Hi all,

This is going to be a short but important POTD!

I wanted to write about an airway set up technique, colloquially termed “The Double Set Up” that the trauma and northside teams used yesterday during a level 1 trauma.

Without giving any secrets away for a case that will likely be an M&M in the future, for some situational background, the patient was getting progressively hypoxic with vomitus covering the entire airway. It was hard to get visualization of the airway using the Glidescope. The airway options were clear: either tube via DL or crich.

The team smartly employed the double set up technique to secure the airway. 

What does this term mean?

The double set up is when you have simultaneously set up for an orotracheal intubation and for a cricothyroidotomy. The EM/ anesthesia physician is at the head of the bed with the orotracheal airway equipment, while the surgeon is completely prepared for the crich with the scalpel in hand at the neck of the patient. The neck should already be prepped, and the landmarks should be identified.

When should we do the double set up?

Strayer has an amazing blog post about this (see below). Here are some indications where you might want to do the double set-up:

• An unstable maxillofacial trauma patient

• As a last ditch effort to secure the orotracheal tube after a failed attempt

• Rapidly desaturating patient with challenging anatomical features / cannot be successfully bagged

• Concern for an obstructed airway

If the intubator is ultimately unsuccessful, they indicate to the surgical airway physician to proceed. If the orotracheal intubator is successful, then the surgical airway physician can stop.

References:

• Check out Strayer’s excellent post on this: https://emupdates.com/the-emergency-department-double-setup/ 

• https://www.emed.theclinics.com/article/S0733-8627(17)30075-5/pdf 

• http://maryland.ccproject.com/wp-content/uploads/sites/8/2015/09/Leeuwenberg-2015-Airway-Management-of-the-Critically-Ill-Patient-Modifications-of-Traditional-Rapid-Sequence-Induction-and-Intubation.pdf
  

Here is an overview of spinal cord injury syndromes.

CENTRAL CORD SYNDROME:

Injuries to the central cord region typically affect the spinothalamic tract (pain and temperature) and the corticospinal tract (motor). 

Etiologies:

• Typically due to hyperEXTENSION

• Incomplete lesion

• Develops due to poor blood flow of the spinal cord

• Degenerative joint disease – the vignette might be about an old person with OA

Classic features:

• Symptoms are worse in upper extremities compared to lower extremities (this is the testable feature!)

• Sensory and motor deficits

• Variable prognosis

ED management:

• Intubate if the injury is higher than C5

• If you must intubate, consider video laryngoscopy to avoid the further hyperextension of direct laryngoscopy

ANTERIOR CORD SYNDROME:

Etiologies:

• Direct injury: HyperFLEXION injury; crush or compression from a hematoma; just think of it as the neck crushing down on the anterior column.

• Incomplete lesion

• Indirect injury: ischemia to anterior spinal artery

Classic features:

• Loss of motor, pain, and temperature below the level of injury

• Posterior column features are preserved – e.g. touch, proprioception, and vibration

• Bad prognosis :-( 

BROWN-SEQUARD SYNDROME:

Etiology:

• Usually penetrating trauma

• These question stems might involve a “stab to the back”

Classic features:

• Hemisection of spinal cord

• Ipsilateral motor paralysis

• Contralateral sensory loss of pain and temperature

I know you’ll never forgive me if I don’t include a quick reminder about the spinal column. If you’re struggling to keep things straight, just reminder that the posterior columns are responsible for proprioception, touch, and vibration. See below for pictures.

References:

• https://litfl.com/spinal-cord-anatomy-and-syndromes/

• Rosh Review :)

• https://wikem.org/wiki/Spinal_cord_injury 

 Epidemiology

-       3 primary age groups

o   Toddlers – household sockets, appliances, etc.

o   Adolescents – risk-taking behavior

o   Adults – occupational hazard

-       Lightning strikes – account for 50-300 deaths per year in US (mostly Florida)

-       ~6,500 injuries and 1,000 deaths annually from all electrocution injuries

Classification

-       Low voltage: ≤1000 volts (V)

o   Household outlets in US typically 120 V

-       High Voltage: >1000 V

o   Power lines > 7000 V

-       Alternating current (AC) = electrical source with changing direction of flow  household outlets

o   Induces rhythmic muscle contraction  tetany  prolonged electrocution as individual is locked in place

o   Although generally lower voltages, can be more dangerous than DC as the time of electrocution is much higher

-       Direct Current (DC) = electrical source with unchanging direction of current of flow  lightning strikes, cars, railroad tracks, batteries

o   Usually induces a single, forceful muscle contraction  can throw an individual with significant force  higher risk of severe blunt trauma 

Mechanisms of Injury

-       Induced muscle contraction  rhabdomyolysis

-       Blunt trauma

-       Burns

o   Internal thermal heating – most of damage caused by direct electrocution

o   Flash/Arc burns – electricity passes over skin causing external burns

o   Flame – electricity can ignite clothing

o   Lightning strikes can briefly raise the ambient temperature to temperatures greater than 54,000F

Severity of Injury – is determined by…

-       Type of current – AC vs. DC

-       Duration of contact

-       Voltage

-       Environmental circumstances (rain, etc.)

Clinical Manifestations

-       Cardiac – 15%, mostly benign and occur within few hours of hospital stay

o   Arrhythmias - Most occur shortly after the event, though non-life-threatening arrhythmias can occur a few hours after the event and are usually self-resolving. Generally, …

§  DC = asystole

§  AC = ventricular fibrillation

o   Other EKG findings – QT prolongation, ST elevations, bundle branch blocks, AV blocks, atrial fibrillation

-       Pulmonary

o   Respiratory paralysis – diaphragmatic muscle

o   Blunt trauma – pneumothorax, hemothorax, pulmonary contusions, etc.

-       Neurologic – generally, patient can APPEAR DEAD but is the cause of neurologic electrocution and may be temporary. IE.

o   Coma

o   Fixed, dilated pupils

o   Dysautonomia

o   Paralysis or anesthesia

-       Renal – Rhabdomyolysis

-       Skin – All kinds of burns

-       MSK – from severe muscle contractions

o   Always assume C-spine injury

o   Compartment syndrome

o   Fractures/Dislocations

Management – we’ll divide them into categories of severity. Basically, always do an EKG!!

1)    Mild (<1000V) – examples include brief house outlet shock, stun gun

a.     EKG – other work-up such as troponin and CPK usually unnecessary

b.     If history/physical unremarkable (patient endorses brief contact with house outlet) patient can be discharged without further work-up

c.     If PMH puts patient at higher risk of arrhythmia (cardiac disease, sympathomimetics) can do a brief period of telemetry observation

d.    Can always observe 4-8 hours to be on the safe side

e.     High Risk Features

                                               i.     Chest pain

                                             ii.     Syncope

                                            iii.     Prolonged exposure

                                            iv.     Wet skin

2)    Severe Electrocution (>1000V) – industrial accidents, lightning strikes

a.     Coding – pursue usual ACLS

                                               i.     Keep in mind traumatic causes of arrest (tension pneumothorax, etc.)

                                             ii.     KEY FACT: remember that patients with fixed, dilated pupils, no respiratory effort, and no spontaneous movement may only have TEMPORARY neurologic stunning

                                            iii.     Pursue resuscitation longer than usual as patient with ROSC can still have good outcomes  does not appear to be any definitive guidelines on when to terminate, at physician discretion

b.     Otherwise, broad medical and traumatic work-up and likely admission for telemetry monitoring (basically just send all the labs and images)

                                               i.     Start with primary/secondary trauma survey and further imaging as required

                                             ii.     Don’t forget CPK to assess for rhabdomyolysis

c.     Consider transfer to burn center

TL;DR

-       Treat as you would a trauma/burn patient

-       Most household outlet shocks – history/physical, EKG, and likely quick discharge unless high risk features

-       Industrial shocks – at best admit for telemetry. At worst prolonged ACLS as good outcomes are possible. Don’t forget traumatic causes such as tension pneumothorax

http://brownemblog.com/blog-1/2020/4/14/acute-care-of-the-electrocuted-patient

http://www.emdocs.net/electrical-injury/

http://www.emdocs.net/em3am-electrical-injuries/

http://www.emdocs.net/em-cases-electrical-injuries-the-tip-of-the-iceberg-view-larger-image/

https://www.tamingthesru.com/blog/air-care-series/electrocution