Your search keyword '"Marias, Kostas"' showing total 19 results

1. Deep learning enables the differentiation between early and late stages of hip avascular necrosis.

Author

Klontzas ME, Vassalou EE, Spanakis K, Meurer F, Woertler K, Zibis A, Marias K, and Karantanas AH

Subjects

Humans, Retrospective Studies, Neural Networks, Computer, Magnetic Resonance Imaging methods, Deep Learning, Osteonecrosis

Abstract

Objectives: To develop a deep learning methodology that distinguishes early from late stages of avascular necrosis of the hip (AVN) to determine treatment decisions., Methods: Three convolutional neural networks (CNNs) VGG-16, Inception ResnetV2, InceptionV3 were trained with transfer learning (ImageNet) and finetuned with a retrospectively collected cohort of (n = 104) MRI examinations of AVN patients, to differentiate between early (ARCO 1-2) and late (ARCO 3-4) stages. A consensus CNN ensemble decision was recorded as the agreement of at least two CNNs. CNN and ensemble performance was benchmarked on an independent cohort of 49 patients from another country and was compared to the performance of two MSK radiologists. CNN performance was expressed with areas under the curve (AUC), the respective 95% confidence intervals (CIs) and precision, and recall and f1-scores. AUCs were compared with DeLong's test., Results: On internal testing, Inception-ResnetV2 achieved the highest individual performance with an AUC of 99.7% (95%CI 99-100%), followed by InceptionV3 and VGG-16 with AUCs of 99.3% (95%CI 98.4-100%) and 97.3% (95%CI 95.5-99.2%) respectively. The CNN ensemble the same AUCs Inception ResnetV2. On external validation, model performance dropped with VGG-16 achieving the highest individual AUC of 78.9% (95%CI 51.6-79.6%) The best external performance was achieved by the model ensemble with an AUC of 85.5% (95%CI 72.2-93.9%). No significant difference was found between the CNN ensemble and expert MSK radiologists (p = 0.22 and 0.092 respectively)., Conclusion: An externally validated CNN ensemble accurately distinguishes between the early and late stages of AVN and has comparable performance to expert MSK radiologists., Clinical Relevance Statement: This paper introduces the use of deep learning for the differentiation between early and late avascular necrosis of the hip, assisting in a complex clinical decision that can determine the choice between conservative and surgical treatment., Key Points: • A convolutional neural network ensemble achieved excellent performance in distinguishing between early and late avascular necrosis. • The performance of the deep learning method was similar to the performance of expert readers., (© 2023. The Author(s).)

Published

2024

2. Differentiation between subchondral insufficiency fractures and advanced osteoarthritis of the knee using transfer learning and an ensemble of convolutional neural networks.

Author

Klontzas ME, Vassalou EE, Kakkos GA, Spanakis K, Zibis A, Marias K, and Karantanas AH

Subjects

Humans, Neural Networks, Computer, ROC Curve, Retrospective Studies, Deep Learning, Fractures, Stress diagnostic imaging, Osteoarthritis, Knee diagnostic imaging

Abstract

Purpose: Subchondral insufficiency fractures (SIF) and advanced osteoarthritis (OA) of the knee are usually seen in conjunction with bone marrow lesions (BMLs) and their differentiation may pose a significant diagnostic challenge. We aimed to develop a convolutional neural network (CNN) ensemble which could successfully differentiate between these two entities., Materials and Methods: A total of 212 knees with SIF and 102 knees with advanced OA with BMLs were retrospectively included. Coronal fat suppressed PD-w images were augmented, resized and normalized, reaching a total of 1174 images. Data was used to fine-tune three ImageNet-pretrained CNNs (VGG-16, InceptionV3 and Inception-ResNet-V2). Agreement of at least two networks was recorded as the decision of the network ensemble. Ensemble performance was compared to that of two MSK radiologists on the validation set. Receiver operating characteristics (ROC) curves and the respective areas under the curve (AUC) were used to evaluate human and machine performance., Results: InceptionV3 achieved the highest AUC (93.68%) and VGG-16 the lowest AUC (82.18%) among individual CNNs. CNN ensemble achieved the highest overall performance with an AUC of 95.97%. The first of the two MSK radiologists achieved a performance similar to the ensemble, reaching an AUC of 91.95%. The second radiologist achieved lower AUC of 82.76% which was lower than both the other specialist and the ensemble (P < 0.001)., Conclusion: A CNN ensemble was highly accurate in differentiating between SIF and OA, achieving a higher or equal performance to MSK radiologists., Competing Interests: Declarations of Competing Interest None, (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

3. Deep Learning in mHealth for Cardiovascular Disease, Diabetes, and Cancer: Systematic Review.

Author

Triantafyllidis A, Kondylakis H, Katehakis D, Kouroubali A, Koumakis L, Marias K, Alexiadis A, Votis K, and Tzovaras D

Subjects

Humans, Prospective Studies, Cardiovascular Diseases therapy, Deep Learning, Diabetes Mellitus therapy, Neoplasms diagnosis, Neoplasms therapy, Telemedicine

Abstract

Background: Major chronic diseases such as cardiovascular disease (CVD), diabetes, and cancer impose a significant burden on people and health care systems around the globe. Recently, deep learning (DL) has shown great potential for the development of intelligent mobile health (mHealth) interventions for chronic diseases that could revolutionize the delivery of health care anytime, anywhere., Objective: The aim of this study is to present a systematic review of studies that have used DL based on mHealth data for the diagnosis, prognosis, management, and treatment of major chronic diseases and advance our understanding of the progress made in this rapidly developing field., Methods: A search was conducted on the bibliographic databases Scopus and PubMed to identify papers with a focus on the deployment of DL algorithms that used data captured from mobile devices (eg, smartphones, smartwatches, and other wearable devices) targeting CVD, diabetes, or cancer. The identified studies were synthesized according to the target disease, the number of enrolled participants and their age, and the study period as well as the DL algorithm used, the main DL outcome, the data set used, the features selected, and the achieved performance., Results: In total, 20 studies were included in the review. A total of 35% (7/20) of DL studies targeted CVD, 45% (9/20) of studies targeted diabetes, and 20% (4/20) of studies targeted cancer. The most common DL outcome was the diagnosis of the patient's condition for the CVD studies, prediction of blood glucose levels for the studies in diabetes, and early detection of cancer. Most of the DL algorithms used were convolutional neural networks in studies on CVD and cancer and recurrent neural networks in studies on diabetes. The performance of DL was found overall to be satisfactory, reaching >84% accuracy in most studies. In comparison with classic machine learning approaches, DL was found to achieve better performance in almost all studies that reported such comparison outcomes. Most of the studies did not provide details on the explainability of DL outcomes., Conclusions: The use of DL can facilitate the diagnosis, management, and treatment of major chronic diseases by harnessing mHealth data. Prospective studies are now required to demonstrate the value of applied DL in real-life mHealth tools and interventions., (©Andreas Triantafyllidis, Haridimos Kondylakis, Dimitrios Katehakis, Angelina Kouroubali, Lefteris Koumakis, Kostas Marias, Anastasios Alexiadis, Konstantinos Votis, Dimitrios Tzovaras. Originally published in JMIR mHealth and uHealth (https://mhealth.jmir.org), 04.04.2022.)

Published

2022

4. Deep learning for diabetic retinopathy detection and classification based on fundus images: A review.

Author

Tsiknakis N, Theodoropoulos D, Manikis G, Ktistakis E, Boutsora O, Berto A, Scarpa F, Scarpa A, Fotiadis DI, and Marias K

Subjects

Artificial Intelligence, Female, Fundus Oculi, Humans, Uterus, Deep Learning, Diabetes Mellitus, Diabetic Retinopathy diagnostic imaging

Abstract

Diabetic Retinopathy is a retina disease caused by diabetes mellitus and it is the leading cause of blindness globally. Early detection and treatment are necessary in order to delay or avoid vision deterioration and vision loss. To that end, many artificial-intelligence-powered methods have been proposed by the research community for the detection and classification of diabetic retinopathy on fundus retina images. This review article provides a thorough analysis of the use of deep learning methods at the various steps of the diabetic retinopathy detection pipeline based on fundus images. We discuss several aspects of that pipeline, ranging from the datasets that are widely used by the research community, the preprocessing techniques employed and how these accelerate and improve the models' performance, to the development of such deep learning models for the diagnosis and grading of the disease as well as the localization of the disease's lesions. We also discuss certain models that have been applied in real clinical settings. Finally, we conclude with some important insights and provide future research directions., (Copyright © 2021 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2021

5. Automated analysis of fundus images for the diagnosis of retinal diseases: a review

Author

Berto, Alexa, Scarpa, Fabio, Tsiknakis, Nikos, Manikis, Georgios, Fotiadis, Dimitrios I., Marias, Kostas, and Scarpa, Alberto

Published

2024

6. Deep Learning Fundamentals

Author

Trivizakis, Eleftherios, Marias, Kostas, van Ooijen, Peter M. A., Series Editor, Ranschaert, Erik R., Series Editor, Trianni, Annalisa, Series Editor, Klontzas, Michail E., Series Editor, Fanni, Salvatore Claudio, editor, and Neri, Emanuele, editor

Published

2023

7. LoockMe: An Ever Evolving Artificial Intelligence Platform for Location Scouting in Greece

Author

Trivizakis, Eleftherios, Aidonis, Vassilios, Pezoulas, Vassilios C., Goletsis, Yorgos, Oikonomou, Nikolaos, Stefanis, Ioannis, Chondromatidou, Leoni, Fotiadis, Dimitrios I., Tsiknakis, Manolis, Marias, Kostas, Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Prates, Raquel Oliveira, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Barbosa, Simone Diniz Junqueira, Editorial Board Member, Chen, Phoebe, Editorial Board Member, Cuzzocrea, Alfredo, Editorial Board Member, Du, Xiaoyong, Editorial Board Member, Kara, Orhun, Editorial Board Member, Liu, Ting, Editorial Board Member, Sivalingam, Krishna M., Editorial Board Member, Slezak, Dominik, Editorial Board Member, Washio, Takashi, Editorial Board Member, Yang, Xiaokang, Editorial Board Member, Yuan, Junsong, Editorial Board Member, Iliadis, Lazaros, editor, Maglogiannis, Ilias, editor, Alonso, Serafin, editor, Jayne, Chrisina, editor, and Pimenidis, Elias, editor

Published

2023

8. Automatic stress analysis from facial videos based on deep facial action units recognition

Author

Giannakakis, Giorgos, Koujan, Mohammad Rami, Roussos, Anastasios, and Marias, Kostas

Published

2022

9. A new smart-cropping pipeline for prostate segmentation using deep learning networks

Author

Zaridis Dimitris, Mylona Eugenia, Tachos Nikolaos, Marias Kostas, Papanikolaou Nikolaos, Tsiknakis Manolis, and Fotiadis Dimitrios

Subjects

prostate, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, deep learning, ProCAncer-I, image segmentation, U-net, cropping

Abstract

Prostate segmentation from magnetic resonance imaging (MRI) is a challenging task. In recent years, several network architectures have been proposed to automate this process and alleviate the burden of manual annotation. Although the performance of these models has achieved promising results, there is still room for improvement before these models can be used safely and effectively in clinical practice. One of the major challenges in prostate MR image segmentation is the presence of class imbalance in the image labels where the background pixels dominate over the prostate. In the present work we propose a DL-based pipeline for cropping the region around the prostate from MRI images to produce a more balanced distribution of the foreground pixels (prostate) and the background pixels and improve segmentation accuracy. The effect of DL-cropping for improving the segmentation performance compared to standard center- cropping is assessed using five popular DL networks for prostate segmentation, namely U-net, U-net+, Res Unet++, Bridge U-net and Dense U-net. The proposed smart-cropping outperformed the standard center cropping in terms of segmentation accuracy for all the evaluated prostate segmentation networks. In terms of Dice score, the highest improvement was achieved for the U- net+ and ResU-net++ architectures corresponding to 8.9% and 8%, respectively.

Published

2021

10. Deep Learning for the Differential Diagnosis between Transient Osteoporosis and Avascular Necrosis of the Hip.

Author

Klontzas, Michail E., Stathis, Ioannis, Spanakis, Konstantinos, Zibis, Aristeidis H., Marias, Kostas, and Karantanas, Apostolos H.

Subjects

DEEP learning, DIFFERENTIAL diagnosis, CONVOLUTIONAL neural networks, OSTEOPOROSIS, NECROSIS, IDIOPATHIC femoral necrosis, SIGNAL convolution

Abstract

Differential diagnosis between avascular necrosis (AVN) and transient osteoporosis of the hip (TOH) can be complicated even for experienced MSK radiologists. Our study attempted to use MR images in order to develop a deep learning methodology with the use of transfer learning and a convolutional neural network (CNN) ensemble, for the accurate differentiation between the two diseases. An augmented dataset of 210 hips with TOH and 210 hips with AVN was used to finetune three ImageNet-trained CNNs (VGG-16, InceptionResNetV2, and InceptionV3). An ensemble decision was reached in a hard-voting manner by selecting the outcome voted by at least two of the CNNs. Inception-ResNet-V2 achieved the highest AUC (97.62%) similar to the model ensemble, followed by InceptionV3 (AUC of 96.82%) and VGG-16 (AUC 96.03%). Precision for the diagnosis of AVN and recall for the detection of TOH were higher in the model ensemble compared to Inception-ResNet-V2. Ensemble performance was significantly higher than that of an MSK radiologist and a fellow (P < 0.001). Deep learning was highly successful in distinguishing TOH from AVN, with a potential to aid treatment decisions and lead to the avoidance of unnecessary surgery. [ABSTRACT FROM AUTHOR]

Published

2022

11. Deep learning opens new horizons in personalized medicine

Author

Papadakis, Georgios Z., Karantanas, Apostolos H., Tsiknakis, Manolis, Tsatsakis, Aristidis, Spandidos, Demetrios A., and Marias, Kostas

Subjects

deep learning, Review, personalized medicine

Abstract

Although the idea of the personalization of patient care dates back to the time of Hippocrates, recent advances in diagnostic medical imaging and molecular medicine are gradually transforming healthcare services, by offering information and diagnostic tools enabling individualized patient management. Facilitating personalized / precision medicine requires taking into account multiple heterogenous parameters, such as sociodemographics, gene variability, environmental and lifestyle factors. Therefore, one of the most critical challenges in personalized medicine is the need to transform large, multi-modal data into decision support tools, capable of bridging the translational gap to the clinical setting. Towards these challenges, deep learning (DL) provides a novel approach, which enables obtaining or developing high-accuracy, multi-modal predictive models, that allow the implementation of the personalized medicine vision in the near future. DL is a highly effective strategy in addressing these challenges, with DL-based models leading to unprecedented results, matching or even improving state-of-the-art prediction/detection rates based on both intuitive and non-intuitive disease descriptors. These results hold promise for significant socio-economic benefits from the application of DL personalized medicine.

Published

2019

12. ResQu-Net: Effective prostate's peripheral zone segmentation leveraging the representational power of attention-based mechanisms.

Author

Zaridis, Dimitrios I., Mylona, Eugenia, Tachos, Nikolaos, Kalantzopoulos, Charalampos Ν., Marias, Kostas, Tsiknakis, Manolis, Matsopoulos, George K., Koutsouris, Dimitrios D., and Fotiadis, Dimitrios I.

Subjects

PROSTATE, STANDARD deviations, MAGNETIC resonance imaging, DEEP learning

Abstract

• We propose a novel Deep Learning model, namely the ResQu-Net, specifically tailored for Peripheral Zone Segmentation on T2W MR images. • Six DL architectures were implemented and compared using three openly available datasets with 392 patient cases. • Qualitative Explainability Analysis reveals that conventional segmentation metrics, such as Dice Score, and Hausdorff Distance, might not reflect properly the performance of a DL segmentation model. Prostate cancer is a leading cause of male cancer worldwide. With more than 70 % of prostate cancers arising in the peripheral zone of the prostate, accurate segmentation of this region is of paramount importance for the effective diagnosis and treatment of the disease. Although peripheral zone is well recognized as one of the most challenging regions to delineate within the prostate, no algorithms specifically tailored for this segmentation task are currently available. The present study introduces a new deep learning (DL) algorithm, named as ResQu-Net, which is designed to accurately segment the peripheral zone (PZ) of the prostate on T2-weighted magnetic resonance imaging (MRI). Using three publicly available datasets, the ResQu-Net outperformed the six DL segmentation models used for comparison, namely the Attention U-Net, the Dense2U-Net, the Proper-Net, the TransU-net, the U-Net, and the USE-Net, demonstrating superior performance for different anatomical regions, such as the apex, the midgland and the base. The assessment of the suggested approach was conducted not only quantitatively (Sensitivity, Balanced Accuracy, Dice Score, 95 % Hausdorff Distance, and Average Surface Distance) but also qualitatively. For the qualitative evaluation the feature maps obtained from the last layers of each model were compared with the Density Map of the Ground Truth annotations using root mean squared error. Overall, the ResQu-Net model exhibits improved performance compared to other models, of more than 5 % and 1.87 mm in terms of Dice Score and 95 % Hausdorff Distance, respectively. These advancements may contribute significantly in addressing the challenges associated with PZ segmentation, and ultimately enabling improved clinical decision-making and patient outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

13. Pollen Grain Classification Based on Ensemble Transfer Learning on the Cretan Pollen Dataset.

Author

Tsiknakis, Nikos, Savvidaki, Elisavet, Manikis, Georgios C., Gotsiou, Panagiota, Remoundou, Ilektra, Marias, Kostas, Alissandrakis, Eleftherios, and Vidakis, Nikolas

Abstract

Pollen identification is an important task for the botanical certification of honey. It is performed via thorough microscopic examination of the pollen present in honey; a process called melissopalynology. However, manual examination of the images is hard, time-consuming and subject to inter- and intra-observer variability. In this study, we investigated the applicability of deep learning models for the classification of pollen-grain images into 20 pollen types, based on the Cretan Pollen Dataset. In particular, we applied transfer and ensemble learning methods to achieve an accuracy of 97.5%, a sensitivity of 96.9%, a precision of 97%, an F1 score of 96.89% and an AUC of 0.9995. However, in a preliminary case study, when we applied the best-performing model on honey-based pollen-grain images, we found that it performed poorly; only 0.02 better than random guessing (i.e., an AUC of 0.52). This indicates that the model should be further fine-tuned on honey-based pollen-grain images to increase its effectiveness on such data. [ABSTRACT FROM AUTHOR]

Published

2022

14. The Constantly Evolving Role of Medical Image Processing in Oncology: From Traditional Medical Image Processing to Imaging Biomarkers and Radiomics.

Author

Marias, Kostas

Subjects

BIOMARKERS, RADIOMICS, DIAGNOSTIC imaging, IMAGE processing, CANCER diagnosis, DEEP learning

Abstract

The role of medical image computing in oncology is growing stronger, not least due to the unprecedented advancement of computational AI techniques, providing a technological bridge between radiology and oncology, which could significantly accelerate the advancement of precision medicine throughout the cancer care continuum. Medical image processing has been an active field of research for more than three decades, focusing initially on traditional image analysis tasks such as registration segmentation, fusion, and contrast optimization. However, with the advancement of model-based medical image processing, the field of imaging biomarker discovery has focused on transforming functional imaging data into meaningful biomarkers that are able to provide insight into a tumor's pathophysiology. More recently, the advancement of high-performance computing, in conjunction with the availability of large medical imaging datasets, has enabled the deployment of sophisticated machine learning techniques in the context of radiomics and deep learning modeling. This paper reviews and discusses the evolving role of image analysis and processing through the lens of the abovementioned developments, which hold promise for accelerating precision oncology, in the sense of improved diagnosis, prognosis, and treatment planning of cancer. [ABSTRACT FROM AUTHOR]

Published

2021

15. Segmenting 20 Types of Pollen Grains for the Cretan Pollen Dataset v1 (CPD-1).

Author

Tsiknakis, Nikos, Savvidaki, Elisavet, Kafetzopoulos, Sotiris, Manikis, Georgios, Vidakis, Nikolas, Marias, Kostas, and Alissandrakis, Eleftherios

Subjects

PALYNOLOGY, DEEP learning, POLLEN, PLANT species, MACHINE learning, GRAIN

Abstract

Pollen analysis and the classification of several pollen species is an important task in melissopalynology. The development of machine learning or deep learning based classification models depends on available datasets of pollen grains from various plant species from around the globe. In this paper, Cretan Pollen Dataset v1 (CPD-1) is presented, which is a novel dataset of grains from 20 pollen species from plants gathered in Crete, Greece. The pollen grains were prepared and stained with fuchsin, in order to be captured by a camera attached to a microscope under a × 400 magnification. In addition, a pollen grain segmentation method is presented, which segments and crops each unique pollen grain and achieved an overall detection accuracy of 92%. The final dataset comprises 4034 segmented pollen grains of 20 different pollen species, as well as the raw data and ground truth, as annotated by an expert. The developed dataset is publicly accessible, which we hope will accelerate research in melissopalynology. [ABSTRACT FROM AUTHOR]

Published

2021

16. Pathomics and Deep Learning Classification of a Heterogeneous Fluorescence Histology Image Dataset.

Author

Ioannidis, Georgios S., Trivizakis, Eleftherios, Metzakis, Ioannis, Papagiannakis, Stilianos, Lagoudaki, Eleni, Marias, Kostas, Di Ruberto, Cecilia, Loddo, Andrea, and Putzu, Lorenzo

Subjects

DEEP learning, FLUORESCENCE, STEREOLOGY, MACHINE learning, CLASSIFICATION, HISTOLOGY

Abstract

Automated pathology image classification through modern machine learning (ML) techniques in quantitative microscopy is an emerging AI application area aiming to alleviate the increased workload of pathologists and improve diagnostic accuracy and consistency. However, there are very few efforts focusing on fluorescence histology image data, which is a challenging task, not least due to the variable imaging acquisition parameters in pooled data, which can diminish the performance of ML-based decision support tools. To this end, this study introduces a harmonization preprocessing protocol for image classification within a heterogeneous fluorescence dataset in terms of image acquisition parameters and presents two state-of-the-art feature-based approaches for differentiating three classes of nuclei labelled by an expert based on (a) pathomics analysis scoring an accuracy (ACC) up to 0.957 ± 0.105, and, (b) transfer learning model exhibiting ACC up-to 0.951 ± 0.05. The proposed analysis pipelines offer good differentiation performance in the examined fluorescence histology image dataset despite the heterogeneity due to the lack of a standardized image acquisition protocol. [ABSTRACT FROM AUTHOR]

Published

2021

17. Emerging deep learning techniques using magnetic resonance imaging data applied in multiple sclerosis and clinical isolated syndrome patients (Review).

Author

Kontopodis, Eleftherios E., Papadaki, Efrosini, Trivizakis, Eleftherios, Maris, Thomas G., Simos, Panagiotis, Papadakis, Georgios Z., Tsatsakis, Aristidis, Spandidos, Demetrios A., Karantanas, Apostolos, and Marias, Kostas

Subjects

MAGNETIC resonance imaging, DEEP learning, COMPUTER-aided diagnosis, MULTIPLE sclerosis, CENTRAL nervous system diseases, POLYNEUROPATHIES

Abstract

Computer-aided diagnosis systems aim to assist clinicians in the early identification of abnormal signs in order to optimize the interpretation of medical images and increase diagnostic precision. Multiple sclerosis (MS) and clinically isolated syndrome (CIS) are chronic inflammatory, demyelinating diseases affecting the central nervous system. Recent advances in deep learning (DL) techniques have led to novel computational paradigms in MS and CIS imaging designed for automatic segmentation and detection of areas of interest and automatic classification of anatomic structures, as well as optimization of neuroimaging protocols. To this end, there are several publications presenting artificial intelligence-based predictive models aiming to increase diagnostic accuracy and to facilitate optimal clinical management in patients diagnosed with MS and/or CIS. The current study presents a thorough review covering DL techniques that have been applied in MS and CIS during recent years, shedding light on their current advances and limitations. [ABSTRACT FROM AUTHOR]

Published

2021

18. Advancing COVID-19 differentiation with a robust preprocessing and integration of multi-institutional open-repository computer tomography datasets for deep learning analysis.

Author

Trivizakis, Eleftherios, Tsiknakis, Nikos, Vassalou, Evangelia E., Papadakis, Georgios Z., Spandidos, Demetrios A., Sarigiannis, Dimosthenis, Tsatsakis, Aristidis, Papanikolaou, Nikolaos, Karantanas, Apostolos H., and Marias, Kostas

Subjects

COVID-19, COVID-19 pandemic, DEEP learning, TOMOGRAPHY, IMAGE analysis, PICTURE archiving & communication systems

Abstract

The coronavirus pandemic and its unprecedented consequences globally has spurred the interest of the artificial intelligence research community. A plethora of published studies have investigated the role of imaging such as chest X-rays and computer tomography in coronavirus disease 2019 (COVID-19) automated diagnosis. Οpen repositories of medical imaging data can play a significant role by promoting cooperation among institutes in a world-wide scale. However, they may induce limitations related to variable data quality and intrinsic differences due to the wide variety of scanner vendors and imaging parameters. In this study, a state-of-the-art custom U-Net model is presented with a dice similarity coefficient performance of 99.6% along with a transfer learning VGG-19 based model for COVID-19 versus pneumonia differentiation exhibiting an area under curve of 96.1%. The above was significantly improved over the baseline model trained with no segmentation in selected tomographic slices of the same dataset. The presented study highlights the importance of a robust preprocessing protocol for image analysis within a heterogeneous imaging dataset and assesses the potential diagnostic value of the presented COVID-19 model by comparing its performance to the state of the art. [ABSTRACT FROM AUTHOR]

Published

2020

19. Musculoskeletal trauma imaging in the era of novel molecular methods and artificial intelligence.

Author

Klontzas, Michail E., Papadakis, Georgios Z., Marias, Kostas, and Karantanas, Apostolos H.

Subjects

*DIFFUSION magnetic resonance imaging, *ARTIFICIAL intelligence, *DIFFUSION tensor imaging, *COMPUTER-assisted image analysis (Medicine), *SOFT tissue injuries, *SPORTS injuries, *MUSCULOSKELETAL system diseases, *MAGNETIC resonance imaging, *ALGORITHMS

Abstract

Over the past decade rapid advancements in molecular imaging (MI) and artificial intelligence (AI) have revolutionized traditional musculoskeletal radiology. Molecular imaging refers to the ability of various methods to in vivo characterize and quantify biological processes, at a molecular level. The extracted information provides the tools to understand the pathophysiology of diseases and thus to early detect, to accurately evaluate the extend and to apply and evaluate targeted treatments. At present, molecular imaging mainly involves CT, MRI, radionuclide, US, and optical imaging and has been reported in many clinical and preclinical studies. Although originally MI techniques targeted at central nervous system disorders, later on their value on musculoskeletal disorders was also studied in depth. Meaningful exploitation of the large volume of imaging data generated by molecular and conventional imaging techniques, requires state-of-the-art computational methods that enable rapid handling of large volumes of information. AI allows end-to-end training of computer algorithms to perform tasks encountered in everyday clinical practice including diagnosis, disease severity classification and image optimization. Notably, the development of deep learning algorithms has offered novel methods that enable intelligent processing of large imaging datasets in an attempt to automate decision-making in a wide variety of settings related to musculoskeletal trauma. Current applications of AI include the diagnosis of bone and soft tissue injuries, monitoring of the healing process and prediction of injuries in the professional sports setting. This review presents the current applications of novel MI techniques and methods and the emerging role of AI regarding the diagnosis and evaluation of musculoskeletal trauma. [ABSTRACT FROM AUTHOR]

Published

2020