Burn Care Procedures - Clinical Tree

Two million people suffer a burn-related injury every year in the United States. The American Burn Association (ABA) estimates that almost 500,000 of these patients received medical evaluation and treatment in 2014 and approximately 40,000 required hospitalization. According to the 2014 National Burn Repository, patients who suffer burn injuries are predominately male (69%), and their mean age is 32 years old. Children younger than 5 years account for 19% of burns, and patients older than 60 years account for an additional 13%. Seventy-four percent of all burns involve less than 10% of the total body surface area (TBSA). Nearly 80% of all burns are caused by flame or fire or by scalds, with scald injury occurring most in children younger than 5 years.

Overall, the incidence of burn injury has declined in recent decades and advances in medical care have improved the morbidity and mortality of burn patients. Enhancements in resuscitation, surgical and anesthetic techniques, intensive care, infection control, nutrition, and metabolic support have all contributed to dramatic improvements in the survival, preservation of body function, physical appearance, and emotional outcomes of patients with this injury. The initial care provided to burn patients by emergency medical providers can improve outcomes by preventing the conversion of superficial burns to deep burns requiring surgery and by improving the long-term functional and cosmetic outcomes of the affected tissues.

The classification of burns is based on three criteria : depth of skin injury, percentage of TBSA involved, and source of injury (thermal, chemical, electrical, or radiation). The seriousness of a burn injury is determined by the characteristics and temperature of the burning agent, the duration of exposure, the location of the injury, the presence of associated injuries, and the age and general health of the victim ( Table 38.1 ).

TABLE 38.1

Characteristics of Burns, by Depth

Modified after Clayton MC, Solem LD: No ice, no butter: advice on management of burns for primary care physicians, Postgrad Med 97:151, 1995; Morgan ED, Bledsoe SC, Barker J: Ambulatory management of burns, Am Fam Physician 62:2015, 2000.

CLASSIFICATION OF BURN	ETIOLOGY	APPEARANCE	SENSATION	TIME TO COMPLETE HEALING	SCARRING
First Degree
Superficial epidermal layers	Sunburn, other UV exposure Short flash flame burns	Dry, red Blanches with pressure	Present May be quite painful	3–7 days	No
Second Degree
Varying depth, blisters, or bullae formation
Dermal appendages spared (e.g., sweat glands, hair follicles)
Includes entire epidermis and some portion of the dermis
Superficial partial thickness	Water scald Longer flash burn	Blisters, peeling skin Blanches with pressure Skin red and moist under blisters	Painful Exposure to air and temperature painful	7–21 days	Unusual if no infection and proper follow-up Pigment change may be seen Burned area may be sensitive to frostbite, windburn, and sunburn for many months Itching may be problematic for weeks after healing
Deep partial thickness	Flame Water immersion Oil, grease, hot foods (e.g., soup)	Variable color Wet or waxy dry, does not blanch Blisters easily removed, skin peeling off	Pressure only	>21 days	Severe; risk for contracture
Third Degree
Loss of all skin elements, thrombosis and coagulation of vessels	Flame, steam, oil grease Immersion, scald Caustic chemical, high voltage	Leathery appearance, white or charred, dry, inelastic; blanching with pressure May be present under blisters	Deep pressure only	Never heals Requires grafting	Very severe, high risk for contracture

UV, Ultraviolet.

The ABA defines minor burns as uncomplicated partial-thickness burns involving less than 5% TBSA in children (<10 years old) or the elderly (>50 years old), less than 10% TBSA in adults, or full-thickness burns less than 2% TBSA. Moderate or major burns include injuries that involve a greater TBSA, as well as burns in areas of specialized function, such as the face, hands, feet, and perineum. More serious burns also include those caused by a high-voltage electrical injury or those with associated inhalation injuries or other major trauma.

Throughout the course of history, clinicians have experimented with burn therapies to relieve pain and promote healing. Many treatment regimens and home remedies have been successful, largely because minor burns generally do well with a modicum of intervention and commonsense wound care. Although little has changed in the care of minor ambulatory burns over the past 3 decades, treatment of major burns has significantly improved, including the development of sophisticated burn centers, increased knowledge of burn wound physiology, and prevention of infection.

Wound Evaluation

Emergency clinicians should be aware that the depth of a burn wound cannot always be determined accurately on clinical grounds alone at initial evaluation and that burn injury is a dynamic process that may change over time, particularly during the 24 to 48 hours after the burning process has been arrested. It is common, for example, for a seemingly minor or superficial burn to appear deeper on the second or third return visit ( Fig. 38.1 ). This phenomenon is not a continuation of the burning process that can be altered by clinician intervention but is considered to be a pathophysiologic event related to tissue edema, dermal ischemia, or desiccation.

Figure 38.1, It may be difficult to accurately assess the depth or severity of a burn on the first visit. A, This full-thickness burn will not heal without a skin graft. B, This blistered hot water burn is probably second degree, but full-thickness burns can develop under blisters. C, At 2 weeks, a second-degree burn and a small area of third-degree burn (arrows).

Estimating Burn Depth

The depth of a burn has historically been classified by degree. First degree involves the epidermis only, second-degree (or partial-thickness) burns extend into the dermis, and third-degree (or full-thickness) burns destroy the entire skin. An additional fourth degree is sometimes used to describe injuries to the underlying muscle, tendon, or bone ( Fig. 38.2 ).

Figure 38.2, Depths of a burn. First-degree burns are confined to the epidermis. Second-degree burns extend into the dermis (dermal burns). Third-degree burns are full thickness through the epidermis and dermis. Fourth-degree burns involve injury to underlying tissue structures such as muscle, tendons, and bone.

First-degree burns involve the epidermis only ( Fig. 38.3 A ). The skin is reddened but is intact and not blistered. This injury ranges from mildly irritating or even pruritic to exquisitely painful. Minor edema may be noted. Causes include ultraviolet light (as in sunburn) and brief thermal “flash” burns. First-degree burns may blister within 24 to 36 hours, and the patient should be warned about this possibility. Frequently, the epidermis may flake or peel within 5 to 10 days. Healing occurs spontaneously, usually without scarring.

Figure 38.3, Depth of thermal injury. A, Patient with sunburn on the lower extremity (a superficial or first-degree burn with associated blisters on the anterior tibial surface). B, Partial-thickness injury of the hand (superficial second-degree burn). C, Partial-thickness injury extending beyond the subcutaneous layers (deep second-degree burn). D, Full-thickness (third-degree) burn. E, Full-thickness injury with extensive tissue loss (fourth-degree burn).

Second-degree burns involve the epidermis and extend into the dermis to include the sweat glands and hair follicles. Superficial second-degree burns involve only the papillary dermis (see Fig. 38.3 B ) . These burns are pink, moist, and extremely painful. Blisters are common and the skin may slough. The burn blanches with pressure, and mild to moderate edema is common. Hair follicles often remain intact. Superficial second-degree burns are the most common burns seen in the emergency department (ED). The usual causes are scalds, contact with hot objects, or exposure to chemicals. Barring infection or repeated trauma, these burns heal spontaneously and without scarring in approximately 2 weeks. These areas may be sensitive to sunburn, windburn, and skin irritation for months after the original injury has healed.

Deep second-degree burns involve the reticular dermis and appear mottled white or pink (see Fig. 38.3 C ). There is obvious edema and sloughing of the skin, and any blisters are usually ruptured. Blanching is absent. These burns are not generally painful initially and may have decreased sensation, but pressure may be perceived. Within a few days, however, these burns can become exquisitely painful. This type of burn may be converted to a full-thickness injury by further trauma or infection.

Third-degree burns result from complete loss of the dermis and may extend into subcutaneous (SQ) tissue (see Fig. 38.3 D ) . These burns usually appear dry, pearly white, or charred. They are initially painless, with a leathery texture. Circumferential third-degree burns on an extremity or the torso cause a loss of elasticity that may impair the circulation or ventilation and necessitate an escharotomy.

Fourth-degree burns extend deeply into SQ tissue, muscle, fascia, or bone (see Fig. 38.3 E ) . These burns are characteristically caused by contact with molten metal, flame, or high-voltage electricity.

A more practical method of classifying burns is to describe them as either superficial or deep because this approach defines both treatment and prognosis. In general, first- and second-degree burns are considered partial-thickness burns, whereas third- and fourth-degree burns are full-thickness burns. As such, superficial burns involve the papillary dermis, with its rich vascular plexus, and the epidermis, which permits spontaneous healing by reepithelialization from the dermal appendages, including hair follicles, sebaceous glands, and sweat glands. This usually occurs within 2 weeks with minimal scarring. Superficial burns appear wet, pink, and blistered and blanch with pressure. They are painful. Deep burns involve the reticular dermis and SQ fat and generally lack sufficient epithelial appendages for spontaneous healing. If healing does occur, it will occur slowly and produce unstable skin, hypertrophic scarring, and contracture. Deep burns are best treated by excision and skin grafting. The initial appearance of deep burns ranges from cherry red, mottled, white, and nonblanching to leathery, charred, brown, and insensate ( Table 38.2 ).

TABLE 38.2

American Burn Association's Grading System for Burn Severity and Disposition of Patients ^a

Adapted with permission from hospital and prehospital resources for optimal care of patients with burn injury: Guidelines for development and operation of burn centers: American Burn Association, J Burn Care Rehabil 11:98, 1990; with additional information from Hartford CE: Care of outpatient burns. In Herndon DN, editor: Total burn care, Philadelphia, 1996, Saunders p 71 .

	Type of Burn
	Minor	Moderate	Major
Criteria	<10% TBSA burn in adult	10%–20% TBSA burn in adult	>20% TBSA burn in adult
	<5% TBSA burn in young or old	5%–10% TBSA burn in young or old	>10% TBSA burn in young or old
	<2% full-thickness burn	2%–5% full-thickness burn	>5% full-thickness burn
		High-voltage injury Suspected inhalation injury Circumferential burn Concomitant medical problem predisposing the patient to infection (e.g., diabetes, sickle cell disease)	High-voltage burn Known inhalation injury Any significant burn involving the face, eyes, ears, hands, feet, genitalia, or joints Significant associated injuries (e.g., fracture, other major trauma)
Disposition	Outpatient management	Hospital admission vs. higher-level, structured outpatient care	Consider referral to a burn center ^b

TBSA, Total body surface area (percentage) affected by the injury.

a Burn, partial-thickness or full-thickness burn, unless specified; young, patient younger than 10 years; adult, patient 10 to 50 years of age; old, patient older than 50 years.

b Decision to refer to a burn center is according to physician judgment on a case-by-case basis. The above list are guidelines set by the ABA for consideration for referral.

Although bedside evaluation of very superficial or deep wounds presents little diagnostic difficulty, clinical assessment of a mid-dermal or “indeterminate” burn is accurate only approximately two-thirds of the time. Even though it is useful to initially characterize the extent of the burn, it must be noted that the early appearance of a burn wound may not accurately reflect the true extent of the soft tissue injury. Reexamination and follow-up are critical because burn wounds may change during the 24 to 72 hours following injury. Indeterminate burns may eventually heal spontaneously, or they may convert to deeper wounds requiring excision and skin grafting (see Fig. 38.1 ).

Estimating Burn Size

Calculating burn size is necessary to determine treatment plan, fluid requirements, and aids in prognosis. It is important for the emergency provider to accurately estimate the burn size. Note that first-degree burns do not count in the calculation of total burn surface area when utilizing fluid resuscitation formulas. Overestimating the burn size is a common error, especially in children. Several formulas are available to estimate TBSA in burn patients. In 1944, Lund and Browder published the now famous Lund-Browder chart ( Fig. 38.4 ). In their landmark paper, they used direct measurements and body surface area formulas to produce a chart that clinicians can use to estimate %TBSA. Burn centers typically utilize the Lund-Browder chart for estimating burn size. The initial Lund-Browder chart was developed from human anatomic studies derived from 11 adults (3 women and 8 men) and produced a unisex chart. A 2004 study involving 60 volunteers determined that the Lund-Browder chart significantly underestimates the size of chest burns in large-breasted women. The investigators developed a table that incorporates a correction using brassiere cup size.

Figure 38.4, Lund-Browder charts. A, The Lund-Browder charts are somewhat more accurate than the rule of nines in estimating the total body surface area (TBSA) burned. B, Proportion of TBSA of individual areas according to age. When compared with adults, children have larger heads and smaller legs. Other areas are relatively equivalent throughout life. The rule of nines is not accurate in determining the percentage of TBSA burned in children.

The simplest method for estimating TBSA in adults is the “rule of nines.” This formula was developed in the late 1940s by Pulaski and Tennison, who observed that the percentage of each body segment was approximately a multiple of nine ( Fig. 38.5 ). Similar formulas for children adjust estimates for their disproportionately large head surface area. However, in a study of obese patients it was determined that this formula underestimates %TBSA of the legs and torso and overestimates %TBSA of the arms and head. The authors suggested replacing the “rule of nines” with a “rule of fives” for obese patients heavier than 80 kg.

Figure 38.5, The “rule of nines.” The rule of nines is a rough estimate of the total body surface area (TBSA) burned. Note that adults and children are different. This formula frequently overestimates the extent of a burn in clinical practice. As a rough guide, the area covered by the individual's palm is approximately 1.25% TBSA. See Fig. 38.4 for a more accurate method of determining TBSA burned in children.

The size of a burn can also be estimated by using the patient's hand as representing approximately 1% TBSA. With this method, the hand is a rectangle. However, two studies using planimetry have determined that the hand actually represents from 0.5% to 0.78% of a patient's TBSA.

Regardless of the method used, it is important for the emergency provider to take time to quantify the %TBSA as accurately as possible. It should be reemphasized that fluid recommendations based on %TBSA DO NOT include first-degree burns in the %TBSA, rather they are based on %TBSA of second- and third- (and fourth-) degree burns. Including first-degree burns in the calculation of %TBSA results in an overestimate of the total burned areas, and is a common error.

Histopathology of Burns

One thermal wound theory describes three zones of injury in burns ( Fig. 38.6 ) :

1.
Zone of coagulation: dead, avascular tissue that must be débrided.
2.
Zone of stasis: injured tissue in which blood flow is impaired. Desiccation, infection, or mechanical trauma may lead to cell death.
3.
Zone of hyperemia: minimally injured, inflamed tissue that forms the border of the wound. The hyperemia usually resolves within 7 to 10 days but may be mistaken for cellulitis.

Histologically, full-thickness burns are characterized by confluent vascular thrombosis involving arterioles, venules, and capillaries. Edema secondary to loss of microvascular integrity results not only from the effects of direct thermal injury but also from the release of vasoactive mediators. The increase in vascular permeability is linked to activation of complement and release of histamine. Histamine increases catalytic activity of the enzyme xanthine oxidase, with resultant production of hydrogen peroxide and hydroxyl radicals. These by-products increase the damage to dermal vascular endothelial cells and result in progressive vascular permeability.

Figure 38.6, Zones of injury after a burn. The zone of coagulation is the portion that is irreversibly injured. The zones of stasis and hyperemia are defined in response to the injury.

The cellular debris and denatured proteins of the eschar provide a milieu that supports the proliferation of microorganisms. The devitalized tissue (eschar) sloughs spontaneously, usually as a result of the proteolytic effect of bacterial enzymes. The greater the degree of wound bacteriostasis, the greater the delay in sloughing.

Partial-thickness burns result in incomplete vascular thrombosis, usually limited to the upper dermis. The dermal circulation is restored gradually, generally over a period of several days, thus resulting in a significant interval of relative ischemia. The eschar in deep partial-thickness burns is thinner than in a full-thickness burn and sloughs as a result of reepithelialization rather than bacterial proteolysis.

Outpatient Versus Inpatient Care

One of the first steps in minor burn care is to select patients for whom outpatient care is appropriate. For patients determined to require inpatient care, the decision to admit or transfer the patient depends on the burn care capabilities of the initial treating facility. Guidelines set forth by the ABA regarding criteria for referral to a burn center are listed hereafter. Burn injuries that should be considered for referral to a burn center include the following:

1.
Partial thickness burns greater than 10% TBSA
2.
Burns involving the face, hands, feet, genitalia, perineum, or major joints
3.
Third-degree burns in any age group
4.
Electrical burns, including lightning injury
5.
Chemical burns
6.
Inhalation injury
7.
Burn injury in patients with preexisting medical disorders that could complicate management, prolong recovery, or affect mortality
8.
Any patient with burns and concomitant trauma in which the burn injury poses the greatest risk for morbidity or mortality after emergency or surgical stabilization of the traumatic injuries. In such cases if the trauma poses the greatest immediate risk, the patient's condition may be stabilized initially in a trauma center before transfer to a burn center. Physician judgment will be necessary in such situations and should be in concert with the regional medical control plan and triage protocols.
9.
Burned children in hospitals without qualified personnel or equipment for the care of children
10.
Burn injury in patients who will require special social, emotional, or rehabilitative intervention

Note, the previously-mentioned guidelines are not absolute clinical mandates and clinical judgment and patient characteristics may allow certain patients listed in these categories to be treated appropriately without transfer to a burn center. If in doubt, the decision to admit a patient with an acute burn injury is rarely inappropriate. Candidates who can be considered for outpatient treatment are generally adults and children meeting the ABA criteria for minor burn criteria. Burns usually better managed initially on an inpatient basis are large or deep burns involving the hands, face, feet, neck, or perineum; burns resulting from abuse or attempted suicide; burns occurring in association with other trauma or inhalation injuries; and chemical or electrical burns.

Patients who are at risk for poor outcomes with even minor burns include patients with concomitant medical problems such as diabetes mellitus, peripheral vascular disease, congestive heart failure, and end-stage renal disease; patients taking steroids or other immunosuppressive agents; patients who are very young or very old; those who are mentally impaired or have drug and alcohol dependency; homeless persons; those who are malnourished; and patients without a sufficient home support system. Whereas very minor burns in these patients may still be treated appropriately in the outpatient setting, inpatient treatment might be necessary in these circumstances even though the burn might be considered “minor” by ABA criteria. Other admission considerations include pain control, the ability to return for follow-up care, the degree of incapacity, the ability to receive wound care at home, and the overall social situation; all should influence the final decision of whether admission or transfer is warranted.

Additional guidelines that can guide emergency providers in determining the need for admission following an acute burn injury include the following:

1.
Patients requiring intravenous (IV) access. Following a burn there is an immediate capillary leak of plasma-like fluid that can last for 18 to 24 hours. In burns involving greater than 20% TBSA, the leak occurs in both burned and nonburned tissues. If not replaced, this fluid loss can lead to hypovolemic shock and renal failure. IV fluid resuscitation is indicated for all patients with second- and third-degree burns greater than 10% TBSA, in patients younger than 10 or older than 50 years, and for burns greater than 20% TBSA in all other age groups.
2.
Anticipated surgery. Deep burns are best treated by early surgical excision and skin grafting. This permits faster wound healing, provides more stable skin, and reduces contractures. Hospital admission facilitates wound care and preparation for surgery.
3.
Respiratory problems. Patients with respiratory distress requiring oxygen therapy and those suspected of inhaling toxic fumes or vapors should be admitted for observation or intubation and for mechanical ventilation ( Box 38.1 ). Direct bronchoscopic evaluation of the airway may assist in the evaluation and diagnosis of tracheobronchitis or pneumonitis from a smoke inhalation injury.
Box 38.1

General Approach to Blisters With Minor Burns ^a

a All blisters and burned skin are débrided in the presence of infection. Note: Multiple approaches to blisters are acceptable, and practice varies considerably.
If Treated Less Than 48 Hours After the Burn
- 1.
  Leave all intact blisters alone.
- 2.
  If blisters have ruptured, treat them as dead skin and débride them completely.
- 3.
  Needle aspiration of blisters is not advised.
On Follow-Up or More Than 48 to 72 Hours After the Burn
- 1.
  Débride large (>6 cm in diameter) intact blisters and all blisters that have ruptured. Large, firm blisters on the palms and soles may be left intact longer. Do not aspirate blisters.
- 2.
  Do not débride small or spotty blisters until they break or until 5 to 7 days after the burn.
Five to 7 Days After the Burn
- 1.
  Débride all blisters completely.
Note: Intact blisters provide significant pain relief. Be prepared for an exacerbation of pain immediately after débridement. Prophylactic analgesia is recommended.
4.
Need for special nursing care. Specialized wound care, dressings, and nursing care are often required for burns involving the face, hands, feet, perineum, and genitalia and may best be treated on an inpatient basis if outpatient care is not feasible or ideal based on the case specifics. Patients unable to care for themselves or those lacking family and friends able to assist them may also require admission.
5.
Special burn injuries. Chemical injuries are often more severe than the initial examination would suggest. Unlike thermal burns, tissue destruction may continue many hours after injury. Patients with chemical injuries should be admitted whenever the injuries are of indeterminate depth, affect a large area, or are deep and require surgical excision or if there are systemic manifestations of chemical toxicity or when the chemical responsible for injury requires a specific antidote. Swelling from deep circumferential burns may constrict the chest or limbs and result in compartment syndrome. Such burns should be monitored frequently to determine the potential need for escharotomy or fasciotomy ( Fig. 38.7 ). Whenever the patient's condition prevents a reliable clinical examination, direct measurement of compartment pressures can provide an objective measurement of intracompartmental pressure and assist in the decision to perform these surgical procedures (see Chapter 54 ). Adult and pediatric patients with extensive burn injuries that require fluid resuscitation with large volumes of crystalloid should be monitored closely for the development of abdominal compartment syndrome. Patients with mechanical burns involving large areas of skin loss or with significant frostbite injuries are often admitted for specialized wound care and parenteral pain management. Patients with certain electrical injuries may require admission for cardiac monitoring, specialized wound care, or IV fluids.

Procedure

Emergency Treatment

Home or field treatment and ED care overlap. Initial treatment of a thermal injury begins immediately following the burn. If safe to do so, patients should be rapidly removed from the source of injury. Flames are extinguished by smothering the fire with a blanket, jacket, or equivalent item; by dousing the fire with water; or by using a chemical fire extinguisher. Most chemical injuries are best treated by irrigating the affected area with copious quantities of clean water. Patients with electrical injuries are removed from contact with the electrical source as soon as it is safe to do so.

Cooling is most beneficial for small burns if started within 3 minutes of injury and possibly of additional benefit if continued for the first few hours after the burn. Doing so has been shown to reduce pain significantly and can limit tissue damage by decreasing thromboxane production. When cooling a burn wound, it is important to avoid hypothermia or freezing of tissue because this may deepen the injury. At home or in the field, room-temperature or cold tap water irrigation, immersion, or compresses (20°C to 25°C) will provide some pain relief without the risk of further injuring burned tissues and inducing hypothermia, which can occur with iced solutions ( Fig. 38.8 ). Placing ice on a burn should not be done. Sterile dressings are not required for field treatment; a moist towel or nonadherent sheet may be used. Nonmentholated shaving cream makes an excellent temporary covering for out-of-hospital use if a dressing is not available. Home remedies, such as butter or Vaseline, are best avoided but are probably benign. Remove jewelry and gross debris in the field if possible.

Figure 38.8, To cool a burn that cannot easily be immersed in water, cover the area with unfolded gauze pads that have been soaked in room-temperature saline. Continue to frequently soak the gauze with cool saline or tap water drawn up in a syringe. Adding a few ice chips to the liquid is helpful, but do not cover the burn with ice. Towels are generally too bulky for this procedure. Narcotics are the best way to control pain in any burn, and should be used liberally.

Initial Care of Major Burns

Major burns require the specialized resources of a burn center. In such cases, emergency providers should initiate the resuscitation, consult the burn center for referral, and transfer the patient as soon as practically possible. Initial resuscitation should follow standardized trauma protocols, including a primary and secondary survey, and provide immediate interventions directed at airway management, breathing, and cardiovascular support, as needed. IV catheters can be inserted initially through burned skin when unburned sites are unavailable. Early IV access permits the administration of resuscitative fluids, medications, and parenteral narcotics to relieve the pain. Patients with burns exceeding 20% TBSA should receive IV fluid resuscitation with lactated Ringer's (LR) solution based on various available formulas. LR solution is preferred because large saline infusions will produce hyperchloremic acidosis. One need not use bolus fluid resuscitation as fluids are lost via capillary leak and via the raw skin, and significant fluid loss does not occur within the first hour.

Historically, the Parkland or Brooke formulas have been used to estimate fluid needs. It should be noted that the 2011 Advanced Burn Life Support (ABLS) Manual specifies that research has shown that the Parkland formula's 4 mg/kg × %TBSA formula commonly results in excessive edema formation and over-resuscitation. Whether this is because first-degree burns may have been erroneously included in the %TBSA or other reasons is unclear. For adults the ABLS advises a total of 2 mL LR × body weight in kilograms × % second- and third-degree burns in the first 24 hours. For pediatric patients (under age 14 and weight less than 40 kg), the ABLS advises a total of 3 mL LR × body weight in kilograms × % second- and third-degree burns in the first 24 hours. It should be noted that 24 hours starts at the time of the burn and not the time medical care begins. After the total amount is calculated, fluids should be administered as a constant infusion rather than by bolus administration. Half of the calculated fluid requirement should be given in the first 8 hours and the remaining half provided over the following 16 hours ( Box 38.2 ). Lastly, these fluid quantities are guidelines and urine output monitoring will assist in adjusting the rate or volume to meet the target outputs of 0.5 mL/kg per hour for adults and 1 mL/kg per hour for children weighing under 40 kg. According to the ABA, Foley catheter placement is advised in major burns to accurately monitor urine output.

Box 38.2

ABA ABLS Initial Fluid Recommendations for Burn Patients in First 24 Hours

1.
Lactated Ringer's (LR) is the fluid of choice.
2.
Estimate %TBSA (count second and third degree only)
3.
Obtain actual body weight in kilograms.
4.
Utilize appropriate formula as detailed below:
- Adults with Thermal and Chemical Burns:
  
  2 mL LR × patient's body weight in kg × %TBS A (second and third degree only)
- Children 14 years or younger and body weight of less than 40 kg
  
  3 mL LR × child's weight in kg × %TBSA (second and third degree only)-add normal maintenance fluid to the fluid requirements, consider including dextrose in maintenance fluids for infants and young children who may rapidly deplete glycogen stores, particularly for those 2 years and younger.
- Adult patients with High Voltage Electrical Injuries
- If there is evidence of deep tissue injury or red pigments in urine use:
  
  4 mL LR × patient's body weight in kg × %TBS A (second and third degree only)
5.
Infuse half of the calculated 24-hour fluid needs in the first 8 hours following the burn. Infuse the second half of the 24-hour fluid needs in the next 16 hours (hours 9–24)
6.
Increase or decrease the fluid rate based on the patient's urine output (and pigment). Adjust fluids to maintain urine output at 0.5 mL/kg per hr in adults and 1 mL/kg per hr in children.

ABA, American Burn Association; ABLS, advanced burn life support; TBSA, total body surface area.

More recently, the US Army Institute of Surgical Research has advocated a simpler formula for estimating hourly fluid requirements in burn patients. This simpler formula may be more useful for prehospital providers or ED resuscitation ( Box 38.3 ). The formulas estimate hourly fluid requirements and must be adjusted up or down to achieve a urine output of 0.5 to 1.0 mL/hr. Insertion of a Foley catheter is usually necessary to accurately measure hourly urine output.

Box 38.3

From Chung KK, Salinas J, Renz EM, et al: Simple derivation of the initial fluid rate for the resuscitation of severely burned adult combat casualties: in silico validation of the rule of 10, J Trauma 69:S49–S54, 2010.

Simplified ED Burn Fluid Resuscitation: the Rule of 10

1.
Estimate burn size (%TBSA) to the nearest 10.
2.
%TBSA × 10 = initial fluid rate in mL/hr (for adult patients weighing 40 to 80 kg).
3.
For every 10 kg above 80 kg, increase the rate by 100 mL/hr.

ED, Emergency department; TBSA, total body surface area.

Patients exposed to carbon monoxide should have carboxyhemoglobin levels measured and empirically receive 100% oxygen. The duration of oxygen administration will depend on the level and symptoms of the individual patient, but often require 6 hours or more. Once considered a traditional empirical treatment, there is no evidence-based proven benefit from hyperbaric oxygen therapy for carbon monoxide poisoning. A Cochrane review ( http://www.summaries.cochrane.org/CD002042 ) concluded that there is insufficient evidence to support the use of hyperbaric oxygen for the treatment of patients with carbon monoxide poisoning. The Cochrane review of published trials found conflicting, potentially biased, and generally weak evidence regarding the usefulness of hyperbaric oxygen for the prevention of neurologic injury. Per an evidence-based analysis, existing randomized trials do not establish whether the administration of hyperbaric oxygen to patients with carbon monoxide poisoning reduces the incidence of adverse neurologic outcomes. Because there may still be advocates of hyperbaric oxygen therapy, consultation with a local hyperbaric center is reasonable in certain cases, but it is not standard that this intervention be routinely implemented. Critically ill and pregnant patients are still often offered hyperbaric treatment, but controversy over the efficacy and safety persists even for these subgroups.

Cyanide is released from mattress fires and burning of upholstery. Patients suspected of having been exposed to significant levels of cyanide and manifesting symptoms should receive hydroxocobalamin (Cyanokit [Meridian Medical Technologies, Inc., Columbia, MD]). If not available, the Cyanide Antidote Package may be used despite lack of proven benefit of this traditional cyanide therapy. It is reasonable to empirically administer hydroxocobalamin or the sodium thiosulfate portion of the cyanide kit to burn victims in coma or to those exhibiting metabolic (lactic) acidosis after smoke exposure.

In addition to the logical increased mortality with larger areas of TBSA involved, the mortality of patients with burns is also increased when concomitant inhalation is present. The Baux Score was developed a half-century ago by Professor Serge Baux to estimate the mortality of burns. This score was updated in 2010 using data from the National Burn Registry to include the effect of inhalation injury to mortality ( Box 38.4 ). In short, the original Baux score became outdated because advances in care of the burn victim which has improved the mortality of patients. The modified Baux score is now more accurate for modern burn survival rates.

Box 38.4

From Baux S: Contribution a l'Etude du traitment local des brulures thermigues etendues , Paris, 1961, These; Osler, et al: Simplified estimates and probability of death after burn injuries: extending and updating the Baux score, J Trauma Inj Crit Care 68(3):690–697, 2010.

Baux Score and Modified Baux Score to Predict Mortality in Burn Injury

Original Baux Score: % Mortality = Age + %TBSA
Modified Baux Score: % Mortality = Age + %TBSA + 17*(Inhalation Injury, Yes=1, No=0)

Plot of the observed mortality versus the group midpoint computed within 10 groups of the revised Baux score.

Burn patients have an impaired ability to regulate their core body temperature and will quickly become hypothermic if untreated. Core temperature should be measured frequently, and active and passive warming strategies should be implemented to prevent hypothermia from developing. This can include minimizing exposure by covering patients with sheets and blankets, warming IV fluids, warming the room, or applying radiant or convective warming systems. In anticipation of transfer to a burn center or before surgical consultation, remove any wet cooling dressings that may have been applied initially and cover the wounds with dry gauze dressings.

Initial Care of Minor Burns

Prompt cooling of the burned part is an almost instinctive response and is one of the oldest recorded burn treatments, having been recommended by Galen ( ad 129–199) and Rhazes ( ad 852–923). In the ED, room-temperature or cold tap water irrigation, immersion, or compresses (20°C to 25°C) are optimal in obtaining pain relief and providing some measure of protection for burned tissues without the problems of hypothermia that iced solutions can cause. If not done before ED treatment, immediate cold water immersion may still have some ability to limit the extent of a burn and will provide significant pain relief. It is acceptable to add a few ice chips to the water, but packing the wound in ice must be avoided.

All involved clothing and jewelry (such as rings), along with any gross debris, should be removed from the burned area. Chemical burns involving the skin or eyes require prolonged tap water irrigation. The burn should otherwise be covered with a moist, sterile dressing. In the ED and prehospital phase, appropriate analgesics, usually narcotics, are the best way to control pain and should not be forgotten in the initial phase of burn care. The burned area may be immersed immediately in room-temperature water or covered with gauze pads soaked in room-temperature water or saline (see Fig. 38.8 ). The gauze may be kept cool and moist to provide continued pain relief; the patient will let the clinician know when additional cooling is desired. Many clinicians use sterile saline for cooling, but it has no proven benefit over tap water, even when the skin is broken. It is acceptable to add ice chips to water or saline to lower the temperature. As stated previously, immersion of burned tissue in ice or ice water should be avoided because ice immersion increases pain and risks frostbite injury or systemic hypothermia.

The potential benefits of burn cooling are listed in Box 38.5 . Because most patients with minor burns seek medical attention after initial self-instituted prehospital cooling, it is unlikely that the clinician can favorably affect the burned tissue with any intervention in the ED. With the exception of pain relief and removal of debris, the primary benefits of burn cooling are probably experienced only if the burn is cooled promptly, within the first 3 minutes after injury, thus making home care important. Minor burns are considered tetanus prone, and tetanus toxoid should be administered if patients are unsure of their tetanus immunization status or when it has been more than 10 years since the last immunization. Nonimmunized patients should receive tetanus toxoid and immunization with subsequent boosters in accordance with current guidelines.

Box 38.5

Advantages of Prompt Burn Cooling

Limit extent of thermal damage
Reduction or cessation of pain
Elimination of local hyperthermia
Inhibition of postburn tissue destruction
Decreased edema
Reduced metabolism and toxin production

Outpatient Care of Minor Burns

Minor burns are generally those that will heal spontaneously and do not require surgery or specialized wound care. These wounds are not associated with immunosuppression or hypermetabolism, nor are they highly susceptible to infection, a quality associated with larger burns. Treated conservatively, most minor burns will heal without significant scarring. Many complications seen with minor burns are thought to result from overtreatment rather than undertreatment. Examples include the use of dry dressings that can adhere to newly forming skin and secondary infections from the overzealous use of topical or systemic antibiotics.

The most important characteristic of a dressing is that it controls fluids within the wound. Burn dressings that keep the surface of the wound moist and avoid pooling of fluids will speed healing. The best material for this purpose is a generous amount of simple dry gauze applied over a nonadherent dressing or topical preparation. The outer layer of dressing should be porous to permit evaporation of water from the absorbent dressing material. Some clinicians prefer to eschew a nonadherent portion of the dressing so that subsequent dressing removal aids in minor débridement. Wound preparation and basic bandaging should include the following steps ( Fig. 38.9 ):

1.
Cleanse the burned area gently with a clean cloth or gauze and a mild antibacterial wound cleaner such as chlorhexidine, and irrigate the wound with saline or water. It is not necessary to shave the hair in or around the wound. There is no benefit to vigorously washing a minor wound with strong antiseptic preparations (such as povidone-iodine [Betadine, Purdue Products L.P., Stamford, CT] and others).
2.
Although some authors recommend leaving blisters intact, most sources advise that providers débride blisters and sloughed skin initially by peeling the devitalized skin from the wound ( Fig. 38.10 A–C ). Blisters can be opened with scissors and forceps. If necessary, provide analgesia for any painful débridement. On the initial débridement, attempt to remove only grossly devitalized tissue. Additional débridement of the wound can take place, if needed, during subsequent follow-up visits when the wound has matured.
3.
Consider applying a layer of antibiotic cream or ointment such as 1% silver sulfadiazine (Silvadene [Pfizer Inc., New York, NY]) or bacitracin directly to the wound (see Fig. 38.10 D ).
4.
Apply fine-mesh gauze or commercial nonadherent gauze such as Adaptic or petrolatum gauze impregnated with 3% bismuth tribromophenate (Xeroform [DeRoyal, Powell, TN]) to the burn wound.
5.
Cover and pad the wound with loose gauze fluffs. If fingers and toes are involved, pad the web spaces and the digits individually and separate them with strips of gauze (see Figs. 38.9 D and 38.10 E and F ). Wrap the entire dressing snugly (but not tightly) with an absorbent, slightly elastic material such as Kerlix (Medtronic, Minneapolis, MN).
6.
Instruct the patient to elevate the affected limb to prevent swelling, which may cause delayed burn conversion or wound infection.

Figure 38.9, Outpatient burn dressing of the hand. Patients with serious hand burns should be admitted to the hospital, but minor burns can be treated in the outpatient setting. A, After the application of an antibiotic ointment or a dry, nonadherent dressing, separate the fingers with fluffs in the web spaces and B, enclose the entire hand in a position of function (here with the help of a roll of Kerlix). C, If the wrist is involved, a removable plaster splint may be applied over the dressing. D, The result of a minor burn involving the hand when the fingers were not wrapped individually. Initially, there were only a few blisters, but this patient now has second-degree skin loss because of an improper burn dressing that caused maceration of normal skin between the fingers. Not only were the fingers incorrectly wrapped together in one gauze wrap, but the first wound check was also incorrectly scheduled in 6 days, too long for the first wound inspection of a hand burn.

Open Burn Care

Following cleansing of the wound with chlorhexidine soap and débridement of blisters and any loose skin, wounds that are not amenable to a dressing, such as those on the face, can be managed initially by the application of a bland topical antibiotic such as bacitracin. The wound can be washed two or three times per day, followed by reapplication of the topical agent. This is the preferred method for managing burns on the face and neck.

Burn Dressings

Biologic Dressings

Biologic dressings are natural tissues, including skin that consists of collagen sheets containing elastin and lipid. They are not routinely used in the emergency care of minor wounds and are primarily treatment options in burn centers. The benefits of biologic dressings include a reduction in surface bacterial colonization, diminished fluid and heat loss, avoidance of further wound contamination, and prevention of damage to newly developed granulation tissue. Examples of biologic dressings include cadaveric human skin and commercially available porcine xenograft or collagen sheets.

Synthetic Dressings

Synthetic dressings are manufactured in various forms. Film-type dressings have a homogeneous structure and are usually polymers. Because these dressings are nonpermeable, problems with retention of wound exudates have occurred. Some second-generation dressings have been developed to address these problems. These products include Tegaderm (3M Medical, St. Paul, MN), Vigilon (Bard Medical, Covington, GA), DuoDERM (ConvaTec, Bridgewater, NJ), Biobrane (Smith & Nephew), Op-Site (Smith & Nephew, Inc., Andover, MA), Acticoat (Smith & Nephew), Aquacel products (ConvaTec, Greensboro, NC), and TransCyte (Advanced Tissue Sciences, La Jolla, CA). These preparations have theoretical benefits under certain circumstances, but are not proven to have superior performance over simple gauze dressings for minor outpatient burns. These products are most often used by burn centers and have little applicability for minor burns in patients discharged from the ED. For patients admitted or transferred to a burn center, simple gauze dressings are appropriate. Some burn centers prefer that topical agents not be applied before transfer so that the full extent of the burn can be assessed immediately.

Specific Clinical Issues in Minor Burn Care

Analgesia

Pain is a critical feature of any burn injury. Relief of pain by the appropriate and judicious use of narcotic analgesics is of the utmost importance in the initial care of all burn patients. Prehospital narcotics are very appropriate when standard contraindications do not exist. Analgesia should be provided before extensive examination or débridement is performed. Inadequate analgesia is probably the most common ED error in the treatment of burn injuries, especially when burns occur in children. Parenteral narcotic analgesics have been erroneously relegated to pain control only for major burns, but it is suggested that narcotics be generously administered in the initial treatment of even minor painful burns.

Parenteral opioids (e.g., fentanyl, 1 to 2 µg/kg, or morphine, 0.1 to 0.2 mg/kg) are usually required, especially if painful procedures such as débridement and dressing changes are planned. We prefer to use IV opioids (occasionally supplemented with a short-acting benzodiazepine such as midazolam) for all painful procedures. For complicated débridement or dressing changes adequate analgesia is a minimum requirement with some patients requiring procedural sedation (see Chapter 33 ).

Regional or nerve block anesthesia is an excellent alternative when practical, and if feasible, nitrous oxide analgesia may be used. Ketamine may also be a reasonable alternative. Oral opioids may be inadequate for the initial treatment of significant pain but can be used for continued outpatient analgesia. Local anesthetics may be injected in small quantities when appropriate, such as for the débridement of a deep ulcer or other small burn. Topical analgesics have no role in burn care. A properly designed dressing will do much toward preventing further discomfort after release home; however, home burn care and dressing changes may be quite painful. For this reason, an adequate supply of an oral opioid analgesic should be provided, and responsibility in analgesic use should be encouraged.

Pruritus

Postburn pruritus is one of the most common and distressing complications of burn injury and is estimated to affect 87% of burns. It typically develops in the subacute phase and is therefore not a common issue for the emergency provider in the acute treatment phase. Despite the limited literature on the treatment of postburn pruritus, available therapies include oral antihistamines, topical antihistamines, and topical moisturizers. The use of topical therapies should be withheld until sufficient wound healing has occurred.

Edema

Minor burns lead to immediate inflammation mediated by the release of histamine and bradykinins, which cause localized derangements in vascular permeability with resultant burn wound edema. This edema may be harmful in several ways. First, the increase in interstitial fluid increases the diffusion distance of oxygen from capillaries to cells and thereby increases hypoxia in an already ischemic wound. Second, the edema may produce untoward hemodynamic effects by a purely mechanical mechanism: compression of vessels in muscular compartments. Third, edema has been associated with the inactivation of streptococcicidal skin fatty acids, thus predisposing the patient to burn cellulitis.

Successful management of burn edema hinges on immobilization and elevation. Most patients are unfamiliar with the medical definition of elevation and are not aware or convinced of its value. Patient education in this regard is critical; however, certain burns (e.g., burns in dependent body areas) are prone to edema despite everyone's best intentions. It is for this reason that lower extremity burns in general and foot burns in particular are prone to problems. Major burns of the hand should be elevated while the patient is still in the ED. This is most readily accomplished by hanging the injured hand from an IV pole with a stockinette to support the bandaged hand ( Fig. 38.11 ).

Figure 38.11, Begin elevation of a burned hand in the emergency department. After a hand dressing is applied, suspend the arm from an intravenous pole with stockinette. A plaster or fiberglass splint may also be incorporated into the dressing.

Use of Topical Preparations and Antimicrobials

Minor burns result in insignificant impairment of normal host immunologic defenses, and burn wound infection is not usually a significant problem. Topical antimicrobials are often used; however, some believe that these agents may actually impair wound healing. Although the procedure is of unproven value, many clinicians routinely use antibiotic creams or ointments on even the most minor burns. Most patients expect some type of topical concoction, so a discussion of their use—or nonuse—is prudent.

Topical antimicrobials were designed for the prevention and care of burn wound sepsis or wound infection, primarily in hospitalized patients with major burns, and there is no convincing evidence that their use alters the course of first-degree burns and superficial partial-thickness injuries. As noted, the burn dressing is the key factor in minimizing complications in all burns. Nonetheless, topical antimicrobials are often soothing to minor burns, and their daily use prompts the patient to look at the wound, assess healing, perform prescribed dressing changes, or otherwise become personally involved in the care. Keep in mind that if a topical antimicrobial is used, its effectiveness is decreased in the presence of proteinaceous exudate, thus necessitating regular dressing changes if the antimicrobial benefit of topical therapy is to be realized. In reality, once-daily dressing changes are most practical and are commonly prescribed, and no data indicate that this regimen is inferior to more frequent dressing changes.

All full-thickness burns should receive topical antimicrobial therapy because the eschar and burn exudate are potentially good bacterial culture media and deep escharotic or subescharotic infections may not be easily detected until further damage is done. All deep partial-thickness injuries likewise benefit from the application of a topical antimicrobial. As stated, this intervention can await definitive therapy in a burn unit.

Criteria for choosing a specific topical agent include its' in vitro and clinical efficacy, toxicity (absorption), superinfection rate, ease and flexibility of use, cost, patient acceptance, and side effects. It is important to note that no firm scientific data convincingly support the use of any specific topical antimicrobial for minor outpatient burns.

Specific Topical Agents

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