Your search keyword '"Eleonora Tiribilli"' showing total 5 results

1. Deep Learning-Based Workflow for Bone Segmentation and 3D Modeling in Cone-Beam CT Orthopedic Imaging

Author

Eleonora Tiribilli and Leonardo Bocchi

Subjects

cone beam CT, segmentation, 3D models, bones, orthopedic, neural networks, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

In this study, a deep learning-based workflow designed for the segmentation and 3D modeling of bones in cone beam computed tomography (CBCT) orthopedic imaging is presented. This workflow uses a convolutional neural network (CNN), specifically a U-Net architecture, to perform precise bone segmentation even in challenging anatomical regions such as limbs, joints, and extremities, where bone boundaries are less distinct and densities are highly variable. The effectiveness of the proposed workflow was evaluated by comparing the generated 3D models against those obtained through other segmentation methods, including SegNet, binary thresholding, and graph cut algorithms. The accuracy of these models was quantitatively assessed using the Jaccard index, the Dice coefficient, and the Hausdorff distance metrics. The results indicate that the U-Net-based segmentation consistently outperforms other techniques, producing more accurate and reliable 3D bone models. The user interface developed for this workflow facilitates intuitive visualization and manipulation of the 3D models, enhancing the usability and effectiveness of the segmentation process in both clinical and research settings. The findings suggest that the proposed deep learning-based workflow holds significant potential for improving the accuracy of bone segmentation and the quality of 3D models derived from CBCT scans, contributing to better diagnostic and pre-surgical planning outcomes in orthopedic practice.

Published

2024

2. Innovative Tool for Automatic Detection of Arterial Stenosis on Cone Beam Computed Tomography

Author

Agnese Simoni, Eleonora Barcali, Cosimo Lorenzetto, Eleonora Tiribilli, Vieri Rastrelli, Leonardo Manetti, Cosimo Nardi, Ernesto Iadanza, and Leonardo Bocchi

Subjects

cone beam computed tomography, segmentation, stenosis, software, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Arterial stenosis is one of the main vascular diseases that are treated with minimally invasive surgery approaches. The aim of this study was to provide a tool to support the medical doctor in planning endovascular surgery, allowing the rapid detection of stenotic vessels and the quantification of the stenosis. Skeletonization was used to improve vessels’ visualization. The distance transform was used to obtain a linear representation of the diameter of critical vessels selected by the user. The system also provides an estimate of the exact distance between landmarks on the vascular tree and the occlusion, important information that can be used in the planning of the surgery. The advantage of the proposed tool is to lead the examination on the linear representation of the chosen vessels that are free from tortuous vascular courses and from vessel crossings.

Published

2023

3. A Novel Implementation of Road Mapping from Digital Subtraction Angiography Images

Author

Cosimo Lorenzetto, Ernesto Iadanza, Leonardo Manetti, Leonardo Bocchi, and Eleonora Tiribilli

Subjects

medicine.diagnostic_test, Computer science, business.industry, DSA, Road mapping, Fluoroscopy, Segmentation, Radiology, Digital subtraction angiography, Imaging phantom, medicine, Computer vision, Artificial intelligence, MATLAB, business, Fluoroscopic image, computer, computer.programming_language, Graphical user interface

Abstract

Road Mapping (RM) is a variant of the commonly used Digital Subtraction Angiography (DSA). In this work we propose a Road Mapping algorithm in which the mask is extracted by means of vessels segmentation from DSA images. The algorithm extracts a two-dimensional map consisting of two values (black and white), to be superimposed on the live fluoroscopic image. A dedicated phantom has been created to develop the RM algorithm, simulating a circulatory system. A prototype algorithm is developed in Matlab R2018b in order to reach some preliminary results and compare different techniques. A Qt graphical interface is also developed for a fast and effective use of this new RDA approach to real veterinary fluoroscopies. Two workflows are presented, both succeeding in performing segmentation of the vessel. Their performances are compared and discussed.

Published

2021

4. 3D Vessel Segmentation in CT for Augmented and Virtual Reality

Author

Eleonora Tiribilli, Leonardo Manetti, Leonardo Bocchi, Agnese Simoni, Cosimo Lorenzetto, and Ernesto Iadanza

Subjects

Cone beam computed tomography, Surgical approach, Tissue segmentation, genetic structures, Computer science, business.industry, Ranging, Vessel segmentation, Virtual reality, Cone bean computed radiography, Virtual and Augmented Reality, 3D rendering, Visualization, Segmentation, Computer vision, Artificial intelligence, business

Abstract

Blood vessels 3D rendering has numerous applications, ranging from diagnosis to pre-procedural and surgical approaches as it enriches vessels visualization for the clinician. In this paper, we propose a 3D blood vessels segmentation method designed for use with a cone beam computed tomography (CBCT). The algorithm constitutes a module in the development of an angio-CT visualization system, based on augmented or virtual reality as instruments supporting and improving medical decisions.

Published

2021

5. Modeling of Voltage Imaging for the Study of Action Potential Propagation

Author

Costanza Scortecci, Leonardo Bocchi, Leonardo Sacconi, Francesca Bologna, Michele Sorelli, Eleonora Tiribilli, Pietro Tarchi, and Diletta Pennati

Subjects

Physics, Stack (abstract data type), Action potential, Acoustics, Waveform, Focus (optics), Signal, Action (physics), Exponential function, Voltage

Abstract

Voltage imaging allows to visualize the propagation of the action potential while it propagates in cardiac tissue. In our experiment we acquire a stack of voltage images, using a fluorescence microscope. In this work we focus on the development of a model of the signal and on the estimation of its parameters. We assumed the signal can be represented as the sum of two exponential functions, starting from the instant of activation of the cell. Results indicate the model is able to adequately describe the shape of the waveform, despite the high noise level in the original images.

Published

2019