Aerobic Exercise,What is aerobic exercise?
Aerobic exercise is sometimes known as “cardio” — exercise that requires pumping of oxygenated blood by the heart to deliver oxygen to working muscles.
Aerobic exercise stimulates the heart rate and breathing rate to increase in a way that can be sustained for the exercise session. In contrast, anaerobic (“without oxygen”) exercise is activity that causes you to be quickly out of breath, like sprinting or lifting a heavy weight.
Examples of aerobic exercises include cardio machines, spinning, running, swimming, walking, hiking, aerobics classes, dancing, cross country skiing, and kickboxing. There are many other types.
Aerobic exercises can become anaerobic exercises if performed at a level of intensity that is too high.
Aerobic exercise not only improves fitness; it also has known benefits for both physical and emotional health.
Aerobic exercise can help prevent or reduce the chance of developing some cancers, diabetes, depression, cardiovascular disease, and osteoporosis.
An aerobic exercise plan should be simple, practical, and realistic. Specific equipment (such as cardio machines) may be used but is not necessary for successful aerobic exercise.
What is aerobic exercise?
Share Your Story
Imagine that you’re exercising. You’re working up a sweat, you’re breathing hard, your heart is thumping, blood is coursing through your vessels to deliver oxygen to the muscles to keep you moving, and you sustain the activity for more than just a few minutes. That’s aerobic exercise (also known as “cardio” in gym lingo), which is any activity that you can sustain for more than just a few minutes while your heart, lungs, and muscles work overtime. In this article, I’ll discuss the mechanisms of aerobic exercise: oxygen transport and consumption, the role of the heart and the muscles, the proven benefits of aerobic exercise, how much you need to do to reap the benefits, and more.
The beginning
It all starts with breathing. The average healthy adult inhales and exhales about 7 to 8 liters of air per minute. Once you fill your lungs, the oxygen in the air (air contains approximately 20% oxygen) is filtered through small branches of tubes (called bronchioles) until it reaches the alveoli. The alveoli are microscopic sacs where oxygen diffuses (enters) into the blood. From there, it’s a beeline direct to the heart.
Getting to the heart of it
The heart has four chambers that fill with blood and pump blood (two atria and two ventricles) and some very active coronary arteries. Because of all this action, the heart needs a fresh supply of oxygen, and as you just learned, the lungs provide it. Once the heart uses what it needs, it pumps the blood, the oxygen, and other nutrients out through the large left ventricle and through the circulatory system (cardiovascular system) to all the organs, muscles, and tissues that need it.
A whole lot of pumping going on
Your heart beats approximately 60-80 times per minute at rest, 100,000 times a day, more than 30 million times per year, and about 2.5 billion times in a 70-year lifetime! Every beat of your heart sends a volume of blood (called stroke volume — more about that later), along with oxygen and many other life-sustaining nutrients, circulating through your body. The average healthy adult heart pumps about 5 liters of blood per minute.
Oxygen consumption and muscles
All that oxygen being pumped by the blood is important. You may be familiar with the term “oxygen consumption.” In science, it’s labeled VO2, or volume of oxygen consumed. It’s the amount of oxygen the muscles extract, or consume from the blood, and it’s expressed as ml/kg/minute (milliliters per kilogram of body weight). Muscles are like engines that run on fuel (just like an automobile that runs on fuel); only our muscles use fat and carbohydrates instead of gasoline. Oxygen is a key player because, once inside the muscle, it’s used to burn fat and carbohydrate for fuel to keep our engines running. The more efficient our muscles are at consuming oxygen, the more fuel we can burn, the more fit we are, and the longer we can exercise.
How aerobically fit can we be?
The average sedentary adult will reach a level of oxygen consumption close to 35 ml/kg/minute during a maximal treadmill test (where you’re asked to walk as hard as you can). Translated, that means the person is consuming 35 milliliters of oxygen for every kilogram of body weight per minute. That’ll get you through the day, but elite athletes can reach values as high as 90 ml/kg/minute! How do they do it? They may have good genes for one, but they also train hard. And when they do, their bodies adapt. The good news is that the bodies of mere mortals like the rest of us adapt to training too. Here’s how.
What are the fitness benefits of aerobic exercise?
How our bodies adapt
Here’s what happens inside your body when you do aerobic exercise regularly:
Your heart gets stronger and pumps more blood with each beat (larger stroke volume). Elite athletes, as I just mentioned, can have stroke volumes more than twice as high as average individuals. But it’s not just that. Conditioned hearts also have greater diameter and mass (the heart’s a muscle too and gets bigger when you train it), and they pump efficiently enough to allow for greater filling time, which is a good thing because it means that more blood fills the chambers of the heart before they pump so that more blood gets pumped with each beat.
Greater stroke volume means the heart doesn’t have to pump as fast to meet the demands of exercise. Fewer beats and more stroke volume mean greater efficiency. Think about a pump emptying water out of a flooded basement. The pump works better and lasts longer if it can pump larger volumes of water with each cycle than if it has to pump faster and strain to get rid of the water. High stroke volume is why athletes’ hearts don’t pump as fast during exercise and why they have such low resting heart rates; sometimes as low as 40 beats per minute, whereas the average is 60-80 beats per minutes.
Downstream from the heart are your muscles, which get more efficient at consuming oxygen when you do regular aerobic exercise (remember, “consuming” oxygen means that the muscles are taking the oxygen out of the blood). This happens because of an increase in the activity and number of enzymes that transport oxygen out of the bloodstream and into the muscle. Imagine 100 oxygen molecules circulating past a muscle. You’re twice as fit if the muscle can consume all 100 molecules than if it can only consume 50. Another way of saying it is that you’re twice as fit as someone if your VO2 max is 60ml/kg/min. and theirs is 30ml/kg/min. In terms of performance in this scenario, you’ll have more endurance because your muscles won’t run out of oxygen as quickly.
Mitochondria inside the muscle increase in number and activity. Mitochondria are the powerhouses of your cells. They do all the heavy-duty work to keep you moving. They use the oxygen to burn the fat and carbohydrate that makes you go. The good news is that they increase in number and activity, by as much as 50%, in just a matter of days to weeks in response to regular aerobic exercise in adults of all ages.
Burn, baby, burn
I mentioned that fat and carbohydrate are the fuels our muscles burn. The difference between them is that fat is high-test; it contains 9 calories per gram whereas carbohydrate has only 4, and so you get more energy and can go farther on a gram of fat than on a gram of carbohydrate. You want to burn fat because it’s such an efficient fuel, plus it’s nice to lose some of your excess fat! The catch is that you need more oxygen to burn fat because it’s denser than carbohydrate. The good news is that your body gets better at using oxygen and burning fat when you do regular aerobic exercise; like I described, your heart pumps more blood, your muscles consume more oxygen, and you have more mitochondria.
What is the difference between aerobic vs. anaerobic exercise?
I defined aerobic exercise for you in the introduction. It’s any activity that stimulates your heart rate and breathing to increase but not so much that you can’t sustain the activity for more than a few minutes. Aerobic means “with oxygen,” and anaerobic means “without oxygen.” Anaerobic exercise is the type where you get out of breath in just a few moments, like when you lift weights for improving strength, when you sprint, or when you climb a long flight of stairs.
A caveat
Dancing, swimming, water aerobics, biking, walking, hiking, climbing steps (two at a time for a more vigorous workout), low-impact dance classes, kick-boxing, all the cardio machines at the gum (treadmill, elliptical, bike, rower, x-c skiing, stair-climber), and many other activities are all examples of types of aerobic or cardio activities, but they can be anaerobic too if they are performed at a high enough intensity. Try riding your bike alongside Lance Armstrong in the French Alps and you’ll know what anaerobic exercise means in moments. But then again, riding along on your bike at a leisurely 8-10 mph on the boardwalk at the seashore is the same activity, but at a much lower intensity, much lower heart rate, and much lower oxygen consumption, and so in this case, biking is aerobic. The bottom line is that the intensity at which you perform an activity determines if it’s aerobic or anaerobic.
How do I get started on an aerobic exercise program?
My suggestion for getting started with an exercise program is almost always the same. Keep it simple, keep it practical, keep it convenient, keep it realistic, keep it specific, and don’t try to make up for years of inactivity all at once. Select any activity and amount of time where the probability of sticking with it is high. You may not love walking, but if you can do it right outside your door, and it requires no special equipment, and you already know how to do it (you’ve been walking your entire life!), then walking might be your best bet for getting started because it’s so convenient.
What I mean by “be specific” pertains to setting exercise plans. Planning is helpful for behavior change, and I suggest that you set goals each week. I suggest writing down what day(s) of the week you’ll exercise, what time of day, minutes of activity, location, and the activity that you’ll do. Be as specific and realistic as possible, and remember that it’s not how much you do when you get started but that you simply get started (getting started is usually the hardest part).
A sample plan might look like this:
Monday: Take a 20-minute brisk walk at 7 a.m. around the block four times.
Tuesday: Do the same as on Monday.
Wednesday: Take a 20-minute walk at 6:30 p.m. (right before dinner) around the block.
Thursday: Take the day off.
Friday: Take a 20-minute walk at 7 a.m. around the block.
Saturday: Walk with your family at 10 a.m. for 45 minutes in park.
Sunday: Bike ride with your spouse for 60 minutes in park at noon. Mom will baby-sit.
Another plan I like is the five-minute out, five-minute back plan. Just like it sounds, you walk for five minutes from your starting point, turn around, and walk back. It’s simple and doable for almost everyone. It’s a change in your activity behavior even though it’s not all that much, and you can increase as you get more used to it. From five minutes you could go to seven and a half out, seven and a half back, a total of 15 minutes just like that. And you can keep your eye on 15 out, 15 back, and there you go meeting the Surgeon General’s recommendation of 30 minutes. If you’re feeling ambitious, you can add some abdominal crunches and push-ups once you get back. For push-ups, if you can’t do a standard one on the floor, modify them by leaning against a wall, leaning against a table, or on your knees on the floor. The lower you go the harder they are. Start with two to three sets of crunches and push-ups, 12-15 repetitions, three to four days a week. As they get easier, you can increase the intensity of crunches by going slower or putting your legs in the air with your knees bent. As push-ups get easier, you can go to the next lower level (for example, from wall to table to on your knees on the floor).
I suggest keeping records of your weekly progress by writing down what happens, or at least checking off that you followed through, and then setting your weekly plan every week for at least three months. Then at three months, you can evaluate your progress and see if any changes need to be made. How will you know if you’re ready to stop setting weekly goals each week? Ask yourself if you believe you will be exercising regularly in six months. If the answer is “I’m not sure,” or “no,” then you ought to continue to set weekly goals. If you are confident that you can maintain the behavior and will be exercising in six months, then you may not need to set weekly goals, but at the first sign of slipping, you ought to go back to it.