Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-29T06:36:02.777Z Has data issue: false hasContentIssue false

Impact of the mother’s voice on sedation need and stress during cardiologic examination of children (SMUSS study): a prospective, interventional, randomised, controlled, monocentric study

Published online by Cambridge University Press:  02 October 2024

Gregor Massoth*
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Emma Vorhofer
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Nikolai Spuck
Affiliation:
Institute of Medical Biometry, Informatics and Epidemiology, Medical Faculty, University of Bonn, Bonn, Germany
Marian Mikus
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Nathalie Mini
Affiliation:
Department of Cardiology, Paediatric Heart Centre, University Hospital Bonn, Bonn, Germany
Nadine Strassberger-Nerschbach
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Maria Wittmann
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Claudia Neumann
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
Ehrenfried Schindler
Affiliation:
Department of Anesthesiology and Intensive Care Medicine, University Hospital Bonn, Bonn, Germany
*
Corresponding author: Gregor Massoth; Email: gregor.massoth@ukbonn.de
Rights & Permissions [Opens in a new window]

Abstract

Introduction:

Cardiac catheterisation is crucial for diagnosing and treating paediatric heart diseases, but it is poorly tolerated by small children, infants, and newborns without sedation. This study investigated whether maternal voice during sedation could lower stress and pain in children undergoing cardiac catheterisation and also assessed mothers’ stress levels before and after the procedure.

Methods:

This was a prospective, monocentric, randomised, controlled interventional study at the University Hospital Bonn. Children aged 4 years or younger scheduled for elective cardiac catheterisation under procedural sedation and American Society of Anaesthesiologists class between 1 and 3 were eligible.

Results:

At the end of cardiac catheterisation, the intervention group showed a higher Newborn Infant Parasympathetic Evaluation index with an adjusted mean difference of 9.5 (± 4.2) (p = 0.026) and a lower median Children’s and Infants Postoperative Pain Scale score of 2.0 (IQR: 0.0–5.0) versus 4.5 (IQR: 3.0–6.0) than the control group (p = 0.027). No difference in the children’s cortisol level was found (p = 0.424). The mothers in the intervention group had a lower cortisol level than those in the control group before cardiac catheterisation (adjusted mean difference: −4.5 nmol/l (± 1.8 nmol/l), p = 0.011).

Conclusion:

Listening to the maternal voice during cardiac catheterisation could lead to less postoperative pain and significantly lower stress and discomfort level in children. Less pain could reduce the incidence of postoperative delirium.

Additionally, mothers perceived involvement as positive. A reduced stress level of mothers can positively influence children and possibly reduce pain and anxiety.

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 (https://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

Cardiac catheterisation represents an important diagnostic and therapeutic procedure in individuals, both children and adults, with heart diseases. In complex cardiac catheterisations and in young children, either general anaesthesia including airway management or more often procedural sedation is usually necessary to achieve appropriate conditions during the cardiologic intervention.

To our knowledge, guidelines regarding the choice of general anaesthesia or sedation for paediatric cardiac catheterisations are not yet available. However, in many paediatric cardiology departments, sedation is preferred over general anaesthesia in clinical practice. Reference Bertram1

Even in a sedated state, patients can notice auditory stimuli that can positively or negatively impact their well-being. Reference Quan, Yi and Ye2

The extent and consequences of perioperative pain, anxiety, and stress in children are often insufficiently considered due to the lack of objectivity, Reference Messerer, Gutmann, Vittinghoff, Weinberg, Meissner and Sandner-Kiesling3 and intraoperative stress significantly influences postoperative recovery. Reference Song, Kwak and Kim4

Procedural pain and stress are primarily treated pharmacologically. In addition to conventional methods such as anaesthesia or deep sedation, non-invasive and non-pharmacological approaches to reduce anxiety and stress in young children are playing an increasingly significant role. The method of auditory stimulation to reduce perioperative stress and anxiety has been studied for several years. Reference Argstatter, Haberbosch and Bolay5,Reference Hasanah, Mulatsih, Haryanti and Haikal6 Azarmnejad et al. (2015) demonstrated that the maternal voice leads to a less painful arterial blood draw in children Reference Azarmnejad, Sarhangi, Javadi and Rejeh7 and that the maternal voice can be a significant stimulus for infants. Several studies are indicating that listening to recordings of the maternal voice in the paediatric setting can contribute to the reduction of anxiety, stress, and postoperative pain. Reference Byun, Song, Kim, Ryu, Jeong and Kim8Reference Yang, Zhang and Sun11

This study examined if listening to the pre-recorded maternal voice during a cardiac catheterisation would result in a measurable reduction of stress parameters measured via cortisol and alpha-amylase levels in the children (primary endpoints). Additionally, it tried to evaluate the impact of the intervention on the postoperative necessity for analgesic medication and CHIPPS (Children’s and Infants Postoperative Pain Scale). A secondary endpoint was to assess whether the involvement of parents in the medical procedure of their children leads to a measurable reduction in stress among the parents again assessed via cortisol and alpha-amylase levels.

Materials and methods

Study design

The prospective, monocentric, randomised, controlled interventional study was registered in the German Clinical Trials Register (DRKS) under the study number DRKS00023774 and conducted at the University Hospital in Bonn, Germany. Children aged 4 years or younger scheduled for elective cardiac catheterisation in the morning under procedural sedation and with an American Society of Anaesthesiologists class <4 were eligible. Patients were included after informed consent was provided by both parents and the mother agreed to voice recording. Emergency patients and children requiring intensive care or mechanical ventilation were excluded. Other exclusion criteria were hearing impairment of the child, absence of the mother, and cardiac catheterisation under general anaesthesia.

Setting

The study was conducted from 20 April 2021 to 5 August 2022 in the cardiac catheterisation laboratory at the University Hospital Bonn, Germany. Parents were informed about the possibility to participate in the study by an anaesthetist during the preoperative evaluation on the day before the planned intervention. Patient recruitment was done consecutively. The children and their mothers were randomised into two groups by lottery procedure (via randomisation list provided by randomizer.org). In the intervention group, the mother read a fairy tale validated for the age range of her child for 15 min. This was recorded on a tablet computer and pseudomised with a code specific for her child. The children of the intervention group heard their mother’s reading via headset from induction of anaesthesia until the end of cardiac catheterisation nonstop. Recording equipment was fitted to reproduce voices with a nearly natural spectrum. All recordings were uncompressed. Volume was adjusted to the child’s age. Apart from the study intervention, all children were treated according to standard of care. Sedation medication and haemodynamic data such as blood pressure, heart rate, and Newborn Infant Parasympathetic Evaluation (NIPE) were documented and analysed.

Children followed the perioperative fasting guidelines outlined in the European Society of Anaesthesiology and Intensive Care guideline of 2022. Reference Sümpelmann, Beck and Rudolph12 All children older than 6 months received 0.5 mg/kg midazolam orally preoperatively.

At the operating room entrance, the child’s preoperative anxiety was assessed by a third person via the modified Yale Preoperative Anxiety Scale. Here the children were still accompanied by their parents. The modified Yale Preoperative Anxiety Scale is a validated observation scale that assesses the preoperative anxiety in children. It consists of five items: activity, vocalisation, emotional expressivity, state of apparent arousal, use of apparent arousal, and use of parents. Reference Kain, Mayes, Cicchetti, Bagnall, Finley and Hofstadter13 The assessment took place at four different time points (see Table 1 ). The item “use of parents” was not assessed as parents were absent at the aforementioned time points. In the calculation, each item value was divided by the highest possible achievable value. Subsequently, the values of all four items were added, divided by 4, and multiplied by 100. This resulted in the modified Yale Preoperative Anxiety Scale score, a dimensionless number between 22.92 and 100, a higher value indicating more stress and increased anxiety. Reference Jenkins, Fortier, Kaplan, Mayes and Kain14

Table 1. Assessment points for questionnaires and laboratory parameters

mYPAS = modified Yale Preoperative Anxiety Scale; NIPE = Newborn Infant Parasympathetic Evaluation; CHIPPS = Children’s and Infants Postoperative Pain Scale; PAED = Paediatric Anaesthesia Emergence Delirium; T1 = transfer OR; T2 = induction of sedation; T3 = cannulation by cardiologists; T4 = +30 min after cannulation by the cardiologists; T5 = end of cardiac catheterisation.

Additionally, a saliva sample was collected from the mother using a SalivaBio Oral Swab (Salimetrics, Carlsbad, USA) to assess the stress level by measuring cortisol and alpha-amylase (Table 1). The cortisol level was analysed using the Expanded Range High Sensitivity Salivary Cortisol Enzyme Immunoassay Kit (Salimetrics, Carlsbad, USA). The alpha-amylase concentration was examined using the Salivary Alpha-Amylase Kinetic Assay Kit (Salimetrics, Carlsbad, USA).

Upon arrival in the operation room, a saliva sample was taken from the children using a SalivaBio Children’s (Salimetrics, Carlsbad, USA). No stimulants were applied before or during saliva collection.

Children were connected to standard monitoring and the NIPE device. Additionally, the level of sedation was controlled and recorded via electroencephalogram monitoring (Narcotrend-Compact M device, MT MonitorTechnik GmbH & Co. KG, Bad Bramstedt, Germany). The depth of anaesthesia was evaluated at various study time points to ensure an adequate depth of sedation (Table 1).

Both groups received headphones during anaesthesia induction (Amiron Home headphones, Beyerdynamic, Heilbronn, Germany, specialised for playing human voices). The position of the headphones did not interfere with the cardiologists or anaesthesiologists. In the intervention group, the maternal voice was played in a loop.

All cardiac catheterisations were performed under sedation with spontaneous breathing. Inhalation induction was carried out with sevoflurane. Sedation was maintained continuously with intravenous propofol at a rate of 5–10 mg/kg/h. The last measurement of the children’s stress parameters in saliva was performed as soon as sevoflurane was no longer detectable on expiration. Headphones were removed, and the patients were transferred to the recovery room (Table 1) where the vital parameters of the subjects were recorded again. Mothers provided a second saliva sample. Before transfer to the regular ward, the Paediatric Anaesthesia Emergence Delirium scale and the Children’s and Infants Postoperative Pain Scale were applied to screen for emergence delirium and to measure postoperative pain (Table 1).

The validated Paediatric Anaesthesia Emergence Delirium scale was developed by Sikich and Lerman for children aged 0–6 years. Reference Sikich and Lerman15 The Paediatric Anaesthesia Emergence Delirium score was calculated according to the S2e21 Guidelines: Prevention and Treatment of Paediatric Emergence Delirium. Reference Ghamari, Höhne and Becke16 However, the Paediatric Anaesthesia Emergence Delirium score can also be increased by pain-related agitation. Distinction between postoperative pain and delirium is not always easy. Reference Ghamari, Höhne and Becke16 Locatelli et al. (2013) recommend assessing only the first three items of the Paediatric Anaesthesia Emergence Delirium scale (ED I score). Delirium can be assumed for values of ≥9. Reference Locatelli, Ingelmo and Emre17 The collection of a pain scale can be useful to differentiate between postoperative agitation due to pain and delirium. Therefore, the Paediatric Anaesthesia Emergence Delirium scale was used in combination with the Children’s and Infants Postoperative Pain Scale.

Statistics

Analyses were performed using the statistical software R (Version 4.0.3). Linear mixed regression models were used to analyse the primary endpoints cortisol and alpha-amylase. The measurement time point, group assignment (with or without the mother’s voice), and interaction terms between time and group assignment were included as fixed effects. Time was modelled as a categorical variable. To adjust for the dependence of observations due to repeated measurements, random effects in the form of patient-specific intercepts were included in the model. Effect estimates were determined using the restricted maximum likelihood method. As a sensitivity analysis, an additional model adjusted for the applied surgical procedure was fitted, and a subgroup analysis including only the children who underwent diagnostic procedures was performed.

Secondary endpoints with repeated measurements were analysed analogously to the primary endpoints using linear mixed regression models. For the comparison of CHIPPS and Paediatric Anaesthesia Emergence Delirium (PAED) scores between the two groups, the Mann–Whitney U Test was used.

Results

After screening 73 patients, 55 patients were randomised. Four patients had to be excluded due to intraoperative complications. A total of 51 children with a mean age of 19.5 (±14.3) months were analysed, with 26 children in the intervention group and 25 in the control group (Figure 1). Children in the intervention group were younger and lighter than children in the control group. While more than half of the intervention group—children had to undergo vascular dilatation, most children in the control group received diagnostic cardiac catheterisation. Both groups were similar regarding gender distribution, duration of anaesthesia, length of procedure, and American Society of Anaesthesiologist classification (Table 2).

Figure 1 Patient sample.

Table 2. Patient characteristics

p-values are based on Fisher’s exact tests (for the categorical variables), independent samples t tests (for age, height, and weight), and Mann–Whitney U test (for time of anaesthesia).

ASA status = American Society of Anaesthesiologists physical status; HLHS = hypoplastic left heart syndrome; MAPCA = main aortopulmonary collateral artery; PDA = patent ductus arteriosus; ASD = atrial septal defect; n = number of patients; SD = standard deviation.

Perioperative haemodynamic parameters as well as Narcotrend and NIPE values were similar throughout the study period.

Results of the children study group

The results of the secondary endpoint analyses are exploratory rather than confirmatory and may be interesting points to further investigate in future studies.

Cortisol level

The results of the mixed model indicate a 3.5 (±4.2) nmol/l increased cortisol level in the intervention group compared to the control group at the end of cardiac catheterisation (T5) adjusted for the levels before surgery (T1). The difference between the two groups was not statistically significant (p = 0.424; Supplemental Material, Table 1). Additionally adjusting for the procedure yielded similar results (adjusted mean difference: 5.8 [± 4.4] nmol/l, p = 0.204). The subgroup analysis including only children who underwent diagnostic procedures resulted in a slightly lower adjusted mean difference cortisol (2.3 [±5.8] nmol/l, p = 0.699).

Alpha-amylase level

The adjusted mean difference in alpha-amylase level between the two groups at the end of cardiac catheterisation was estimated as 26.0 (± 60.7) U/l indicating a higher level in the intervention group. However, the result was not statistically significant (p = 0.670; Supplemental Material, Table 1). Results of the sensitivity analysis with adjusting for procedure were similar (adjusted mean difference: 20.3 [± 60.1] U/l, p = 0.745). A slightly lower adjusted mean difference was found in the subgroup analysis of the children who underwent diagnostic procedures (17.0 [± 95.6] U/l, p = 0.861).

Heartbeat and blood pressure

The control group consistently showed slightly higher heartbeat rates than the intervention group and the mean systolic (adjusted mean difference: 13.3 [± 3.4] mmHg, p < 0.001) and diastolic blood pressure values (adjusted mean difference: 6.0 [± 2.7] mmHg, p = 0.027) were higher in the intervention group at the end of cardiac catheterisation, but this was not clinically relevant (see Supplemental Material, Table 2).

Narcotrend index

The important adequate sedation of both groups is similar at vascular cannulation by the cardiologist with slightly higher values in the intervention group (adjusted mean difference: 4.9 [± 6.0], p = 0.412) (see Supplemental Material, Table 2).

Newborn Infant Parasympathetic Evaluation index

The NIPE index shows similar values for both groups at the first measurements. At the end of cardiac catheterisation, the intervention group presented with a higher index (58.8 ± 7.36) than the control group (57.1 ± 8.5) (p = 0.026). The mean difference at T5 adjusted for the scores at T1 was 9.5 (± 4.2, p = 0.026) (Supplemental Material, Figure 1).

Paediatric Anaesthesia Emergence Delirium (PAED)

While the Children’s and Infants Postoperative Pain Scale of the intervention group shows a median score of 2.0 (IQR: 0.0–5.0), the control group had a median score of 4.5 (IQR: 3.0–6.0). The Mann–Whitney U test yields p = 0.027 (Supplemental Material, Table 3). Median PAED score was 2.0 (IQR:1.0–5.0) in the intervention group and 3.0 (IQR: 2.3–5.8) in the control group (p = 0.272; Supplemental Material, Table 3).

Results of the modified Yale Preoperative Anxiety Scale questionnaire differed not significantly at all four different time points (Supplemental Material, Table 3).

Results of the mother study group

Before surgery, the intervention group mothers showed a higher cortisol level (6.7 ± 3.6 nmol/l) than the mothers in the control group (11.2 ± 10.7 nmol/l; adjusted mean difference: –4.5 [±1.8] nmol/l, p = 0.010). After the intervention, the intervention group mothers had a mean cortisol concentration of 5.8 (±2.7) nmol/l, and the control group mothers had an average value of 7.4 (±4.1) nmol/l (Figure 2).

Figure 2 Cortisol levels of the mother at T1 and T5. T1 = transfer OR; T5 = end of cardiac catheterisation.

Discussion

The influence of the mother’s voice on children has been studied several times in recent years. Authors such as Kim et al. (2010) and Rajan et al. (2017) demonstrated a positive effect of the mother’s voice on children’s well-being. Reference Kim, Oh, Kim, Kwak and Na9,Reference Rajan, Lakshmanan, Gupta, Sivasubramanian, Saxena and Juneja10 In this study, stress was measured through selected hormone parameters in the saliva of both children and mothers. Furthermore, post-interventional pain and consciousness were stratified using observation scales.

Our primary hypothesis that the maternal voice would reduce the stress level of their children could not be confirmed. However, we found both reduced post-interventional pain in children and relevant lower preoperative stress levels in the mothers of the intervention group.

With a similar modified Yale Preoperative Anxiety Scale, we assumed that the preoperative anxiety of both groups was alike. In our results, all mean modified Yale Preoperative Anxiety Scale scores were above 30. Yang et al. (2020), who investigated the effect of the maternal voice on children during surgery, also determined preoperative anxiety using the modified Yale Preoperative Anxiety Scale and found values between 42.5 and 45.5. Reference Yang, Zhang and Sun11

Unfamiliar environment as well as separation from their parents could contribute significantly to preoperative anxiety. The preoperatively increased anxiety level of the children might have influenced the subsequent measurement of stress levels.

Contrary to our results, Kim et al. (2010) described an influence of the maternal voice on the depth of sedation and the need for sedatives. Reference Kim, Oh, Kim, Kwak and Na9

In our patients, an increase in cortisol concentration was observed from the baseline point (before the voice was played) to the end of the measurement (after the voice was played) with slightly increased cortisol levels in children who heard the mother’s voice during intervention. However, the difference between the two groups was not significant. The results match those of Liu et al. (2019) found no significant minimisation of stress levels in saliva during surgery. Reference Liu, Cole and Gilmore18

The emotional state of children and very anxious parents have a negative effect on children in the perioperative setting.19

The interindividual stress levels of the patients resulted in large differences in cortisol levels. The heterogeneity of the concentrations in saliva has also been described by other authors. Reference Hasanah, Mulatsih, Haryanti and Haikal6,Reference Forclaz, Moratto and Pennisi20

In the study by Davis et al. (2009), baseline stress levels for cortisol from 5.5 nmol/l to 8.28 nmol/l were measured in the age group 12–24 months. Reference Davis and Granger21 This is also the average age of our patient collective where average baseline values for cortisol of 11.9 nmol/l were measured. Comparison of the stress levels is only possible to a limited extent, as Davis et al. (2009) studied only mentally and physically healthy children. The slightly higher level of our patients might be linked to their cardiological diseases and pretreatments.

Uniform times of cardiac catheterisation were chosen for this study to account for the circadian release of cortisol. The cortisol awakening response, which leads to an increased cortisol level in the early morning, could have influenced the results. Other factors, such as current medication, sleep rhythm, and age, can also affect the cortisol level. Reference Davis and Granger21

Furthermore, an adequate measurement of acute stress is potentially distorted by the presence of chronic stress. Reference Chojnowska, Ptaszyńska-Sarosiek, Kępka, Knaś and Waszkiewicz22

According to Chaturvedi et al. (2018), there is a significant increase in alpha-amylase in saliva during medical procedures such as tooth extractions. Reference Chaturvedi, Chaturvedy, Marwah, Chaturvedi, Agarwal and Agarwal23 In our evaluation, alpha-amylase levels were higher in the intervention group than in the control group, and no effect of the maternal voice on alpha-amylase levels could be detected.

The reasons for this could be similar to the analysis of cortisol values.

The maternal cortisol levels decreased between the preoperative and postoperative measurement and the cortisol concentrations of the mothers in the intervention group were lower at both measurement points. This could be due to the fact that the test subjects were randomised after agreeing to study participation. Active involvement might explain why the mothers in the intervention group showed lower stress levels. This was confirmed through the mother’s feedback during and after the recording of the audio file.

In a similar setting, Kim et al. (2010) showed that mothers were less stressed if they could do something good for their child. Reference Kim, Oh, Kim, Kwak and Na9

The NIPE index was between 40 and 60 at all time points indicating no pain. Reference Neumann, Babasiz and Straßberger-Nerschbach24

The mean heart rate between 106 and 119 beats per minute was normal for the respective age groups. Reference Davignon, Rautaharju, Boisselle, Soumis, Mégélas and Choquette25 The average heart rate of the control group was slightly higher than that of the intervention group. Argstatter et al. (2006) found similar results in their investigations on the effect of music during exercise. Reference Argstatter, Haberbosch and Bolay5 Kim et al. (2010), on the other hand, found an increase in heart rate over the course of the cardiac catheterisation, without significant differences between the intervention group and the control group. Reference Kim, Oh, Kim, Kwak and Na9

With values of 85 mmHg to 87 mmHg, average systolic blood pressure is within the physiological range for this age group. Reference Flynn, Kaelber and Baker-Smith26 Analysis showed a slight increase in the mean systolic and diastolic values of the intervention group at the end of the cardiac catheterisation. Similar results were found in other studies on the effect of maternal voice or music. Reference Argstatter, Haberbosch and Bolay5,Reference Kim, Oh, Kim, Kwak and Na9,Reference Rajan, Lakshmanan, Gupta, Sivasubramanian, Saxena and Juneja10

We measured lower CHIPPS scores in the intervention group (median: 2.0) than in the control group (median: 4.5).

According to Bächle-Helde (2013), postoperative pain and discomfort can be assumed at a Children’s and Infants Postoperative Pain Scale score higher than 4. Reference Bächle-Helde27 Our results are consistent with those of Byun et al. (2018), who found less postoperative pain after auditioning the maternal voice. Reference Byun, Song, Kim, Ryu, Jeong and Kim8 Further studies on auditory stimulation with music have also found reduced postoperative pain. Reference Nowak, Zech and Asmussen28

Our results showed less postoperative delirium in the intervention group. This result could be confirmed by other studies. Reference Song, Kwak and Kim4,Reference Byun, Song, Kim, Ryu, Jeong and Kim8,Reference Kim, Oh, Kim, Kwak and Na9,Reference Yang, Zhang and Sun11

As the occurrence of emergence delirium is closely linked to the occurrence of postoperative pain and results of the CHIPPS score indicate less postoperative pain in the intervention group compared to the control group, this could explain the reduced occurrence of postoperative delirium in the intervention group.

Limitations

We assumed that the mother’s voice has a positive effect on children. However, it cannot be ruled out that the mother’s voice is a negative stimulus for some children and that maternal emotions such as anxiety and stress may be transferred to the children. Reference Kim, Oh, Kim, Kwak and Na9

The observation scales were collected by the doctoral student or study staff. This could lead to subjective evaluations by the observers. Furthermore, as the study personnel was not blinded, bias cannot be ruled out.

An additional limitation is the sample size, as the main objective of the study was to investigate group differences in the primary endpoints cortisol and alpha-amylase levels. In order to evaluate the secondary outcome parameters more precisely, further studies with an appropriate number of subjects are needed.

Conclusion

Listening to their mother’s voice during cardiac catheterisation did not lower cortisol and alpha-amylase levels significantly but showed potential in reducing post-procedure pain and stress in children. This intervention could also decrease the likelihood of postoperative delirium. Its benefits include being non-invasive, easy to implement, and cost-effective, without impacting medical procedures negatively. Mothers involved felt less stressed and valued their participation positively. Further research is necessary to explore these observations.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1047951124025757.

Acknowledgements

None.

Author’s contributions

EV, NSN, MW, CN, MW, and ES designed the study. MM, NSN, and NM recruited the patients. GM, EV, MM, NM, and NSN collected the data. GM, NS, EV, and ES analysed the data. GM wrote the first draft of the paper. MW and CN revised the article critically. All authors read and approved the final manuscript.

Financial support

This study received no financial support from any commercial or non-profit entities.

Competing interests

The author(s) declare none.

Ethical standard

The study was conducted in accordance with the ethical principles of the Declaration of Helsinki 1964 and its subsequent updates as well as the national guidelines (AMG). Ethics approval was provided by the Ethics Commission of the Medical Faculty of the University Hospital Bonn (lfd. Nr. 343/20) on 4 November 2020.

References

Bertram, H. Empfehlungen und Standards für die Analgosedierung kinderkardiologischer Patienten. 2023. Available from https://www.springermedizin.de/allgemeinanaesthesie/angeborene-herzfehler/empfehlungen-und-standards-fuer-die-analgosedierung-kinderkardio/17039032 Google Scholar
Quan, X, Yi, J, Ye, TH et al. Propofol and memory: a study using a process dissociation procedure and functional magnetic resonance imaging. Anaesthesia 2013; 68: 391399.CrossRefGoogle ScholarPubMed
Messerer, B, Gutmann, A, Vittinghoff, M, Weinberg, AM, Meissner, W, Sandner-Kiesling, A. Postoperative pain assessment in special patient groups: part I: children without cognitive impairment. Schmerz Berl Ger 2011; 25: 245255.Google ScholarPubMed
Song, SY, Kwak, SG, Kim, E. Effect of a mother’s recorded voice on emergence from general anesthesia in pediatric patients: study protocol for a randomized controlled trial. Trials 2017; 18: 430.CrossRefGoogle ScholarPubMed
Argstatter, H, Haberbosch, W, Bolay, HV. Study of the effectiveness of musical stimulation during intracardiac catheterization. Clin Res Cardiol Off J Ger Card Soc 2006; 95: 514522.Google ScholarPubMed
Hasanah, I, Mulatsih, S, Haryanti, F, Haikal, Z. Effect of music therapy on cortisol as a stress biomarker in children undergoing IV-line insertion. J Taibah Univ Med Sci 2020; 15: 238243.Google ScholarPubMed
Azarmnejad, E, Sarhangi, F, Javadi, M, Rejeh, N. The effect of mother’s voice on arterial blood sampling induced pain in neonates hospitalized in neonate intensive care unit. Glob J Health Sci 2015; 7: 198204.CrossRefGoogle ScholarPubMed
Byun, S, Song, S, Kim, JH, Ryu, T, Jeong, MY, Kim, E. Mother’s recorded voice on emergence can decrease postoperative emergence delirium from general anaesthesia in paediatric patients: a prospective randomised controlled trial. Br J Anaesth 2018; 121: 483489.CrossRefGoogle ScholarPubMed
Kim, SJ, Oh, YJ, Kim, KJ, Kwak, YL, Na, S. The effect of recorded maternal voice on perioperative anxiety and emergence in children. Anaesth Intensive Care 2010; 38: 10641069.CrossRefGoogle ScholarPubMed
Rajan, D, Lakshmanan, G, Gupta, SK, Sivasubramanian, R, Saxena, A, Juneja, R. Effect of recorded maternal voice on child’s cooperation during cardiac catheterization – a randomized controlled trial. Indian Pediatr 2017; 54: 204207.CrossRefGoogle ScholarPubMed
Yang, YY, Zhang, MZ, Sun, Yet al.Effect of recorded maternal voice on emergence agitation in children undergoing bilateral ophthalmic surgery: a randomised controlled trial. J Paediatr Child Health 2020; 56: 14021407.CrossRefGoogle ScholarPubMed
Sümpelmann, R, Beck, C, Rudolph, D, et al. S1-Leitlinlinie: PerioperativeNüchternzeiten bei Kindern und Jugendlichen. Anästh Intensivmed 2022;63: 320–328.Google Scholar
Kain, ZN, Mayes, LC, Cicchetti, DV, Bagnall, AL, Finley, JD, Hofstadter, MB. The yale preoperative anxiety scale: how does it compare with a gold standard? Anesth Analg 1997; 85: 783788.CrossRefGoogle ScholarPubMed
Jenkins, BN, Fortier, MA, Kaplan, SH, Mayes, LC, Kain, ZN. Development of a short version of the modified yale preoperative anxiety scale. Anesth Analg 2014; 119: 643650.CrossRefGoogle Scholar
Sikich, N, Lerman, J. Development and psychometric evaluation of the pediatric anesthesia emergence delirium scale. Anesthesiology 2004; 100: 11381145.CrossRefGoogle ScholarPubMed
Ghamari, S, Höhne, C, Becke, K, et al. Prävention und Therapie des pädiatrischen Emergence Delir. Anästh Intensivmed 2019; 60: 445455.Google Scholar
Locatelli, BG, Ingelmo, PM, Emre, Sğlu et al. Emergence delirium in children: a comparison of sevoflurane and desflurane anesthesia using the paediatric anesthesia emergence delirium scale. Paediatr Anaesth Apr 2013; 23: 301308.CrossRefGoogle ScholarPubMed
Liu, P, Cole, PM, Gilmore, RO et al. Young children’s neural processing of their mother’s voice: An fMRI study. Neuropsychologia 2019; 1: 1119.CrossRefGoogle Scholar
Bevan, JC, Johnston, C, Haig, MJ et al. Preoperative parental anxiety predicts behavioural and emotional responses to induction of anaesthesia in children. Can J Anaesth J Can Anesth 1990; 37: 177182.CrossRefGoogle ScholarPubMed
Forclaz, MV, Moratto, E, Pennisi, A et al. Salivary and serum cortisol levels in newborn infants. Arch Argent Pediatr 2017; 115: 262266.Google ScholarPubMed
Davis, EP, Granger, DA. Developmental differences in infant salivary alpha-amylase and cortisol responses to stress. Psychoneuroendocrinology 2009; 34: 795804.CrossRefGoogle ScholarPubMed
Chojnowska, S, Ptaszyńska-Sarosiek, I, Kępka, A, Knaś, M, Waszkiewicz, N. Salivary biomarkers of stress, anxiety and depression. J Clin Med 2021; 10: 517.CrossRefGoogle ScholarPubMed
Chaturvedi, Y, Chaturvedy, S, Marwah, N, Chaturvedi, S, Agarwal, S, Agarwal, N. Salivary cortisol and alpha-amylase-biomarkers of stress in children undergoing extraction: an in vivo study. Int J Clin Pediatr Dent 2018; 11: 214218.Google ScholarPubMed
Neumann, C, Babasiz, T, Straßberger-Nerschbach, N et al.Comparison of the Newborn Infant Parasympathetic Evaluation (NIPETM) index to changes in heart rate to detect intraoperative nociceptive stimuli in healthy and critically ill children below 2 years: an observational study. Paediatr Anaesth 2022; 32: 815824.CrossRefGoogle ScholarPubMed
Davignon, A, Rautaharju, P, Boisselle, E, Soumis, F, Mégélas, M, Choquette, A. Normal ECG standards for infants and children. Pediatr Cardiol 1980; 1: 123131.CrossRefGoogle Scholar
Flynn, J, Kaelber, D, Baker-Smith, C et al. Clinical practice guideline for screening and management of high blood pressure in children and adolescents. Pediatrics 2017; 140: e20171904.CrossRefGoogle ScholarPubMed
Bächle-Helde, B. Wie weh tut es? JuKiP - Ihr Fachmag Für Gesundh- Kinderkrankenpflege 2013; 2: 164167.Google Scholar
Nowak, H, Zech, N, Asmussen, S et al. Effect of therapeutic suggestions during general anaesthesia on postoperative pain and opioid use: multicentre randomised controlled trial. BMJ 2020; 371: m4284.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Assessment points for questionnaires and laboratory parameters

Figure 1

Figure 1 Patient sample.

Figure 2

Table 2. Patient characteristics

Figure 3

Figure 2 Cortisol levels of the mother at T1 and T5. T1 = transfer OR; T5 = end of cardiac catheterisation.

Supplementary material: File

Massoth et al. supplementary material

Massoth et al. supplementary material
Download Massoth et al. supplementary material(File)
File 59.6 KB