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Evaluation of the Burn Wound: Management Decisions
Introduction
Advances in the resuscitation of burn patients have greatly improved survival so that death from burn shock has become uncommon. In the 21st century, prompt functional recovery for the burn patient hinges on proper early management of the burn wound. The greatest advance in burn care to date has been the institution of early surgical burn wound excision with an immediate or delayed wound closure strategy individualized to each patient. For years, burns were treated by daily washing, removal of loose dead tissue, and application of some sort of topical nostrum until wounds healed or granulated. Superficial dermal burns healed within 2 weeks, and deep dermal burns healed over many weeks if infection could be prevented. Full-thickness burns lost their eschar in 2–6 weeks by bacterial enzyme production and daily bedside debridement; split-thickness skin grafts were applied usually 3–8 weeks after injury. A 50% graft survival rate was acceptable, and repeated grafting eventually closed the wound. The prolonged and intense inflammatory response led to hypertrophic scars, contractures, and considerable physical and psychological disability.
Burns that heal within 3 weeks generally do so without significant hypertrophic scarring or functional impairment, although long-term pigmentation is unpredictable. Burns needing longer than 3 weeks to heal often result in unsightly hypertrophic scars and functional impairment. State-of-the-art burn care now involves early excision and grafting. The challenge is to define “early.” Knowing which burn wounds benefit from early excision and grafting requires understanding of skin biology and pathophysiological changes caused by thermal injury. In spite of ongoing efforts to objectively assess wound depth, the standard technique for determining burn depth in the 21st century remains clinical assessment of the wound by a burn specialist.
Pathophysiology of the Burn Wound
Skin Biology
Skin protects against fluid and electrolyte loss, infection, and radiation and provides thermal regulation. Skin contact provides clues to the surrounding environment through touch, perception of temperature, and pain. In addition, skin appearance is a major determinant of identity and body image and affects interpersonal interactions. The largest organ in the human body, skin is comprised of two layers: the epidermis and the dermis. Epidermal thickness varies among different body parts: from 0.05 mm on the eyelids to over 1 mm on the soles. Most skin thickness comes from the dermis, which varies with age, gender, and body location.
Epidermis derives from ectoderm; the principal cell is the keratinocyte, but epidermis also contains melanocytes, Langerhans cells, Merkel cells, and inflammatory cells. Keratinocytes begin their division and differentiation at the stratum basale and migrate progressively outward over 2–4 weeks through the stratum spinosum, the stratum granulosum, the stratum lucidum, and the stratum corneum, at which point they are flattened anuclear cornified structures. In a wound with a sloughed epidermal basal layer, keratinocytes proliferate and migrate from the wound edges and epidermal appendages (hair follicles, sweat glands, and sebaceous glands) to achieve epithelialization. Melanocytes produce melanin pigment essential for protection against ultraviolet radiation, and Langerhans cells and other inflammatory cells perform phagocytosis and antigen presentation. After injury, melanocytes regenerate more slowly and less predictably, leading to potential permanent pigment changes.
Epidermal projections (rete ridges) interdigitate with dermal projections (papillae) at the basement membrane zone, which connects the epidermis and dermis via keratinocyte-derived collagen VII anchoring fibrils, critical structures that stabilize the epidermal–dermal junction. Since anchoring fibrils take several months to mature during wound healing, minor shearing forces cause shearing, blistering, and epidermal loss.
The dermis is comprised of the superficial papillary and deeper reticular dermis, separated by a capillary plexus that delivers necessary nutrients to dermal cellular structures. The abundant extracellular matrix, comprised primarily of collagen and elastin fibers, provides the dermal structure; organized collagen fiber orientation provides tensile strength and elastin fibers impart cutaneous elastic recoil properties. Glycosaminoglycans and proteoglycans, such as hyaluronic acid and chondroitin sulfate, attract water to maintain matrix hydration, provide absorption, and regulate cellular cross-talk by binding and releasing inflammatory mediators. Protein turnover, accounting for the high plasticity of skin, increases with mechanical stress and responses to injury. After wounding, microvascular endothelial cells mediate local and systemic inflammatory responses and eventually proliferate and migrate to form new vessels during angiogenesis. Sensory nerves, which traverse into the epidermis, also play a significant role after injury, as they mediate pain and itching, modulate inflammation, and influence the remodeling phase of wound healing. The dermis, like other mesoderm-derived structures, heals not by regeneration but by fibrosis and scarring.
Pathophysiological Changes of Thermal Injury
Applied heat at the cellular level causes denaturation of proteins and loss of plasma membrane integrity. Temperature and duration of contact have a synergistic effect; cell necrosis occurs after 1s of exposure at 156°F (69°C), or after 1h at 113°F (45°C). Following a burn, necrosis occurs at the center of the injury and becomes progressively less severe at the periphery. Jackson's description in 1953 of the three zones of injury remains our conceptual understanding of the burn wound ( Fig. 10.1 ). The zone of coagulation at the center of the wound has no remaining viable cells. A mix of viable and nonviable cells, capillary vasoconstriction, and ischemia characterizes the surrounding zone of stasis; this “at-risk” zone may convert to necrosis in the presence of hypoperfusion, desiccation, edema, or infection. Approximately half of the cells in the zone of stasis undergo apoptosis or necrosis as a result of oxidative stress, ongoing inflammation, and decreased blood flow due to microthrombosis. Systemic factors such as advanced age, diabetes, and other chronic illnesses increase risk for “conversion.” Efforts to enhance wound healing have focused on prevention of necrosis in the zone of stasis since medical care has little impact on the outcome of the zone of coagulation. Protection of this sensitive area is achieved with adequate fluid resuscitation, avoidance of vasoconstriction and edema, and prevention of infection. Optimal wound care consists of nondesiccating dressings, topical antimicrobials, and regular monitoring of the wound. At the periphery of the burn wound, the zone of hyperemia contains viable cells with vasodilation mediated by local inflammatory mediators. Tissue in this zone usually recovers unless complicated by infection or hypoperfusion.
Interest in cooling of the wound to minimize the extent of injury can be traced to antiquity but, firm evidence of its efficacy is lacking. Cooling immediately after injury should not supersede other priorities in the evaluation of the injured patient. The optimal temperature and duration of cooling is unknown but excessive or prolonged cooling may be harmful in that it promotes vasoconstriction and systemic hypothermia. Current guidelines of the American Burn Association recommend limiting cooling to 30 min in the management of minor burns. Modalities to improve dermal perfusion and block injury from released inflammatory mediators have also garnered much interest. Whereas beneficial effects of many pharmacologic agents such as heparin, steroidal and nonsteroidal anti-inflammatory agents, thromboxane inhibitors, and epidermal growth factor have been reported, all remain investigational since none has demonstrated clinical validity.
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