How to avoid Drowning or submerging in.pdf

Leavenworth Paramedic Lecture Series
2019
Brian Rogge RN, CFRN, EMT-P

Objectives
• Terminology
• Definition
• Incidence
• Prognosis
• Interventions/management
• Opportunities impacting outcome

Terminology
• Drowning
–death within 24 hours of a submersion
incident
• Near Drowning
–survive at least 24 hrs after a submersion
incident

Terminology
• Wet Drowning
–Water identified in the lungs
• Dry Drowning
–No water entered the lungs

Definitions
• Drowning
– Consensus definition: a process resulting in
primary respiratory impairment from
submersion in a liquid medium.
• Outcomes:
– Death
– Morbidity
– No Morbidity

Incidence
• CDC 2005-2014 for US
▪ ~3,536 fatal unintentional drownings (non-boating
related) annually
▪ An additional 332 people died each year from
drowning in boating-related incidents
▪ Leading cause of injury death among children 1-4 yrs
▪ 2nd leading cause of all accidental deaths <14 yr
(MVC 1st)
▪ Fatality: male:female ( 4:1 )

Incidence
• About one in five people who die from drowning are
children 14 and younger. For every child who dies
from drowning, another five receive emergency
department care for nonfatal submersion injuries.
• 50% of drowning victims require hospitalization or
transfer
• Incidence: ↑ holidays, weekends and warm weather
• Children
– < 5 years old – pools
– older kids and adults - open water
– regionally specific

Morbidity & Mortality
• 15% of children admitted for drowning die in
the hospital
• As many as 20% of drowning survivors suffer
severe, permanent neurological disability

Risk Factors
• Lack of swimming ability
• Lack of barriers
• Lack of close supervision
• Location
• Failure to wear a life jacket
• Alcohol use
• Seizure disorders

Causes
• Toddlers:
– Lapse of
supervision
– Afternoon/early
evening-meal time
– 84% with
responsible
supervising adults
– Only 18% of cases
actually witnessed

Causes
• Recreational boating
– 90% of deaths due to drowning
• Vast majority are not wearing life jackets
– 1,200/yr
– Small, open boats
– 20% of deaths
• Too few or no floatation devices!
• Diving
– 700-800/yr
– 1st dive in unfamiliar water
– 40-50% alcohol related

Alcohol
• 25-50% of teen and adult deaths associated
with water recreation
• Alcohol influences balance, coordination, and
judgment, and its effects are heightened by
sun exposure and heat

Causes
• Spas, hot tubs
– Entrapment in
drains, covers
• Buckets drowning
– males>females
– Warm months>cold
– Consider child abuse

Causes
• Epilepsy:
– 1.5-4.6 % had pre-existing seizure disorder
– >5 years old, drown in bathtub, not supervised
• Long QT syndrome:
– Swimming may be a trigger for arrest in patients
with LQTS
– Drowning may be first presentation
– Specific gene KVLQT1 mutation associated with
swimming trigger & submersion

Baby Swim Classes
• Done to “teach” babies
to float
• No reported drownings
in class
• Several reports of
hyponatremic seizures
following class
• False sense of security?

Stages of Drowning
• Stage I
– 0-2 minutes
– Submersion occurs
– Aspiration and Laryngospasm
• Stage II
– 1-2 minutes
– Swallow water
• Laryngospasm relaxes
OR
• Laryngospasm recurs

Stages of Drowning
• Stage III
– Laryngospasm aborted
• Aspiration of water (90%)
– Laryngospasm recurs
• Anoxia, seizure and death without aspiration (10%)

Pathophysiology
• Part I
– Voluntary breath-holding
– Aspiration of small amounts into larynx
– Involuntary laryngospasm
– Swallow large amounts
– Laryngospasm abates (due to hypoxia)
– Aspiration into lungs

Pathophysiology
• Part II
– Decrease in oxygenation
– Decrease in cardiac output
– Intense peripheral vasoconstriction
– Hypothermia
– Bradycardia
– Circulatory arrest
– Extravascular fluid shifts, diuresis

Pathophysiology
• Diving reflex
– Bradycardia, apnea, vasoconstriction
– Relatively weak in humans
• better in kids
– Occurs when the face is submerged in water < 10-15°C
– May occur to some extent in water at 20°C but only
when the air temperature is 30°C or more (10°C
temperature gradient).
– Extent of neurologic protection in humans due to diving
reflex is likely very minimal

Pathophysiology
• Asphyxia, hypoxemia, hypercarbia, & metabolic
acidosis
• Fresh water vs salt water - little difference (except
for drowning in water with very high mineral
content, like the Dead Sea)
• Hypoxemia
– Occlusion of airways with water & particulate debris
– Changes in surfactant activity
– Bronchospasm
– Physiologic dead space increased

Pathophysiology
• Cardiac arrhythmias
• Hypoxic encephalopathy
• Renal insufficiency
• Pulmonary injury
• Global brain anoxia & potential diffuse
cerebral edema

Pathophysiology – Pulmonary Injury
• Aspiration of as little as 1-3 mL/kg can cause
significant effect on gas exchange
– Increased permeability
– Exudation of proteinaceous material in alveoli
– Pulmonary edema
– Decreased compliance

Pathophysiology
• Findings at autopsy
– Wet, heavy lungs
– Varying amounts of hemorrhage and edema
– Disruption of alveolar walls
– ~ 70% of victims had aspirated vomitus, sand,
mud, and aquatic vegetation
– Cerebral edema and diffuse neuronal injury
– Acute tubular necrosis

Pathophysiology – Fresh vs. Salt
• Theoretical changes not supported clinically
– Salt water: hypertonic pulmonary edema
– Fresh water: plasma hypervolemia, hyponatremia
• Both salt and fresh wash out surfactant
– Damaged alveolar basement membrane →
pulmonary edema, Acute Respiratory Distress
Syndrome (ARDS)

Pathophysiology
• Most aspirate 3-4 mL/kg
– Aspirate > 11 mL/kg before fluid changes
– Aspirate > 20 mL/kg before significant electrolyte
changes

Cold vs Icy Water Immersion
• Usually hypothermia is an unfavorable sign
• Several case reports of dramatic neurologic recovery after
prolonged (10-150 min) icy water submersions (<5°C)
• Core body temperature less than 28-30°C, or much lower
• For hypothermia to be protective, core body temperature
must fall rapidly, decreasing cellular metabolic rate, before
significant hypoxemia begins

Hypothermia Easier in Kids
• High Body Surface Area/mass ratio and
decreased subcutaneous fat insulation
• Moderate hypothermia (core 32-35°C)
increases oxygen uptake (VO2) due to
shivering thermogenesis & increased
sympathetic tone
• Severe hypothermia (core <32°C) - shivering
stops & the cellular metabolic rate decreases
(~ 7%/°C drop in temperature)

Hypothermia & Brain Protection
• Hypothermia protects the brain and other
organs from anoxia for 75-110 min in
controlled circumstances where core body
temperature is cooled first to 18°C and then
the heart is stopped [deep hypothermic
circulatory arrest (DHCA)]
• Once cell death from hypoxemia occurs (~ 5-6
min), there is no protective hypothermic
effect or improved recovery

Hypothermia – Surface Cooling
• Surface cooling alone cannot decrease core
temperature fast enough to yield protection
• Cooling rate in drowning victims is difficult to
estimate as patient may also be swallowing or
breathing in cold water
• Hypothermic protection involving surface
cooling only would seem to require
submersion in icy (not cold) water

Cold Water Submersion - Humans
• Few cold water victims have significant brain
protection
• Hypothermia is more commonly an unfavorable
prognostic sign
• King County, WA (water is cold, but rarely icy)
– Hypothermic protection has not been observed
• 92% of good survivors had initial core temp of >34°C
• 61% of those who died or had severe neurologic injury
had core temp <34°C
• Finnish study: Median water temp 16°C
– Submersion duration <10 minutes had greatest sensitivity
in predicting good outcome

Drowning Signs and Symptoms
• 70% develop signs and symptoms within 7 hrs
• Alertness → agitation → coma
• Cyanosis, coughing & pink frothy sputum
(pulmonary edema)
• Tachypnea, tachycardia
• Low grade fever
• Rales, rhonchi & less often wheezes
• Signs of associated trauma to the head & neck
should be sought

Pre-Hospital Treatment
• Rapid and cautious retrieval from the
water. Safety first!
• Immediately establish the airway with C-
spine precautions
• Breathing:
Mouth-Mouth
• In-water CPR is
generally ineffective
and dangerous

• CPR
• Bag-valve-mask
– Higher pressures may be required for ventilation
because of the poor compliance resulting from
pulmonary edema.
• Intubation with PEEP
• Supplemental oxygen on all patients

• Human surviving drowning victims aspirate
small quantities of water
• Postural drainage or the abdominal thrusts
(Heimlich maneuver) are of unproven efficacy
• Delays ventilation and transport
• Can lead to regurgitation and
pulmonary aspiration

• Treatment of hypothermia in the comatose
drowning victim remains controversial and a
topic of investigation.
• Most recommend removal of wet clothing and
wrapping in warm blankets.
• It is generally recommended anyone with
temperatures less than 32-34°C be treated.

• Any patient with a significant episode should
be transported to the hospital for evaluation
–Even if the patient is asymptomatic

Treatment
• ED evaluation begins with immediate
resuscitation and treatment of respiratory failure.
• Frequent neurologic assessment
• Evaluate associated injuries (e.g., cervical spine
injury).
• Early use of intubation and PEEP (or CPAP/BiPAP
in the awake, cooperative, and less hypoxic
individual), if hypoxia or dyspnea persists despite
100% oxygen.

Treatment
• Disposition depends on the history, presence
of associated injuries, and degree of
immersion injury.

Treatment
• Patients can be discharged from the ED after
6-8 hours of observation if they meet the
following criteria:
– Able to relay a good history of minor immersion
injury
– No evidence of significant injury
– No change in mental status or behavior
– No evidence of bronchospasm or
tachypnea/dyspnea
– No evidence of inadequate oxygenation (by ABG
analysis and pulse oximetry)

Treatment
• Victims of mild to moderately severe
submersion, with mild symptoms and no
abnormalities on ABG analysis, pulse oximetry
and chest radiograph, are generally observed
overnight.
• Patients with more severe submersions or
symptoms are admitted to the hospital ward
or ICU.

Treatment – ICU Respiratory
• Positive pressure ventilation, CPAP or PEEP
• Treatment of bronchospasm
• Bronchoscopy
• Steroids: no benefit
• Prophylactic antibiotics: no benefit
• Surfactant: no benefit

Recommendations
• Pre-hospital resuscitation, including early intubation,
ventilation, vascular access, and administration of
advanced life support medications
• Continued resuscitation and stabilization in the ED
• Full supportive care in the ICU for a minimum of 48 hrs
• ECMO?
• Consider withdrawal of support if no neurologic
improvement is detected after 48 hours
– Ancillary testing such as brainstem evoked responses, EEG,
and MRI (not CT) may prove helpful to corroborate the
neurologic examination

Prognosis
• Better outcomes associated with early CPR
(bystander)
• C-spine protection
• Transport
– Continue effective CPR
– Establish airway
– Remove wet clothes
– Hospital evaluation

Outcome Predictors
• Poor outcomes
– Age < 3yrs
– Submersion time: >10 min
– Time to BLS >10 min
– Serum pH: <7.0
– CPR >25 min
– Initial core temp <33°C
– GCS <5
– Lactic acid >6 mmol/L

Neurologic Prognosis
• Absence of spontaneous respiration is an
ominous sign associated with severe
neurologic sequelae
• Permanent neurologic sequelae persists in
~20% of victims who present comatose

Outcome Predictors
• Submersion time
• Water Temperature
• Bystander CPR
• EMS response time

Outcome Predictors
• Prolonged resuscitation may increase the
success of resuscitation without normal
neurologic recovery
→ After 25? min of full but unsuccessful
resuscitation, think “PROGNOSIS”

In Conclusion
Prevention is Key!

How to avoid Drowning or submerging in.pdf

How to avoid Drowning or submerging in.pdf

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