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Mobile medical clinics were established by an international medical relief organization to provide health care to victims of the war in Somalia. The study's purpose was to examine the prevalence of diseases seen and the effectiveness of mobile medical clinics, and to evaluate military support in security and care provisions.
Methods:
This is a descriptive case series conducted over a 6-month period. Physicians determined clinical diagnoses, and clinic personnel assigned security scores (one to five) based on: 1) crowd control; 2) the incidence of looting; and 3) threats of violence by individuals demanding treatment.
Setting:
Mobile medical teams that provided health care to regions in urban and rural Somalia assisted by United States and Italian military forces.
Participants:
At 149 mobile clinics, 25,265 patients were treated.
Interventions:
Medical treatment included dispensing medications, intravenous rehydration, and minor surgical procedures. The effectiveness of security measures was scored based on: 1) effective crowd control; 2) the lack of theft or threats of violence; and 3) the unimpaired operation of the clinic.
Results:
Medical teams treated 25,265 patients. The most common medical problems encountered were skin infections (19.5%), upper and lower respiratory tract infections (16.1%), and gastroenteritis with dehydration (7.1%). Malnutrition was seen in 4.7% of cases, and trauma accounted for only 0.7% of complaints. When military escorts were provided, the mean security score was 43% higher (4.85 ±0.46) as compared to the absence of a military escort (3.40 ±0.60) (p <0.001).
Conclusions:
Mobile medical clinics were found to be effective in this setting despite difficult conditions, limited therapeutic modalities, and few in-patient facilities. Infectious diseases were most common, while malnutrition and trauma were less commonly seen. The cooperation of United States and Italian military forces facilitated relief efforts by maintaining security, particularly in unstable areas.
Prehospital emergency medical services (EMS) personnel, as initial responders to calls for assistance, are in an ideal position to identify abused or neglected elderly. A survey of prehospital personnel in Michigan was conducted to determine the scope of this problem, levels of awareness, and willingness to report cases of elder abuse.
Methods:
The study population was a random sample of 500 prehospital personnel throughout one state. A blinded, self-administered survey was completed by emergency medical technicians (EMTs) and paramedics outlining their practice characteristics, prevalence of abuse in their community, and training available specific to elder abuse. Attitudes concerning the understanding and reporting of geriatric abuse were measured using a Likert-type scale.
Results:
A total of 156 surveys (31%) was completed; 68% of the respondents were paramedics. Respondents had an average of 8.7 years (range: 9 months-30 years) of prehospital emergency-care experience, and evaluated an average of 11 patients (range: 1–59) older than 65 years of age each week. Seventy-eight percent had seen a suspected case of elder abuse or negligence during their careers; 68% had seen a case during the past 12 months (mean: 2.3 cases/yr; range: 0–24 cases/yr). However, surveyed personnel reported only 27% of suspected cases to authorities last year (mean: 0.62 cases/yr). Reasons for not reporting included 1) unsure which authorities take reports; 2) unclear definitions; 3) unaware of mandatory reporting laws; and 4) lack of anonymity. Ninety-five percent of respondents stated that training related to elder abuse was not available through their EMS agency.
Conclusion:
Paramedics and EMTs lack complete understanding of their role in the identification and reporting of elder abuse. This information should be emphasized during EMS training and reinforced through continuing education.
Mask ventilation is a procedure routinely used in emergency medicine. Potential hazards are inadequate alveolar ventilation and inflation of the stomach with air, leading to subsequent regurgitation and aspiration. The aim of this study was to measure lung function and gastric inflation pressures during mask ventilation.
Methods:
For this purpose, 31 patients scheduled for routine urological procedures were studied during induction of anesthesia. Lung function was assessed by recording respiratory flow and pressure directly at the face mask. Gastric inflation was observed with a microphone taped to the epigastric area.
Results:
Gastric inflation occurred in 22 of the 31 patients. Mean gastric inflation pressure was 27.5 ±6.55 cm H2O, mean compliance was 67 ±24.1 ml/cm H2O, mean resistance was 17.4 ±6.41 cm H2O/L/sec, and the mean respiratory time constant was 1.1 ±0.26 seconds.
Conclusions:
These data suggest that inspiratory pressure be limited to 20 cm H2O, and that an inspiratory time of at least four times the respiratory time constant be allowed. Monitoring airway pressure and gastric inflation is a simple technique that may improve the safe-ty of patients during mask ventilation.
The resuscitation rate from out-of-hospital cardiac arrest is low. There are many factors to be considered as contributing to this phenomenon. One factor not previously considered is the impact of a moving ambulance environment on the ability to perform closed-chest compressions.
Hypothesis:
Proper closed-chest compressions can be performed in a moving ambulance.
Methods:
A cardiopulmonary resuscitation (CPR) training mannequin with an attached skill meter (Skillmeter ResusciAnnie®, Laerdal, Armonk, N. Y., USA) that measures each chest compression for proper depth and hand placement was used. Ten emergency medical technician-basic (EMT-B) certified prehospital providers were assigned into one of five teams. Each team performed a total of four sessions of five minutes of continuous closed-chest compressions on the mannequin. Two sessions were done by each team: one in the control environment with the mannequin placed on the floor, and the other in the experimental environment with the mannequin placed in the back of a moving ambulance. The ambulance was operated without warning lights and siren, and all traffic rules were obeyed. The percentage of correct closed-chest compressions was recorded for each session, and the mean values were compared using Student's t-test with alpha set at 0.01 for statistical significance.
Results:
Ten sessions of compressions were done in both environments. The mean percentage of correct compressions was 77.6 ±15.6 for the control group and 45.6 ±18.3 for the ambulance group (p = 0.0005).
Conclusion:
A moving ambulance environment appears to impair the ability to perform closed-chest compressions.
Although many emergency medical services (EMS) providers are concerned about liability litigation, no comprehensive, national studies of EMS appelate cases have been published. Information about these cases and the use of liability immunity (sovereign immunity, emergency medical care immunity, or Good Samaritan immunity) as a defense could be used for EMS risk management and better patient care.
Objective:
To review recent EMS system civil litigation cases to determine their common characteristics and the number that used liability immunity as a legal defense.
Methods:
An observational study of the WESTLAW computerized database of legal cases from all state and federal appellate courts. All legal cases that named a member of the EMS system as a defendant, involved either a patient-care incident or ambulance collision, and received an appellate court opinion from 1987 through 1992, were studied.
Results:
Eighty-six cases were identified and analyzed. Most cases (85%) were related to a patient-care incident, and 71 % of the cases involved a death or significant physical injury. More than 49% of the patient cases alleged inadequate assessment or treatment, and 27% alleged delay in ambulance arrival or no ambulance arrival. There were 11 cases (15%) that alleged no transport of the patient to the hospital. Liability immunity was used as a defense in 53% of the cases. The appellate courts ruled in favor of 68% of the defendants that did not use an immunity defense and in favor of 72% of those that did use liability immunity.
Conclusion:
There have been a large number of recent appellate cases involving EMS systems. The common characteristics of many of these cases demonstrate the need for providing rapid ambulance arrival, proper assessment and treatment, and rapid patient transportation to a hospital. Although liability immunity was used as a legal defense by most EMS system defendants, the appellate court outcome was similar regardless of its use.
Complex humanitarian emergencies lack a mechanism to coordinate, communicate, assess, and evaluate response and outcome for the major participants (United Nations, Intenational Committee of the Red Cross, non-governmental organizations and military forces). Success in these emergencies will depend on the ability to accomplish agreed upon measures of effectiveness (MOEs). A recent civil-military humanitarian exercise demonstrated the ability of participants to develop consensus-driven MOEs. These MOEs combined security measures utilized by the military with humanitarian indicators recognized by relief organizations. Measures of effectiveness have the potential to be a unifying disaster management tool and a partial solution to the communication and coordination problems inherent in these complex emergencies.
Pediatric mortality is predicted by age, presence of head trauma, head trauma with a low Glasgow Coma Scale (GCS) score, a low Pediatric Trauma Score (PTS), and transport directly to a pediatric trauma center.
Population:
Studied were 1,429 patients younger than 16 years old admitted to or declared dead on arrival (DOA) in a pediatric trauma center from January through October, 1988. The trauma system, which served 3-million persons, included six pediatric trauma centers.
Methods:
Data were obtained by a retrospective review of summary statistics provided to the Chicago Department of Health by the pediatric trauma centers.
Results:
Overall mortality was 4.8% (68 of 1429); 32 of the patients who died (47.1%) were DOA. The in-hospital mortality rate was 2.6%. Head injury was the principal diagnosis in 46.2% of admissions and was a factor in 72.2% of hospital deaths. The mortality rate was 20.3% in children with a GCS≤10 and 0.4% when the GCS was >10 (odds ratio [OR] = 67.0, 95% CI = 15.0–417.4). When the PTS was ≤ 5, mortality was 25.6%; with a PTS > 5, the mortality was 0.2% (OR = 420.7, 95% CI = 99.3–2,520). Although transfers to a pediatric trauma center accounted for 73.6% of admissions, direct field triage to a pediatric trauma center was associated with a 3.2 times greater mortality risk (95% CI = 1.58–6.59). Mortality rates were equal for all age groups. Pediatric trauma center volume did not influence mortality rates.
Conclusions:
Head injury and death occur in all age groups, suggesting the need for broad prevention strategies. Specific GCS and PTS values that predict mortality can be used in emergency medical services (EMS) triage protocols. Although the high proportion of transfers mandates systemwide transfer protocols, the lower mortality in these patients suggests appropriate EMS field triage. These factors should be considered as states develop pediatric trauma systems.