Experts still trying to crack knuckle case
In some households, cracking your knuckles is a declaration of war. Whether you can’t stand the sound or can’t see what the fuss is about, you might be surprised to learn that where exactly the sound is coming from is still a subject of scientific research.
For more than 50 years people have been publishing scholarly papers about what causes it. Lately an older theory, that the sound arises from the popping of a bubble in the joint, has been challenged by one that holds that the formation of the bubble itself is responsible. In the latest edition of the journal Scientific Reports, the saga continued: A pair of researchers at the Ecole Polytechnique in France reveal a mathematical model of a cracking knuckle and suggest that the old theory could accurately explain the sound.
The first thing to understand about the knuckle is that it is full of fluid. Where the two bones of the finger meet, a little lake of synovial fluid keeps them from grinding on each other. There is gas dissolved in the synovial fluid, mostly carbon dioxide, and it usually stays there.
However, when the bones are pulled away from each other, there’s a sudden drop in pressure in the middle of the joint. Lower pressure allows the gases to come together, forming bubbles. Earlier work had suggested the collapse of such structures was behind the noise.
In 2015, however, Greg Kawchuk of University of Alberta and collaborators used an MRI scanner to record what was happening in the finger of a volunteer who was a frequent knuckle-cracker. In the images, a bulge suddenly appears in the knuckle as it is cracked.
That is the result, Kawchuk and colleagues wrote, of the formation of a bubble, which persisted for some time afterward, and whose creation might be responsible for the cracking noise. They posited that the bubble generated a pressure wave in the fluid, producing a sound.
Abdul Barakat, a professor of biomechanics at the Ecole Polytechnique in France, and Vineeth Suja, then a master’s student, came across the 2015 paper as they grew interested in knuckle-cracking. They created a simplified mathematical model of a joint with a bubble in it and ran simulations, comparing the theoretical sounds of the bubble collapsing in the model with recordings of Suja, who is now a doctoral student at Stanford University, and others cracking their knuckles.
They found that the sounds predicted by the model would have the volume and frequency to match the recordings fairly well — even if the bubble only shrank suddenly, rather than disappearing. “You don’t need full bubble collapse for the sound to be generated,” Barakat said. “All you need is partial collapse.”