A medical history of Governor John B. Connally and his gunshot wounds.

: On November 22, 1963, the Governor of Texas, John Connally, was injured during the assassination of President John F. Kennedy. Multiple authors have documented President Kennedy's injuries, the attempted resuscitation, and the controversies surrounding these events. However, the injuries sustained by Governor Connally have been overlooked by historians predominantly because of the extraordinary importance of the presidential assassination and its impact on the national consciousness. This review discusses the governor's political life, the mechanism of injury, his medical care, and the role the injuries had on his subsequent public life.

Heart rate variability and its association with mortality in prehospital trauma patients.

BACKGROUND: Accurate prehospital triage of trauma patients is difficult, especially in mass casualty situations. Accordingly, the U.S. Military has initiated a program directed toward improving noninvasive prehospital triage algorithms based on available physiologic data. The purpose of this study was to assess heart rate variability and its association with mortality in prehospital trauma patients. METHODS: Trauma patients without significant head injury requiring helicopter transport were identified from a retrospective research database. An equal number, unmatched sample of patients who lived were compared with those who died (n = 15 per group). All patients were transported to a single Level I urban trauma center. The primary independent variable was mortality. Patients with Abbreviated Injury Scale head scores >2 were excluded from the analysis, so that the effects seen were based on hemorrhagic shock. Age, sex, Glasgow Coma Scale score (GCS), blood pressure, pulse pressure, pulse, intubation rate, SpO2, mechanism of injury, transport time, and time of death after admission were recorded. R-waves from the first available 120 seconds of usable data were detected from normal electrocardiograms and heart rate variability was assessed. RESULTS: Patients who died demonstrated a lower GCS (7.9 +/- 1.4 versus 14.4 +/- 0.2; p = 0.0001) and higher intubation rate (53% of patients who died versus 0% patients who lived). Pulse rate, arterial pressure, and SpO2 were not distinguishable statistically between groups (p = 0.08), but pulse pressure was lower in patients who died (39 +/- 3 versus 50 +/- 2 mm Hg; p = 0.01). Compared with patients who lived, those who died had lower normalized low-frequency (LF) power (42 +/- 6 versus 62 +/- 4 LFnu; p = 0.009), higher high-frequency (HF) power (42 +/- 3 versus 32 +/- 3 HFnu; p = 0.04) and higher HF-to-LF ratio (144 +/- 30 versus 62 +/- 11nu; p = 0.01). With absolute HF/LF adjusted for GCS, the intergroup variance accounted for by HF/LF was reduced to 6% (p = 0.16). CONCLUSIONS: Analysis of heart rate variability provides insight into adequacy of autonomic compensation to severe trauma. In our cohort of trauma patients, low pulse pressures coupled with relatively higher parasympathetic than sympathetic modulation characterized and separated patients who died versus patients who survived traumatic injuries when standard physiologic measurements are not different. These data do not suggest advantages of heart rate variability analysis over GCS scores, but suggest future possibilities for remote noninvasive triage of casualties when GCS scores are unattainable.

Radial pulse character relationships to systolic blood pressure and trauma outcomes.

BACKGROUND: Patient measurements that do not require monitoring equipment may be the only way to evaluate casualties in austere conditions to determine treatment and transport priority. Objective. To test the hypothesis that palpable pulse characteristics in the radial artery would estimate systolic blood pressure (SBP) and predict outcome in trauma patients. METHODS: Data were analyzed from the medical records of 342 trauma patients ranging from 18 to 50 years of age. Prehospital data were collected by helicopter emergency medical personnel at the scene of the injury. Based on radial pulse character, patients were divided into normal (n = 313) and weak (n = 29) groups. Those whose medical records did not describe pulse characters were not considered. Differences in SBP, mortality, and medical interventions between the radial-pulse-character groups were evaluated. RESULTS: The SBP taken at the scene was a mean of 26 mm Hg lower in those patients with weak radial pulse characters (102 mm Hg versus 128 mm Hg). Similarly, the lowest mean SBPs recorded in the field between the normal- and weak-pulse-character groups were 112 mm Hg and 99 mm Hg, respectively. Patient mortality increased with weak pulse character such that the mortality rats were 3% for the normal-pulse-character group and 29% for the weak-pulse-character-group (odds ratio = 15.2). CONCLUSIONS: These preliminary data suggest that a weak radial pulse may be an acceptable method for initial rapid evaluation of trauma patients. This simple and rapid method of pulse evaluation should be considered for the triage of trauma patients in field conditions with limited instrumentation.

Prehospital physiologic data and lifesaving interventions in trauma patients.

BACKGROUND: The ability to accurately triage trauma patients can be difficult in the prehospital environment. Prehospital trauma scoring systems have been developed with a goal of determining which patients should be transported immediately to a trauma center, thus benefiting from critical personnel and resource-intensive lifesaving interventions (LSIs). A resource-based endpoint, LSIs, therefore might be the optimal endpoint of prehospital triage scoring and could be used to determine where patients are transported. We hypothesized that simple physiologic data available immediately upon scene arrival would prove predictive of the need for a LSI. METHODS: Trauma patients transported from the injury scene by helicopter were eligible for entry into the study. Prehospital physiologic data and interventions were timed and recorded by flight medical personnel, whereas hospital vital signs, injuries, and interventions were prospectively recorded from the inpatient records. The motor component of the Glasgow Coma Scale was used as an indicator of neurologic function. LSIs were procedures deemed lifesaving by a multidisciplinary panel of trauma experts. RESULTS: Physiologic data were collected from August 2001 to February 2002. Data were collected for 216 random patients transported by the Life Flight helicopter service. There were no differences between LSI and non-LSI patients in age, gender, or transport time, and 80 patients underwent 197 LSIs. The mean age was 33 +/- 17 years, 73% of patients were male, 90% suffered blunt injury, the injury severity score was 14 +/- 9, hypotension (systolic blood pressure of < 90 mm Hg) was present in 14% of cases, and the mortality rate was 6%. Penetrating injury and increasing injury severity score were associated with LSI. Univariate analysis of the physiologic data immediately available in the field revealed that SBP of < 90 mm Hg, motor score of < 6, delayed capillary refill, and increasing pulse were significantly associated with a LSI. However, multivariate analysis revealed that only SBP of < 90 mm Hg and motor score of < 6 were associated with a LSI. When both variables were abnormal, 95% of patients required a LSI; when both variables were normal, 21% of patients required a LSI. CONCLUSIONS: The presence of hypotension or decreased motor score was correlated with the need for LSIs. However, normotensive patients with normal motor scores still frequently required LSIs. Optimal discrimination of this group of patients will require new analytic approaches.