The anatomy of zebra finches’ eyes is distinct from known vertebrate tissues. Their retinas, responsible for light detection, utilize an unusual energy source by absorbing glucose instead of the typical oxygen.

This groundbreaking discovery addresses a 400-year-old question regarding avian eye physiology. Christian Damsgaard from Aarhus University in Denmark notes, “This is compelling evidence that certain neurons can operate without oxygen, notably in common garden birds.”

The retina sends light signals to the brain, demanding considerable energy supplied by oxygen and nutrients through blood vessels. However, the thick avascular retina in zebra finches raises the question of how these essential nerve cells sustain life.

Damsgaard and his research team investigated zebra finches, or Teniopygia guttata, in the lab. By attaching oxygen sensors to their eyes, they discovered that the inner retinal layer does not receive oxygen.

“Oxygen enters through the back of the eye, but it cannot permeate the retina,” explains Damsgaard.

Analyzing metabolic gene activity in various retinal layers revealed frequent reliance on glycolysis in areas devoid of oxygen. Although this process is less efficient, it serves the retina’s energy needs.

“This method requires 15 times more glucose for equivalent energy output,” states Damsgaard. So, where does all this sugar come from?

The answer lies in the pecten, a structure of rake-shaped blood vessels found in avian eyes. Previously thought to transport oxygen, recent findings show that the pecten instead inundates the retina with glucose—four times what brain cells absorb—fueling its high-energy requirements.

According to Luke Tyrrell, researchers at the State University of New York at Plattsburgh are astonished that birds have evolved to depend on such a less efficient method for vision. “The avian retina is among the most energy-intensive tissues in the animal kingdom,” he adds.

This specialized, blood vessel-free retina may provide superior vision in birds, with the pecten sugar supply being a crucial evolutionary adaptation. An oxygen-independent retina could also contribute to their capabilities for high-altitude migratory flights.

For Pavel Niemec, findings from Charles University in Prague, Czech Republic, illustrate that evolution can yield counterintuitive solutions to physical challenges.

Damsgaard and his colleagues believe there may be future applications for modifying human cells to allow greater resilience under low-oxygen conditions, such as after a stroke.