Comparing near-infrared spectroscopy—measured cerebral oxygen saturation and corresponding venous oxygen saturations in children with congenital heart disease: a systematic review and meta-analysis
Original Article

Comparing near-infrared spectroscopy—measured cerebral oxygen saturation and corresponding venous oxygen saturations in children with congenital heart disease: a systematic review and meta-analysis

Yiqi Ma1#, Lihong Zhao1#, Jiafu Wei2, Ziwei Wang1, Su Lui1, Bin Song1, Qiyong Gong1,3, Pu Wang4,5, Min Wu1

1Department of Radiology, Functional and Molecular Imaging Key Laboratory of Sichuan Province, West China Hospital, Sichuan University, Chengdu, China; 2Department of Cardiology, West China Hospital, Sichuan University, Chengdu, China; 3Department of Radiology, West China Xiamen Hospital of Sichuan University, Xiamen, China; 4Department of Rehabilitation Medicine, The Seventh Hospital of Sun Yat-Sen University, Shenzhen, China; 5Guangdong Engineering Technology Research Center for Rehabilitation Medicine and Clinical Translation, Guangzhou, China

Contributions: (I) Conception and design: Y Ma, L Zhao; (II) Administrative support: M Wu; (III) Provision of study materials or patients: Y Ma, L Zhao; (IV) Collection and assembly of data: Y Ma, L Zhao, J Wei, Z Wang; (V) Data analysis and interpretation: Y Ma, J Wei, Z Wang; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.

#These authors contributed equally to this work.

Correspondence to: Min Wu. Department of Radiology, Functional and Molecular Imaging Key Laboratory of Sichuan Province, West China Hospital, Sichuan University, 37 Guo Xue Alley, Chengdu 610041, China. Email: wuminscu@scu.edu.cn.

Background: Near-infrared spectroscopy (NIRS) is a non-invasive approach that measures cerebral regional oxygen saturation (rScO2). In this study, we evaluated the evidence on the validity of NIRS and the interchangeability between NIRS and common invasive approaches by exploring the correlation and consistency and comparing the mean and standard deviation between the NIRS rScO2 and jugular bulb venous oxygen saturation (SjvO2) as well as central venous oxygen saturation (ScvO2) in the perioperative period of children with congenital heart disease (CHD).

Methods: We searched electronic bibliographic databases (PubMed, The Cochrane Library and Embase) and screened the studies that met the inclusion criteria. We included cross-sectional studies of CHD pediatric patients in the perioperative period receiving both tests for NIRS rScO2 and SjvO2 or NIRS rScO2 and ScvO2. Methodological quality assessment and heterogeneity analyses were performed. We qualitatively summarized the results of Bland-Altman’s analysis. Meta-regression, subgroup analyses, and sensitivity analyses were carried out to explore the causes of heterogeneity.

Results: There was no significant difference in Cohen’s d between rScO2 and ScvO2 or between rScO2 and SjvO2 (Cohen’s d =0.06, 95% CI: −0.16 to 0.28; Cohen’s d =0.03, 95% CI: −0.25 to 0.31, respectively) and notable heterogeneity existed (I2=76.0%, P<0.001; I2=73.6%, P<0.001, respectively). A positive linear correlation was present between rScO2 and ScvO2 or between rScO2 and SjvO2 (r=0.58, 95% CI: 0.54 to 0.63; r=0.60, 95% CI: 0.54 to 0.66, respectively) and the heterogeneity was not significant (I2=36.7%, P=0.065; I2=12.7%, P=0.328, respectively). In most studies, the 95% limits of agreements of Bland-Altman’s analysis were large. No evidence of publication bias was observed.

Conclusions: TherScO2 measured by NIRS reflected the SjvO2 and ScvO2 monitored by invasive measurements in the perioperative period of children with CHD to some extent. However, wide limits of agreements between rScO2 and SjvO2 as well as ScvO2 indicated that NIRS and SjvO2 as well as ScvO2 are not interchangeable. Whether NIRS plays a prominent role in monitoring cerebral oxygen saturation in children with CHD needs further research.

Keywords: Near-infrared spectroscopy (NIRS); cerebral oxygen saturation; congenital heart disease (CHD); jugular bulb venous oxygen saturation (SjvO2); central venous oxygen saturation (ScvO2)


Submitted Jul 11, 2022. Accepted for publication Aug 12, 2022.

doi: 10.21037/tp-22-345


Introduction

In the past several years, the postoperative survival rate of children with congenital heart disease (CHD) has improved, but whether their postoperative quality of life has also improved is not known (1-3). For CHD patients undergoing cardiac surgery or cardiac catheterization, brain injury could occur before and after interventions, and neurodevelopmental impairment could affect patients’ cognition, motor skills, social interaction and behavior, language, concentration, and executive function (4,5). Preoperative and postoperative hypotension and hypoxemia are significant risk factors for brain injury in pediatric CHD patients (6,7). Thus, real-time neurological monitoring is necessary for children with CHD undergoing cardiac surgery or cardiac catheterization (5). Cerebral perfusion and oxygen saturation are important factors affecting neurological functions that must be monitored perioperatively to assure satisfactory patient outcomes.

Direct or indirect invasive approaches are used to monitor cerebral oxygen saturation. The best indicator reflecting global tissue oxygen saturation is mixed venous saturation, but it is inconvenient to acquire. Central venous oxygen saturation (ScvO2) is considered the gold standard substitute for mixed venous oxygen saturation to monitor tissue oxygen saturation in pediatric cardiac surgery (8-10). Pulmonary artery catheters can provide ScvO2 directly. In the absence of pulmonary artery catheters, superior vena cava saturation can be used to reflect cardiac index and mixed venous oxygen saturation after cardiac surgery as a measure of tissue oxygen saturation. Sampling through retrograde cannulation of the jugular vein and measuring jugular bulb venous oxygen saturation (SjvO2) by reflectance oximetry is another accepted invasive method for measuring global cerebral oxygen saturation. An SjvO2 below 50% indicates that insufficient oxygen is supplied to the brain, and treatment to increase cerebral oxygen supply and/or decrease metabolic demand is needed (11).

Near-infrared spectroscopy (NIRS) is a non-invasive method for the measurement of cerebral regional oxygen saturation (rScO2) (12). Invented by Jöbsis et al. in 1997 (12), NIRS is a widely used and reliable tool for the measurement of cerebral hypoperfusion in infants with CHD (13). The NIRS monitoring system is based on tissue transmission and absorption of near-infrared light (wavelength 700–950 nm) via biomolecules, for example, oxygenated and deoxygenated hemoglobin. Owing to different optical densities in the near-infrared spectrum, the concentrations of hemoglobin molecules can be determined by their relative absorption wavelength (14). In addition, rScO2 measures the oxygen saturation of brain tissue after weighting that of arteries, veins, and capillaries, and it is simultaneously related to physiological variables such as arterial oxygen saturation, partial pressure of arterial carbon dioxide (PCO2), blood pressure, hematocrit, cerebral blood flow, cerebral blood volume, and cerebral metabolic rate (15,16). In pediatric cardiac surgery, it is recommended that NIRS oxygenation monitoring start before delivery of oxygen and continue to the postoperative period (7). As a sustainable, rapid, and non-invasive monitoring tool for rScO2 measurement, NIRS may yield improved measurement of cerebral oxygen saturation. Nevertheless, due to the lack of generally accepted reference values and assumption of fixed arterio-venous ratio as well as diverse algorithms, the accuracy of NIRS remains controversial (17). The paradox is that biologic variation exists in arterio-venous ratio related to hypoxia while manufacturers hypothesize a fixed arterio-venous ratio, which will inevitably affect the results of NIRS (18). Besides, readings of NIRS vary considerably between repeated measurement of the same subjects and between subjects with different cerebral oximeters (19). Currently, the Food and Drug Administration (FDA) have not regulated the standards for accuracy of cerebral oximeters. A systematic review and meta-analysis is needed to validate the accuracy of NIRS and assess whether rScO2 can replace SjvO2 and ScvO2 to monitor cerebral oxygen saturation.

This systematic review and meta-analysis intended to assess the validity of NIRS in measuring cerebral oxygen saturation in children with CHD undergoing surgery and evaluate the interchangeability between noninvasive NIRS and common invasive approaches in observational studies. Our specific objectives were to compare Cohen’s d between NIRS rScO2 and ScvO2 as well as SjvO2 and explore the correlation and consistency between NIRS rScO2 and ScvO2 and SjvO2. We hypothesized that the validity of NIRS is comparable to that of ScvO2 and SjvO2 measurements. We presented the following article in accordance with the MOOSE reporting checklist (available at https://tp.amegroups.com/article/view/10.21037/tp-22-345/rc) (20).


Methods

Search strategy

A literature search was conducted by 2 investigators independently from the inception of the relevant databases until February 2022. The electronic bibliographic databases of PubMed, The Cochrane Library, and Embase were searched. We searched these databases using the search strategies described in Supplementary Appendix 1, Appendix 2, and Appendix 3. All the retrieved results were crosschecked by Y Ma, L Zhao.

Inclusion criteria

Types of studies

Cross-sectional analyses.

Types of participants

CHD pediatric patients younger than 18 years of age undergoing cardiac surgery or cardiac catheterization.

Types of examination method

(I) Cerebral oxygen saturation of patients was monitored perioperatively by NIRS and SjvO2. (II) Patients were monitored perioperatively by NIRS and ScvO2 as an assessment of cerebral oxygen saturation. (III) All included studies provided details of the NIRS devices used.

Statistics

The included studies reported mean difference (MD), standard deviation (SD), and correlation coefficient (r) values between rScO2 and SjvO2 and between rScO2 and ScvO2.

Study selection

After removal of duplicate papers, the remaining articles retrieved in the databases were screened through the titles and abstracts according to the inclusion criteria. Editorials, reviews, animal experiments, commentaries, conference papers, non-English language articles, abstracts, unpublished articles, and irrelevant articles were excluded. Articles with unobtainable original texts were also excluded. Full text articles were assessed for eligibility, and articles that lacked the data mentioned stipulated by the inclusion criteria were excluded. The screening was performed manually and independently by 2 reviewers, and differences were resolved through discussion and consensus.

Data extraction

The following data were extracted from the included studies: author, publication year, study design, number of patients, data points, median age, types of treatment, diagnosis, sites of NIRS, types of NIRS device, types of venous oxygen saturation measurement, MD, SD, r values between 2 methods, and 95% limits of agreement (LOA). Data extraction was conducted by 4 experienced investigators.

As the MD and SD were not provided in some studies, we extracted rScO2, ScvO2, and SjvO2 values from scatter diagrams created by MATLAB® (MathWorks, Inc., Natick, MA, USA) instead of contacting authors and then calculated the MD and SD between rScO2 and ScvO2 and between rScO2 and SjvO2. To standardize effect size, we used Cohen’s d to evaluate the difference between the 2 methods. Cohen’s d was calculated as the MD divided by the SD (21). Most studies used Pearson’s correlation coefficients to describe the correlation between the 2 methods. For several studies that used Spearman’s correlation coefficients, we converted the Spearman’s correlation coefficients into Pearson’s correlation coefficients for the sake of uniformity (22). Before calculating the pooled Pearson’s correlation coefficient, we transformed the correlation coefficients into Fisher’s Z, as the variance or standard error was closely related to the r values.

Methodological quality assessment

Considering that all the included articles were cross-sectional studies, we used the 11-item checklist for methodological quality assessment of cross-sectional studies recommended by the Agency for Healthcare Research and Quality (AHRQ) (23). When the answer was ‘NO’ or ‘UNCLEAR’, the item was scored ‘0’; if it was answered ‘YES’, then the item was scored ‘1’. Studies rated as 8–11 scores were regarded as high-quality studies; scores of 4–7 indicated intermediate-quality; and scores of 0–3 suggested low-quality (24).

Statistical analysis

We divided all the studies into rScO2 versus ScvO2 and rScO2 versus SjvO2 groups to estimate the difference and correlation among methods. For continuous variables, we evaluated the pooled Cohen’s d and r values with their 95% confidence intervals (95% CIs) in the rScO2vs. ScvO2 and rScO2vs. SjvO2 groups, respectively, using the Stata 15.0 software (Stata Corporation, College Station, TX, USA). We then performed heterogeneity analyses by I2 test with Stata under a fixed effects model. A score of 25%<I2<50% suggested low heterogeneity, and 50%<I2<75% and I2<75% indicated intermediate heterogeneity and high heterogeneity, respectively (25). When the heterogeneity was significant, meta-analysis was performed under a random effects model. The results were presented in the form of forest plots; when the results suggested high heterogeneity, we carried out meta-regression subgroup analyses and sensitivity analyses to explore the cause of heterogeneity. Meta-regression and subgroup analyses were performed based on the types of NIRS devices used, number of patients, and types of treatment. We drew a funnel plot to detect publication bias only when more than 10 studies were included and used Egger’s test to assess funnel plot asymmetry quantitatively (26). For all analyses, P<0.05 was considered statistically significant.


Results

The search and methodological quality assessment

Based on our search strategy, 1,590 articles were retrieved from the PubMed, Cochrane Library, and Embase databases (Figure 1). The number of papers remaining after removing duplicates was 1,115. A total of 47 papers were left after we excluded editorials, reviews, animal experiments, comments, conference papers, non-English language articles, and irrelevant articles through reading of the titles and abstracts. After full text screening of the remaining articles, and additional 24 articles were excluded. Two articles lacked a description of NIRS devices; 8 articles included patients without CHD; 8 articles lacked a comparison between rScO2 and SjvO2 as well as ScvO2; and data in 6 articles could not be extracted. A total of 23 studies with 997 children from 1995 to 2022 were eligible for inclusion (8,10,27-47). The search flowchart of this meta-analysis is shown in Figure 1. Since we excluded non-English language articles, there was language bias in this study.

Figure 1 Search flowchart.

Regarding the methodological quality assessment, the scores of the included studies as assessed by the 11-item checklist recommended by AHRQ are given in Table 1. Among them, 4 studies were of high quality, and the remainder were of intermediate quality.

Table 1

Characteristics of the included studies

Author Year Study design Cases Data points Median age (range) Types of treatment Diagnosis [n] Sites of NIRS NIRS devices Types of venous oxygen saturation 95% LOA (%) Quality scores
Yoxall (27) 1995 Cross-sectional study 15 150 2 (0.3–14.0) y Cardiac catheterization PDA [3], VSD [4], after corrective surgery [3], PH [1], complex cyanotic banalities [4] Right fronto-temporal NIRO 500 (Hamamatsu Photonics, Japan) SjvO2 −18.8 to 20.5 6
Daubeney (28) 1996 Cross-sectional study 40 147 4.5 (0.04–14.5) y Cardiac catheterization or cardiac surgery under CPB Acyanotic and cyanotic forms of congenital heart disease Bilateral forehead INVOS 3100 (Somanetics Corp., Troy, MI, USA) SjvO2 NA 6
Nagdyman (10) 2004 Cross-sectional study 43 70 2.8 (0.02–16.8) y Cardiac corrective surgery ASD [16], VSD [13], complete endocardial cushion defect [1], AS [6], MS [3], CoA [1], complex congenital heart defect [9], HOC [1], PS [2] Supra-orbital region NIRO 300 (Hamamatsu Photonics, Japan) ScvO2 NA 6
Nagdyman (29) 2005 Cross-sectional study 60 60 4.4 (0.1–16.0) y Cardiac Catheterization ASD [14], VSD [6], complete endocardial cushion defect [7], AS [3], MS [2], CA [2], complex congenital heart defects [8], HCM [2], TGA [6], TOF [10] Right forehead NIRO 300 (Hamamatsu Photonics, Japan) SjvO2 −15.3 to 11.7 8
Shimizu (30) 2005 Cross-sectional study 5 14 0.6 (0.2–1.3) y Cardiac surgery under CPB TGA [1], VSD [1], AVSD [1], TOF [2] Forehead NIRO 300 (Hamamatsu Photonics, Japan) SjvO2 −17.8 to 11.0 7
Tortoriello (31) 2005 Cross-sectional study 20 100 0.8 (0.4–8.0) y Reparative or palliative cardiac surgery under CPB HLHS [5], PA [6], BTS [7], BDG [4], PHTN [3], CAVC [3] Right, left, or bilateral forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −10.1 to 13.4 6
Bhutta (32) 2007 Cross-sectional study 29 52 8.6 (1.3–17.0) y Cardiac catheterization, myocardial biopsy post-orthotopic heart transplant [29] Forehead INVOS 5100B (Somanetics Corp., Troy, MI, USA) ScvO2 −12.5 to 16.3 7
Kirshbom (33) 2007 Cross-sectional study 20 20 0.6 (NA) y Cardiac catheterization HLHS [8], PA or TA [10], DORV variants [2] Bilateral forehead INVOS (Somanetics Corp., Troy, MI) ScvO2 NA 6
McQuillen (34) 2007 Cross-sectional study 70 NA 0.3 (0.01–1.2) y Cardiac surgery under CPB AVSD [10], TGA [8], TOF [8], VSD [5], ASD [3], PA [3], truncus arteriosus [2], TAPVD [2], PS [1], PDA [1], AI [1], CoA [4], IAA [1], TA/PA [5], RAI [2], TA [1], Ebstein’s anomaly [1], HLHS [7], uAVSD [2], HRV [2] Left forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −25.6 to 23.5 7
Knirsch (35) 2008 Cross-sectional study 60 120 4.3 (0.2–16.0) y Cardiac catheterization CHD [60] Right forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −15.5 to 15.9 6
SjvO2 −18.6 to 17.4
Nagdyman (36) 2008 Cross-sectional study 30 36
60
3.1 (0.1–16.0) y Cardiac catheterization ASD [6], VSD [2], PDA [1], heart transplantation [5], complex congenital heart defects [8], cardiomyopathy [2], TGA [1], TOF [6] Left forehead NIRO 200 (Hamamatsu Photonics, Tokyo, Japan) ScvO2 −20.1 to 10.3 8
SjvO2 −20.1 to 15.7
Ranucci (37) 2008 Cross-sectional study 15 117 1.5 (0.02–7.0) y Cardiac surgery under CPB ASD [2], VSD [3], TOF [5], TAPVR [1], CPC [2], AS [2] Forehead INVOS (Somanetics Corp., Troy, MI, USA) ScvO2 −15.2 to 26.4 8
Ricci (38) 2010 Cross-sectional study 100 890 13.0 (NA) days Cardiac surgery under CPB TGA [39], HLHS and UVH [26], TOF [24], other diagnosis [11] Right forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −25.0 to 25.0 5
Ginther (39) 2011 Cross-sectional study 8 690 8.1 (2.0–15.0) y Bicaval cardiac catheterization PS [2], AS [2], VSD [1], ASD [1], MR [1], RV-PA conduit insufficiency and stenosis [1] Right forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 NA 6
Marimón (40) 2012 Cross-sectional study 20 605 4.5 (0.02–16.3) y Cardiac surgery under CPB TOF [4], atrioventricular canal defect [4], VSD [2], TA [1], aortic vascular ring [1], AS [1], CoA [1], ASD [1], HLHS [3], TOF with MAPCA and VSD [2] Forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 NA 6
Hansen (41) 2013 Cross-sectional study 32 NA 0.2 (0.1–0.80) y Superior cavopulmonary anastomosis with CPB HLHS [26], MA [2], TGA [1], DILV [1], DORV [1], AS [1] Midline forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −17.9 to 19.8 5
Moreno (8) 2013 Cross-sectional study 23 980 12.0 (2–46) d Open heart surgery HLHS [8], TGA [6], TAPVC [5], IAA with VSD [2], multiple VSD [1], TA [1] Forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −17.2 to 38.1 7
Iodice (42) 2014 Cross-sectional study 10 36 2.2 (0.1–8.5) y Cardiac surgery under CPB MR [1], PA with VSD [1], TGA [2], IAA [1], TA [2], TOF [1], MS [1], univentricular heart with HAA [1] Forehead INVOS 5100 (Somanetics Corp., Troy, MI, USA) ScvO2 −13.0 to 10.0 5
Kussman (43) 2017 Cross-sectional study 57 NA 4.8 (NA) y Cardiac catheterization Acyanotic or cyanotic congenital heart disease [57] Forehead FORE-SIGHT (CASMED, Inc., Branford, CT, USA) SjvO2 −7.7 to 9.9 7
Naguib (44) 2017 Cross-sectional study 34 361 3.5 (NA) y Cardiac surgery utilizing CPB and require bicaval cannulation VSD [24], ASD [6], ASD + VSD [12], AVSD [9], BDG [3], Fontan [3], valve replacement [18], TOF [12], subaortic membrane resection [3], cortriatriatum [6], Ebstein’s anomaly [3], aortic arch augmentation [3] Right and left forehead FORE-SIGHT (P/N 01-06-2030C; CASMED, Inc., Branford, CT, USA) SjvO2 NA 8
Rescoe (45) 2017 Cross-sectional study 73 520 7.9 (NA) d Stage 1 palliation under CPB HLHS [73] Forehead FORE-SIGHT (CASMED, Inc., Branford, CT, USA) ScvO2 −17.6 to 34.1 7
Gagnon (46) 2020 Cross-sectional study 47 506 11.3 (NA) d Stage 1 palliation under CPB HLHS [38], DILV [4], TA [3], others [2] Forehead FORE-SIGHT ELITE (CASMED, Inc., Branford, CT, USA) ScvO2 −10.6 to 38.6 6
Terada (47) 2022 Cross-sectional study 186 NA 6.0 (NA) y Cardiac catheterization ASD [16], VSD [54], AVSD [9], AS [8], PA [2], PDA [4], TAPVR [3], TGA [15], TOF [16), DORV [1], Single right ventricle [14], Single left ventricle [18], others [10] Forehead INVOS 5100C (Covidien, Tokyo, Japan) ScvO2, SjvO2 NA 4

NIRS, near-infrared spectroscopy; LOA, limits of agreement; PDA, patent ductus arteriosus; VSD, ventricular septal defect; PH, pulmonary hypertension; SjvO2, jugular bulb venous oxygen saturation; CPB, cardiopulmonary bypass; ASD, atrial septal defect; AS, aortic stenosis; MS, mitral stenosis; ScvO2, central venous oxygen saturation; HOC, hypertrophic obstructive cardiomyopathy; PS, pulmonary stenosis; HCM, hypertrophic cardiomyopathy; TGA, transposition of great arteries; TOF, tetralogy of Fallot; AVSD, atrioventricular septal defect; NA, not available; HLHS, hypoplastic left heart syndrome; PA, pulmonary atresia; BTS, Blalock-Taussig shunt; BDG, bidirectional Glen; PHTN, pulmonary hypertension; CAVC, complete atrioventricular canal; TA, tricuspid atresia; DORV, double outlet right ventricle; TAPVD, total anomalous pulmonary venous drainage; AI, aortic insufficiency; CoA, coarctation of aorta; IAA, interrupted aortic arch; RAI, right atrial isomerism; uAVSD, unbalanced atrioventricular septal defect; HRV, hypoplastic right ventricle; CHD, congenital heart disease; TAPVR, total anomalous pulmonary venous return; CPC, cavo-pulmonary connection; MA, mitral atresia; DILV, double inlet left ventricle; TAPVC, total anomalous pulmonary venous connection; INVOS, a type of NIRS device; NIRO, a type of NIRS device; FORE-SIGHT, a type of NIRS device.

Descriptors

The studies included in this meta-analysis are listed in Table 1. All 23 included articles were cross-sectional studies. There were a total of 997 participants in the 23 included studies. The sample sizes ranged from 5 to 186. The ages of patients were spread over a broad range in each study. The mean age ranged from 7.9 days to 8.6 years. Studies were carried out in diverse countries, including the UK, USA, Germany, Italy, Argentina, Canada, and Japan. The treatment for CHD involved 2 approaches: 9 studies used cardiac catheterization; 13 studies used cardiac surgery under cardiopulmonary bypass; and 1 study included patients undergoing cardiac surgery or cardiac catheterization. The devices of NIRS mentioned in the involved studies were the NIRO 500/300/200 (Hamamatsu Photonics, Hamamatsu, Japan), the INVOS 3100/5100 (Somanetics Corp., Troy, MI, USA), the INVOS (Covidien, Boulder, CO, USA), the INVOS 5100C (Covidien, Tokyo, Japan), the FORE-SIGHT (CAS Medical Systems, Inc, Branford, CT, USA), and the FORE-SIGHT ELITE (CAS Medical Systems, Inc., Branford, CT, USA). The INVOS 5100C and FORE-SIGHT were approved by the FDA for use in pediatric patients. The NIRS probes were placed over the forehead of patients.

Main outcomes

The pooled Cohen’s d with 95% CIs as well as the I2 for the rScO2vs. ScvO2 group and the rScO2 vs SjvO2 group were performed under a random effects model (Figures 2,3).

Figure 2 Cohen’s d between rScO2 and ScvO2. CI, confidence interval; rScO2, cerebral regional oxygen saturation; ScvO2, central venous oxygen saturation.
Figure 3 Cohen’s d between rScO2 and SjvO2. CI, confidence interval; rScO2, cerebral regional oxygen saturation; SjvO2, jugular venous oxygen saturation.

The pooled Cohen’s d was 0.06 (95% CI: −0.16 to 0.28; Figure 2) in the rScO2 versus the ScvO2 group and 0.03 (95% CI: −0.25 to 0.31; Figure 3) in the rScO2 versus the SjvO2 group, which indicated no statistically significant difference between the Cohen’s d of rScO2 measured by NIRS and ScvO2 as well as SjvO2 measured by invasive approaches. The heterogeneity for the rScO2vs. ScvO2 group was high (I2=76.0%, P<0.001), and the heterogeneity for the rScO2vs. the SjvO2 group was intermediate (I2=73.6%, P<0.001). The fixed effects model showed that the rScO2 was positively correlated with the ScvO2 (Fisher’s Z =0.67, 95% CI: 0.60 to 0.74; Figure 4) with an r value of 0.58 (95% CI: 0.54 to 0.63) after Fisher’s Z transformation. Accordingly, rScO2 and SjvO2 were correlated (Fisher’s Z =0.70, 95% CI: 0.61 to 0.79; r=0.60, 95% CI: 0.54 to 0.66; Figure 5). The heterogeneity was within the acceptable range in the rScO2vs. ScvO2 group (I2=36.7%, P=0.065) and the rScO2vs. SjvO2 group (I2=12.7%, P=0.328).

Figure 4 Fisher’s Z between rScO2 and ScvO2. CI, confidence interval; rScO2, cerebral regional oxygen saturation; ScvO2, central venous oxygen saturation.
Figure 5 Fisher’s Z between rScO2 and SjvO2. CI, confidence interval; rScO2, cerebral regional oxygen saturation; SjvO2, jugular venous oxygen saturation.

Sixteen of the included studies performed Bland-Altman’s analysis to discuss the consistencies between rScO2 and SjvO2 or rScO2 and ScvO2. The 95% LOA of each study is summarized in Table 1, and it was fairly wide in most studies. Among them, 3 studies postulated that a difference of ±5% was considered clinically acceptable (8,29,36). Apparently, consistencies between rScO2 and SjvO2 or rScO2 and ScvO2 were poor in these studies with this standard. With one exception, Shimizu et al. declared that rScO2 and SjvO2 showed a reasonable consistency because the difference in the two parameters within the limits of ±10% accounted for 86% (30). Notably, this study only included 5 patients with 14 data points which was unrepresentative.

Publication bias

To assess publication bias, we drew funnel plots for the meta-analyses of Cohen’s d and Fisher’s Z only in the rScO2vs. ScvO2 group (Figure 6). Since there were fewer than 10 studies in the rScO2vs. SjvO2 group, we did not analyze publication bias in this group. Egger’s tests revealed no evidence of publication bias (P=0.76 for Cohen’s d analysis between rScO2 and ScvO2; P=0.067 for Fisher’s Z analysis between rScO2 and ScvO2).

Figure 6 Funnel plot with pseudo 95% confidence limits for Cohen’s d and Fisher’s Z. (A) Cohen’s d between rScO2 and ScvO2; (B) Fisher’s Z between rScO2 and ScvO2. rScO2, cerebral regional oxygen saturation; ScvO2, central venous oxygen saturation.

Sensitivity analyses, meta-regression, and subgroup analyses

Removal of any one of the studies alone did not significantly affect the overall results, which suggested that the results of this meta-analysis were stable (Figures S1-S4). In view of the low heterogeneity of Fisher’s Z analyses, further analysis was not carried out. As relatively significant heterogeneity existed in Cohen’s d analyses in both the rScO2 versus ScvO2 and the rScO2 versus SjvO2 groups, we conducted meta-regression to explore the cause. As a result, the types of NIRS devices were related to high heterogeneity of Cohen’s d in the rScO2 versus ScvO2 group (P<0.001), whereas the number of patients (P=0.67) and the types of treatment (P=0.46) were not related. The meta-regression result of Cohen’s d in the rScO2 versus SjvO2 group also indicated that the types of NIRS devices were responsible for the heterogeneity (P<0.001), and that the number of patients (P=0.98) and types of treatment (P=0.88) were not responsible.

In the analyses of the rScO2 versus ScvO2 group, significant heterogeneity was noted between the 3 subgroups of types of NIRS devices (P<0.001), and, among them, the FORE-SIGHT subgroup had the highest heterogeneity (I2=67.3%, P<0.001). After removal of studies using the FORE-SIGHT device (45,46), the I2 was reduced to 43.9% (P=0.04). Similarly, in the analyses of the rScO2 versus SjvO2 group, heterogeneity between different types of NIRS devices was significant (P=0.03, and the heterogeneity of the FORE-SIGHT subgroup was high (I2=79.9%, P=0.03). The I2 decreased to 0.0% (P=0.76) when studies of the FORE-SIGHT subgroup were removed (43,44). No significant heterogeneity existed between the number of patients and the types of treatment subgroups. The results of subgroup analyses can be found in Table 2.

Table 2

Subgroup analysis

Subgroup Number of studies Cohen’s d, (95% CI) P value I2 Heterogeneity between subgroups, P
Number of patients
   rScO2vs. ScvO2 0.264
    Patients ≤20 6 −0.10 (−0.40, 0.20) 0.496 6.30%
    Patients >20 11 0.13 (−0.15, 0.40) 0.362 83.40%
   rScO2vs. SjvO2 0.508
    Patients ≤20 2 −0.17 (−0.80, 0.45) 0.583 0.00%
    Patients >20 7 0.06 (−0.25, 0.37) 0.7 79.80%
Types of treatment
   rScO2vs. ScvO2 0.108
    Cardiac surgery under CPB 11 0.17 (−0.15, 0.49) 0.294 80.60%
    Cardiac catheterization 6 −0.13 (−0.32, 0.05) 0.166 17.10%
   rScO2vs. SjvO2 0.639
    Cardiac surgery under CPB 2 0.17 (−0.29, 0.64) 0.467 2.40%
    Cardiac catheterization 6 0.03 (−0.34, 0.40) 0.869 82.50%
Types of NIRS devices
   rScO2vs. ScvO2 <0.001
    NIRO 2 −0.56 (−0.89, −0.23) 0.001 0.00%
    INVOS 13 −0.00 (−0.15, 0.14) 0.952 25.30%
    FORE-SIGHT 2 0.86 (0.38, 1.33) <0.001 67.30%
   rScO2vs. SjvO2 0.032
    NIRO 4 −0.29 (−0.55, −0.03) 0.031 0.00%
    INVOS 3 −0.03 (−0.20, 0.13) 0.699 0.00%
    FORE-SIGHT 2 0.63 (−0.05, 1.32) 0.071 79.90%

NIRS, near-infrared spectroscopy; CI, confidence interval; rScO2, cerebral regional oxygen saturation; ScvO2, central venous oxygen saturation; SjvO2, jugular venous saturation; CPB, cardiopulmonary bypass; NIRO, a type of NIRS device; INVOS, a type of NIRS device; FORE-SIGHT, a type of NIRS device.


Discussion

This systematic review and meta-analysis assessed the validity of NIRS in measuring rScO2 in children with CHD undergoing surgery and the interchangeability between NIRS and common invasive approaches that measure SjvO2 and ScvO2. After removing studies that met the exclusion criteria, such as reviews, animal experiments, non-English language articles, unpublished articles and irrelevant articles, we included 23 studies of intermediate to high quality. No evidence of publication bias was observed. No statistically significant difference was found between rScO2 and SjvO2 and between rScO2 and ScvO2 in the pediatric patients with CHD and NIRS rScO2 was positively correlated with the saturation of jugular bulb blood and central venous blood. The results indicated that NIRS exhibited comparative accuracy to a certain extent. Nevertheless, significant heterogeneity was found in the results, which could be attributed to variation in the diverse NIRS devices, especially the FORE-SIGHT device, used in the measurement of rScO2. This shortcoming detracted from the validity of the research. Besides, in terms of Bland-Altman’s analysis, the 95% LOAs of most studies were wide, which suggested that the interchangeability between NIRS and SjvO2 as well as ScvO2 was up for debate.

Through the application of sensitivity analyses, meta-regression, and subgroup analyses to investigate the cause of heterogeneity, we learned that different NIRS devices calculate rScO2 through different algorithms. The NIRO device calculates the tissue oxygenation index (TOI) through spatially resolved spectroscopy by the equation TOI = HbO2/(HbO2 + HHb) × 100 (48,49). The INVOS device calculates rScO2 according to the ratio of oxyhemoglobin to total hemoglobin (47,50). In the FORE-SIGHT device, cerebral mixed arterial-venous oxygen saturation is measured by the different absorption of oxygenated and deoxygenated hemoglobin to near-infrared light, thus detecting rScO2 by the formula rScO2 = 0.3 SaO2 + 0.7 ScvO2 or rScO2 = 0.3SaO2 + 0.7 SjvO2 according to a 30% arterial to 70% venous ratio (45,51,52). The effectiveness of monitoring cerebral oxygen saturation varies from device to device. Theoretically, NIRS monitors oxygenation saturation at the tissue and cellular level; at the cellular level, cytochrome aa3 is a key variable to measure changes in mitochondrial oxygenation (53). However, the INVOS 3100 device cannot provide information about this parameter on account of technical difficulties, whereas the NIRO 500 device not only measures the level of cytochrome aa3 but also monitors the oxygenation state of hemoglobin (54). In addition, Naguib et al. (44) reported that the FORESIGHT device had higher sensitivity, whereas the INVOS device had better specificity. The use of different algorithms among commercial NIRS devices makes comparing the rScO2 of the devices difficult, and industry standards among devices are lacking.

This study has reference significance for the application of NIRS in clinical practice to monitor cerebral oxygen saturation properly in children with CHD undergoing surgery. The results of our study revealed that rScO2 measured by NIRS reflected the SjvO2 and ScvO2 measured by co-oximetry in the perioperative period of children with CHD to a certain extent. However, the agreement between NIRS and invasive oxygen saturation measurements was below expectation, and the LOA was wide, which indicated that NIRS cannot replace SjvO2 and ScvO2. The NIRS method has inherent limitations that restrict its application. As a monitoring tool, NIRS is affected by factors such as hemoglobin, blood volume, arterial blood pressure (55), cardiac output, arterial oxyhemoglobin saturation, the position of the probe head, body position, and vasoactive drugs (19). Due to the discrepancy in sensor technology, near infrared wavelength, fixed arterio-venous (A/V) ratio, and reference values of different NIRS devices, each manufacturer lacks large sample data to determine reference values of cerebral oxygen, which is the major limitation in NIRS validation. Studies have found that the A/V ratio differed among subjects, which implies that a fixed A/V ratio is not appropriate for validating the technology (56).

Despite the limitations of NIRS, the ability of providing noninvasive continuous monitoring for cerebral oxygen saturation is of importance and the potential to identify cerebral ischemic events is prominent. Venous thrombosis, infection, and extracerebral contamination are common and intractable problems of invasive measurements, which can be avoid by using NIRS (57,58). NIRS has been extensively used in pediatric patients undergoing cardiovascular operations with a high risk of compromised cerebral perfusion (59). Cruz et al. (60) reported that the variance of peripheral capillary oxygen saturation (SpO2) was larger than that of NIRS, meaning that NIRS monitoring was more stable and better at predicting events. Similar results were replicated in a 24-hour observational study that found NIRS superior to SpO2 in monitoring hypoxia and ischemic events (61). Moerman et al. (62) demonstrated that NIRS monitoring identified compromised cerebral perfusion despite hemodynamic measurements being normal. However, Robust studies, including randomized clinical trials, are needed to prove the clinical benefit of NIRS. There is still no evidence that early monitoring of cerebral oxygenation during pediatric surgery under general anesthesia improves prognosis after surgery (63). A systematic review of surgical treatment of pediatric CHD concluded that the benefit and cost-effectiveness of NIRS monitoring and management capable of improving short-term clinical neurological outcomes has not yet been demonstrated (64). Zheng et al. (65) reported that the correlation between decreased rScO2 and postoperative neurological complications was low, and improving rScO2 desaturation in attempts to prevent stroke, delirium, or postoperative cognitive dysfunction could not be supported by available evidence. Future studies should look at solving the heterogeneity problems, that is, setting uniform reference standards among NIRS devices. In addition, more research should attempt to determine whether perioperative monitoring with NIRS can improve postoperative outcomes.

This systematic review and meta-analysis had some limitations. First, the proposed data extraction and analysis method may be inadequate, as the discrepancy in data acquisition led to downstream data issues. We used MATLAB to extract data from images in articles when the MD and SD were not provided. In that case, the ordinate and abscissa values of the scatter points were measured manually, which may have introduced errors. When the scattered points were stacked together, accurately identifying them separately was difficult, and accurately measuring the diameter of the scattered points themselves was challenging. The second limitation was the relatively high heterogeneity in the analyses of Cohen’s d. Under normal circumstances, combining effect size in the case of high heterogeneity due to the broad distribution and variation of sample characteristics is not recommended. However, since we discussed the cause of high heterogeneity through sensitivity analyses, meta-regression, and subgroup analyses, the results were still of reference value. Thirdly, the lack of randomized controlled trials reduced the validity of the study. More high-quality studies are required in this field.


Conclusions

This systematic review and meta-analysis revealed that rScO2 measured by NIRS reflects SjvO2 and ScvO2 recorded by invasive measurements in the perioperative period of children with CHD to some extent. Nevertheless, wide LOA indicated that the interchangeability between NIRS and invasive oxygen saturation measurements was below expectation. Despite the technical limitations of NIRS, it provides a non-invasive, convenient approach for the real-time monitoring of hypoxia, ischemia, and changes in cerebral perfusion. More evidence is needed to prove the possible clinical benefits of NIRS in monitoring cerebral oxygen saturation in children with CHD.


Acknowledgments

Funding: This work was supported by the Sichuan Foundation for Distinguished Young Scholars (No. 2021YFS0242); the Chengdu International Science and Technology Cooperation Funding (No. 2019-GH02-00074-HZ); the Chengdu Science and Technology Bureau (No. 2021-YF05-00698-SN); the 1.3.5 Project for Disciplines of Excellence-Clinical Research Incubation Project, West China Hospital, Sichuan University (No. 2021HXFH035); and the Scientific and Technological Achievements Transformation Fund of West China Hospital, Sichuan University (No. CGZH21002).


Footnote

Reporting Checklist: The authors have completed the MOOSE reporting checklist. Available at https://tp.amegroups.com/article/view/10.21037/tp-22-345/rc

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://tp.amegroups.com/article/view/10.21037/tp-22-345/coif). The authors have no conflicts of interest to declare.

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References

  1. Hirsch JC, Jacobs ML, Andropoulos D, et al. Protecting the infant brain during cardiac surgery: a systematic review. Ann Thorac Surg 2012;94:1365-73; discussion 1373. [Crossref] [PubMed]
  2. Flechet M, Güiza F, Vlasselaers D, et al. Near-Infrared Cerebral Oximetry to Predict Outcome After Pediatric Cardiac Surgery: A Prospective Observational Study. Pediatr Crit Care Med 2018;19:433-41. [Crossref] [PubMed]
  3. Andropoulos DB, Easley RB, Gottlieb EA, et al. Neurologic Injury in Neonates Undergoing Cardiac Surgery. Clin Perinatol 2019;46:657-71. [Crossref] [PubMed]
  4. Kim MJ, Baek JS, Kim JA, et al. Cerebral and Somatic Oxygen Saturation in Neonates with Congenital Heart Disease before Surgery. J Clin Med 2021;10:2455. [Crossref] [PubMed]
  5. Zhu S, Sai X, Lin J, et al. Mechanisms of perioperative brain damage in children with congenital heart disease. Biomed Pharmacother. 2020;132:110957. [Crossref] [PubMed]
  6. McQuillen PS, Barkovich AJ, Hamrick SE, et al. Temporal and anatomic risk profile of brain injury with neonatal repair of congenital heart defects. Stroke 2007;38:736-41. [Crossref] [PubMed]
  7. Yoshitani K, Kawaguchi M, Ishida K, et al. Guidelines for the use of cerebral oximetry by near-infrared spectroscopy in cardiovascular anesthesia: a report by the cerebrospinal Division of the Academic Committee of the Japanese Society of Cardiovascular Anesthesiologists (JSCVA). J Anesth 2019;33:167-96. [Crossref] [PubMed]
  8. Moreno GE, Pilán ML, Manara C, et al. Regional venous oxygen saturation versus mixed venous saturation after paediatric cardiac surgery. Acta Anaesthesiol Scand 2013;57:373-9. [Crossref] [PubMed]
  9. Tweddell JS, Hoffman GM. Postoperative management in patients with complex congenital heart disease. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu 2002;5:187-205. [Crossref] [PubMed]
  10. Nagdyman N, Fleck T, Barth S, et al. Relation of cerebral tissue oxygenation index to central venous oxygen saturation in children. Intensive Care Med 2004;30:468-71. [Crossref] [PubMed]
  11. Milne B, Gilbey T, Gautel L, et al. Neuromonitoring and Neurocognitive Outcomes in Cardiac Surgery: A Narrative Review. J Cardiothorac Vasc Anesth. 2022;36:2098-2113. [Crossref] [PubMed]
  12. Jöbsis FF. Noninvasive, infrared monitoring of cerebral and myocardial oxygen sufficiency and circulatory parameters. Science 1977;198:1264-7. [Crossref] [PubMed]
  13. Hirsch JC, Charpie JR, Ohye RG, et al. Near-infrared spectroscopy: what we know and what we need to know--a systematic review of the congenital heart disease literature. J Thorac Cardiovasc Surg 2009;137:154-9, 159e1-12.
  14. Smith M, Elwell C. Near-infrared spectroscopy: shedding light on the injured brain. Anesth Analg 2009;108:1055-7. [Crossref] [PubMed]
  15. Ghosh A, Elwell C, Smith M. Review article: cerebral near-infrared spectroscopy in adults: a work in progress. Anesth Analg 2012;115:1373-83. [Crossref] [PubMed]
  16. Diop M, Verdecchia K, Lee TY, et al. Calibration of diffuse correlation spectroscopy with a time-resolved near-infrared technique to yield absolute cerebral blood flow measurements. Biomed Opt Express 2011;2:2068-81. [Crossref] [PubMed]
  17. Nasr VG, Bergersen LT, Lin HM, et al. Validation of a Second-Generation Near-Infrared Spectroscopy Monitor in Children With Congenital Heart Disease. Anesth Analg 2019;128:661-8. [Crossref] [PubMed]
  18. Zaleski KL, Kussman BD. Near-Infrared Spectroscopy in Pediatric Congenital Heart Disease. J Cardiothorac Vasc Anesth. 2020;34:489-500. [Crossref] [PubMed]
  19. Bickler PE, Feiner JR, Rollins MD. Factors affecting the performance of 5 cerebral oximeters during hypoxia in healthy volunteers. Anesth Analg 2013;117:813-23. [Crossref] [PubMed]
  20. Stroup DF, Berlin JA, Morton SC, et al. Meta-analysis of observational studies in epidemiology: a proposal for reporting. Meta-analysis Of Observational Studies in Epidemiology (MOOSE) group. JAMA 2000;283:2008-12. [Crossref] [PubMed]
  21. Kadel RP, Kip KE. A SAS macro to compute effect size (Cohen's) and its confidence interval from raw survey data. South East SAS Users Group (SESUG). 2012.
  22. Rupinski MT, Dunlap WP. Approximating Pearson product-moment correlations from Kendall's Tau and Spearman's Rho. Educ Psychol Meas 1996;56:419-29. [Crossref]
  23. Rostom A, Dubé C, Cranney A, et al. Rockville (MD): Agency for Healthcare Research and Quality (US); 2004. Available online: https://www.ncbi.nlm.nih.gov/books/NBK35156
  24. Hu J, Dong Y, Chen X, et al. Prevalence of suicide attempts among Chinese adolescents: A meta-analysis of cross-sectional studies. Compr Psychiatry 2015;61:78-89. [Crossref] [PubMed]
  25. Higgins JP, Thompson SG, Deeks JJ, et al. Measuring inconsistency in meta-analyses. BMJ 2003;327:557-60. [Crossref] [PubMed]
  26. Egger M, Davey Smith G, Schneider M, et al. Bias in meta-analysis detected by a simple, graphical test. BMJ 1997;315:629-34. [Crossref] [PubMed]
  27. Yoxall CW, Weindling AM, Dawani NH, et al. Measurement of cerebral venous oxyhemoglobin saturation in children by near-infrared spectroscopy and partial jugular venous occlusion. Pediatr Res 1995;38:319-23. [Crossref] [PubMed]
  28. Daubeney PE, Pilkington SN, Janke E, et al. Cerebral oxygenation measured by near-infrared spectroscopy: comparison with jugular bulb oximetry. Ann Thorac Surg 1996;61:930-4. [Crossref] [PubMed]
  29. Nagdyman N, Fleck T, Schubert S, et al. Comparison between cerebral tissue oxygenation index measured by near-infrared spectroscopy and venous jugular bulb saturation in children. Intensive Care Med 2005;31:846-50. [Crossref] [PubMed]
  30. Shimizu N, Gilder F, Bissonnette B, et al. Brain tissue oxygenation index measured by near infrared spatially resolved spectroscopy agreed with jugular bulb oxygen saturation in normal pediatric brain: a pilot study. Childs Nerv Syst 2005;21:181-4. [Crossref] [PubMed]
  31. Tortoriello TA, Stayer SA, Mott AR, et al. A noninvasive estimation of mixed venous oxygen saturation using near-infrared spectroscopy by cerebral oximetry in pediatric cardiac surgery patients. Paediatr Anaesth 2005;15:495-503. [Crossref] [PubMed]
  32. Bhutta AT, Ford JW, Parker JG, et al. Noninvasive cerebral oximeter as a surrogate for mixed venous saturation in children. Pediatr Cardiol 2007;28:34-41. [Crossref] [PubMed]
  33. Kirshbom PM, Forbess JM, Kogon BE, et al. Cerebral near infrared spectroscopy is a reliable marker of systemic perfusion in awake single ventricle children. Pediatr Cardiol 2007;28:42-5. [Crossref] [PubMed]
  34. McQuillen PS, Nishimoto MS, Bottrell CL, et al. Regional and central venous oxygen saturation monitoring following pediatric cardiac surgery: concordance and association with clinical variables. Pediatr Crit Care Med 2007;8:154-60. [Crossref] [PubMed]
  35. Knirsch W, Stutz K, Kretschmar O, et al. Regional cerebral oxygenation by NIRS does not correlate with central or jugular venous oxygen saturation during interventional catheterisation in children. Acta Anaesthesiol Scand 2008;52:1370-4. [Crossref] [PubMed]
  36. Nagdyman N, Ewert P, Peters B, et al. Comparison of different near-infrared spectroscopic cerebral oxygenation indices with central venous and jugular venous oxygenation saturation in children. Paediatr Anaesth 2008;18:160-6. [PubMed]
  37. Ranucci M, Isgrò G, De la Torre T, et al. Near-infrared spectroscopy correlates with continuous superior vena cava oxygen saturation in pediatric cardiac surgery patients. Paediatr Anaesth 2008;18:1163-9. [Crossref] [PubMed]
  38. Ricci Z, Garisto C, Favia I, et al. Cerebral NIRS as a marker of superior vena cava oxygen saturation in neonates with congenital heart disease. Paediatr Anaesth 2010;20:1040-5. [Crossref] [PubMed]
  39. Ginther R, Sebastian VA, Huang R, et al. Cerebral near-infrared spectroscopy during cardiopulmonary bypass predicts superior vena cava oxygen saturation. J Thorac Cardiovasc Surg 2011;142:359-65. [Crossref] [PubMed]
  40. Marimón GA, Dockery WK, Sheridan MJ, et al. Near-infrared spectroscopy cerebral and somatic (renal) oxygen saturation correlation to continuous venous oxygen saturation via intravenous oximetry catheter. J Crit Care 2012;27:314.e13-8. [Crossref] [PubMed]
  41. Hansen JH, Schlangen J, Armbrust S, et al. Monitoring of regional tissue oxygenation with near-infrared spectroscopy during the early postoperative course after superior cavopulmonary anastomosis. Eur J Cardiothorac Surg 2013;43:e37-43. [Crossref] [PubMed]
  42. Iodice FG, Ricci Z, Haiberger R, et al. Fiberoptic monitoring of central venous oxygen saturation (PediaSat) in small children undergoing cardiac surgery: continuous is not continuous. F1000Res 2014;3:23. [Crossref] [PubMed]
  43. Kussman BD, Laussen PC, Benni PB, et al. Cerebral Oxygen Saturation in Children With Congenital Heart Disease and Chronic Hypoxemia. Anesth Analg 2017;125:234-40. [Crossref] [PubMed]
  44. Naguib AN, Winch PD, Sebastian R, et al. The Correlation of Two Cerebral Saturation Monitors With Jugular Bulb Oxygen Saturation in Children Undergoing Cardiopulmonary Bypass for Congenital Heart Surgery. J Intensive Care Med 2017;32:603-8. [Crossref] [PubMed]
  45. Rescoe E, Tang X, Perry DA, et al. Cerebral near-infrared spectroscopy insensitively detects low cerebral venous oxygen saturations after stage 1 palliation. J Thorac Cardiovasc Surg 2017;154:1056-62. [Crossref] [PubMed]
  46. Gagnon MH, Kussman BD, Zhou L, et al. Sensitivity of a Next-Generation NIRS Device to Detect Low Mixed Venous Oxyhemoglobin Saturations in the Single Ventricle Population. Anesth Analg 2020;131:e138-41. [Crossref] [PubMed]
  47. Terada K, Nakamura S, Nakao Y, et al. Cerebral hemoglobin oxygenation in children with congenital heart disease. Pediatr Int 2022;64:e14726. [Crossref] [PubMed]
  48. Yagi T, Kawamorita T, Kuronuma K, et al. Usefulness of a New Device to Monitor Cerebral Blood Oxygenation Using NIRS During Cardiopulmonary Resuscitation in Patients with Cardiac Arrest: A Pilot Study. Adv Exp Med Biol. 2020;1232:323-329. [Crossref] [PubMed]
  49. Gagnon RE, Macnab AJ, Gagnon FA, et al. Comparison of two spatially resolved NIRS oxygenation indices. J Clin Monit Comput 2002;17:385-91. [Crossref] [PubMed]
  50. Ziehenberger E, Urlesberger B, Binder-Heschl C, et al. Near-infrared spectroscopy monitoring during immediate transition after birth: time to obtain cerebral tissue oxygenation. J Clin Monit Comput 2018;32:465-9. [Crossref] [PubMed]
  51. Schneider A, Hofstätter E, Brandner J, et al. Benchmarking of Four Near Infrared Spectroscopy Devices for Long Time Use in Neonates. Klin Padiatr. 2018;230:240-244. [Crossref] [PubMed]
  52. Benni PB, Chen B, Dykes FD, et al. Validation of the CAS neonatal NIRS system by monitoring vv-ECMO patients: preliminary results. Adv Exp Med Biol 2005;566:195-201. [Crossref] [PubMed]
  53. du Plessis AJ, Newburger J, Jonas RA, et al. Cerebral oxygen supply and utilization during infant cardiac surgery. Ann Neurol 1995;37:488-97. [Crossref] [PubMed]
  54. Wollert HG, Eckel L. Cerebral oxygenation measured by near-infrared spectroscopy. Ann Thorac Surg 1997;63:292-author reply 292-3. [PubMed]
  55. Sørensen H, Secher NH, Rasmussen P. A note on arterial to venous oxygen saturation as reference for NIRS-determined frontal lobe oxygen saturation in healthy humans. Front Physiol 2013;4:403. [PubMed]
  56. Watzman HM, Kurth CD, Montenegro LM, et al. Arterial and venous contributions to near-infrared cerebral oximetry. Anesthesiology 2000;93:947-53. [Crossref] [PubMed]
  57. Alten J, Mariscalco MM. Critical appraisal of Perez et al: Jugular venous oxygen saturation or arteriovenous difference of lactate content and outcome in children with severe traumatic brain injury. Pediatr Crit Care Med 2005;6:480-2. [Crossref] [PubMed]
  58. Berman W Jr, Fripp RR, Yabek SM, et al. Great vein and right atrial thrombosis in critically ill infants and children with central venous lines. Chest 1991;99:963-7. [Crossref] [PubMed]
  59. Scheeren TWL, Kuizenga MH, Maurer H, et al. Electroencephalography and Brain Oxygenation Monitoring in the Perioperative Period. Anesth Analg 2019;128:265-77. [Crossref] [PubMed]
  60. Cruz SM, Akinkuotu AC, Rusin CG, et al. A novel multimodal computational system using near-infrared spectroscopy to monitor cerebral oxygenation during assisted ventilation in CDH patients. J Pediatr Surg 2016;51:38-43. [Crossref] [PubMed]
  61. Koch HW, Hansen TG. Perioperative use of cerebral and renal near-infrared spectroscopy in neonates: a 24-h observational study. Paediatr Anaesth 2016;26:190-8. [Crossref] [PubMed]
  62. Moerman A, Meert F, De Hert S. Cerebral near-infrared spectroscopy in the care of patients during cardiological procedures: a summary of the clinical evidence. J Clin Monit Comput 2016;30:901-9. [Crossref] [PubMed]
  63. Nielsen HB. Systematic review of near-infrared spectroscopy determined cerebral oxygenation during non-cardiac surgery. Front Physiol 2014;5:93. [Crossref] [PubMed]
  64. Deschamps A, Lambert J, Couture P, et al. Reversal of decreases in cerebral saturation in high-risk cardiac surgery. J Cardiothorac Vasc Anesth 2013;27:1260-6. [Crossref] [PubMed]
  65. Zheng F, Sheinberg R, Yee MS, et al. Cerebral near-infrared spectroscopy monitoring and neurologic outcomes in adult cardiac surgery patients: a systematic review. Anesth Analg 2013;116:663-76. [Crossref] [PubMed]
Cite this article as: Ma Y, Zhao L, Wei J, Wang Z, Lui S, Song B, Gong Q, Wang P, Wu M. Comparing near-infrared spectroscopy—measured cerebral oxygen saturation and corresponding venous oxygen saturations in children with congenital heart disease: a systematic review and meta-analysis. Transl Pediatr 2022;11(8):1374-1388. doi: 10.21037/tp-22-345

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