The tiny fossil of a prehistoric baby bird is helping scientists understand how early avians came into the world in the Age of Dinosaurs.
Artist impression of Enantiornithes [Credit: Raúl Martín] |
It measures less than five centimetres -- smaller than the little finger on an average human hand -- and would have weighed just 10 grams or 0.3 ounces when it was alive. What makes this fossil so important and unique is the fact it died not long after its birth. This is a critical stage in a bird's skeletal formation. That means this bird's extremely short life has given researchers a rare chance to analyse the species' bone structure and development.
Studying and analysing ossification - the process of bone development - can explain a lot about a young bird's life the researchers say. It can help them understand everything from whether it could fly or if it needed to stay with its parents after hatching or could survive on its own.
Phosphorous mapping image and photo of fossil [Credit: Dr. Fabien Knoll] |
With the fossil being so small the team used synchrotron radiation to picture the tiny specimen at a 'submicron' level, observing the bones' microstructures in extreme detail.
Knoll said: 'New technologies are offering palaeontologists unprecedented capacities to investigate provocative fossils. Here we made the most of state-of-the-art facilities worldwide including three different synchrotrons in France, the UK and the United States.'
Dr Fabien Knoll in lab [Credit: Dr. Fabien Knoll] |
The patterns of ossification observed in this and the other few very young enantiornithine birds known to date also suggest that the developmental strategies of this particular group of ancient avians may have been more diverse than previously thought.
However, the team say that its lack of bone development doesn't necessarily mean the hatchling was over reliant on its parents for care and feeding, a trait known as being 'altricial'. Modern day species like love birds are highly dependent on their parents when born. Others, like chickens, are highly independent, which is known as 'precocial'. Although, this is not a black-and-white issue, but rather a spectrum, hence the difficulty in clarifying the developmental strategies of long gone bird species.
Luis Chiappe, from the LA Museum of Natural History and study's co-author added: 'This new discovery, together with others from around the world, allows us to peek into the world of ancient birds that lived during the age of dinosaurs. It is amazing to realise how many of the features we see among living birds had already been developed more than 100 million years ago.'
The findings are published in Nature Communications.
Source: University of Manchester [March 05, 2018]