Chest Compression Rates of 90/min versus 180/min during Neonatal Cardiopulmonary Resuscitation: A Randomized Controlled Animal Trial
by
, and
Marlies Bruckner
1,2,3,
Mattias Neset
1,2,
Catalina Garcia-Hidalgo
1,2,
Tze-Fun Lee
1,2,
Megan O’Reilly
1,2,
Po-Yin Cheung
2 and
Georg M. Schmölzer
1,2,* 1
Centre for the Studies of Asphyxia and Resuscitation, Neonatal Research Unit, Royal Alexandra Hospital, Edmonton, AB T5H 3V9, Canada
2
Department of Pediatrics, Faculty of Medicine and Dentistry, University of Alberta, Edmonton, AB T6G 2R3, Canada
3
Division of Neonatology, Department of Pediatrics and Adolescent Medicine, Medical University of Graz, 8036 Graz, Austria
*
Author to whom correspondence should be addressed.
Children 2022, 9(12), 1838; https://0-doi-org.brum.beds.ac.uk/10.3390/children9121838
Submission received: 28 September 2022
/
Revised: 21 November 2022
/
Accepted: 25 November 2022
/
Published: 28 November 2022
(This article belongs to the Special Issue Stabilization and Resuscitation of Newborns: 2nd Edition)
Abstract
:Background: To compare chest compression (CC) rates of 90/min with 180/min and their effect on the time to return of spontaneous circulation (ROSC), survival, hemodynamic, and respiratory parameters. We hypothesized that asphyxiated newborn piglets that received CC at 180/min vs. 90/min during cardiopulmonary resuscitation would have a shorter time to ROSC. Methods: Newborn piglets (n = 7/group) were anesthetized, intubated, instrumented and exposed to 45 min normocapnic hypoxia followed by asphyxia and cardiac arrest. Piglets were randomly allocated to a CC rate of 180/min or 90/min. CC was performed using an automated chest compression machine using CC superimposed with sustained inflation. Hemodynamic and respiratory parameters and applied compression force were continuously measured. Results: The mean (SD) time to ROSC was 91 (34) and 256 (97) s for CC rates of 180/min and 90/min, respectively (p = 0.08). The number of piglets that achieved ROSC was 7 (100%) and 5 (71%) with 180/min and 90/min CC rates, respectively (p = 0.46). Hemodynamic parameters (i.e., diastolic and mean blood pressure, carotid blood flow, stroke volume, end-diastolic volume, left ventricular contractile function) and respiratory parameters (i.e., minute ventilation, peak inflation and peak expiration flow) were all improved with a CC rate of 180/min. Conclusion: Time to ROSC and hemodynamic and respiratory parameters were not statistical significant different between CC rates of 90/min and 180/min. Higher CC rates during neonatal resuscitation warrant further investigation.
1. Introduction
Current neonatal resuscitation guidelines recommend a 3:1 compression to ventilation (C:V) ratio with 90 chest compressions (CCs) and 30 inflations to achieve approximately 120 events per minute [1,2]. However, the optimal CC rate to optimize coronary and cerebral perfusion while providing adequate ventilation of an asphyxiated newborn remains unknown [3].
A decade ago, we described a different approach to chest compression, by superimposing a sustained inflation (SI) during chest compression (CC + SI) [4]. The observed benefits included passive lung aeration resulting in improved minute ventilation and oxygenation and improved hemodynamics with significantly higher pulmonary and carotid blood flow [4]. Schmölzer et al. compared CC + SI with 3:1 C:V and reported significant reduced time to return of spontaneous circulation (ROSC) [38 (23–44) s vs. 143 (84–303) s (p = 0.0008)] and improved survival [7/8 [87.5%] vs. 3/8 [37.5%] (p = 0.038)] in bradycardic piglets [5]. We further compared CC + SI with chest compression rate of 90/min or 120/min and observed similar time of ROSC, survival rates, and hemodynamic and respiratory parameters during cardiopulmonary resuscitation [6]. However, when we compared CC + SI with a CC rate of 90/min with 3:1 C:V, CC + SI significantly reduced the median (IQR) time of ROSC [34 (28–156) s vs. 210 (72–300) s, (p = 0.048)] [7]. While these studies show, that CC + SI at either rates of 90/min or 120/min reduced time to ROSC and improves survival, a mathematical study suggests that the most effective CC rate to optimize systemic perfusion depends upon body size and weight [3]. This would translate to CC rates of 180/min in term infants and higher rates for preterm infants. However, CC rates of 180 CC/min or above are impossible to achieve using a 3:1 C:V ratio. If a clear effect of body size and weight on the optimal compression frequencies for CPR exists, then optimizing compression frequencies for neonatal CPR has the potential to improve short- and long-term outcomes in newborn infants.
We aimed to examine different CC rates and their effect on the time to return of spontaneous circulation (ROSC), survival, and hemodynamic and respiratory parameters. We hypothesized that a CC rate of 180/min compared to 90/min during cardiopulmonary resuscitation would result in a shorter time to ROSC in asphyxiated newborn piglets.
2. Materials and Methods
All experiments were conducted between January and November 2020 in accordance with the guidelines and approval of the Animal Care and Use Committee (Health Sciences), University of Alberta (AUP00001764), presented according to the ARRIVE guidelines [8], and registered at preclincialtrials.eu (PTCE0000148). A graphical display of the study protocol is presented in Figure 1. The authors declare that all supporting data are available within the article.
2.1. Randomization
Piglets were randomly allocated to two groups (“CC rate 180/min or “90/min”). Randomization was 1:1 with variable block sizes using a computer-generated randomization program (http://www.randomizer.org, accessed on 24 November 2022). Sequentially numbered, sealed, brown envelopes containing the group allocation were opened during the experiment (Figure 1).
2.2. Sample Size and Power Estimates
The primary outcome measure was the time of CPR to achieve ROSC. Our previous studies showed a mean (standard deviation) ROSC of 220 (25) s with a CC rate of 90/min. We hypothesized that a CC rate of 180/min would reduce the time to achieve ROSC. A sample size of 7/group would be sufficient to detect a clinically important (20%) reduction in time to ROSC (i.e., 176 s vs. 220 s) with 90% power and a 2-tailed alpha error of 0.05.
2.3. Inclusion and Exclusion Criteria
Newborn mixed-breed piglets (0–3 days of age) obtained on the day of experimentation from the University Swine Research Technology Center were included. There were no exclusion criteria.
2.4. Animal Preparation
Piglets were instrumented as previously described with some modifications [5]. Following the induction of anesthesia using isoflurane, piglets were intubated via tracheostomy, and mechanical ventilation (Sechrist infant ventilator model IV-100; Sechrist Industries, Anaheim, CA, USA) was commenced at a 20/min rate, peak inflation pressure of 25 cmH2O and positive end-expiratory pressure of 5 cmH2O. Oxygen saturation was kept within 90–100%, glucose level and hydration were maintained with an intravenous infusion of 5% dextrose at 10 mL/kg/h. During the experiment, anesthesia was maintained with intravenous propofol 5–10 mg/kg/h and morphine 0.1 mg/kg/h. Additional doses of propofol (1–2 mg/kg) and morphine (0.05–0.1 mg/kg) were also given as needed, and their body temperature was maintained at 38.5–39.5 °C by using an overhead warmer and a heating pad.
2.5. Hemodynamic Parameters
A 5-French Argyle® (Klein-Baker Medical Inc., San Antonio, TX, USA) double-lumen catheter was inserted into the femoral vein for fluid administration and medications. A 5-French Argyle® single-lumen catheter was inserted above the right renal artery via the femoral artery for continuous arterial blood pressure monitoring and arterial blood gas measurements. The right common carotid artery was exposed and encircled with a real-time ultrasonic flow probe (2 mm; Transonic Systems Inc., Ithica, NY, USA) to measure carotid blood flow. A Millar catheter (MPVS Ultra, ADInstruments, Houston, TX, USA) was inserted into the left ventricle (LV) via the left common carotid artery for continuous measurement of stroke volume, end-diastolic volumes, dp/dtmax (maximal rate of rise of left ventricular pressure), and dp/dtmin (minimum rate of change of ventricular pressure), which served as a surrogate for cardiac output. Because of the size difference between the Millar catheter and LV longitudinal axis, which poses a limitation for the accuracy of in vivo volume measurement, an alpha factor = 0.46, based on comparison between Millar’s recording and direct echocardiographic measurements in three piglets, was used to correct the conductance volume [9].
Piglets were placed in the supine position and allowed to recover from surgical instrumentation until baseline hemodynamic measures were stable (minimum of one hour). The ventilator rate was adjusted to keep the partial arterial CO2 between 35–45 mmHg as determined by periodic arterial blood gas analysis. Arterial blood pressure, heart rate, and percutaneous oxygen saturation were continuously measured and recorded throughout the experiment with a Hewlett Packard 78833B monitor (Hewlett Packard Co., Palo Alto, CA, USA).
2.6. Respiratory Parameters
A respiratory function monitor (NM3, Respironics, Philips, Andover, MA, USA) continuously measured tidal volume, airway pressures, gas flow, and end-tidal CO2. The sensor was placed between the endotracheal tube and the ventilation device. Tidal volume was calculated by integrating the flow signal, and end-tidal CO2 was measured using a nondispersive infrared absorption technique [10,11]. The accuracy for gas flow was ±0.125 L/min, and the end-tidal CO2 was ±2 mmHg.
2.7. Automated Chest Compression Machine
The automated CC machine was custom designed in our laboratory. The settings for the automated CC machine were anterior-poster depth 33%, acceleration of compression 500 cm/s2, speed of recoil 50 cm/s, a simulated two-thumb technique, and a CC rate of 90/min or 180/min according to group allocation [12,13].
2.8. Force Measurement
2.9. Experimental Protocol
Piglets were randomized into two groups: “CC rate 180/min” or “CC rate 90/min”. Following surgical instrumentation and stabilization, the piglets were placed onto the automated CC machine, which was placed on the surgical bed. The piglets’ chest diameter was measured from the sternum to the vertebrae touching the bed (anterior to posterior) with a measuring tape, and then the anterior-posterior depth of 33% was calculated [12,13]. Piglets were then exposed to 45 min of normocapnic hypoxia, which was followed by asphyxia. Normocapnic hypoxia was achieved by reducing the fraction on inspired oxygen and adjusting the ventilation rate. Asphyxia was achieved by disconnecting the ventilator and clamping the endotracheal tube until asystole. Asystole was defined as zero carotid blood flow and no audible heartbeat during auscultation. Fifteen seconds after asystole, positive pressure ventilation was provided for 30 s with a Neopuff T-Piece (Fisher & Paykel, Auckland, New Zealand) with 21% oxygen, peak inspiratory pressure of 30 cmH2O, positive end-expiratory pressure of 5 cmH2O, gas flow of 8 L/min, and at a rate of 50/min. After 30 s of positive pressure ventilation, mechanical CC using our automated CC machine was initiated [12,13] using 21% oxygen [14,15], with an antero-posterior chest diameter depth of 33% [12,13], and continuous CC was initiated during sustained inflation (CC + SI) with a peak inspiratory pressure of 30 cmH2O for 30 s [16,17,18]. Sustained inflation was interrupted for 1 s before a further 30 s of sustained inflation was provided, and this was continued until ROSC [5]. Chest compressions were provided for a maximum time of 10 min, if no ROSC, resuscitation efforts were stopped. Epinephrine (0.02 mg/kg per dose) was administered intravenously 2 min after the start of positive pressure ventilation and every 3 min until ROSC with a maximum of three doses [1,2], as the maximum resuscitation time was 10 min. The administration of epinephrine was immediately followed by a saline flush of 3 mL [19,20]. ROSC was defined as an unassisted heart rate >100/min for at least 15 s. After ROSC, piglets recovered for one hour before being euthanized with an intravenous overdose of sodium pentobarbital (120 mg/kg). If there was no ROSC, piglets were euthanized immediately with an intravenous overdose of sodium pentobarbital (120 mg/kg).
2.10. Data Collection and Statistical Analysis
Demographics of study piglets were recorded. Transonic flow probe, heart rate and pressure transducer outputs were digitized and recorded with LabChart® programming software (AD Instruments, Houston, TX, USA). To analyze the hemodynamic data until time to ROSC (i.e., arterial blood pressure, central venous pressure, and carotid blood flow), the duration of CC time was divided into 10 epochs. To analyze stroke volume, end-diastolic volume, dp/dtmax, and dp/dtmin, the pressure–volume loops were compared between groups. Airway pressures, gas flow, tidal volume, and end-tidal CO2 were measured and analyzed using Flow Tool Physiologic Waveform Viewer (Philips Healthcare, Wallingford, CT, USA). For all respiratory parameters, the median values for each piglet during CPR were calculated first, and then the mean of the median was calculated for comparison. Time to ROSC was the primary outcome measure, however when a piglet did not achieve ROSC (maximum CPR time of 10 min or 600 s), this time was used as time to ROSC in the analysis.
The data are presented as the mean (standard deviation—SD) for normally distributed continuous variables and median (interquartile range—IQR) when the distribution was skewed. The data were tested for normality (Shapiro–Wilk and Kolmogorov–Smirnov test) and compared using t-tests or rank sum for normally or skewed distributed data. p-values are 2-sided, and p < 0.05 was considered statistically significant. Statistical analyses were performed with SigmaPlot (Systat Software Inc., San Jose, CA, USA).
3. Results
Fourteen newborn mixed breed piglets (0–3 days, weight 1.9–2.4 kg) were randomly assigned to CC rate of 180/min (n = 7) or 90/min (n = 7). Parameters at baseline or at start of CPR (end of asphyxia) were not different between groups (Table 1). The median (IQR) duration of asphyxia was 470 (360–585) and 440 (280–506) s in the 180/min and 90/min CC groups, respectively (p = 0.65).
3.1. Resuscitation and Primary Outcome
The number of piglets that achieved ROSC was 7 (100%) and 5 (71%) with 180/min and 90/min CC rates, respectively (p = 0.46). When all piglets were included in the median (IQR) time to ROSC was 103 (79–170) s for CC rate of 180/min and 189 (96–600) s for CC rate of 90/min (p = 0.12). However, when the piglets who did not achieve ROSC were excluded the median (IQR) time to ROSC was 103 (79–170) s for CC rate of 180/min and 136 (88–395) s for CC rate of 90/min (p = 0.43). Piglets received 0 (0–1) and 1 (0–3) epinephrine boluses with CC rates of 180/min and 90/min, respectively. The mean (SD) compression forces were 2.4 (1) and 2.6 (0.7) kg at 90 CC/min and 180 CC/min, respectively.
3.2. Hemodynamic Parameters
Hemodynamic parameters at baseline and at commencement of resuscitation were not different (Table 1). Diastolic and mean blood pressure and carotid blood flow were significantly higher with a CC rate of 180/min, while systolic blood pressure was not different between groups (Figure 2). Stroke volume and end-diastolic volume were improved, but this did not reach statistical significance (Figure 3), while dp/dtmax and dp/dtmin significantly improved with a CC rate of 180/min (Figure 3).
3.3. Respiratory Parameters
The tidal volume was not different between groups, while the minute ventilation was significantly increased with CC rate 180/min with mean (SD) 945 (249) compared to 522 (79) mL/kg with CC rate 90/min group (p = 0.003) (Table 2). Similarly, peak inflation flow and peak expiration flow were significantly higher with a CC rate of 180/min (Table 3).
Data separated by sex are presented in Table 3.
4. Discussion
Current neonatal resuscitation guidelines recommend providing 90 CC and 30 inflations (=120 events/min) to optimize cardiac output and oxygen delivery [1,2]. However, the optimal CC rate during neonatal CPR remains unclear. A mathematical study suggests that the most effective CC rate depends upon body size and weight and that higher CC rates, as currently recommended, might improve survival in newborn infants [3]. In the current study, we compared CC rates of 180/min and 90/min using CC + SI. The results can be summarized as follows: During CC + SI with a CC rate of 180/min (i) survival and (ii) time to ROSC was not different to CC + SI with a CC rate of 90/min; (iii) less epinephrine administration; (iv) higher blood pressure (diastolic and mean) and carotid blood flow (Figure 2); (v) similar stroke volume and end-diastolic volume, and significantly improved left ventricular function (Figure 3); and (vi) significantly increased minute ventilation and thereby oxygen delivery (Table 2).
Mathematical models described the maximal cardiac output during CPR depends on the fraction of cycle time available for pump filling and emptying, with pump filling being dominant [3,21]. Fitzgerald et al. compared CC rates between 20–140/min in 6–16 kg adult mongrel dogs and reported the maximum cardiac output would be achieved with a CC rate of 126/min [21]. The physiological heart rate in neonates ranges between 120–160/min [22], and an increase in the CC rate might have the potential to boost artificial cardiac output compared to recommended CC rates, which are based largely on experimental work in animal models larger than neonates. The mathematical model by Babbs et al. calculated the optimal CC rate for maximum cardiac output with a CC rate of 184/min for a 3 kg newborn infant, indicating an effect of body size and weight [3]. In the current study, stroke volume was higher at a CC rate of 180/min (Figure 3), and as cardiac output is simple, the product of compression rate × stroke volume, cardiac output was also higher (results not shown).
During neonatal resuscitation, Patel et al. randomized asphyxiated transitioned newborn piglets to continuous CC with asynchronized ventilation with CC rates of 90/min, 100/min, and 120/min and reported similar mean times to ROSC [23]. Notably, the piglets in the 90/min and 100/min groups had higher cerebral inflammation and brain injury than those in the 120/min group [23]. Similar, Vali et al. [24] used a transitional asphyxia lamb model and randomized them to either 3:1 C:V (90 CCs + 30 breaths/min) or continuous CC with asynchronized ventilation with CC rate of (120 CCs + 30 breaths/min) and reported no difference in rate of and time to ROSC. Continuous CC with asynchronized ventilation was associated with a higher PaO2, greater left carotid blood flow, and oxygen delivery. We recently compared CC + SI with 3:1 C:V in bradycardic piglets and reported significant reduced time to return of spontaneous circulation (ROSC) [38 (23–44) s vs. 143 (84–303) s (p = 0.0008)] and improved survival [7/8 [87.5%] vs. 3/8 [37.5%] (p = 0.038)] [5]. Similar, using CC + SI with either a CC rate of 90/min or 120/min resulted in similar time of ROSC, survival rates, and hemodynamic and respiratory parameters. In comparison, when CC + SI with a CC rate of 90/min with 3:1 C:V was compared a significantly reduced the median (IQR) time of ROSC with CC + SI was observed [34 (28–156) s vs. 210 (72–300) s, (p = 0.048)] [6]. However, CC with a higher rate had higher cardiac output and left ventricular function expressed by dp/dtmax and dp/dtmin [6]. Similarly, we recently compared cardiac function (i.e., stroke volume, cardiac output, and left ventricular function (i.e., dp/dtmax and dp/dtmin)) with CC rates between 60–180/min [25]. Stroke volume and cardiac output were highest with a CC rate of 180/min, while end-diastolic volume, dp/dtmax or dp/dtmin was highest at a CC rate of 150/min. A further increase to a CC rate of 180/min did not further increase the end-diastolic volume, dp/dtmax or dp/dtmin [25]. These data suggest that CC with a rate of 150–180/min might have optimal cardiovascular performance.
We used a custom-designed chest compression machine [12,13], which allowed consistent delivery of CC rates and reduced potential bias (e.g., fatigue during CC or inability to constantly achieve allocated rate). Indeed, manikin studies compared CC rates of 90/min vs. 120/min and observed higher fatigue and up to 50% decay in CC depth after 90 or 120 s CC rate, respectively [26,27]. While we recognize that CPR using a CC rate of 180/min using a 3:1 C:V ratio is nearly impossible, it might be feasible using continuous compressions.
Limitations
In the current study, we used continuous CC during sustained inflation [4], which is mentioned in the knowledge gap section of the neonatal resuscitation guidelines, however it is currently not recommended [1,2]. Our use of a piglet asphyxia model is a great strength of this translational study, as this model closely simulates delivery room events, with the gradual onset of severe asphyxia leading to bradycardia. Our asphyxia model uses piglets that have already undergone the fetal-to-neonatal transition, and piglets were sedated/anesthetized. Our model uses tracheostomy with a tightly sealed endotracheal tube to prevent endotracheal tube leak; this may not occur in the delivery room, as uncuffed endotracheal tubes are routinely used. A strength of this study is the use of our automated chest compression machine, which can apply high rates of CC [12,13].
5. Conclusions
Time to ROSC and survival were not statistically different between CC rates of 90/min and 180/min. Respiratory and hemodynamic parameters were also improved with a CC rate of 180/min compared to 90/min. A higher CC rate might improve organ perfusion and oxygen delivery compared to lower CC rates and warrants further investigation.
Author Contributions
Conception and design: P.-Y.C., M.O., T.-F.L. and G.M.S. Collection and assembly of data: P.-Y.C., M.O., T.-F.L., G.M.S., M.B., M.N. and C.G.-H. Analysis and interpretation of the data: P.-Y.C., M.O., T.-F.L., G.M.S., M.B., M.N. and C.G.-H. Drafting of the article: P.-Y.C., M.O., T.-F.L., G.M.S., M.B., M.N. and C.G.-H. Critical revision of the article for important intellectual content: P.-Y.C., M.O., T.-F.L., G.M.S., M.B., M.N. and C.G.-H. Final approval of the article: P.-Y.C., M.O., T.-F.L., G.M.S., M.B., M.N. and C.G.-H. All authors have read and agreed to the published version of the manuscript.
Funding
We would like to thank the public for donating money to our funding agencies: The project was supported by a project grant from the Laerdal Foundation. G.M.S. was a recipient of the Heart and Stroke Foundation/University of Alberta Professorship of Neonatal Resuscitation, a National New Investigator of the Heart and Stroke Foundation Canada and an Alberta New Investigator of the Heart and Stroke Foundation Alberta.
Institutional Review Board Statement
All experiments were conducted between January and November 2020 in accordance with the guidelines and approval of the Animal Care and Use Committee (Health Sciences), University of Alberta (AUP00001764), presented according to the ARRIVE guidelines [8], and registered at preclincialtrials.eu (PTCE0000148).
Informed Consent Statement
Not applicable.
Data Availability Statement
The authors declare that all supporting data are available within the article.
Conflicts of Interest
The authors declare no conflict of interest.
Abbreviation
| CC | Chest compression |
| CC + SI | Continuous chest compressions during sustained inflations |
| CPR | Cardiopulmonary resuscitation |
| CO | Cardiac output |
| C:V ratio | Compression to ventilation ratio |
| ROSC | Return of spontaneous circulation |
References
- Aziz, K.; Lee, H.C.; Escobedo, M.B.; Hoover, A.V.; Kamath-Rayne, B.D.; Kapadia, V.S.; Magid, D.J.; Niermeyer, S.; Schmölzer, G.M.; Szyld, E.; et al. Part 5: Neonatal Resuscitation: 2020 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation 2020, 142, S524–S550. [Google Scholar] [CrossRef] [PubMed]
- Wyckoff, M.H.; Wyllie, J.P.; Aziz, K.; de Almeida, M.F.; Fabres, J.; Fawke, J.; Guinsburg, R.; Hosono, S.; Isayama, T.; Kapadia, V.S.; et al. Neonatal Life Support: 2020 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science with Treatment Recommendations. Circulation 2020, 142, 329–337. [Google Scholar] [CrossRef] [PubMed]
- Babbs, C.; Meyer, A.; Nadkarni, V. Neonatal CPR: Room at the top—A mathematical study of optimal chest compression frequency versus body size. Resuscitation 2009, 80, 1280–1284. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Schmölzer, G.M. Chest Compressions during Sustained Inflation during Cardiopulmonary Resuscitation in Newborn Infants Translating Evidence from Animal Studies to the Bedside. JACC Basic Transl. Sci. 2019, 4, 116–121. [Google Scholar] [CrossRef] [PubMed]
- Schmölzer, G.M.; O’Reilly, M.; LaBossiere, J.; Lee, T.-F.; Cowan, S.; Qin, S.; Bigam, D.L.; Cheung, P.-Y. Cardiopulmonary resuscitation with chest compressions during sustained inflations: A new technique of neonatal resuscitation that improves recovery and survival in a neonatal porcine model. Circulation 2013, 128, 2495–2503. [Google Scholar] [CrossRef] [Green Version]
- Li, E.S.; Cheung, P.-Y.; Lee, T.-F.; Lu, M.; O’Reilly, M.; Schmölzer, G.M. Return of spontaneous Circulation Is not Affected by Different Chest Compression Rates Superimposed with Sustained Inflations during Cardiopulmonary Resuscitation in Newborn Piglets. PLoS ONE 2016, 11, e0157249. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Li, E.S.; Görens, I.; Cheung, P.-Y.; Lee, T.-F.; Lu, M.; O’Reilly, M.; Schmölzer, G.M. Chest Compressions during Sustained Inflations Improve Recovery when Compared to a 3:1 Compression:Ventilation Ratio during Cardiopulmonary Resuscitation in a Neonatal Porcine Model of Asphyxia. Neonatology 2017, 112, 337–346. [Google Scholar] [CrossRef] [PubMed]
- Kilkenny, C.; Altman, D.G.; Browne, W.J.; Cuthill, I.C.; Emerson, M. Improving Bioscience Research Reporting: The ARRIVE Guidelines for Reporting Animal Research. J. Pharmacol. Pharmacother. 2010, 8, e1000412. [Google Scholar] [CrossRef]
- Wagner, M.; Cheung, P.-Y.; Li, E.S.; Lee, T.-F.; Lu, M.; O’Reilly, M.; Olischar, M.; Schmölzer, G.M. Effects of epinephrine on hemodynamic changes during cardiopulmonary resuscitation in a neonatal piglet model. Pediatr. Res. 2018, 83, 897–903. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Schmölzer, G.M.; Kamlin, C.O.F.; Dawson, J.A.; te Pas, A.B.; Morley, C.J.; Davis, P.G. Respiratory monitoring of neonatal resuscitation. Arch. Dis. Child.-Fetal Neonatal Ed. 2010, 95, F295–F303. [Google Scholar] [CrossRef]
- Os, S.; Cheung, P.; Pichler, G.; Aziz, K.; O’Reilly, M.; Schmölzer, G.M. Exhaled carbon dioxide can be used to guide respiratory support in the delivery room. Acta Paediatr. 2014, 103, 796–806. [Google Scholar] [CrossRef]
- Bruckner, M.; Kim, S.Y.; Shim, G.H.; Neset, M.; Garcia-Hidalgo, C.; Lee, T.F.; O’Reilly, M.; Cheung, P.Y.; Schmölzer, G.M. Assessment of optimal chest compression depth during neonatal cardiopulmonary resuscitation: A randomised controlled animal trial. Arch. Dis. Child.-Fetal Neonatal Ed. 2022, 107, 262–268. [Google Scholar] [CrossRef]
- Bruckner, M.; O’Reilly, M.; Lee, T.-F.; Neset, M.; Cheung, P.Y.; Schmölzer, G.M. Effects of varying chest compression depths on carotid blood flow and blood pressure in asphyxiated piglets. Arch. Dis. Child.-Fetal Neonatal Ed. 2021, 106, 553–556. [Google Scholar] [CrossRef]
- Garcia-Hidalgo, C.; Solevåg, A.; Kim, S.Y.; Shim, G.H.; Cheung, P.-Y.; Lee, T.-F.; O’Reilly, M.; Schmölzer, G.M. Sustained inflation with 21% versus 100% oxygen during cardiopulmonary resuscitation of asphyxiated newborn piglets-A randomized controlled animal study. Resuscitation 2020, 155, 39–47. [Google Scholar] [CrossRef]
- Garcia-Hidalgo, C.; Cheung, P.-Y.; Vento, M.; Solevåg, A.L.; O’Reilly, M.; Saugstad, O.; Schmölzer, G.M. A Review of Oxygen Use During Chest Compressions in Newborns—A Meta-Analysis of Animal Data. Front. Pediatr. 2018, 6, S196–S197. [Google Scholar] [CrossRef] [Green Version]
- Solevåg, A.; Lee, T.-F.; Lu, M.; Schmölzer, G.M.; Cheung, P.-Y. Tidal volume delivery during continuous chest compressions and sustained inflation. Arch. Dis. Child.-Fetal Neonatal Ed. 2017, 102, F85–F87. [Google Scholar] [CrossRef]
- Shim, G.-H.; Kim, S.Y.; Cheung, P.-Y.; Lee, T.-F.; O’Reilly, M.; Schmölzer, G.M. Effects of sustained inflation pressure during neonatal cardiopulmonary resuscitation of asphyxiated piglets. PLoS ONE 2020, 15, e0228693. [Google Scholar] [CrossRef]
- Mustofa, J.; Cheung, P.-Y.; Patel, S.; Lee, T.-F.; Lu, M.; Pasquin, M.P.; O’Reilly, M.; Schmölzer, G.M. Effects of different durations of sustained inflation during cardiopulmonary resuscitation on return of spontaneous circulation and hemodynamic recovery in severely asphyxiated piglets. Resuscitation 2018, 129, 82–89. [Google Scholar] [CrossRef]
- Sankaran, D.; Vali, P.; Chandrasekharan, P.; Chen, P.; Gugino, S.F.; Koenigsknecht, C.; Helman, J.; Nair, J.; Mathew, B.; Rawat, M.; et al. Effect of a Larger Flush Volume on Bioavailability and Efficacy of Umbilical Venous Epinephrine during Neonatal Resuscitation in Ovine Asphyxial Arrest. Children 2021, 8, 464. [Google Scholar] [CrossRef] [PubMed]
- Sankaran, D.; Chandrasekharan, P.K.; Gugino, S.F.; Koenigsknecht, C.; Helman, J.; Nair, J.; Mathew, B.; Rawat, M.; Vali, P.; Nielsen, L.; et al. Randomised trial of epinephrine dose and flush volume in term newborn lambs. Arch. Dis. Child.-Fetal Neonatal Ed. 2021, 106, 578–583. [Google Scholar] [CrossRef]
- Fitzgerald, K.R.; Babbs, C.F.; Frissora, H.A.; Davis, R.W.; Silver, D.I. Cardiac output during cardiopulmonary resuscitation at various compression rates and durations. Am. J. Physiol.-Heart Circ. Physiol. 1981, 241, H442–H448. [Google Scholar] [CrossRef] [Green Version]
- Vrancken, S.L.; Heijst AF van de Boode, W.P. Neonatal Hemodynamics: From Developmental Physiology to Comprehensive Monitoring. Front. Pediatr. 2018, 6, 87. [Google Scholar] [CrossRef] [Green Version]
- Patel, S.; Cheung, P.-Y.; Lee, T.-F.; Pasquin, M.P.; Lu, M.; O’Reilly, M.; Schmölzer, G.M. Asynchronous ventilation at 120 compared with 90 or 100 compressions per minute improves haemodynamic recovery in asphyxiated newborn piglets. Arch. Dis. Child.-Fetal Neonatal Ed. 2020, 105, 357–363. [Google Scholar] [CrossRef]
- Vali, P.; Lesneski, A.; Hardie, M.; Alhassen, Z.; Chen, P.; Joudi, H.; Sankaran, D.; Lakshminrusimha, S. Continuous chest compressions with asynchronous ventilations increase carotid blood flow in the perinatal asphyxiated lamb model. Pediatr. Res. 2021, 90, 752–758. [Google Scholar] [CrossRef] [PubMed]
- Bruckner, M.; Neset, M.; O’Reilly, M.; Lee, T.-F.; Cheung, P.-Y.; Schmölzer, G.M. Haemodynamic changes with varying chest compression rates in asphyxiated piglets. Arch. Dis. Child.-Fetal Neonatal Ed. 2022. [Google Scholar] [CrossRef] [PubMed]
- Boldingh, A.M.; Jensen, T.H.; Bjørbekk, A.T.; Solevåg, A.L.; Nakstad, B. Rescuers’ physical fatigue with different chest compression to ventilation methods during simulated infant cardiopulmonary resuscitation. J. Matern.-Fetal Neonatal Med. 2015, 29, 3202–3207. [Google Scholar] [CrossRef] [PubMed]
- Li, E.S.; Cheung, P.-Y.; O’Reilly, M.; Aziz, K.; Schmölzer, G.M. Rescuer fatigue during simulated neonatal cardiopulmonary resuscitation. J. Perinatol. 2015, 35, 142–145. [Google Scholar] [CrossRef] [PubMed]
Figure 1.
Study flow diagram.
Figure 2.
Changes in systolic blood pressure, diastolic blood pressure, mean blood pressure, and carotid blood flow during chest compression were divided into 10 epochs.
Figure 2.
Changes in systolic blood pressure, diastolic blood pressure, mean blood pressure, and carotid blood flow during chest compression were divided into 10 epochs.
Figure 3.
% change from baseline in stroke volume, end-diastolic volume, dp/dt max (maximal rate of rise of left ventricular pressure), and dp/dt min (minimum rate of change of ventricular pressure).
Figure 3.
% change from baseline in stroke volume, end-diastolic volume, dp/dt max (maximal rate of rise of left ventricular pressure), and dp/dt min (minimum rate of change of ventricular pressure).
Table 1.
Characteristics of Newborn Piglets at Baseline and at Commencement of Cardiopulmonary Resuscitation.
Table 1.
Characteristics of Newborn Piglets at Baseline and at Commencement of Cardiopulmonary Resuscitation.
| CC Rate 90/min (n = 7) | CC Rate 180/min (n = 7) | p Value | |
|---|---|---|---|
| Baseline characteristics | |||
| Age (days) | 2 (1–3) | 3 (1–3) | 0.81 |
| Weight (kg) | 2.2 (2.0–2.4) | 2.0 (1.9–2.2) | 0.21 |
| Heart rate (bpm) | 144 (142–159) | 140 (131–168) | 0.86 |
| Mean Arterial blood pressure (mmHg) | 53 (52–61) | 57 (50–62) | 0.82 |
| Carotid flow (mL/min) | 36 (34–51) | 31 (20–37) | 0.18 |
| Cerebral oxygenation (%) | 32 (32–41) | 36 (34–45) | 0.20 |
| pH | 7.47 (7.46–7.51) | 7.51 (7.48–7.52) | 0.12 |
| PaO2 (torr) | 62 (61–90) | 62 (55–71) | 0.46 |
| PaO2 (torr) | 36.3 (35.0–38.9) | 37.4 (34.1–40.0) | 0.94 |
| Base excess (mmol/L) | 3 (2–4) | 4 (3–7) | 0.17 |
| Lactate (mmol/L) | 3.6 (2.5–4.2) | 2.6 (2.5–3.1) | 0.37 |
| Duration of asphyxia (s) | 440 (280–506) | 470 (360–585) | 0.65 |
| Characteristics at commencement of Resuscitation | |||
| Heart rate (bpm) | 0 (0–0) | 0 (0–0) | |
| Carotid blood flow (mL/min) | 0 (0–0) | 0 (0–0) | |
| Arterial pH | 6.58 (6.54–6.68) | 6.55 (6.50–6.73) | 0.46 |
| paCO2 (torr) | 102 (67–121) | 106 (86–112) | 0.68 |
| Lactate (mmol/L) | 16 (16–19) | 19 (17–20) | 0.13 |
| Base Excess (mmol/L) | −29 (−30–−26) | −28 (−30–−22) | 0.65 |
| Characteristics immediately after return of spontaneous circulation | |||
| Heart rate (bpm) | 180 (165–212) | 204 (182–248) | 0.21 |
| Carotid blood flow (mL/min) | 23 (21–30) | 20 (16–23) | 0.12 |
| Arterial pH | 6.78 (6.52–6.84) | 6.78 (6.74–6.96) | 0.54 |
| paCO2 (torr) | 50 (39–73) | 52 (40–58) | 0.43 |
| Lactate (mmol/L) | 20 (18–20) | 20 (20–20) | 0.36 |
| Base Excess (mmol/L) | −28 (−30–−26) | −26 (−29–−25) | 0.38 |
| Characteristics 30 min after return of spontaneous circulation | |||
| Heart rate (bpm) | 190 (152–219) | 206 (192–241) | 0.19 |
| Carotid blood flow (mL/min) | 29 (25–39) | 33 (18–39) | 0.87 |
| Arterial pH | 7.02 (6.93–7.19) | 7.12 (6.97–7.24) | 0.65 |
| paCO2 (torr) | 37 (33–57) | 33 (28–44) | 0.64 |
| Lactate (mmol/L) | 16 (14–19) | 17 (16–19) | 0.47 |
| Base Excess (mmol/L) | −20 (−23–−15) | −20 (−23–−17) | 0.79 |
Data are presented as median (IQR); CC = chest compression.
Table 2.
Respiratory parameters during CPR.
| CC Rate 90/min (n = 7) | CC Rate 180/min (n = 7) | p Value | |
|---|---|---|---|
| Tidal volume (mL/kg) | 5.8 (0.9) | 5.3 (1.4) | 0.477 |
| Minute Ventilation (mL/kg/min) | 522 (79) | 945 (248) | 0.003 |
| Peak Inspiratory Flow (L/min) | 3.7 (0.4) | 5.8 (0.9) | 0.0007 |
| Peak Expiration Flow (L/min) | −5.8 (0.7) | −8.0 (0.7) | 0.0009 |
| Peak Inflation Pressure (cmH2O) | 30.0 (1.5) | 31.1 (4.2) | 0.546 |
| Positive End Expiratory Pressure (cmH2O) | 29.1 (2.0) | 30.2 (5.1) | 0.625 |
| End-tidal CO2 (mmHg) | 18 (7) | 23 (15) | 0.248 |
| Rate (/min) * | 90 (1) | 179 (1) | <0.0001 |
Data are presented as the mean (SD), * Rate = Ventilation and number of chest compressions, which corresponds to the number of ventilations per minute; CC = chest compression.
Table 3.
Data separated by sex.
| CC Rate 90/min (n = 7) | CC Rate 180/min (n = 7) | |||||
|---|---|---|---|---|---|---|
| Male (n = 2) | Female (n = 5) | p Value | Male (n = 3) | Female (n = 4) | p Value | |
| Asphyxia time (s) # | 399 (198–600) | 440 (313–501) | 1.00 | 430 (360–585) | 481 (365–573) | 0.86 |
| Achieving ROSC (n) | 1 (50%) | 3 (60%) | 1.00 | 3 (100%) | 4 (100%) | 1.00 |
| ROSC time (s) # | 395 (189–600) | 136 (88–600) | 0.57 | 79 (73–118) | 137 (95–290) | 0.23 |
| Requiring epinephrine (n) | 2 (100%) | 3 (60%) | 1.00 | 0 (0%) | 2 (50%) | 0.43 |
| Epinephrine doses # | 2 (1–3) | 1 (0–3) | 0.57 | 0 (0–0) | 0.5 (0–2) | 0.40 |
Data are presented as numbers (%), unless indicated # median (IQR); CC = chest compression.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. |
© 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Bruckner, M.; Neset, M.; Garcia-Hidalgo, C.; Lee, T.-F.; O’Reilly, M.; Cheung, P.-Y.; Schmölzer, G.M. Chest Compression Rates of 90/min versus 180/min during Neonatal Cardiopulmonary Resuscitation: A Randomized Controlled Animal Trial. Children 2022, 9, 1838. https://0-doi-org.brum.beds.ac.uk/10.3390/children9121838
AMA Style
Bruckner M, Neset M, Garcia-Hidalgo C, Lee T-F, O’Reilly M, Cheung P-Y, Schmölzer GM. Chest Compression Rates of 90/min versus 180/min during Neonatal Cardiopulmonary Resuscitation: A Randomized Controlled Animal Trial. Children. 2022; 9(12):1838. https://0-doi-org.brum.beds.ac.uk/10.3390/children9121838
Chicago/Turabian StyleBruckner, Marlies, Mattias Neset, Catalina Garcia-Hidalgo, Tze-Fun Lee, Megan O’Reilly, Po-Yin Cheung, and Georg M. Schmölzer. 2022. "Chest Compression Rates of 90/min versus 180/min during Neonatal Cardiopulmonary Resuscitation: A Randomized Controlled Animal Trial" Children 9, no. 12: 1838. https://0-doi-org.brum.beds.ac.uk/10.3390/children9121838
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
