Airway and Sedation

[pbruss]

Sometimes i get emails from EM Lyceum for ER related posts. See below for one i just put up for 

Questions, Airway and Sedation 2014
1. Do you reach for video laryngoscopy or direct laryngoscopy first for intubations?
2. Do you use cricoid pressure during induction and paralysis?

3. How long do you keep patients NPO prior to procedural sedation?
4. When using ketamine for procedural sedation do you pretreat with benzodiazepines or anticholinergics?


1. I opt for DL first but always have VL ready. I have read multiple studies that show evidence for VL as superior but not all of them are done on patients in the ED. See 5 article below for further reading. These are ED patients only and I excluded any company sponsored trial. In my opinion the bugie with DL is the best combination for difficult airway.



1. Tracheal intubation in the emergency department: a comparison of GlideScope® video laryngoscopy to direct laryngoscopy in 822 intubations.

Sakles JC1, Mosier JM, Chiu S, Keim SM.

Author information

Abstract

BACKGROUND:

Video laryngoscopy has, in recent years, become more available to emergency physicians. However, little research has been conducted to compare their success to conventional direct laryngoscopy.

OBJECTIVES:

To compare the success rates of GlideScope(®) (Verathon Inc., Bothell, WA) videolaryngoscopy (GVL) with direct laryngoscopy (DL) for emergency department (ED) intubations.

METHODS:

This was a 24-month retrospective observational study of all patients intubated in a single academic ED with a level I trauma center. Structured data forms were completed after each intubation and entered into a continuous quality improvement database. All patients intubated in the ED with either the GlideScope(®) standard, Cobalt, Ranger, or traditional Macintosh or Miller laryngoscopes were included. All patients intubated before arrival were excluded. Primary analysis evaluated overall and first-attempt success rates, operator experience level, performance characteristics of GVL, complications, and reasons for failure.

RESULTS:

There were 943 patients intubated during the study period; 120 were excluded due to alternative management strategies. DL was used in 583 (62%) patients, and GVL in 360 (38%). GVL had higher first-attempt success (75%, p = 0.03); DL had a higher success rate when more than one attempt was required (57%, p = 0.003). The devices had statistically equivalent overall success rates. GVL had fewer esophageal intubations (n = 1) than DL (n = 18); p = 0.005.

CONCLUSION:

The two techniques performed equivalently overall, however, GVL had a higher overall success rate, and lower number of esophageal complications. In the setting of ED intubations, GVL offers an excellent option to maximize first-attempt success for airway management.

Published by Elsevier Inc.

PMID: 21689899 [PubMed - indexed for MEDLINE]



2. Acad Emerg Med. 2009 Sep;16(9):866-71. doi: 10.1111/j.1553-2712.2009.00492.x. Epub 2009 Aug 6.

A comparison of GlideScope video laryngoscopy versus direct laryngoscopy intubation in the emergency department.

Platts-Mills TF1, Campagne D, Chinnock B, Snowden B, Glickman LT, Hendey GW.

Author information

Abstract

OBJECTIVES:

The first-attempt success rate of intubation was compared using GlideScope video laryngoscopy and direct laryngoscopy in an emergency department (ED).

METHODS:

A prospective observational study was conducted of adult patients undergoing intubation in the ED of a Level 1 trauma center with an emergency medicine residency program. Patients were consecutively enrolled between August 2006 and February 2008. Data collected included indication for intubation, patient characteristics, device used, initial oxygen saturation, and resident postgraduate year. The primary outcome measure was success with first attempt. Secondary outcome measures included time to successful intubation, intubation failure, and lowest oxygen saturation levels. An attempt was defined as the introduction of the laryngoscope into the mouth. Failure was defined as an esophageal intubation, changing to a different device or physician, or inability to place the endotracheal tube after three attempts.

RESULTS:

A total of 280 patients were enrolled, of whom video laryngoscopy was used for the initial intubation attempt in 63 (22%) and direct laryngoscopy was used in 217 (78%). Reasons for intubation included altered mental status (64%), respiratory distress (47%), facial trauma (9%), and immobilization for imaging (9%). Overall, 233 (83%) intubations were successful on the first attempt, 26 (9%) failures occurred, and one patient received a cricothyrotomy. The first-attempt success rate was 51 of 63 (81%, 95% confidence interval [CI] = 70% to 89%) for video laryngoscopy versus 182 of 217 (84%, 95% CI = 79% to 88%) for direct laryngoscopy (p = 0.59). Median time to successful intubation was 42 seconds (range, 13 to 350 seconds) for video laryngoscopy versus 30 seconds (range, 11 to 600 seconds) for direct laryngoscopy (p < 0.01).

CONCLUSIONS:

Rates of successful intubation on first attempt were not significantly different between video and direct laryngoscopy. However, intubation using video laryngoscopy required significantly more time to complete.

(c) 2009 by the Society for Academic Emergency Medicine.

Comment in

The ethics of observation. [Acad Emerg Med. 2009]



3. Comparison of GlideScope Videolaryngoscopy to Direct Laryngoscopy for Intubation of a Pediatric Simulator by Novice Physicians

Joni E. Rabiner,1 Marc Auerbach,2 Jeffrey R. Avner,1 Dina Daswani,1 and Hnin Khine1

Emergency Medicine International

Volume 2013 (2013), Article ID 407547, 6 pages

Abstract



Objective. To compare novice clinicians’ performance using GlideScope videolaryngoscopy (GVL) to direct laryngoscopy (DL). Methods. This was a prospective, randomized crossover study. Incoming pediatric interns intubated pediatric simulators in four normal and difficult airway scenarios with GVL and DL. Primary outcomes included time to intubation and rate of successful intubation. Interns rated their satisfaction of the devices and chose the preferred device. Results. Twenty-five interns were included. In the normal airway scenario, there were no differences in mean time for intubation with GVL or DL (61.4 versus 67.4 seconds, ) or number of successful intubations (19 versus 18, ). In the difficult airway scenario, interns took longer to intubate with GVL than DL (87.7 versus 61.3 seconds, ), but there were no differences in successful intubations (14 versus 15, ). There was a trend towards higher satisfaction for GVL than DL (7.3 versus 6.4, ), and GVL was chosen as the preferred device by a majority of interns (17/25, 68%). Conclusions. For novice clinicians, GVL does not improve time to intubation or intubation success rates in a pediatric simulator model of normal and difficult airway scenarios. Still, these novice clinicians overall preferred GVL.



4. Comparison of video and direct laryngoscope for tracheal intubation in emergency settings: A meta-analysis



Yi-Kung Lee, Chien-Chih Chen, Tzong-Luen Wang, Kueiyu Joshua Lin, Yung-Cheng Sucorrespondenceemail

Received: March 13, 2012; Accepted: April 25, 2012; Published Online: June 29, 2012

Abstract

Background

Video laryngoscope has recently been introduced as an alternative for performing intubation; however, its validity in emergency settings has not been thoroughly evaluated. Therefore, we conducted a meta-analysis to assess its value compared with direct laryngoscope in emergency settings.



Purpose

We conducted a meta-analysis to assess its value compared with direct laryngoscope in emergency settings.



Methods

PubMed and EMBASE were searched for studies published through April 2011. Trials that reported data comparing video laryngoscope versus direct laryngoscope-assisted intubation in the emergency room or prehospital locations were included.



Results

Four trials reporting a total of 1305 participants were identified. During intubation, video laryngoscope failed to produce high rates of successful intubation (success rate: 0.70; 95% confidence interval [CI]: 0.49–1.01). Time to intubation was not different when using either video laryngoscope or direct laryngoscope (standardized mean difference: 0.19; 95% CI: -0.20—0.58). Furthermore, video laryngoscope seems to achieve a similar glottic view as direct laryngoscope (ratio of better glottic view: 0.96; 95% CI: 0.63–1.46).



Conclusion

In the reviewed studies, video laryngoscope was not superior to direct laryngoscope for performing intubation in emergency settings.



5.Learning Curves for Direct Laryngoscopy and GlideScope® Video Laryngoscopy in an Emergency Medicine Residency



Journal Issue:

Western Journal of Emergency Medicine, 15(7)



Author:

Sakles, John C., University of Arizona, Department of Emergency Medicine, Tucson, Arizona;

Mosier, Jarrod M., University of Arizona, Department of Emergency Medicine, Tucson, Arizona;

Patanwala, Asad E., University of Arizona College of Pharmacy, Department of Pharmacy Practice and Science, Tucson, Arizona;

Dicken, John M., University of Arizona College of Medicine, Tucson, Arizona



Introduction: Our objective is to evaluate the resident learning curves for direct laryngoscopy (DL) and GlideScope® video laryngoscopy (GVL) over the course of an emergency medicine (EM) residency training program.



Methods: This was an analysis of intubations performed in the emergency department (ED) by EM residents over a seven-year period from July 1, 2007 to June 30, 2014 at an academic ED with 70,000 annual visits. After EM residents perform an intubation in the ED they complete a continuous quality improvement (CQI) form. Data collected includes patient demographics, operator post- graduate year (PGY), difficult airway characteristics (DACs), method of intubation, device used for intubation and outcome of each attempt. We included in this analysis only adult intubations performed by EM residents using a DL or a standard reusable GVL. The primary outcome was first pass success, defined as a successful intubation with a single laryngoscope insertion. First pass success was evaluated for each PGY of training for DL and GVL. Logistic mixed-effects models were constructed for each device to determine the effect of PGY level on first pass success, after adjusting for important confounders.



Results: Over the seven-year period, the DL was used as the initial device on 1,035 patients and the GVL was used as the initial device on 578 patients by EM residents. When using the DL the first past success of PGY-1 residents was 69.9% (160/229; 95% CI 63.5%-75.7%), of PGY-2 residents was 71.7% (274/382; 95% CI 66.9%-76.2%), and of PGY-3 residents was 72.9% (309/424; 95% CI 68.4%-77.1%). When using the GVL the first pass success of PGY-1 residents was 74.4% (87/117; 95% CI 65.5%-82.0%), of PGY-2 residents was 83.6% (194/232; 95% CI 76.7%-87.7%), and of PGY-3 residents was 90.0% (206/229; 95% CI 85.3%-93.5%). In the mixed-effects model for DL, first pass success for PGY-2 and PGY-3 residents did not improve compared to PGY-1 residents (PGY-2 aOR 1.3, 95% CI 0.9-1.9; p-value 0.236) (PGY-3 aOR 1.5, 95% CI 1.0-2.2, p-value 0.067). However, in the model for GVL, first pass success for PGY-2 and PGY-3 residents improved compared to PGY-1 residents (PGY-2 aOR 2.1, 95% CI 1.1-3.8, p-value 0.021) (PGY-3 aOR 4.1, 95% CI 2.1-8.0, p<0.001).



Conclusion: Over the course of residency training there was no significant improvement in EM resident first pass success with the DL, but substantial improvement with the GVL. [West J Emerg Med. 2014;15(7):-0.]





2. I do not routinely use cricoid pressure. I do not find that it helps with my view and have not been convinced about its benefit based on research I have read.Coppy and paste the link below in your browser for a nice review.



file:///C:/Users/discharge/Downloads/annals-of-emergency-medicine-2007-ellis1.pdf





3. In the ER I have no control over when a patient last took PO and DO NOT let it affect my decision on procedural sedation. See below from ACEPs 2014 Clinical Policies.



CRITICAL QUESTIONS

1. In patients undergoing procedural sedation and

analgesia in the emergency department, does preprocedural

fasting demonstrate a reduction in the risk of emesis or

aspiration?

Recommendations

Level A recommendations. None specified.

Level B recommendations. Do not delay procedural sedation

in adults or pediatrics in the ED based on fasting time.

Preprocedural fasting for any duration has not demonstrated a

reduction in the risk of emesis or aspiration when administering

procedural sedation and analgesia.

Level C recommendations. None specified.

Key words/phrases for literature searches: conscious sedation,

sedation, procedural sedation, procedural analgesia, moderate

sedation, deep sedation, fasting, gastric emptying, complication,

aspiration, emesis, and variations and combinations of the key

words/phrases; years January 2004 to May 2012.

Emesis or aspiration during procedural sedation in the ED

is rare.21 For healthy patients undergoing elective sedation/

analgesia, other professional society guidelines outside of

emergency medicine recommend a 2-hour fasting time for

clear liquids, 4-hour fasting time for breast milk, and a 6-hour

fasting time for solids. However, the guidelines are based on the

extrapolation of general anesthesia cases in the operating room,

in which airway manipulation during intubation and extubation

increases the aspiration risk. Thus, it is not clear whether

applying these guidelines to ED procedural sedation and

analgesia reduces the risk of emesis or aspiration. Moreover, even

within the framework of these guidelines, emergent sedations

are an exclusion from fasting requirements.22

As a result, guidelines for elective procedures in the operating

room (eg, nothing by mouth, preoperative fasting guidelines) are

not directly applicable in the ED. In addition, multiple other

practice guidelines and systematic reviews do not find evidence to

support a specific fasting period before ED procedural sedation.

Two systematic reviews23,24 and 2 practice advisories11,25

acknowledge the lack of evidence to support specific preprocedural

fasting requirements.

Four Class II trials with pediatric patients26-29 and 1 Class II

trial with adult and pediatric patients30 examined the effect

of fasting time (0 to >8 hours) on emesis and aspiration during

ED procedural sedation. None of these studies demonstrated a

significant difference in rates of emesis or aspiration when

comparing fasting times. In addition, no serious adverse events

caused by emesis or aspiration were found. The current evidence

does not support the rationale put forth in the non–emergency

medicine guidelines that adhering to a minimum fasting time

reduces adverse events in ED procedural sedation.

Roback et al26 performed a single-center study of 1,555

pediatric patients undergoing procedural sedation with ketamine,

midazolam, midazolam/ketamine, midazolam/fentanyl, and a

small number of other agents. The study found no relationship

between fasting time and the proportion of patients with adverse

events. Respiratory adverse events were defined as apnea,

laryngospasm, pulse oximetry less than 90% on room air at the

elevation of the study site (5,280 feet), and aspiration. Any

adverse events (vomiting or adverse respiratory event) occurred in

12.0% in the 0- to 2-hour group, 16.4% in the 2- to 4-hour group, 14.0% in the 4- to 6-hour group, 14.6% in the 6- to

8-hour group, and 14.5% in the greater than 8 hours group.

Using the group that fasted 0 to 2 hours as the reference group,

the difference in proportion of any adverse events was 4.3% in

the 2- to 4-hour group, 2.0% in the 4- to 6-hour group, 2.6% in

the 6- to 8-hour group, and 2.5% in the greater than 8 hours

group. There were no aspiration events documented in the entire

cohort of 1,555 patients.

Treston27 included 257 pediatric patients undergoing

procedural sedation with ketamine. In this study also, fasting

time did not correlate with the incidence of emesis, which

occurred in 6.6% in the 1 hour or less fasting group, 14.0% in

the 1- to 2-hour fasting group, and 15.7% in the 3 hours or

greater group. Using the group that fasted 1 hour or less as the

reference group, the difference in proportion of vomiting in the

1- to 2-hour fasting group was 7.3%; in the 3-hour or greater

group, 9.1%. No clinically detectable aspiration occurred, and no

airway maneuvers or suctioning was required.

Babl et al28conducted a study of 218 consecutive pediatric

patients undergoing procedural sedation with nitrous oxide.

Fasting guidelines for solids were not met by 71.1% of the patients.

There was no statistical difference in incidence of emesis, which

occurred in 7.1% of patients who did not meet fasting guidelines

for solids compared with 6.3% in those who met guidelines.

Serious adverse events were defined as pulse oximetry less than

95%, apnea, stridor, airway misalignment requiring repositioning,

laryngospasm, bronchospasm, cardiovascular instability,

pulmonary aspiration, unplanned hospital admission,

endotracheal intubation, permanent neurologic injury, or death.

There were no serious adverse events observed.

McKee et al29 examined 471 pediatric patients undergoing

procedural sedation with ketamine, in which presedation oral

analgesic administration was recorded. In this Class II study,

42.7% of patients received oral analgesics within 6 hours of

sedation. Emesis occurred in 5.0% of patients who received oral

analgesics compared with 2.6% of patients who did not receive

oral analgesics. Additional adverse events recorded were hypoxia

(desaturation requiring supplemental oxygen), hypoventilation,

laryngospasm, apnea, bradycardia, or tachycardia. Total adverse

events were similar for patients receiving oral analgesia (5.0%)

and those not receiving oral analgesia (5.6%). The authors did

not report episodes of intubation, aspiration, unplanned

admission, or death, although these were not explicit outcome

measures in the study.

Bell et al30 followed 400 adult and pediatric patients

undergoing procedural sedation with propofol. The authors

found that 70.5% of those enrolled did not meet American

Society of Anesthesiologists (ASA) fasting guidelines for solids or

liquids. They identified no significant difference between the

groups meeting and not meeting fasting guidelines with respect

to adverse events that included emesis and respiratory

interventions. Emesis occurred in 0.4% of patients who did not

meet fasting guidelines compared with 0.8% of those who met

guidelines. The combined endpoint of respiratory adverse events

was defined as transient apnea, pulse oximetry less than 95%,

respiratory rate less than 12 breaths/min, elevated end-tidal

carbon dioxide (ETCO2) greater than 10 mm Hg, vomiting, and

aspiration. Respiratory adverse events occurred in 22.4% of

patients who did not meet fasting guidelines compared with

19.5% of those who met guidelines. With only 2 episodes of

emesis and no aspiration events, this combined endpoint was

driven primarily by interventions less likely to be related to

fasting, such as respiratory depression and desaturation. The

combined endpoint of respiratory interventions was defined as

basic airway maneuvers, Guedel/bag-valve-mask, and suctioning.

Respiratory interventions occurred in 33.3% of patients who did

not meet fasting guidelines compared with 24.6% of those who

met guidelines. With only 3 interventions requiring suctioning,

this combined endpoint is predominantly weighted by basic

airway and bag-valve-mask interventions, which are less likely to

be affected by fasting. There were no aspiration events,

intubations, laryngeal mask airway insertions, or unplanned

admissions related to sedation or recovery in either group.

Future research should focus on the identification of a

potential high-risk population that might benefit from a fasting

time or a sedation agent with better efficacy after patient fasting if

such a delay is to be relevant in any ED procedural sedations. In

addition, research into the harms of enforcing fasting periods

would bring balance to the literature. Concerns about procedural

difficulty, ED resource utilization, and pediatric hypoglycemia

related to enforced fasting periods for ED procedural sedation

have not been evaluated.



4. I DO NOT pretreat with benzodiazepines or anticholinergics when using ketamine. See below from ACEPs 2011 Clinical Practice Guidelines.



Coadministered Anticholinergics

Traditionally the prophylactic coadministration of an

anticholinergic (ie, atropine or glycopyrrolate) has been routinely

recommended, with the intent of mitigating oral secretions and

thus presumably airway adverse events.1,12,15,16 However, large

case series of patients have been safely treated without this

adjunct.35,80 The large meta-analysis found anticholinergics to

be associated with significantly more airway and respiratory

adverse events and significantly less vomiting; however, both

were at magnitudes of doubtful clinical importance.2,3,81 Given

this lack of tangible benefit or harm, the literature is not

supportive of anticholinergic prophylaxis. Instead, these drugs

could be reserved for the treatment of unusual occurrences of

clinically important hypersalivation or for patients with an

impaired ability to mobilize secretions.

Coadministered Benzodiazepines

As with anticholinergics, the prophylactic coadministration of

benzodiazepines has been traditionally recommended with the

intent of preventing or reducing recovery reactions.4,12,15,16 A

single controlled trial in ED adults found that midazolam

pretreatment (0.03 mg/kg IV) significantly reduced the

incidence of recovery agitation by 17% (number needed to

benefit6).28 Unfortunately, this study failed to describe the

nature or severity of these reactions, and so it remains unclear

how many of the events were clinically important and how

many were minor and transient. Nevertheless, midazolam

prophylaxis appears a reasonable but nonmandatory option in

adults.

In children, however, 2 controlled trials82,83 and a large

meta-analysis3 have failed to note even a trend toward benefit

from such prophylaxis. Children have far fewer recovery

reactions than adults, and thus the routine pretreatment of such

patients is not supported by the evidence.

When unpleasant ketamine-associated recovery reactions do

rarely occur, they can be rapidly and reliably diminished with

titrated benzodiazepines.4,12,16,19,20,36,71,83,84