Limiting Emergence Phenomena After General Anesthesia With Combined LMA and ETT Airway Management Technique

Not Applicable

Recruiting

• Conditions: Limit Emergence Phenomena After General Anesthesia
• Interventions: Procedure: Induction of anesthesia; Device: Laryngoscopy and placement of ETT; Device: Placement of LMA [Ambu (R) AuraGain (TM) disposable laryngeal mask]; Procedure: Ventilation via the ETT; Procedure: Removal of the ETT; Procedure: Intubation of the trachea through the LMA; Procedure: Ventilation via the LMA; Procedure: Emergence from anesthesia

• Registration Number: NCT02708836
• Lead Sponsor: Milton S. Hershey Medical Center

Brief Summary

Emergence from general anesthesia with a laryngeal mask airway compared with an endotracheal tube has been shown to favorable with respect to limiting emergence phenomena such as coughing, straining, restlessness, and sympathetic stimulation leading to hypertension and tachycardia.

Many anesthesiologists would prefer the use of an ETT to an LMA in cases in which higher ventilation pressures may be required, in those patients who are perceived to be high risk for reflux and pulmonary aspiration of gastric contents, as well as during cases that allow the anesthesiologist to have little accessibility the airway.

The aim of this study is to investigate an airway management technique that would allow for the benefits of the ETT in terms of a secure airway for the duration of the surgical procedure as well the potential for less emergence phenomena seen when emerging with an LMA.

Detailed Description

Emergence from general anesthesia is a critical period of anesthetic management (1. Popat, 2012). The noxious stimuli of an endotracheal tube as well as the excitement stage of anesthesia, commonly seen prior to return of consciousness while emerging from general anesthesia, both lead to emergence phenomena of coughing, straining, and restlessness in addition to physiologic derangements (2. Atkinson, 1987). Physiologically, emergence from anesthesia is associated with rising sympathetic tone (as evidenced by elevated catecholamine levels and the resultant hemodynamic changes of increasing heart rate and blood pressure), intracranial pressure, and intraocular pressure. Airway tone and reflexes are also problematic as they may be depressed by the lingering pharmacologic effects of anesthetics and analgesics leading to decreased airway obstruction or aspiration events. Airway reflexes may also be exaggerated while traversing the excitement stage; this can lead to undesirable consequences of coughing, breath-holding, bucking or in extreme cases laryngospasm. A smooth emergence is preferable for all patients but is required for those patients who would not tolerate the above physiologic changes (e.g. severe aortic stenosis or coronary artery disease, both of which would poorly tolerate tachycardia) or those would be at risk in terms of the procedure that was performed (cerebral aneurysm clipping, carotid endarterectomy, thyroidectomy: procedures in which stress fresh surgical wounds with hypertension and straining would be undesirable).

Several airway management (3. Koga 1998, 4. Perello-Cerda 2015) and pharmacologic strategies (5. Minogue 20014, 6. Nho 2009, 7. Guler 2005) have been employed to provide a smooth emergence from general anesthesia. One of the most efficacious strategies is the use of supraglottic airway devices rather than endotracheal tubes. Despite evidence supporting the safety and efficacy of ventilation of SGAs during laparoscopic procedures (8. Natalini 2003, 9. Belena 2012, 10. Carron 2012, 11. Bernardini 2009), many anesthesiologists would prefer the use of an ETT to an SGA in cases in which higher ventilation pressures may be required (obesity, steep Trendeleberg position, pneumoperitoneum). In addition to the cases requiring high ventilation pressures, ETTs are preferred to SGAs in those patients who are perceived to be high risk for reflux and pulmonary aspiration of gastric contents (non-fasted, intestinal obstruction, gastroparesis, parturients), as well as during cases that allow the anesthesiologist to have little accessibility the airway (neurosurgical, ENT, etc).

The Bailey maneuver (managing the airway with an ETT throughout the case and then exchanging for an LMA while deeply anesthetized (12. Nair 1995), has also been shown to provide less stimulating emergence. Unfortunately, the Bailey maneuver is relatively contraindicated in cases in which there is the perception that reintubation would be difficult, as the risks of exchanging a functioning airway device for one that has not been tested outweighs the potential benefits of a smooth emergence.

The airway management technique under investigation involves initially placing an LMA after induction of anesthesia. Once adequate ventilation has been accomplished using the LMA, the patient will be endotracheally intubated using a fiberoptic bronchoscope and the in situ LMA as a conduit (13. Timmermann 2011). General anesthesia will be maintained with sevoflurane and narcotics at the discretion of the primary anesthesiologist. The patient will be ventilated via the endotracheal tube during the duration of the surgical procedure and then the trachea will be extubated while the patient is at a deep plane of anesthesia after release of the pneumoperitoneum and return to supine positioning. This technique is a potential method for reducing the stress of emergence in patients who would benefit from the use of an endotracheal tube intraoperatively.

Study Timeline

• Study First Submitted: 2016-03-04
• Study First Submitted QC: 2016-03-09
• Study First Posted: 2016-03-15
• Study Start: 2020-01-01
• Status Verified: 2025-03
• Last Update Submitted: 2025-03-19
• Last Update Posted: 2025-03-24
• Primary Completion: 2025-06-01
• Study Completion: 2025-06-01

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 130

Inclusion Criteria

• ASA 1-3
• Patients undergoing elective laparoscopic surgery

Exclusion Criteria

• Individuals who cannot provide consent
• Individuals who would require translation services to provide consent
• Prisoners
• Parturients
• Non-fasted patients (as per HMC Anesthesiology Department NPO policy)
• Patients felt to be high risk for gastric reflux and pulmonary aspiration (those with gastroparesis, symptomatic GERD, etc.: at the discretion of primary anesthesia team) Those patients with anticipated difficult airway requiring maintenance of spontaneous ventilation (awake intubation)

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
ETT only	Induction of anesthesia	Endotracheal tube intubation after induction of anesthesia. Ventilation with ETT until emergence.
Combined ETT/LMA technique	Removal of the ETT	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
Combined ETT/LMA technique	Emergence from anesthesia	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
ETT only	Laryngoscopy and placement of ETT	Endotracheal tube intubation after induction of anesthesia. Ventilation with ETT until emergence.
ETT only	Removal of the ETT	Endotracheal tube intubation after induction of anesthesia. Ventilation with ETT until emergence.
Combined ETT/LMA technique	Placement of LMA [Ambu (R) AuraGain (TM) disposable laryngeal mask]	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
Combined ETT/LMA technique	Ventilation via the ETT	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
ETT only	Ventilation via the ETT	Endotracheal tube intubation after induction of anesthesia. Ventilation with ETT until emergence.
Combined ETT/LMA technique	Ventilation via the LMA	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
ETT only	Emergence from anesthesia	Endotracheal tube intubation after induction of anesthesia. Ventilation with ETT until emergence.
Combined ETT/LMA technique	Induction of anesthesia	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.
Combined ETT/LMA technique	Intubation of the trachea through the LMA	Placement of LMA after induction of anesthesia. Intubation of trachea with ETT via LMA with fiberoptic bronchoscope. Ventilation with ETT throughout case. Removal of ETT while deeply anesthetized. Ventilation with LMA until emergence.

Primary Outcome Measures

Name	Time	Method
Change in rate pressure product during emergence	Intraoperative	Difference in heart rate multiplied by systolic blood pressure measured during the \~5 minutes prior to emergence and the \~5 minutes after removal of the airway device. Heart rate is continuously monitored and recorded at one minute intervals. Blood pressure is intermittently monitored at 3 minute intervals. The two SBPs measured prior to removal of the airway device will be multiplied by the HR at those times and the RPPs will be averaged. This will be compared with average of the product of the two SBPs and their corresponding HRs measured after removal of the airway device.

Secondary Outcome Measures

Name	Time	Method
Change in rate pressure product during induction of anesthesia and intubation	Intraoperative	Difference in heart rate multiplied by systolic blood pressure measured during the \~5 minutes prior to induction of anesthesia and the \~5 minutes after placement of the airway device. Heart rate is continuously monitored and recorded at one minute intervals. Blood pressure is intermittently monitored at 3 minute intervals. The two SBPs measured prior to placement of the airway device will be multiplied by the HR at those times and the RPPs will be averaged. This will be compared with average of the product of the two SBPs and their corresponding HRs measured after placement of the airway device.
Presence/ severity of cough during prior to removal of airway device	Intraoperative	During 5 minutes prior to removal of airway device.; Cough will be graded as follows: None Mild = 1 episode of unsustained coughing (\< 5 s) Moderate = More than 1 episode of unsustained (\<5 s) coughing Severe = Sustained bout(s) of coughing (\>5 s) http://www.ncbi.nlm.nih.gov/pubmed/15385385 - (5. Minogue 2004)
Total opioids (morphine equivalents) administered intraoperatively	Intraoperative	From pre-induction until patient hand-off to post-anesthesia care unit team. Total intraoperative narcotics will be converted to morphine equivalents.
Time to successful ventilation via ETT	Intraoperative	From administration of induction medication until ETT placement confirmed via capnography.
Success rate of ventilation with LMA after extubation of trachea	Intraoperative	After deflation of the pneumoperitoneum, the ETT will be removed and ventilation will be continued through the LMA.; Success will be graded as follows: 1. Adequate ventilation via LMA without need for adjustment.; 2. Adequate ventilation via LMA after adjustment of LMA.; 3. Inadequate ventilation via LMA. Unable to successfully re-seat LMA and need to re-intubate.
LMA cuff pressures when inflated to seal	Intraoperative	After placement of LMA and LMA cuff inflated to seal. Pressure in the cuff will be measured and then deflated to pressures of 50-60 cmH20.
Presence of sore throat.	Up to 1 week	Postoperative day 3-5. A phone call will be made to determine the number of participants with sore throat (subjectively rated as none, mild, or severe).
Presence/ severity of cough during after removal of airway device	Intraoperative	During 5 minutes after removal of airway device.; Cough will be graded as follows: None Mild = 1 episode of unsustained coughing (\< 5 s) Moderate = More than 1 episode of unsustained (\<5 s) coughing Severe = Sustained bout(s) of coughing (\>5 s) http://www.ncbi.nlm.nih.gov/pubmed/15385385 - (5. Minogue 2004)
LMA cuff pressures prior to removal of ETT.	Intraoperative	After deflation of the pneumoperitoneum. Pressure in the cuff will be measured and then deflated to pressures of 50-60 cmH20.
Presence of oropharyngeal sensory or motor nerve palsy.	Up to 1 week	Postoperative day 3-5. A phone call will be made to determine the number of participants with the presence of any oropharyngeal numbness / paresthesias, hoarseness (recurrent laryngeal n. - Lehnert, 2008), dysphagia/ dysarthria (hypoglossal n. - Takahoko, 2014 \& Shah, 2015), decreased sensation and sense of taste (lingual n. - El Toukhy, 2012) that could be indicative of a neuropraxia versus nerve palsy.

Trial Locations

Locations (1)

Penn State Health - Hershey Medical Center; 🇺🇸 Hershey, Pennsylvania, United States