Initial Evaluation and Management of the Burn Patient
Outcomes for burn patients have improved dramatically over the past 20 years, yet burns still cause substantial morbidity and mortality. [1, 2] Proper evaluation and management, coupled with appropriate early referral to a specialist, greatly help in minimizing suffering and optimizing results. [3, 4, 5]
Burn injury is a common cause of morbidity and mortality.  In the United States, approximately 1.25 million people with burns present to the emergency department each year. [7, 8] Among these, 63,000 have minor burn injuries that are treated primarily in the emergency department and an additional 6000 sustain major burn injuries that require hospital admission. [9, 10, 11]
Before management of the burn wound can begin, the patient should be properly and completely evaluated. [4, 13, 5, 14, 15] Often, this is a brief effort, particularly in patients with small, uncomplicated wounds. In those with larger burns, evaluation of the wound is often of secondary importance.  As described by the American College of Surgeons Committee on Trauma, evaluation of the burn patient is organized into a primary survey and secondary survey. 
Burn patients should be systematically evaluated using the methodology of the American College of Surgeons Advanced Trauma Life Support course. This evaluation is described by the primary survey, with its emphasis on support of the airway, gas exchange, and circulatory stability.  First evaluate the airway; this is an area of particular importance in burn patients. Early recognition of impending airway compromise, followed by prompt intubation, can be lifesaving.  Obtain appropriate vascular access and place monitoring devices, then complete a systematic trauma survey, including indicated radiographs and laboratory studies.
Burn patients should then undergo a burn-specific secondary survey, which should include a determination of the mechanism of injury, an evaluation for the presence or absence of inhalation injury and carbon monoxide intoxication, an examination for corneal burns, the consideration of the possibility of abuse, and a detailed assessment of the burn wound. 
Of particular importance is eliciting a detailed history upon first evaluation and transmitting this information with the patient to the next level of care. Inhalation injury is diagnosed based on a history of a closed-space exposure and soot in the nares and mouth.  Carbon monoxide intoxication is probable in persons injured in structural fires, particularly if they are obtunded; carboxyhemoglobin levels can be misleading in those ventilated with oxygen.  Persons with facial burns should undergo a careful examination of the cornea prior to the development of lid swelling that can compromise examination.  After evaluation of the burn wound, begin fluid resuscitation and make decisions concerning outpatient or inpatient management or transfer to a burn center (see American Burn Association burn center transfer criteria in Evaluation of the Burn Wound). [5, 22, 23]
Tissue burn involves direct coagulation and microvascular reactions in the surrounding dermis that may result in extension of the injury. Large injuries are associated with a systemic response caused by a loss of the skin barrier, the release of vasoactive mediators from the wound, and subsequent infection. This results clinically in interstitial edema in distant organs and soft tissues, with an initial decrease in cardiac output and the metabolic rate. 
After successful resuscitation, a hypermetabolic response occurs, with near doubling of cardiac output and resting energy expenditure. Accelerated gluconeogenesis, insulin resistance, and increased protein catabolism accompany this response. Modification of this physiology through the administration of beta-adrenergic blockade, beta-adrenergic supplementation, nonsteroidal anti-inflammatory agents, recombinant growth hormone, androgenic steroids, and insulinlike growth factor 1 have been proposed to modify this physiology. Currently, data do not support the routine use of these therapies.
Burn patients demonstrate a graded capillary leak, which increases with injury size, delay in initiation of resuscitation, and the presence of inhalation injury for the first 18-24 hours after injury. Because the changes are different in every patient, fluid resuscitation can only be loosely guided by formulas.  The inherent inaccuracy of formulas requires continuous reevaluation and adjustment of infusions based on resuscitation targets. 
Most formulas recommend that all crystalloid be isotonic during the first 24 hours, generally Ringer lactate solution. Hypertonic saline has been recommended for resuscitation, but this practice has largely been abandoned because it is technically challenging and is not associated with improved clinical outcomes. In smaller children, whose gluconeogenetic capacity is immature, hypoglycemia is a threat and Ringer lactate solution with 5% dextrose should be added at a maintenance rate.
The modified Brooke or Parkland formulas are reasonable consensus formulas and are used to help determine the initial volume of infusion. Half of the total calculated 24-hour volume is administered in the first 8 hours post injury. Should the resuscitation be delayed, this volume is administered so that infusion is completed by the end of the eighth hour post injury. After 18-24 hours, capillary integrity generally returns and fluid administration should be decreased, following resuscitation endpoints. At this point, colloid administration is useful, generally 5% albumin in Ringer lactate solution. Increasingly, providers are replacing a portion of the calculated crystalloid with 5% albumin in patients with large deep burns. 
As a general rule, burns over less than 15% of the body surface area are not associated with an extensive capillary leak, and children with burns of this size can be treated with fluid administered at 150% of a calculated maintenance rate and close observation of their hydration status. Those who are able and willing to take fluid by mouth may be given fluid by mouth, with additional fluid administered intravenously at a maintenance rate.
Pigmented urine is commonly seen in the setting of high-voltage or very deep thermal injury.  This pigment should be cleared promptly to avoid renal failure. This can usually be achieved through the administration of additional crystalloid. The administration of bicarbonate may facilitate clearance of myoglobin by preventing its entry into the tubular cells. In rare circumstances, loop diuretics or mannitol can be useful, but this obscures urine output as a valid indicator of circulating volume.
Electrolyte levels should be carefully monitored and corrected. Cerebral edema and seizures can occur with severe hyponatremia, and rapid correction of hyponatremia may result in central pontine demyelinating lesions. Serum sodium, potassium, ionized calcium, phosphorous, and magnesium levels should be monitored and kept within physiologic range. Ideally, begin enteral feedings during resuscitation, except in patients with massive injuries or those who are underresuscitated and less likely to tolerate tube feedings because of ileus secondary to splanchnic underperfusion.
After the patient has been fully evaluated and stable hemodynamics and gas exchange are ensured, evaluate the burn wound in detail.  Evaluate burn wounds initially for extent, depth, and circumferential components. Decisions regarding the type of monitoring, wound care, hospitalization, and transfer are made based on this information. [22, 23] The American Burn Association burn center transfer criteria are as follows: 
Second- or third-degree burns greater than 10% total body surface area (TBSA) in patients younger than 10 years or older than 50 years 
Second- or third-degree burns greater than 20% TBSA in persons of other age groups
Second- or third-degree burns that involve the face, hands, feet, genitalia, perineum, or major joints
Third-degree burns greater than 5% TBSA in persons of any age group
Electrical burns, including lightening injury
Inhalational injury 
Burn injury in patients with preexisting medical disorders that could complicate management, prolong recovery, or affect mortality
Any patients with burns or concomitant trauma (eg, fracture) in which the burn injury poses the greatest risk of morbidity or mortality: In such cases, if the trauma poses the greater immediate risk, the patient may be treated initially in a trauma center until stable before being transferred to a burn center. Physician judgment is necessary in such situations and should be in concert with the regional medical control plan and triage protocols. 
A lack of qualified personnel or equipment for the care of children (transfer to facility with these qualities) 
An accurate estimate of burn size is important for treatment and transfer decisions. Burn size or extent can be estimated in a number of ways. Perhaps most accurate is the age-specific chart based on the Lund-Browder diagram that compensates for the changes in body proportions with growth (see the image below). A burn is drawn on a cartoon figure, and an associated age-specific table is used to calculate the body surface area involved.
An alternative in adults is the “rule of nines.” This is less accurate in children because their body proportions are different from those of adults.  For areas of irregular or nonconfluent burns, the palmar surface of the patient’s hand can be used.  For a wide age range, the area of the palm without the fingers represents 0.5% of the body surface.
Burn depths are routinely underestimated during the initial examination.  Devitalized tissue may appear viable for some time after injury, and often, some degree of progressive microvascular thrombosis is observed on the wound periphery. Consequently, the wound appearance changes over the days following injury. Serial examination of burn wounds can be very useful.
Burn depth is classified as first, second, third, or fourth degree, as follows: 
First-degree burns are usually red, dry, and painful. Burns initially termed first-degree are often actually superficial second-degree burns, with sloughing occurring the next day.
Second-degree burns are often red, wet, and very painful. Their depth, ability to heal, and propensity to form hypertrophic scars (see the image below) vary enormously.
Third-degree burns are generally leathery in consistency, dry, insensate, and waxy. These wounds will not heal, except by contraction and limited epithelial migration, with resulting hypertrophic and unstable cover. Burn blisters can overlie both second- and third-degree burns. The management of burn blisters remains controversial, yet intact blisters help greatly with pain control. Debride blisters if infection occurs. See the images below.
Fourth-degree burns involve underlying subcutaneous tissue, tendon, or bone. Usually, even an experienced examiner has difficulty accurately determining burn depth during early examination. As a general rule, burn depth is underestimated upon initial examination. 
Note circumferential, or near-circumferential, burn wounds because they may cause progressive extremity ischemia or interfere with ventilation as burn wound swelling increases. In such situations, timely escharotomy is essential. Perform extremity escharotomies as soon as peripheral perfusion is threatened. Do not wait until the extremity is overtly ischemic. Perform torso escharotomies as soon as ventilation appears compromised.
An ability to make the diagnosis of burn wound infection is important. A clinically focused set of burn wound infection definitions has recently been published and is summarized as follows:
Diagnostic points – Loss of epithelium from previously epithelialized surface; not related to local trauma
Treatment strategies – Regular cleaning of debris and exudate; topical antistaphylococcal antibiotics; grafting of chronically unstable areas of epithelium
Burn-related surgical wound infection
Diagnostic points – Infection in surgically created would that has not yet epithelialized; includes loss of any overlying graft or membrane
Treatment strategies – Regular cleaning of debris and exudate; systemic and topical antistaphylococcal antibiotics; grafting of chronically unstable areas of epithelium
Burn wound cellulitis
Diagnostic points – Infection occurs in uninjured skin surrounding a wound; signs of local infection progress beyond what is expected from burn-related inflammation
Treatment strategies – Systemic antibiotics directed against Streptococcus pyogenes; proper treatment of primary wound
Invasive burn wound infection
Diagnostic points – Infection occurs in unexcised burn and invades viable underlying tissue; diagnosis may be supported by results from histologic examination or quantitative culture
Treatment strategies – Systemic antibiotics directed against presumed pathogen; wound excision, with biologic closure when possible
Two of these, burn wound cellulitis and invasive burn wound infection, are seen with some regularity by clinicians outside a burn center environment.
Burn wound cellulitis (see the image below) usually manifests with progressive erythema, swelling, and pain in the uninjured skin around a wound. Usually, this is seen in the first few days after the burn occurred and is typically caused by S pyogenes. Infection can progress rapidly, but it is generally sensitive to penicillin. Excision of associated deep eschar can be essential to the successful treatment of cellulitis. Elevation to reduce edema is an important adjunct.
Invasive burn wound infection (see the image below) is a rapid proliferation of bacteria in burn eschar that invades underlying viable tissues. A change in color, new drainage, and, occasionally, a foul or sickly sweet odor are clinical findings. Pseudomonal and other gram-negative species are common causes. This infection can be life-threatening and usually requires combined treatment with surgery and antibiotics.
Fever and systemic toxicity commonly accompany both infections. Inspect burn wounds frequently to identify infection early. This is an important consideration in outpatient burn care. Someone must inspect the wounds managed in the outpatient environment to promptly detect infections. Errors in initial depth assessment are routine. Infections occur and must be treated in a timely manner. A wound monitoring plan is an essential part of burn care.
Most burns are small; patients with small burns are appropriately treated in an outpatient setting if the burns do not involve critical areas such as the face, hands, genitals, or feet. [9, 11] The outpatient setting is the primary focus of this section. Outpatient burn management can be taxing and, when poorly performed, can cause unnecessary suffering and compromise long-term results. In some situations, the best plan is to coordinate outpatient management with the burn unit’s team of doctors, nurses, and therapists because their expertise may facilitate attaining optimal outpatient results. However, most small burns can be properly managed by community-based providers with burn center consultation as needed. 
Several factors are relevant to the decision regarding the location of burn care. Airways must not be compromised. The wound must be small enough so that fluid resuscitation is unnecessary, which generally precludes outpatient care for burns over 10-15% of TBSA. The patient must be able to ingest adequate fluid orally. Typically, serious burns to the face, ears, hands, genitals, or feet should initially be managed in an inpatient setting.
The patient and family must be able to support an outpatient care plan. An adult caregiver should be available who can be with a child treated in an outpatient setting. A family member or visiting nurse must be available who can perform the necessary wound cleansing, inspection, and dressing applications because most patients cannot do this themselves. The family must have adequate transportation to return for clinic visits and unexpected emergency visits. If abuse is suspected, outpatient management is contraindicated. Finally, if the initial examination findings indicate that surgery is needed for a full-thickness wound area, the patient should be promptly admitted for surgery.  Despite all of these qualifications, most patients with smaller burns can be successfully treated in an outpatient setting.
Components of outpatient burn care include the following: 
Patient and family education
Choice of topical or membrane dressing 
Early return instructions
Follow-up clinic visits
Long-term follow-up care
Wound cleansing and dressing techniques must be taught to the person who changes the dressings. Ideally, document this instruction.
The choice of the many medications or membranes to place on burn wounds remains unclear, but certain basic principles apply to all situations. Gently clean the wound of debris and exudate on a regular basis. This usually requires daily removal of accumulated exudate and topical medications. Small superficial burns managed in this setting present a low risk of infection, thus, a clean rather than sterile technique is reasonable. Patients may clean the burn with lukewarm tap water and mild soap.
Soaking dressings in lukewarm tap water may decrease the pain associated with their removal. Gently cleanse the wound with a gauze or clean washcloth, inspect for signs of infection, pat dry with a clean towel, and re-dress the patient. To manage infections promptly, teaching the patient and family to return promptly if they notice erythema, swelling, increased tenderness, odor, or drainage is important. The frequency of wound cleansing and dressing change is debated, but most small burns are managed adequately with daily cleansing and dressing.
Wound dressing, whether one is using topical medication or a wound membrane, should provide 4 benefits, including (1) prevention of wound desiccation, (2) control of pain, (3) reduction of wound colonization and infection, and (4) prevention of added trauma to the wound.  Most topical dressings for outpatient use have a viscous carrier that prevents wound desiccation and a broader antibacterial spectrum that reduces wound colonization. The addition of a gauze wrap minimizes soiling of both clothing and unburned skin and protects the wound from the external environment. A large number of excellent agents are available.
Superficial facial burns are commonly treated with a clear, viscous antibacterial ointment. Wounds around the eyes can be treated with heavy topical ophthalmic antibiotic ointments.  Treat deep burns of the external ear with mafenide acetate because it penetrates the eschar and prevents purulent infection of the cartilage. Appropriate wound care strategies address these principles.
Pain control in the outpatient setting can be difficult, and if pain and anxiety cannot be adequately managed at home, then hospitalization is appropriate. For most patients, an oral narcotic medication administered 30-60 minutes prior to a planned dressing change provides adequate pain control. Because most dressings are occlusive, pain control between dressing changes tends to be managed adequately without narcotics in most patients. Elaborate specific conditions may mandate an early return to the hospital. Particularly important are (1) pain and anxiety associated with wound care to the degree that wound care is compromised, (2) signs of infection, or (3) a wound that appears deeper than appreciated during the initial examination. Review wound care instructions with caregivers.
The management plan for patients with large burns that require inpatient care is usually determined by the physiology of the burn injury. Management strategies for these patients are beyond the scope of this article yet generally require a coordinated approach that involves a specialized team. Hospitalization is divided into 4 general phases, including (1) initial evaluation and resuscitation, (2) initial wound excision and biologic closure, (3) definitive wound closure, and (4) rehabilitation and reconstruction.
Early excision and closure of full-thickness wounds changes the natural history of burn injury, avoiding the otherwise common occurrence of wound sepsis.  Wound size is the most important factor in determining the need for early operation because this correlates with the physiologic threat represented by the injury. These operations can be bloody and physiologically stressful, but the blood and stress can be minimized with proper planning and execution.
A prediction regarding the probability a wound will require operative management is of enormous practical value. Examination by an experienced burn surgeon remains the most reliable method, despite the many devices developed to measure burn depth or burn blood flow. The changes in wound appearance over the first few days after injury make serial examinations particularly useful tools in surgical planning.
Patients with small burns rarely develop overwhelming wound sepsis, and burn care providers often have the luxury of time to allow the wound to fully evolve, allowing accurate operative planning. An initial nonoperative approach to such wounds helps minimize the need for operation. Patients with larger injuries generally do better if their wound is addressed during the first few days after the burn occurred. If wounds cover more than 40% TBSA, this may require staged procedures. If the wounds involve more than 50% of the body surface, achieving immediate autograft closure is often impossible. When autograft material is exhausted, temporary biologic closure is achieved with human allograft or other temporary wound closure material. Wounds are later resurfaced with autograft when donor sites have healed.
Most wounds can be managed with layered excisions that optimize appearance and function. Sheet grafts are used whenever reasonable. Blood loss associated with these operations has been estimated in the past at 3.5-5% of the blood volume for every 1% of the body surface excised. However, less blood loss can be achieved through the use of extremity tourniquets, dilute epinephrine injection, and a brisk operative pace. Intraoperative hypothermia should be anticipated and prevented though operating room heating.
Temporary skin substitutes provide protection from mechanical trauma, a vapor barrier, and a physical barrier to bacteria.  These membranes contribute to a moist wound environment with a low bacterial density that is consistent with optimal wound healing. Split thickness human allograft remains the optimal temporary skin cover.
A number of membranes have been developed to effect permanent wound coverage, including epidermal, dermal, and composite substitutes. A sheet of autologous epithelial cells can be grown from a full-thickness skin biopsy specimen. These can be useful in patients with massive injury, but they are very fragile, expensive, and provide unreliable definitive cover. Dermal analogs include Integra R (Integra Life Sciences, Plainsboro, NJ) and AlloDerm R (LifeCell Corporation, The Woodlands, Tex); both require an associated epithelial autograft. Integra R is a bilayer material with an inner layer of 2-mm thick collagen isolated from bovine tissue and chondroitin-6-sulfate and an outer layer of 0.009-in polysiloxane polymer with vapor transmission characteristics similar to skin. Allogenic dermis designed to be combined with a thin epithelial autograft, AlloDerm R is another promising dermal analog. Hopefully, an autologous composite skin substitute will ultimately be developed.
The choice of medication or membrane for a wound is a never-ending source of discussion and argument. Fortunately, most medications and membranes perform well if physicians carefully monitor wounds, keep them clean, prevent desiccation, and properly manage secondary infection.
A wide range of topical medications is available, including simple petrolatum, various antibiotic-containing ointments and aqueous solutions, and debriding enzymes. Some of the available topical medications and their characteristics are described in the lists below. All of them can be effective when used properly by experienced providers in a program of burn care that includes wound evaluation, regular cleansing, and monitoring.
See the list below:
Silver sulfadiazine – Broad antibacterial spectrum; painless application 
Aqueous 0.5% silver nitrate – Broad-spectrum coverage, including fungi; leeches electrolytes
Mafenide acetate – Broad antibacterial spectrum; penetrates eschar best
Petrolatum – Bland and nontoxic
Various debriding enzymes – Useful in selected partial-thickness wounds
Various antibiotic ointments – Useful in many superficial partial-thickness wounds
See the list below:
Porcine xenograft – Adheres to wound coagulum and provides excellent pain control
Split-thickness allograft – Vascularizes and provides durable temporary closure of wounds
Various hydrocolloid dressings – Provide vapor and bacteria barrier while absorbing wound exudate
Various impregnated gauzes – Provide vapor and bacteria barrier while allowing drainage
Various semipermeable membranes – Provide vapor and bacteria barrier
Acticoat (Westhaim Biomedical, Saskatchewan, Canada) – Nonadherent wound dressing that delivers a low concentration of silver for antisepsis
Biobrane (Dow-Hickman, Sugarland, Tex) – Synthetic bilaminate that facilitates fibrovascular tissue growth into inner layer and provides temporary vapor and bacteria barrier
Transcyte (Smith and Nephew, Largo, Fla) – Synthetic bilaminate that facilitates fibrovascular tissue growth into inner layer populated with allogenic fibroblasts and overlying layer that provides temporary vapor and bacteria barrier
AlloDerm R – Consists of cell-free allogenic human dermis; requires an immediate thin overlying autograft
Integra R – Provides scaffold for neodermis; requires delayed thin autograft
Wound membranes are different from medications and dressings in that they provide transient physiologic wound closure. This implies a degree of protection from mechanical trauma, vapor transmission characteristics similar to skin, and a physical barrier to bacteria. These membranes facilitate a moist wound environment with low bacterial density. They are commonly placed on clean superficial wounds while awaiting epithelialization. These membranes are mostly occlusive; therefore, they must be used with caution if wounds are not clearly clean and superficial. If an occlusive membrane is placed over devitalized tissue, submembrane purulence can occur with subsequent local and systemic sepsis.
The diagnosis of inhalation injury is primarily clinical, based on a history of closed-space exposure, facial burns, singed nasal hairs, and carbonaceous debris in the mouth and pharynx or sputum.  Chest radiograph findings are routinely normal until complications (usually infection) develop. Bronchoscopy findings may include carbonaceous debris, ulceration, or erythema, but these changes are not always apparent.
The clinical consequences of inhalation injury include upper airway edema, bronchospasm, small airway occlusion, increased dead space and intrapulmonary shunting, decreased lung and chest wall compliance, and infection. Management is supportive only. 
Pneumonia or tracheobronchitis occurs in at least 30% of patients with inhalation injuries, due to the loss of the ciliary clearance mechanism, small airway occlusion, alveolar flooding, and endotracheal intubation. Vigorous pulmonary toilet, with toilet bronchoscopy in selected patients, is a very important component of therapy. The role of tracheostomy in the management of inhalation injury is controversial. It can be very useful if particularly prolonged intubation or difficult weaning is anticipated or if unusually thick secretions are unmanageable through an endotracheal tube. Tracheostomy in children is associated with a higher incidence of serious structural problems that require prolonged cannulation and reconstruction and, ideally, is avoided whenever possible. 
Compartment syndrome, cardiac arrhythmia, or myoglobinuria is uncommon in patients exposed to less than 500 volts, although patients sustaining midrange injuries (200-1000 V) can have destructive local injuries. High-voltage injuries are commonly associated with loss of consciousness, falls, fractures, myoglobinuria, compartment syndrome, and arrhythmia, and these individuals should be treated as trauma patients.
Treatment of chemical exposures should begin with immediate removal of clothing and chemicals. [30, 31] First responders need to protect themselves from injury. Copious irrigation with tap water should then be performed for at least 30 minutes. Alkaline substances, less soluble in water, often take longer to clear. Consultation with personnel at the poison control center should be considered when evaluating anyone with a chemical burn. Adequate ocular irrigation can be facilitated by topical ocular anesthetics. With larger injuries, fluid resuscitation may be required. Some agents are associated with irritating fumes, which can result in airway compromise.
Toxic epidermal necrolysis is a systemic process triggered by a medication or viral syndrome that results in a separation at the dermal-epidermal junction. Both a cutaneous wound and a visceral wound develop, with variable degrees of dermal, mucosal, and conjunctival involvement. Endotracheal intubation is often required for airway protection. Wound care should be directed to prevent desiccation and superinfection, and nutritional support is important.
Especially in adolescents and adults, the deep sweat and sebaceous glands of the central face make it likely that most second-degree burns will heal well with adequate topical wound care. Many reasonable management options are available, including topical silver sulfadiazine or bland antibiotic ointments.  Burns around the eyes can be dressed with topical ophthalmic antibiotic ointments.  If grafting is a possibility, reserve thick donor skin with optimal color match for facial resurfacing.  Often, the “blush” areas, such as the upper back and shoulders, make good facial donor sites.
The most important point of early management of deeply burned ears is prevention of auricular chondritis. This is a serious complication in which the cartilage becomes infected and quickly liquefies. Twice-daily cleansing and the application of topical mafenide acetate, which penetrates the eschar, can minimize the condition. Subsequent management of the ear is based on the depth of injury.
Deep corneal burns are obvious during the physical examination.  The cornea has a clouded appearance. More subtle injuries can be detected only with topical fluorescein application. After facial edema resolves, lid retraction may occur with variable degrees of exposure of the globe or ectropion. When this is relatively mild, no intervention is required beyond ocular lubricants. Should keratitis occur, early lid release is advised.
Hand burns assume a high priority from the onset of care.  During the first 24-48 hours, adequate blood flow must be ensured. Regularly monitor consistency, temperature, and the presence of pulsatile flow (detectable using Doppler studies of the digital pulp). If blood flow is questionable, perform escharotomy or fasciotomy.
Splint hands in a position of function, ie, the metatarsophalangeal joints at 70-90°, interphalangeal joints in extension, first web space open, and wrist at 20° of extension. Elevate the hands to minimize edema, and have the patient perform range-of-motion exercises with a therapist twice daily. Deep dermal and full-thickness burns should undergo early excision and sheet autograft closure. Perform hand therapy throughout the healing period, stopping only in the few days immediately after grafting. If this is not performed, suboptimal long-term function results (see the image below).
The final phase of burn care is rehabilitation and reconstruction. As survival has improved, this field has evolved rapidly, becoming highly specialized. Therapy should begin in the critical care setting; priorities include ranging, splinting, and antideformity positioning. Ranging is ideally performed twice daily, with the therapist taking all joints through a passive of range of motion. These activities help prevent the occurrence of many common contractures. As the seriously burned patient begins to recover, priorities include continuing passive ranging, increasing active ranging and strengthening, minimizing edema, pursuing activities of daily living, and preparing for work or play and school. 
Important aspects of rehabilitation after discharge include ongoing and progressive ranging and strengthening, postoperative therapy after reconstructive operations, and scar management. The most difficult hypertrophic scarring is seen in deep dermal burns that heal spontaneously in less than 3 weeks. Therapies to minimize hypertrophic scarring are begun as soon as burns are well healed and include scar massage, compression garments, topical silicone, steroid injections, and management of pruritus.
If they participate in a coordinated multidisciplinary burn aftercare program, most patients have satisfying long-term outcomes.
Bessey PQ, Phillips BD, Lentz CW, Edelman LS, Faraklas I, Finocchiaro MA, et al. Synopsis of the 2013 annual report of the national burn repository. J Burn Care Res. 2014 May-Jun. 35 Suppl 2:S218-34. [Medline].
Klein MB, Goverman J, Hayden DL, et al, Inflammation and Host Response to Injury, and Large-Scale Collaborative Research Program. Benchmarking outcomes in the critically injured burn patient. Ann Surg. 2014 May. 259 (5):833-41. [Medline].
King BT, Peterson WC. The Care of Thermally Injured Patients in Operational, Austere, and Mass Casualty Situations. Wilderness Environ Med. 2017 Jun. 28 (2S):S103-S108. [Medline].
Gursel E, Binns JH. Early management of burned patients. Emerg Med Clin North Am. 1983 Dec. 1(3):595-600. [Medline].
Cancio LC, Lundy JB, Sheridan RL. Evolving changes in the management of burns and environmental injuries. Surg Clin North Am. 2012 Aug. 92 (4):959-86, ix. [Medline].
Clark CJ, Reid WH, Gilmour WH, Campbell D. Mortality probability in victims of fire trauma: revised equation to include inhalation injury. Br Med J (Clin Res Ed). 1986 May 17. 292(6531):1303-5. [Medline].
Pujji O, Nizar B, Bechar J, North D, Jeffery S. Burns Centre and fire services: What information can be exchanged to manage the burn patient?. Burns. 2017 Nov 24. 10(2):100-7. [Medline].
Sheridan RL, Friedstat J, Votta K. Lessons Learned from Burn Disasters in the Post-9/11 Era. Clin Plast Surg. 2017 Jul. 44 (3):435-440. [Medline].
Brandt CP, Coffee T, Yurko L, Yowler CJ, Fratianne RB. Triage of minor burn wounds: avoiding the emergency department. J Burn Care Rehabil. 2000 Jan-Feb. 21(1 Pt 1):26-8. [Medline].
Khan AA, Rawlins J, Shenton AF, Sharpe DT. The Bradford Burn Study: the epidemiology of burns presenting to an inner city emergency department. Emerg Med J. 2007 Aug. 24 (8):564-6. [Medline].
Sheridan R. Outpatient burn care in the emergency department. Pediatr Emerg Care. 2005 Jul. 21(7):449-56; quiz 457-9. [Medline].
Sheridan RL. Management of burns. Surg Clin North Am. 2014 Aug. 94 (4):xv-xvi. [Medline].
Laing JH, Morgan BD, Sanders R. Assessment of burn injury in the accident and emergency department: a review of 100 referrals to a regional burns unit. Ann R Coll Surg Engl. 1991 Sep. 73(5):329-31. [Medline].
Moncrief JA. Burns. I. Assessment. JAMA. 1979 Jul 6. 242(1):72-4. [Medline].
Stylianou N, Buchan I, Dunn KW. A review of the international Burn Injury Database (iBID) for England and Wales: descriptive analysis of burn injuries 2003-2011. BMJ Open. 2015 Feb 27. 5 (2):e006184. [Medline].
Sheridan RL. Burn care: results of technical and organizational progress. JAMA. 2003 Aug 13. 290(6):719-22. [Medline].
Silver GM, Freiburg C, Halerz M, Tojong J, Supple K, Gamelli RL. A survey of airway and ventilator management strategies in North American pediatric burn units. J Burn Care Rehabil. 2004 Sep-Oct. 25(5):435-40. [Medline].
Patel BC. Emergency eye care in the accident and emergency department. Arch Emerg Med. 1993 Dec. 10(4):387-8. [Medline].
Jones SW, Williams FN, Cairns BA, Cartotto R. Inhalation Injury: Pathophysiology, Diagnosis, and Treatment. Clin Plast Surg. 2017 Jul. 44 (3):505-511. [Medline].
Walker AR. Emergency department management of house fire burns and carbon monoxide poisoning in children. Curr Opin Pediatr. 1996 Jun. 8(3):239-42. [Medline].
Edlich RF, Haynes BW, Larkham N, Allen MS, Ruffin W Jr, Hiebert JM, et al. Emergency Department treatment, triage and transfer protocols for the burn patient. JACEP. 1978 Apr. 7(4):152-8. [Medline].
Sheridan R, Weber J, Prelack K, Petras L, Lydon M, Tompkins R. Early burn center transfer shortens the length of hospitalization and reduces complications in children with serious burn injuries. J Burn Care Rehabil. 1999 Sep-Oct. 20(5):347-50. [Medline].
Sheridan RL, Tompkins RG. What’s new in burns and metabolism. J Am Coll Surg. 2004 Feb. 198 (2):243-63. [Medline].
Theron A, Bodger O, Williams D. Comparison of three techniques using the Parkland Formula to aid fluid resuscitation in adult burns. Emerg Med J. 2014 Sep. 31 (9):730-5. [Medline].
Sheridan R. Less Is More-Revisiting Burn Resuscitation. Pediatr Crit Care Med. 2016 Jun. 17 (6):578-9. [Medline].
Gordon M, Goodwin CW. Burn management. Initial assessment, management, and stabilization. Nurs Clin North Am. 1997 Jun. 32(2):237-49. [Medline].
Sheridan RL. The seriously burned child: resuscitation through reintegration–2. Curr Probl Pediatr. 1998 May-Jun. 28(5):139-67. [Medline].
Binns H, Gursel E, Wilson N. Gasoline contact burns. JACEP. 1978 Nov. 7(11):404-5. [Medline].
Kennedy CS, Knapp JF. Childhood burn injuries related to gasoline can home storage. Pediatrics. 1997 Mar. 99(3):E3. [Medline].
Banco L, Lapidus G, Zavoski R, Braddock M. Burn injuries among children in an urban emergency department. Pediatr Emerg Care. 1994 Apr. 10(2):98-101. [Medline].
Tiyyagura G, Beucher M, Bechtel K. Nonaccidental Injury in Pediatric Patients: Detection, Evaluation, and Treatment. Pediatr Emerg Med Pract. 2017 Jul. 14 (7):1-32. [Medline].
Stoddard, F, Ronfeldt H, Kagan J. Young burned children: the course of acute stress and physiological and behavioral responses. Am J Psychiatry. 2006. 163(6):1084-90.
Heaton PA. The pattern of burn injuries in childhood. N Z Med J. 1989 Nov 8. 102(879):584-6. [Medline].
Sheridan RL, Petras L, Basha G, Salvo P, Cifrino C, Hinson M, et al. Planimetry study of the percent of body surface represented by the hand and palm: sizing irregular burns is more accurately done with the palm. J Burn Care Rehabil. 1995 Nov-Dec. 16(6):605-6. [Medline].
Papini R. Management of burn injuries of various depths. BMJ. 2004 Jul 17. 329(7458):158-60. [Medline].
Sheridan, RL. Current Problems in Surgery. Comprehensive Management of Burns. 2001. 38(9): 641-756.
Greenhalgh DG. Topical antimicrobial agents for burn wounds. Clin Plast Surg. 2009 Oct. 36 (4):597-606. [Medline].
Yuxiang L, Lingjun Z, Lu T, Mengjie L, Xing M, Fengping S, et al. Burn patients’ experience of pain management: A qualitative study. Burns. 2011 Nov 11. [Medline].
Sheridan RL. Sepsis in pediatric burn patients. Pediatr Crit Care Med. 2005 May. 6(3 Suppl):S112-9. [Medline].
Sheridan RL, Tompkins RG. Skin substitutes in burns. Burns. 1999 Mar. 25(2):97-103. [Medline].
Cartotto R. Topical antimicrobial agents for pediatric burns. Burns Trauma. 2017. 5:33. [Medline].
Sheridan RL. Fire-Related Inhalation Injury. N Engl J Med. 2016 Nov 10. 375 (19):1905. [Medline].
Kadilak PR, Vanasse S, Sheridan RL. Favorable short- and long-term outcomes of prolonged translaryngeal intubation in critically ill children. J Burn Care Rehabil. 2004 May-Jun. 25(3):262-5. [Medline].
Philp L, Umraw N, Cartotto R. Late Outcomes After Grafting of the Severely Burned Face: A Quality Improvement Initiative. J Burn Care Res. 2011 Nov 10. [Medline].
Sheridan RL, Baryza MJ, Pessina MA, O’Neill KM, Cipullo HM, Donelan MB, et al. Acute hand burns in children: management and long-term outcome based on a 10-year experience with 698 injured hands. Ann Surg. 1999 Apr. 229 (4):558-64. [Medline].
Heath K, Timbrell V, Calvert P, Stiller K. Outcome measurement tools currently used to assess pediatric burn patients: an occupational therapy and physiotherapy perspective. J Burn Care Res. 2011 Nov. 32(6):600-7. [Medline].
Robert L Sheridan, MD Assistant Chief of Staff, Chief of Burn Surgery, Shriners Burns Hospital; Associate Professor of Surgery, Department of Surgery, Division of Trauma and Burns, Massachusetts General Hospital and Harvard Medical School
Robert L Sheridan, MD is a member of the following medical societies: American Academy of Pediatrics, American Association for the Surgery of Trauma, American Burn Association, American College of Surgeons
Disclosure: Received research grant from: Shriners Hospitals for Children; Physical Sciences Inc, Mediwound.
Francisco Talavera, PharmD, PhD Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference
Disclosure: Received salary from Medscape for employment. for: Medscape.
John Geibel, MD, DSc, MSc, AGAF Vice Chair and Professor, Department of Surgery, Section of Gastrointestinal Medicine, Professor, Department of Cellular and Molecular Physiology, Yale University School of Medicine; Director of Surgical Research, Department of Surgery, Yale-New Haven Hospital; American Gastroenterological Association Fellow
John Geibel, MD, DSc, MSc, AGAF is a member of the following medical societies: American Gastroenterological Association, American Physiological Society, American Society of Nephrology, Association for Academic Surgery, International Society of Nephrology, New York Academy of Sciences, Society for Surgery of the Alimentary Tract
Disclosure: Nothing to disclose.
H Scott Bjerke, MD, FACS Clinical Associate Professor, Department of Surgery, University of Missouri-Kansas City School of Medicine; Medical Director of Trauma Services, Research Medical Center; Clinical Professor, Department of Surgery, Kansas City University of Medicine and Biosciences
H Scott Bjerke, MD, FACS is a member of the following medical societies: American Association for the History of Medicine, American Association for the Surgery of Trauma, American College of Surgeons, Midwest Surgical Association, Royal Society of Medicine, Eastern Association for the Surgery of Trauma, Association for Academic Surgery, National Association of EMS Physicians, Pan-Pacific Surgical Association, Southwestern Surgical Congress, Wilderness Medical Society
Disclosure: Nothing to disclose.
Michael A Grosso, MD Consulting Staff, Department of Cardiothoracic Surgery, St Francis Hospital
Disclosure: Nothing to disclose.
Initial Evaluation and Management of the Burn Patient
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