Abstract
Underwater blast differs from blast in air. The increased density and viscosity of water relative to air cause injuries to occur almost exclusively as primary blast, and may cause disorientation in a diver, which may lead to inability to protect the airway and cause drowning. However, cognitive impairments from under water blast wave exposure have not been properly investigated, and no experimental model has been described. We established an experimental model (water shock tube) for simulating the effects of underwater blast pressure waves in rodents, and to investigate neurology in relation to organ injury. The model produced standardized pressure waves (duration of the primary peak 3.5 ms, duration of the entire complex waveform including all subsequent reflections 325 ms, mean impulse 141–281 kPa-ms, mean peak pressure 91–194 kPa). 31 rats were randomized to control (n = 6), exposure 90 kPa (n = 8), 152 kPa (n = 8), and 194 kPa (n = 9). There was a linear trend between the drop height of the water shock tube and electroencephalography (EEG) changes (p = 0.014), while no differences in oxygen saturation, heart rate, S100b or macroscopic bleedings were detected. Microscopic bleedings were detected in lung, intestines, and meninges. Underwater pressure waves caused changes in EEG, at pressures when mild hemorrhage occurred in organs, suggesting an impact on brain functions. The consistent injury profile enabled for the addition of future experimental interventions.
Highlights
Underwater blast injuries were first described in 1917
The water shock tube produced a pressure wave, when hitting ground, with a duration of the primary peak of 3.5 ms, and the duration of the entire complex waveform including all subsequent reflections of 325 ms
In this study we describe an experimental model for investigating the effects of underwater pressure waves on rodents
Summary
Underwater blast injuries were first described in 1917. During WWII, thousands of soldiers and civilians were injured or killed by underwater blast, which led to the development of safety standards to prevent injury or death. While no universal standard for underwater blast safety currently exists, the guideline developed by Richmond et al seems to be the most commonly applied today.[14]. Underwater blast differs from blast in air. The increased density and viscosity of water relative to air cause underwater blast injuries to occur almost exclusively as primary blast. This type of injury is the result of the energy of the blast wave interacting with the tissues of the human body.[12]. While animal studies have been performed since 1944 to assess the spectrum of injury, summarized in a comprehensive review,[12] cognitive
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