Your search keyword '"McNutt, Brody"' showing total 3 results

1. Whole-Herd Elephant Pose Estimation from Drone Data for Collective Behavior Analysis

Author

McNutt, Brody, Zhang, Libby, Carey-Douglas, Angus, Vollrath, Fritz, Pope, Frank, and Brickson, Leandra

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

This research represents a pioneering application of automated pose estimation from drone data to study elephant behavior in the wild, utilizing video footage captured from Samburu National Reserve, Kenya. The study evaluates two pose estimation workflows: DeepLabCut, known for its application in laboratory settings and emerging wildlife fieldwork, and YOLO-NAS-Pose, a newly released pose estimation model not previously applied to wildlife behavioral studies. These models are trained to analyze elephant herd behavior, focusing on low-resolution ($\sim$50 pixels) subjects to detect key points such as the head, spine, and ears of multiple elephants within a frame. Both workflows demonstrated acceptable quality of pose estimation on the test set, facilitating the automated detection of basic behaviors crucial for studying elephant herd dynamics. For the metrics selected for pose estimation evaluation on the test set -- root mean square error (RMSE), percentage of correct keypoints (PCK), and object keypoint similarity (OKS) -- the YOLO-NAS-Pose workflow outperformed DeepLabCut. Additionally, YOLO-NAS-Pose exceeded DeepLabCut in object detection evaluation. This approach introduces a novel method for wildlife behavioral research, including the burgeoning field of wildlife drone monitoring, with significant implications for wildlife conservation., Comment: Accepted to CV4Animals: Computer Vision for Animal Behavior Tracking and Modeling Workshop in conjunction with Computer Vision and Pattern Recognition 2024

Published

2024

2. Derivation of elephant induced pluripotent stem cells

Author

Appleton, Evan, primary, Hong, Kyunghee, additional, Rodríguez-Caycedo, Cristina, additional, Tanaka, Yoshiaki, additional, Ashkenazy-Titelman, Asaf, additional, Bhide, Ketaki, additional, Rasmussen-Ivey, Cody, additional, Ambriz-Peña, Xochitl, additional, Korover, Nataly, additional, Bai, Hao, additional, Quieroz, Ana, additional, Nelson, Jorgen, additional, Rathod, Grishma, additional, Knox, Gregory, additional, Morgan, Miles, additional, Malviya, Nandini, additional, Zhang, Kairui, additional, McNutt, Brody, additional, Kehler, James, additional, Kowalczyk, Amanda, additional, Bow, Austin, additional, McLendon, Bryan, additional, Cantarel, Brandi, additional, James, Matt, additional, Mason, Christopher E., additional, Gray, Charles, additional, Koehler, Karl R., additional, Pearson, Virginia, additional, Lamm, Ben, additional, Church, George, additional, and Hysolli, Eriona, additional

Published

2024

3. Federated Learning for Multicenter Collaborations of Small Biomedical Research Institutions: A Framework for Navigating Challenges and Realizing Opportunities

Author

McNutt, Brody, Thompson, Jeffrey, Hunt, Brady, Song, Arnold, Christensen, Brock, Moore, Jason, Vaickus, Louis, and Levy, Joshua

Abstract

The promises of Machine Learning (ML)-aided medicine have yet to be realized, in large part because robust optimization and generalizability of ML models requires large training datasets, which are logistically challenging to obtain. The majority of ML medical research is conducted using small- to mid-scale single institution datasets and does not equitably represent the general population. For institutions with smaller footprint, resources, and catchment areas, the problem is exacerbated, making engagement in high-quality ML model development challenging. The emergence of Federated Learning (FL) as a new discipline has great potential to empower smaller institutions to collaboratively train algorithms for healthcare applications without sharing private patient data. This will open the door for application of ML-assisted medicine in rural settings and other underrepresented contexts, including for conditions with low prevalence. However, there remain numerous pragmatic concerns of how multicenter collaborations can be coordinated between small, similarly resourced groups outside of joining large consortiums that are coordinated around centralized, well-resourced leadership. We seek to address this problem by discussing the challenges faced by federated coalitions of smaller biomedical research institutions and proposing a three-stage plan to facilitate (1) the formation of an inter-institutional Working Group, (2) the design and engineering of operating policies and infrastructure, and (3) the execution of study and open dissemination of lessons learned.

Published

2022