Introduction
Texas A&M University (TAMU; College Station, Texas USA) ranked third in the nation for gameday attendance in 2022 with an average of 97,213 fans per game.1 The university’s five-year average game attendance sits at 84,455 fans per game.1 The population of College Station, Texas is just over 120,500 people,2 meaning the number of people in College Station swells on home game weekends (HGWs), creating the potential for increased stress on local health services.
Mass-gathering events (MGEs) have been shown to divert the needs of the local community in order to accommodate individuals attending the event.Reference Martin-Gill, William and Barlotta3 They can also lead to increased workloads for local Emergency Medical Services (EMS) and create “hotspots” in which most calls originate.Reference Koski, Pappinen, Kouvonen and Nordquist4 Studies conducted in Europe found that major soccer tournaments have led to small increases in emergency department visitsReference Hughes, Colon-Gonzalez and Fouillet5 and increased medical costs incurred by the host city.Reference Martinolli, Tanyeli and Hasler6 Several studies have found, however, that staging EMS personnel or other medical professionals at the location of an MGE can reduce the number of ambulance transports.Reference Grange, Baumann and Vaezazizi7–Reference Boyle, De Lorenzo and Garrison12
There are few studies, however, that examine how MGEs impact external health services such as ambulances and hospitals.Reference Ranse, Hutton and Keene13 Additionally, there is limited research on how college football games affect community health services. Studies that have addressed the intersection of college football games and medical care primarily focus on the provision of medical care inside the football stadium.Reference Shelton, Haire and Gerard14,Reference Sampson, Maberry and Stilley15
Of those studies examining how college football games affect health services, one found that allowing alcohol sales in the stadium led to a decrease in alcohol-related calls to the local EMS service.Reference Ruehlmann, Halbur, Moylan, Georgakakos, Negaard and House16 Another study assessed how football games at West Virginia University (Morgantown, West Virginia USA) affected transport to the local hospital and determined that transport intervals were longer on HGWs, demonstrating an impact of home college football games on access to health services for community members.Reference Bonasso, Lucke-Wold, Riffon, Long, Wilson and Knight17
While these findings lend important understanding to how MGEs can affect medical personnel and access to community health services, there remains a significant gap in the literature. No studies have examined how college football games affect emergency response intervals. Understanding the impact of home football games on emergency vehicle response intervals is critical because faster response intervals increase chances of patient survival.Reference Holmen, Herlitz and Ricksten18–Reference Byrne, Mann and Dai20 Previous research hypothesized that on-site staging of medical personnel is important because college football games are likely to lead to delays in EMS response,Reference Sampson, Maberry and Stilley15 but this claim is yet to be investigated. This study aims to address this gap by examining how TAMU home football games during the 2021-2023 college football seasons were related to response intervals of emergency response vehicles from the College Station Fire Department (CSFD; College Station, Texas USA).
Methods
The CSFD is a municipal, fire-based 9-1-1 first response, Advanced Life Support (ALS), transport EMS system. This means that the EMS service is supported by the city government rather than a private or for-profit entity. The EMS service is integrated into the fire department, and it responds to 9-1-1 calls rather than scheduled transports. Additionally, as a first response EMS system, the ambulance is an initial responder rather than responding only if another responder such as fire or the police deem the ambulance necessary. As an ALS system, all ambulances in the CSFD have ALS capabilities. Lastly, CSFD transports their own patients, rather than relying on other ambulance services to do so.
A retrospective analysis was conducted of CSFD incident data for TAMU HGWs and non-home game weekends (NHGWs) from 2021-2023. Home games served as the period of interest and non-home games served as the control period to determine how home football games affect emergency response intervals. Call times, dispatch times, scene arrival times, dispatch locations, response areas, and game data, specifically whether the opposing team belonged to the Southeastern Conference (SEC), were collected for a 72-hour period (12:00am Friday to 11:59pm Sunday) on HGWs and NHGWs during the 2021-2023 football seasons. During the study period, there were 20 HGWs and 20 NHGWs. Of the game weekends, 11 game weekends involved games against SEC opponents, which include flagship public universities with large student populations and are in-conference games for TAMU.
Incidents with response intervals of zero were eliminated from analysis, as were incidents that lacked timestamps for vehicle dispatched, vehicle enroute, and on-scene arrival. Only data on the first unit response were analyzed to determine emergency response intervals. This resulted in 5,095 incident observations utilized for analysis. Data were analyzed using STATA 17 (StataCorp; College Station, Texas USA). Descriptive statistics were performed to determine response intervals by calculating the difference between vehicle dispatch and vehicle on-scene arrival timestamps. Means were estimated and hypothesis tests performed using logistic regression models. For all tests, a P <.05 was considered statistically significant.
Results
Emergency Response Intervals
Average response time for HGWs was five minutes twelve seconds and response intervals on NHGWs was five minutes and forty-two seconds. When HGWs in which TAMU competed against an SEC opponent were compared to HGWs in which the opponents were not from the SEC, there was no statistically significant difference in response intervals.
Dispatch Intervals and Locations
Average dispatch intervals, defined as the time between the vehicle dispatched and vehicle enroute timestamps, was 2.4 seconds faster on HGWs compared to NHGWs (Table 1).
Notes: Cell entries represent logistical regression models with standard errors in parentheses. Times represented on a scale of 0-1 with 1 representing 1 full minute.
a P <.01.
On HGWs, there was a 16.5% decrease in vehicles dispatched from fire department stations. Instead, vehicles often responded to a call from an “off-site” location (Table 2). On weekends in which the game was against an SEC opponent, vehicles were 21.1% less likely to be dispatched from fire department stations.
Notes: Cell entries represent logistical regression models with standard errors in parentheses. Times represented on a scale of 0-1 with 1 representing 1 full minute.
a P <.01.
For vehicles dispatched from fire department stations on HGWs, response intervals were 43.8 seconds slower than those of units dispatched from non-station locations. On HGWs in which the game was against an SEC opponent, response intervals from station locations were 33 seconds slower compared to HGWs in which the opponent was not an SEC team.
Fire Station Locations
Differences in responses based on station location were also identified. Stations located near the university campus and those responding from off-site (ie, non-station) locations had response intervals 1.2 seconds slower than response intervals from stations located further from the university campus (ie, campus stations). On HGWs, however, stations near the university campus and responses from off-site locations had response intervals 0.48 seconds faster than stations located further from campus (Table 2).
These campus stations and non-campus stations are described in Figure 1. Additionally, campus stations had an average response time 0.86 seconds faster on HGWs than on NHGWs. Interestingly, campus stations responded more slowly to calls on campus on HGWs compared to calls outside of the city limits (Table 2).
Home Game Impacts on Response Area
Home football games affected the areas that emergency personnel responded to within College Station (Figure 2). On HGWs, responses to areas located on the TAMU campus increased 12.1% and responses to the entertainment district increased by 9.7%. When the game was against an SEC opponent, responses to areas on campus increased by 10.6% and responses to the entertainment district increased by 21.4% compared to game weekends in which the opponent was not an SEC team.
Discussion
The CSFD response intervals on HGWs were 30 seconds faster than response intervals on NHGWs. The faster response intervals suggest that MGEs do not necessarily impede emergency care access and suggests that assumptions in the literature are not supported. A potential factor of faster response intervals on HGWs compared to NHGWs may be the lower likelihood that emergency response vehicles will be dispatched from a fire station. These findings show that response intervals are slower on HGWs for response vehicles dispatched from fire stations, however response vehicles are dispatched less frequently from fire stations on HGWs. This suggests that the ability to respond more quickly on HGWs may be due to off-site dispatch locations. While all observations in which response time was equal to zero were eliminated, it is possible that ambulance staging on HGWs contributed to the finding of faster response intervals.
It was found that response intervals at “campus stations,” or those located closest to the university campus, experienced significantly faster response intervals. This analysis showed that a greater percentage of emergency calls came from the university campus and the nearby entertainment district on HGWs compared to NHGWs. It was noted, however, that campus stations responded more slowly to calls from campus compared to calls outside the city limits on HGWs. This may be due to the fact that campus station locations are primarily on the northern boundary of the city giving them an increased ability to respond to requests for help from the neighboring city of Bryan. Conversely, this could indicate that the influx of people onto the physical campus at TAMU reduces response time for that specific response location, despite not having an overall impact on the surrounding community.
Limitations
This study has several limitations. Data on CSFD staffing or staging of emergency vehicles on HGWs compared to NHGWs were not known. Therefore, it is not possible to know what role these played in response time outcomes. Additionally, this study only collected data from one community, meaning that the results of this study cannot be generalized to other communities. Despite this limitation, however, the study offers important insights into the effect of mass-gathering sporting events on community emergency care access.
Conclusion
These findings suggest that mass-gathering sporting events do not result in slower emergency vehicle response intervals. As discussed, the CSFD maintained emergency care access on HGWs and responded faster to emergency calls. This suggests that CSFD’s preparedness for HGWs and their understanding of call location trends may prevent delays and ensure unaffected emergency care access for the community.
Conflicts of interest
The authors report there are no competing interests to declare.
Acknowledgements
The authors would like to acknowledge Stuart Marrs, Richard Mann, and the rest of the College Station Fire Department for sharing their incident data and taking the time to answer data-related questions. They would also like to thank Hannah Rochman and Alee Lockman for their guidance during data analysis.