wikipedia

https://en.wikipedia.org/wiki/Image_analysis

[2] Image analysis - Wikipedia — Image analysis or imagery analysis is the extraction of meaningful information from images; mainly from digital images by means of digital image processing techniques. Image analysis tasks can be as simple as reading bar coded tags or as sophisticated as identifying a person from their face.. Computers are indispensable for the analysis of large amounts of data, for tasks that require

vaia

https://www.vaia.com/en-us/explanations/media-studies/visual-communication-media-studies/image-analysis/

[3] Image Analysis: Understanding & Techniques | Vaia — History and Evolution of Image Analysis: Image analysis has come a long way since its origin. Initially, efforts were manual and slowly evolved through analog processing methods. With advancements in computer technology and digital imagery, automated techniques were introduced. ... Image Analysis Techniques: Involves steps like acquisition, pre

leica-microsystems

https://www.leica-microsystems.com/science-lab/microscopy-basics/50-years-of-image-analysis/

[4] 50 Years of Image Analysis | Learn & Share | Leica Microsystems — Modern image analysis systems perform highly sophisticated image processing functions on images from an automated microscope and digital camera. 50 years ago, the first image analysis system was analogue, based on a video camera and the area measurements could be read from a meter. Nevertheless, it marked the beginning of automation in this field.

lakezurichopenmri

https://lakezurichopenmri.com/evolution-of-medical-imaging/

[7] The Evolution of Medical Imaging: A Timeline of Advancements — Medical imaging has been one of the most revolutionary advancements in healthcare, transforming diagnostics and treatment for countless conditions. The Discovery of X-rays: The Foundation of Medical Imaging This molecular imaging technique is often used in conjunction with CT or MRI to diagnose and monitor cancers, heart diseases, and brain disorders. The Future of Medical Imaging: AI and Beyond By combining AI with imaging technologies like MRI and CT scans, healthcare professionals can expect faster, more accurate diagnoses in the coming years. The evolution of medical imaging has had an undeniable impact on the healthcare industry, improving diagnostics, treatment planning, and patient outcomes. AI in Medical Imaging: Transforming the Future of Diagnostics Tags: AI, Diagnostic Imaging, Medical Imaging, technological advancements, X-rays

spsoft

https://spsoft.com/tech-insights/ai-and-medical-imaging-use-cases/

[9] Transforming Diagnostic Accuracy And Patient Care With AI And Medical ... — Transforming Diagnostic Accuracy And Patient Care With AI And Medical Imaging Home - How AI and Medical Imaging Applications Reshape Diagnosis and Patient Care How AI and Medical Imaging Applications Reshape Diagnosis and Patient Care AI has the power to enable more personalized treatment strategies by providing comprehensive and data-rich analyses of medical images and individual patient histories. Implementing these AI in medical imaging methods has enhanced diagnostic speed and precision, augmenting radiologist capabilities and elevating the quality of care. As a pioneer in applying AI and medical imaging to improve diagnostics, they offer algorithms capable of identifying various diseases by analyzing CT scans and X-rays. How is AI improving diagnostic accuracy in medical imaging?

ieee

https://ieeexplore.ieee.org/document/9756442

[12] Artificial Intelligence for Remote Sensing Data Analysis: A review of ... — Artificial intelligence (AI) plays a growing role in remote sensing (RS). Applications of AI, particularly machine learning algorithms, range from initial image processing to high-level data understanding and knowledge discovery. AI techniques have emerged as a powerful strategy for analyzing RS data and led to remarkable breakthroughs in all RS fields. Given this period of breathtaking

nature

https://www.nature.com/articles/s41592-019-0582-9

[15] ilastik: interactive machine learning for (bio)image analysis — We present ilastik, an easy-to-use interactive tool that brings machine-learning-based (bio)image analysis to end users without substantial computational expertise. It contains pre-defined

teachingsocialstudies

https://teachingsocialstudies.org/2025/01/15/enhancing-student-learning-with-ai-powered-image-features/

[17] Enhancing Student Learning with AI-Powered Image Features — One such innovation is AI-powered image recognition, which has the potential to revolutionize real-world learning experiences, from understanding historical documents to visualizing complex ideas. Instant insights: enhancing real-world learning. My recent experience in Seville, Spain, underscores how AI can make learning more dynamic and personal.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[19] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

aimspress

https://www.aimspress.com/article/doi/10.3934/biophy.2025008

[20] Medical image analysis using deep learning algorithms (DLA) — Deep Learning Algorithms (DLAs) have emerged as transformative tools in medical image analysis, offering unprecedented accuracy and efficiency in diagnostic tasks. We explored the state-of-the-art applications of DLAs in medical imaging, focusing on their role in disease detection, segmentation, workflow automation, and multi-modality data integration. Key architectures such as Convolutional

medium

https://cyril-picard.medium.com/detailed-report-on-image-analysis-afa671d83617

[43] Detailed Report on Image Analysis | by Cyril Picard | Medium — Image analysis is a crucial field that involves the extraction of meaningful information from images, primarily digital images, through various digital image processing techniques. This report aims to explore the multifaceted aspects of image analysis, including its techniques, applications, and the ongoing evolution of tools and methodologies

leica-microsystems

https://www.leica-microsystems.com/science-lab/microscopy-basics/50-years-of-image-analysis/

[47] 50 Years of Image Analysis | Learn & Share | Leica Microsystems — Image analysis as we know it today was only made possible by the development of television technology:  50 years ago, in 1962, the first television-based image analyzer of microscopic images was developed by Metals Research – a Cambridge-based company that became part of the Leica Group. The LAS software integrates the latest advances in automated microscopy, computing and digital image analysis. The LAS Measurement Module is irreplaceable to make measurements on the objects, quantify all data acquired and transfer the results to an excel sheet." Of course, image analysis has long been established in life sciences in the whole spectrum of  applications on Leica widefield and confocal systems from simple cell culture observation to sophisticated imaging tasks in biomedical research.

networkoptix

https://www.networkoptix.com/blog/2024/08/01/80-years-of-computer-vision-from-early-concepts-to-state-of-the-art-ai

[48] 80 Years of Computer Vision: From Early Concepts to State-of-the-Art AI — Simply put, it is the automated extraction, analysis, and understanding of useful information from a single image or a sequence of images. And in recent years computer vision has become a technology used in countless applications, ranging from autonomous vehicles to medical imaging. ... and explore potential future developments. Early Foundations.

ieee

https://ieeexplore.ieee.org/document/10933346

[50] A Review on the Applications of Machine Learning and Deep Learning ... — Modern image recognition has experienced dramatic improvements because of Machine Learning and Deep Learning algorithms together. This study investigates CNNs and SVMs for recognition enhancement while reviewing image recognition technologies extensively through literature. This paper demonstrates how the applications of healthcare and security systems and social media analysis influence

springer

https://link.springer.com/chapter/10.1007/978-3-031-47718-8_30

[51] Enhancing Medical Diagnosis Through Deep Learning and Machine Learning ... — Medical imaging analysis plays a critical role in the medical field, transforming how diseases are found, diagnosed, and treated. The integration of machine learning and deep learning has dramatically advanced the field of medical image analysis, leading to the creation of more advanced algorithms for improved diagnosis and disease detection. This study examines the impact of these cutting

futurefarming

https://www.futurefarming.com/tech-in-focus/imaging-technology-unveils-future-of-precision-agriculture/

[55] Imaging technology unveils future of precision agriculture — The global market for imaging technology for precision agriculture held a market value of US$ 955.4 Mn for the base year 2022. The market size is estimated to increase to the market value of US$ 1,042.3 Mn in 2023 and is estimated to reach US$ 2,889.3 Mn by 2033, growing at a CAGR of 10.7%. as per report published by Persistence Market Research.

api4

https://api4.ai/blog/boosting-agricultural-productivity-with-ai-powered-image-analysis

[56] Boosting Agricultural Productivity with AI-Powered Image Analysis — Discover how AI-powered image analysis is transforming agriculture by enhancing crop monitoring, disease detection and precision farming. ... Precision Agriculture: Precision agriculture is all about doing more with less, by tailoring the use of resources to meet the exact needs of the crop: ... Future Trends and Opportunities.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[57] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

prlab

https://prlab.co/blog/social-impact-of-visuals-and-use-of-images/

[60] Social impact of visuals and use of images - PRLab — This article showcases the dynamic interplay between visuals and their social impact. It explores images as a catalyzing factor for changes in different spheres of life, including marketing. This guideline also uncovers how pictures can amplify messaging, foster community, and drive societal progress.

researchgate

https://www.researchgate.net/publication/390013252_Visual_Sociology_The_Sociological_Analysis_of_the_Image

[62] Visual Sociology: The Sociological Analysis of the Image - ResearchGate — A content analysis Method was adopted to deconstruct the social and cultural issues associated with images and to underscore the importance of sociological analysis in understanding visual phenomena.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2543925122001024

[63] A review of the studies on social media images from the perspective of ... — Image is the visual basis for human to understand the world and objectively reflect natural scenery, and it is an important means for human to obtain, express and transmit information (Murray, 2008).). "Capture and share the world's wonderful moments" is the slogan of Instagram, the world's largest image social media platform, and also the dominant visual communication concept in today's

thehistory

https://thehistory.tech/history-computer-vision-ai-image-recognition/

[79] The History of Computer Vision and AI Image Recognition — The History of Computer Vision and AI Image Recognition The History of Computer Vision and AI Image Recognition History of Computer Vision and AI Image Recognition AI image recognition, also known as computer vision, refers to the technology and processes by which artificial intelligence systems are trained to interpret and understand visual information from images or videos. At its core, AI image recognition involves the use of advanced algorithms and deep learning techniques, such as convolutional neural networks (CNNs), to analyze and identify objects, patterns, or features within digital images or video frames. Artificial intelligence (AI) and image processing play crucial roles in the field of computer vision, working synergistically to enable machines to interpret and understand visual data: History of Computer Vision and AI Image Recognition

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0262885624001410

[81] Image recognition based on lightweight convolutional neural network ... — Image recognition based on lightweight convolutional neural network: Recent advances - ScienceDirect Image recognition based on lightweight convolutional neural network: Recent advances A comprehensive review of recent advances in lightweight CNN for image recognition. In recent years, with the advent of deep learning, lightweight convolutional neural network (CNN) has brought new opportunities for image recognition, which allows high-performance recognition algorithms to run on resource-constrained devices with strong representation and generalization capabilities. Then, a comprehensive review is provided on recent image recognition techniques using lightweight CNN. According to the strategies applied to optimize image recognition performance, existing methods are classified into three categories: (1) model compression, (2) optimization of lightweight network, and (3) combining Transformer with lightweight network. For all open access content, the relevant licensing terms apply.

medium

https://medium.com/@API4AI/mastering-deep-learning-key-concepts-and-its-impact-on-image-processing-1dc6d7ac0999

[83] Deep Learning in Image Processing: Key Concepts & Applications - Medium — From improving security through enhanced facial recognition systems to enabling autonomous vehicles to interpret their surroundings, the applications of deep learning in image processing are vast and varied. By leveraging large datasets and computational power, deep learning models can perform complex tasks such as image recognition, natural language processing, and more with remarkable accuracy. These models leverage vast amounts of textual data to understand and generate human-like text, enhancing image processing applications by providing contextual understanding. Deep learning models, particularly autoencoders and CNNs, can be trained to detect anomalies in images. Deep learning models process real-time images from cameras and sensors to understand the vehicle’s surroundings, recognize traffic signs, detect pedestrians, and monitor road conditions.

ieee

https://ieeexplore.ieee.org/document/10935312

[88] Deep Learning-Based Medical Object Detection: A Survey — Recent advancements in medical object detection (MOD) have been propelled by the rapid evolution of deep learning (DL) technologies, revolutionizing medical imaging and diagnostic workflows. This survey comprehensively reviews a vast scope of studies across diverse imaging modalities, including X-Ray, CT, MRI, Ultrasound, and Histopathology. Notable improvements include the integration of You

mdpi

https://www.mdpi.com/journal/applsci/special_issues/1CA6TF532Z

[90] Deep Learning for Biomedical Image Analysis: Recent Advances and ... - MDPI — Deep learning has revolutionized biomedical image analysis, enabling significant advancements in disease diagnosis, treatment planning, and drug discovery. This Special Issue aims to showcase cutting-edge research and novel applications of deep learning techniques in biomedical imaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11144045/

[91] Deep Learning Approaches for Medical Image Analysis and Diagnosis — To summarize, the integration of deep learning algorithms, particularly CNNs, into radiological practices represents a paradigm shift in medical imaging, offering unprecedented capabilities in the automated detection and classification of abnormalities in chest X-rays. Addressing these challenges requires the development of techniques and methodologies to enhance the interpretability, robustness, and reliability of deep learning models for medical image analysis. One of the primary challenges in medical image analysis is the scarcity of large annotated datasets, which are essential for effectively training deep learning models. In medical image analysis, interpretable and explainable deep learning models can help clinicians validate model predictions, understand underlying disease mechanisms, and guide treatment decisions .

thespinejournalonline

https://www.thespinejournalonline.com/article/S1529-9430(25

[92] Using Deep Learning to Enhance Reporting Efficiency and Accuracy in ... — The integration of artificial intelligence in medical imaging offers potential solutions to enhance productivity and diagnostic consistency. ... To assess whether a transformer-based deep learning model (DLM) can improve the efficiency and accuracy of radiologists in reporting DCS MRIs.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC10740686/

[93] How Artificial Intelligence Is Shaping Medical Imaging Technology: A ... — The innovation segment explores cutting-edge developments in AI, such as deep learning algorithms, convolutional neural networks, and generative adversarial networks, which have significantly improved the accuracy and efficiency of medical image analysis. For instance, in medical imaging, where obtaining large, diverse datasets can be challenging, GANs enable researchers to generate additional, realistic medical images for training diagnostic models, ultimately improving the accuracy of disease detection . By leveraging the capabilities of AI, medical imaging data, such as CT scans and MRI images, can be transformed into detailed three-dimensional models that provide an enhanced understanding of a patient’s anatomy. 75.Trevisan de Souza V.L., Marques B.A.D., Batagelo H.C., Gois J.P. A Review on Generative Adversarial Networks for Image Generation.

33rdsquare

https://www.33rdsquare.com/image-prediction-using-a-pre-trained-model/

[99] Unleashing the Power of Pre-trained Models for Image Prediction — Medical Image Analysis: Pre-trained models can be adapted to analyze medical images, assisting in tasks like disease diagnosis, tumor segmentation, and anomaly detection. Autonomous Vehicles: Pre-trained models can be utilized in perception systems of autonomous vehicles to detect and classify objects in the environment, enabling safe navigation.

arxiv

https://arxiv.org/html/2503.18873

[100] Efficient Self-Supervised Adaptation for Medical Image Analysis - arXiv.org — Foundation models pretrained on diverse, large-scale natural scene datasets have shown remarkable effectiveness in medical imaging .However, their direct transfer is hindered by domain shifts, as natural and medical images differ significantly in structure and content .Transfer learning, or supervised adaptation (SA), helps bridge this gap by fine-tuning the model weights to

biomedcentral

https://bmcmedimaging.biomedcentral.com/articles/10.1186/s12880-022-00793-7

[102] Transfer learning for medical image classification: a literature review — Background Transfer learning (TL) with convolutional neural networks aims to improve performances on a new task by leveraging the knowledge of similar tasks learned in advance. It has made a major contribution to medical image analysis as it overcomes the data scarcity problem as well as it saves time and hardware resources. However, transfer learning has been arbitrarily configured in the

medium

https://cyril-picard.medium.com/detailed-report-on-image-analysis-afa671d83617

[116] Detailed Report on Image Analysis | by Cyril Picard | Medium — Detailed Report on Image Analysis | by Cyril Picard | Medium Image analysis is a crucial field that involves the extraction of meaningful information from images, primarily digital images, through various digital image processing techniques. Understanding Image Analysis Image analysis refers to the process of extracting useful information from images using computational methods. Techniques in Image Analysis Challenges in Image Analysis Applications of Image Analysis For instance, image analysis can help in identifying tumors in scans, thereby enhancing early detection and treatment (Dempster, 2001). The Future of Image Analysis From medical diagnostics to environmental monitoring, the techniques and methodologies employed in image analysis continue to evolve, driven by advancements in artificial intelligence and machine learning. Image Analysis. Image analysis. Image Analysis

wikipedia

https://en.wikipedia.org/wiki/Image_analysis

[117] Image analysis - Wikipedia — Image analysis or imagery analysis is the extraction of meaningful information from images; mainly from digital images by means of digital image processing techniques. Image analysis tasks can be as simple as reading bar coded tags or as sophisticated as identifying a person from their face. Computers are indispensable for the analysis of large amounts of data, for tasks that require

sciencedirect

https://www.sciencedirect.com/topics/computer-science/image-analysis

[118] Image Analysis - an overview | ScienceDirect Topics — Image analysis refers to the extraction of meaningful information from digital images using digital image processing techniques. It involves tasks such as object recognition, image segmentation, motion detection, and medical scan analysis. Image analysis is an important field in computer science that allows computers to automatically study images and obtain useful information from them. AI

synapseforges

https://synapseforges.com/articles/image-analysis-methodologies-scientific-research/

[120] A Comprehensive Approach to Image Analysis in Scientific Research — Moreover, accurate image analysis can lead to improved diagnostic methods in medical research, more effective material characterizations in chemistry, and enhanced geological predictions in earth sciences. Image processing techniques form a crucial component of image analysis in scientific research. Image processing allows researchers to extract meaningful information from raw data by applying systematic methods that can significantly improve analysis outcomes. Quantitative image analysis is essential in scientific research as it provides a systematic approach to extract meaningful data from images. The integration of image analysis within various scientific fields is essential for advancing research methodologies. "The advancement of image analysis tools will not only enhance research outcomes but also redefine our understanding of complex biological systems."

data-science-ua

https://data-science-ua.com/blog/image-processing-techniques-image-types-and-applications/

[121] Image Processing Techniques, Image Types and Applications | data ... — Image Processing Techniques, Image Types and Applications | data-science-ua.com Practical Image Processing Technique Image processing is a technique of performing operations on images for enhancement or to gather useful information from them. Advanced Image Processing Techniques Image Processing Applications Across Industries Advanced image processing technologies are being increasingly adopted in industries for inspection and quality control; manufacturers are automating systems to detect defects that help ensure compliance with standards. Organizations use image processing to digitize documents and enhance access and data management. Image processing has a variety of benefits, from quality improvement to enhancing the biometric analysis capability and efficiency in data handling. As technology advances, the techniques and applications of image processing will expand, unlocking new possibilities for innovation and efficiency.

ieee

https://ieeexplore.ieee.org/document/9311202

[126] A Review on Traditional Machine Learning and Deep Learning Models for ... — In computer vision, traditional machine learning (TML) and deep learning (DL) methods have significantly contributed to the advancements of medical image analysis (MIA) by enhancing prediction accuracy, leading to appropriate planning and diagnosis. These methods substantially improved the diagnoses of automatic brain tumor and leukemia/blood cancer detection and can assist the hematologist

sciencedirect

https://www.sciencedirect.com/science/article/pii/S0010482520304601

[127] The impact of pre- and post-image processing techniques on deep ... — The majority of recent machine learning methods in digital pathology have a pre- and/or post-processing stage which is integrated with a deep neural network. These stages, based on traditional image processing methods, are employed to make the subsequent classification, detection, or segmentation problem easier to solve.

researchgate

https://www.researchgate.net/publication/383113395_A_Research_on_Image_Recognition_and_Classification_Based_on_Traditional_Machine_Learning_and_Deep_Learning

[128] A Research on Image Recognition and Classification Based on Traditional ... — Spatial structure information is very important in image analysis algorithms. Traditional machine learning methods based on vectorization strategies often ignore the spatial information of the

arxiv

https://arxiv.org/pdf/2204.05983

[129] Comparison Analysis of Traditional Machine Learning and Deep Learning ... — Deep Learning techniques: using deep convolutional neural networks, i.e., a pre-trained model and the proposed ANN Additionally, using the above-mentioned methods, we aim to address the following: 1. Suggest a novice CNN architecture for image classification Lastly, the technical novelty of this article is not only presenting a comparative study between traditional ML and Deep Learning techniques, but suggesting a new CNN that achieves accuracy levels of slightly over 90% - and in some cases higher - similarly with the most recent scientific advances in the field. Mouslech, Kassiani Skoulariki, Alexandros Gazis E-ISSN: 2224-2880 124 Volume 21, 2022 3.4 Deep Learning Algorithms Apart from the ML methods discussed, Neural Networks (NN) are also used extensively combined with supervised learning techniques to identify and classify objects between classes .

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[130] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

nanoknowledgeai

https://nanoknowledgeai.com/the-role-of-ai-in-early-disease-detection/

[156] The Role of AI in Early Disease Detection - NanoKnowledgeAI — The Role of AI in Early Disease Detection The Role of AI in Early Disease Detection NanoKnowledgeAI > Blog > Science > Artificial Intelligence > AI Health > The Role of AI in Early Disease Detection The Role of AI in Early Disease Detection By analyzing this data, AI can detect patterns that indicate the early stages of a disease. The Challenges of Using AI in Early Disease Detection The Future of AI in Early Disease Detection This data can be analyzed by AI to detect early signs of disease, allowing for timely intervention without the need for in-person visits. By analyzing vast amounts of data, recognizing patterns, and making predictions, AI can detect diseases at an early stage, when they are most treatable.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[157] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11144045/

[158] Deep Learning Approaches for Medical Image Analysis and Diagnosis — To summarize, the integration of deep learning algorithms, particularly CNNs, into radiological practices represents a paradigm shift in medical imaging, offering unprecedented capabilities in the automated detection and classification of abnormalities in chest X-rays. Addressing these challenges requires the development of techniques and methodologies to enhance the interpretability, robustness, and reliability of deep learning models for medical image analysis. One of the primary challenges in medical image analysis is the scarcity of large annotated datasets, which are essential for effectively training deep learning models. In medical image analysis, interpretable and explainable deep learning models can help clinicians validate model predictions, understand underlying disease mechanisms, and guide treatment decisions .

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11582495/

[159] The Role of Artificial Intelligence in Diagnostic Radiology — All studies were found by searching for keywords such as "artificial intelligence," "radiological applications," "diseases," and "diagnostics," with the subcategories "radiological image interpretation," "deep learning," and "diagnostic accuracy." An automated keyword-based search strategy was used within the search engines of the databases such as PubMed, Google Scholar, Cureus Journal, and the National Library of Medicine. The study by Rubin, which was published in the National Library of Medicine (2019) , is an in-depth study of the potential of artificial intelligence (AI) in the field of radiology, particularly as it relates to diagnostic imaging. Tang (2020) The role of artificial intelligence in medical imaging research The study underscores the capabilities and potential of AI, especially machine learning and deep learning, in identifying intricate patterns in medical images, which can facilitate the early diagnosis of diseases like cancer.

acm

https://dl.acm.org/doi/fullHtml/10.1145/3584202.3584278

[185] AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING - ACM Digital Library — AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING. Some of these challenges are inherited in the medical images and others are related to diseases characteristics, and the techniques and methods of image processing. Since most imaging modalities became digital, with continually increasing resolution, medical image processing has to face the challenges of big data (Scholl et al., 2011). Automation helps to mitigate these challenges; however, automatic analysis of medical images requires many image processing techniques such as feature extraction and segmentation and also pre-processing operations like noise removal, image enhancement, edge detection etc (Roy and Phadikar, 2014). 4 MEDICAL IMAGE PROCESSING CHALLENGES

acm

https://dl.acm.org/doi/fullHtml/10.1145/3584202.3584278

[188] AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING - ACM Digital Library — AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING AN OVERVIEW OF CHALLENGES IN MEDICAL IMAGE PROCESSING. Some of these challenges are inherited in the medical images and others are related to diseases characteristics, and the techniques and methods of image processing. Since most imaging modalities became digital, with continually increasing resolution, medical image processing has to face the challenges of big data (Scholl et al., 2011). Automation helps to mitigate these challenges; however, automatic analysis of medical images requires many image processing techniques such as feature extraction and segmentation and also pre-processing operations like noise removal, image enhancement, edge detection etc (Roy and Phadikar, 2014). 4 MEDICAL IMAGE PROCESSING CHALLENGES

sciencedirect

https://www.sciencedirect.com/science/article/pii/S1361841516300998

[189] Four challenges in medical image analysis from an industrial ... — While many algorithmic approaches and ideas are now available which allow medical image analysis tasks in commercial products to be addressed, new challenges are arising. Accordingly, training and machine learning approaches are gaining importance which for instance combine supervised with unsupervised learning, use a small database with detailed GT annotations (e.g. detailed 3D delineation of anatomical structures) together with a large database with weak annotations (e.g. a sparse set of organ boundary locations) or synthetically extend the GT database by exploiting known image properties. In general, the importance of generating patient-specific anatomical models from 3D image data was recognized early as a key topic in medical image analysis with many applications (Höhne et al., 1995).

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11673497/

[190] Lightweight Super-Resolution Techniques in Medical Imaging: Bridging ... — Medical imaging plays an essential role in modern healthcare, providing non-invasive tools for diagnosing and monitoring various medical conditions. However, the resolution limitations of imaging hardware often result in suboptimal images, which can

irjmets

https://www.irjmets.com/uploadedfiles/paper/issue_2_february_2024/49604/final/fin_irjmets1708609604.pdf

[191] PDF — Limitations of Edge-based Methods Edge-based segmentation has some inherent limitations. Disjointed edges often result from noise, texture and insufficient contrast. Additional processing is needed to link edges into complete object boundaries. Weak or missing edges also cause segmentation errors. Edge localization degrades for blurry images.

openmedscience

https://openmedscience.com/mastering-medical-imaging-quality-tools-techniques-and-outcomes/

[195] Medical Image Quality in Accurate Diagnosis | Open Medscience — It examines factors like contrast, blur, noise, artefacts, and distortion, while also discussing strategies to meet diagnostic imaging standards, achieve radiological clarity, utilise optimised imaging parameters, apply image contrast enhancement, focus on minimising imaging artefacts, and emphasise reducing image distortion. Attaining superior medical image quality relies on multiple interwoven factors: the meticulous selection of equipment, the application of optimised imaging parameters, rigorous adherence to diagnostic imaging standards, and continuous efforts towards image contrast enhancement, radiological clarity, minimising imaging artefacts, and reducing image distortion. A: Consistent training, routine equipment maintenance, and careful selection of optimised imaging parameters help maintain medical image quality, ensuring that your images meet established standards and offer dependable radiological clarity.

researchgate

https://www.researchgate.net/publication/261471122_Noise_Reduction_in_Medical_Images_-_Comparison_of_noise_removal_algorithms

[199] (PDF) Noise Reduction in Medical Images - ResearchGate — The obtained images from different medical acquisition techniques are not clear enough and usually corrupted by noise . Noise in the medical image can be caused via a variety of sources which

pythonguides

https://pythonguides.com/machine-learning-image-processing/

[208] Machine Learning Image Processing - Python Guides — Machine Learning Image Processing Machine Learning Image Processing Machine learning image processing combines computer vision and artificial intelligence to extract useful information from pictures and videos. Good data handling is key for machine learning image processing. Image analysis and feature extraction are key steps in machine learning for processing visual data. Machine learning models for image processing can be enhanced through various methods. Machine learning is used in many image processing tasks. I discussed the fundamentals of image processing and Machine Learning, key technologies and frameworks, data handling for image processing, image analysis and feature extraction, advanced image processing applications, Machine Learning for image classification, improving performance, visual enhancement and restoration, emerging trends in ML image processing, and some

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11182665/

[218] Metrics Reloaded: Recommendations for image analysis validation — In fact, validation that is not conducted according to relevant metrics could be one major reason for why many artificial intelligence (AI) developments in medical imaging fail to reach clinical practice . In other words, the numbers presented in journals and conference proceedings do not reflect how successful a system will be when

jacr

https://www.jacr.org/article/S1546-1440(24

[220] Establishing a Validation Infrastructure for Imaging-Based Artificial ... — With promising artificial intelligence (AI) algorithms receiving FDA clearance, the potential impact of these models on clinical outcomes must be evaluated locally before their integration into routine workflows. Robust validation infrastructures are pivotal to inspecting the accuracy and generalizability of these deep learning algorithms to ensure both patient safety and health equity

biomedcentral

https://bmcmedicine.biomedcentral.com/articles/10.1186/s12916-025-03994-3

[221] The validation of prediction models deserves more recognition — The TRIPOD AI reporting guideline for developing CPMs requires not only to have clear definitions of populations, context, and methods, but also references to competing models and a justification to develop a new CPM. Organizations responsible for development of clinical guidelines should require external validation and impact studies of CPMs. Here, systematic reviews on CPMs and meta-analyses of their external validations identify current best evidence cost-efficiently and rapidly. Systematic reviews of CPMs cannot be performed because respective external validation or impact studies are missing, preventing experience with CPMs and allowing misconceptions about the capabilities of such a model. Evaluation of clinical prediction models (part 1): from development to external validation; BMJ. Evaluation of clinical prediction models (part 3): calculating the sample size required for an external validation study.

frontiersin

https://www.frontiersin.org/research-topics/64771/advancements-in-image-processing-and-analysis-techniques-for-microphysiological-systems

[223] Advancements in Image Processing and Analysis Techniques for ... — Overall, the implementation of advanced image processing and analysis techniques in this field holds significant promise for advancing our understanding of human biology, disease pathology, and drug efficacy, ultimately paving the way for personalized medicine and therapeutic development. ... This topic plans to explore recent advancements in

mdpi

https://www.mdpi.com/journal/applsci/special_issues/1CA6TF532Z

[224] Deep Learning for Biomedical Image Analysis: Recent Advances and ... - MDPI — Deep learning has revolutionized biomedical image analysis, enabling significant advancements in disease diagnosis, treatment planning, and drug discovery. This Special Issue aims to showcase cutting-edge research and novel applications of deep learning techniques in biomedical imaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC8473276/

[225] Recent Advances in Multi- and Hyperspectral Image Analysis — To extract value from such highly dimensional data capturing up to hundreds of spectral bands in the electromagnetic spectrum, researchers have been developing a range of image processing and machine learning analysis pipelines to process these kind of data as efficiently as possible. Multi- and hyperspectral image processing using machine learning and advanced data analysis has become an important research area due to the numerous challenges that need to be effectively faced before such imaging techniques can be robustly employed in emerging real-life use cases that span across various fields of engineering and industry. 14.Li S., Song W., Fang L., Chen Y., Ghamisi P., Benediktsson J.A. Deep Learning for Hyperspectral Image Classification: An Overview.

biomedcentral

https://bmcmethods.biomedcentral.com/articles/10.1186/s44330-024-00010-7

[226] Advances in medical imaging techniques - BMC Methods — Advances in medical imaging techniques | BMC Methods | Full Text The BMC Methods Collection “Advances in medical imaging techniques” will showcase the latest advancements in this field, including state-of-the-art imaging modalities, novel biomedical applications, progress in molecular probes and radiopharmaceuticals, and innovative methodologies for image analysis, data fusion, and visualization. Since then, medical imaging has evolved rapidly, with the development of diverse modalities like ultrasound, X-ray computed tomography (CT), magnetic resonance imaging (MRI), positron emission tomography (PET), and single-photon emission computed tomography (SPECT). The BMC Methods Collection “Advances in medical imaging techniques” (https://www.biomedcentral.com/collections/amit), compiles original methodology and protocol articles on the latest developments in medical imaging, covering advances in imaging modalities, biomedical applications, molecular probes, radiopharmaceuticals, and data and image processing.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC10740686/

[227] How Artificial Intelligence Is Shaping Medical Imaging Technology: A ... — The innovation segment explores cutting-edge developments in AI, such as deep learning algorithms, convolutional neural networks, and generative adversarial networks, which have significantly improved the accuracy and efficiency of medical image analysis. For instance, in medical imaging, where obtaining large, diverse datasets can be challenging, GANs enable researchers to generate additional, realistic medical images for training diagnostic models, ultimately improving the accuracy of disease detection . By leveraging the capabilities of AI, medical imaging data, such as CT scans and MRI images, can be transformed into detailed three-dimensional models that provide an enhanced understanding of a patient’s anatomy. 75.Trevisan de Souza V.L., Marques B.A.D., Batagelo H.C., Gois J.P. A Review on Generative Adversarial Networks for Image Generation.

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[230] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC7594889/

[231] The role of artificial intelligence in medical imaging research — However, it might take much less time, as it solely depends on curated data and the corresponding metadata rather than the domain expertise, which usually takes years to develop.12 As the traditional AI requires predefined features and have shown plateauing performance over recent years, and with the current success of AI/deep learning in image research, it is expected that AI will further dominate the image research in radiology. Similar to radiology, it started with traditional AI and now with deep learning.3,22–242526 In the most recent Medical Physics journal (May 2019, Volume 46, Issue 5), there were 16/51 papers on deep learning-based imaging research.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC10740686/

[232] How Artificial Intelligence Is Shaping Medical Imaging Technology: A ... — The innovation segment explores cutting-edge developments in AI, such as deep learning algorithms, convolutional neural networks, and generative adversarial networks, which have significantly improved the accuracy and efficiency of medical image analysis. For instance, in medical imaging, where obtaining large, diverse datasets can be challenging, GANs enable researchers to generate additional, realistic medical images for training diagnostic models, ultimately improving the accuracy of disease detection . By leveraging the capabilities of AI, medical imaging data, such as CT scans and MRI images, can be transformed into detailed three-dimensional models that provide an enhanced understanding of a patient’s anatomy. 75.Trevisan de Souza V.L., Marques B.A.D., Batagelo H.C., Gois J.P. A Review on Generative Adversarial Networks for Image Generation.

ulasalle

https://revistas.ulasalle.edu.pe/innosoft/article/view/159

[233] Ethics in artificial intelligence : analysis of image generator models ... — This article on the ethics of artificial intelligence, based on image generation, contains a comprehensive analysis of the ethical and practical dilemmas associated with AI. In the introduction, we highlight the widespread impact of AI on human society and emphasize the importance of addressing the ethical dilemmas arising from its use, distinguishing in areas such as decision making in

taftcollege

https://lib.taftcollege.edu/ai-literacy/ethics

[234] Ethical Considerations - AI Literacy - LibGuides at Taft College — AI ethics is a crucial component of AI literacy. As AI systems become more integrated into our daily lives and decision-making processes, it's crucial to address these ethical challenges to ensure responsible development and use. Below are just a few of the key ethical considerations in AI. Image sourced from Canva.com

sciencedirect

https://www.sciencedirect.com/science/article/pii/S2666990024000132

[238] AI in diagnostic imaging: Revolutionising accuracy and efficiency — Through 30 included studies, the review identifies four AI domains and eight functions in diagnostic imaging: 1) In the area of Image Analysis and Interpretation, AI capabilities enhanced image analysis, spotting minor discrepancies and anomalies, and by reducing human error, maintaining accuracy and mitigating the impact of fatigue or oversight, 2) The Operational Efficiency is enhanced by AI through efficiency and speed, which accelerates the diagnostic process, and cost-effectiveness, reducing healthcare costs by improving efficiency and accuracy, 3) Predictive and Personalised Healthcare benefit from AI through predictive analytics, leveraging historical data for early diagnosis, and personalised medicine, which employs patient-specific data for tailored diagnostic approaches, 4) Lastly, in Clinical Decision Support, AI assists in complex procedures by providing precise imaging support and integrates with other technologies like electronic health records for enriched health insights, showcasing ai's transformative potential in diagnostic imaging.

nih

https://pmc.ncbi.nlm.nih.gov/articles/PMC11651983/

[241] A literature review of artificial intelligence (AI) for medical image ... — Thus, AI-based approaches to medical image segmentation face several challenges, including model interpretation issues, age and racial bias, concerns related to robustness, and the ongoing problem of uncertainty in medical diagnoses. (111) proposed an XAI-based medical image segmentation model, GradXcepUNet, which combines the segmentation capability of the U-Net with the interpretability feature of Grad-CAM’s Xception classification network. This article provides a review of the literature on traditional AI, XAI, and TAI algorithms, particularly focusing on their application in medical image segmentation. Future research directions include exploring new AI architectures, integrating multimodal data fusion techniques, and advancing TAI methods to improve the reliability and trustworthiness of AI in medical image segmentation.