It's interesting that everyone agrees <.21 is hypoxic. And their reasoning is that is below normal air conditions at sea level. I live at altitude and normal for me is .18. I still would call <.21 hypoxic but because it is below normal for most divers not because it is below normal for me.
And at the same time when refering to trimix mixtures they use the term "Normoxic" (Sounds a lot like normal) with a 16% rule.
It's interesting that everyone agrees <.21 is hypoxic. And their reasoning is that is below normal air conditions at sea level. I live at altitude and normal for me is .18. I still would call <.21 hypoxic but because it is below normal for most divers not because it is below normal for me.
And at the same time when refering to trimix mixtures they use the term "Normoxic" (Sounds a lot like normal) with a 16% rule.
If you PM me the case, we may have the data for it.. I was just curious to know if you were referring to an analysis of a case I saw some time ago where the inspired PO2 had been calculated based on a number of assumptions that were inaccurate.
In the latter case we use a window of 0.065 to 0.10 as the range in which a dive would become unconscious while active on a rebreather loop. If the dive is inactive, we increase the upper limit to 0.12 atm.
Not every one.
I said 0.16 which is what i was taught for OC trimix.
Thats a PP02 of 3.47
AD_Ward9 said:Mark Chase raises an interesting hazard, that can lead to over-confidence for rebreather divers.
Possably for the purpose of incident reporting, taking in mind the issues of depth changes and P02 on CCR, any drop below low set point of 0.7 should qualifie as an incident?
Hi Gareth, it seems to me you are looking for a definition that will fit more with an incident monitoring style of study (i.e. something that had the potential to cause harm if not detected, as well as something that actually caused harm). For a definition like that, you want to know why and how often the PO2 falls outside of what the diver, the training agencies or the manufacturers consider to be a safe range.
So if an eCCR wanders outside of range according to the various standards, then that could constitute an incident. However this is so common during a dive as to be "normal" e.g. a small spike on descent, a small spike due to over enthusiastic manual addition, a small drop during ascent etc. So you could widen that range considerably to consider CLEAR breaches of equipment function or diver procedure. e.g. <0.3 and > 1.8. If you only look at a range that constitutes a major physiological threat then I think you will be missing a lot of cases which can contribute to your understanding of root cause analysis.
mCCR use is I believe, associated with more frequent digressions from safe PO2 ranges (that has certainly been my personal experience, usually as a result of task loading and inattention) and the two low PO2 incidents I have personally suffered certainly reflect that (once surface swimming into current before descent with hypoxic dil and one being harassed by sharks in fairly shallow water). eCCR would not have allowed these incidents to happen if functioning properly.
It is impossible to put a high or low number as a cut off for physiological responses e.g. seizure or loss or consciousness, for all the intra- and inter-individual as well as contextual variations (alveolar CO2, work rate and metabolism, cerebral CO2, serum green tea levels!) that exist. So as I said, I'd look at defining safe operational levels rather than physiological ones.
It is impossible to put a high or low number as a cut off for physiological responses e.g. seizure or loss or consciousness, for all the intra- and inter-individual as well as contextual variations (alveolar CO2, work rate and metabolism, cerebral CO2, serum green tea levels!) that exist.
Perhaps a more useful and universally agreeable approach would be to establish a guideline for incident classification as any variation of X% outside of the planned and expected PO2.
Thanks for all of the feedback.
Hypoxia: Where the diver ends up with an Oxygen toxicity (OxTox) event/seizure, or the CCR has a pO2 above the planned maximum set point which was not demanded by the diver nor recognised that it would happen. e.g. a diver may push the pO2 above 1.6 to check the cells or when descending fast down a shotline - neither of these are incidents because they are expected and/or demanded.
Hyperoxia: Where an OC diver ends up breathing a gas with a pO2 less than 0.18 underwater, or the CCR has a pO2 less than .7 which was not demanded by the diver nor recognised that it would happen. e.g. on the ascent the pO2 may drop as the ambient pressure drops but this should be controlled by the diver or the CCR electronics to be at a level which is sustainable and controlled or the diver may demand a dil flush which may bring the pO2 below 0.7 depending on the dil gas.
Any thoughts/comments/feedback would be appreciated before I get formal endorsement from a consensus of 'named individuals'.
Regards
Thanks for all of the feedback.
I am now putting things together and am using the following definitions to define whether a diver has had an incident to understand the distribution of HFACS categories within the sample population - the survey will be based in the UK so I am not too bothered about high altitude environments and looking to collect responses from 175 CCR users and 25 CCR instructors (plus 800 OC divers).
Hypoxia: Where the diver ends up with an Oxygen toxicity (OxTox) event/seizure, or the CCR has a pO2 above the planned maximum set point which was not demanded by the diver nor recognised that it would happen. e.g. a diver may push the pO2 above 1.6 to check the cells or when descending fast down a shotline - neither of these are incidents because they are expected and/or demanded.
Hyperoxia: Where an OC diver ends up breathing a gas with a pO2 less than 0.18 underwater, or the CCR has a pO2 less than .7 which was not demanded by the diver nor recognised that it would happen. e.g. on the ascent the pO2 may drop as the ambient pressure drops but this should be controlled by the diver or the CCR electronics to be at a level which is sustainable and controlled or the diver may demand a dil flush which may bring the pO2 below 0.7 depending on the dil gas.
Hypercapnia: Where the diver had an event where they have a high confidence that excess CO2 was to blame for outcomes, or was formally diagnosed as having a hypercapnic event. This could be on OC due to dense gas and/or high workloads, or CCR due to a variety of mechanical (scrubber, mushroom valves, missing o-rings etc) issues and/or physiological issues such as being a CO2 retainer or skip breathing.
Any thoughts/comments/feedback would be appreciated before I get formal endorsement from a consensus of 'named individuals'.
Regards