Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-26T01:59:58.777Z Has data issue: false hasContentIssue false

Analysis of haemodynamics surrounding blood transfusions after the arterial switch operation: a pilot study utilising real-time telemetry high-frequency data capture

Published online by Cambridge University Press:  07 March 2024

Matthew F. Mikulski
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Surgery and Perioperative Care, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
Antonio Linero
Affiliation:
Department of Statistics and Data Sciences, College of Natural Sciences, The University of Texas at Austin, Austin, TX, USA
Daniel Stromberg
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Pediatrics, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
Jeremy T. Affolter
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Pediatrics, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
Charles D. Fraser
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Surgery and Perioperative Care, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
Carlos M. Mery
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Surgery and Perioperative Care, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
Richard P. Lion*
Affiliation:
Texas Center for Pediatric and Congenital Heart Disease, UT Health Austin and Dell Children’s Medical Center, Austin, TX, USA Department of Pediatrics, Dell Medical School, The University of Texas at Austin, Austin, TX, USA
*
Corresponding author: Richard Lion; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background:

Packed red blood cell transfusions occur frequently after congenital heart surgery to augment haemodynamics, with limited understanding of efficacy. The goal of this study was to analyse the hemodynamic response to packed red blood cell transfusions in a single cohort, as “proof-of-concept” utilising high-frequency data capture of real-time telemetry monitoring.

Methods:

Retrospective review of patients after the arterial switch operation receiving packed red blood cell transfusions from 15 July 2020 to 15 July 2021. Hemodynamic parameters were collected from a high-frequency data capture system (SickbayTM) continuously recording vital signs from bedside monitors and analysed in 5-minute intervals up to 6 hours before, 4 hours during, and 6 hours after packed red blood cell transfusions—up to 57,600 vital signs per packed red blood cell transfusions. Variables related to oxygen balance included blood gas co-oximetry, lactate levels, near-infrared spectroscopy, and ventilator settings. Analgesic, sedative, and vasoactive infusions were also collected.

Results:

Six patients, at 8.5[IQR:5-22] days old and weighing 3.1[IQR:2.8-3.2]kg, received transfusions following the arterial switch operation. There were 10 packed red blood cell transfusions administered with a median dose of 10[IQR:10-15]mL/kg over 169[IQR:110-190]min; at median post-operative hour 36[IQR:10-40]. Significant increases in systolic and mean arterial blood pressures by 5-12.5% at 3 hours after packed red blood cell transfusions were observed, while renal near-infrared spectroscopy increased by 6.2% post-transfusion. No significant changes in ventilation, vasoactive support, or laboratory values related to oxygen balance were observed.

Conclusions:

Packed red blood cell transfusions given after the arterial switch operation increased arterial blood pressure by 5-12.5% for 3 hours and renal near-infrared spectroscopy by 6.2%. High-frequency data capture systems can be leveraged to provide novel insights into the hemodynamic response to commonly used therapies such as packed red blood cell transfusions after paediatric cardiac surgery.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Post-operative management of children with CHD is primarily focused on maintaining tissue oxygenation while allowing cardiac recovery and adaptation to a new physiologic state. Reference Miller-Smith, Flint and Allen1,Reference Bronicki and Chang2 Outcome expectations for CHD have drastically improved to ∼ 3% mortality in the modern era thanks to advances in surgical technique and available medical therapies and modalities. Reference Backer, Overman and Dearani3 Post-operative recovery following surgery, however, continues to be a high-risk period for this population, with 30-day survival of the most complex lesions utilised as a benchmark for hospital performance. Reference Backer, Overman and Dearani3Reference McCracken, Spector and Menk7 Accurate assessments of cardiac output and oxygen delivery are necessary to optimise global organ perfusion and provide therapeutic targets to guide titration of mechanical ventilation, vasoactive, analgesic, and sedative infusions, as well as volume repletion. Reference Miller-Smith, Flint and Allen1,Reference Bronicki and Chang2,Reference Domico and Allen8

Packed red blood cell transfusions are frequently utilised to increase oxygen-carrying capacity for oxygen delivery and maintain intravascular volume for cardiac output, with more than 70% of congenital heart surgery patients receiving a transfusion in the perioperative period. Reference Patel, Weld and Flores9 In addition to high rates of packed red blood cell transfusion exposure, the unique physiologies associated with complex CHD such as shunt dependent blood flow, and intracardiac mixing in univentricular circulation place them at high risk for transfusion-related complications including circulatory overload, ventricular dysfunction, elevated vascular resistance, and allo-sensitisation. Reference Kipps, Wypij, Thiagarajan, Bacha and Newburger10Reference Mille, Badheka and Yu13

In 2018, the Transfusion and Anemia Expertise Initiative published guidelines specific to CHD, recommending packed red blood cell transfusions “if haemoglobin (Hb) <7 g/dL after biventricular repair and if >9 g/dL after staged single ventricle palliation for the patient with stable haemodynamics and adequate oxygenation (weak recommendation, low quality evidence)”. Reference Cholette, Willems, Valentine, Bateman and Schwartz12 The rationale for this strategy, based on the “growing body of literature illustrating a strong association between transfusion and worse clinical outcomes in patients with paediatric heart disease”, consists of three small retrospective studies of transfusions given during cardiopulmonary bypass, not post-operatively, with duration of mechanical ventilation and length of stay the only outcome variables affected, not survival. Reference Kipps, Wypij, Thiagarajan, Bacha and Newburger10,Reference Redlin, Boettcher, Kukucka, Kuppe and Habazettl14,Reference Iyengar, Scipione and Sheth15

However, two subsequent meta-analyses comparing “restrictive” and “liberal” packed red blood cell transfusion strategies during paediatric cardiac surgery found no significant difference in risk of in-hospital mortality, infection, blood loss, duration of mechanical ventilation, or length of stay. Reference Duan, Chen, Yang and Zhang16,Reference Deng, Wang and Huang17 Furthermore, subgroup analysis of patients with cyanotic CHD treated with “liberal” transfusion strategy demonstrated a significantly shorter duration of post-operative mechanical ventilation. Reference Duan, Chen, Yang and Zhang16

Regarding efficacy, outcome measures focusing on oxygen delivery biomarkers such as lactate and mixed venous oxygen saturation (SvO2) have failed to find consistent benefit from packed red blood cell transfusion transfusion after paediatric cardiac surgery. Reasons for this are likely multifactorial, including high baseline Hb levels at time of transfusion and failing to account for the concomitant effects supplemental oxygen, mechanical ventilation, vasoactive support, analgesics, and neuromuscular blockade have on overall oxygen balance. Reference Hanson, Karam and Birch11,Reference Mille, Badheka and Yu13,Reference Zürn, Höhn and Hübner18,Reference De Gast-Bakker, De Wilde and Hazekamp19 In addition to impaired oxygen delivery, patients after paediatric cardiac surgery are at significant risk of low cardiac output due to varying degrees of systolic and diastolic ventricular dysfunction, valvular regurgitation, and myocardial inflammation depending on type of surgery and CPB exposure. Reference Caneo, Matte and Frey20,Reference Guzzetta21 Strategies to improve cardiac output after paediatric cardiac surgery include balancing systemic and pulmonary vascular resistance, which packed red blood cell transfusions are known to affect. Reference Vanderpool and Naeije22Reference Tanimura, Dohi and Fujimoto24

Two recent studies of oxygen delivery response to packed red blood cell transfusions after single ventricle palliation reported drastically conflicting results, highlighting the need for further in-depth investigation, including leveraging developing HFDC technology to guide patient-specific care. Reference Olive and Owens25 Loomba, et al. determined packed red blood cell transfusions “may be a useful intervention to increase systemic oxygen delivery” based on a significant decrease in lactate from ∼ 5 to 4 mmol/L and an increase in PaO2/FiO2 ratio from ∼ 85 to 100, which equals ∼ 5% reduction in FiO2 requirement; however, they did not control for other variables related to oxygen delivery Reference Patel, Weld and Flores9 . Meanwhile, Savorgnan, et al. concluded there was “surrogate evidence of coronary ischaemia” during packed red blood cell transfusions based solely on increased ST segment-vector variability from baseline during the transfusion period, despite significantly decreased HR and increased diastolic pressures. Reference Savorgnan, Bhat and Checchia26 Not only were no oxygen delivery biomarkers included in this study, but the ST segment-vector significance was determined using an advanced HFDC algorithm unique to that institution that has not been validated elsewhere. Reference Savorgnan, Bhat and Checchia26

Sickbay™ (Medical Informatics Corp, Houston, TX) is one such HFDC platform that continuously records numeric and waveform vital sign data across multiple standard monitoring and therapeutic devices. Reference Olive and Owens25,Reference Jone, Gearhart and Lei27 In addition to allowing real-time, second-to-second analysis, this platform has provided novel insights into patient response to therapy, such as time to arrhythmia cessation with IV sotalol and hypotension associated with IV acetaminophen. Reference Achuff, Moffett, Acosta, Lasa, Checchia and Rusin28,Reference Valdés, Miyake and Niu29 Even routine bedside procedures such as vasoactive infusion syringe pump exchanges-performed by the bedside nurse every 24-72 hours, have been shown to significantly alter subsequent patient haemodynamics. Reference Achuff, Achuff and Park30

Accordingly, we sought to leverage the Sickbay™ system to describe the real-time hemodynamic response to packed red blood cell transfusions in dextro-transposition of the great arteries (d-TGA) patients after the ASO. We chose this cohort for our pilot study given their relative homogeneity in preoperative diagnosis, demographics, and perioperative clinical course, in effort to minimise confounding variables affecting oxygen balance at time of transfusion. Reference Fraser31Reference Wernovsky33 By leveraging HFDC analysis of haemodynamics in addition to controlling for variables related to oxygen delivery, we may better understand the effect packed red blood cell transfusions have on cardiac output and oxygen delivery after paediatric cardiac surgery.

Patients and methods

Study structure and data sources

The study was approved by the Institutional Review Board at The University of Texas at Austin (STUDY00001279, approved 11 November 2021). This is a retrospective review of d-TGA patients who underwent ASO and received a post-operative packed red blood cell transfusions at Dell Children’s Medical Center from 15 July 2020 to 15 July 2021. Our cardiac care unit utilises Philips© telemetry monitors (Koninklijke Philips N.V., Amsterdam, Netherlands) to display HR calculated from electrocardiogram leads, oxygen saturations from pulse oximetry (SpO2), and systolic, diastolic, and mean arterial blood pressures (ABP-S, ABP-D, and ABP-M) from invasive arterial catheter measurements. Both numeric and waveform data are captured by Sickbay™ at 0.5 to 2-Hz fidelity and stored for future analysis. Continuous vital sign data were collected by Sickbay™ up to 6hr prior to packed red blood cell transfusions, during packed red blood cell transfusions (up to 4h), and 6hrs after packed red blood cell transfusions, except for cerebral and renal NIRs, due to lack of monitor capture by Sickbay™ at our institution.

Binary pre-and-post-packed red blood cell transfusion markers of oxygen delivery from arterial blood gas analysis were collected within 4h of packed red blood cell transfusions, with data closest to transfusion time used for analysis. Standard practice at our institution includes hourly post-operative arterial blood gas, while venous co-oximetry is only performed at the discretion of the provider team and thus was not able to be included for comparative analysis peri-transfusion. All patients had post-operative transesophageal echocardiograms, allowing documentation of ventricular function at time of transfusion.

Continuous sedative, analgesic and neuromuscular blockade infusion doses, and vasoactive inotropic scores were collected hourly from medical records for the study period duration. As per our standard institutional practice, no other volume resuscitation was given at the time of transfusion.

Statistical analysis

Descriptive statistics were used for clinical demographics and categorical laboratory values. Continuous variables were reported as median [interquartile range (IQR)]. For hourly recorded data, the mean values over the 6hrs pre- and post-packed red blood cell transfusions were compiled, and a mean difference was calculated, while median pre- to post-packed red blood cell transfusion labs were compared using Wilcoxon signed rank test.

Sickbay™ data analysis was performed using previously published methods. Reference Achuff, Moffett, Acosta, Lasa, Checchia and Rusin28,Reference Achuff, Achuff and Park30 Data were cleaned by filtering out all packed red blood cell transfusions/time pairs with missing data. The time axis for each packed red blood cell transfusions was standardised so that time “0-min” corresponded to the recorded packed red blood cell transfusion starting time. Pre-transfusion baselines were taken to be their average values prior to packed red blood cell transfusions, excluding the 10 minutes leading up to the packed red blood cell transfusions to account for possible error between documented and actual start time. A non-overlapping, 5-minute moving average was applied to the time series for each event to filter out monitor “noise”. Hemodynamic variables in these intervals were converted into percentage changes relative to their packed red blood cell transfusions-specific baseline. Aggregated hemodynamic data were then plotted along with 95% confidence intervals (95%CI). Additionally, to provide additional context, binary comparisons of baseline hemodynamic values 1 hour prior to packed red blood cell transfusions compared to hemodynamic values at 3hr and 6hr after packed red blood cell transfusions using paired Wilcoxon signed rank tests. All statistical analyses were performed using R and RStudio (https://www.R-project.org).

Results

Patient population and clinical course

There were six patients who underwent ASO at median 8.5[IQR:5-22] days and 3.1[IQR:2.8-3.2]kg and received a total of 10 packed red blood cell transfusion post-operatively (Table 1). One patient had prior pulmonary artery banding at day of life 4 at 3.4 kg because of challenging ventricular septal and coronary anatomy. That patient underwent ASO, at 3 months of age, weighing 4.85 kg. Median packed red blood cell transfusion prescriptions were 10[IQR:10-15]mL/kg, over 169[IQR:110-190]min at median 36[IQR:10-40] hours post-procedure. At the time of transfusion, 50% of patients had mild-to-moderately depressed left ventricular function. Indications for packed red blood cell transfusions were at the discretion of the clinical care team. There were no adverse events directly related to packed red blood cell transfusions. All patients survived to discharge, with zero 30-day readmissions.

Table 1. Baseline demographics and transfusion characteristics (n = 6)

Key: IQR = interquartile range; pRBCTx = packed red blood cell transfusion.

Hemodynamic analysis

Leveraging HFDC system allowed for analysis of up to 57,600 continuous data points (1 data point per second over the 16hr study period) per vital sign for each packed red blood cell transfusion exposure. Figure 1 displays aggregated mean change in HR and SpO2, and Figure 2 displays the aggregate change in ABP-S, ABP-D, and ABP-M over time for all packed red blood cell transfusions events. After packed red blood cell transfusion initiation, all three ABP parameters crossed 95%CI at ∼ 3hr by 7-12.5%, with return to baseline by 6hr. HR trended downward after packed red blood cell transfusions, though never crossing 95%CI. To determine if these trends were statistically different, comparison of baseline hemodynamic values were compared to those at 3hr and 6hr. At 3hr, there was a 5.1 ± 2.2% (p = 0.039) increase in ABP-S and 5.4 ± 2.1% (p = 0.039) increase in ABP-M, but no significant changes in HR, ABP-D, or SpO2 at 3hr and no changes in any hemodynamic parameters compared to baseline at 6hr after packed red blood cell transfusions (Table 2). Concurrently, there were no significant changes in ventilator support, doses of sedative, analgesia, or vasoactive infusions throughout the study period (Table 3). No patients were under neuromuscular blockade at time of transfusion.

Figure 1. Sickbay™ Aggregate Percent Change from Baseline – HR (1a) and SpO2 (1b). The central line represents the aggregate percent change from baseline of all nine red blood cell transfusion using 1 data point per second per red blood cell transfusion with the surrounding grey area representing the 95% confidence interval. HR trends began declining at 3hr after red blood cell transfusion but never eclipse 95% confidence interval. Key: HR—heart rate; SpO2—oxygen saturations.

Figure 2. Sickbay™ Aggregate Percent Change from Baseline – ABP-S (2a), ABP-D (2b), and ABP-M (2c). The central line represents the aggregate percent change from baseline of all nine pRBCTx using 1 data point per second per red blood cell transfusion with the surrounding grey area representing the 95% confidence interval. The 95% confidence interval is eclipsed at roughly 3hr after red blood cell transfusion corresponding to 7-12.5% increase from baseline with decrease to original baseline at 6 hr. Key: ABP-D—diastolic arterial blood pressure; ABP-M—mean arterial blood pressure; ABP-S—systolic arterial blood pressure.

Table 2. Comparisons of hemodynamic parameters pre- and post-red blood cell transfusion*

Key: ABP-S/D/M = arterial blood pressure-systolic/diastolic/mean; HR = heart rate; SD = standard deviation; SE = standard error; SpO2 = oxygen saturations.

* p-values are computed from a paired Wilcoxon signed rank test, comparing change at 3 hours to baseline and 6 hours to baseline, respectively.

Table 3. Laboratory and clinical variables affecting DO2

p-value considered significant < 0.05.

Markers of oxygen delivery

Pre-to-post-packed red blood cell transfusions we appreciated an increase in median Hb from 10.4[IQR: 9-11] to 12[IQR: 11.6-12.3] (p = 0.021) and median haematocrit from 31.5[IQR: 26.5-33.4] to 35.5[IQR: 34.6-36.6] (p = 0.027), but there were no differences in markers of oxygen delivery, such as PaO2 or lactate (Table 3). Hourly renal and cerebral NIRS, a surrogate marker of end-organ oxygenation and venous saturations, are plotted in Figure 3. Renal NIRS showed an overall increasing trajectory, with a significant increase of 6.2% (from 67.4% before packed red blood cell transfusions to 73.6% after packed red blood cell transfusions, p = 0.039). Cerebral NIRS increased by 6% but did not reach statistical significance (p = 0.055).

Figure 3. Cerebral and Renal NIRS Over Time. Lines correspond to hourly data from each of the red blood cell transfusion events included in final analysis. Key: NIRS—near-infrared spectroscopy.

Discussion

To the authors’ knowledge, this represents the first report of the hemodynamic response of CHD patients to packed red blood cell transfusions utilising HFDC analysis. This pilot study functions as proof-of-concept for the feasibility to leverage Sickbay as a clinical research platform. We found a significant increase in ABPs of 5-12.5% from baseline at roughly 3hr after packed red blood cell transfusions with a subsequent return to baseline at 6hr as well as a sustained 6% increase in renal NIRS. This was despite 50% of the cohort having mild-to-moderately depressed left ventricular function at the time of transfusion.

During the entire study period, there were no significant changes in ventilator support, vasoactive inotropic scores, or doses of analgesic and sedative medications that contributed to oxygen balance. These data, which require further validation, describe real-time augmentation of cardiac output during packed red blood cell transfusions after paediatric cardiac surgery while controlling for other variables of oxygen delivery. Leveraging HFDC systems can help create nuanced, patient-specific care plans by allowing better understanding of hemodynamic responses to frequently utilised therapies such as packed red blood cell transfusions.

For a term neonate status post ASO with ABP-M of 35-40mmHg, a 5-12.5% increase would correspond to a 2-5mmHg improvement, providing a considerable increase in overall perfusion pressure. The ability to augment haemodynamics with packed red blood cell transfusions—perhaps instead of interventions such as increasing vasoactive or ventilator support—could have significant clinical implications for many CHD patients. Especially for those who cannot tolerate high ventilator airway pressures, FiO2 or vasoactive infusion doses, packed red blood cell transfusions may offer another therapeutic option for augmentation of cardiac output during surgical recovery.

Given the paucity of existing evidence, leveraging HFDC to elucidate the effects of packed red blood cell transfusions from a hemodynamic perspective may help provide justification to guide packed red blood cell transfusions after paediatric cardiac surgery. With HFDC, we demonstrate a significant increase in ABP and renal NIRS post-transfusion, with a non-significant downward trend in HR. This is consistent with the findings of elevated ABP-D and lowered HR reported by Savorgnan, et al. Reference Savorgnan, Bhat and Checchia26

Regarding oxygen delivery effect, there were minimal confounding variables during the peri-transfusion period. This was in effort to isolate the effect of packed red blood cell transfusions on outcome measures, including patients being at a similar clinical time course (∼36 hours post-procedure). Given the baseline Hb of 10.4 as well as concomitant cardiopulmonary support at time of packed red blood cell transfusions, it is not surprising there was no effect on oxygen delivery. In contrast to Loomba et al’s study cohort, our patients did not have baseline hyperlactatemia and were already receiving mechanical ventilation at the time of transfusion. Reference Patel, Weld and Flores9

There were several limitations to this pilot study, designed as proof-of-concept for feasibility of leveraging HFDC integration into transfusion medicine research. This was performed as a retrospective review at a single centre, on a small, homogeneous patient cohort. packed red blood cell transfusion prescription dose and duration were at the discretion of the clinical team and vary by provider within our institution. Indication for transfusion could not be assessed from the medical record due to lack of documentation. Sickbay data capture at our institution at the time of study was limited to the telemetry monitor recordings of HR, SpO2, and ABP. For NIRS, ventilator settings and medication dosages, we relied on manually entered data from the electronic medical record, which is prone to errors and a lag-time between occurrence and documentation. Reference Schlosser Metitiri and Perotte34

Conclusion

In this pilot study investigating high-fidelity, real-time hemodynamic parameters surrounding packed red blood cell transfusions after ASO, packed red blood cell transfusions resulted in short-term increases in ABP-M and ABP-S by 5-12% relative to baseline without significant changes in vasoactive or ventilator support. Future studies should be prospective in nature and powered to detect significant changes in CO relative to hemodynamic markers such as vasoactive inotropic scores in addition to standard vital signs. Future cohorts should be expanded to include other index lesions, univentricular defects, and patients with varying degrees of ventricular function to assess hemodynamic response to transfusion in different clinical settings. HFDC should continue to be leveraged for this research to develop patient-specific management strategies after paediatric cardiac surgery.

Acknowledgements

Supported in part by the National Science Foundation under Grant No. DMS-2144933.

Financial support

Supported in part by the National Science Foundation under Grant No. DMS-2144933.

Competing interests

None.

Informed consent

This study was approved under the auspice of the Institutional Review Board at The University of Texas at Austin (STUDY00001279, approved on 11 November 2021).

Meeting Presentation

The abstract from this work was presented at the Pediatric Cardiac Intensive Care Society Annual Meeting, Miami, FL, 15-18 December 2022.

References

Miller-Smith, L, Flint, JL, Allen, GL. Cardiac critical care of the post-operative congenital heart disease patient. Semin Pediatr Surg 2021; 30: 151037. DOI: 10.1016/j.sempedsurg.2021.151037.CrossRefGoogle Scholar
Bronicki, RA, Chang, AC. Management of the postoperative pediatric cardiac surgical patient: crit care med . Critical Care Medicine 2011; 39: 19741984. DOI: 10.1097/CCM.0b013e31821b82a6.CrossRefGoogle Scholar
Backer, CL, Overman, DM, Dearani, JA, et al. Recommendations for centers performing pediatric heart surgery in the United States. J Thorac Cardiovasc Surg. 2023; 166: 17821820. DOI: 10.1016/j.jtcvs.2023.09.001.CrossRefGoogle Scholar
Jacobs, JP, O’Brien, SM, Pasquali, SK, et al. Variation in outcomes for benchmark operations: an analysis of the society of thoracic surgeons congenital heart surgery database. Ann Thorac Surg. 2011; 92: 21842192. DOI: 10.1016/j.athoracsur.2011.06.008.CrossRefGoogle Scholar
Jacobs, JP, He, X, Mayer, JE, et al. Mortality trends in pediatric and congenital heart surgery: an analysis of the society of thoracic surgeons congenital heart surgery database. Ann Thorac Surg. 2016; 102: 13451352. DOI: 10.1016/j.athoracsur.2016.01.071.CrossRefGoogle Scholar
Jacobs, JP, Mayer, JE, Pasquali, SK, et al. The society of thoracic surgeons congenital heart surgery database: 2019 update on outcomes and quality. Ann Thorac Surg. 2019; 107: 691704. DOI: 10.1016/j.athoracsur.2018.12.016.CrossRefGoogle Scholar
McCracken, C, Spector, LG, Menk, JS, et al. Mortality following pediatric congenital heart surgery: an analysis of the causes of death derived from the national death index. J Am Heart Assoc 2018; 7: e010624. DOI: 10.1161/JAHA.118.010624.CrossRefGoogle ScholarPubMed
Domico, M, Allen, M. Biomarkers in pediatric cardiac critical care. Pediatr Crit Care Med 2016; 17: S215S221. DOI: 10.1097/PCC.0000000000000778.CrossRefGoogle ScholarPubMed
Patel, RD, Weld, J, Flores, S, et al. The acute effect of packed red blood cell transfusion in mechanically ventilated children after the norwood operation. Pediatr Cardiol. 2022; 43: 401406. DOI: 10.1007/s00246-021-02735-6.CrossRefGoogle ScholarPubMed
Kipps, AK, Wypij, D, Thiagarajan, RR, Bacha, EA, Newburger, JW. Blood transfusion is associated with prolonged duration of mechanical ventilation in infants undergoing reparative cardiac surgery: pediatr crit care med . Pediatric Critical Care Medicine 2011; 12: 5256. DOI: 10.1097/PCC.0b013e3181e30d43.CrossRefGoogle Scholar
Hanson, SJ, Karam, O, Birch, R, et al. Transfusion practices in pediatric cardiac surgery requiring cardiopulmonary bypass: a secondary analysis of a clinical database. Pediatr Crit Care Med. 2021; 22: 978987. DOI: 10.1097/PCC.0000000000002805.CrossRefGoogle ScholarPubMed
Cholette, JM, Willems, A, Valentine, SL, Bateman, ST, Schwartz, SM. Recommendations on RBC transfusion in infants and children with acquired and congenital heart disease from the pediatric critical care transfusion and anemia expertise initiative. Pediatr Crit Care Med 2018; 19: S137S148. DOI: 10.1097/PCC.0000000000001603.CrossRefGoogle ScholarPubMed
Mille, FK, Badheka, A, Yu, P, et al. Red blood cell transfusion after stage I palliation is associated with worse clinical outcomes. J Am Heart Assoc 2020; 9: e015304. DOI: 10.1161/JAHA.119.015304.CrossRefGoogle Scholar
Redlin, M, Boettcher, W, Kukucka, M, Kuppe, H, Habazettl, H. Blood transfusion during versus after cardiopulmonary bypass is associated with postoperative morbidity in neonates undergoing cardiac surgery. Perfusion. 2014; 29: 327332. DOI: 10.1177/0267659113517922.CrossRefGoogle ScholarPubMed
Iyengar, A, Scipione, CN, Sheth, P, et al. Association of complications with blood transfusions in pediatric cardiac surgery patients. Ann Thorac Surg. 2013; 96: 910916. DOI: 10.1016/j.athoracsur.2013.05.003.CrossRefGoogle ScholarPubMed
Duan, ZX, Chen, DX, Yang, BZ, Zhang, XQ. Transfusion strategies for pediatric cardiac surgery: a meta-analysis and trial sequential analysis. Pediatr Cardiol. 2021; 42: 12411251. DOI: 10.1007/s00246-021-02644-8.CrossRefGoogle ScholarPubMed
Deng, X, Wang, Y, Huang, P, et al. Red blood cell transfusion threshold after pediatric cardiac surgery: a systematic review and meta-analysis. Medicine (Baltimore) 2019; 98: e14884. DOI: 10.1097/MD.0000000000014884.CrossRefGoogle ScholarPubMed
Zürn, C, Höhn, R, Hübner, D, et al. Risk assessment of red cell transfusion in congenital heart disease. Thorac Cardiovasc Surg 2022; 70: e15e20. DOI: 10.1055/s-0042-1756493.Google ScholarPubMed
De Gast-Bakker, DH, De Wilde, RBP, Hazekamp, MG, et al. Safety and effects of two red blood cell transfusion strategies in pediatric cardiac surgery patients: a randomized controlled trial. Intensive Care Med. 2013; 39: 20112019. DOI: 10.1007/s00134-013-3085-7.CrossRefGoogle ScholarPubMed
Caneo, LF, Matte, G, Frey, T. Minimizing the need for transfusion in pediatric congenital heart surgery. Int J Clin Transfus Med 2019;Volume; 7: 19. DOI: 10.2147/IJCTM.S168256.CrossRefGoogle Scholar
Guzzetta, NA. Benefits and risks of red blood cell transfusion in pediatric patients undergoing cardiac surgery. Pediatr Anesth. 2011; 21: 504511. DOI: 10.1111/j.1460-9592.2010.03464.x.CrossRefGoogle ScholarPubMed
Vanderpool, RR, Naeije, R. Hematocrit-corrected pulmonary vascular resistance. Am J Respir Crit Care Med. 2018; 198: 305309. DOI: 10.1164/rccm.201801-0081PP.CrossRefGoogle ScholarPubMed
Saugel, B, Klein, M, Hapfelmeier, A, et al. Effects of red blood cell transfusion on hemodynamic parameters: a prospective study in intensive care unit patients. Scand J Trauma Resusc Emerg Med 2013; 21: 21. DOI: 10.1186/1757-7241-21-21.CrossRefGoogle ScholarPubMed
Tanimura, M, Dohi, K, Fujimoto, N, et al. Effect of anemia on cardiovascular hemodynamics, therapeutic strategy and clinical outcomes in patients with heart failure and hemodynamic congestion. Circ J. 2017; 81: 16701677. DOI: 10.1253/circj.CJ-17-0171.CrossRefGoogle ScholarPubMed
Olive, MK, Owens, GE. Current monitoring and innovative predictive modeling to improve care in the pediatric cardiac intensive care unit. Transl Pediatr. 2018; 7: 120128. DOI: 10.21037/tp.2018.04.03.CrossRefGoogle ScholarPubMed
Savorgnan, F, Bhat, PN, Checchia, PA, et al. RBC transfusion induced ST segment variability following the norwood procedure. Crit Care Explor 2021; 3: e0417. DOI: 10.1097/CCE.0000000000000417.CrossRefGoogle Scholar
Jone, PN, Gearhart, A, Lei, H, et al. Artificial intelligence in congenital heart disease. JACC Adv 2022; 1: 100153. DOI: 10.1016/j.jacadv.2022.100153.CrossRefGoogle ScholarPubMed
Achuff, BJ, Moffett, BS, Acosta, S, Lasa, JJ, Checchia, PA, Rusin, CG. Hypotensive response to IV acetaminophen in pediatric cardiac patients*. Pediatr Crit Care Med. 2019; 20: 527533. DOI: 10.1097/PCC.0000000000001880.CrossRefGoogle ScholarPubMed
Valdés, SO, Miyake, CY, Niu, MC, et al. Early experience with intravenous sotalol in children with and without congenital heart disease. Heart Rhythm. 2018; 15: 18621869. DOI: 10.1016/j.hrthm.2018.07.010.CrossRefGoogle ScholarPubMed
Achuff, BJ, Achuff, JC, Park, HH, et al. Epinephrine syringe exchange events in a paediatric cardiovascular ICU: analysing the storm. Cardiol Young. 2018; 28: 409415. DOI: 10.1017/S1047951117002232.CrossRefGoogle Scholar
Fraser, CD. The neonatal arterial switch operation: technical pearls. semin thorac cardiovasc surg pediatr card surg annu . Seminars in Thoracic and Cardiovascular Surgery: Pediatric Cardiac Surgery Annual 2017; 20: 3842. DOI: 10.1053/j.pcsu.2016.10.002.CrossRefGoogle Scholar
Villafañe, J, Lantin-Hermoso, MR, Bhatt. AB, et al, D-transposition of the great arteries. J Am Coll Cardiol. 2014; 64: 498511. DOI: 10.1016/j.jacc.2014.06.1150.CrossRefGoogle Scholar
Wernovsky, G. Transposition of the great arteries and common variants. Pediatr Crit Care Med 2016; 17: S337S343. DOI: 10.1097/PCC.0000000000000819.CrossRefGoogle ScholarPubMed
Schlosser Metitiri, KR, Perotte, A. Delay between actual occurrence of patient vital sign and the nominal appearance in the electronic health record: single-center, retrospective study of PICU data, 2014-2018. Pediatr Crit Care Med. Published online November 2023; 15: 5461. DOI: 10.1097/PCC.0000000000003398.Google Scholar
Figure 0

Table 1. Baseline demographics and transfusion characteristics (n = 6)

Figure 1

Figure 1. Sickbay™ Aggregate Percent Change from Baseline – HR (1a) and SpO2 (1b). The central line represents the aggregate percent change from baseline of all nine red blood cell transfusion using 1 data point per second per red blood cell transfusion with the surrounding grey area representing the 95% confidence interval. HR trends began declining at 3hr after red blood cell transfusion but never eclipse 95% confidence interval. Key: HR—heart rate; SpO2—oxygen saturations.

Figure 2

Figure 2. Sickbay™ Aggregate Percent Change from Baseline – ABP-S (2a), ABP-D (2b), and ABP-M (2c). The central line represents the aggregate percent change from baseline of all nine pRBCTx using 1 data point per second per red blood cell transfusion with the surrounding grey area representing the 95% confidence interval. The 95% confidence interval is eclipsed at roughly 3hr after red blood cell transfusion corresponding to 7-12.5% increase from baseline with decrease to original baseline at 6 hr. Key: ABP-D—diastolic arterial blood pressure; ABP-M—mean arterial blood pressure; ABP-S—systolic arterial blood pressure.

Figure 3

Table 2. Comparisons of hemodynamic parameters pre- and post-red blood cell transfusion*

Figure 4

Table 3. Laboratory and clinical variables affecting DO2

Figure 5

Figure 3. Cerebral and Renal NIRS Over Time. Lines correspond to hourly data from each of the red blood cell transfusion events included in final analysis. Key: NIRS—near-infrared spectroscopy.