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EMS Confined Space Care

Editor: Gal Pachys Updated: 9/26/2022 5:42:30 PM

Introduction

Confined space medicine is practiced in areas with limited access and potentially decreased ventilation. The limited space is often secondary to the structural collapse of buildings from natural disasters such as earthquakes, hurricanes, or tornadoes. However, confined space medicine practices may be needed after a terrorist blast, fire, or poor building standards. The number of victims involved may vary, from a small number in a house collapse to a larger number in a mass-casualty event such as the 1995 bombing of the Alfred P. Murrah building in Oklahoma City, which resulted in 168 deaths, or the 2001 World Trade Center attack which resulted in over 3000 deaths.[1][2][3][4]

Issues of Concern

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Issues of Concern

Types of Building Collapse

There are 4 general types of building collapse: 

  1. Pancake collapse: All of the floors fall on top of each other
  2. Lead to collapse: The floor, wall, or beam collapses, but a remaining wall still supports the structure
  3. V collapse: The floor or roof collapses into a lower level in the shape of a V
  4. Cantilever collapse: The outer wall is destroyed, leaving the roof and upper floors dangling

Urban Search and Rescue

Urban search and rescue (USAR) is a unique, multihazard discipline involved in locating, extricating, and stabilizing victims of confined spaces such as a building collapse. USAR team members include search and rescue personnel, structural specialists, physicians, and other medical staff. Regardless of the cause of the collapse or the number of victims, the rescuer's safety is a priority. Structural engineers are responsible for determining the relative safety of the site. Recognizing and minimizing the risk of team members becoming injured or trapped in a secondary collapse is paramount. The team leader is responsible for deciding whether to enter the scene. Appropriate equipment is necessary, including a helmet, dust mask, earplugs, safety glasses, heavy-duty gloves, steel-toe boots, and coveralls.

On an international level, USAR is organized by the International Search and Rescue Advisory Group (INSARAG), part of the United Nations Office for the Coordination of Humanitarian Affairs, and is a global network of more than 80 countries. The Federal Emergency Management Agency has 28 teams nationwide in the United States. Europe has similar rescue groups and other volunteer USAR teams worldwide.

USAR operations are organized into 5 stages:

  1. Reconnaissance
  2. Medical assessment of victims
  3. Search of other areas for live victims
  4. Removal of small debris by "bucket brigades"
  5. Removal of larger debris by heavy equipment.

Rescue dogs or even rescue robots may reach victims. Acoustic microphones help detect victims trapped in the debris. Victim assessments can be conducted verbally, using cameras or fiberoptic devices. The first 24 to 48 hours after the start of the event, or the "golden day," is critical. In contrast to traumas and injuries in other situations, there is no actual golden hour. If rescuers cannot immediately get access to the victims, they often die. Patients who die in the first 24 hours usually do so from either shock or airway issues, whereas patients who die after 24 hours usually do so from sepsis or multi-organ failure. Injuries in collapsed structures may include fractures, multiple trauma, lacerations, closed head injury, hypothermia, dehydration, and crush injury or crush syndrome. The inhalation of toxic fumes or dust can injure victims.

Airway Management

Managing the airway in a confined space begins with the basic standard equipment, including suction, bag valve mask, oral airways, laryngoscope, nasotracheal tubes, and endotracheal tubes. Other equipment, such as the laryngeal mask airway, esophageal obturator airway, esophageal, gastric tube airway, lighted stylet, and cricothyrotomy kits may be useful. Extended-length tubing for oxygen may be necessary. If there is a concern about dust inhalation, then albuterol or ipratropium may be beneficial.

Intubating in a confined space has unique challenges. Inline c-spine stabilization may be difficult or impossible. Spacial constraints can prevent intubation from the standard position from behind the patient. This situation often requires the face-to-face technique known as inverse intubation or icepick intubation. The laryngoscope is still held with the right hand and the handle toward the patient’s feet; the incubator may be on the patient's side or straddle the patient. In this position and approach, video laryngoscopy has no clear, proven advantage over traditional laryngoscopy blades. Another technique that may be useful in the unconscious patient is digital intubation. The rescuer uses his or her fingers to lift the epiglottis and then guide the tube through the glottis and into the trachea. When a cricothyrotomy is required, a recent study showed that the Quicktrak proved faster to insert than the Melker kit. The time saving from using the Quicktrack was believed to be secondary to fewer parts and less manipulation required.

Chest Injuries

Mild to severe chest injuries can occur, with the worst often being fatal. Tension pneumothorax should be treated by needle application, finger thoracostomy, or chest tube placement. If needle application is to be performed, current studies show greater success with a longer needle catheter, such as a 14 gauge 5 cm needle with a 4.5 cm catheter sheath. More importantly, success is also tied to the insertion of the needle in either the 4th/5th intercostal space at the midaxillary or anterior axillary line instead of placement at the 2nd intercostal space midclavicular line.

Crush Injury and Crush Syndrome

Crush injury and crush syndrome may be encountered. Crush injury is the direct injury to the limb or organ by compressive forces, whereas crush syndrome is the systemic effects of a crush injury. Systemic effects of a crush injury can include rhabdomyolysis, renal failure, sepsis, acute respiratory distress syndrome, disseminated intravascular coagulation, bleeding, arrhythmias, and electrolyte imbalance. It is the second most frequent cause of death from earthquakes, the first being trauma. The pathophysiology includes impaired kidney perfusion and intratubular obstruction caused by myoglobin and uric acid.

Treatment emphasizes early fluid resuscitation even while the victim is under the rubble. After intravenous (IV) access is established, recommendations are for administering normal saline at 1000 mL per hour, tapered by 50% after 2 hours for adults and 20 mL/kg per hour for children for the first 2 hours and then 10 cc/kg per hour. In the elderly, children, or those with volume overload, less fluid should be given. If it is impossible to obtain IV access, an intraosseous (IO) catheterization can be attempted. If IV or IO access attempts are unsuccessful, hypodermoclysis and administering fluids subcutaneously, with a flow rate of 1 mL per minute, should be considered.

Hypodermoclysis can be used in more than one location on a patient, and up to 3 L can be administered daily. Lactated ringers should be avoided as they contain potassium, which can worsen potentially life-threatening hyperkalemia in some patients. Generally, 3 to 6 L should be given over the first 6 hours while monitoring the patient’s hemodynamic status and urine output. If there is anuria (after hypovolemia is excluded), give only 500 to 1000 mL per day in addition to fluid losses. If close monitoring is impossible, then give up to 3 to 6 L of intravenous fluid per day. When close monitoring is available, more than 6 L can be given daily.

Once the victim is extricated, 50 mEq of sodium bicarbonate can be added to each liter of half-normal saline (combined produces a solution nearly isotonic) to maintain urinary pH over 6.5. Patients with rhabdomyolysis need approximately 200 to 300 mEq of bicarbonate a day. Treatment with mannitol is controversial, given its proven efficacy in traumatic rhabdomyolysis and its side effect profile. Mannitol may be useful to increase extracellular volume and prevent the deposition of renal tubular casts. Still, its use may also lead to heart failure and renal toxicity if not dosed properly. Mannitol is contraindicated in oliguria, hypervolemia, hypertension, and heart failure, so the decision to give this medication should not be automatic. Mannitol, if used, should be given as a 60-ml dose of 20% mannitol over 3 to 5 minutes to test if there is a urinary response. Mannitol should only be continued if there is a 30 to 50 mL per hour increase in urinary output over baseline. The dose of mannitol is 1 to 2 gm/kg per day for a total of 120 gm per day at a rate of 5 gm per hour.

Several electrolyte abnormalities may be present. Hypocalcemia should only be treated if the patient is symptomatic since the patient may later develop hypercalcemia. Start with 10 mL of intravenous calcium gluconate 10% or 5 mL of intravenous calcium chloride 10% over 2 minutes. Hyperkalemia should be monitored and treated based on the potassium level and electrocardiographic changes. The electrocardiogram may not change when the potassium level is dangerously elevated. If there are severe or life-threatening electrocardiographic changes or arrhythmias, such as widening the QRS to third-degree heart block or pulseless electrical activity, intravenous calcium gluconate or chloride should be given immediately. It may be necessary to give several doses every 10 minutes to achieve the cardioprotective effects of calcium.

If the patient is acidotic, sodium bicarbonate 1 mEq/kg should be given immediately intravenously over several minutes. To drive the potassium into the cells, 10 units of intravenous insulin and 1 to 2 ampules of D50 should be given. The beta-agonist effect of albuterol inhalation treatments can also help transiently decrease potassium levels. Kaexylate with sorbitol can be given orally at 25 to 50 gm, or it may be given as a retention enema. Patients with life-threatening hyperkalemia need the potassium removed from their system. The medications and treatments are temporary measures to provide time for the excretion or removal of potassium from the body. The patient may require emergent dialysis. Critiques of recent disaster responses were that there was an insufficient number of dialysis machines to treat those with renal failure secondary to crush injuries. Blood products should be given as necessary and when indicated.

One of the more severe complications of crush injury is compartment syndrome. One should monitor for the "5Ps," which include pain, paresthesias, paralysis, pallor, and pulselessness. However, it is important to realize that pain out of a portion of the exam may be present before the other symptoms, which is the initial presentation of compartment syndrome. Patients may also continue to have a pulse when compartment pressures are elevated, and if pulses are lost, then this is a late sign. A more objective measure is to check pressures within the compartment. A pressure greater than 40 mm hg indicates the need for a fasciotomy. Although there is no consensus regarding the exact number, some sources recommend that compartment syndrome has an intracompartmental pressure greater than 30 mm Hg or a less-than-30–mm Hg difference between intracompartmental pressure and diastolic blood pressure as an indication for fasciotomy.

Clinical Significance

Confined space medicine involves a multihazard and interprofessional approach to treating victims trapped in a structural collapse. There are unique challenges to both the initial treatment of such victims regarding airway management as well as the treatment of crush syndrome.[5][6][7]

References


[1]

Page D, Krost W. Excrement Happens A complicated entrapment leads to a crew's reprimand. EMS world. 2016 Aug:45(8):16-18     [PubMed PMID: 29846046]


[2]

Wright SW, Lindsell CJ, Hinckley WR, Williams A, Holland C, Lewis CH, Heimburger G. High fidelity medical simulation in the difficult environment of a helicopter: feasibility, self-efficacy and cost. BMC medical education. 2006 Oct 5:6():49     [PubMed PMID: 17020624]

Level 2 (mid-level) evidence

[3]

Sayre MR, White LJ, Brown LH, McHenry SD, National EMS Agenda Writing Team. National EMS Research Agenda. Prehospital emergency care. 2002 Jul-Sep:6(3 Suppl):S1-43     [PubMed PMID: 12108581]


[4]

Cone DC,Wydro GC,Mininger CM, Physician field response: a national survey. Prehospital emergency care : official journal of the National Association of EMS Physicians and the National Association of State EMS Directors. 2000 Jul-Sep;     [PubMed PMID: 10895915]

Level 3 (low-level) evidence

[5]

Padaki A, Redha W, Clark T, Nichols T, Jacoby L, Slivka R, Ranniger C, Lehnhardt K. Simulation Training for In-Flight Medical Emergencies Improves Provider Knowledge and Confidence. Aerospace medicine and human performance. 2018 Dec 1:89(12):1076-1079. doi: 10.3357/AMHP.4945.2018. Epub     [PubMed PMID: 30487028]


[6]

Kornhall D, Hellikson F, Näslund R, Lind F, Broms J, Gellerfors M. A Protocol for Helicopter In-Cabin Intubation. Air medical journal. 2018 Sep:37(5):306-311. doi: 10.1016/j.amj.2018.05.002. Epub 2018 Jun 7     [PubMed PMID: 30322633]


[7]

Bhatnagar V, Jinjil K, Dwivedi D, Verma R, Tandon U. Cardiopulmonary Resuscitation: Unusual Techniques for Unusual Situations. Journal of emergencies, trauma, and shock. 2018 Jan-Mar:11(1):31-37. doi: 10.4103/JETS.JETS_58_17. Epub     [PubMed PMID: 29628666]