Your search keyword '"Greer, Hastings"' showing total 12 results

1. CARL: A Framework for Equivariant Image Registration

Author

Greer, Hastings, Tian, Lin, Vialard, Francois-Xavier, Kwitt, Roland, Estepar, Raul San Jose, and Niethammer, Marc

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Image registration estimates spatial correspondences between a pair of images. These estimates are typically obtained via numerical optimization or regression by a deep network. A desirable property of such estimators is that a correspondence estimate (e.g., the true oracle correspondence) for an image pair is maintained under deformations of the input images. Formally, the estimator should be equivariant to a desired class of image transformations. In this work, we present careful analyses of the desired equivariance properties in the context of multi-step deep registration networks. Based on these analyses we 1) introduce the notions of $[U,U]$ equivariance (network equivariance to the same deformations of the input images) and $[W,U]$ equivariance (where input images can undergo different deformations); we 2) show that in a suitable multi-step registration setup it is sufficient for overall $[W,U]$ equivariance if the first step has $[W,U]$ equivariance and all others have $[U,U]$ equivariance; we 3) show that common displacement-predicting networks only exhibit $[U,U]$ equivariance to translations instead of the more powerful $[W,U]$ equivariance; and we 4) show how to achieve multi-step $[W,U]$ equivariance via a coordinate-attention mechanism combined with displacement-predicting refinement layers (CARL). Overall, our approach obtains excellent practical registration performance on several 3D medical image registration tasks and outperforms existing unsupervised approaches for the challenging problem of abdomen registration.

Published

2024

2. uniGradICON: A Foundation Model for Medical Image Registration

Author

Tian, Lin, Greer, Hastings, Kwitt, Roland, Vialard, Francois-Xavier, Estepar, Raul San Jose, Bouix, Sylvain, Rushmore, Richard, and Niethammer, Marc

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Conventional medical image registration approaches directly optimize over the parameters of a transformation model. These approaches have been highly successful and are used generically for registrations of different anatomical regions. Recent deep registration networks are incredibly fast and accurate but are only trained for specific tasks. Hence, they are no longer generic registration approaches. We therefore propose uniGradICON, a first step toward a foundation model for registration providing 1) great performance \emph{across} multiple datasets which is not feasible for current learning-based registration methods, 2) zero-shot capabilities for new registration tasks suitable for different acquisitions, anatomical regions, and modalities compared to the training dataset, and 3) a strong initialization for finetuning on out-of-distribution registration tasks. UniGradICON unifies the speed and accuracy benefits of learning-based registration algorithms with the generic applicability of conventional non-deep-learning approaches. We extensively trained and evaluated uniGradICON on twelve different public datasets. Our code and the uniGradICON model are available at https://github.com/uncbiag/uniGradICON.

Published

2024

3. $\texttt{NePhi}$: Neural Deformation Fields for Approximately Diffeomorphic Medical Image Registration

Author

Tian, Lin, Greer, Hastings, Estépar, Raúl San José, Sengupta, Roni, and Niethammer, Marc

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

This work proposes NePhi, a generalizable neural deformation model which results in approximately diffeomorphic transformations. In contrast to the predominant voxel-based transformation fields used in learning-based registration approaches, NePhi represents deformations functionally, leading to great flexibility within the design space of memory consumption during training and inference, inference time, registration accuracy, as well as transformation regularity. Specifically, NePhi 1) requires less memory compared to voxel-based learning approaches, 2) improves inference speed by predicting latent codes, compared to current existing neural deformation based registration approaches that \emph{only} rely on optimization, 3) improves accuracy via instance optimization, and 4) shows excellent deformation regularity which is highly desirable for medical image registration. We demonstrate the performance of NePhi on a 2D synthetic dataset as well as for real 3D medical image datasets (e.g., lungs and brains). Our results show that NePhi can match the accuracy of voxel-based representations in a single-resolution registration setting. For multi-resolution registration, our method matches the accuracy of current SOTA learning-based registration approaches with instance optimization while reducing memory requirements by a factor of five. Our code is available at https://github.com/uncbiag/NePhi., Comment: ECCV 2024

Published

2023

4. Inverse Consistency by Construction for Multistep Deep Registration

Author

Greer, Hastings, Tian, Lin, Vialard, Francois-Xavier, Kwitt, Roland, Bouix, Sylvain, Estepar, Raul San Jose, Rushmore, Richard, and Niethammer, Marc

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Inverse consistency is a desirable property for image registration. We propose a simple technique to make a neural registration network inverse consistent by construction, as a consequence of its structure, as long as it parameterizes its output transform by a Lie group. We extend this technique to multi-step neural registration by composing many such networks in a way that preserves inverse consistency. This multi-step approach also allows for inverse-consistent coarse to fine registration. We evaluate our technique on synthetic 2-D data and four 3-D medical image registration tasks and obtain excellent registration accuracy while assuring inverse consistency.

Published

2023

5. MultiGradICON: A Foundation Model for Multimodal Medical Image Registration

Author

Demir, Başar, Tian, Lin, Greer, Hastings, Kwitt, Roland, Vialard, François-Xavier, Estépar, Raúl San José, Bouix, Sylvain, Rushmore, Richard, Ebrahim, Ebrahim, Niethammer, Marc, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Modat, Marc, editor, Simpson, Ivor, editor, Špiclin, Žiga, editor, Bastiaansen, Wietske, editor, Hering, Alessa, editor, and Mok, Tony C. W., editor

Published

2024

6. $\texttt{GradICON}$: Approximate Diffeomorphisms via Gradient Inverse Consistency

Author

Tian, Lin, Greer, Hastings, Vialard, François-Xavier, Kwitt, Roland, Estépar, Raúl San José, Rushmore, Richard Jarrett, Makris, Nikolaos, Bouix, Sylvain, and Niethammer, Marc

Subjects

Computer Science - Computer Vision and Pattern Recognition, Electrical Engineering and Systems Science - Image and Video Processing

Abstract

We present an approach to learning regular spatial transformations between image pairs in the context of medical image registration. Contrary to optimization-based registration techniques and many modern learning-based methods, we do not directly penalize transformation irregularities but instead promote transformation regularity via an inverse consistency penalty. We use a neural network to predict a map between a source and a target image as well as the map when swapping the source and target images. Different from existing approaches, we compose these two resulting maps and regularize deviations of the $\bf{Jacobian}$ of this composition from the identity matrix. This regularizer -- $\texttt{GradICON}$ -- results in much better convergence when training registration models compared to promoting inverse consistency of the composition of maps directly while retaining the desirable implicit regularization effects of the latter. We achieve state-of-the-art registration performance on a variety of real-world medical image datasets using a single set of hyperparameters and a single non-dataset-specific training protocol., Comment: 29 pages, 16 figures, CVPR 2023

Published

2022

7. The Brain Tumor Sequence Registration (BraTS-Reg) Challenge: Establishing Correspondence Between Pre-Operative and Follow-up MRI Scans of Diffuse Glioma Patients

Author

Baheti, Bhakti, Chakrabarty, Satrajit, Akbari, Hamed, Bilello, Michel, Wiestler, Benedikt, Schwarting, Julian, Calabrese, Evan, Rudie, Jeffrey, Abidi, Syed, Mousa, Mina, Villanueva-Meyer, Javier, Fields, Brandon K. K., Kofler, Florian, Shinohara, Russell Takeshi, Iglesias, Juan Eugenio, Mok, Tony C. W., Chung, Albert C. S., Wodzinski, Marek, Jurgas, Artur, Marini, Niccolo, Atzori, Manfredo, Muller, Henning, Grobroehmer, Christoph, Siebert, Hanna, Hansen, Lasse, Heinrich, Mattias P., Canalini, Luca, Klein, Jan, Gerken, Annika, Heldmann, Stefan, Hering, Alessa, Hahn, Horst K., Meng, Mingyuan, Bi, Lei, Feng, Dagan, Kim, Jinman, Zeineldin, Ramy A., Karar, Mohamed E., Mathis-Ullrich, Franziska, Burgert, Oliver, Abderezaei, Javid, Pionteck, Aymeric, Chopra, Agamdeep, Kurt, Mehmet, Yan, Kewei, Yan, Yonghong, Tang, Zhe, Ma, Jianqiang, Nasser, Sahar Almahfouz, Kurian, Nikhil Cherian, Meena, Mohit, Shamsi, Saqib, Sethi, Amit, Tustison, Nicholas J., Avants, Brian B., Cook, Philip, Gee, James C., Tian, Lin, Greer, Hastings, Niethammer, Marc, Hoopes, Andrew, Hoffmann, Malte, Dalca, Adrian V., Christodoulidis, Stergios, Estiene, Theo, Vakalopoulou, Maria, Paragios, Nikos, Marcus, Daniel S., Davatzikos, Christos, Sotiras, Aristeidis, Menze, Bjoern, Bakas, Spyridon, and Waldmannstetter, Diana

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition

Abstract

Registration of longitudinal brain MRI scans containing pathologies is challenging due to dramatic changes in tissue appearance. Although there has been progress in developing general-purpose medical image registration techniques, they have not yet attained the requisite precision and reliability for this task, highlighting its inherent complexity. Here we describe the Brain Tumor Sequence Registration (BraTS-Reg) challenge, as the first public benchmark environment for deformable registration algorithms focusing on estimating correspondences between pre-operative and follow-up scans of the same patient diagnosed with a diffuse brain glioma. The BraTS-Reg data comprise de-identified multi-institutional multi-parametric MRI (mpMRI) scans, curated for size and resolution according to a canonical anatomical template, and divided into training, validation, and testing sets. Clinical experts annotated ground truth (GT) landmark points of anatomical locations distinct across the temporal domain. Quantitative evaluation and ranking were based on the Median Euclidean Error (MEE), Robustness, and the determinant of the Jacobian of the displacement field. The top-ranked methodologies yielded similar performance across all evaluation metrics and shared several methodological commonalities, including pre-alignment, deep neural networks, inverse consistency analysis, and test-time instance optimization per-case basis as a post-processing step. The top-ranked method attained the MEE at or below that of the inter-rater variability for approximately 60% of the evaluated landmarks, underscoring the scope for further accuracy and robustness improvements, especially relative to human experts. The aim of BraTS-Reg is to continue to serve as an active resource for research, with the data and online evaluation tools accessible at https://bratsreg.github.io/.

Published

2021

8. Inverse Consistency by Construction for Multistep Deep Registration

Author

Greer, Hastings, primary, Tian, Lin, additional, Vialard, Francois-Xavier, additional, Kwitt, Roland, additional, Bouix, Sylvain, additional, San Jose Estepar, Raul, additional, Rushmore, Richard, additional, and Niethammer, Marc, additional

Published

2023

9. GradICON: Approximate Diffeomorphisms via Gradient Inverse Consistency

Author

Tian, Lin, primary, Greer, Hastings, additional, Vialard, François-Xavier, additional, Kwitt, Roland, additional, Estépar, Raúl San José, additional, Rushmore, Richard Jarrett, additional, Makris, Nikolaos, additional, Bouix, Sylvain, additional, and Niethammer, Marc, additional

Published

2023

10. Introducing the Open and Reproducible Musculoskeletal Imaging Research (ORMIR) community

Author

Bonaretti, Serena, Barzaghi, Leonardo, Barzegari, Mojtaba, Burghardt, Andrew J., Cameron, Donnie, Carballido-Gamio, Julio, Crimi, Gianluigi, Durongbhan, Pholpat, Espinosa Hernandez, Michelle, Fraterrigo, Giulia, Grassi, Lorenzo, Greer, Hastings, Iori, Gianluca, Kuczynski, Michael, Manske, Sarah, McCormick, Matthew, Neeteson, Nathan, Niethammer, Marc, Pani, Martino, Quintiens, Jilmen, Sadeghi, Majid Mohammad, Santini, Francesco, Schileo, Enrico, Stok, Kathryn S., Taddei, Fulvia, Tse, Justin J, Vicory, Jared, Wesseling, Mariska, Wong, Andy Kin On, and Zukić, Dženan

Abstract

Preprint of the manifesto paper of the ORMIR community

Published

2023

11. Investigating training-test data splitting strategies for automated segmentation and scoring of COVID-19 lung ultrasound images

Author

Roshankhah, Roshan, primary, Karbalaeisadegh, Yasamin, additional, Greer, Hastings, additional, Mento, Federico, additional, Soldati, Gino, additional, Smargiassi, Andrea, additional, Inchingolo, Riccardo, additional, Torri, Elena, additional, Perrone, Tiziano, additional, Aylward, Stephen, additional, Demi, Libertario, additional, and Muller, Marie, additional

Published

2021

12. GradICON: Approximate Diffeomorphisms via Gradient Inverse Consistency.

Author

Tian L, Greer H, Vialard FX, Kwitt R, Estépar RSJ, Rushmore RJ, Makris N, Bouix S, and Niethammer M

Abstract

We present an approach to learning regular spatial transformations between image pairs in the context of medical image registration. Contrary to optimization-based registration techniques and many modern learning-based methods, we do not directly penalize transformation irregularities but instead promote transformation regularity via an inverse consistency penalty. We use a neural network to predict a map between a source and a target image as well as the map when swapping the source and target images. Different from existing approaches, we compose these two resulting maps and regularize deviations of the Jacobian of this composition from the identity matrix. This regularizer - GradICON - results in much better convergence when training registration models compared to promoting inverse consistency of the composition of maps directly while retaining the desirable implicit regularization effects of the latter. We achieve state-of-the-art registration performance on a variety of real-world medical image datasets using a single set of hyperparameters and a single non-dataset-specific training protocol. Code is available at https://github.com/uncbiag/ICON.

Published

2023