Your search keyword '"Neha Gianchandani"' showing total 5 results

1. Integration of Swin UNETR and statistical shape modeling for a semi-automated segmentation of the knee and biomechanical modeling of articular cartilage

Author

Reza Kakavand, Mehrdad Palizi, Peyman Tahghighi, Reza Ahmadi, Neha Gianchandani, Samer Adeeb, Roberto Souza, W. Brent Edwards, and Amin Komeili

Subjects

Medicine, Science

Abstract

Abstract Simulation studies, such as finite element (FE) modeling, provide insight into knee joint mechanics without patient involvement. Generic FE models mimic the biomechanical behavior of the tissue, but overlook variations in geometry, loading, and material properties of a population. Conversely, subject-specific models include these factors, resulting in enhanced predictive precision, but are laborious and time intensive. The present study aimed to enhance subject-specific knee joint FE modeling by incorporating a semi-automated segmentation algorithm using a 3D Swin UNETR for an initial segmentation of the femur and tibia, followed by a statistical shape model (SSM) adjustment to improve surface roughness and continuity. For comparison, a manual FE model was developed through manual segmentation (i.e., the de-facto standard approach). Both FE models were subjected to gait loading and the predicted mechanical response was compared. The semi-automated segmentation achieved a Dice similarity coefficient (DSC) of over 98% for both the femur and tibia. Hausdorff distance (mm) between the semi-automated and manual segmentation was 1.4 mm. The mechanical results (max principal stress and strain, fluid pressure, fibril strain, and contact area) showed no significant differences between the manual and semi-automated FE models, indicating the effectiveness of the proposed semi-automated segmentation in creating accurate knee joint FE models. We have made our semi-automated models publicly accessible to support and facilitate biomechanical modeling and medical image segmentation efforts ( https://data.mendeley.com/datasets/k5hdc9cz7w/1 ).

Published

2024

2. Unsupervised Domain Adaptation of MRI Skull-stripping Trained on Adult Data to Newborns.

Author

Abbas Omidi, Aida Mohammadshahi, Neha Gianchandani, Regan King, Lara Leijser, and Roberto Souza 0001

Published

2024

3. A Multitask Deep Learning Model for Voxel-Level Brain Age Estimation.

Author

Neha Gianchandani, Johanna Ospel, M. Ethan MacDonald, and Roberto Souza 0001

Published

2023

4. Studying the Effects of Sex-Related Differences on Brain Age Prediction Using Brain MR Imaging.

Author

Mahsa Dibaji, Neha Gianchandani, Akhil Nair, Mansi Singhal, Roberto Souza 0001, and Mariana P. Bento

Published

2023

5. Rapid COVID-19 diagnosis using ensemble deep transfer learning models from chest radiographic images

Author

Vijay Kumar, Aayush Jaiswal, Neha Gianchandani, Manjit Kaur, and Dilbag Singh

Subjects

Ensemble models, Coronavirus disease 2019 (COVID-19), General Computer Science, Computer science, Radiography, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), 02 engineering and technology, medicine.disease_cause, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, 0202 electrical engineering, electronic engineering, information engineering, medicine, Coronavirus, Original Research, Ensemble forecasting, business.industry, SARS-CoV-2, Bacterial pneumonia, Chest X-ray, Outbreak, COVID-19, Pattern recognition, medicine.disease, Transfer learning, Viral pneumonia, 020201 artificial intelligence & image processing, Artificial intelligence, business, Transfer of learning

Abstract

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes novel coronavirus disease (COVID-19) outbreak in more than 200 countries around the world. The early diagnosis of infected patients is needed to discontinue this outbreak. The diagnosis of coronavirus infection from radiography images is the fastest method. In this paper, two different ensemble deep transfer learning models have been designed for COVID-19 diagnosis utilizing the chest X-rays. Both models have utilized pre-trained models for better performance. They are able to differentiate COVID-19, viral pneumonia, and bacterial pneumonia. Both models have been developed to improve the generalization capability of the classifier for binary and multi-class problems. The proposed models have been tested on two well-known datasets. Experimental results reveal that the proposed framework outperforms the existing techniques in terms of sensitivity, specificity, and accuracy.

Published

2020