Lazarus phenomenon revisited: a case of delayed return of spontaneous circulation after carbon dioxide embolism under laparoscopic cholecystectomy


Kerai Sukhyanti, Chand ShriKrishan, Kapur Anu, Dang Ashish

Department of Anesthesiology & Critical Care, NDMCMC & Hindu Rao Hospital, New Delhi-110007 (India)
Correspondence: Dr Sukhyanti Kerai, Department of Anesthesiology & Critical Care, The North Delhi Municipal Corporation Medical College (NDMCMC) & Hindu Rao Hospital, North Delhi Muncipal Corporation, Malka Ganj, New Delhi, Delhi 110007, (India); Cell: +9968527122; E-mail: drsukhi25@gmail.com

ABSTRACT
The Lazarus phenomenon is rare occurrence of delayed return of spontaneous circulation (ROSC) after cardiac arrest when the resuscitation efforts are discontinued. It can have serious medico legal consequences. There are various explanations proposed for this phenomenon. We report a case of intraoperative cardiac arrest due to carbon dioxide embolism under laparoscopic cholecystectomy where ROSC occurred when cardiopulmonary resuscitation was abandoned.

Key words: Lazarus phenomenon; ROSC; Carbon dioxide embolism; Anesthesia

Citation: Sukhyanti K, ShriKrishan C, Anu K, Ashish D. Lazarus phenomenon revisited: a case of delayed return of spontaneous circulation after carbon dioxide embolism under laparoscopic cholecystectomy. Anaesth Pain & Intensive Care 2016;20(3):338-340

Received: 29 June 2016; Reviewed: 30 & 23 August 2016; Accepted: 15 September 2016

INTRODUCTION
The Lazarus phenomenon is rare occurrence of delayed return of spontaneous circulation (ROSC) after cardiac arrest when the resuscitation efforts are discontinued1. The scientific explanations for this phenomenon have been difficult to prove. There are only 39 cases reported so far in medical literature.2,3 The outcome in these cases has been variable with about 45% of cases dying soon after. No significant correlation is observed between the outcome and duration of CPR, time interval for ROSC or the etiology of cardiac arrest..

We report a case of delayed ROSC after a case of probable intraoperative carbon dioxide (CO2) embolism during laparoscopic cholecystectomy.

CASE REPORT
A 25-year-old lady, weighing 60 kg was scheduled to undergo laparoscopic cholecystectomy. The preanesthetic clinical evaluation and routine laboratory investigations were unremarkable. In the operating room standard anesthetic monitoring including continuous electrocardiogram (ECG), pulse oximetry (SpO2) and non-invasive blood pressure (NIBP) were started. For premedication inj midazolam 1 mg and fentanyl 100 μg were administered intravenously (IV). General anesthesia was induced using inj propofol 100 mg and endotracheal intubation was accomplished by inj atracurium 30 mg. For maintenance of anesthesia oxygen and nitrous oxide mixture (33:66) with sevoflurane 1.5% was started. The patient was then handed over to surgeons for the procedure. The volume control mode of ventilation with tidal volume of 500 ml and respiratory rate of 12/min was started. The surgeons started CO2 insufflation at a pressure of 12 mmHg and rate of initially 1lit/min and then increased to 4 lit/min. During insufflations of CO2, end tidal CO2 concentration (EtCO2) started to decrease gradually, we immediately checked for circuit connections. Within a minute heart rate (HR) and SpO2 also began to fall. The heart rate decreased to 50/min from 90/min and SpO2 came down to 70% from baseline of 100%. The surgeons were asked to stop insufflations of CO2 and evacuate the peritoneal cavity. The NIBP reading was 56/28 mmHg. The patient was started on manual ventilation with 100% oxygen and other anesthetic gases were discontinued. However, the patient developed cardiac arrest with ECG showing asystole. Cardiopulmonary resuscitation (CPR) with chest compressions was started at a rate of 100 / min immediately. The patient was manually ventilated with 100% oxygen at a rate of 8-10 / min with low tidal volume just sufficient to produce a visible chest rise. The OT table was moved to head down and right up position. The feasibility of insertion of a central venous catheter in view of suspected CO2 embolism was discussed but it was not favored as it would have required interruption in ongoing chest compression. During the resuscitative efforts continuous capnography monitoring was used to monitor quality of chest compressions. We followed the adult advanced cardiovascular life support algorithm for cardiac arrest for resuscitation. The rhythm check using paddles of defibrillator was done every 2 min after chest compressions. A pulseless ventricular fibrillation was detected in between for which a biphasic shock of 200J was given. The CPR was continued for about 40 min but spontaneous circulation could not be resumed. During this period of CPR, 4 doses of 1 mg adrenaline (1:10000) and a defibrillation shock were administered. After discussion with surgeons and the relatives of the patient the resuscitative efforts were discontinued. Incidentally the endotracheal tube of patient was not disconnected from the ventilator.

About 5-7 min after discontinuation of CPR the ECG on monitor started showing idioventricular rhythm. The carotid pulse was not palpable at this time. After 5 min the sinus rhythm at a rate of 96 / min appeared on monitor. The heart sounds by auscultation were confirmed and the carotid pulse albeit of low volume was also palpable. The NIBP reading was 60/32 mmHg. The patient was administered a bolus of 1 lit of crystalloid solution. The noradrenaline and dopamine infusions were started. Gradually the pulse oximeter plethysmography also appeared on the monitor. However, the BP continued in the range of 70-80 mmHg systolic. The patient was shifted to intensive care unit for further management. Mechanical ventilation with FiO2 100% and infusions of inotropes were continued. Neurological examination revealed dilated non reacting pupils and a Glasgow coma score 3. The arterial blood gas analysis showed severe metabolic acidosis and hypoxia. Attempts for achieving therapeutic hypothermia with available resources were made. After 4 hours the patient again developed cardiac arrest and despite all resuscitative efforts could not be revived.

DISCUSSION
Our patient’s case illustrates a rare occurrence of return of spontaneous circulation (ROSC) after cessation of CPR attempts. This has been reported as Lazarus phenomenon in the literature and the first case was reported in 1982.1,4 So far, only 39 cases of delayed ROSC have been reported with both in-hospital and out of hospital cardiac arrest. The majority of cases were diagnosed as myocardial infarction or obstructive airway disease.2 Other etiologies include ruptured abdominal aortic aneurysm, hyperkalemia, gastrointestinal hemorrhage, fat embolism, trauma, sepsis and toxicity of digoxin, opiates and cocaine.

The exact mechanism of delayed ROSC is unclear. In patients with COPD rapid ventilation without adequate time for expiration during CPR can lead to dynamic hyperinflation (generation of auto- PEEP) of lungs which impairs venous return and cardiac output. Discontinuation of CPR and hyperventilation has been postulated to improve venous return and hence can result in delayed ROSC.5 Other authors have suggested delayed action of drugs administered during CPR, hyperkalemia and myocardial stunning as mechanism of delayed ROSC.6,7
The carbon dioxide embolism during laparoscopic surgeries is rare complication with incidence of 0.001%. The clinically significant CO2 emboli however, may be fatal with reported mortality rate of 28%.8 The majority of cases reported in literature occurred at the beginning of surgery due to misplacement of Veress needle into vein or parenchymal organ. Because of its high solubility, CO2 embolism has less marked effect compared to embolism of air. However, the large amount of CO2 entering into circulation can be fatal. CO2 embolism can manifest itself through a “gas lock” effect in the vena cava, right atrium or pulmonary artery, causing obstruction to venous return, RV ejection, right and left heart failure, paradoxical embolism, arrhythmia, pulmonary hyperten­sion, systemic hypotension, and cardiovascular collapse.

In our case the embolism of CO2 occurred probably due to misplacement of tip of Veress needle into a blood vessel as on the retrospective examination it was noticed to be blood stained. During insufflations of CO2 pressure was maintained at 12-13 mmHg and the flow rate was adjusted 1-5 L/mins. The diagnosis of CO2 embolism was apparent when EtCO2 started falling but simultaneously hemodynamic instability rapidly progressed to asystole. The CPR in our patient was immediately ensued after recognition of embolism. The decision to stop resuscitative efforts were made after 40 minutes of cardiac arrest as the EtCO2 was persistently less than 10 mmHg, carotid pulse was not palpable and no cardiac rhythm appeared by this time. The surprise appearance of idioventricular rhythm and then sinus rhythm prompted us to resume steps for hemodynamic optimization of patient. As with majority of cases of Lazarus phenomenon the ROSC occurred within 10 minutes of cessation of CPR. We tried our best to ensure the optimal quality of chest compressions by maintaining adequate rate and depth, minimizing interruptions, keeping ventilation rate at 8-10 / min and by timely rotation of team members doing chest compressions by our team leader. The delayed ROSC could be related to high solubility of CO2 leading to dissolution of gas lock effect with passage of time. The plausibility of this assumption is supported by the reports of reversal of CO2 embolism with CPR.9,10 The chest compressions during CPR would have also helped in fragmenting CO2 embolism into small bubbles. It is also a possibility that more than one of above mechanisms could be involved in delayed ROSC.

After ROSC however, our patient developed persistent hypotension probably due to ischemia sustained due to gas lock by CO2 emboli causing right ventricular strain or decreased cardiac output. The hypotension did not respond to fluid resuscitation and inotropic supports and ultimately led to second episode of cardiac arrest.

CONCLUSION
The delayed return of ROSC can have serious medicolegal and professional consequences. As majority of reported patients with Lazarus phenomenon have had ROSC within 10 minutes after cessation of CPR, one should always monitor a patient at least for ten minutes or longer following unsuccessful CPR.

Conflict of interest: None declared by the authors.

Author contribution: All authors took part in the management of the patient and preparation of the manuscript.

REFERENCES
  1. Bray JG Jr. The Lazarus phenomenon revisited. Anesthesiology. 1993 May;78(5):991. [PubMed] [Free full text]
  2. Adhiyaman V, Adhiyaman S, Sundaram R. The Lazarus phenomenon. J R Soc Med. 2007 Dec; 100(12):552-7.[PubMed] [Free full text]
  3. Huang Y, Kim S, Dharia A, Shalshin A, Dauer J. Delayed return of spontaneous circulation following cessation of cardiopulmonary resuscitation in older patient: a case report. J Med Case Rep. 2013 Mar 12;7:65. doi: 1186/1752-1947-7-65. [PubMed] [Free full text]
  4. Linko K, Honkavaara P, Salmenpera M. Recovery after discontinued cardiopulmonary resuscitation. Lancet. 1982 Jan 9;1(8263):106-7.[PubMed]
  5. Rogers PL, Schlichtig R, Miro A,Pinsky M. Auto-PEEP during CPR. An “occult” cause of electromechanical dissociation? Chest. 1991 Feb;99(2):492-3.[PubMed]
  6. Quick G, Bastani B. Prolonged asystolic hyperkalemic cardiac arrest with no neurological sequalae. Ann Emerg Med. 1994 Aug;24(2):305-11.[PubMed]
  7. Martens P,Vandekerckhove YMullie A. Return of spontaneous circulation after cessation of cardiopulmonary resuscitation. Lancet. 1993 Mar 27;341(8848):841. [PubMed]
  8. Park EY, Kwon JY, Kim KJ. Carbon dioxide embolism during laproscopy. Yonsei Med J. 2012 May;53(3):459-66. doi: 10.3349/ymj.2012.53.3.459. [PubMed] [Free full text]
  9. Haroun‐Bizri S, El Rassi T. Successful resuscitation after catastrophic carbon dioxide embolism during laparoscopic cholecystectomy. Eur J Anaesthesiol. 2001;18:118-21.
  10. Zhang W, Ho KS, Han HJ, Kong CS, Eu KW. Successful resuscitation after carbon dioxide embolism during laparoscopic-assisted abdomino-perineal resection. Singapore Med J. 2005;46(7):347. [Free full text]