DOI: 10.1136/military-2025-003229 ISSN: 2633-3767

Analysis of brain injuries in 268 ejection seat aircraft ejections: the prevalence of loss of consciousness and helmet design implications

Alasdair Iain Mackay, Xiancheng Yu, Matthew Elfed Lewis

Introduction

Ejections from combat aircraft pose a significant risk of head injury, and the primary protective measure against such injuries is the aircrew helmet. Internationally, aircrew helmets are typically certified against motorcycle or motorcycle-derived helmet standards, which may not reflect the injury mechanisms experienced during aircraft ejections.

Methods

The objective of this study was to identify the historical risk of head injury associated with combat aircraft ejections. All UK combat aircraft ejections from 1972 to 2025 were analysed to determine common brain pathologies, head injury mechanisms and helmet damage characteristics.

Results

In total, 268 aircraft ejections were recorded, with 12% resulting in a head injury. Two primary head injury mechanisms were identified: headbox impact (58%) and parachute landing (27%). The findings indicate that aircrew helmets provide protection against skull fracture as no cases were recorded following in-envelope ejections. This outcome is likely attributable to existing aircrew helmet standards, which assess helmet performance based on peak translational acceleration, a parameter closely linked to skull fracture. A key finding is that loss of consciousness associated with head rotation was the most prevalent pathology, comprising 76% of all head injuries.

Conclusions

These results inform potential improvements in aircrew helmet standards. Even a brief incapacitation, such as a loss of consciousness, can impair aircrew escape and evasion capabilities, thereby affecting survivability. Consequently, this study recommends that future aircrew helmet standards expand their test methods to include assessments of rotational injury, with the aim of mitigating the risk of loss of consciousness.

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