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Advanced airway management is the subset of airway management that involves advanced training, skill, and invasiveness. It encompasses various techniques performed to create an open or patent airway – a clear path between a patient's lungs and the outside world.
This is accomplished by clearing or preventing obstructions of airways. There are multiple causes of potential airway obstructions, including the patient's own tongue or other anatomical components of the airway, foreign bodies, excessive amounts of blood and body fluids, or aspiration of food particles.
Unlike basic airway management, such as the head tilt/chin lift or jaw-thrust maneuver, advanced airway management relies on the use of medical equipment and advanced training. Certain invasive airway management techniques can be performed "blind" or with visualization of the glottis. Visualization of the glottis can be accomplished either directly by using a laryngoscope blade or by utilizing newer video technology options.
In roughly increasing order of invasiveness are the use of supraglottic devices such as oropharyngeal (OPA), nasopharyngeal (NPA), and laryngeal mask airways (LMA). Laryngeal mask airways can even be used to deliver general anesthesia. These are followed by infraglottic techniques, such as tracheal intubation and finally surgical techniques.
Advanced airway management is a key component in cardiopulmonary resuscitation, anesthesia, emergency medicine, and intensive care medicine. The "A" in the ABC initialism mnemonic for dealing with critically ill patients stands for airway management. Many airways are straightforward to manage. However, some can be challenging. Such difficulties can be predicted to some extent; a recent Cochrane systematic review examines the sensitivity and specificity of the various bedside tests commonly used to predict difficulty in airway management.[1]
Pharnygeal airways
Pharyngeal airway devices are used in spontaneously breathing patients to move the tongue away from the back of the throat to restore airway patency.[2][3] Obstruction of the upper airway caused by the tongue most commonly occurs during decreased levels of consciousness.[2][3][4] Pharyngeal airway devices include oropharyngeal airways (OPAs) and nasopharyngeal airways (NPAs). These devices are the simplest artificial airways.[3][4]
Oropharyngeal airways
An oropharyngeal airway (OPA) is a rigid tube that is inserted into the mouth through the oropharynx and placed above the tongue to move it away from the back of the throat.[2][4] They are more commonly used than nasopharyngeal airways (NPAs).[4] OPAs should only be used in profoundly unresponsive or unconscious patients without a gag reflex. Placement of the device may stimulate the gag reflex and cause vomiting, aspiration, and laryngospasm.[2][4][3] Complications from OPA placement include damage to the teeth and the lingual nerve, which may cause changes in taste and sensation of the tongue.[2][4]
Nasopharyngeal airways
A nasopharyngeal airway (NPA) is a flexible tube that is passed through the nose into the back of the throat. They are the artificial airways of choice in patients who are conscious and have intact gag reflexes because they are less likely to stimulate the gag reflex than oropharyngeal airways (OPAs).[4][2] NPAs can also be used in other sitations where OPAs cannot, such as in patients with restricted mouth opening or oral trauma.[2] NPAs are generally not recommended if there is suspicion of a fracture to the base of the skull due to the risk of the tube entering the skull.[2][3] They are also contraindicated in the presence of significant facial trauma.[3] Nosebleeds are a complication of NPAs that may result from the use of excessive force or a lack of lubrication during placement.[4][3]
Extraglottic airways
Extraglottic airway devices (EGDs) create a patent airway without entering the trachea. These devices are highly effective for providing oxygenation and ventilation.[3][5] They can be used as primary airway devices, such as during CPR, or as rescue devices in situations where securing an airway using other devices has failed.[3][5][4] EGDs are especially effective rescue devices for obese patients and patients with significant facial trauma.[3] EGDs do not protect the trachea from obstruction or aspiration. They may be used for several hours until a definitive airway can be secured.[5][4]
Each type of EGD has different features, including the ability to remove air from the stomach (gastric decompression) and perform tracheal intubation.[5][4] All EGDs can be placed without directly seeing the glottis (also called "blind" placement).[3][4] EGDs can be classified into supraglottic airways and retroglottic airways.[3][5]
Supraglottic airways
Supraglottic airway devices (SGAs) create a seal over the glottic opening to route oxygen directly into the trachea.[3][5] The SGAs consist entirely of laryngeal masks. Several manufacturers produce these devices, the most well known being the laryngeal mask airway (LMA).[3][5][4] Success rates of SGAs in securing airways are similar between the different models, and these devices provide effective ventilation in more than 98% of patients.[3][5] SGAs can be placed in under 30 seconds, making them advantageous for emergency use.[3] Serious complications are rare and usually result from nerve and soft tissue trauma in the pharynx during placement.[4]
Retroglottic airways
Retroglottic airway devices (RGAs) pass behind the glottis and into the esophagus to create a seal allowing oxygen to be delivered directly to the trachea.[3][5] The RGAs are designed as laryngeal tubes.[3] Examples of RGAs include the Combitube and the King LT. Studies comparing the effectiveness between the RGAs are lacking.[3][4] Like SGAs, most complications from RGAs result from trauma to the pharynx during placement.[4]
Tracheal intubation
Tracheal intubation, often simply referred to as intubation, is the placement of a flexible plastic or rubber endotracheal tube (ETT) into the trachea to maintain an open airway, allow for effective ventilation, protect the airway from aspiration (when a cuffed ETT is used), and to serve as a conduit through which to administer inhaled anesthetics. It is frequently performed in surgery, critically injured, ill or anesthetized patients to facilitate ventilation of the lungs, including mechanical ventilation, and to prevent the possibility of asphyxiation or airway obstruction. The most widely used route is orotracheal intubation, in which an endotracheal tube is passed through the mouth, through the vocal cords, and into the trachea. In a nasotracheal intubation, a nasotracheal tube (NTT) is passed through the nose, through the vocal cords, and into the trachea.[6][7][8]
Indications
There are specific indications or guidelines for deciding a more invasive and more secure airway is worth the associated risk:[6]
- respiratory failure
- apnea or the suspension of breathing
- decreased or altered level of consciousness, rapid mental status change, Glasgow Coma Scale score less than 8 (GCS<8).
- major trauma, such as penetrating injury to the abdomen or chest
- direct airway injury or facial burns
- high risk of aspiration
Methods
Direct Laryngoscopy
Classically, tracheal intubation has been performed utilizing direct laryngoscopy to obtain direct visualization of the vocal cords. There are multiple different laryngoscope blade styles, shapes, and lengths from which to choose based on patient anatomy and clinician preference.[9] In North America, the Macintosh blade is the most commonly used curved blade while the Miller blade is the most common straight blade.[9] Many modern laryngoscopes are equipped with a fiberoptic light source to aid in visualization. Regardless of blade shape, direct laryngoscopy technique involves passage of the laryngoscope through the mouth and into the back of the throat. Manipulation of the neck and lifting of the tongue allows for direct visualization of the larynx and vocal cords by the operator. Following visualization, the endotracheal tube can be passed along the blade, through the vocal cords, and into the trachea.[10]
Video Laryngoscopy
Multiple intubation tools are now available with built-in video technology, also known as video laryngoscopy.[9] The GlideScope model utilizes a curved laryngoscopic blade with an integrated camera connected to a large external monitor. The McGrath model has a compact design with a small display directly attached to the laryngoscopic blade. The operator introduces the video laryngoscope through the mouth with a technique similar to direct laryngoscopy. The larynx and vocal cords are visualized via the camera and the operator is able to pass the endotracheal tube through the vocal cords and into the trachea under direct visualization on the video monitor.[9] Studies have shown that when compared to direct laryngoscopy, video laryngoscopy resulted in fewer failed intubation attempts, especially in patients with known difficult airways.[11] Limitations of video laryngoscopy exist and prevent the exclusive use of this method over direct laryngoscopy. Excessive blood and saliva in the airway can cover the camera lens on the video laryngoscope and obscure effective visualization of the anatomy, preventing effective intubation attempts. This is of importance in patients with trauma to their airway, increasing the amount of blood present, and patients taking sialogogues, or drugs that increase the flow of saliva.[12]
Fiberoptic Intubation
In patients with known difficult airways, fiberoptic intubation can be considered. This technique involves the use of a flexible fiberoptic bronchoscope for visualization of the vocal cords. The bronchoscope can be passed directly into the trachea and the endotracheal tube can be threaded over the bronchoscope into position. This technique has various advantages over direct laryngoscopy and video laryngoscopy techniques. The fiberoptic scope is flexible and can be directed by the operator, allowing it to traverse the upper airway with minimal manipulation of the patient's neck. The operator can manipulate the device around obstructions in the upper airway, making the technique advantageous for patients with cancer or swelling in the upper airway. The device is relatively small compared to a laryngoscope and can therefore be implemented in patients with small mouth openings. Additionally, the fiberoptic scope can be passed through the nostril to provide visualization for a nasotracheal intubation. Lastly, fiberoptic intubation can be conducted in an awake patient with sufficient use of local anesthetics, which can prove useful in patients who would otherwise be unable to be anesthetized without having a secure airway in place beforehand. [9]
Confirming placement
It is necessary to confirm placement of the endotracheal tube to ensure that the tube is properly positioned within the trachea and has not accidentally passed into the esophagus instead. Additionally, it is important to confirm that the endotracheal tube was not placed too deep in the trachea where is may only be ventilating one of the lungs due to it being positioned within a mainstem bronchi (frequently the right mainstem bronchi due to a more obtuse angle than the left). The gold standard for confirming successful placement of an endotracheal tube is direct visualization of the tube passing through the vocal cords and positive end-tidal carbon dioxide on capnography. Secondary methods of confirmation include oxygen saturation, chest x-ray, ultrasound, condensation in the endotracheal tube, equal chest rise, breath sounds heard on both sides of the chest (often with the assistance of a large tidal volume breath), and an absence of breath sounds over the epigastrium. No single method of confirming placement is 100% reliable so multiple methods of confirmation should be utilized.[6][13][14]
Surgical airways
Surgical methods for airway management rely on making a surgical incision below the glottis in order to achieve direct access to the lower respiratory tract, bypassing the upper respiratory tract. Surgical airway management is performed as a last resort in cases where tracheal intubation has failed, is not feasible, or is contraindicated.[15] Surgical methods for airway management include cricothyrotomy and tracheostomy.[15][16]
Cricothyrotomy
A cricothyrotomy is a procedure during which an incision is made through the cricothyroid membrane, allowing an artificial airway to be placed in the trachea. It is the first-line surgical procedure to access an airway in an emergency because it can be performed more quickly than a tracheotomy and is less likely to cause bleeding and damage to thyroid tissue.[15][16] A cricothyrotomy creates a temporary airway that can be used until a more definitive airway can be secured.[16] A cricothyrotomy is typically performed as an emergency procedure when other airway management attempts have failed and is at risk of asphyxiation. The procedure is frequently performed by otorhinolaryngologist (an ear, nose, and throat surgeon) if available or an anesthesiologist.[17][18]
Tracheotomy
A tracheotomy is a surgical procedure creating an incision in the front of the neck down to the trachea.[16][19] A tracheostomy tube can be placed through the opening created by the incision, which allows breathing through the tube rather than the nose and mouth.[16][20] Although the terms are sometimes used interchangeably, a "tracheotomy" is the surgical procedure creating an incision into the trachea, while "tracheostomy" refers to the opening in the trachea created by the incision.[20] The most common acute complications of a tracheotomy are difficulty speaking or swallowing due to nerve damage, prolonged bleeding at the incision site, and pneumothorax.[15][21] A tracheotomy is rarely indicated in an emergent setting. It more commonly performed in a controlled environment to create an airway that can be used long-term, such as for prolonged mechanical ventilation.[16][21]
Pediatric considerations
Many advanced airway techniques may be applied to children. In the fields of pediatric anesthesiology, pediatric critical care, and pediatric emergency medicine, a clear passage between the lungs and the environment is essential.[22]
Children have numerous anatomic differences from adults which present unique challenges when implementing advanced airway techniques. Neonates and infants have overall smaller airway anatomy including a shorter trachea and smaller nasal openings. Additionally, they have proportionally larger tongues and heads. As a result, infants are obligate nasal breathers until the age of 5 months.[9] Given their overall smaller airway diameter, children are more susceptible to airway obstruction from swelling.[9] Given the rapid growth throughout childhood, care must be taken to choose the proper sized airway device for every individual. Broselow tape is a tool used to help facilitate rapid and accurate equipment sizing decisions in pediatric emergency situations.
Supraglottic airway devices, direct laryngoscopy, indirect video laryngoscopy, and fiberoptic intubation are all techniques which can be used to secure the pediatric airway. In the event that these techniques cannot adequately ventilate the patient, a surgical airway may be required. Surgical help should be requested for invasive access, however, in scenarios in which a pediatric otorhinolaryngologist is not available, a needle cricothyrotomy is an emergency alternative.[22]
See also
References
- ↑ Roth, Dominik; et al. (2018). "Airway physical examination tests for detection of difficult airway management in apparently normal adult patients". Cochrane Database of Systematic Reviews. 2018 (5): CD008874. doi:10.1002/14651858.CD008874.pub2. PMC 6404686. PMID 29761867.
- 1 2 3 4 5 6 7 8 Al-Shaikh, Baha (2019). "Tracheal tubes, tracheostomy tubes and airways". Essentials of equipment in anaesthesia, critical care, and peri-operative medicine. Simon Stacey (5 ed.). Edinburgh. ISBN 978-0-7020-7196-6. OCLC 1021173545.
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: CS1 maint: location missing publisher (link) - 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 "Basic Airway Management and Decision Making". Roberts and Hedges' clinical procedures in emergency medicine and acute care. James R. Roberts, Catherine B. Custalow, Todd W. Thomsen (7 ed.). Philadelphia, PA. 2019. ISBN 978-0-323-54794-9. OCLC 1025330199.
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: CS1 maint: location missing publisher (link) CS1 maint: others (link) - 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 "Airway Management in the Adult". Miller's anesthesia. Michael A. Gropper, Ronald D. Miller (9th ed.). Philadelphia, PA. 2020. ISBN 978-0-323-61264-7. OCLC 1124935549.
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: CS1 maint: location missing publisher (link) CS1 maint: others (link) - 1 2 3 4 5 6 7 8 9 "Airway". Rosen's emergency medicine : concepts and clinical practice. Ron M. Walls, Robert S. Hockberger, Marianne Gausche-Hill (9th ed.). Philadelphia, PA. 2018. ISBN 978-0-323-39016-3. OCLC 989157341.
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: CS1 maint: location missing publisher (link) CS1 maint: others (link) - 1 2 3 Avva, Usha; Lata, Julie M.; Kiel, John (2023), "Airway Management", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 29262130, retrieved 2024-01-11
- ↑ Alvarado, Andrea C.; Panakos, Patricia (2023), "Endotracheal Tube Intubation Techniques", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 32809565, retrieved 2024-01-11
- ↑ Folino, Thomas B.; Mckean, George; Parks, Lance J. (2023), "Nasotracheal Intubation", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 29763142, retrieved 2024-01-11
- 1 2 3 4 5 6 7 Butterworth, John F.; Mackey, David C.; Wasnick, John D. (2022). Morgan & Mikhail's Clinical Anesthesiology (7th ed.). New York: McGraw Hill. pp. 307–343. ISBN 978-1-260-47379-7.
- ↑ Peterson, Katherine; Ginglen, Jacob G.; Desai, Ninad M.; Guzman, Nilmarie (2023), "Direct Laryngoscopy", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 30020596, retrieved 2023-11-30
- ↑ Lewis SR, Butler AR, Parker J, Cook TM, Smith AF. Videolaryngoscopy versus direct laryngoscopy for adult patients requiring tracheal intubation. Cochrane Database of Systematic Reviews 2016, Issue 11. Art. No: CD011136 DOI: 10.1002/14651858.CD011136.pub2.
- ↑ Chemsian, Rv; Bhananker, S.; Ramaiah, R. (January 2014). "Videolaryngoscopy". International Journal of Critical Illness and Injury Science. 4 (1): 35–41. doi:10.4103/2229-5151.128011. ISSN 2229-5151. PMC 3982369. PMID 24741496.
- ↑ "Verification of Endotracheal Tube Placement". Annals of Emergency Medicine. 68 (1): 152. July 2016. doi:10.1016/j.annemergmed.2016.04.055. ISSN 1097-6760. PMID 27343673.
- ↑ Reichman, Eric F. (2013), "Chapter 12. Confirmation of Endotracheal Intubation", Emergency Medicine Procedures (2 ed.), New York, NY: The McGraw-Hill Companies, retrieved 2024-01-11
- 1 2 3 4 Hagberg, Carin A. (2017). Hagberg and Benumof's Airway Management E-Book (4th ed.). Elsevier Health Sciences. ISBN 978-0-323-44918-2. OCLC 1012122640.
- 1 2 3 4 5 6 Current therapy of trauma and surgical critical care. Juan A. Asensio, Donald D. Trunkey (2 ed.). Philadelphia, PA. 2016. ISBN 978-0-323-16917-2. OCLC 912278253.
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: CS1 maint: location missing publisher (link) CS1 maint: others (link) - ↑ Park, Joseph C.; Hillel, Alexander T. (June 2020). "The approach and operative implications for the partially obstructed airway with impending or sudden loss of the airway". Operative Techniques in Otolaryngology-Head and Neck Surgery. 31 (2): 111–119. doi:10.1016/j.otot.2020.04.007. ISSN 1043-1810. S2CID 219507502.
- ↑ McKenna, Peter; Desai, Ninad M.; Tariq, Amina; Morley, Eric J. (2023), "Cricothyrotomy", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 30726035, retrieved 2024-01-12
- ↑ Andriolo, Brenda N. G.; Andriolo, Régis B.; Saconato, Humberto; Atallah, Álvaro N.; Valente, Orsine (2015-01-12). "Early versus late tracheostomy for critically ill patients". The Cochrane Database of Systematic Reviews. 1 (12): CD007271. doi:10.1002/14651858.CD007271.pub3. ISSN 1469-493X. PMC 6517297. PMID 25581416.
- 1 2 Molnar, Heather. "What is a tracheostomy?". www.hopkinsmedicine.org. Retrieved 2022-01-19.
- 1 2 "Tracheostomy - Mayo Clinic". www.mayoclinic.org. Retrieved 2022-01-19.
- 1 2 Krishna, Senthil; Bryant, Jason; Tobias, Joseph (September 2018). "Management of the Difficult Airway in the Pediatric Patient". Journal of Pediatric Intensive Care. 07 (3): 115–125. doi:10.1055/s-0038-1624576. ISSN 2146-4618. PMC 6260357. PMID 31073483.