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  1. Nremt Aemt Level

  3. Airway Adjuncts and Supraglottic Airway Devices

NREMT AEMT LEVEL • AIRWAY, RESPIRATION & VENTILATION

Airway Adjuncts and Supraglottic Airway Devices

Mastering the tools and techniques that maintain patent airways when basic maneuvers alone are insufficient.

SECTION 1

Historical Context & Motivation

Airway management has been the cornerstone of emergency medicine since practitioners first recognized that respiratory failure is among the most rapidly fatal conditions a patient can experience. Before the development of modern airway devices, clinicians relied almost exclusively on manual maneuvers such as the head-tilt/chin-lift and jaw thrust, along with crude improvised tools, to maintain an open passage for air to reach the lungs. The mortality rates associated with airway obstruction in unconscious patients were staggeringly high, particularly in the prehospital setting where definitive surgical airways or endotracheal intubation were impractical. This gap between basic manual techniques and advanced surgical interventions created a pressing clinical need for intermediate devices—tools that could be placed quickly by trained providers to secure the airway without requiring direct visualization of the vocal cords. The development of airway adjuncts and supraglottic airway devices (SGAs) represents one of the most significant advances in prehospital airway management over the past century.

1888
First Oropharyngeal Airway Concept
Early prototypes of oral airways emerged as surgeons sought devices to prevent tongue obstruction during ether anesthesia. These rudimentary designs laid the groundwork for modern oropharyngeal airways.
1930s
Guedel Oropharyngeal Airway
Arthur Guedel standardized the oropharyngeal airway (OPA) design with a flanged, curved plastic tube that displaced the tongue anteriorly. This became the template for the modern OPA still used in EMS today.
1968
Nasopharyngeal Airway Adoption
The nasopharyngeal airway (NPA) gained widespread acceptance in emergency medicine as an alternative for patients with intact gag reflexes. Its soft, flexible design allowed insertion through the nostril to bypass upper airway obstruction.
1988
Laryngeal Mask Airway (LMA) Introduced
Dr. Archie Brain introduced the laryngeal mask airway (LMA), the first widely adopted supraglottic device. It revolutionized airway management by providing a seal around the glottic opening without requiring laryngoscopy.
2000s–Present
Modern SGAs in EMS Protocols
Devices such as the King LT, i-gel, and second-generation LMAs became standard in prehospital protocols. They offer rapid insertion, improved seals, and gastric access ports, bridging the gap between basic and advanced airway management at the AEMT scope.

The central question that drove the evolution of these devices remains the same one AEMT providers face on every call: how can a rescuer rapidly secure a compromised airway in a patient who cannot protect it, particularly when endotracheal intubation is not within the provider's scope or when conditions make it impractical? Understanding the history and rationale behind airway adjuncts and SGAs equips you to select the right device for each clinical scenario with confidence.

SECTION 2

Core Principles & Definitions

Before examining individual devices in detail, it is essential to establish the foundational principles that govern airway adjunct selection and use. Every device discussed in this lesson operates on the same fundamental premise: the upper airway of an unconscious or semiconscious patient is prone to obstruction—most commonly by the tongue falling posteriorly against the pharyngeal wall—and a mechanical device can physically prevent that obstruction or bypass it altogether. The distinction between basic airway adjuncts (OPA and NPA) and supraglottic airway devices lies in their placement relative to the glottis and the degree of airway protection they offer.

1

Patency Is Priority

An airway that is not patent cannot deliver oxygen. Every intervention in airway management begins with ensuring an open passage from the nose or mouth to the trachea. Devices exist on a continuum from simple adjuncts to definitive airways.
2

Anatomical Positioning

Basic adjuncts sit in the oropharynx or nasopharynx to displace the tongue. Supraglottic devices seat over or around the glottic opening without entering the trachea, creating a seal that permits positive-pressure ventilation.
3

Gag Reflex Assessment

The presence or absence of a gag reflex is the critical decision point for OPA use. A patient who gags on an OPA is at risk for vomiting and aspiration. NPAs and SGAs offer alternatives in patients with some degree of protective reflexes.
4

Size Selection Matters

Every airway device must be properly sized for the patient. An OPA too small will not displace the tongue; one too large will obstruct the airway. SGAs sized incorrectly will fail to seal or may cause tissue trauma.
5

Aspiration Risk Awareness

No basic adjunct or first-generation SGA provides definitive aspiration protection. Second-generation SGAs with gastric channels reduce but do not eliminate this risk. Continuous monitoring for regurgitation is mandatory.
✦ KEY TAKEAWAY
Think of the airway as a collapsible tent. Manual maneuvers like the jaw thrust are your hands holding the fabric up—effective but unsustainable. An OPA or NPA is a tent pole that keeps the structure open passively. A supraglottic airway is a sealed canopy over the opening, allowing you to push air in under pressure without it escaping out the sides. Each step up the ladder provides greater airway security but demands greater skill and carries device-specific risks.
SECTION 3

Visual Explanation — Airway Adjunct Anatomy & Placement

Sagittal Cross-Section: OPA vs NPA PlacementTracheaNasopharynxOropharynxHypopharynxTongueEpiglottisOPA PlacementFlangeBodyDistal TipSizing: Corner of mouth toearlobe or angle of jawNPA PlacementFlangeShaftBevel TipSizing: Tip of nose to earlobe
Left: Sagittal view of the upper airway showing the nasopharynx, oropharynx, hypopharynx, tongue, epiglottis, and trachea. Right top: OPA structure with flange, body, and distal tip, sized from corner of mouth to earlobe. Right bottom: NPA structure with flanged end, shaft, and beveled tip, sized from tip of nose to earlobe.

The diagram above illustrates the critical anatomical relationships that govern adjunct placement. On the left, you can see how the tongue occupies a substantial volume of the oropharynx; in an unconscious patient, loss of muscle tone allows it to fall posteriorly and occlude the airway at the level of the hypopharynx. The OPA follows the natural curvature of the palate, with its distal tip resting in the posterior oropharynx to physically displace the tongue forward. The NPA takes a different route entirely, passing through the nostril along the floor of the nasal cavity and into the nasopharynx, bypassing the oral cavity altogether. Note the sizing landmarks: an improperly sized device not only fails to serve its purpose but can actively harm the patient through trauma or further obstruction.

💡 Clinical Pearl
When inserting an OPA in an adult, the standard technique is to insert it with the tip pointing toward the hard palate (upside down) and rotate it 180° as it passes the tongue. In pediatric patients, insert the OPA right-side up using a tongue depressor to avoid traumatizing the soft palate. Never force either device—if you encounter resistance, reassess sizing and patient anatomy.
SECTION 4

Mechanism of Action — How Supraglottic Devices Work

Supraglottic airway devices occupy an intermediate position on the airway management hierarchy, sitting above the level of the glottis (hence the name "supraglottic") to create a functional seal that permits positive-pressure ventilation without entering the trachea. Unlike an endotracheal tube, which passes through the vocal cords and directly seals the trachea, an SGA forms its seal in the hypopharynx surrounding the laryngeal inlet. This distinction is fundamental to understanding both the advantages and limitations of these devices in the prehospital setting.

Seal Mechanisms

SGAs achieve their airway seal through one of two primary mechanisms. Inflatable-cuff devices (such as the King LT and classic LMA) use an air-filled cuff that, once inflated, conforms to the tissues of the hypopharynx and creates a low-pressure seal around the glottic opening. The King LT (Laryngeal Tube) employs a dual-cuff design: a larger proximal cuff that occludes the oropharynx and a smaller distal cuff that seats in the upper esophagus, with ventilation ports positioned between the two cuffs directly over the glottic opening. Non-inflatable devices (such as the i-gel) use a pre-formed thermoplastic elastomer cuff that conforms to the perilaryngeal anatomy through body-heat softening, eliminating the need for cuff inflation and reducing insertion time.

Ventilation Through an SGA

Once seated, the SGA's lumen provides a direct channel from the 15-mm standard connector (which attaches to a bag-valve-mask or ventilator circuit) through the device to the ventilation aperture at the distal end. When positive pressure is applied, air flows through this channel and enters the trachea through the glottic opening. The seal around the glottis prevents air from escaping into the esophagus or back through the oropharynx, though the quality of this seal is quantified by the oropharyngeal leak pressure (OLP). Most modern SGAs achieve an OLP of 20–30 cmH₂O, which is sufficient for most clinical ventilation needs but substantially lower than the seal provided by a properly placed endotracheal tube.

OROPHARYNGEAL LEAK PRESSURE
OLP = Pressure at which audible air leak occurs around the SGA seal (cmH₂O)
OLP is measured by closing the expiratory valve of the breathing circuit and allowing fresh gas to flow at a fixed rate (typically 3 L/min) while monitoring the airway pressure manometer. The pressure at which an audible leak is detected at the mouth or a plateau is reached represents the OLP. An OLP ≥ 20 cmH2O is generally considered adequate for positive-pressure ventilation.

Second-Generation SGAs and Gastric Access

A major advancement in SGA design is the incorporation of a gastric drainage channel. Second-generation SGAs such as the LMA Supreme, i-gel, and King LTS-D include a separate port that aligns with the esophageal opening, allowing passage of a gastric tube to decompress the stomach. This is clinically significant because gastric distension from bag-valve-mask ventilation increases the risk of regurgitation and aspiration. By providing a channel for passive or active gastric drainage, second-generation devices substantially mitigate one of the chief hazards of supraglottic ventilation.

✦ KEY TAKEAWAY
If an endotracheal tube is like a sealed pipe inserted directly into a tank, an SGA is like a funnel pressed tightly over the tank's opening. Both direct flow into the tank, but the funnel's seal is external and less absolute—it works well under normal pressures but may leak if pressures climb too high. Second-generation SGAs add a drain hose to that funnel to prevent overflow (gastric contents) from backing up into the system.
SECTION 5

Device Classification & Selection Guide

AEMT providers must be familiar with a range of airway devices, understanding when each is indicated, contraindicated, and how they relate to one another on the airway management continuum. The following classification organizes devices by their anatomical positioning and functional capability, followed by a detailed comparison table that serves as a rapid clinical reference.

Airway Management Hierarchy & Device ClassificationBASIC MANUAL MANEUVERSHead-tilt/Chin-lift • Jaw Thrust • SuctioningOPAOropharyngeal Airway• No gag reflex requiredNPANasopharyngeal Airway• Tolerated with gag reflexBASIC ADJUNCTSSUPRAGLOTTIC AIRWAY DEVICES (SGAs) — AEMT SCOPEKing LT / LTS-DDual-cuff designSingle lumenLTS-D: gastric porti-gelNon-inflatable cuffThermoplastic elastomerBuilt-in gastric channelLMA (Classic/Supreme)Perilaryngeal maskInflatable cuffSupreme: gastric portCombitubeDual-lumenEsophageal/TrachealLegacy deviceENDOTRACHEAL INTUBATION (Paramedic Scope)Definitive airway • Requires direct/video laryngoscopyIncreasing Airway Security →
The airway management hierarchy from basic manual maneuvers (top) through basic adjuncts (OPA and NPA), supraglottic airway devices within AEMT scope (center), to endotracheal intubation at the paramedic level (bottom, dashed border). The vertical axis represents increasing airway security and invasiveness.
Comparison of Airway Adjuncts and Supraglottic Airway Devices Commonly Used at the AEMT Level
DeviceTypeCuffGastric AccessKey IndicationKey Contraindication
OPABasic adjunctNoneNoUnconscious patient, absent gag reflexIntact gag reflex
NPABasic adjunctNoneNoSemi-conscious, gag present, trismusSevere midface trauma (relative)
King LTSGA – 1st genDual inflatableNoCardiac arrest, failed BVMIntact gag, caustic ingestion, known esophageal disease
King LTS-DSGA – 2nd genDual inflatableYesSame as King LT with gastric decompression needSame as King LT
i-gelSGA – 2nd genNon-inflatable (gel)YesCardiac arrest, rapid insertion neededIntact gag, limited mouth opening (<2 cm)
LMA ClassicSGA – 1st genInflatableNoAlternative airway when ETI unavailableIntact gag, high aspiration risk
LMA SupremeSGA – 2nd genInflatableYesSame as LMA Classic with improved sealSame as LMA Classic

Device selection in the field is governed by patient presentation, available equipment, and local protocols. In general, the AEMT should first attempt basic manual maneuvers combined with suctioning, escalate to an OPA or NPA as appropriate, and if ventilation remains inadequate or the patient requires ongoing positive-pressure ventilation, advance to an SGA. The specific SGA chosen will depend on what is stocked on the unit and what the provider has been trained and authorized to use. Many EMS systems have standardized on a single SGA platform—often the King LTS-D or i-gel—to simplify training and reduce decision fatigue under stress.

SECTION 6

Worked Example — SGA Insertion Scenario

Consider the following clinical scenario: You are dispatched to a 58-year-old male found unresponsive in his home by family members. He is supine on the floor, breathing with sonorous (snoring) respirations at a rate of 6 breaths per minute. He is unresponsive to painful stimuli. No gag reflex is present. Your partner is performing bag-valve-mask ventilation but is reporting significant difficulty achieving adequate chest rise despite a jaw thrust and proper mask seal. Your service carries King LTS-D devices. Walk through the clinical decision-making and insertion process step by step.

King LTS-D Insertion: Step-by-Step Clinical Approach

Step 1 — Assess the Need for an Advanced Airway

The patient is unresponsive with no gag reflex, has a respiratory rate of 6 (bradypneic, requiring assisted ventilation), and your partner is unable to achieve adequate ventilation with BVM alone. This meets the criteria for SGA insertion: failed BVM ventilation in an unconscious patient without protective airway reflexes.
Decision: Proceed with King LTS-D insertion.

Step 2 — Select the Appropriate Size

King LT devices are sized by patient height. For an adult male of average height (approximately 5'6" to 6'0"), a size 4 (yellow connector) is appropriate for patients 5'0"–6'0", and a size 5 (purple connector) for patients over 6'0". Estimate the patient's height or use available information. In this case, family reports he is 5'10".
Size selected: King LTS-D Size 4 (yellow)

Step 3 — Prepare the Device

Remove the King LTS-D from its packaging. Test the cuff integrity by inflating it with the maximum recommended volume (size 4: 80 mL), inspect for leaks, then fully deflate the cuff. Apply water-soluble lubricant generously to the distal tip and posterior surface of the device. Ensure suction is immediately available at the patient's side.
Device tested, lubricated, and ready. Suction available.

Step 4 — Position the Patient and Insert the Device

Place the patient in the sniffing position (neck flexed, head extended) unless cervical spine precautions are indicated. Pre-oxygenate with BVM at 100% O₂ for 30 seconds if possible. Hold the King LTS-D at the connector, open the patient's mouth with a cross-finger technique, and insert the device along the midline of the tongue with the tip directed posteriorly along the hard palate. Advance the device until the base of the connector aligns with the patient's teeth or gums. Do not force the device.
Device inserted to appropriate depth (base of connector at teeth).

Step 5 — Inflate the Cuff and Confirm Placement

Using the provided syringe, inflate the cuff with 60–80 mL of air (start with the minimum recommended volume for the size). Attach the BVM to the 15-mm connector and ventilate. Confirm placement by: (1) observing bilateral chest rise, (2) auscultating bilateral lung sounds and absence of epigastric sounds, (3) monitoring waveform capnography for consistent ETCO₂ waveform, and (4) noting improvement in SpO₂. If the device appears to back out slightly during inflation, this is normal—allow it to seat itself. If ventilation is inadequate, withdraw the device slightly, add more air to the cuff, or remove and re-attempt with a different size.
Bilateral chest rise confirmed, ETCO₂ 38 mmHg with consistent waveform, SpO₂ rising. Placement successful.

Step 6 — Secure and Monitor

Secure the device with a commercial tube holder or tape. Insert a gastric tube through the gastric port (the "D" channel in the LTS-D) to decompress the stomach. Continue assisted ventilation at 10–12 breaths per minute, monitoring ETCO₂ continuously. Reassess lung sounds after every patient movement or position change. Document the device size, insertion depth, cuff volume, and confirmation findings.
Device secured. Gastric tube placed. Ongoing monitoring established.
SECTION 7

Strengths, Limitations & Device Comparisons

No single airway device is perfect for every clinical scenario. Understanding the relative strengths and limitations of each option allows the AEMT to make informed, rapid decisions. The table below provides a side-by-side comparison of the three most commonly encountered SGAs in prehospital practice, evaluated across the parameters most relevant to field use.

Side-by-Side Comparison of Common Prehospital SGAs
ParameterKing LTS-Di-gelLMA Supreme
Insertion Time~15–25 seconds~5–15 seconds (no cuff inflation)~15–20 seconds
Cuff Inflation RequiredYes (single pilot balloon)NoYes
Oropharyngeal Leak Pressure~25 cmH₂O~24–28 cmH₂O~27–32 cmH₂O
Gastric AccessYes (LTS-D variant)Yes (built-in)Yes
ReusableSingle-useSingle-useSingle-use
First-Pass Success Rate~85–92%~90–95%~88–94%
Sizing MethodPatient heightPatient weightPatient weight
Key AdvantageEsophageal occlusion by distal cuffFastest insertion, no cuff managementHighest oropharyngeal leak pressure
Key LimitationCuff pressure monitoring neededMay provide lower seal in some patientsRequires precise sizing for optimal seal
✦ KEY TAKEAWAY
Think of SGA selection like choosing a wrench for a bolt: you could use an adjustable wrench (inflatable-cuff SGA like the King LT—versatile but requires adjustment), a precision socket wrench (the LMA Supreme—tight fit, excellent seal, but must be exactly the right size), or a self-adjusting wrench (the i-gel—conforms to the anatomy automatically, fastest to deploy). All three will turn the bolt, but the best choice depends on the job conditions. In a cardiac arrest with time pressure, speed favors the i-gel; when gastric decompression and esophageal occlusion are priorities, the King LTS-D excels.
SECTION 8

Connection to Advanced Airway Management

While SGAs represent a significant advancement over basic adjuncts, they remain a bridge to more definitive airway management in many clinical scenarios. Understanding how SGAs fit within the broader airway management continuum prepares the AEMT to collaborate effectively with paramedic and physician partners, and also establishes a conceptual foundation for providers who advance to the paramedic level. The table below contrasts SGAs with endotracheal intubation (ETI), the traditional gold standard for definitive airway management in the prehospital setting.

SGA vs. Endotracheal Intubation Comparison
FeatureSupraglottic Airway (SGA)Endotracheal Intubation (ETI)
Placement relative to glottisAbove (supraglottic)Through the glottis (infraglottic/transglottic)
Visualization requiredNo (blind insertion)Yes (direct or video laryngoscopy)
Aspiration protectionPartial (2nd gen with gastric port improves)Near-complete (inflated cuff seals trachea)
Skill level requiredAEMT (moderate training)Paramedic (extensive training + ongoing proficiency)
Insertion success rate (prehospital)85–95% first-pass70–90% first-pass (operator dependent)
Ventilation pressures toleratedUp to ~25–30 cmH₂O (OLP-limited)No practical upper limit in normal use
Considered definitive airwayNoYes

Recent literature, including landmark studies such as the AIRWAYS-2 and PART trials, has challenged the assumption that ETI always produces superior outcomes compared to SGAs in prehospital cardiac arrest. In several large randomized controlled trials, SGAs demonstrated non-inferior or even superior neurological outcomes compared to ETI when performed by paramedics in the field. These findings have led many EMS systems to adopt SGAs as the primary advanced airway in cardiac arrest, reserving ETI for specific indications or post-return-of-spontaneous-circulation (ROSC) scenarios. For the AEMT, the practical implication is clear: mastery of SGA placement is not merely a stepping stone to intubation—it is a clinically valuable skill in its own right that may be the most important airway intervention you perform in cardiac arrest management.

🔭 Looking Ahead
As you progress through your career, you may encounter video laryngoscopy-assisted SGA placement, SGA-guided intubation (using an SGA as a conduit for an endotracheal tube), and advanced rescue airway algorithms. The foundational knowledge of supraglottic anatomy, device mechanics, and confirmation techniques you build now will underpin every future airway skill.
SECTION 9

Practice Problems

PROBLEM 1 — CONCEPTUAL
Explain the fundamental difference between a basic airway adjunct (OPA or NPA) and a supraglottic airway device in terms of their anatomical position and functional capability. Why can a provider deliver positive-pressure ventilation more effectively through an SGA than through an OPA alone?
PROBLEM 2 — BASIC CALCULATION
You are preparing to insert a King LTS-D on a patient who is 5'8" tall. According to standard King LT sizing guidelines: Size 3 (green) = 4'0"–5'0", Size 4 (yellow) = 5'0"–6'0", Size 5 (purple) = >6'0". What size do you select, and what is the recommended initial cuff inflation volume for that size (Size 3 = 45–60 mL, Size 4 = 60–80 mL, Size 5 = 70–90 mL)?
PROBLEM 3 — INTERMEDIATE
You arrive on scene to find a 34-year-old female who was in a motor vehicle collision. She has significant facial trauma with blood in the oral cavity, a GCS of 7 (E1V2M4), and an intact but weak gag reflex. She is breathing at 8 breaths per minute with poor tidal volume. You attempt BVM ventilation but air is leaking around the mask due to facial injuries. Describe your airway management plan, including which devices you would use and in what order, and justify each decision.
PROBLEM 4 — APPLIED
During a cardiac arrest resuscitation, you successfully place a King LTS-D and confirm placement with waveform capnography showing an ETCO₂ of 18 mmHg. After 5 minutes of CPR, you notice the ETCO₂ has dropped to 5 mmHg, chest rise has become asymmetric, and you hear diminished breath sounds on the right side. What are the most likely causes of this change, and what is your systematic troubleshooting approach?
PROBLEM 5 — CRITICAL THINKING
Recent large-scale trials (AIRWAYS-2 and PART) compared supraglottic airways with endotracheal intubation in prehospital cardiac arrest and found comparable or superior outcomes with SGAs. Given these findings, critically evaluate whether SGAs should replace ETI as the default advanced airway in all prehospital settings. Consider provider training, patient population variability, and system-level factors in your analysis.
SUMMARY

Summary — Airway Adjuncts and Supraglottic Airway Devices

Airway management at the AEMT level relies on a progressive hierarchy of interventions. Basic manual maneuvers such as the head-tilt/chin-lift and jaw thrust form the foundation, supplemented by oropharyngeal airways (OPAs) for unconscious patients without gag reflexes and nasopharyngeal airways (NPAs) for patients who retain some protective reflexes. When basic adjuncts and BVM ventilation fail to achieve adequate oxygenation and ventilation, supraglottic airway devices provide an intermediate-level solution that creates a functional seal around the glottic opening, enabling reliable positive-pressure ventilation without requiring visualization of the vocal cords.

Key SGAs within the AEMT scope include the King LT/LTS-D (dual-cuff design, sized by height), the i-gel (non-inflatable thermoplastic cuff, fastest insertion, sized by weight), and the LMA Supreme (inflatable perilaryngeal mask, highest leak pressures). Second-generation devices incorporate gastric drainage channels to reduce aspiration risk. Proper sizing, technique, and waveform capnography confirmation are essential for successful SGA use. Contemporary evidence supports SGAs as non-inferior to endotracheal intubation in prehospital cardiac arrest, making SGA proficiency a core competency for every AEMT.

Varsity Tutors • NREMT AEMT Level • Airway Adjuncts and Supraglottic Airway Devices