The DEBUNKING thread.........myths that need to be trashed

portexploit

Walking and running are not the same activities and shouldn't be compared. When walking, only one foot leaves the ground at a time. In running, both feet are off the ground. It's more of a jumping action and burns more calories. Now, running slowly vs running quickly probably burns about the same calories per distance, as does strolling vs brisk walking. If I were to hop like I was on an invisible pogo stick for one mile, I'm sure I'd burn a crap-ton more calories over the same distance as running OR walking.

This has been an interesting thread for me, as a physics instructor, to read. LorinaLynn gets it. A quick thought experiment will demonstrate that the physical work done is not simply a function of the distance traveled: imagine running in place for an hour. You didn't go anywhere, so you didn't burn any calories, right? (Not right.)

By the way, for the person who multiplied their weight by the distance they traveled, please understand that you have correctly calculated the work required ... assuming the distance was vertical. Most of us run horizontally.

An exercise for any physics students out there: Jane Doe starts from rest, accelerates to 3.0 m/s in 10 m, runs at that speed for an additional 5000 m, then decelerates to rest over a final 10 m. What is the net work done on Jane Doe?

That's right ... zero.

Thanks james... my question is why is it vertical compared to horizontal?

TrainingWithTonya

Thank you for this thread!!!! This is exactly what I needed to hear today. I just recently starting lifting weights and am currently holding the water weight as a result. My question to you is, should I keep my heart rate lower when doing cardio to allow my muscles to build? I've heard that if you do cardio too intense when trying to build muscle, you can halt your progress?

I dont get why you think you're retaining water as a result of weight lifting.

Because the first physiological response to heavy weight training is actually an increase in glycogen storage in the muscles. Glycogen is stored in 3 times as much water. So, if you store an additional gram of glycogen, you store 3 additional grams of water.

Reference: NSCA Essentials of Strength Training and Conditioning

James_1954

Thanks james... my question is why is it vertical compared to horizontal?

Portexploit sent me a message, but let me copy my reply here, too.

If you travel straight up a distance Y at a constant velocity, you (or whatever's moving you) do positive work in the amount:

W = mgY

where m is your mass and g is the acceleration due to gravity (9.8 m/s^2 at Earth's surface).

The gravitational force does the same amount of work on you, but it's negative work ( = -mgY). Work is positive if it's done by a force in the same direction as the displacement, or travel; it's negative if done by a force directed opposite the displacement.

The total work done on you is zero (mgY - mgY = 0). This has to be true if you move at a constant velocity; the work-energy theorem says that the total net work done on you is equal to the increase in your kinetic energy. Your total mechanical energy increases, however, because you end up higher than you started. The increase is in the form of gravitational potential energy and is also equal to mgY. If you then fall freely from that height (Y) above ground, you will arrive with a speed V, where mgY = (0.5)·m·V^2. The (0.5)·m·V^2 term is your kinetic energy. The work you did in climbing that height Y is returned to you as kinetic energy.

If you move horizontally through a distance X, and there's no friction (think of an air-hockey puck, where there's ALMOST no friction), no force is required to keep you moving. So the work is equal to F·X, but F is zero, so the work is also zero. If there is a frictional force (F) that opposes your motion, then you have to do work = F·X to travel a horizontal distance X. In any real situation, though, F is going to be much less than your weight (mg).

Sorry to let my inner geek out for a walk like this. I didn't teach all last year, and I think I'm jonesing for it a little.

One other thing, looking back at LorinaLynn's reply (up a couple): she makes an excellent point about traveling a mile by invisible pogo stick and consequently burning a crap-ton of calories. To make that even stronger, consider: suppose she just invisible-pogo-stick-jumps in place for the same amount of time she'd have needed to pogo-stick that mile? You can see that her calorie expenditure would be the same. The net distance traveled -- if any -- is irrelevant.

I really like that quantity, by the way: the "crap-ton." With your permission, I'll borrow it. "My next trip to the dentist is gonna be a whole crap-ton of fun!" :-)

LorinaLynn

:laugh: Yes, "crap-ton" does have a very scientific ring to it. :laugh:

TrainingWithTonya

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

What we do use are equations based on VO2 estimations. The reason for that is because the usage of 1 Liter of Oxygen by the body requires 5 Kilocalories of energy. So, if we can determine how many liters of oxygen you use to do something, then we can determine how many kilocalories you are burning doing that activity. There are several ways of estimating these things. Some formulas use heart rate because there appears to be a positive relationship between exercise heart rate and VO2. Unfortunately, if the elevation in heart rate isn't related to the actual activity of the body, then cellular respiration is virtually unchanged so the VO2 doesn't actually increase, meaning you aren't really burning more calories just because the heart rate increases. So, if your heart rate is already elevated by medications, caffeine, smoking, etc. a heart rate monitor isn't going to give you an accurate estimate of calorie burn. Nor is it going to give you an accurate estimate of calorie burn for anything that isn't steady state aerobic activity. (IE: it's inaccurate for intervals, weight training, etc.) The other methods we use to estimate calorie burn include formulas that take into consideration the mass, distance, speed, and incline. These formulas are based on years of research that show them to be fairly accurate for the AVERAGE population. Meaning some people will burn more and some people will burn less based on their fitness level and the efficiency of their body to utilize oxygen, carbohydrate, fat, etc. Those things actually can change within a matter of hours in the same individual too, based on what fuel they have consumed so even estimates based on the same person aren't 100% accurate. The only 100% accurate way to estimate your calorie burn is to live in a human calorimeter. In the calorimeter, everything that is consumed is weighed and measured and everything that is expelled is weighed and measured. You are basically stuck in this room where even the air you breathe is measured for it's oxygen content as you are breathing in and out. So, we do the best we can with estimates.

Anyway, the real point of the calorie thing is not necessarily how many calories you burn in a mile, but how many of the calories you burn are actually being burned from fat as opposed to carbohydrate and protein. Yes, you may burn 500 calories by running for 30 minutes and only 300 for walking an hour, but what percentage of those calories came from your fat stores? If you are doing a lower intensity workout, you can get 50% from fat, or in this hypothetical case, 150 fat calories. At the intensity of a run, however, only about 20% of the calories come from fat, so this hypothetical person would only burn 100 calories from fat. Yes, they burned more calories, but they burned fewer from their fat stores. And isn't it body fat we're actually trying to lose?

Now, if you are trying to improve your VO2 max and strengthen the heart, that has only been proven to be done at higher intensities, so we don't need to cut all high intensity exercise so we get more fat burning. It needs to be a balance, some high intensity, some low intensity, and some moderate intensity so we get all the best benefits to the body.

References:
Exercise Physiology by Powers and Howley
NSCA Essentials of Strength Training and Conditioning
ACSM Guidelines for Exercise Testing and Prescription
And Dr. Green T. Waggener, Professor of KSPE3420 Exercise Physiology at Valdosta State University, Valdosta, GA

James_1954

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

Tonya, I love you to death and am not trying to be a pain -- really! But we physicists -- modern ones, at least -- don't use "calories" at all if we can avoid it. We work in the SI ("Le Systeme International d'Unites"), where energy is measured in joules (J). And, of course, you're correct: the calorie is the energy required to increase the temperature of one gram of water by one Celsius degree, while in the nutritional world, what's commonly referred to as the "calorie" is actually a thousand times as much, and will warm up a kilogram of water by 1 C°.

Also, I would never tell you that you don't do work when you raise a weight and then lower it to its starting position. On the contrary -- if you lift a mass m through a height h, you do m·g·h of work in raising it, and another m·g·h of work in lowering it, assuming constant velocity. It is true that the first work has a positive sign and the second is negative, but that doesn't matter to your muscles -- they neither know nor care whether you're doing negative or positive work. That matters only to the weight -- it's had zero total work done on it, and its final state is the same as its initial one. Your muscles still did the work, however.

As a physicist, if I want to really tick you off, here's how I'll do it: please stand with your arms stretched straight out to both sides, level, holding a 15-pound dumbbell in each hand. Don't move. Just stand there, perfectly still ... with your arms starting to tremble ... and then shake ... you're gritting your teeth ... sweat's starting to run down your forehead ... hold it ... hold it ... until you finally throw the weights at me and say, "What do you mean, I didn't do any work???!!?" Well, in the physical definition of work, sorry: no displacement, no work. But that just shows that physical work and muscle effort aren't the same thing.

Anyway, thanks for your patience. Just look at your picture, and then at mine. One thing's clear: exercise physiologists may not use physics equations, but they're a hell of a lot better-looking than physicists are! And the physicists appreciate it, too. I mean, we're not blind. :-)

portexploit

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

What we do use are equations based on VO2 estimations. The reason for that is because the usage of 1 Liter of Oxygen by the body requires 5 Kilocalories of energy. So, if we can determine how many liters of oxygen you use to do something, then we can determine how many kilocalories you are burning doing that activity. There are several ways of estimating these things. Some formulas use heart rate because there appears to be a positive relationship between exercise heart rate and VO2. Unfortunately, if the elevation in heart rate isn't related to the actual activity of the body, then cellular respiration is virtually unchanged so the VO2 doesn't actually increase, meaning you aren't really burning more calories just because the heart rate increases. So, if your heart rate is already elevated by medications, caffeine, smoking, etc. a heart rate monitor isn't going to give you an accurate estimate of calorie burn. Nor is it going to give you an accurate estimate of calorie burn for anything that isn't steady state aerobic activity. (IE: it's inaccurate for intervals, weight training, etc.) The other methods we use to estimate calorie burn include formulas that take into consideration the mass, distance, speed, and incline. These formulas are based on years of research that show them to be fairly accurate for the AVERAGE population. Meaning some people will burn more and some people will burn less based on their fitness level and the efficiency of their body to utilize oxygen, carbohydrate, fat, etc. Those things actually can change within a matter of hours in the same individual too, based on what fuel they have consumed so even estimates based on the same person aren't 100% accurate. The only 100% accurate way to estimate your calorie burn is to live in a human calorimeter. In the calorimeter, everything that is consumed is weighed and measured and everything that is expelled is weighed and measured. You are basically stuck in this room where even the air you breathe is measured for it's oxygen content as you are breathing in and out. So, we do the best we can with estimates.

Anyway, the real point of the calorie thing is not necessarily how many calories you burn in a mile, but how many of the calories you burn are actually being burned from fat as opposed to carbohydrate and protein. Yes, you may burn 500 calories by running for 30 minutes and only 300 for walking an hour, but what percentage of those calories came from your fat stores? If you are doing a lower intensity workout, you can get 50% from fat, or in this hypothetical case, 150 fat calories. At the intensity of a run, however, only about 20% of the calories come from fat, so this hypothetical person would only burn 100 calories from fat. Yes, they burned more calories, but they burned fewer from their fat stores. And isn't it body fat we're actually trying to lose?

Now, if you are trying to improve your VO2 max and strengthen the heart, that has only been proven to be done at higher intensities, so we don't need to cut all high intensity exercise so we get more fat burning. It needs to be a balance, some high intensity, some low intensity, and some moderate intensity so we get all the best benefits to the body.

References:
Exercise Physiology by Powers and Howley
NSCA Essentials of Strength Training and Conditioning
ACSM Guidelines for Exercise Testing and Prescription
And Dr. Green T. Waggener, Professor of KSPE3420 Exercise Physiology at Valdosta State University, Valdosta, GA

This doens't make sense to me. You said the more oxygen we consume the more calories we consume. VO2MAX part of the formula for VO2MAX is based on bodyweight. If nothing changes for a person in terms of fitness except weight their VO2MAX would be higher. So according to what you said, or maybe I didn't understand fully you're saying a lighter person would burn more calories, which we all know not to be true.

Another thing you said, about less fat being burned during high intensity. I am pretty sure we all agree on this to be true. As you also know the POC(Post Oxygen Consumption) when we rest from high intensity, we aren't in a anerobic state anymore so most of the calories in theory would come from fat.

One more thing, from my understanding the higher the mitochondria the more fat burning ability. Mitochandria is produced by low intensity work, yes you can do it with high intensity work of course. You pretty much said low intensity work won't increase VO2MAX much. The people who have the highest VO2MAX are endurance athletes, the majority of their training is in a aerobic state.

JNick77

Thank you for this thread!!!! This is exactly what I needed to hear today. I just recently starting lifting weights and am currently holding the water weight as a result. My question to you is, should I keep my heart rate lower when doing cardio to allow my muscles to build? I've heard that if you do cardio too intense when trying to build muscle, you can halt your progress?

I dont get why you think you're retaining water as a result of weight lifting.

Because the first physiological response to heavy weight training is actually an increase in glycogen storage in the muscles. Glycogen is stored in 3 times as much water. So, if you store an additional gram of glycogen, you store 3 additional grams of water.

Reference: NSCA Essentials of Strength Training and Conditioning

.

But at the same time aren't you burning glycogen for energy during weight lifting and thereby reducing your glycogen stores?

ninerbuff

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

What we do use are equations based on VO2 estimations. The reason for that is because the usage of 1 Liter of Oxygen by the body requires 5 Kilocalories of energy. So, if we can determine how many liters of oxygen you use to do something, then we can determine how many kilocalories you are burning doing that activity. There are several ways of estimating these things. Some formulas use heart rate because there appears to be a positive relationship between exercise heart rate and VO2. Unfortunately, if the elevation in heart rate isn't related to the actual activity of the body, then cellular respiration is virtually unchanged so the VO2 doesn't actually increase, meaning you aren't really burning more calories just because the heart rate increases. So, if your heart rate is already elevated by medications, caffeine, smoking, etc. a heart rate monitor isn't going to give you an accurate estimate of calorie burn. Nor is it going to give you an accurate estimate of calorie burn for anything that isn't steady state aerobic activity. (IE: it's inaccurate for intervals, weight training, etc.) The other methods we use to estimate calorie burn include formulas that take into consideration the mass, distance, speed, and incline. These formulas are based on years of research that show them to be fairly accurate for the AVERAGE population. Meaning some people will burn more and some people will burn less based on their fitness level and the efficiency of their body to utilize oxygen, carbohydrate, fat, etc. Those things actually can change within a matter of hours in the same individual too, based on what fuel they have consumed so even estimates based on the same person aren't 100% accurate. The only 100% accurate way to estimate your calorie burn is to live in a human calorimeter. In the calorimeter, everything that is consumed is weighed and measured and everything that is expelled is weighed and measured. You are basically stuck in this room where even the air you breathe is measured for it's oxygen content as you are breathing in and out. So, we do the best we can with estimates.

Anyway, the real point of the calorie thing is not necessarily how many calories you burn in a mile, but how many of the calories you burn are actually being burned from fat as opposed to carbohydrate and protein. Yes, you may burn 500 calories by running for 30 minutes and only 300 for walking an hour, but what percentage of those calories came from your fat stores? If you are doing a lower intensity workout, you can get 50% from fat, or in this hypothetical case, 150 fat calories. At the intensity of a run, however, only about 20% of the calories come from fat, so this hypothetical person would only burn 100 calories from fat. Yes, they burned more calories, but they burned fewer from their fat stores. And isn't it body fat we're actually trying to lose?

Now, if you are trying to improve your VO2 max and strengthen the heart, that has only been proven to be done at higher intensities, so we don't need to cut all high intensity exercise so we get more fat burning. It needs to be a balance, some high intensity, some low intensity, and some moderate intensity so we get all the best benefits to the body.

References:
Exercise Physiology by Powers and Howley
NSCA Essentials of Strength Training and Conditioning
ACSM Guidelines for Exercise Testing and Prescription
And Dr. Green T. Waggener, Professor of KSPE3420 Exercise Physiology at Valdosta State University, Valdosta, GA

Maybe I should restate this way in relevance to weight loss. I totally remember this from ACSM, but didn't do a very good explanation. What you have posted would apply more to what others here are trying to achieve. I don't think many care about the actual way they burned off the weight from exercise as long as it was burned off.
I will concede that the explanation James gave about running in place makes total sense and I didn't consider it. I'm more than man enough to admit that if I was wrong on the actual calculations, that I was wrong and glad it was corrected.

ninerbuff

Here's another: "TO GET "CUT" LIFT LIGHTER WEIGHTS AND DO HIGHER REPS". I hear this one at the gym all the time. Getting "cut" is about loss of body fat. If the same people that tout the belief that you can't "spot exercise" any portion of your body to get smaller or lose fat, then why would they say that this is true? Fat loss comes down to calorie deficit so that you use that stored fat for energy.
You can lift heavy and still get "cut". Heavy weight training increases metabolism and helps you retain more lean muscle as you lose weight. Doing light weights for 20 reps will possibly "pump" you up, but in reality won't help to "tone" you up more. You're much better off lifting as much weight as you can for 8-12 reps and having shorter rest intervals so you can increase your muscle endurance and cardio vascular endurance as well.

tigersword

where do i start

1. "YOU'RE BUILDING AND GAINING MUSCLE, THAT'S WHY THE SCALE IS MOVING"

YES you can build muscle on a caloric deficit(4). (btw 2out of 5 Americans are obese) saying that is rare doesn't mean it can be done. It depends more on your body type. Endo vs Ecto vs Meso each will gain muscle at a different rate and loss fat at a different rate. Meso would build muscle as long as they took in enough protein and stayed over the starvation point, were an ecto couldn't build muscle with out going heavy on calories, an Endo would fall in the category you based your topic on.

2. "YOU ARE BUILDING LONG LEAN MUSCLES"

no you can't change the length of your muscle all you can do is control the size of it . (see below)

3. "I DON'T LIFT BECAUSE I DON'T WANT TO GET BULKY"

Alright ... here we go Look the "Bulk" of your muscle is controlled (in part) by the amount of testosterone(1)you have , most women lack enough to look like a body builder and never have to worry about it. Also (in part) by hypertrophy training(2) which will allow you to grow bigger muscles where endurance training will allow you to get stronger with out the bulk.

4. "YOU CAN'T LOSE WEIGHT UNLESS YOU EXERCISE WITH AN ELEVATED HEART RATE"-

You are right on this one , you can lose weight watching TV and not moving all you have to do is not eat anything.
Does that make it effective? no
does that even make it a good idea? no
If you are going to commit to a weight loss program you have to understand it won't be comfortable if it is you are doing it wrong.
They use to talk about fat burning zone, your HR hits that point you are burning primarily fat, if you amp it up you burn more fat but you will also burn muscle. Its like this you burn more calories doing HIIT every other day opposite steady rate cardio every other day then you will doing steady cardio every day(3). You compare a 2 mile walk to a mile run. a mile run will not only burn more calories but will also increase your Resting Metabolic Rate... meaning you burn more during you exercise and will continue to burn more throughout your day.

Sources:
(1)http://ajpendo.physiology.org/content/283/1/E154.short
(2)http://www.t-nation.com/free_online_article/sports_body_training_performance/endurance_and_hypertrophy_paradox
(3)http://www.teenbodybuilding.com/justin6.htm
(4) http://www.fourhourworkweek.com/blog/2007/04/29/from-geek-to-freak-how-i-gained-34-lbs-of-muscle-in-4-weeks/

Just to point out, you're quoting a source that claims to have put on 34 pounds of muscle in a month. The average muscle gain for a weight lifter is 1 pound of lean muscle a month. I'm not sure I'd put too much stock in that article, especially when he's selling stuff from it. People in a controlled experiment testing a protein supplement put on 8 pounds of muscle in 6 weeks. I find his claims of putting on 34 pounds of muscle with just 4 hours of training in a month to be sketchy, at best.

TrainingWithTonya

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

Tonya, I love you to death and am not trying to be a pain -- really! But we physicists -- modern ones, at least -- don't use "calories" at all if we can avoid it. We work in the SI ("Le Systeme International d'Unites"), where energy is measured in joules (J). And, of course, you're correct: the calorie is the energy required to increase the temperature of one gram of water by one Celsius degree, while in the nutritional world, what's commonly referred to as the "calorie" is actually a thousand times as much, and will warm up a kilogram of water by 1 C°.

Also, I would never tell you that you don't do work when you raise a weight and then lower it to its starting position. On the contrary -- if you lift a mass m through a height h, you do m·g·h of work in raising it, and another m·g·h of work in lowering it, assuming constant velocity. It is true that the first work has a positive sign and the second is negative, but that doesn't matter to your muscles -- they neither know nor care whether you're doing negative or positive work. That matters only to the weight -- it's had zero total work done on it, and its final state is the same as its initial one. Your muscles still did the work, however.

As a physicist, if I want to really tick you off, here's how I'll do it: please stand with your arms stretched straight out to both sides, level, holding a 15-pound dumbbell in each hand. Don't move. Just stand there, perfectly still ... with your arms starting to tremble ... and then shake ... you're gritting your teeth ... sweat's starting to run down your forehead ... hold it ... hold it ... until you finally throw the weights at me and say, "What do you mean, I didn't do any work???!!?" Well, in the physical definition of work, sorry: no displacement, no work. But that just shows that physical work and muscle effort aren't the same thing.

Anyway, thanks for your patience. Just look at your picture, and then at mine. One thing's clear: exercise physiologists may not use physics equations, but they're a hell of a lot better-looking than physicists are! And the physicists appreciate it, too. I mean, we're not blind. :-)

My physics professor swore up and down that muscular effort didn't matter because it wasn't accounted for in the physics formula for work. My physics professor didn't do anything but confuse me, though, so I try not to hang out in the physics department often. But if I'd had a physics professor who was as easy going and funny as you, I'd have to hang out there more for the laughs!

And I was only half joking about the physics formulas. We did use some of them in my Biomechanics classes when analyzing movement patterns. I just use those a lot less then the Calorie burn stuff because most of my clients could care less about the forces on the various muscles and such, but seem to be a lot more focused on what they are burning while I'm torturing, um, I mean training them.

And yes, I realize that you don't like to use calories if you don't have to. I like joules actually, myself, because it seems like I'm doing more work based on the higher number. But I'm really glad that when we measure weight that we use pounds or kilograms instead of Newtons. :laugh:

ninerbuff

But at the same time aren't you burning glycogen for energy during weight lifting and thereby reducing your glycogen stores?

Yes, but you replenish it once you digested a meal and drink water. You especially do this quite quickly with a post exercise meal of whey, carbs and water.

bprague

wait did I read that right....you saying you burn as many calories walking the same distance as a run or did I confuse myself?

If the distance it the goal, let's say 1 mile, whether you run it or walk it the calories burned is the SAME.

Now I know this one is not technically true. http://www.runnersworld.com/article/0,7120,s6-242-304-311-8402-0,00.html

It makes sense when you think physics. Sorry, I agree with the rest of your statements.

TrainingWithTonya

As for the Calorie thing, I have to comment because this has been such a fun conversation so far. Exercise Physiologists don't use Physics equations. First of all, the calories that physicists use do not equal the Calories exercise physiologists use. Ours are Kilocalories and actually 1000 times larger then the physics calories. Second, physicists keep saying we aren't doing any work when we lift a weight and put it back down because the weight is in the same position at the end of the movement as at the beginning of the movement.

What we do use are equations based on VO2 estimations. The reason for that is because the usage of 1 Liter of Oxygen by the body requires 5 Kilocalories of energy. So, if we can determine how many liters of oxygen you use to do something, then we can determine how many kilocalories you are burning doing that activity. There are several ways of estimating these things. Some formulas use heart rate because there appears to be a positive relationship between exercise heart rate and VO2. Unfortunately, if the elevation in heart rate isn't related to the actual activity of the body, then cellular respiration is virtually unchanged so the VO2 doesn't actually increase, meaning you aren't really burning more calories just because the heart rate increases. So, if your heart rate is already elevated by medications, caffeine, smoking, etc. a heart rate monitor isn't going to give you an accurate estimate of calorie burn. Nor is it going to give you an accurate estimate of calorie burn for anything that isn't steady state aerobic activity. (IE: it's inaccurate for intervals, weight training, etc.) The other methods we use to estimate calorie burn include formulas that take into consideration the mass, distance, speed, and incline. These formulas are based on years of research that show them to be fairly accurate for the AVERAGE population. Meaning some people will burn more and some people will burn less based on their fitness level and the efficiency of their body to utilize oxygen, carbohydrate, fat, etc. Those things actually can change within a matter of hours in the same individual too, based on what fuel they have consumed so even estimates based on the same person aren't 100% accurate. The only 100% accurate way to estimate your calorie burn is to live in a human calorimeter. In the calorimeter, everything that is consumed is weighed and measured and everything that is expelled is weighed and measured. You are basically stuck in this room where even the air you breathe is measured for it's oxygen content as you are breathing in and out. So, we do the best we can with estimates.

Anyway, the real point of the calorie thing is not necessarily how many calories you burn in a mile, but how many of the calories you burn are actually being burned from fat as opposed to carbohydrate and protein. Yes, you may burn 500 calories by running for 30 minutes and only 300 for walking an hour, but what percentage of those calories came from your fat stores? If you are doing a lower intensity workout, you can get 50% from fat, or in this hypothetical case, 150 fat calories. At the intensity of a run, however, only about 20% of the calories come from fat, so this hypothetical person would only burn 100 calories from fat. Yes, they burned more calories, but they burned fewer from their fat stores. And isn't it body fat we're actually trying to lose?

Now, if you are trying to improve your VO2 max and strengthen the heart, that has only been proven to be done at higher intensities, so we don't need to cut all high intensity exercise so we get more fat burning. It needs to be a balance, some high intensity, some low intensity, and some moderate intensity so we get all the best benefits to the body.

References:
Exercise Physiology by Powers and Howley
NSCA Essentials of Strength Training and Conditioning
ACSM Guidelines for Exercise Testing and Prescription
And Dr. Green T. Waggener, Professor of KSPE3420 Exercise Physiology at Valdosta State University, Valdosta, GA

This doens't make sense to me. You said the more oxygen we consume the more calories we consume. VO2MAX part of the formula for VO2MAX is based on bodyweight. If nothing changes for a person in terms of fitness except weight their VO2MAX would be higher. So according to what you said, or maybe I didn't understand fully you're saying a lighter person would burn more calories, which we all know not to be true.

Another thing you said, about less fat being burned during high intensity. I am pretty sure we all agree on this to be true. As you also know the POC(Post Oxygen Consumption) when we rest from high intensity, we aren't in a anerobic state anymore so most of the calories in theory would come from fat.

One more thing, from my understanding the higher the mitochondria the more fat burning ability. Mitochandria is produced by low intensity work, yes you can do it with high intensity work of course. You pretty much said low intensity work won't increase VO2MAX much. The people who have the highest VO2MAX are endurance athletes, the majority of their training is in a aerobic state.

Okay, I think you're confusing VO2 Max with VO2 during exercise. VO2 max is the maximum amount of oxygen that person can consume, which will improve with training. The VO2 during exercise is the volume of oxygen that they use to do that activity. The individual who is advanced in their training will become more efficient and actually consume less oxygen to do the same activity so therefore, their VO2 during exercise will be lower then it previously was doing the same activity so they will burn fewer calories for that activity then they previously did. The formulas for estimating calories burned also take weight into account because VO2 is generally listed in milliliters of oxygen per kilogram of body weight per minute. So, someone who is 50 kg will burn fewer calories then someone who is 100 kg if they are using the same amount of oxygen milliliters per kilogram per minute.

As for the EPOC curve, yes, we have an elevated burn after the workout and yes, it is primarily aerobic metabolism. However, the EPOC doesn't raise the metabolism so much that we even count those calories in our calorie burn estimate, so it's not much from fat stores because it's not a whole lot overall.

As for mitochondrial density, yes that is increased by aerobic endurance training. Mitochondrial density does increase the ability of the body to burn fat by using oxygen. Unfortunately, the research I've seen doesn't indicate that this increase in mitochondrial density elevates the VO2 max for an individual. In fact, it shows that oxygen is produced as a part of the chemical reaction in the mitochondria where fat is being burned, so there will be more oxygen in the body to be exhaled and read as less being used if we are going strictly by the volume of oxygen consumed which is O2 inhaled - O2 exhaled. Therefore, someone with more mitochondria from lots of low intensity training would be able to produce more oxygen in the body for the chemical processes of producing ATP and their VO2 during exercise would be lessened.

TrainingWithTonya

Thank you for this thread!!!! This is exactly what I needed to hear today. I just recently starting lifting weights and am currently holding the water weight as a result. My question to you is, should I keep my heart rate lower when doing cardio to allow my muscles to build? I've heard that if you do cardio too intense when trying to build muscle, you can halt your progress?

I dont get why you think you're retaining water as a result of weight lifting.

Because the first physiological response to heavy weight training is actually an increase in glycogen storage in the muscles. Glycogen is stored in 3 times as much water. So, if you store an additional gram of glycogen, you store 3 additional grams of water.

Reference: NSCA Essentials of Strength Training and Conditioning

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But at the same time aren't you burning glycogen for energy during weight lifting and thereby reducing your glycogen stores?

Yes, you are burning glycogen, but the response of the body to the usage of the stored glycogen is to store more glycogen for the next time you do that activity. It will then store more then it had previously stored to be able to do more work as you progress your training. It generally levels off after a couple of months of steady training to a balanced amount to what you regularly need for your workouts provided you fuel properly with carbs.

JNick77

Thank you for this thread!!!! This is exactly what I needed to hear today. I just recently starting lifting weights and am currently holding the water weight as a result. My question to you is, should I keep my heart rate lower when doing cardio to allow my muscles to build? I've heard that if you do cardio too intense when trying to build muscle, you can halt your progress?

I dont get why you think you're retaining water as a result of weight lifting.

Because the first physiological response to heavy weight training is actually an increase in glycogen storage in the muscles. Glycogen is stored in 3 times as much water. So, if you store an additional gram of glycogen, you store 3 additional grams of water.

Reference: NSCA Essentials of Strength Training and Conditioning

.

But at the same time aren't you burning glycogen for energy during weight lifting and thereby reducing your glycogen stores?

Yes, you are burning glycogen, but the response of the body to the usage of the stored glycogen is to store more glycogen for the next time you do that activity. It will then store more then it had previously stored to be able to do more work as you progress your training. It generally levels off after a couple of months of steady training to a balanced amount to what you regularly need for your workouts provided you fuel properly with carbs.

Gotcha', thanks.

ljmeep

wow! That was a lot of info to take in, especially reading all the reply posts. lol. I had no clue I was going to end up getting a lesson in physics.

I am very glad I took the time to read it all though. This info. is very helpful and nice to hear especially for someone who is just starting out. It's easy to get discouraged because your so over weight that your body is not physically capable of doing the same work outs as many of those around us (especially in a gym setting). I actually try very hard to do the most I can every time I work out. I find it very helpful to go w/ my bff because we push each other and compeat to burn the most calories in each work out. It also makes it fun.

I also tend to take every piece of advice on these forums with a grain of salt. But it's nice to see so much backing in some of these posts... it's also rather amusing to read the debates back and forth. Thanks for taking the time to share your knowledge and for being man enough to admit your mistakes as you did earlier in my readings.

NeuroticVirgo

If the distance it the goal, let's say 1 mile, whether you run it or walk it the calories burned is the SAME.

This definitely doesn't hold true for cycling: 10 miles at 15 mph burns less calories than cycling 10 miles at 18 mph. There is empirical proof of this in a number of places, not to mention my own experience with my heart rate monitor and numerous exercise calculators. Therefore, I don't see how it could hold true for walking or running.

I'm confused too. If I jog a mile I burn almost DOUBLE the amount of calories as I do walking...at least according to my HRM. I'm not an expert, but I don't see how they can be the same.

KeriA

Just recently I fit into clothes that I wore when I was about 10-15 pounds lighter than I am now. I am in the obese range but 27 pounds lighter than when I started however not quite as light as I was when I was wearing these clothes last. I have been exercising alot while losing weight. I have periods where I was in a weight loss plateau and continued to lose inches I thought because I was exercising. My only explanation is that I am as slim now as I was when I weighed less. I would expect that it is because I am fitter and have a greater % muscle than I did when I was lighter. I could definitely be wrong but how would you explain it. I am not talking about the size but the actual clothes I wore so it isn't the brand or style. I do not think that it is rare to find obese people on MFP. I think your post is great but now I have no explanation for this. Do you?

ninerbuff

Just recently I fit into clothes that I wore when I was about 10-15 pounds lighter than I am now. I am in the obese range but 27 pounds lighter than when I started however not quite as light as I was when I was wearing these clothes last. I have been exercising alot while losing weight. I have periods where I was in a weight loss plateau and continued to lose inches I thought because I was exercising. My only explanation is that I am as slim now as I was when I weighed less. I would expect that it is because I am fitter and have a greater % muscle than I did when I was lighter. I could definitely be wrong but how would you explain it. I am not talking about the size but the actual clothes I wore so it isn't the brand or style. I do not think that it is rare to find obese people on MFP. I think your post is great but now I have no explanation for this. Do you?

Obese people ARE one of the few who can put on a small amount of muscle while on calorie deficit. It doesn't hold true for the majority of people who are just trying to lose weight though.

ninerbuff

"Stretching prevents injuries."

After analyzing the results of six studies, researchers at the U.S. Centers for Disease Control and Prevention could not find any correlation between stretching and injury prevention. According to Dr. Julie Gilchrist, one of the researchers involved with the study, "Stretching increases flexibility, but most injuries occur within the normal range of motion." Dr. Gilchrist goes on to say, Stretching and warming up have just gone together for decades. It's simply what's done, and it hasn't been approached through rigorous science."
Make no mistake: A stretching program is not without benefits. Seven of nine studies suggest that a regular stretching program does help to strengthen muscles. However, it does not appear to actually prevent injuries. Warming up prior to exercise and increasing blood flow to the muscles is actually more conducive to injury prevention. I'm not suggesting that you eliminate stretching. It is valuable and flexibility is certainly important as we age. However, we may be off base assuming it's an injury-prevention technique.

James_1954

"Stretching prevents injuries."

... Warming up prior to exercise and increasing blood flow to the muscles is actually more conducive to injury prevention. I'm not suggesting that you eliminate stretching. ...

That's interesting, and it's something I've read from time to time. I guess my question is: what does a "warmup" look like? Is it basically a slower or easier version of the activity we're warming up for, or what?

Thanks in advance for your answer.

joejccva71

Good stuff Niner.

I have another myth debuking thread regarding more on the nutrition side that I bump usually once a day. A mod messaged me and said he couldn't sticky it. Maybe we can consolodate our threads somehow lol.

ninerbuff

That's interesting, and it's something I've read from time to time. I guess my question is: what does a "warmup" look like? Is it basically a slower or easier version of the activity we're warming up for, or what?

Thanks in advance for your answer.

If you're warming up for a run, a light slow jog or fast walk to start is a good. If you're going to lift weights, you do the movement with light weights for about 15 to 20 reps to get the blood and recruitment of muscle active. Usually a 5-10 minutes of light cardio is a good way to warm up for just about any exercise activity.

ninerbuff

Good stuff Niner.

I have another myth debuking thread regarding more on the nutrition side that I bump usually once a day. A mod messaged me and said he couldn't sticky it. Maybe we can consolodate our threads somehow lol.

Post it here!

James_1954

If you're warming up for a run, a light slow jog or fast walk to start is a good. If you're going to lift weights, you do the movement with light weights for about 15 to 20 reps to get the blood and recruitment of muscle active. Usually a 5-10 minutes of light cardio is a good way to warm up for just about any exercise activity.

Thanks! I'll try that.

One more question (and, if you don't feel like getting used as a free trainer-consultant, I understand): Most of what I do right now is cardio and all-lower-body (cycling and the elliptical). THis is because I've been troubled lately with some aching in the muscle on the outside of the upper arm (not the biceps, which is in front, and not the triceps, which is in back, but on the outside of the arm. It's the right arm only. I pretty much suspended my arm-related exercise, thinking that I need to rest it. But, after several weeks of resting it, it still aches. If this was you, would you go back to working it, do you think? (I'm 57 years old, and my whole musculo-skeletal is increasingly becoming a collection of minor aches and pains, which I mostly ignore unless they start feeling dangerous.)

Thanks again.

joejccva71

Good stuff Niner.

I have another myth debuking thread regarding more on the nutrition side that I bump usually once a day. A mod messaged me and said he couldn't sticky it. Maybe we can consolodate our threads somehow lol.

Post it here!

It's quite long bro.

JNick77

[ If you're going to lift weights, you do the movement with light weights for about 15 to 20 reps to get the blood and recruitment of muscle active. Usually a 5-10 minutes of light cardio is a good way to warm up for just about any exercise activity.

Have you ever read Chritian Thibaudeau's work on Neural Ramping? If not you should check it out because I think it's actually a more effective method of warming up for your lift. He actually promotes starting with some kind of explosive movement with very light weight to get the nervous system activated and then moving onto the Neural Ramping. For example you'd do something like,

Activation work: Power clean from the hang @ 60% of your normal work weight for 2 sets x 2 - 3 reps:
If you're Bench Pressing and your maximum work weight for this session is 200lbs then it would look something like,
Feeler set @ 90lbs
Set 1: 140lbs
Set 2: 160lbs
Set 3: 180lbs
Set 4: 200lbs
Begin your workout.

Each set is suppose to be completed with momentum. Ever since I've started doing this I feel like my core pressing lifts have become more productive.

ninerbuff

Thanks! I'll try that.

One more question (and, if you don't feel like getting used as a free trainer-consultant, I understand): Most of what I do right now is cardio and all-lower-body (cycling and the elliptical). THis is because I've been troubled lately with some aching in the muscle on the outside of the upper arm (not the biceps, which is in front, and not the triceps, which is in back, but on the outside of the arm. It's the right arm only. I pretty much suspended my arm-related exercise, thinking that I need to rest it. But, after several weeks of resting it, it still aches. If this was you, would you go back to working it, do you think? (I'm 57 years old, and my whole musculo-skeletal is increasingly becoming a collection of minor aches and pains, which I mostly ignore unless they start feeling dangerous.)

Thanks again.

If it's the outside of your upper arm it's either the biceps or triceps. Does it hurt more when curl up or push down?