Burn

A burn is a type of injury that may be caused by heat, cold, electricity, chemicals, light, radiation, or friction.[1][2] Burns can be highly variable in terms of the tissue affected, the severity, and resultant complications. Muscle, bone, blood vessel, and epidermal tissue can all be damaged with subsequent pain due to profound injury to nerve endings. Depending on the location affected and the degree of severity, a burn victim may experience a wide number of potentially fatal complications including shock, infection, electrolyte imbalance and respiratory distress.[3] Beyond physical complications, burns can also result in severe psychological and emotional distress due to scarring and deformity. It is generally accepted that a burn affecting more than one percent of the body surface, (approximately area of the casualty's palm) should be assessed by a medical practitioner.

Contents

Classification

The traditional system of classifying burns categorizes them as first-, second-, or third-degree. Sometimes this is extended to include a fourth or even up to a sixth degree, but most burns are first- to third-degree, with the higher-degree burns typically being used to classify burns postmortem. The following are brief descriptions of these classes:[4]

This system is however being replaced by one reflecting the need for surgical intervention. The burn depths are described as either superficial, superficial partial-thickness, deep partial-thickness, or full-thickness.[5]

By degree

Second degree burn.
Major second degree burn caused by contact with boiling water.

Current classification system

A newer classification of "Superficial Thickness", "Partial Thickness" (which is divided into superficial and deep categories) and "Full Thickness" relates more precisely to the epidermis, dermis and subcutaneous layers of skin and is used to guide treatment and predict outcome.

Table 1. A description of the traditional and current classifications of burns.

Nomenclature Traditional nomenclature Depth Clinical findings
Superficial thickness First-degree Epidermis involvement Erythema, minor pain, lack of blisters
Partial thickness — superficial Second-degree Superficial (papillary) dermis Blisters, clear fluid, and pain
Partial thickness — deep Second-degree Deep (reticular) dermis Whiter appearance, with decreased pain. Difficult to distinguish from full thickness
Full thickness Third- or Fourth-degree Dermis and underlying tissue and possibly fascia, bone, or muscle Hard, leather-like eschar, purple fluid, no sensation (insensate)

Other classifications

Main article: Total body surface area

Burns can also be assessed in terms of total body surface area (TBSA), which is the percentage affected by partial thickness or full thickness burns (superficial thickness burns are not counted). The rule of nines is used as a quick and useful way to estimate the affected TBSA.

Causes of burns

Burns are caused by a wide variety of substances and external sources such as exposure to chemicals, friction, electricity, radiation, and extreme temperatures, both hot and cold.

Most chemicals that cause severe chemical burns are strong acids or bases.[6] Chemical burns are usually caused by caustic chemical compounds, such as sodium hydroxide, silver nitrate, and more serious compounds (such as sulfuric acid and Nitric acid).[7] Hydrofluoric acid can cause damage down to the bone and its burns are sometimes not immediately evident.[8]

Electrical burns are caused by an exogenous electric shock. Common causes of electrical burns include workplace injuries or being defibrillated or cardioverted without a conductive gel. Lightning is a rare cause of electrical burns. The internal injuries sustained may be disproportionate to the size of the burns seen, and the extent of the damage is not always obvious. Such injuries may lead to cardiac arrhythmias, cardiac arrest, and unexpected falls with resultant fractures.[9]

Radiation burns are caused by protracted exposure to UV light (as from the sun), tanning booths, radiation therapy (as patients who are undergoing cancer therapy), sunlamps, and X-rays. By far the most common burn associated with radiation is sun exposure, specifically two wavelengths of light UVA, and UVB, the latter being more dangerous. Tanning booths also emit these wavelengths and may cause similar damage to the skin such as irritation, redness, swelling, and inflammation. More severe cases of sun burn result in what is known as sun poisoning.

Scalding

Two day-old scald caused by boiling radiator fluid.

Scalding is caused by hot liquids or gases, most commonly occurring from exposure to high temperature tap water.[10] A Scald is a "bubble" in the skin filled with serous fluid as part of the body's reaction to the heat and nerve damage. Steam is a common gas that causes scalds. The injury is usually regional and usually does not cause death. More damage can be caused if hot liquids enter an orifice. However, deaths have occurred in more unusual circumstances, such as when people have accidentally broken a steam pipe. The demographics that are of the highest risk to suffering from scalding are young children, with their delicate skin, and the elderly over 65 years of age.

Cold burn

Frostbitten hands

A cold burn (compare frostbite) is a kind of burn which arises when the skin is in contact with a low-temperature body. They can be caused by prolonged contact with moderately cold bodies (snow and cold air for instance) or brief contact with very cold bodies such as dry ice, liquid helium, liquid nitrogen, liquid discharged from an upside-down gas duster, or other refrigerants. In such a case, the heat transfers from the skin and organs to the external cold body.

Management

A local anesthetic is usually sufficient in managing pain of minor first-degree and second-degree burns; also Aloe vera sap can be used to heal the burn area. However, systemic anti-inflammatory drugs such as naproxen may be effective in mitigating pain and swelling. Additionally, topical antibiotics such as Mycitracin are useful in preventing infection to the damaged area.[11] Lidocaine can be administered to the spot of injury and will generally negate most of the pain. Regardless of the cause, the first step in managing a person with a burn is to stop the burning process at the source. For instance, with dry powder burns, the powder should be brushed off first. With other burns, such as those caused by exposure to chemicals, the affected area should be rinsed thorougly with a large amount of clean water to remove the caustic agent and any foreign bodies. Cold water should not be applied to a person with extensive burns, however, as it may compromise the burn victim's temperature status.

If the patient was involved in a fire accident, then it must be assumed that he or she has sustained inhalation injury until proven otherwise, and treatment should be managed accordingly. At this stage of management, it is also critical to assess the airway status. Any hint of burn injury to the lungs (e.g. through smoke inhalation) is considered a medical emergency.

Once the burning process has been stopped, the patient should be volume resuscitated according to the Parkland formula (4ml lactated ringers x TBSA % burned x pt. weight kg.), since such injuries can disturb a person's osmotic balance. This formula dictates the amount of Lactated Ringer's solution to deliver in the first twenty four hours after time of injury. This formula excludes first and most second degree burns. Half of the fluid should be given in the first eight hours post injury and the rest in the subsequent sixteen hours. Inhalation injuries in conjunction with thermal burns initially reqiure up to 40-50% more fluid. The formula is a guide only and infusions must be tailored to the urine output and central venous pressure. Inadequate fluid resuscitation causes renal failure and death. Adequate pain management, including administration of opioid analgesics and sometimes other medication (e.g. ketamine, tranquilizers or general anesthetics) are important to alleviates the severe distress from the burns.

Hyperbaric oxygenation has not been shown to be a useful adjunct to traditional treatments.[12]

To help ease the suffering of a burn victim, they may be placed in a special burn recovery bed which evenly distributes body weight and helps to prevent painful pressure points and bed sores. Survival and outcome of severe burn injuries is remarkably improved if the patient is treated in a specialized burn center/unit rather than a hospital. Serious burns, especially if they cover large areas of the body, can result in death.

Reactions and complications

Following a major burn injury heart rate and peripheral vascular resistance increase. This is due to the release of catecholamines from injured tissues, and the relative hypovolemia that occurs from fluid volume shifts. Initially cardiac output decreases. At approximately 24 hours after burn injuries (for patients receiving fluid resuscitation) cardiac output returns to normal, then increases to meet the hypermetabolic needs of the body.

Infection is a major complication of burns. Infection is linked to impaired resistance from disruption of the skin's mechanical integrity and generalized immune suppression. The skin barrier is replaced by eschar. This moist, protein rich avascular environment encourages microbial growth. Migration of immune cells is hampered, and there is a release of intermediaries that impede the immune response. Eschar also restricts distribution of systemically administered antibiotics because of its avascularity.

Risk factors of burn wound infection include: - burn > 30% TBS - full-thickness burn - extremes in age (very young, very old) - preexisting disease e.g. diabetes - virulance and antibiotic resistnace of colonizing organism - failed skin graft - improper initial burn wound care - prolonged open burn wound

Burn wounds are prone to tetanus. A tetanus booster shot is required if individual has not been immunized within the last 5 years.

Circumferential burns of extremities may compromise circulation. Elevation of limb may help to prevent dependent edema. An Escharotomy may be required.

Acute Tubular Necrosis of the kidneys can be caused by myoglobin and hemoglobin released from damaged muscles and red blood cells. This is common in electrical burns or crush injuries where adequate fluid resuscitaion has not been achieved.

See also

References

  1. Burns MedlinePlus Accessed February 25, 2008
  2. Burns Topic Overview WebMD Accessed February 27, 2008
  3. A review of the complications of burns, their origin and importance for illness and death - Abstract J Trauma. 1979 May;19(5):358-69. Accessed February 27, 2008
  4. Burn Degrees Lifespan.org Accessed February 24, 2008
  5. Mertens DM, Jenkins ME, Warden GD (June 1997). "Outpatient burn management". Nurs. Clin. North Am. 32 (2): 343–64. PMID 9115481. 
  6. Chemical Burn Causes emedicine Health Accessed February 24, 2008
  7. Chemical Burn Causes eMedicine Accessed February 24, 2008
  8. Hydrofluoric Acid Burns emedicine Accessed February 24, 2008
  9. Electrical Burns: First Aid Mayo Clinic Accessed February 24, 2008
  10. Scald and Burn Care, Public Education City of Rochester Hills Accessed February 24, 2008
  11. Minor Burns quickcare.org Accessed February 25, 2008
  12. Villanueva E, Bennett MH, Wasiak J, Lehm JP (2004). "Hyperbaric oxygen therapy for thermal burns". Cochrane Database Syst Rev (3): CD004727. doi:10.1002/14651858.CD004727.pub2. PMID 15266540. 

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