How Sound Reveals The Invisible Within Us
Editor's note: One of the most intriguing stories we ran in 2015 looked at — and listened to — how the invention of the stethoscope changed medicine. We're presenting it again, in case you missed it in July.
Over the years, scientists have mostly interpreted the world through what they can see. But in the past few decades, a culture of listening has blossomed, especially among biologists who seek to understand how animals communicate. Morning Edition undertook a weekly series called Close Listening: Decoding Nature Through Sound. This was the first piece among those stories.
Microscopes illuminate the invisibly tiny; telescopes reveal the heavens. But sound? Scientists didn't really see it as all that important, until an amazing invention came along that opened new worlds: the stethoscope.
"I think the first time one can see this kind of 'listening culture' is with the development of the stethoscope at the beginning of the 19th century in Paris," says Trevor Pinch, a Cornell University sociologist.
"You couldn't see inside a body back then," Pinch says, "unless of course it was dead, which was a bit late for anyone except a pathologist." But a stethoscope told a living story — of circulating blood, or the seesawing of lungs.
"It was one of the first ways of getting a diagnosis on a patient independent of their own version of what was happening," says Pinch. "In fact, it's become so important that the emblem of the physician is often the stethoscope around the neck — that's how you tell who the doc is."
We asked one of those doctors to help us hear the way he hears. Dr. Adam Law, an endocrinologist and primary care physician in Ithaca, N.Y., was teaching a medical student how to use a stethoscope to diagnose a heart problem in one of his patients. We brought along recording equipment so we could listen in. Law's student is Nick Maston, in his third year at Weill Cornell Medical College.
Law ushered the patient into the examining room, and turned to his student. "Nick, why don't you examine this patient's cardiovascular system?" We'd already plugged our recorder into the electronic stethoscope, but Law and Maston both warned us — interpreting sounds from inside a body is not for amateurs.
"As a student it's hard to learn ... you have to listen to thousands of hearts to find that out," Maston said."
Maston placed the bell of the instrument on the patient's neck — right on the carotid artery — and we all heard this:
It's the sound of the heart pumping blood through its aortic valve and out into the pulsing carotid artery. Then Maston moved the bell to the patient's side, placing it just under the man's armpit. A slightly different sound came through:
Law turned to his student: "Hear the difference in quality?" Maston didn't hesitate: "Yeah, very loud second heart sound."
Law's patient has a heart murmur — a malfunction of the heart valves that control blood flow. Textbooks say you can hear a murmur's "swishing" sound. But if you didn't hear it, don't feel bad. We journalists couldn't make out any swishing sound, either.
Maston apparently could. "So, do you want me to talk about what I heard?" he asked us. "It sounded like a mitral murmur, but I heard it best where I expect to hear an aortic murmur. So ... this is a situation where Dr. Law is going to have to jump in and rescue me."
Law confirmed that Nick had it right. The patient's heart has a little bit of both types of murmur, he said, from the mitral and aortic valves.
We amateurs didn't hear it because we simply didn't know what to listen for. Think of the sound as if it were the audio version of a fossil bone or relic lying in the dirt; a seasoned archaeologist can pick those out more readily than other people because the pros have a sort of "search image" in their brain.
"The musical note of the heart is actually complicated," Law said. "It has harmonics; it has overtones. And that gives the sound — and the murmurs — in the heart a certain quality," he explained. "One has to tune one's ears."
So how do you tune your ears? "Pattern recognition is the key," Pinch told us later.
Some patterns, like the start of Beethoven's Fifth Symphony, are easily recognized. But it gets harder as the sounds get more complex. Two mustached wrens singing a duet start as two seemingly random singers. Then they suddenly synchronize their songs, and a pattern emerges:
Pinch has made a career of studying how scientists listen. He notes that listening has certain advantages over vision. "The visual field is kind of in front of us — like a kind of screen," he says, while sound is "all around."
If seeing is like being in an art gallery, hearing is more like being in a swimming pool — where we're swimming all the time. At night, we'll wake up to a baby's cry, or to the sound of danger — a predator, perhaps. Such sounds trigger an ancient alarm system buried deep within our species' brains. Listening, says Pinch, especially at night, "has probably been evolutionarily very, very important."
The problem of using sound to understand physical phenomena — from the weather to animal behavior, to the fact that an engine needs oil — is that sound is ephemeral. It's in one ear and out the other.
That is, until, as Pinch points out, people invented a way to nail down sound. "I think the development of the phonograph, in particular, around 1880 ... really does change how we think about sound," Pinch says. "Because, for the first time ever, sound is really transportable. ... You can store it in a medium."
Once people could capture sound, and really listen, Pinch says, that opened up a universe of new possibilities.
Editor's note: An alert reader reminded us that heart murmurs can arise from other sources, too, and that many such sounds are harmless.
Bill McQuay is an audio producer at the Cornell Lab of Ornithology.
Alison Richards, NPR's senior editor for science, is the series' editor.
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