Indian-Origin Scientist Developes New 3D Software to Track Embryonic Development

WASHINGTON:  An Indian-origin scientist has developed a new, open-source software that can help track the embryonic development and movement of neuronal cells throughout the body of the worm, and is now available to scientists.

The software is described in a paper published in the open access journal, eLife on December 3rd by researchers at the National Institute of Biomedical Imaging and Bioengineering (NIBIB) and the Center for Information Technology (CIT); along with Memorial Sloan-Kettering Institute, New York City; Yale University, New Haven, Connecticut; Zhejiang University, China; and the University of Connecticut Health Center, Farmington. NIBIB is part of the National Institutes of Health.
Although scientists have identified a number of important proteins that determine how neurons navigate during brain formation, it is largely unknown how all of these proteins interact in a living organism.

“Understanding why and how neurons form and the path they take to reach their final destination could one day give us valuable information about how proteins and other molecular factors interact during neuronal development,” explained Hari Shroff, head of the National Institute of Biomedical Imaging and Bioengineering (NIBIB) research team.

The new technology will be pivotal in their project to create a 4D neurodevelopmental “worm atlas” that attempts to catalog the formation of the worm nervous system.

This catalog will be the first comprehensive view of how an entire nervous system develops.

According to Mr Shroff, it will be helpful in understanding the fundamental mechanisms by which all nervous systems, including ours, assemble.

They also expect that some of the concepts developed, such as the approach taken to combine neuronal data from multiple embryos, can be applied to additional model organisms besides the worm.

“We do not yet understand neurodevelopment even in the context of the humble worm but we’re using it as a simple model of how these factors work together to drive the development of the worm brain and neuronal structure,” he informed.

“We are hoping that by doing so, some of the lessons will translate all the way up to humans,” Mr Shroff added.

The worm known as C elegans has only 302 neurons, 222 of which form while the worm is still an embryo.

The worm even has its own versions of many of the same proteins used to direct brain formation in more complex organisms such as flies, mice, or humans.

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