Asunto(s)
Técnicas de Laboratorio Clínico , Hipercalcemia/diagnóstico , Anciano , Calcio/análisis , Femenino , HumanosRESUMEN
CONTEXT: Following the Boston Marathon bombings in April 2013, pathology departments at hospitals across Boston, Massachusetts received numerous amputated limbs, as well as other surgical specimens from trauma surgeries. In the absence of clear guidelines, each department faced uncertainties in performing gross examination of these specimens. OBJECTIVE: To develop a protocol for processing surgical specimens with forensic evidence. DESIGN: We collaborated with representatives who knew the practices at 3 major Boston hospitals, the Office of the Chief Medical Examiner of Massachusetts, and a senior team leader for the evidence response team for the Boston, Massachusetts division of the US Federal Bureau of Investigation to construct a protocol for processing specimens with forensic evidence. RESULTS: A simple and robust protocol approved by experts in forensic evidence collection was developed. Important points in this protocol include (1) assigning the task of processing the specimens to one individual or one team of individuals, (2) photographing all specimens before and after washing, (3) obtaining a radiograph of each specimen, and (4) identifying a secure area to store forensic evidence. CONCLUSIONS: When acts of terror occur, protocols provide order and clarification to the processing of surgical specimens. We propose a protocol that provides guidance for pathology departments across the country to handle trauma-related surgical specimens with forensic evidence in an efficient manner to allow optimal patient care and a secure way of gathering forensic evidence.
Asunto(s)
Patologia Forense/métodos , Patologia Forense/normas , Manejo de Especímenes/métodos , Manejo de Especímenes/normas , Boston , Humanos , TerrorismoRESUMEN
In a murine model of acute fatal pneumonia, we previously showed that nasal immunization with a live-attenuated aroA deletant of Pseudomonas aeruginosa strain PAO1 elicited LPS serogroup-specific protection, indicating that opsonic Ab to the LPS O Ag was the most important immune effector. Because P. aeruginosa strain PA14 possesses additional virulence factors, we hypothesized that a live-attenuated vaccine based on PA14 might elicit a broader array of immune effectors. Thus, an aroA deletant of PA14, denoted PA14DeltaaroA, was constructed. PA14DeltaaroA-immunized mice were protected against lethal pneumonia caused not only by the parental strain but also by cytotoxic variants of the O Ag-heterologous P. aeruginosa strains PAO1 and PAO6a,d. Remarkably, serum from PA14DeltaaroA-immunized mice had very low levels of opsonic activity against strain PAO1 and could not passively transfer protection, suggesting that an antibody-independent mechanism was needed for the observed cross-serogroup protection. Compared with control mice, PA14DeltaaroA-immunized mice had more rapid recruitment of neutrophils to the airways early after challenge. T cells isolated from P. aeruginosa DeltaaroA-immunized mice proliferated and produced IL-17 in high quantities after coculture with gentamicin-killed P. aeruginosa. Six hours following challenge, PA14DeltaaroA-immunized mice had significantly higher levels of IL-17 in bronchoalveolar lavage fluid compared with unimmunized, Escherichia coli-immunized, or PAO1DeltaaroA-immunized mice. Antibody-mediated depletion of IL-17 before challenge or absence of the IL-17 receptor abrogated the PA14DeltaaroA vaccine's protection against lethal pneumonia. These data show that IL-17 plays a critical role in antibody-independent vaccine-induced protection against LPS-heterologous strains of P. aeruginosa in the lung.