Thermal Injuries - Clinical Tree

Key Concepts

After removing the patient from the source of injury, burns should be cooled with room temperature water while avoiding hypothermia in patients with large burns.
Clinical signs such as facial burns, hoarseness, drooling, carbonaceous sputum, and singed nasal hairs indicate inhalation injury; however, they are poor predictors of injury severity.
Confirmation of inhalation injury is best accomplished by direct visualization of the glottic inlet via flexible or rigid video laryngoscopy augmented by topical anesthesia and judicious sedation, when necessary.
Worsening hoarseness, edema, or soot in the supraglottic region necessitates immediate intubation.
Supplemental oxygen should be given in patients with suspected inhalation injury and determination of carbon monoxide levels should be performed.
Crystalloid resuscitation is required to support vital organ perfusion and is guided by urine output. Care should be taken to avoid over-resuscitation.
Pain relief is required for larger burns and is accomplished through both pharmacological and non-pharmacological methods. Pain levels should be assessed frequently.
Patients with large body surface area burns (>20% for adults and >10% for children and the elderly) or deep burns will require admission to a burn center. Most other patients presenting to the ED will have small and superficial burns that can be managed with over-the-counter or commercially available topical agents.

Foundations

Background and Importance

Thermal injuries, which consist of fire or flame injuries, scald injuries, and contact with hot object injuries, are common in the emergency department (ED). Cooling, assessment of percent total body surface area (% TBSA), depth of tissue involvement, pain control and local wound care is generally all that is necessary for minor burns. For treatment of major burns, early management of airway, breathing, and circulation as well as continuous reassessment of burn depth are essential. Careful wound care to minimize the advancement of burns to greater thickness and prevent infection is imperative.

Burn injuries result in significant morbidity and mortality worldwide. According to the World Health Organization (WHO), burn injuries result in more than 10 million disability adjust life years (DALYs) lost and more than 150,000 deaths each year, 90% of which are in low- and middle-income countries. In the United States alone, there were approximately 560,000 visits to EDs for injuries or burns related to fire or a hot object or substance in 2016. Data from burn admissions in the United States between 2008 and 2017 show that more than 67% of burns were less than 10% TBSA. The overall mortality rate was 3.1%; however, flame and fire injuries had an overall mortality rate of 5.6%. Patients aged 1 to 15 years comprised more than 23% of the total burns, adults aged 20 to 59 years comprised 55% of burns, and patients age 60+ year comprised 15%. Fire and flame injuries, scalds, and contact injuries account for more than 85% of cases, with scalds being most common in children under five, and fire or flame most common in other age groups. Burn injuries occur most often in men (67%) and at home (74%). Only 13% are work related, and 95% are accidents. Patients are more commonly Caucasian/White (59%).

Deaths from burn injury increase with increased burn size, presence of inhalation injury, and advanced age. Pneumonia is the most common complication and is more common in patients requiring four or more days of mechanical ventilation. The hospital length of stay (LOS) is estimated as just over 1 day per percent TBSA. Overall, the burnt surface area associated with a 50% case fatality (LD-50) is 70% TBSA. However, this drops to 40% to 50% TBSA at age 55, 30% to 40% at age 60, and 20% to 30% at age 65 and older. ^,

Anatomy, Physiology, and Pathophysiology

The skin is the largest organ of the human body and serves as a barrier between the internal and external environments minimizing fluid losses and microbial invasion. It is comprised of seven layers: five in the epidermis (serving as the protective layer or barrier) and two in the dermis (containing structures that provide thermoregulation, water balance, immune surveillance, sensation, and most of the mechanical properties of the skin). The hypodermis, or subcutaneous tissues, are not a part of the skin, but contain subcutaneous fat and connective tissue that serve to connect the skin to the underlying structures. The thickness and resiliency of the skin depends on the location on the body (thickest on the sole of the foot, thinnest on the eyelid) as well as an individual’s age, with peak skin thickness occurring in the middle age. Damage or loss to the skin can result in significant volume loss, thermo-dysregulation, and possible infection.

Pathophysiology of Burns

Thermal burns are the result of exposure of body surfaces to energy in the form of heat. The extent of injury is directly related to the integrity of the skin or epithelial surface, temperature of the offending agent, and duration of exposure. Higher temperatures (starting as low as 41°C) result in denaturing of cellular proteins and coagulative necrosis. ^,

Cutaneous Injury

The classical three zones of burn injury to the skin include the central zone of coagulation or irreversible necrosis, the intermediate and potentially reversible zone of stasis or ischemia, and the peripheral reversible zone of hyperemia or inflammation.

The exact cellular-level of pathophysiology in the different zones is not entirely known, however it involves mechanisms of necrosis or necroptosis that result in significant inflammatory responses as well as autophagy—which, may have a protective effect—and either early or delayed apoptosis, that results in cellular loss, but with less inflammatory response. ^, ^, All of these mechanisms result in immediate loss of skin tissue and play a role in burn injury progression if not managed both in the ED and throughout the three phases of wound healing: the inflammatory phase , the proliferative phase , and the remodeling phase .

Thermal injury not only sets into motion a cascade of local events, but also results in systemic responses, especially in larger burns. Local processes include inflammation, activation, and aggregation of immune cells. Additionally, this causes microthrombosis with ischemia as a result of endothelial damage, vasoconstriction, dilation, edema, and reperfusion with production of reactive oxygen species and toxic cytokines. Systemic processes not only include inflammatory, cytokine, and immunologic responses, but also metabolic and endocrine responses.

Burn shock is characterized by macro- and microcirculatory impairment and cellular damage, both at the site of injury and throughout the body. The initial resuscitation phase (hypodynamic or ebb phase) occurs within the first 24 to 72 hours and involves cytokine and inflammatory pathway activation as well as systemic circulation of reactive oxygen species, leading to diffuse alterations of transmembrane potentials, plasma extravasation, and edema. This process has either a biphasic pattern—most severe in the first hour and then again at 12 to 24 hours post-burn—or single peak with the most significant manifestations in the first eight hours followed by a slow but steady reduction over the following 16 hours. Subsequently, there is increased vascular resistance, reduced cardiac output, and diffuse end-organ damage. ^, ^, ^, Given the resulting hypoproteinemia and capillary leak, an imbalance between oncotic and hydrostatic forces develop, making resuscitation essential at this stage. The second phase is the hyperdynamic or hypermetabolic flow phase that begins 24 to 72 hours post-injury. As vascular permeability and systemic vascular resistance drop, heart rate and cardiac output increase and metabolic rates can rise two- to three-fold. ^, Additional systemic effects include impaired immunity, insulin resistance, renal and hepatic dysfunction, increased serum triglycerides and free fatty acids, muscle wasting, bowel mucosa degradation with reduced absorptive capacity, and hormonal changes, including reductions in growth hormone, TSH, T3, T4, and testosterone. ^, ^,

Inhalation Injury

The incidence of inhalation injury with thermal burns is approximately 6%, however incidences range from 2% in smaller burn injuries to nearly 60% in larger burn injuries and burns to the face. ^, It can occur with or without cutaneous burns, and, after age and TBSA, it is the most important predictive factor of mortality and is associated with a nearly threefold increase in mortality and a decrease in the LD-50 by 25% in certain population groups. ^,

Inhalational injury is caused by thermal injury to the upper airway and chemical injury to the lower airway. Additionally, systemic toxicity occurs from inhalation of substances such as carbon monoxide and cyanide. Heat can stimulate the glottic closure reflex resulting in rapid asphyxiation and death. At the cellular level, the effect of thermal injury on the upper airway is similar to the pathophysiologic cutaneous response with inflammation, including activation and aggregation of immune cells as well as ischemia, followed by edema and reperfusion injury. Progressive airway edema after significant thermal injury is predictable and may threaten airway patency within hours of initial presentation. Additional complications can occur in the first 24 to 48 hours such as bronchoconstriction, ulceration and hemorrhage, pseudomembrane formation, loss of surfactant, and impaired ciliary transport. These can lead to ventilation/perfusion (V/Q) mismatch, decreased lung compliance, obstruction, barotrauma, increased dead space ventilation, and infection.

Clinical Features

You're Reading a Preview

Become a Clinical Tree membership for Full access and enjoy Unlimited articles

Become membership

If you are a member. Log in here