Your lungs are really amazing. An anatomy professor explains why

Lungs are remarkable organs that continuously achieve amazing feats, which they do so well that we take them for granted, except when their function is diminished. It all happens in a space inside your chest, divided in two and reduced by the presence of the heart, the great vessels and the esophagus.

With Supreme Court Justice Ruth Bader Ginsburg having recently returned to the court after surgery for lung cancer, I have been asked a lot of questions about the lungs, as I am a professor of anatomy.

Many lung cancers are not operable, but to treat some types of lung disease, such as early stages of lung cancer, a surgical treatment called a lobectomy may be performed. In this operation, a lobe of a lung (your right lung has three lobes, your left lung has two) is removed. Afterward, the other lobes expand to adapt and compensate for the missing tissue, allowing the lungs to work as well or better than they did before.

In addition to being highly efficient organs, the lungs are beautifully complex in their structure. I can’t help but wonder: If we appreciated them more, would we be more proactive in taking care of them?

Breath of life

The primary function of the respiratory system is to bring oxygen into our lungs. There it is exchanged for a waste product, carbon dioxide, which is then removed from the body.

Several weeks following conception, the work of the lungs is performed by the placenta, a structure outside our fetal bodies where our blood exchanges carbon dioxide and oxygen with the maternal blood of the uterus.

Before birth, we just practice respiratory movements, moving amniotic fluid instead of air in and out of the lungs.

A newborn and mother. After birth, a baby gasps because of a buildup of CO2 and takes its first breath to take in oxygen. Anneka/
Within seconds after the umbilical cord is cut, a buildup of carbon dioxide causes newborns to gasp for breath to exchange it for oxygen, an activity that will continue until our death. The average person breathes some 13 million cubic feet of air during their lifetime.

During quiet activity, such as bed rest or sitting, we take eight to 16 breaths per minute, each breath inhaling about a pint of air containing 21 percent oxygen and a small amount of carbon dioxide for about two seconds. Then for three seconds, we exhale the same amount of air, but it now contains 16 percent oxygen and a 100-fold increase in carbon dioxide. In other words, you spend about 40 percent of your life drawing air in, and 60 percent of your life expelling it.

Your lungs, by the numbers

Each day, 5,000 gallons of air are transported through airways leading into and extending throughout the lungs. The airways branch and diminish in size 22 times. Almost of all this occurs within our lungs, with these airways reaching a combined length of 14,900 miles.

About 2,600 gallons of the transported air are delivered into and removed from 300 million tiny, thin-walled, hollow sacs, or alveoli, that provide an enormous surface for the exchange of oxygen, required by all our cells, for carbon dioxide, a waste product from them. This is an area varying in size between half and most of a regulation tennis court.

This immense area is contained within two lungs, each only somewhat smaller than three, 1-liter bottles. The left lung is 10 percent smaller than the right, due to the left-sided position of the heart.

A 3-D illustration of alveoli. RAJ CREATIONZS/
The alveoli are tightly surrounded by blood vessels, or capillaries, so small that red blood cells continuously pass through them squeezed into a single row as they exchange carbon dioxide for oxygen.

The capillaries of the lung receive an immense blood supply, equal to that distributed to all other parts of the entire body. The alveoli expand and contract 15,000 times a day. During activity, the rate of respiration doubles – and in extreme activities triples – and the amount of air reaching the alveoli increases three to five times. Breathing deeper and faster uses lung capacity that’s held in reserve while at rest. Stress can also result in deeper and faster respiration.