With 76 seconds left in the hockey game Denver beat Minnesota Duluth 2-1. The Minnesota-Duluth ice rink is 702 feet above sea level; Denver is 5,279 feet above sea level. The Loveland Ice Arena is 4,982 feet above sea level: below Denver. Ice hockey is an oxygen-deficit game. The ice was a perfectly level playing field, but hardly a neutral venue.
The Big Red were hurt by that situation against Denver in the 1969 NCAA title game.
And with Denver beating tUMD, the Frozen Four became 25% less fun.
Did you see the GWG in that game? Are you proposing the thin air created the ricochet off the end glass and made it easier for the puck to nearly bounce in off the back of Fanti's leg?
I get the altitude argument, but oxygen had nothing to do with that bit of puck luck.
The thinner air helped speed up the puck. Perhaps.
Quote from: Greenberg '97Did you see the GWG in that game? Are you proposing the thin air created the ricochet off the end glass and made it easier for the puck to nearly bounce in off the back of Fanti's leg?
I get the altitude argument, but oxygen had nothing to do with that bit of puck luck.
osorojo is saying that Denver's squad is more accustomed to breathing at altitude than UMD. altitude and oxygen-deficit are the same argument.
A hockey player who is not acclimated to a 5,000 foot rise in altitude suffers a degradation of stamina from the first drop of the puck, not just on certain plays or circumstances. It's about as fair as a hockey team with little speed raising their home ice temperature to exactly 32 degrees to slow down the speedy visitors. Don't tell me this slow-ice ploy has not been used, or it hasn't worked as well as mile-high oxygen depravation does.
Colorado has used the altitude argument to pry away some Olympic training facilities from Lake Placid. It makes sense given there's no (little?) downside training for extended periods at altitude.
Quote from: ugartealtitude and oxygen-deficit are the same argument.
Unless you're George Floyd.
To even things up how about the high-altitude team has to walk on their skates (with no skate guards) over 30 yards of concrete sidewalk before the game - and not sharpen their skates afterward? That should level-up the playing field (ice).
Quote from: osorojoTo even things up how about the high-altitude team has to walk on their skates (with no skate guards) over 30 yards of concrete sidewalk before the game - and not sharpen their skates afterward? That should level-up the playing field (ice).
Make them use figure skates.
Quote from: TrotskyQuote from: ugartealtitude and oxygen-deficit are the same argument.
Unless you're George Floyd.
Unless he was high https://www.foxnews.com/us/medical-examiner-george-floyd-fentanyl-system
Quote from: Greenberg '97I get the altitude argument, but oxygen had nothing to do with that bit of puck luck.
Quote from: ugartealtitude and oxygen-deficit are the same argument.
Yes, I know. I was using the old journalism trick of trying to restate without repeating.
Anyway, if Denver was clearly the stronger team in the closing minutes of the game, or if they outlasted UMD into the third overtime, you'd have a case. But not with the way that game was won.
Looks like Fanti is going to be just fine (https://www.uscho.com/2022/03/28/oilers-ink-minnesota-duluth-goalie-fanti-who-leaves-bulldogs-after-junior-campaign-for-nhl-contract/).
Quote from: nshapiroQuote from: TrotskyQuote from: ugartealtitude and oxygen-deficit are the same argument.
Unless you're George Floyd.
Unless he was high https://www.foxnews.com/us/medical-examiner-george-floyd-fentanyl-system
IATLO.
Sic semper proditoribus
I wonder how coaches and players [versus casual fans] feel about real or imagined claims of high-altitude rinks being an advantage for home teams playing opponents fresh from the lowlands?
The athletes don't have to search hard or long to see the impact of performance. You'd think they'd notice it as soon as they lace on skates, sneakers or cross-country ski boots. A non-athlete (me) can feel winded climbing a flight or two of stairs. One resource says, above 1,500M / 4900 ft, performance falls by 10% per 1,000M/3300ft. https://blog.mapmyrun.com/high-altitude-affects-performance/
www.ncbi.nlm.nih.gov
"General consensus is that athletes should arrive at moderate altitude AT LEAST TWO WEEKS before a given event."
Quote from: osorojowww.ncbi.nlm.nih.gov
"General consensus is that athletes should arrive at moderate altitude AT LEAST TWO WEEKS before a given event."
Alternatively, athletes could train at their home rink with some type of mask on that reduced the availability of oxygen. For student athletes, this would be much more practical.
The partial pressure of oxygen in Denver is ~135 mmHg, which is ~15% lower than it is at sea level (160 mmHg).
Quote from: iceQuote from: osorojowww.ncbi.nlm.nih.gov
"General consensus is that athletes should arrive at moderate altitude AT LEAST TWO WEEKS before a given event."
Alternatively, athletes could train at their home rink with some type of mask on that reduced the availability of oxygen. For student athletes, this would be much more practical.
The partial pressure of oxygen in Denver is ~135 mmHg, which is ~15% lower than it is at sea level (160 mmHg).
No, that doesn't work at all. Your body needs to be in the reduced density atmosphere 24/7 so its metabolism can adjust. Restricting oxygen just during workouts is not at all the same thing.
Quote from: RobbQuote from: iceQuote from: osorojowww.ncbi.nlm.nih.gov
"General consensus is that athletes should arrive at moderate altitude AT LEAST TWO WEEKS before a given event."
Alternatively, athletes could train at their home rink with some type of mask on that reduced the availability of oxygen. For student athletes, this would be much more practical.
The partial pressure of oxygen in Denver is ~135 mmHg, which is ~15% lower than it is at sea level (160 mmHg).
No, that doesn't work at all. Your body needs to be in the reduced density atmosphere 24/7 so its metabolism can adjust. Restricting oxygen just during workouts is not at all the same thing.
Well, I based my comment on information from an exercise physiology text book (Powers and Howley), which attributes much of the adaptation to hypoxia-induced increases in hematocrit (red blood cells). Hematocrit increases by ~5% for people who move from sea level to altitudes of ~5,000 feet. For altitude changes of ~15,000 feet, hematocrit increases by ~33%.
Just now though, I have also read that there are acute pressure effects on the brain. Sea-level dwellers who travel to high altitudes can experience cerebral edema and consequently headache. It was unclear to me whether or not this would be important at 5,000 feet.
Here is a reference: https://www.sciencedirect.com/science/article/abs/pii/S0033062010000307?via%3Dihub
I don't think you can train an athletes for a sudden four or five thousand foot increase in altitude by holding their breath at sea level.
Quote from: iceQuote from: RobbQuote from: iceQuote from: osorojowww.ncbi.nlm.nih.gov
"General consensus is that athletes should arrive at moderate altitude AT LEAST TWO WEEKS before a given event."
Alternatively, athletes could train at their home rink with some type of mask on that reduced the availability of oxygen. For student athletes, this would be much more practical.
The partial pressure of oxygen in Denver is ~135 mmHg, which is ~15% lower than it is at sea level (160 mmHg).
No, that doesn't work at all. Your body needs to be in the reduced density atmosphere 24/7 so its metabolism can adjust. Restricting oxygen just during workouts is not at all the same thing.
Well, I based my comment on information from an exercise physiology text book (Powers and Howley), which attributes much of the adaptation to hypoxia-induced increases in hematocrit (red blood cells). Hematocrit increases by ~5% for people who move from sea level to altitudes of ~5,000 feet. For altitude changes of ~15,000 feet, hematocrit increases by ~33%.
Just now though, I have also read that there are acute pressure effects on the brain. Sea-level dwellers who travel to high altitudes can experience cerebral edema and consequently headache. It was unclear to me whether or not this would be important at 5,000 feet.
Here is a reference: https://www.sciencedirect.com/science/article/abs/pii/S0033062010000307?via%3Dihub
The point is that you can't just reduce O
2 during exercise. To really adapt you're doing it 24 hours/day.
Ned Harkness solved the problem in 1954 when the tourney was in Colorado Springs by getting oxygen tanks for his players to use. The problem was the tanks were empty.