The diamond of death: Hypocalcemia in trauma and resuscitation.

INTRODUCTION: Early recognition and management of hemorrhage, damage control resuscitation, and blood product administration have optimized management of severe trauma. Recent data suggest hypocalcemia exacerbates the ensuing effects of coagulopathy in trauma. OBJECTIVE: This narrative review of available literature describes the physiology and role of calcium in trauma resuscitation. Authors did not perform a systematic review or meta-analysis. DISCUSSION: Calcium is a divalent cation found in various physiologic forms, specifically the bound, inactive state and the unbound, physiologically active state. While calcium plays several important physiologic roles in multiple organ systems, the negative hemodynamic effects of hypocalcemia are crucial to address in trauma patients. The negative ramifications of hypocalcemia are intrinsically linked to components of the lethal triad of acidosis, coagulopathy, and hypothermia. Hypocalcemia has direct and indirect effects on each portion of the lethal triad, supporting calcium's potential position as a fourth component in this proposed lethal diamond. Trauma patients often present hypocalcemic in the setting of severe hemorrhage secondary to trauma, which can be worsened by necessary transfusion and resuscitation. The critical consequences of hypocalcemia in the trauma patient have been repeatedly demonstrated with the associated morbidity and mortality. It remains poorly defined when to administer calcium, though current data suggest that earlier administration may be advantageous. CONCLUSIONS: Calcium is a key component of trauma resuscitation and the coagulation cascade. Recent data portray the intricate physiologic reverberations of hypocalcemia in the traumatically injured patient; however, future research is needed to further guide the management of these patients.

Interrater Agreement and Reliability of Burn Size Estimations Between Emergency Physicians and Burn Unit.

The initial approach to burn injuries has remained relatively unchanged over the past several decades and revolves around trauma assessment and fluid resuscitation, frequently initiated in the emergency department (ED). While previous research suggests that emergency physicians (EP) are poor estimators at total body surface area (TBSA) affected, we believe that estimation differences are improving, specifically at academic centers with co-located burn units that emphasize burn injury education. This study investigated the interrater agreement and reliability of burn size estimations at an academic ED and its co-located burn unit. This single-center, retrospective study was conducted at a large academic ED with a co-located burn unit. The study included adult patients admitted to the burn unit after receiving paired burn size estimations from EPs and the burn unit. The primary endpoint was the interrater agreement, measured by the kappa coefficient, κ, of 10% TBSA estimation intervals. The secondary endpoint was the intraclass correlation coefficient (ICC), evaluating the reliability of exact, nonranged, and TBSA estimations. A chart review was performed for patients evaluated from November 1, 2016 to July 31, 2019. One thousand one hundred and eighty-four patients were admitted to the burn unit, 1176 of which met inclusion criteria for the primary endpoint. The κ of TBSA between EPs and the burn unit was 0.586, while the weighted κ was 0.775. These values correlate with moderate and substantial agreements, respectively. Additionally, 971 patients had exact TBSA estimations from paired EPs and the burn unit which were used for the secondary endpoint. The ICC between EPs and the burn unit was 0.966, demonstrating an excellent reliability. Further sub-analysis was performed, revealing mean over- and underestimation differences of exact TBSA estimations of 3.93 and 2.93, respectively. EPs at academic institutions with co-located burn units are accurate estimators of TBSA in the assessment of burn injuries. We believe that burn education, to include core rotations within the burn unit, plays a major role in improved burn size estimations.