Iris Publishers-Open access Journal of Nursing & Care | Comparison of Pulse Oximetry and Capnography Monitoring with Arterial Blood Gases Parameters among Postoperative Pediatric Cardiac Surgeries at a University Hospital

Authored by Nahla Shaaban Khalil

Background: Pediatric patients undergone mechanical ventilation after cardiac surgeries need rapid and reliable evaluation of their respiratory status. Monitoring of pulse oximetery and capnography as a surrogate, noninvasive measurement of arterial oxygen saturation (Sao₂) and arterial carbon dioxide tension (PaCo₂) became important respiratory monitoring.
The aim of the study: Was to compare pulse oximetery and capnography monitoring values with arterial blood gas parameters among postoperative pediatric cardiac surgeries.
Subjects and Methods: A descriptive correlational design was adopted utilizing a convenience sample of 88 pediatric patients with cardiac anomalies who undergoing total repair surgeries, intubated for mechanical ventilation and had an indwelling arterial catheter as part of their evaluation in postoperative period were included in the study. Patient’s demographic, clinical relevant data as well as invasive and noninvasive monitoring of arterial oxygen saturation and arterial carbon dioxide partial pressure were utilized in data collection
Results: Statistical analysis demonstrated mean differences between Sao₂ and Spo₂ (98.2 ±1.6% and 97.5±2.4% respectively; p=0.024)) as well as the mean difference between PaCo₂ and PetCo₂ (36.9±6.9mmHg and 33.1±7.7mmHg respectively; p <0.001). As well, a significant positive correlation was found between the mean Sao₂ and Spo₂ (r= 0.935, p<0.001) as well as, between the mean PaCo₂ and PetCo₂ (r= 0.930, p<0.001).
Conclusion It can be concluded that Spo₂ and EtCo₂ values are positively correlated with Sao₂ and PaCo₂ in mechanically ventilated pediatric patients after cardiac surgeries. Therefore Spo₂ and EtCo₂ monitoring can be used as a continuous, non-invasive predictor for Sao₂ and PaCo₂.

Introduction

Pediatric patients on mechanical ventilation after cardiac surgeries are in a vulnerable period that requiring continuous and comprehensive monitoring and every single change in the patient’s physiological variables are taken into account [1]. Pediatric patients who undergo cardiac surgery are at risk for developing respiratory insufficiency after cardiac surgery as a result of the effects of general anesthesia, the surgical procedure and inflammatory response to cardiopulmonary bypass, therefore, they need careful management of mechanical ventilation for supporting oxygenation and ventilation [2]. Arterial blood gases is the gold standard for the assessment of oxygenation and ventilation [3]. However, there are several complications and limitations of arterial blood sampling which can arise from arterial puncture or presence of indwelling arterial catheter especially in pediatrics which includes local hematoma, artery vasospasm, infection at the puncture site, hemorrhage, arterial occlusion, air or thrombus embolism and local pain. Moreover, sampling is intermittent, timeconsuming and delay in obtaining results which can affect the clinical decision about patient management [4]. Pulse oximetry and capnography technology became monitoring standard in critical care units and commonly useful for accompanying mechanical ventilation management [5]. Pulse oximetry is an effective method for continuous and non-invasive monitoring of arterial oxygen saturation using a probe attached to different body sites which can lead to a more rapid treatment of serious hypoxemia, used for titration of inspired oxygen and wean mechanical ventilation [6]. Capnography is a useful noninvasive and continuous monitoring tool for arterial carbon dioxide tension. PetCo₂ monitoring provides an assessment of the adequacy of ventilation also it can be used for confirming correct ETT placement, early warning for loss of the ventilator circuit integrity and changes in cardiopulmonary status [7]. Hence, the direction towards non-invasive methods for continuous monitoring of Sao₂ and PaCo₂values should be used followed to facilitate clinical diagnosis and treatment. In addition to avoiding complications related to invasive monitoring and helps in reducing medical cost [8].

The Aim of the Study

The main aim of this study was to compare pulse oximetry and capnography (Spo₂ and EtCo₂) monitoring values with arterial blood gas parameters (Sao₂ and PaCo₂) among postoperative mechanically ventilated pediatric patients after cardiac surgeries.

Subjects and Methods

A prospective descriptive correlational design was used to conduct this study. The study was conducted at the pediatric cardiac surgery intensive care unit Mansoura University Child Hospital (MUCH). A Convenience sample of 88 pediatric patients with cardiac anomalies who undergoing total repair surgeries, intubated for mechanical ventilation and had an indwelling arterial catheter as part of their evaluation in postoperative period were included in the study. The exclusion criteria included pediatric patients with low cardiac output, palliative surgeries for cyanotic congenital heart disease, extreme peripheral vasoconstriction and high doses of vasoactive drugs, intravascular dyes, seizures and severe anemia.

Tools of data collection

Demographic data included data related to age, gender, weight, diagnosis and operation type. Moreover, clinical relevant data included monitoring of Cardiovascular parameters such as heart rate (HR), mean arterial pressure (MAP), pulse pressure (PP),core temperature. As well , Ventilator parameters were monitored including as mode of ventilator, respiratory rate (RR), fraction of inspired oxygen (Fio₂), post end expiratory pressure (PEEP), peak inspiratory pressure (PIP), pressure support (PS) and I: E ratio. Finally , checking the hemoglobin level
Tool (2) : invasive and noninvasive monitoring of arterial oxygen saturation and arterial carbon dioxide partial pressure:
Invasive monitoring consisted of Sao₂ and PaCo₂in addition to PH and arterial blood partial pressure of oxygen (pao₂). On the other hand , Noninvasive monitoring included of Spo₂ and PetCo₂.

Validity and Reliability of Tool

Content validity of tools was revised and ensured by a panel of five experts in the field of critical care nursing and medical specialties based on the expert’s opinions; the researcher developed the last validated form of the tools. The developed and validated a tool for invasive and noninvasive monitoring of arterial oxygen saturation and arterial carbon dioxide partial pressure comparison tool was tested for reliability using Cronbach’s test and its value was 0.823.

Pilot Study

A pilot study was done on 10 subjects to test feasibility and clarity of the tools and the necessary modifications were done prior data collection such as in pediatrics, pressure-controlled ventilation was mostly used rather than volume controlled ventilation so tidal volume parameter was canceled. The subjects included in the pilot study were excluded from the whole study sample.

Ethical Consideration

Ethical approval was obtained from the research ethics of the Faculty of Nursing at Mansoura University. An official consent was obtained from hospital administrators at Child Hospital Mansoura University to initiate data collection. Informed consent was obtained from the child’s mother before enrollment in the study after explaining the purpose of the study and emphasized that participation in the study is voluntary.

Data Were Collected in Two Phases

Phase I: Preparatory phase

Adequate preparations for the study subjects and proper calibration for pulse oximetry and capnography were performed as well; the accuracy of the detected waveform by both devices was verified.

Phase II: Implementation phase

The readings were taken after (15-20) minutes of any procedure affecting ABGs results such as after transportation from operating room to ICU and every time changes in ventilator parameters had been performed as the child should be in a respiratory steady state. Later, the simultaneous recording of physiological parameters was recorded before taking Spo₂ and PetCo₂ reading. Then, Spo₂ and Pet Co₂ reading were obtained using monitor (model Infinity Kappa, Drager Medical Systems, Inc. Danvers, MA01923 USA), exhaled Co₂ was continuously monitored through available mainstream capnography and So₂ was monitored through finger probe later, arterial blood sample was drawn from the arterial catheter (within 2 minutes) for Sao₂ and PaCo₂ analysis utilizing arterial blood gas analyzer (Siemens, RAPID point 500, Ny10591-5097 USA).Then, the reading was recorded.

Data Analysis

All statistical analyses were performed using SPSS for windows version 20.0 (SPSS, Chicago, IL). Data were tested for normality of distribution prior to any calculations. Continuous data were expressed in mean ± standard deviation (SD). Categorical data were expressed in number and percentage. The comparisons were determined using Student’s t-test for variables with continuous data while Chi-square test was used for comparison of variables with categorical data. The correlations were tested using the correlation coefficient test. Statistical significance was set at p<0.05.

Results

A total 88 mechanically ventilated pediatric patients were studied. The data collection took approximately ten months from beginning of May 2016 to end of February2017.The age of the studied subjects ranged from 3 months to 143 months, median of the age was 13 months (interquartile range [IQR] 31 months) nearly half of them were infants. As well, more than half of the subjects, (58%) were male while, (42%) were female their body weight range from 4kg-50kg (mean 12.5 ±10.6kg). It found that two thirds of children hadn’t cyanosis pre-operative (68.2%) while, third (28%) of children had cyanosis pre-operative. The baseline physiological variables are summarized in Table 1.
The correlation between Sao₂ and Spo₂ (r= 0.935, p<0.001) is shown in Figure 1, as well as the positive correlation between PaCo₂and ETCo₂ (r= 0.930, p<0.001) is shown in Figure 2. The effect of studied variables on the mean differences between (Sao₂ – SPo₂) and (PaCo₂ – PetCo₂) is illustrated in Table 3 & 7 which showed the mean difference between Sao₂ – SPo₂ was significantly correlated to heart rate (P=0.048); PIP (P=0.004); Pao₂ (P=0.003); Sao₂ (P=0.039) and Spo₂ (P<0.001). Moreover, the mean difference between PaCo₂ andPetCo₂ was also significantly correlated to PIP (P=0.013); Pao₂ P=0.042) and PetCo₂ (P<0.001).

Discussion

The analysis of data in the present study showed that there was a significant difference between the mean Sao₂ and the mean Spo₂ as well as, between the mean PaCo₂and the mean PetCo₂. Regarding pulse oximetry researchers interpreted this difference by the fact that the study findings were obtained from critically ill pediatric patients; the most likely group of patients to exhibit clinical conditions that adversely affect pulse oximetry accuracies such as hypoxemia and hypotension as reported by [10] who studied comparison between pulse oximeters and arterial oxygen saturation in critically ill children. Moreover, another explanation that pulse oximeter manufacturers provide data from studies that have been extensively performed on the accuracy of pulse oximetry in various adult and pediatric patients and them stated that in critically ill patients with Sao₂ values of 90 % or higher, the mean difference between Spo₂ and Sao₂ is less than 2 % however, worsen when Sao₂ is lower than 90 % [16&17].This compatible with the mean difference observed between Spo₂ and Sao₂in the current study as oxygenation status was more than 90 %.As well, regarding capnography there are clinical conditions that occur from general anesthesia and cardiac surgical correction and cause ventilationperfusion( V/Q) mismatching such as pulmonary congestion and atelectasis which affecting on capnography accuracy supported by [18] study who evaluate the difference between ETCo₂ and PaCo₂ in anaesthetized patients and concluded that the difference between PaCo₂ and ETCo₂ can be explained with the theory of ventilation-perfusion mismatch which can occur in patients who are given general anesthesia or have lung diseases. Moreover, another explanation that the difference observed between PaCo₂ and PetCo₂ is congruent with the fact that PETC o₂ physiologically is approximately 2–5 mmHg lower than PaCo₂ so that even in the healthy lung, the difference between PaCo₂ and ETCo₂ is not usually zero [19-20] and this compatible with the mean difference observed between EtCo₂ and PaCo₂ in the current study.
Therefore, the difference between the two measurements is a fact that must be taken in consideration and the mean (PaCo₂- PetCo₂) difference, as well as the mean (Sao₂- Spo₂) difference that observed in current study closely approximates the true physiologic difference and consistent with previously published values.
Further assessment revealed that there was a significant positive correlation was found between two methods of measuring oxyhemoglobin saturation and those two methods of measuring carbon dioxide partial pressure for all studied readings.
Regarding pulse oximetry, because the oxygenation status of the studied subjects in the current study was more than 90% so that, several studies in agreement with the current study finding as, they have shown consistently satisfactory correlation between Sao₂ and Spo₂ readings and less difference was found between two techniques in saturation range from 80-100% such as the study conducted by [21] on the accuracy of pulse oximetry in children. As well, a study was done by [10] who studied the comparison between pulse oximeters and arterial oxygen saturation in critically ill children.
Regarding capnography, previous studies that evaluate the predictive capability of end tidal carbon dioxide monitoring in different clinical settings are in agreement with the current study findings and have shown that EtCo₂ is correlated highly withPaCo₂ , they concluded that EtCo₂ monitoring displayed a good validity to predict PaCo₂ and its use may reduce the need for repeated ABG analysis such as a study observed by [9] whoevaluated the relationship between PaCo₂ and EtCo₂ in critically ill mechanically ventilated neonates and children. As well, in a study done by [22]. on the correlation between PaCo₂ and EtCo₂ in mechanically ventilated patients.However, other study findings have indicated a poor correlation between ETCo₂ with PaCo₂ such as a study observed by [23] who studied noninvasive monitoring of carbon dioxide in infants and children with congenital heart disease, they reported that ETCo₂ measurement not accurate predictor of PaCo₂ in infants and children congenital heart disease especially, in patients with cyanotic but, this study in contrast with the criteria of subjects in the present study as the studied subjects had done surgical correction forcongenital heart defects.
The researchers investigated a number of demographic and clinical variables presumed to affect ventilation and oxygenation and the findings showed that heart rate had a significant effect on differences between Sao₂ -SPo₂ whereas tachycardia was associated with low mean Sao₂ – SPo₂ difference compared with normal heart rate. The researchers interpreted that by the fact that post-operative cardiovascular support is frequently being used in children undergoing heart surgery to improve cardiac output, so the majority of patients were associated with tachycardia as stroke volume in pediatric is rate dependent [24].
The current findings also revealed that PIP has a significant effect on the mean difference between (Sao₂ – SPo₂) and (PaCo₂ – PetCo₂) since, high PIP was associated with the highest mean difference. The researchers interpreted that by the fact that the introduction of positive pressure into the thoracic cavity reduces systemic venous return as a result of progressive increases in mean airway pressure which affects cardiovascular function by produces changes in systemic and pulmonary blood flow [25].
Moreover, the current study found that the difference between (Sao₂ – SPo₂) readings significantly affected by Pao₂ values where the high difference between (Sao₂ – SPo₂) readings affected by low Pao₂these can interpret with low Pao₂ values are associated with low Sao₂ values related to their relationship through the oxygen dissociation curve [6]. Additionally, it was noticed that Sao₂ has a significant effect on the mean Sao₂ – SPo₂ difference since, highest mean Sao₂ – SPo₂ difference was associated with Sao₂ less than 95%. This in agreement with [26] findings who reported that as Sao₂decrease, the higher the rate of disturbances which may occur in accuracy between Spo₂and Sao₂ measurements.
On the other side, it was found that Pao₂ has a significant effect on the mean (PaCo₂ – PetCo₂) difference since high Pao₂ was associated with the lowest (PaCo₂ – PetCo₂) difference. These finding may be attributed to the fact that increase Pao₂ lead to relaxing the pulmonary vasculature by decreasing pulmonary vascular resistance (PVR) to improve pulmonary blood flow [27]. This in agreement with [28] findings who studied pulse oximetry and capnography in lung function laboratories.
Finally, current study findings also revealed that Spo₂ value has a significant effect on the difference between (Sao₂ – SPo₂) and the highest mean Sao₂–Spo₂ difference was associated withSpo₂less than 95%. This is in agreement with the findings of [15] who study the efficacy of non-invasive monitoring of arterial oxygen saturation and carbon dioxide partial pressure in mechanically ventilated patients and pointed out that lack of pulse oximeter accuracy was found, as Spo₂values decreased.
It was also found that the PetCo₂ value has a significant effect on the difference between (PaCo₂ – PetCo₂)readings whereas the highest mean PaCo₂ – PetCo₂ difference was associated with PetCo₂ less than 35 mmHg, this finding may be attributed to the fact that PaCo₂ – PetCo₂ difference increased with decrease in PetCo₂ values an increase in PetCo₂ is almost always due to an increase in PaCo₂ however, a decrease in PetCo₂ doesn’t necessarily correspond to a decrease in PaCo₂ as in critically ill patients PetCo₂can be significantly affected with cardiopulmonary perfusion alterations which result in changes in the ventilation/perfusion matching and increase difference between PaCo₂ – PetCo₂ readings [29]this is in agreement with[11] study on arterial to EtCo₂ differences in infants and children.
As well, the highest mean PaCo₂ – PetCo₂ difference was associated with PetCo₂ more than 45 mmHg, this finding is in agreement with [15] findings who study efficacy of non-invasive monitoring of arterial oxygen saturation and carbon dioxide partial pressure in mechanically ventilated patients and reported that the efficacy of capnography decreased when PetCo₂ more than 45 mmHg because this almost associated with patients having underlying lung impairment in which affected lungs are unable to ventilate all retained Co₂ in the blood which in turn increase difference between the two measurements.

Conclusion and Recommendation

This study demonstrates the utility of Spo₂ and EtCo₂ values as a predictor for Sao₂ and PaCo₂in the clinical assessment of pediatric patients after cardiac surgeries. Though Spo₂ and EtCo₂ monitoring do not replace blood gas assessment it can serve as an important adjunct in the clinical management of pediatric patients and could lower the need for frequent invasive ABG sampling not replaces in addition to provides continuous information instead of measurements at a specific point. Further study should continue to define the utility of Spo₂ and EtCo₂ as a measure of Sao₂ and PaCo₂ in pediatric patients with different body system alterations.

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