell, AJ, et al. Cardiac magnetic resonance versus routine cardiac catheterization before bidirectional glenn anastomosis in infants with functional single ventricle: a prospective randomized trial. Circulation 2007; 116: 27182725. DOI: 10.1161/CIRCULATIONAHA.107.723213.10.1161/CIRCULATIONAHA.107.723213CrossRefGoogle ScholarPubMed
James, L, Tandon, A, Nugent, A, et al. Rationalising the use of cardiac catheterisation before Glenn completion. Cardiol Young 2018; 28: 719724. DOI: 10.1017/S1047951118000240.10.1017/S1047951118000240CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Definition of the pulmonary capillary transit time. Pulmonary capillary transit time is defined as the number of cardiac cycles taken for contrast to traverse the pulmonary capillary bed. This is calculated by using either the number of frames (of the angiogram) or in seconds. Calculation of the transit time starts when the contrast reaches the distal major branches of the pulmonary arteries, and stops when the first visible contrast is present in the pulmonary veins.

Figure 1

Figure 2. Loss of direct hepatopulmonary blood flow leads to reversible acceleration of pulmonary capillary transit time (PCTT). (a) There is no significant difference in the PCTT between patients with normal cardiopulmonary vascular connections and single ventricle patients in the Pre-Glenn or Fontan stage. However, the PCTT in patients with Glenn anatomy is significantly accelerated. (b) Tracking individual patients (from A) through each surgical stage shows accelerated PCTT in the Glenn that reverts to normal after restoration of direct hepatopulmonary blood flow. Two patients whose PCTT did not decrease from Pre-Glenn to Glenn are highlighted in red, and one patient whose PCTT did not increase from Glenn to Fontan is highlighted in blue. (c) Stage-to-stage difference for the individual patients shown in (B).

Figure 2

Table 1. Study cohort characteristics

Figure 3

Table 2. Transit time acceleration in the Glenn stage

Figure 4

Table 3. Relation of pulmonary capillary transit time (PCTT) and patient-specific factors during the Glenn stage

Supplementary material: File

Spurgin et al. supplementary material 1

Spurgin et al. supplementary material
Download Spurgin et al. supplementary material 1(File)
File 94.5 KB
Supplementary material: File

Spurgin et al. supplementary material 2

Spurgin et al. supplementary material
Download Spurgin et al. supplementary material 2(File)
File 299 KB