AI is employed in healthcare for various applications, including medical image analysis, disease diagnosis, personalized treatment planning, and patient monitoring. It utilizes machine learning, natural language processing, and data analytics to improve diagnostic accuracy, optimize treatment outcomes, and enhance healthcare delivery, leading to more efficient and effective patient care.
Researchers dissected the intricate relationship between meta-level and statistical features of tabular datasets, unveiling the impactful role of kurtosis, meta-level ratio, and statistical mean on non-tree-based ML algorithms. This study, based on 200 diverse datasets, provides essential insights for optimizing algorithm selection and understanding the nuanced interplay between dataset characteristics and ML performance.
This study explores the acceptance of chatbots among insurance policyholders. Using the Technology Acceptance Model (TAM), the research emphasizes the crucial role of trust in shaping attitudes and behavioral intentions toward chatbots, providing valuable insights for the insurance industry to enhance customer acceptance and effective implementation of conversational agents.
Researchers unveil a groundbreaking method for sound event classification, tackling the challenge of recognizing unknown events not present in training data. Leveraging deep learning and self-supervised learning, the approach demonstrates robust performance, holding promise for applications in smart homes, security systems, healthcare, and personalized content recommendations.
USA researchers delve into the intersection of machine learning and climate-induced health impacts. The review identifies the potential of ML algorithms in predicting health outcomes from extreme weather events, emphasizing feasibility, promising results, and ethical considerations, paving the way for proactive healthcare and policy decisions in the face of climate change.
Researchers showcase the prowess of MedGAN, a generative artificial intelligence model, in drug discovery. By fine-tuning the model to focus on quinoline-scaffold molecules, the study achieves remarkable success, generating thousands of novel compounds with drug-like attributes. This advancement holds promise for accelerating drug design and development, marking a significant stride in the intersection of artificial intelligence and pharmaceutical innovation.
Researchers introduce the Improved Fuzzy High-Utility Pattern Mining (IF-HUPM) algorithm, a groundbreaking approach for computerized medical decision-making. By addressing interpretability challenges in existing High-Utility Pattern Mining (HUPM) algorithms, IF-HUPM incorporates fuzzy preprocessing, achieving efficient and interpretable results for multidimensional medical data. The algorithm demonstrates superior performance, providing a promising avenue for intelligent decision-making in healthcare.
Researchers from the USA leverage Large Language Models (LLMs) to automatically extract social determinants of health (SDoH) from clinical narratives, addressing challenges in healthcare data. Their innovative approach, combining Flan-T5 models and synthetic data augmentation, showcases remarkable efficiency, emphasizing the potential to bridge gaps in understanding and addressing crucial factors influencing patients' well-being.
Korean researchers introduce a groundbreaking framework marrying Explainable AI (XAI) and Zero-Trust Architecture (ZTA) for robust cyberdefense in marine communication networks. Their deep neural network, Zero-Trust Network Intrusion Detection System (NIDS), not only exhibits remarkable accuracy in classifying cyber threats but also integrates XAI methodologies, SHAP and LIME, to provide interpretable insights. This innovative approach fosters transparency and collaboration between AI systems and human experts, promising enhanced cybersecurity in marine, and potentially other, critical infrastructures.
This article explores the revolutionary impact of AI and ML in biomedical research and healthcare, emphasizing the need for responsible and equitable integration. Addressing challenges in governance, infrastructure, and international collaboration, it advocates for a holistic approach to harness AI's transformative potential while prioritizing inclusivity and ethical considerations in shaping the future of healthcare.
In this study, researchers from Valley Children's Hospital leverage artificial intelligence and data visualization to harness clinical genetic data for estimating genetic disorder prevalence and mapping variants to local geographies. The groundbreaking methodology, exemplified in a five-year analysis, offers a blueprint for healthcare systems to translate genetic testing data into actionable insights for tailored population health management.
This paper explores the dynamic integration of artificial intelligence/machine learning (AI/ML) in biomedical research, emphasizing its pivotal role in predictive analysis across diverse domains. While acknowledging transformative potential, the paper highlights challenges such as inclusivity, synergy between computational models and human expertise, and standardization of clinical data, presenting them as opportunities for innovation in a transformative era for human health optimization through AI/ML in biomedical research.
This paper unveils the Elderly and Visually Impaired Human Activity Monitoring (EV-HAM) system, a pioneering solution utilizing artificial intelligence, digital twins, and Wi-Sense for accurate activity recognition. Employing Deep Hybrid Convolutional Neural Networks on Wi-Fi Channel State Information data, the system achieves a remarkable 99% accuracy in identifying micro-Doppler fingerprints of activities, presenting a revolutionary advancement in elderly and visually impaired care through continuous monitoring and crisis intervention.
This study explores the synergies between artificial intelligence (AI) and electronic skin (e-skin) systems, envisioning a transformative impact on robotics and medicine. E-skins, equipped with diverse sensors, offer a wealth of health data, and the integration of advanced machine learning techniques promises to revolutionize data analysis, optimize hardware, and propel applications from prosthetics to personalized health diagnostics.
Researchers from Nanjing University of Science and Technology present a novel scheme, Spatial Variation-Dependent Verification (SVV), utilizing convolutional neural networks and textural features for handwriting identification and verification. The scheme outperforms existing methods, achieving 95.587% accuracy, providing a robust solution for secure handwriting recognition and authentication in diverse applications, including security, forensics, banking, education, and healthcare.
This research, published in PLOS One, investigates the protective feature preferences of the adult Danish population in various AI decision-making scenarios. With a focus on both public and commercial sectors, the study explores the nuanced interplay of demographic factors, societal expectations, and trust in shaping preferences for features such as AI knowledge, human responsibility, non-discrimination, human explainability, and system performance.
This article proposes the Governability, Reliability, Equity, Accountability, Traceability, Privacy, Lawfulness, Empathy, and Autonomy (GREAT PLEA) ethical principles for generative AI applications in healthcare. Drawing inspiration from existing military and healthcare ethical principles, the GREAT PLEA framework aims to address ethical concerns, protect clinicians and patients, and guide the responsible development and implementation of generative AI in healthcare settings.
This research delves into the synergy of Artificial Intelligence (AI) and Internet of Things (IoT) security. The study evaluates and compares various AI algorithms, including machine learning (ML) and deep learning (DL), for classifying and detecting IoT attacks. It introduces a novel taxonomy of AI methodologies for IoT security and identifies LSTM as the top-performing algorithm, emphasizing its potential applications in diverse fields.
This article introduces MEDITRON, an open-source Large Language Model (LLM) tailored for medical reasoning, featuring 7 billion and 70 billion parameters. Built on Llama-2 and leveraging a curated medical corpus, MEDITRON addresses access disparities to medical knowledge. The paper outlines an optimized workflow for scaling domain-specific pretraining, the MEDITRON models' engineering, and their superior performance on medical benchmarks, marking a significant stride toward accessible and capable medical LLMs.
This article presents a groundbreaking study exploring Generative Pre-trained Transformer-4 (GPT-4) capabilities in specialized domains, with a focus on medicine. The innovative "Medprompt" strategy, incorporating dynamic few-shot, self-generated chain of thought, and choice shuffling ensemble techniques, significantly enhances GPT-4's performance, surpassing specialist models across diverse medical benchmarks.
Researchers propose leveraging a Quality Management System (QMS) tailored to healthcare AI as a systematic solution to bridge the translation gap from research to clinical application. The QMS, aligned with ISO 13485 and risk-based approaches, addresses key components enabling healthcare organizations to navigate regulatory complexities, minimize redundancy, and optimize the ethical deployment of AI in patient care.
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