Jureta W. Horton

Because of their extensive wounds, burn patients are chronically exposed to inflammatory mediators. Thus, burn patients, by definition, already have "systemic inflammatory response syndrome." Current definitions for sepsis and infection have many criteria (fever, tachycardia, tachypnea, leukocytosis) that are routinely found in patients with extensive burns, making these current definitions less applicable to the burn population. Experts in burn care and research, all members of the American Burn Association, were asked to review the literature and prepare a potential definition on one topic related to sepsis or infection in burn patients. On January 20, 2007, the participants met in Tucson, Arizona to develop consensus for these definitions. After review of the definitions, a summary of the proceedings was prepared. The goal of the consensus conference was to develop and publish standardized definitions for sepsis and infection-related diagnoses in the burn population. Standardized definitions will improve the capability of performing more meaningful multicenter trials among burn centers.

CONTEXT: Sepsis, organ failure, and shock remain common among patients with moderate to severe burn injuries. The inability of clinical factors to identify at-risk patients suggests that genetic variation may influence the risk for serious infection and the outcome from severe injury. OBJECTIVE: Resolution of genetic variants associated with severe sepsis following burn injury. PATIENTS: A total of 159 patients with burns > or =20% of their total body surface area or any smoke inhalation injury without significant non-burn related trauma (injury severity score (ISS)> or =16), traumatic or anoxic brain injury, or spinal cord injury and who survived more than 48 h post-admission. METHODS: Candidate single nucleotide polymorphisms (SNPs) within bacterial recognition (TLR4 +896, CD14 -159) and inflammatory response (TNF-alpha -308, IL-1beta -31, IL-6 -174) loci were evaluated for association with increased risk for severe sepsis (sepsis plus organ dysfunction or septic shock) and mortality. RESULTS: After adjustment for age, full-thickness burn size, ethnicity, and gender, carriage of the TLR4 +896 G-allele imparted at least a 1.8-fold increased risk of developing severe sepsis following a burn injury, relative to AA homozygotes (adjusted odds ratio (aOR) 6.4; 95% confidence interval (CI) 1.8 to 23.2). Carriage of the TNF-alpha -308 A-allele imparted a similarly increased risk, relative to GG homozygotes (aOR = 4.5; 95% CI 1.7 to 12.0). None of the SNPs examined were significantly associated with mortality. CONCLUSIONS: The TLR4 +896 and TNF-alpha -308 polymorphisms were significantly associated with an increased risk for severe sepsis following burn trauma.

Although numerous studies have provided evidence that the inflammatory cytokines TNF-alpha and IL-1beta have significant negative inotropic effects, the role of the interleukins in burn-mediated cardiac dysfunction has not been defined. Furthermore, most studies examining the cardiotoxic effects of inflammatory cytokines have ignored the complex inflammatory milieu that occurs in the intact subject with trauma, sepsis, or ischemic heart disease. Therefore, this study examined the time course of IL-1beta and IL-6 secretion by cardiomyocytes after burn trauma, and additional studies examined the effects of these cytokines alone or in combination with TNF-alpha on cardiac contractile performance (Langendorff). Sprague-Dawley rats were given a full thickness burn injury over 40% of the total body surface area; fluid resuscitation was lactated Ringers solution, 4 mL/kg per burn percentage of burn area. Sham burn animals received identical anesthesia and handling, but no burn injury. Rats were sacrificed at several different times postburn, and isolated hearts (n = 4-5 rats/group/time period) were perfused with collagenase-containing buffer to prepare cardiomyocytes or were perfused in vitro to examine cardiac contractile function (n = 5-6 rats/group/time period). Additional naive control rats (n = 10) were included to prepare cardiomyocytes that, in turn, were challenged with different concentrations of either IL-1beta, IL-6, or TNF-alpha alone or in combination for several time periods (CO2 incubator at 37 degrees C for 1-3 h). Finally, inflammatory cytokines alone or in combination were added to the perfusate of hearts isolated from additional control rats (n = 6-7/group) to assess the cardiac contraction and relaxation effects of cytokine challenge. Despite aggressive fluid resuscitation, burn trauma produced a time-related increase in cardiomyocyte secretion of IL-1beta, IL-6, and TNF-alpha. Exposure of naive cardiomyocytes prepared from control rats to each cytokine alone or combined cytokine challenge produced a time-dependent and concentration-dependent decrease in cell viability and an increase in supernatant creatine kinase levels. Either IL-1beta or TNF-alpha produced greater cardiac defects than IL-6 when added separately to Langendorff-perfused hearts; dysfunction was maximal with combined cytokine challenge (IL-1beta plus TNF-alpha plus IL-6). The data confirm that burn trauma upregulates inflammatory cytokine secretion by cardiomyocytes and suggest that these inflammatory cytokines act in concert to produce burn-mediated cardiac contractile dysfunction.