Burns

Description

Anesthesia providers are critical members of the multidisciplinary team that is required to treat patients with severe burn injuries, as well as burn reconstruction procedures.
Severe burns affect every organ system, present multiple medical and psychological challenges, and must be treated with prompt and vigilant care.

Epidemiology

Incidence

In the US: 700,000/year; males: 70%, females: 30%; children <5 years: 17%; patients >60 years: 12%

Prevalence

Mild burns: 600/100,000 inhabitants
Severe burns: 5/100,000 inhabitants

Morbidity

Chronic pain, cosmetic consequences, contractures with resultant loss of limb function, long-term rehabilitation, need for repeat surgeries, and financial impact

Mortality

Overall mortality is 3.7% and increases with advancing age (age <16 years: 0.3–1.0%; age >80 years: 27.0%)
Increases with the total body surface area (%TBSA) affected
Increases with smoke inhalation injury

Etiology/Risk Factors

Etiology: Fire/flame (41.6%); scald (31.0%; children are at a higher risk); contact with a hot object (8.8%); electrical (3.8%)
Circumstances of injury: Home (66%); accident, non-work related (66%); accident, work related (14.6%); accident, recreation (4.8%)

Physiology/Pathophysiology

Severe inflammation has been implicated with many post-burn complications: Triggers loss of microvascular wall integrity, intravascular plasma and protein depletion, and interstitial edema (peak edema occurs at 24 hours).
Inhalation injury is direct damage to the upper and lower airways and lungs from heat, smoke, or toxic fume inhalation. Inhalation of carbon monoxide produces carboxyhemoglobin, and inhalation of cyanide fumes causes inhibition of the mitochondrial electron transport chain.

Anesthetic GOALS/GUIDING Principles

If inhalation injury or airway edema is suspected, secure the airway early before worsening edema makes intubation difficult or impossible.
Appropriate fluid management, maintenance of normothermia, glucose control, antibiotic prophylaxis, and ventilatory management have been shown to improve outcome in the ICU setting; these efforts should be extended perioperatively by the anesthesia provider.

Diagnosis ⬆ ⬇

Symptoms

Symptoms of inhalation injury: Voice change, dysphagia, dyspnea

History

Etiology of burn injury, risk factors for inhalation injury (closed space, loss of consciousness), associated injuries, pre-existing medical conditions

Signs/Physical Exam

Signs of inhalation injury include singed eyebrows or nasal hair, facial burns, facial edema, carbonaceous sputum, respiratory distress, and inspiratory stridor.
Standard airway exam
Size of burned area (%TBSA)

Treatment History

Airway management, intravenous access, fluids
Dialysis in patients with acute kidney injury; early continuous veno-venous hemofiltration may reduce 28-day mortality, acute lung injury severity, and respiratory distress (1).
Plasma exchange therapy may decrease the inflammatory response; this is still being investigated (2).
Blood transfusions; patients with comorbidities are more likely to receive blood, especially with small burn injuries (<10% TBSA) (3). However, this may increase infectious complications and mortality. Outcome studies have not provided information on the ideal transfusion paradigm with significant comorbidities.

Medications

Naltrexone for pruritus may affect intraoperative opioid requirements.
TPN should be continued perioperatively; patients are hypermetabolic and have increased caloric requirements.
Sedation for intubated patients
Narcotics

Diagnostic Tests & Interpretation

Labs/Studies

CBC
Complete metabolic panel
Coagulation panel
ABG for baseline acid–base status, lactate, and base deficit trends
Carbon monoxide and methemoglobin levels
Type and cross
Baseline chest radiography

CONCOMITANT ORGAN DYSFUNCTION

Cardiovascular: Intravascular volume depletion, decreased systemic vascular resistance, myocardial depression, and deep vein thrombosis
Pulmonary: Pulmonary edema, impaired gas exchange, reduced chest wall and airway compliance, dysfunctional cilia, respiratory failure, PNA, and ARDS
Renal: Acute kidney injury
Hepatic: Congestion, fatty deposition, cholestasis, centrilobular necrosis, and activation of acute phase reactants
Gastrointestinal: Stress ulcers, decreased motility, ileus, decreased absorption, bacterial translocation, edema, abdominal hypertension, and compartment syndrome
Musculoskeletal: Acute and chronic wasting, contractures
Neuroendocrine: Hypermetabolism increases catecholamines and catabolic hormones, oxygen demand, production of carbon dioxide, muscle wastage, and glucose derangements.

Circumstances to delay/Conditions

The need to treat carbon monoxide poisoning with hyperbaric oxygen should be weighed against the need for emergent surgery.

Classifications

Degrees of burn:
- First-degree, superficial burn extends into epidermis, blanches, does not blister, and is intensely painful.
- Second-degree, superficial partial-thickness burn extends into superficial or papillary dermis, blanches, blisters, and is severely painful.
- Second-degree, deep partial-thickness burn extends into deep or reticular dermis, does not blanch or blister, and is less painful.
- Third-degree, full-thickness burn extends into subcutaneous tissue or deeper, is dry like leather or white, and is minimally painful.
Extent of burn:
- Wallace's Rule of Nine can be used to estimate the %TBSA burned in adults.
- The Lund–Browder chart can be used to estimate %TBSA in children.
ABA grading system:
- Minor burns: <10% TBSA in adults, <5% TBSA in children or elderly patients, <2% full-thickness burn
- Moderate burn: 10–20% TBSA in adults, 5–10% TBSA in children or elderly patients, 2–5% full-thickness burn; high-voltage burn, circumferential burn, suspected inhalation injury, concomitant medical problems
- Major burn: >20% TBSA in adults, >10% TBSA in children or elderly, >5% full-thickness burn, high-voltage burn, known inhalation injury; any significant burn to face, eyes, genitalia, joints or significant associated injuries

Treatment ⬆ ⬇

PREOPERATIVE PREPARATION

Premedications

Benzodiazepines or ketamine may relieve anxiety and decrease opiate requirements.
Dexmedetomidine has been shown to improve the level of sedation compared to benzodiazepines in burn patients in the ICU (4).

INTRAOPERATIVE CARE

Choice of Anesthesia

General anesthesia is required for most burn injury patients; however, regional anesthesia is an option in selected cases.

Monitors

Standard ASA monitors
Intra-arterial blood pressure; femoral artery cannulation is often used in pediatric patients. There is a 1.9% incidence of lost pulses, some requiring thrombectomies; monitoring of distal pulses should be performed to avoid critical ischemia (5).
Core temperature
Foley catheter
Vascular access: Place large-bore IV catheters in non-burned areas whenever possible; most patients will require central venous access once stabilized; intraosseous access is acceptable for primary resuscitation.

Induction/Airway Management

Early rapid-sequence intubation or awake fiberoptic intubation may be the safest approach in patients with inhalation injury or airway edema.
Succinylcholine can be used during the first 48 hours following burn injury. It should not be used after the initial 48 hours or within 1 year of burn injury (extrajunctional receptor proliferation).
Non-depolarizing muscle relaxants are safe in burn injury patients.

Maintenance

Prophylactic antibiotics; the impairment of physical barriers and an immune-compromised state increase the likelihood of infection (Pseudomonas aeruginosa is common).
Inhalational anesthesia or TIVA is appropriate.
Ventilation: High FIO₂ in patients with carbon monoxide poisoning. High-frequency oscillatory ventilation has been shown to improve oxygenation with concurrent ARDS; consider utilizing an ICU ventilator intraoperatively.
Fluid resuscitation to treat burn shock, maintain hemodynamic stability and urine output
- Parkland formula: Lactated Ringer's 4 mL/kg/%TBSA over 24 hours with half in the first 8 hours and the remaining half over the next 16 hours
- Modified Brooke formula: Lactated Ringer's 2 mL/kg/%TBSA over 24 hours
- Children <20 kg: Lactated Ringer's 3 mL/kg/%TBSA over 24 hours plus hourly maintenance thereafter (4 mL/kg for the first 10 kg + 2 mL/kg for next 10 kg + 1 mL/kg)
- Over-resuscitation or "fluid creep" can exacerbate pulmonary edema, chest wall edema, or compartment syndrome of limbs or abdomen. Colloids have not been shown to improve clinical outcomes (6) [A].
- Following inhalation injury, the 24-hour fluid requirement increases (6) [A], (7) [A]. Central venous pressures and urine output can aid with management.
Avoid hypothermia; intraoperative hypothermia during burn excision has been linked to the development of postoperative lung inflammation. Decreases of >1°C demonstrated increased neutrophils 24 hours postsurgery compared to normothermics (8).
Monitor hemoglobin, electrolytes, coagulation, as well as acid–base status.
High-dose opiates for analgesia; the increased volume of distribution reduces drug concentrations.
Local anesthetic infiltration is often used with epinephrine to reduce blood loss.
Tight glucose control (blood sugars <150 mg/dL) and decreased variability have a decreased sepsis rate and mortality in ICU patients (9). Efforts should be continued perioperatively by the anesthesia provider.

Extubation/Emergence

Patients with severe burns and/or inhalation injury are likely to remain intubated after surgery and in the ICU during the acute post-burn injury period. Studies have shown that they have a significantly higher rate of failed extubation; 30% compared to the general ICU population (10) [B].

Follow-Up ⬆ ⬇

Bed Acuity

Transfer to a burn center is indicated for: Age <5 years or >60 years; burns to the face, hands, perineum, joints, or other areas of function; >15% TBSA partial-thickness or >5% full-thickness burn; inhalation injury; chemical, high voltage; concomitant trauma.

Medications/Lab Studies/Consults

Severe burn injury is a permanent, life-altering experience for the patient and his or her family and requires a multimodal approach and often long-term support: Pain specialists, rehabilitation medicine specialists, plastic surgeons, psychiatrists, physical therapists, social workers, and financial counselors.

Complications

Pneumonia (3%), urinary tract infection (2%), wound infection (2%), respiratory failure (3%), septicemia (2%), cellulitis (1.5%), renal failure (1%)

References ⬆ ⬇

Chung KK , Lundy JB , Matson JR , et al. Continuous veno-venous hemofiltration in severely burned patients with acute kidney injury: A cohort study. Crit Care. 2009;13:R62.
Klein MB , Edwards JA , Kramer CB , et al. The beneficial effects of plasma exchange after severe burn injury. J Burn Care Res. 2009;30:243–248.
Boral L , Kowal-Vern A , Yogore M , et al. Transfusions in burn patients with/without comorbidities. J Burn Care Res. 2009;30:268–273.
Talon MD , Woodson LC , Sherwood ER , et al. Intranasal dexmedetomidine premedication is comparable with midazolam in burn children undergoing reconstructive surgery. J Burn Care Res. 2009;30:599–605.
Mourot JM , Oliveira HM , Woodson LC , et al. Complications of femoral artery catheterization in pediatric burn patients. J Burn Care Res. 2009;30:432–436.
Saffle JR. The phenomenon of "fluid creep" in acute burn resuscitation. J Burn Care Res. 2007;28(3):382–395.
Latenser BA. Critical care of the burn patient: The first 48 hours. Crit Care Med. 2009;37(10):2819–2826.
Oda J , Kasai K , Noborio M , et al. Hypothermia during burn surgery and postoperative acute lung injury in extensively burned patients. J Trauma. 2009;66:1525–1529.
Pidcoke HF , Salinas J , Wanek SM , et al. Glucose variability is associated with high mortality after severe burn. J Trauma. 2009;67:990–995.
Smailes ST , Martin RV , McVicar AJ. The incidence and outcome of extubation failure in burn intensive care patients. J Burn Care Res. 2009;30(3):393–394.

section name header

Basics ⬇

Incidence

Prevalence

Morbidity

Mortality

Diagnosis ⬆ ⬇

History

Signs/Physical Exam

Labs/Studies

Treatment ⬆ ⬇

Premedications

Choice of Anesthesia

Monitors

Induction/Airway Management

Maintenance

Extubation/Emergence

Follow-Up ⬆ ⬇

References ⬆ ⬇

Additional Reading ⬆ ⬇

Codes ⬆ ⬇

Clinical Pearls ⬆ ⬇

Author(s) ⬆

section name header

Basics ⬇

Incidence

Prevalence

Morbidity

Mortality

Diagnosis ⬆ ⬇

History

Signs/Physical Exam

Labs/Studies

Treatment ⬆ ⬇

Premedications

Special Concerns for Informed Consent

Choice of Anesthesia

Monitors

Induction/Airway Management

Maintenance

Extubation/Emergence

Follow-Up ⬆ ⬇

References ⬆ ⬇

Additional Reading ⬆ ⬇

Codes ⬆ ⬇

Clinical Pearls ⬆ ⬇

Author(s) ⬆