The Woodruff School

SUMMARY

The roundworm C. elegans offers a unique opportunity as a model organism to develop necessary methodologies for studying head anatomy. Existing approaches, while providing valuable insights, have technical limitations in terms of accuracy, throughput, robustness, and accessibility. This proposal introduces an optimized pipeline to overcome these challenges and explore its application across diverse scenarios. In aim 1, an experimental and computational pipeline will be presented for constructing complete whole-brain data-driven anatomical atlases for N2 young adult worms. In Aim 2, the pipeline will be adapted for comparative studies across various biological factors such as genetic backgrounds and developmental stages, with carefully chosen metrics to understand underlying biology from observed differences. In Aim 3, our standard N2 atlas will be incorporated to address challenges in functional imaging analysis, accompanied by advancements in image processing techniques. This proposed pipeline has the potential to enhance our understanding of C. elegans brain and may contribute to a broader comprehension of nervous systems in other biological organisms.

SUBJECT:	Ph.D. Proposal Presentation

BY:	Zikai Yu

TIME:	Tuesday, March 26, 2024, 2:00 p.m.

PLACE:	EBB, 3029

TITLE:	Automated pipeline for building whole-brain anatomical atlases and comparative analysis of diverse biological factors in C. elegans

COMMITTEE:	Prof. Hang Lu, Chair (Chemical and Biomolecular Engineering) Prof. Mark Styczynski (Chemical and Biomolecular Engineering) Prof. Patrick McGrath (Biological Sciences) Prof. Todd Sulchek (Mechanical Engineering) Prof. Eva Dyer (Biomedical Engineering)

SUMMARY The roundworm C. elegans offers a unique opportunity as a model organism to develop necessary methodologies for studying head anatomy. Existing approaches, while providing valuable insights, have technical limitations in terms of accuracy, throughput, robustness, and accessibility. This proposal introduces an optimized pipeline to overcome these challenges and explore its application across diverse scenarios. In aim 1, an experimental and computational pipeline will be presented for constructing complete whole-brain data-driven anatomical atlases for N2 young adult worms. In Aim 2, the pipeline will be adapted for comparative studies across various biological factors such as genetic backgrounds and developmental stages, with carefully chosen metrics to understand underlying biology from observed differences. In Aim 3, our standard N2 atlas will be incorporated to address challenges in functional imaging analysis, accompanied by advancements in image processing techniques. This proposed pipeline has the potential to enhance our understanding of C. elegans brain and may contribute to a broader comprehension of nervous systems in other biological organisms.