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3,092 results on '"Jafari, Mohammad"'

1. Universal Novelty Detection Through Adaptive Contrastive Learning

Author

Mirzaei, Hossein, Nafez, Mojtaba, Jafari, Mohammad, Soltani, Mohammad Bagher, Azizmalayeri, Mohammad, Habibi, Jafar, Sabokrou, Mohammad, and Rohban, Mohammad Hossein

Subjects
Computer Science - Machine Learning
Abstract

Novelty detection is a critical task for deploying machine learning models in the open world. A crucial property of novelty detection methods is universality, which can be interpreted as generalization across various distributions of training or test data. More precisely, for novelty detection, distribution shifts may occur in the training set or the test set. Shifts in the training set refer to cases where we train a novelty detector on a new dataset and expect strong transferability. Conversely, distribution shifts in the test set indicate the methods' performance when the trained model encounters a shifted test sample. We experimentally show that existing methods falter in maintaining universality, which stems from their rigid inductive biases. Motivated by this, we aim for more generalized techniques that have more adaptable inductive biases. In this context, we leverage the fact that contrastive learning provides an efficient framework to easily switch and adapt to new inductive biases through the proper choice of augmentations in forming the negative pairs. We propose a novel probabilistic auto-negative pair generation method AutoAugOOD, along with contrastive learning, to yield a universal novelty detector method. Our experiments demonstrate the superiority of our method under different distribution shifts in various image benchmark datasets. Notably, our method emerges universality in the lens of adaptability to different setups of novelty detection, including one-class, unlabeled multi-class, and labeled multi-class settings. Code: https://github.com/mojtaba-nafez/UNODE, Comment: 16 pages, 5 figures, conference

Published
2024

2. The Power of Few: Accelerating and Enhancing Data Reweighting with Coreset Selection

Author

Jafari, Mohammad, Zhang, Yimeng, Zhang, Yihua, and Liu, Sijia

Subjects
Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

As machine learning tasks continue to evolve, the trend has been to gather larger datasets and train increasingly larger models. While this has led to advancements in accuracy, it has also escalated computational costs to unsustainable levels. Addressing this, our work aims to strike a delicate balance between computational efficiency and model accuracy, a persisting challenge in the field. We introduce a novel method that employs core subset selection for reweighting, effectively optimizing both computational time and model performance. By focusing on a strategically selected coreset, our approach offers a robust representation, as it efficiently minimizes the influence of outliers. The re-calibrated weights are then mapped back to and propagated across the entire dataset. Our experimental results substantiate the effectiveness of this approach, underscoring its potential as a scalable and precise solution for model training., Comment: Accepted to ICASSP 2024

Published
2024

16. FAM72A degrades UNG2 through the GID/CTLH complex to promote mutagenic repair during antibody maturation

Author

Barbulescu, Philip, Chana, Chetan K., Wong, Matthew K., Ben Makhlouf, Ines, Bruce, Jeffrey P., Feng, Yuqing, Keszei, Alexander F. A., Wong, Cassandra, Mohamad-Ramshan, Rukshana, McGary, Laura C., Kashem, Mohammad A., Ceccarelli, Derek F., Orlicky, Stephen, Fang, Yifei, Kuang, Huihui, Mazhab-Jafari, Mohammad, Pezo, Rossanna C., Bhagwat, Ashok S., Pugh, Trevor J., Gingras, Anne-Claude, Sicheri, Frank, and Martin, Alberto

Published
2024
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19. Validation of machine learning models for estimation of left ventricular ejection fraction on point-of-care ultrasound: insights on features that impact performance

Author

Luong, Christina L., Jafari, Mohammad H., Behnami, Delaram, Shah, Yaksh R., Straatman, Lynn, Van Woudenberg, Nathan, Christoff, Leah, Gwadry, Nancy, Hawkins, Nathaniel M., Sayre, Eric C., Yeung, Darwin, Tsang, Michael, Gin, Ken, Jue, John, Nair, Parvathy, Abolmaesumi, Purang, and Tsang, Teresa

Published
2024
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29. Deep Learning for Detection and Localization of B-Lines in Lung Ultrasound

Author

Lucassen, Ruben T., Jafari, Mohammad H., Duggan, Nicole M., Jowkar, Nick, Mehrtash, Alireza, Fischetti, Chanel, Bernier, Denie, Prentice, Kira, Duhaime, Erik P., Jin, Mike, Abolmaesumi, Purang, Heslinga, Friso G., Veta, Mitko, Duran-Mendicuti, Maria A., Frisken, Sarah, Shyn, Paul B., Golby, Alexandra J., Boyer, Edward, Wells, William M., Goldsmith, Andrew J., and Kapur, Tina

Subjects
Electrical Engineering and Systems Science - Image and Video Processing
Abstract

Lung ultrasound (LUS) is an important imaging modality used by emergency physicians to assess pulmonary congestion at the patient bedside. B-line artifacts in LUS videos are key findings associated with pulmonary congestion. Not only can the interpretation of LUS be challenging for novice operators, but visual quantification of B-lines remains subject to observer variability. In this work, we investigate the strengths and weaknesses of multiple deep learning approaches for automated B-line detection and localization in LUS videos. We curate and publish, BEDLUS, a new ultrasound dataset comprising 1,419 videos from 113 patients with a total of 15,755 expert-annotated B-lines. Based on this dataset, we present a benchmark of established deep learning methods applied to the task of B-line detection. To pave the way for interpretable quantification of B-lines, we propose a novel "single-point" approach to B-line localization using only the point of origin. Our results show that (a) the area under the receiver operating characteristic curve ranges from 0.864 to 0.955 for the benchmarked detection methods, (b) within this range, the best performance is achieved by models that leverage multiple successive frames as input, and (c) the proposed single-point approach for B-line localization reaches an F1-score of 0.65, performing on par with the inter-observer agreement. The dataset and developed methods can facilitate further biomedical research on automated interpretation of lung ultrasound with the potential to expand the clinical utility., Comment: 10 pages, 4 figures

Published
2023

34. HealNet -- Self-Supervised Acute Wound Heal-Stage Classification

Author

Carrión, Héctor, Jafari, Mohammad, Yang, Hsin-Ya, Isseroff, Roslyn Rivkah, Rolandi, Marco, Gomez, Marcella, and Norouzi, Narges

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

Identifying, tracking, and predicting wound heal-stage progression is a fundamental task towards proper diagnosis, effective treatment, facilitating healing, and reducing pain. Traditionally, a medical expert might observe a wound to determine the current healing state and recommend treatment. However, sourcing experts who can produce such a diagnosis solely from visual indicators can be difficult, time-consuming and expensive. In addition, lesions may take several weeks to undergo the healing process, demanding resources to monitor and diagnose continually. Automating this task can be challenging; datasets that follow wound progression from onset to maturation are small, rare, and often collected without computer vision in mind. To tackle these challenges, we introduce a self-supervised learning scheme composed of (a) learning embeddings of wound's temporal dynamics, (b) clustering for automatic stage discovery, and (c) fine-tuned classification. The proposed self-supervised and flexible learning framework is biologically inspired and trained on a small dataset with zero human labeling. The HealNet framework achieved high pre-text and downstream classification accuracy; when evaluated on held-out test data, HealNet achieved 97.7% pre-text accuracy and 90.62% heal-stage classification accuracy.

Published
2022

36. The role of machine learning in advancing precision medicine with feedback control

Author

Zlobina, Ksenia, Jafari, Mohammad, Rolandi, Marco, and Gomez, Marcella

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Electronics, Sensors and Digital Hardware, Materials Engineering, 8.4 Research design and methodologies (health services), Health and social care services research, Good Health and Well Being, Macromolecular and materials chemistry, Electronics, sensors and digital hardware, Materials engineering
Abstract

The capacity of machine-learning methods to handle large and complex datasets makes them suitable for applications in precision medicine. Current methods automate data analysis and predict physiological outcomes of patients with various types of clinical data to inform treatment strategies. In this perspective, we propose ways in which machine learning can be leveraged even further to advance methods of optimizing patient treatment. Namely, machine learning can be used to expand applications of feedback control to direct the response of complex biological systems predictably and automatically. This paves the way for highly sophisticated treatments that continuously adapt to an individual patient's response. The elements of control that can be improved using machine learning include sensor data analysis, modeling, and methods of reconfiguring the control algorithm “on the fly.” We discuss the control challenges unique to the analysis/control of complex biological systems, existing work, and areas that remain underdeveloped.

Published
2022

49. A machine learning based model accurately predicts cellular response to electric fields in multiple cell types.

Author

Sargent, Brett, Jafari, Mohammad, Marquez, Giovanny, Mehta, Abijeet Singh, Sun, Yao-Hui, Yang, Hsin-Ya, Zhu, Kan, Isseroff, Roslyn Rivkah, Zhao, Min, and Gomez, Marcella

Subjects
Keratinocytes, Animals, Mammals, Electric Stimulation, Electricity, Wound Healing, Cell Movement, Machine Learning, Physical Injury - Accidents and Adverse Effects, Affordable and Clean Energy
Abstract

Many cell types migrate in response to naturally generated electric fields. Furthermore, it has been suggested that the external application of an electric field may be used to intervene in and optimize natural processes such as wound healing. Precise cell guidance suitable for such optimization may rely on predictive models of cell migration, which do not generalize. Here, we present a machine learning model that can forecast directedness of cell migration given a timeseries of previous directedness and electric field values. This model is trained using time series galvanotaxis data of mammalian cranial neural crest cells obtained through time-lapse microscopy of cells cultured at 37 °C in a galvanotaxis chamber at ambient pressure. Next, we show that our modeling approach can be used for a variety of cell types and experimental conditions with very limited training data using transfer learning methods. We adapt the model to predict cell behavior for keratocytes (room temperature, ~ 18-20 °C) and keratinocytes (37 °C) under similar experimental conditions with a small dataset (~ 2-5 cells). Finally, this model can be used to perform in silico studies by simulating cell migration lines under time-varying and unseen electric fields. We demonstrate this by simulating feedback control on cell migration using a proportional-integral-derivative (PID) controller. This data-driven approach provides predictive models of cell migration that may be suitable for designing electric field based cellular control mechanisms for applications in precision medicine such as wound healing.

Published
2022

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