The CPR outcomes of online medical video instruction versus on-scene medical instruction using simulated cardiac arrest stations

A common tenet in emergency medical services (EMS) is that faster response equates to better patient outcome, translated by some EMS operations into a goal of a response time of 8 minutes or less for advanced life support (ALS) units responding to life-threatening events. To explore whether an 8-minute EMS response time was associated with mortality. This was a one-year retrospective cohort study of adults with a life-threatening event as assessed at the time of the 9-1-1 call (Medical Priority Dispatch System Echo- or Delta-level event). The study setting was an urban all-ALS EMS system serving a population of approximately 1 million. Response time was defined as 9-1-1 call receipt to ALS unit arrival on scene, and outcome was defined as all-cause mortality at hospital discharge. Potential covariates included patient acuity, age, gender, and combined scene and transport interval time. Stratified analysis and logistic regression were used to assess the response time-mortality association. There were 7,760 unit responses that met the inclusion criteria; 1,865 (24%) were ≥8 minutes. The average patient age was 56.7 years (standard deviation = 21.5). For patients with a response time ≥8 minutes, 7.1% died, compared with 6.4% for patients with a response time ≤7 minutes 59 seconds (risk difference 0.7%; 95% confidence interval [CI]: -0.5%, 2.0%). The adjusted odds ratio of mortality for ≥8 minutes was 1.19 (95% CI: 0.97, 1.47). An exploratory analysis suggested there may be a small beneficial effect of response ≤7 minutes 59 seconds for those who survived to become an inpatient (adjusted odds ratio = 1.30; 95% CI: 1.00, 1.69). These results call into question the clinical effectiveness of a dichotomous 8-minute ALS response time on decreasing mortality for the majority of adult patients identified as having a life-threatening event at the time of the 9-1-1 call. However, this study does not suggest that rapid EMS response is undesirable or unimportant for certain patients. This analysis highlights the need for further research on who may benefit from rapid EMS response, whether these individuals can be identified at the time of the 9-1-1 call, and what the optimum response time is.

Bystander cardiopulmonary resuscitation (CPR) significantly improves survival of cardiac arrest victims. Dispatch assistance increases bystander CPR, but the quality of dispatcher-assisted CPR remains unsatisfactory. This study was conducted to assess the effect of adding interactive video communication to dispatch instruction on the quality of bystander chest compressions in simulated cardiac arrests. A randomized controlled study with a scenario developed to simulate cardiac arrest in a public place. The victim was simulated by a mannequin and the cell phone for dispatch assistance was a video cell phone with both voice and video modes. Chest compression-only CPR instruction was used in the dispatch protocol. Ninety-six adults without CPR training within 5 years were recruited. The subjects were randomized to receive dispatch assistance on chest compression with either voice instruction alone (voice group, n = 53) or interactive voice and video demonstration and feedback (video group, n = 43) via a video cell phone. Performance of chest compression-only CPR throughout the scenario was videotaped. The quality of CPR was evaluated by reviewing the videos and mannequin reports. Chest compressions among the video group were faster (median rate 95.5 vs. 63.0 min-1, p < 0.01), deeper (median depth 36.0 vs. 25.0 mm, p < 0.01), and of more appropriate depth (20.0% vs. 0%, p < 0.01). The video group had more "hands-off" time (5.0 vs. 0 second, p < 0.01), longer time to first chest compression (145.0 vs. 116.0 seconds, p < 0.01) and total instruction time (150.0 vs. 121.0 seconds, p < 0.01). The addition of interactive video communication to dispatcher-assisted chest compression-only CPR initially delayed the commencement of chest compressions, but subsequently improved the depth and rate of compressions. The benefit was achieved mainly through real-time feedback.

Emergency medical services (EMSs) vary considerably. While some are physician staffed, most systems are run by paramedics. The objective of this randomized, controlled simulation study was to compare the emergency care between physician staffed EMS teams (control group) and paramedic teams that were supported telemedically by an EMS physician (telemedicine group). Overall 16 teams (1 EMS physician, 2 paramedics) were randomized to the control group or the telemedicine group. Telemedical functionalities included two-way audio communication, transmission of vital data (numerical values and curves) and video streaming from the scenario room to the remotely located EMS physician. After a run-in scenario all teams completed four standardized scenarios, in which no highly invasive procedures (e.g. thoracic drain) were required, two using high-fidelity simulation (burn trauma, intoxication) and two using standardized patients (renal colic, barotrauma). All scenarios were videotaped and analyzed by two investigators using predefined scoring items. Non case-specific items (31 vs. 31 scenarios): obtaining of 'symptoms', 'past medical history' and 'events' were carried out comparably, but in the telemedicine group 'allergies' (17 vs. 28, OR 7.69, CI 2.1-27.9, p=0.002) and 'medications' (17 vs. 27, OR 5.55, CI 1.7-18.0, p=0.004) were inquired more frequently. No significant differences were found regarding the case-specific items and in both groups no potentially dangerous mistreatments were observed. Telemedically assisted paramedic care was feasible and at least not inferior compared to standard EMS teams with a physician on-scene in these scenarios. Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.