Summary: Can Screamers get any stranger? You bet! Join Kiersten as she discusses some skeletal anomalies that Screamers possess.

For my hearing impaired followers, a complete transcript of this podcast follows the show notes on Podbean

Show Notes:

“Functional significance of the uncinate processes in birds”, by Pete G. Tickle, A. Roland Ennos, Laua E. Lennox, Steven F. Perry, and Jonathan R. Codd. The Journal of Experimental Biology 210, 3955-3961. 2007 doi:10.1242/jeb.008953

“Uncinate processes in birds: Morphology, physiology and function,” by Jonathan R. Codd. Comparative Biochemistry and Physiology Part A: Molecular and Integrative Physiology, Vol 156, Issue 3, July 2010, 303-308.

Britannica: Screamers, https://www.britannica.com

Music written and performed by Katherine Camp

Transcript

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Kiersten - This is Ten Things I Like About…a ten minute, ten episode podcast about unknown or misunderstood wildlife.

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Welcome to Ten Things I Like About… I’m Kiersten, your host, and this is a podcast about misunderstood or unknown creatures in nature. Some we’ll find right out side our doors and some are continents away but all are fascinating. 

This podcast will focus ten, ten minute episodes on different animals and their amazing characteristics. Please join me on this extraordinary journey, you won’t regret it.

Episode six of Screamers is going to take us on an interesting journey into  Screamer anatomy because the sixth thing I like about screamers is their weird anatomical quirks. Last episode we talked about one of their special anatomical accessories, the spurs. In this episode we will look at two more of the Screamer’s anatomical anomalies that also pertain to the skeleton.

Many of you have probably heard somewhere that birds have hollow bones. This is a simplified statement about bird bone anatomy. We will need to understand this a bit before we talk about screamer bones, so, those of you that already know this, bear with me, for those of you who are hearing this for the first time, hold on to your hat, I’m about to blow you mind.

Vertebrate skeletons are made up of hard, calcium rich bones. It’s what give our bodies their shape and ability to move. Birds are vertebrates so they rely on their skeleton to give their body shape and act as the anchor for muscles to allow them movement, just like mammals. Avian bones are special because they have adapted to the bird’s need to fly. If you have too much weight defying gravity can be difficult. Flighted birds adapted to this challenge by evolving less solid bones than mammals. 

Using the word hollow, makes you think of a tube, such as a straw or toilet paper tube that is completely open inside with no internal structure. You can look through one end and see clearly out the other end with no obstacles. Bird bones are not hollow in this manner. Their bones have an internal structure throughout the tube. If we were to look inside a bird’s bone we would see more of a honeycomb design. It’s essentially bones with air pockets. These are called pneumatic bones. 

The bones have lessened weight by getting rid of dense material but have increased strength by adding structure throughout the middle of the bone. This is how flighted birds can get off the ground and fly. They have bones that contain more air that provide structure for the body and muscles without being so solid that flying is a struggle. 

Now having said this, if we look at an average flighted bird, say a Bald Eagle or a Northern Cardinal, not all of their bones have this honeycomb structure. Typically, the larger bones will have this structure and smaller bones will not. The smaller bones will be more solid. This is where the Screamer skeletal oddity applies. All the bones in a screamer have this open