Your search keyword '"SGHEDONI ROBERTO"' showing total 4 results

1. Stability of radiomic features in magnetic resonance imaging of the female pelvis: A multicentre phantom study

Author

Sghedoni, Roberto, Origgi, Daniela, Cucurachi, Noemi, Minischetti, Giuseppe Castiglioni, Alio, Davide, Savini, Giovanni, Botta, Francesca, Marzi, Simona, Aiello, Marco, Rancati, Tiziana, Cusumano, Davide, Politi, Letterio Salvatore, Didonna, Vittorio, Massafra, Raffaella, Petrillo, Antonella, Esposito, Antonio, Imparato, Sara, Anemoni, Luca, Bortolotto, Chandra, Preda, Lorenzo, and Boldrini, Luca

Published

2025

2. Using MRI Texture Analysis Machine Learning Models to Assess Graft Interstitial Fibrosis and Tubular Atrophy in Patients with Transplanted Kidneys.

Author

Trojani, Valeria, Monelli, Filippo, Besutti, Giulia, Bertolini, Marco, Verzellesi, Laura, Sghedoni, Roberto, Iori, Mauro, Ligabue, Guido, Pattacini, Pierpaolo, Giorgi Rossi, Paolo, Ottone, Marta, Piccinini, Alessia, Alfano, Gaetano, Donati, Gabriele, and Fontana, Francesco

Subjects

MACHINE learning, TEXTURE analysis (Image processing), KIDNEY cortex, FEATURE selection, RENAL biopsy

Abstract

Objective: Interstitial fibrosis/tubular atrophy (IFTA) is a common, irreversible, and progressive form of chronic kidney allograft injury, and it is considered a critical predictor of kidney allograft outcomes. The extent of IFTA is estimated through a graft biopsy, while a non-invasive test is lacking. The aim of this study was to evaluate the feasibility and accuracy of an MRI radiomic-based machine learning (ML) algorithm to estimate the degree of IFTA in a cohort of transplanted patients. Approach: Patients who underwent MRI and renal biopsy within a 6-month interval from 1 January 2012 to 1 March 2021 were included. Stable MRI sequences were selected, and renal parenchyma, renal cortex and medulla were segmented. After image filtering and pre-processing, we computed radiomic features that were subsequently selected through a LASSO algorithm for their highest correlation with the outcome and lowest intercorrelation. Selected features and relevant patients' clinical data were used to produce ML algorithms using 70% of the study cases for feature selection, model training and validation with a 10-fold cross-validation, and 30% for model testing. Performances were evaluated using AUC with 95% confidence interval. Main results: A total of 70 coupled tests (63 patients, 35.4% females, mean age 52.2 years) were included and subdivided into a wider cohort of 50 for training and a smaller cohort of 20 for testing. For IFTA ≥ 25%, the AUCs in test cohort were 0.60, 0.59, and 0.54 for radiomic features only, clinical variables only, and a combined radiomic–clinical model, respectively. For IFTA ≥ 50%, the AUCs in training cohort were 0.89, 0.84, and 0.96, and in the test cohort, they were 0.82, 0.83, and 0.86, for radiomic features only, clinical variables only, and the combined radiomic–clinical model, respectively. Significance: An ML-based MRI radiomic algorithm showed promising discrimination capacity for IFTA > 50%, especially when combined with clinical variables. These results need to be confirmed in larger cohorts. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mortality Prediction of COVID-19 Patients Using Radiomic and Neural Network Features Extracted from a Wide Chest X-ray Sample Size: A Robust Approach for Different Medical Imbalanced Scenarios.

Author

Iori, Mauro, Di Castelnuovo, Carlo, Verzellesi, Laura, Meglioli, Greta, Lippolis, Davide Giosuè, Nitrosi, Andrea, Monelli, Filippo, Besutti, Giulia, Trojani, Valeria, Bertolini, Marco, Botti, Andrea, Castellani, Gastone, Remondini, Daniel, Sghedoni, Roberto, Croci, Stefania, and Salvarani, Carlo

Subjects

COVID-19, PROGNOSTIC models, X-rays, FEATURE extraction, FEATURE selection, DEATH forecasting, CHEST tubes

Abstract

Aim: The aim of this study was to develop robust prognostic models for mortality prediction of COVID-19 patients, applicable to different sets of real scenarios, using radiomic and neural network features extracted from chest X-rays (CXRs) with a certified and commercially available software. Methods: 1816 patients from 5 different hospitals in the Province of Reggio Emilia were included in the study. Overall, 201 radiomic features and 16 neural network features were extracted from each COVID-19 patient's radiography. The initial dataset was balanced to train the classifiers with the same number of dead and survived patients, randomly selected. The pipeline had three main parts: balancing procedure; three-step feature selection; and mortality prediction with radiomic features through three machine learning (ML) classification models: AdaBoost (ADA), Quadratic Discriminant Analysis (QDA) and Random Forest (RF). Five evaluation metrics were computed on the test samples. The performance for death prediction was validated on both a balanced dataset (Case 1) and an imbalanced dataset (Case 2). Results: accuracy (ACC), area under the ROC-curve (AUC) and sensitivity (SENS) for the best classifier were, respectively, 0.72 ± 0.01, 0.82 ± 0.02 and 0.84 ± 0.04 for Case 1 and 0.70 ± 0.04, 0.79 ± 0.03 and 0.76 ± 0.06 for Case 2. These results show that the prediction of COVID-19 mortality is robust in a different set of scenarios. Conclusions: Our large and varied dataset made it possible to train ML algorithms to predict COVID-19 mortality using radiomic and neural network features of CXRs. [ABSTRACT FROM AUTHOR]

Published

2022

4. Artificial intelligence applications in medical imaging: A review of the medical physics research in Italy.

Author

Avanzo, Michele, Porzio, Massimiliano, Lorenzon, Leda, Milan, Lisa, Sghedoni, Roberto, Russo, Giorgio, Massafra, Raffaella, Fanizzi, Annarita, Barucci, Andrea, Ardu, Veronica, Branchini, Marco, Giannelli, Marco, Gallio, Elena, Cilla, Savino, Tangaro, Sabina, Lombardi, Angela, Pirrone, Giovanni, De Martin, Elena, Giuliano, Alessia, and Belmonte, Gina

Abstract

• A systematic search for papers on applications of AI to medical imaging in Italy was performed. • 168 research papers were selected 65% using machine learning, 35% deep learning. • A rapid increase of interest in AI was observed in the last years. • Further collaborations, initiatives and guidelines are needed to develop the research on AI on Imaging. To perform a systematic review on the research on the application of artificial intelligence (AI) to imaging published in Italy and identify its fields of application, methods and results. A Pubmed search was conducted using terms Artificial Intelligence, Machine Learning, Deep learning, imaging, and Italy as affiliation, excluding reviews and papers outside time interval 2015–2020. In a second phase, participants of the working group AI4MP on Artificial Intelligence of the Italian Association of Physics in Medicine (AIFM) searched for papers on AI in imaging. The Pubmed search produced 794 results. 168 studies were selected, of which 122 were from Pubmed search and 46 from the working group. The most used imaging modality was MRI (44%) followed by CT(12%) ad radiography/mammography (11%). The most common clinical indication were neurological diseases (29%) and diagnosis of cancer (25%). Classification was the most common task for AI (57%) followed by segmentation (16%). 65% of studies used machine learning and 35% used deep learning. We observed a rapid increase of research in Italy on artificial intelligence in the last 5 years, peaking at 155% from 2018 to 2019. We are witnessing an unprecedented interest in AI applied to imaging in Italy, in a diversity of fields and imaging techniques. Further initiatives are needed to build common frameworks and databases, collaborations among different types of institutions, and guidelines for research on AI. [ABSTRACT FROM AUTHOR]

Published

2021