Your search keyword '"Sarder P"' showing total 11 results

1. Artificial intelligence driven next-generation renal histomorphometry.

Author

Santo BA, Rosenberg AZ, and Sarder P

Subjects

Humans, Neural Networks, Computer, Prognosis, Artificial Intelligence, Image Processing, Computer-Assisted methods, Kidney pathology, Machine Learning

Abstract

Purpose of Review: Successful integration of artificial intelligence into extant clinical workflows is contingent upon a number of factors including clinician comprehension and interpretation of computer vision. This article discusses how image analysis and machine learning have enabled comprehensive characterization of kidney morphology for development of automated diagnostic and prognostic renal pathology applications., Recent Findings: The primordial digital pathology informatics work employed classical image analysis and machine learning to prognosticate renal disease. Although this classical approach demonstrated tremendous potential, subsequent advancements in hardware technology rendered artificial neural networks '(ANNs) the method of choice for machine vision in computational pathology'. Offering rapid and reproducible detection, characterization and classification of kidney morphology, ANNs have facilitated the development of diagnostic and prognostic applications. In addition, modern machine learning with ANNs has revealed novel biomarkers in kidney disease, demonstrating the potential for machine vision to elucidate novel pathologic mechanisms beyond extant clinical knowledge., Summary: Despite the revolutionary developments potentiated by modern machine learning, several challenges remain, including data quality control and curation, image annotation and ontology, integration of multimodal data and interpretation of machine vision or 'opening the black box'. Resolution of these challenges will not only revolutionize diagnostic pathology but also pave the way for precision medicine and integration of artificial intelligence in the process of care.

Published

2020

2. Banff Digital Pathology Working Group: Image Bank, Artificial Intelligence Algorithm, and Challenge Trial Developments.

Author

Farris, Alton, Alexander, Mariam, Balis, Ulysses, Barisoni, Laura, Boor, Peter, Bülow, Roman, Cornell, Lynn, Demetris, Anthony, Farkash, Evan, Hermsen, Meyke, Hogan, Julien, Kain, Renate, Kers, Jesper, Kong, Jun, Levenson, Richard, Loupy, Alexandre, Naesens, Maarten, Sarder, Pinaki, Tomaszewski, John, van der Laak, Jeroen, van Midden, Dominique, Yagi, Yukako, and Solez, Kim

Subjects

Banff, artificial intelligence, digital pathology, image analysis, machine learning, Humans, Artificial Intelligence, Algorithms, Kidney Transplantation, Kidney

Abstract

The Banff Digital Pathology Working Group (DPWG) was established with the goal to establish a digital pathology repository; develop, validate, and share models for image analysis; and foster collaborations using regular videoconferencing. During the calls, a variety of artificial intelligence (AI)-based support systems for transplantation pathology were presented. Potential collaborations in a competition/trial on AI applied to kidney transplant specimens, including the DIAGGRAFT challenge (staining of biopsies at multiple institutions, pathologists visual assessment, and development and validation of new and pre-existing Banff scoring algorithms), were also discussed. To determine the next steps, a survey was conducted, primarily focusing on the feasibility of establishing a digital pathology repository and identifying potential hosts. Sixteen of the 35 respondents (46%) had access to a server hosting a digital pathology repository, with 2 respondents that could serve as a potential host at no cost to the DPWG. The 16 digital pathology repositories collected specimens from various organs, with the largest constituent being kidney (n = 12,870 specimens). A DPWG pilot digital pathology repository was established, and there are plans for a competition/trial with the DIAGGRAFT project. Utilizing existing resources and previously established models, the Banff DPWG is establishing new resources for the Banff community.

Published

2023

3. A Comprehensive Approach Toward Wheat Leaf Disease Identification Leveraging Transformer Models and Federated Learning

Author

Md. Fahim-Ul-Islam, Amitabha Chakrabarty, Sarder Tanvir Ahmed, Rafeed Rahman, Hyun Han Kwon, and Md. Jalil Piran

Subjects

Machine learning, deep learning, federated learning, transformers, attention mechanism, wheat leaf disease identification, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Wheat is one of the most extensively cultivated crops worldwide that contributes significantly to global food caloric and protein production and is grown on millions of hectares yearly. However, diseases like brown rust, septoria, yellow rust, and other fungus diseases pose notable threats to wheat crops, impacting production and quality. Diagnosing these diseases is challenging, especially in areas with limited agricultural experts. Thus, creating computerized disease identification and decision-support technologies is crucial for safeguarding wheat leaf preservation and crop loss mitigation. The traditional approach to integrating data gathering and model training has substantial challenges in terms of data confidentiality, availability, and the costs related to data transmission. To address these challenges, federated learning (FL) is an appealing and effective option. Our study focuses on applying FL to classify agricultural diseases using image analysis. In our study, we conduct experiments on high-parameterized transfer learning (TL) models along with our proposed architecture based on the attention mechanism, introducing these models into a distributed learning strategy founded in FL. Our proposed architecture leverages the beneficial interactions of two cutting-edge vision transformer models including the advanced depthwise incorporating self-attention model referred to as CoAtNets, and the enhanced Swin Transformer V2, resulting in enhanced feature representation. Moreover, we introduce weight pruning into our model which is further classified by a reinforced linear attention mechanism (LA) to lower output dimensions. Our pruned lightweight (32M parameters) considerably decreases inference time with 624.249 ms and 644.899 on devices with low computational power, making it highly efficient in FL-based systems. The proposed model in our FL system significantly outperforms all other tested transfer learning models, including ConvNeXtBase, ConvNeXtLarge, EfficientNetV2L, InceptionResNetV2, ResNet152, and NASNetLarge, achieving accuracies up to 98% and 99%, precision up to 98%, recall up to 98%, and F-1 scores up to 95% across multiple input dimensions for wheat leaf disease classification.

Published

2024

4. Intelligent Resource Allocation in LoRaWAN Using Machine Learning Techniques

Author

Syed Usama Minhaj, Aamir Mahmood, Sarder Fakhrul Abedin, Syed Ali Hassan, Muhammad Talha Bhatti, Syed Haider Ali, and Mikael Gidlund

Subjects

Internet-of-Things (IoT), LPWAN, LoRaWAN, machine learning, network scalability, parameter selection, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

With the ubiquitous growth of Internet-of-things (IoT) devices, current low-power wide-area network (LPWAN) technologies will inevitably face performance degradation due to congestion and interference. The rule-based approaches to assign and adapt the device parameters are insufficient in dynamic massive IoT scenarios. For example, the adaptive data rate (ADR) algorithm in LoRaWAN has been proven inefficient and outdated for large-scale IoT networks. Meanwhile, new solutions involving machine learning (ML) and reinforcement learning (RL) techniques are shown to be very effective in solving resource allocation in dense IoT networks. In this article, we propose a new concept of using two independent learning approaches for allocating spreading factor (SF) and transmission power to the devices using a combination of a decentralized and centralized approach. SF is allocated to the devices using RL for contextual bandit problem, while transmission power is assigned centrally by treating it as a supervised ML problem. We compare our approach with existing state-of-the-art algorithms, showing a significant improvement in both network level goodput and energy consumption, especially for large and highly congested networks.

Published

2023

5. Banff Digital Pathology Working Group: Image Bank, Artificial Intelligence Algorithm, and Challenge Trial Developments

Author

Alton B. Farris, Mariam P. Alexander, Ulysses G. J. Balis, Laura Barisoni, Peter Boor, Roman D. Bülow, Lynn D. Cornell, Anthony J. Demetris, Evan Farkash, Meyke Hermsen, Julien Hogan, Renate Kain, Jesper Kers, Jun Kong, Richard M. Levenson, Alexandre Loupy, Maarten Naesens, Pinaki Sarder, John E. Tomaszewski, Jeroen van der Laak, Dominique van Midden, Yukako Yagi, and Kim Solez

Subjects

Banff, digital pathology, artificial intelligence, machine learning, image analysis, Specialties of internal medicine, RC581-951

Abstract

The Banff Digital Pathology Working Group (DPWG) was established with the goal to establish a digital pathology repository; develop, validate, and share models for image analysis; and foster collaborations using regular videoconferencing. During the calls, a variety of artificial intelligence (AI)-based support systems for transplantation pathology were presented. Potential collaborations in a competition/trial on AI applied to kidney transplant specimens, including the DIAGGRAFT challenge (staining of biopsies at multiple institutions, pathologists’ visual assessment, and development and validation of new and pre-existing Banff scoring algorithms), were also discussed. To determine the next steps, a survey was conducted, primarily focusing on the feasibility of establishing a digital pathology repository and identifying potential hosts. Sixteen of the 35 respondents (46%) had access to a server hosting a digital pathology repository, with 2 respondents that could serve as a potential host at no cost to the DPWG. The 16 digital pathology repositories collected specimens from various organs, with the largest constituent being kidney (n = 12,870 specimens). A DPWG pilot digital pathology repository was established, and there are plans for a competition/trial with the DIAGGRAFT project. Utilizing existing resources and previously established models, the Banff DPWG is establishing new resources for the Banff community.

Published

2023

6. An integrated iterative annotation technique for easing neural network training in medical image analysis

Author

Lutnick, Brendon, Ginley, Brandon, Govind, Darshana, McGarry, Sean D, LaViolette, Peter S, Yacoub, Rabi, Jain, Sanjay, Tomaszewski, John E, Jen, Kuang-Yu, and Sarder, Pinaki

Subjects

Information and Computing Sciences, Machine Learning, Urologic Diseases, Cancer, eess.IV, cs.CV, cs.HC, cs.LG, stat.ML, Engineering, Information and computing sciences

Abstract

Neural networks promise to bring robust, quantitative analysis to medical fields. However, their adoption is limited by the technicalities of training these networks and the required volume and quality of human-generated annotations. To address this gap in the field of pathology, we have created an intuitive interface for data annotation and the display of neural network predictions within a commonly used digital pathology whole-slide viewer. This strategy used a 'human-in-the-loop' to reduce the annotation burden. We demonstrate that segmentation of human and mouse renal micro compartments is repeatedly improved when humans interact with automatically generated annotations throughout the training process. Finally, to show the adaptability of this technique to other medical imaging fields, we demonstrate its ability to iteratively segment human prostate glands from radiology imaging data.

Published

2019

7. MangoLeafBD: A comprehensive image dataset to classify diseased and healthy mango leaves

Author

Sarder Iftekhar Ahmed, Muhammad Ibrahim, Md. Nadim, Md. Mizanur Rahman, Maria Mehjabin Shejunti, Taskeed Jabid, and Md. Sawkat Ali

Subjects

Image classification, Plant disease detection, Machine learning, Precision agriculture, Image dataset, Computer applications to medicine. Medical informatics, R858-859.7, Science (General), Q1-390

Abstract

Agriculture is one of the few remaining sectors that is yet to receive proper attention from the machine learning community. The importance of datasets in the machine learning discipline cannot be overemphasized. The lack of standard and publicly available datasets related to agriculture impedes practitioners of this discipline to harness the full benefit of these powerful computational predictive tools and techniques. To improve this scenario, we develop, to the best of our knowledge, the first-ever standard, ready-to-use, and publicly available dataset of mango leaves. The images are collected from four mango orchards of Bangladesh, one of the top mango-growing countries of the world. The dataset contains 4000 images of about 1800 distinct leaves covering seven diseases. Although the dataset is developed using mango leaves of Bangladesh only, since we deal with diseases that are common across many countries, this dataset is likely to be applicable to identify mango diseases in other countries as well, thereby boosting mango yield. This dataset is expected to draw wide attention from machine learning researchers and practitioners in the field of automated agriculture.

Published

2023

8. Experimental Analysis of Trustworthy In-Vehicle Intrusion Detection System Using eXplainable Artificial Intelligence (XAI)

Author

Hampus Lundberg, Nishat I Mowla, Sarder Fakhrul Abedin, Kyi Thar, Aamir Mahmood, Mikael Gidlund, and Shahid Raza

Subjects

Automotive, intrusion detection system, machine learning, deep learning, XAI, trustworthiness, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Anomaly-based In-Vehicle Intrusion Detection System (IV-IDS) is one of the protection mechanisms to detect cyber attacks on automotive vehicles. Using artificial intelligence (AI) for anomaly detection to thwart cyber attacks is promising but suffers from generating false alarms and making decisions that are hard to interpret. Consequently, this issue leads to uncertainty and distrust towards such IDS design unless it can explain its behavior, e.g., by using eXplainable AI (XAI). In this paper, we consider the XAI-powered design of such an IV-IDS using CAN bus data from a public dataset, named “Survival”. Novel features are engineered, and a Deep Neural Network (DNN) is trained over the dataset. A visualization-based explanation, “VisExp”, is created to explain the behavior of the AI-based IV-IDS, which is evaluated by experts in a survey, in relation to a rule-based explanation. Our results show that experts’ trust in the AI-based IV-IDS is significantly increased when they are provided with VisExp (more so than the rule-based explanation). These findings confirm the effect, and by extension the need, of explainability in automated systems, and VisExp, being a source of increased explainability, shows promise in helping involved parties gain trust in such systems.

Published

2022

9. Integrating Image Analysis and Dental Radiography for Periodontal and Peri-Implant Diagnosis

Author

Amarpreet Sabharwal, Neil Kavthekar, Jeffrey Miecznikowski, Michael Glogauer, Abhiram Maddi, and Pinaki Sarder

Subjects

dental radiography, systems integration, periodontitis, peri-implantitis, artificial intelligence, machine learning, Dentistry, RK1-715

Abstract

The recent change in classification of periodontal and peri-implant diseases includes objective evaluation of intra-oral radiographs and quantification of bone loss for disease staging and grading. Assessment of the progression of periodontal disease requires deduction of bone loss longitudinally, and its interpretation as (1) a percentage in relation to tooth root and (2) as a function of the patient's age. Similarly, bone loss around dental implants, after accounting for initial remodeling, is central for determining diagnosis, severity, and progression of peri-implantitis. Bone gain secondary to periodontal regeneration can be measured using standardized dental radiographs and compared to baseline morphology to determine treatment success. Computational image analysis, including machine learning (ML), has the potential to develop and automate quantitative measures of tooth, implant, bone volumes, and predict disease progression. The developed algorithms need to be standardized while considering pre-analytic, analytic, and post-analytic factors for successful translation to clinic. This review will introduce image analysis and machine learning in the context of dental radiography, and expand on the potential for integration of image analysis for assisted diagnosis of periodontitis and peri-implantitis.

Published

2022

10. From What to Why, the Growing Need for a Focus Shift Toward Explainability of AI in Digital Pathology

Author

Samuel P. Border and Pinaki Sarder

Subjects

digital pathology, deep learning, artificial intelligence, explainability, interpretability, machine learning, Physiology, QP1-981

Abstract

While it is impossible to deny the performance gains achieved through the incorporation of deep learning (DL) and other artificial intelligence (AI)-based techniques in pathology, minimal work has been done to answer the crucial question of why these algorithms predict what they predict. Tracing back classification decisions to specific input features allows for the quick identification of model bias as well as providing additional information toward understanding underlying biological mechanisms. In digital pathology, increasing the explainability of AI models would have the largest and most immediate impact for the image classification task. In this review, we detail some considerations that should be made in order to develop models with a focus on explainability.

Published

2022

11. Application of Big Data and Machine Learning in Smart Grid, and Associated Security Concerns: A Review

Author

Eklas Hossain, Imtiaj Khan, Fuad Un-Noor, Sarder Shazali Sikander, and Md. Samiul Haque Sunny

Subjects

Big data analysis, cyber security, IoT, machine learning, smart grid, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper conducts a comprehensive study on the application of big data and machine learning in the electrical power grid introduced through the emergence of the next-generation power system-the smart grid (SG). Connectivity lies at the core of this new grid infrastructure, which is provided by the Internet of Things (IoT). This connectivity, and constant communication required in this system, also introduced a massive data volume that demands techniques far superior to conventional methods for proper analysis and decision-making. The IoT-integrated SG system can provide efficient load forecasting and data acquisition technique along with cost-effectiveness. Big data analysis and machine learning techniques are essential to reaping these benefits. In the complex connected system of SG, cyber security becomes a critical issue; IoT devices and their data turning into major targets of attacks. Such security concerns and their solutions are also included in this paper. Key information obtained through literature review is tabulated in the corresponding sections to provide a clear synopsis; and the findings of this rigorous review are listed to give a concise picture of this area of study and promising future fields of academic and industrial research, with current limitations with viable solutions along with their effectiveness.

Published

2019