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Every year, around 100 people die in avalanches in the Alps. Many of these accidents occur during winter sports. In most cases, the victims suffocate under the snow after the avalanche has come to a standstill. A key survival factor here is the time it takes to be rescued. If a buried victim is rescued within 15 minutes, the probability of survival is over 90%. After 35 minutes, however, this drops drastically to just 30%.
A modern avalanche rescue system, such as the AvaLung-device, could extend the survival time. The system directs the exhaled air via a tube to the back of the buried person so that no toxic CO2 concentrations build up in the available breathing cavity. It is also intended to prevent the formation of an "ice mask", which can impair the release of oxygen from the snow. This study investigates whether the AvaLung system can extend the survival time in the event of burial.
The aim is to test the effects of such a breathing tube system. The oxygen and carbon dioxide levels of the test subjects are measured while they are buried in a simulated avalanche - once with and once without the AvaLung system. In addition, it is investigated how long it takes before the buried subjects have to stop the examination, for example due to shortness of breath or deteriorating respiratory gases in the blood.
Test setup:
The test subjects lie on their backs with their heads and chests buried under snow. During the test phase, various parameters are continuously monitored, such as the breathing rate and the CO2 concentration in the blood. A comparative study is carried out: once with a functioning rescue system, and once with a manipulated (non-functioning) system.
Expected benefit:
The results of this study should contribute to a better understanding of the effectiveness of avalanche rescue systems and thus increase the chances of survival of avalanche victims in the future. This is particularly important today, as the number of winter sports enthusiasts and the number of avalanches triggered by them is constantly increasing.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Simulated avalanche burial using a artificial air-pocket device | Experimental |
| |
| Simulated avalanche burial using a non-functional artificial air-pocket device | Sham Comparator |
|
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Addition of an artificial air-pocket device during simulated avalanche burial | Device | In contrast to the control group, the subjects in this arm are provided with a functioning device that directs the exhaled air away from the area of the respiratory cavity. |
| Measure | Description | Time Frame |
|---|---|---|
| Course of PtCO2 measured transcutaneously | 45 minutes |
| Measure | Description | Time Frame |
|---|---|---|
| Burial time until the test is terminated | 45 minutes | |
| Course of PetCO2 | 45 minutes | |
| Progression of respiratory minute volume |
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Inclusion Criteria:
Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Hans-Joachim Kabitz, Prof. Dr. med. | Klinik für Pneumologie und Schlafmedizin Kantonsspital Aarau | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Kantonsspital Aarau | Aarau | Canton of Aargau | 5001 | Switzerland |
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| Addition of a non-functioning artificial air-pocket device during simulated avalanche burial | Device | In contrast to the intervention arm, the subjects in this arm are provided with a non-functioning artificial air-pocket device which does not redirect the exhaled air away from the breathing-cavity. |
|
| 45 minutes |
| Course of the body temperature | 45 minutes |
| Heart rate progression and variability | 45 minutes |
| Course of PtO2 | 45 minutes |
| Course of PetO2 | 45 minutes |
| Course of SpO2 | 45 minutes |
| Progression of Respiratory rate | 45 minutes |