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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

Here, we present a US-CAB (Ultrasound, Circulation/Airway/Breathing) protocol for use during cardiopulmonary resuscitation (CPR). US-C evaluates the subxiphoid view of the heart and inferior vena cava. After intubation, tracheal US (US-A) and lung US (US-B) help confirm endotracheal intubation and proper ventilation.

Abstract

The US-CAB (Ultrasound, Circulation/Airway/Breathing) protocol integrates several sonographic techniques into a structured assessment of the circulation, airway, and breathing status of a patient during cardiopulmonary resuscitation (CPR) in an advanced life support-compliant manner. US-C provides a subxiphoid view of the heart, to look for potentially reversible causes of disease, such as pericardial effusion, pulmonary embolism, hypovolemia, and acute coronary thrombosis. Sonographic cardiac activity during CPR not only helps differentiate pseudo-pulseless electrical activity (PEA) from true PEA but also represents a higher chance of the return of spontaneous circulation (ROSC) and survival. Evaluation of the inferior vena cava (IVC) shows the fluid status of the patient and indicates the best methods to use for fluid resuscitation. If aortic dissection is suspected, a subxiphoid view of the aorta is suggested for identifying an intimal flap. Once intubation is done, tracheal ultrasound (US-A) at the suprasternal notch helps differentiate endotracheal intubation (one air-mucosal interface with one comet-tail) from esophageal intubation (double tract sign). Immediately following US-A, bilateral lung US (US-B) should be done to confirm proper bilateral ventilation using the lung sliding sign. In addition, US-C can be serially followed to see the dynamic changes in the cardiac chambers and IVC, or any cardiac contraction suggestive of ROSC. US-B can also detect coexisting lung or pleural pathologies without interfering with the performance of CPR. The main concern when implementing this method is maintaining high-quality CPR without delays in chest compressions when performing US-CAB. Rigorous training and continued practice are key to minimize any interruptions during resuscitation.

Introduction

Effective cardiopulmonary resuscitation (CPR) for cardiac arrest is key to successful revival of a patient. Circulation (C), airway (A), and breathing (B) are the three crucial components in either basic (BLS) or advanced life support (ALS). The evaluation of the C-A-B status during CPR basically relies on pulse checks, auscultation, and capnography1. In true clinical conditions, however, CPR is often complex and chaotic, and these methods may have limitations2,3. For example, the accuracy of pulse checks is often suboptimal even when performed by healthcare providers4. More than half of one lung intubations might be misdirected if guided by auscultation alone5. Even wave capnography can be affected by factors such as low cardiac output, low pulmonary flow, and use of epinephrine during CPR2. Therefore, more effective, accurate evaluation of the C-A-B status is mandatory.

When trying to search for the etiology of cardiac arrest or any potentially reversible factors during CPR, medical history and physical examination are often insufficient. The detection of reversible causes, such as the 5Hs (i.e., hypoxia, hypovolemia, hyperkalemia/hypokalemia, acidosis, and hypothermia) and the 5Ts (i.e., cardiac tamponade, tension pneumothorax, pulmonary thromboembolism, coronary thrombosis, and toxins or tablets), often requires advanced examinations.

Ultrasound (US) is a useful imaging modality in emergency and critical care settings. The European Resuscitation Council (ERC) Guidelines suggest that US can be an integral part of resuscitation6. US can readily identify critical but potentially reversible factors that negatively affect CPR, such as cardiac tamponade, pulmonary thromboembolism, and hypovolemia7,8,9. US also helps rule out pneumothorax and acute coronary syndrome. Moreover, US confers prognostic implications even when CPR is being performed. The presence of sonographic cardiac activity during CPR has been reported to confer higher chances of ROSC, survival, and hospital discharge10,11. In addition to sonographic evaluation of the heart and circulation status, tracheal US is employed for confirmation of proper endotracheal intubation12, while lung US is applied to confirm proper bilateral pulmonary ventilation13.

While high-quality CPR with minimal interruptions to the compressions is the most important factor for resuscitation, it is important to understand how to seamlessly integrate US into the process of resuscitation without interfering with CPR. We therefore developed a novel, ALS-compliant US-CAB protocol for use during CPR14. This paper presents a detailed description of the settings, personnel, and instruments necessary for better integration of the US protocol into the regular CPR process that first-line physicians can easily incorporate and implement into their practice.

Protocol

This procedure was approved by the Institutional Review Board of the National Taiwan University Hospital and registered at ClinicalTrials.gov (NCT02952768).

1. Instrumentation

  1. Use a US machine equipped with a curvilinear 2–5 MHz probe. A portable US is more suitable for CPR.

2. Personnel and their roles in the resuscitation team

  1. Ideally, a resuscitation team should be comprised of six members: 1) a leader; 2) a member for airway management (A) and ventilation (B); 3) one for chest compressions (C); 4) one for defibrillation (D); 5) one for intravenous (IV) catheterization and medication; and 6) a recorder.
  2. If the personnel is limited, have the roles overlap. When US is integrated into the CPR process, the sonographer should be an independent member of the team who is well trained and experienced in resuscitation US and can intervene and interpret the US images in a timely manner without interrupting or delaying resuscitation efforts. However, the leader can also be the sonographer. He or she can use US to search for any potentially reversible causes of resuscitation failure as early as possible while leading the whole CPR process.

3. Cardiopulmonary resuscitation process

  1. Perform all resuscitation procedures according to the ALS guidelines6.
  2. When US is integrated into the CPR process, strict control to minimize interruption of the chest compressions is the highest priority. Restrict the hands-off interval for pulse checks/rhythm analysis and simultaneous US evaluation to no longer than 10 s.
    1. Use a timer with preset alarms to remind the sonographer of the time intervals. Set the alarm for every 2 min of CPR and 10 s for pulse checks.

4. US-CAB protocol

  1. US-C: Use cardiac US (US-C) at the start of CPR and at the end of the first five cycles of chest compressions.
    1. Use the subxiphoid four-chamber view (Figure 1A) to check pericardial effusion, the size of the right and left ventricles, and sonographic cardiac activity.
    2. Turn the probe 90° (parallel to the long axis of the patient) to measure the diameter of the IVC (Figure 1B).
  2. US-A: Use US-A to check the endotracheal tube location after intubation.
    1. Place the probe transversely at the suprasternal notch (Figure 1C).
    2. Note the one air-mucosal interface with one comet-tail artifact (single tract sign) for tracheal intubation.
    3. Move the probe to the lateral side of the neck to reconfirm the single tract sign.
    4. Perform reintubation if there are two air-mucosal interfaces with two comet-tail artifacts (double tract sign)12.
  3. US-B: Use US-B to check proper ventilation.
    1. Put the probe on either side of the chest at the 4th–5th intercostal spaces over the midaxillary line (Figure 1D).
    2. Detect lung sliding to evaluate pulmonary ventilation11,13.
    3. If lung sliding is absent on one side, adjust the depth of the endotracheal tube until bilateral lung sliding is noticed.
  4. US-C: Repeat US-C every 2 min when chest compression is stopped for pulse checks.
  5. Repeat US-AB after transportation and bed transfer of the patient.

5. Settings and approach during CPR

  1. Keep the US machine ready in the resuscitation room of the emergency department. In cases of in-hospital cardiac arrest, a portable US device can be brought to the scene immediately, and turned on instantly.
  2. Because a lot of resuscitation procedures are performed around the head, neck, and chest of the patient (e.g., chest compressions, defibrillation, intubation, ventilation, etc.), place the US machine in the caudal area of the patient (Figure 2). For example, it should be located over the patient’s right side for a right-handed sonographer and vice versa. This way the sonographer can get the probe ready and immediately assess the patient’s condition.

6. Image acquisition and recording

  1. Have the US images interpreted by the sonographer and print or store important images for medical records and further discussion with the resuscitation team.
  2. Ideally, store the US images in the hard disk of the US machine for regular (e.g., monthly) review, either for quality assurance or teaching purposes. Video recording is even better, as it not only provides important information that is less well characterized by still photos but also offers materials for training or subsequent analysis.

7. Data interpretation and analysis

  1. Have the sonographer interpret the US images during CPR on-site to help with clinical judgement and decision making. A sonographer, after structured training and continued practice, can perform sonographic evaluation and interpret the data in real CPR scenarios. The interpretation and discussion of the data can also be done by all resuscitation team members during debriefing immediately after the post-CPR phase. The discussion focuses not only on US diagnosis, but on the therapeutic interventions and impact on CPR outcomes following the US examination.
  2. For research purposes, also have interpretation done afterwards by blinded researchers.

Results

US-C with subxiphoid evaluation of the heart displays a cardiac four-chamber view as shown in Figure 3A. At this point, detection of any of the three typical patterns suggestive of specific etiologies or reversible factors is possible.

Identify the presence and characters of pericardial effusion: If pericardial effusion is present, notice if the right heart chambers (i.e., the right atrium or even the right ventricle) are compressed. If compression of the right at...

Discussion

US is a noninvasive, real-time, and readily available imaging modality in emergency and critical care settings. Application of US during CPR plays an important role in diagnosis, guidance of therapeutic intervention, or monitoring15. While many US protocols have been introduced for use with CPR, the US-CAB protocol complies with the sequence of advanced life support (ALS). It integrates important US techniques to detect possibly reversible causes of any issues, and to evaluate the C-A-B status dur...

Disclosures

The authors have nothing to disclose.

Acknowledgements

This study was supported in part by the grants from the Ministry of Science and Technology, Taiwan (MOST 103-2511-S-002-007). The authors would like to thank Dr. Chih-Hsien Wu and Mr. Jen-Chih Sung for helping the preparation of the photographs and film.

Materials

NameCompanyCatalog NumberComments
UltrasoundCannon, JapanSSA-550Anil

References

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  2. Takeda, T., et al. The assessment of three methods to verify tracheal tube placement in the emergency setting. Resuscitation. 56 (2), 153-157 (2003).
  3. Levine, R., Wayne, M., Miller, C. End-tidal carbon dioxide and outcome of out-of-hospital cardiac arrest. New England Journal of Medicine. 337, 301-306 (1997).
  4. Moule, P. Checking the carotid pulse: diagnostic accuracy in students of the healthcare professions. Resuscitation. 44 (3), 195-201 (2000).
  5. Sitzwohl, C., et al. Endobronchial intubation detected by insertion depth of endotracheal tube, bilateral auscultation, or observation of chest movements: randomised trial. British Medical Journal. 341, 5943 (2010).
  6. Monsieurs, K., et al. European Resuscitation Council Guidelines for Resuscitation 2015: Section 1. Executive summary. Resuscitation. 95, 1-80 (2015).
  7. Breitkreutz, R., et al. Focused echocardiographic evaluation in life support and peri-resuscitation of emergency patients: a prospective trial. Resuscitation. 81 (11), 1527-1533 (2010).
  8. Hernandez, C., et al. C.A.U.S.E.: Cardiac arrest ultra-sound exam--a better approach to managing patients in primary non-arrhythmogenic cardiac arrest. Resuscitation. 76 (2), 198-206 (2008).
  9. Perera, P., Mailhot, T., Riley, D., Mandavia, D. The RUSH exam: Rapid Ultrasound in SHock in the evaluation of the critically lll. Emergency Medicine Clinics of North America. 28 (1), 29-56 (2010).
  10. Blyth, L., Atkinson, P., Gadd, K., Lang, E. Bedside focused echocardiography as predictor of survival in cardiac arrest patients: a systematic review. Academic Emergency Medicine. 19, 1119-1126 (2012).
  11. Lien, W. C., et al. US-CAB protocol for ultrasonographic evaluation during cardiopulmonary resuscitation: validation and potential impact. Resuscitation. 127, 125-131 (2018).
  12. Chou, H. C., et al. Real-time tracheal ultrasonography for confirmation of endotracheal tube placement during cardiopulmonary resuscitation. Resuscitation. 84 (12), 1708-1712 (2013).
  13. Sim, S. S., et al. Ultrasonographic lung sliding sign in confirming proper endotracheal intubation during emergency intubation. Resuscitation. 83 (3), 307-312 (2012).
  14. Lien, W. C., et al. A novel US-CAB protocol for ultrasonographic evaluation during cardiopulmonary resuscitation. Resuscitation. 115, 1-2 (2017).
  15. Roelandt, J. R. Ultrasound stethoscopy. European Journal of Internal Medicine. 15, 337-347 (2004).
  16. Lien, W. C., Chang, W. T. A Potential Pitfall of Tracheal Ultrasound for the Confirmation of Endotracheal Intubations. Journal of Ultrasound in Medicine. , (2019).
  17. Huis In't Veld, M. A., et al. Ultrasound use during cardiopulmonary resuscitation is associated with delays in chest compressions. Resuscitation. 119, 95-98 (2017).
  18. Clattenburg, E. J., et al. Point-of-care ultrasound use in patients with cardiac arrest is associated prolonged cardiopulmonary resuscitation pauses: A prospective cohort study. Resuscitation. 122 (1), 65-68 (2018).
  19. Lien, W. C., et al. Data on evaluation of proficiency for the US-CAB curriculum. Data in Brief. 16 (17), 965-968 (2017).
  20. Lien, W. C., Chang, W. T., Ma, M. H., Chen, W. J. Ultrasonography during CPR: Hands-off or hands-on. Resuscitation. 125, 8-10 (2018).

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US CAB ProtocolUltrasonographic AssessmentCardiopulmonary ResuscitationCPRResuscitation TeamUltrasound IntegrationPericardial EffusionVentricular SizeInferior Vena CavaEndotracheal Tube LocationLung SlidingPulmonary VentilationCardiac UltrasoundAirway Management

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