Helicopter emergency medical services accident rates in different international air rescue systems.

AIM: Each year approximately two to four helicopter emergency medical services (HEMS) crashes occur in Germany. The aim of the present study was to compare crash rates and fatal crash rates in Germany to rates in other countries.
MATERIALS AND METHODS: A MEDLINE search from 1970 to 2009 was performed using combinations of the keywords "HEMS", "rescue helicopter", "accident", "accident rate", "crash", and "crash rate". The search was supplemented by additional published data. Data were compared on the basis of 10,000 missions and 100,000 helicopter flying hours. These data were allocated to specific time frames for analyis.
RESULTS: Eleven relevant studies were identified. Five studies (three from Germany, one from the US, one from Australia) analyzing HEMS accidents on the basis of 10,000 missions were identified. Crash rates per 10,000 missions ranged between 0.4 and 3.05 and fatal crash rates between 0.04 and 2.12. In addition, nine studies (six from the US, two from Germany, one from Australia) used 100,000 flying hours as a denominator. Here, crash rates ranged between 1.7 and 13.4 and fatal crash rates between 0.91 and 4.7.
CONCLUSIONS: Data and accident rates were inhomogeneous and differed significantly. Data analysis was impeded by publication of mean data, use of different time frames, and differences in HEMS systems.

Introduction

In September 1970 the first German public rescue helicopter “Christoph 1” was established at the Hospital of Munich-Harlaching. Since then, helicopter emergency medical services (HEMS) have become increasingly important in the German emergency medical system (EMS). Within one year of starting rescue missions, “Christoph 1” crashed during an approach to an emergency scene in August 1971. Two occupants were killed, one was severely injured, and the helicopter was totally destroyed. This was the first aviation accident related to civilian HEMS in Germany.

Whereas the calculated accident rate and fatal accident rate for rescue helicopter crashes was extremely high in the first years of HEMS, both have steadily decreased over the past decades. During recent years, aviation safety has additionally been improved by regulations (eg, Joint Aviation Regulations for Flight Crew Licensing and Joint Aviation Regulations for Flight Operations) and enhanced aircraft techniques (eg, newer helicopter types, better aviation instruments, and the global positioning system). Still, almost every year, two to four HEMS-related accidents/crashes occur for the 82 rescue helicopters based in Germany. Some of these accidents are associated with fatal outcomes for crew members, patients, or bystanders.

This raises contrary opinions, serious concerns, and fierce disputes about the benefits for patients,1–4 effectiveness,5–8 costs,3,5–7 and especially the safety9,10–17 of the HEMS in general and compared with the ground EMS. To date, several studies have analyzed HEMS performance and HEMS accidents in other countries, but results are difficult to compare, given that different analyzing methods and different time frames are used. The aim of the present study was to compare accident rates and fatal accident rates in Germany with published rates for other countries using a time-based approach.

Materials and methods

A MEDLINE search was performed to retrieve published data on accident rates and fatal accident rates in different international HEMS systems. To identify relevant studies, all combinations of the keywords “HEMS”, “rescue helicopter”, “accident”, “accident rate”, “crash”, or “crash rate” were used (Table 1). Analysis was limited from January 1st 1970 to December 31st 2009 to facilitate comparisons and to analyze only newer and not historical data before introduction of HEMS in Germany. Original contributions and reviews as well as letters to the editor, case reports, case series, and meta-analyses were analyzed. Identified studies were supplemented with published but not indexed studies.10,18–20 Studies dealing with international rescue helicopter systems and accident analysis were eligible for further data analysis. Studies not presenting accident rates were excluded from further analysis.

Table 1

Seven eligible studies retrieved from MEDLINE on 01 January 2010*

Keywords		Total number of eligible studies	Eligible studies for analysis
HEMS	–	424
	Accident	39
	Accident rate	14
	Crash	2
	Crash rate	1
Rescue helicopter	–	404	7 (+4)
	Accident	126
	Accident rate	23
	Crash	18
	Crash rate	2
Summary	–	1.053	11

Note:

Supplemented by four published but not indexed studies.

Data were compared on the basis of 10,000 missions completed and 100,000 helicopter flying hours. Two specialists in anesthesiology with expertise in air rescue categorized the retrieved studies independently as “eligible” or “not eligible”. Consensus was achieved in three cases of discrepancy. For further analysis, data from eligible studies were allocated to the specific timeframes used and presented as time-based figures.

Results

Overall, 1053 studies were identified. Seven indexed studies were identified dealing with HEMS accidents on the basis of 10,000 missions or 100,000 flying hours. These were supplemented with four more published but nonindexed studies.10,18–20 Therefore, a total of eleven studies were analyzed. Five studies (three from Germany,16,18,21 one from the US,15 and one from Australia)13 analyzing HEMS accidents on the basis of 10,000 missions were identified (Figure 1). Crash rates per 10,000 missions ranged between 0.4 (Germany)16 and 3.05 (US)15 and fatal crash rates between 0.04 (Germany)16 and 2.12 (US;15 see Figure 2 and Table 2).

Figure 1

Comparison of accident rates per 10,000 missions in analyzed studies.*

*Year (x-axis), accident rate per 10,000 missions (y-axis). Due to the scale of the figure, one single data point Low et al;15 accident rate per 10,000 missions (3,05) is not presented.

Figure 2

Comparison of fatal accident rates per 10,000 missions in analyzed studies.*

Note: *Year (x-axis), fatal accident rate per 10,000 missions (y-axis). Due to scale of figure, one data point Low et al,15 fatal accident rate per 10,000 missions (2,12) is not presented.

Table 2

Comparison of HEMS accidents and fatal accidents per 10,000 missions

Study	Country	Time frame	Accident rate per 10,000 missions	Fatal accident rate 10,000 per missions
Holland13	Australia	1992–2002	0.60	0.20
Lippay18	Germany	1973–1994	0.91	NA
Thies16	Germany	1980–2001	0.40†	0.04†
Hinkelbein21	Germany	1999–2004	0.54	0.07
Low15	USA	1991	3.05†	2.12†

Note:

Maximum and minimum data.

Abbreviations: HEMS, helicopter emergency services; NA, not accessible data.

In addition, nine studies (six from the US,10,19,20,22–24 two from Germany,2,21,24 and one from Australia)13 used 100,000 flying hours as a denominator (Figure 3). Crash rates per 100,000 flying hours ranged from 1.7 (US)20 to 13.4 (US)19 and fatal crash rates between 0.91 (Germany)21 and 4.7 (US;24 see Table 3 and Figure 4).

Figure 3

Comparison of accident rates per 100,000 flying hours in analyzed studies.*

Note: *Year (x-axis), accident rate per 100,000 flying hours (y-axis).

Table 3

HEMS accident rates and fatal accident rates per 100,000 flying hours

Study	Country	Time frame	Accident rate per 100,000 flying hours	Fatal accident rate per 100,000 flying hours
Holland13	Australia	1992–2002	4.38	1.46
Hinkelbein21	Germany	1999–2004	10.9	0.91†
Rhee24	Germany	1982–1987	10.9	4.1
	US	1982–1987	11.7	4.7†
NTSB19	US	1980–1986	13.4†	NA
Harris22	US	1987–1993	3.1	1.61
DeLorenzo23	US	1987–1995	7.44	NA
Blumen	US	1992–2001	4.83	1.69
Wright20	US	1996–1997	1.7	NA
	US	2000–2004	NA	1.8
	US	2003–2004	4.8	NA

Note:

Maximum and minimum.

Abbreviations: HEMS, helicopter emergency medical services; NA, not accessible data.

Figure 4

Comparison of fatal accident rates per 100,000 flying hours in analyzed studies.*

Note: *Year (x-axis), fatal accident rate per 100,000 flying hours (y-axis).

For both accident rates and fatal accident rates on the basis of 10,000 missions, the published data range was limited to the years 1973–2004. Published data were limited to the years 1980–2004 for accident and fatal accident rates on the basis of 100,000 flying hours.

Discussion

Compared with other aviation areas, the risk profile for HEMS is clearly increased (eg, bad weather, unknown landing site, and stress).15,24,25 This explains the higher accident rate found for HEMS compared with commercial or private aviation.24,25 Unfortunately, the published data are scarce compared with the growing HEMS services in several other European countries, eg, Austria, the UK, Norway, Poland, Switzerland, as well as other countries worldwide.

Data analysis per 10,000 missions

For HEMS missions in Germany, an accident rate of 0.40 to 0.91 versus 0.04 to 0.07 for fatal accidents was found per 10,000 missions (Table 2, Figure 1).21 These data show no relevant differences to other recently published studies16,24 analyzing HEMS accidents between 1973 and 2004. Holland et al13 analyzed a 10-year period with 51,164 missions for HEMS in Australia. They reported a similar accident rate per 10,000 missions (0.60 versus 0.20 for fatal accidents). Although both systems and regional structures are very different (short-distance rural versus long-distance desert areas), accident rates and fatal accident rates are comparable. In contrast, Low et al15 presented relevant differences on HEMS accidents in the US (3.05 and 2.12) by analyzing one single year (Figures 1 and 2). In this study they showed a strong correlation between the accident rate and pilot proficiency. Compared with the other data identified, there was a significant difference with a five-fold higher accident rate and fatal accident rate in the US than Germany and Australia. The underlying reason may potentially be a small sample size within one single year. On the other hand, these significant differences may be due to different mission types (eg, mostly secondary flights in the US and mostly primary flights in Germany), operator-specific procedures, or different national regulations applied.

For an international comparison, data for accident rates on the basis of 10,000 missions were comparable for Australia13 and Germany.18,16,21 In contrast, data for the US15 varied (a fivefold higher rate), for the reasons stated above. Fatal accident rates on the basis of 10,000 missions showed the same congruencies for Australia and Germany and differences for the US.

Data analysis per 100,000 flying hours

On the basis of 100,000 flying hours, accident rates of 10.88 for all accidents and 0.91 for fatal accidents were found in a study by Hinkelbein et al for Germany (Table 3).21 In addition, another study by Rhee et al is available, in which HEMS accidents between 1982 and 1987 were presented.22 Both studies show comparable accident rates for nonfatal accidents but a nearly five-times higher fatal accident rate in the earlier study.21,24 Rhee et al found a surprisingly high fatal accident rate in their analysis (a fatality rate of 4.7 per 100,000 hours) from 1982 to 1987.

Even military HEMS data for accident rates was comparable with civilian data. DeLorenzo et al23 state a rate of 7.44 accidents per 100,000 flying hours, which is nearly the mean of all other studies identified (Table 3). For an international comparison, data for accident rates on the basis of 100,000 flying hours ranged between 1.7 and 13.419,20 which includes rate for Australia13 and Germany.21,24 These data are inhomogeneous and vary significantly.

Limitations

Analysis of aviation accident data is often complicated by a lack of usable denominator data.26 This also applies to the analysis of HEMS accidents. On the other hand, both aircraft accidents as well as HEMS accidents underpin a highly complex error chain which depends on multiple factors. Although a time-frame or time-based approach was used to exclude multiple influences, different pilot qualifications,24 environmental factors, as well as human factors cannot be evaluated adequately in a retrospective study. Both primary (emergency) and secondary (interhospital transfer) missions were analyzed, although there may be some different operating conditions with potentially different accident rates.

Data on the basis of 10,000 missions or 100,000 flying hours should be in concordance for each country analyzed. This point does not apply in the present study. One possible reason may be differences in the duration of a mission (long versus short) in different countries. Unfortunately these data are not published. Using statistical approaches to analyze different rates in various countries would be beneficial for data interpretation. Unfortunately, some of the studies reported only rates but not absolute numbers (eg, number of missions or flying hours). Therefore, specific statistical tests were not possible.

Conclusions

Published data for three countries were identified. Data analysis was impeded by publication of mean data, use of different time frames, and differences in HEMS systems. Nevertheless, the data in the present study are essential to evaluate the accident risk with an HEMS mission. In the future, publication of accident data and studies analyzing the complete time-frame of HEMS missions are required. Additionally, it may be beneficial to record HEMS accident data in detail in a specific database. Besides relevant denominator data (eg, number of missions or flying hours), potential confounding factors (eg, weather conditions, urban versus rural missions, and aircraft maintenance) are of special interest. This approach would facilitate detailed and valid analyses of HEMS accidents. If these data remain inaccessible, future studies may encounter similar interpretation difficulties.