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19 results on '"Daniele M. Papetti"'

1. Large T cell clones expressing immune checkpoints increase during multiple myeloma evolution and predict treatment resistance

Author

Cirino Botta, Cristina Perez, Marta Larrayoz, Noemi Puig, Maria-Teresa Cedena, Rosalinda Termini, Ibai Goicoechea, Sara Rodriguez, Aintzane Zabaleta, Aitziber Lopez, Sarai Sarvide, Laura Blanco, Daniele M. Papetti, Marco S. Nobile, Daniela Besozzi, Massimo Gentile, Pierpaolo Correale, Sergio Siragusa, Albert Oriol, Maria Esther González-Garcia, Anna Sureda, Felipe de Arriba, Rafael Rios Tamayo, Jose-Maria Moraleda, Mercedes Gironella, Miguel T. Hernandez, Joan Bargay, Luis Palomera, Albert Pérez-Montaña, Hartmut Goldschmidt, Hervé Avet-Loiseau, Aldo Roccaro, Alberto Orfao, Joaquin Martinez-Lopez, Laura Rosiñol, Juan-José Lahuerta, Joan Blade, Maria-Victoria Mateos, Jesús F. San-Miguel, Jose-Angel Martinez Climent, Bruno Paiva, the Programa Para el Estudio de la Terapéutica en Hemopatías Malignas/Grupo Español de Mieloma (PETHEMA/GEM) cooperative group, and the iMMunocell study group

Subjects
Science
Abstract

Abstract Tumor recognition by T cells is essential for antitumor immunity. A comprehensive characterization of T cell diversity may be key to understanding the success of immunomodulatory drugs and failure of PD-1 blockade in tumors such as multiple myeloma (MM). Here, we use single-cell RNA and T cell receptor sequencing to characterize bone marrow T cells from healthy adults (n = 4) and patients with precursor (n = 8) and full-blown MM (n = 10). Large T cell clones from patients with MM expressed multiple immune checkpoints, suggesting a potentially dysfunctional phenotype. Dual targeting of PD-1 + LAG3 or PD-1 + TIGIT partially restored their function in mice with MM. We identify phenotypic hallmarks of large intratumoral T cell clones, and demonstrate that the CD27− and CD27+ T cell ratio, measured by flow cytometry, may serve as a surrogate of clonal T cell expansions and an independent prognostic factor in 543 patients with MM treated with lenalidomide-based treatment combinations.

Published
2023
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2. Barcode demultiplexing of nanopore sequencing raw signals by unsupervised machine learning

Author

Daniele M. Papetti, Simone Spolaor, Iman Nazari, Andrea Tirelli, Tommaso Leonardi, Chiara Caprioli, Daniela Besozzi, Thalia Vlachou, Pier Giuseppe Pelicci, Paolo Cazzaniga, and Marco S. Nobile

Subjects
nanopore, unsupervised learning, autoencoder, self-organising map, complexity reduction, RNA barcoding, Computer applications to medicine. Medical informatics, R858-859.7
Abstract

Introduction: Oxford Nanopore Technologies (ONT) is a third generation sequencing approach that allows the analysis of individual, full-length nucleic acids. ONT records the alterations of an ionic current flowing across a nano-scaled pore while a DNA or RNA strand is threading through the pore. Basecalling methods are then leveraged to translate the recorded signal back to the nucleic acid sequence. However, basecall generally introduces errors that hinder the process of barcode demultiplexing, a pivotal task in single-cell RNA sequencing that allows for separating the sequenced transcripts on the basis of their cell of origin.Methods: To solve this issue, we present a novel framework, called UNPLEX, designed to tackle the barcode demultiplexing problem by operating directly on the recorded signals. UNPLEX combines two unsupervised machine learning methods: autoencoders and self-organizing maps (SOM). The autoencoders extract compact, latent representations of the recorded signals that are then clustered by the SOM.Results and Discussion: Our results, obtained on two datasets composed of in silico generated ONT-like signals, show that UNPLEX represents a promising starting point for the development of effective tools to cluster the signals corresponding to the same cell.

Published
2023
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3. Shaping and Dilating the Fitness Landscape for Parameter Estimation in Stochastic Biochemical Models

Author

Marco S. Nobile, Daniele M. Papetti, Simone Spolaor, Paolo Cazzaniga, and Luca Manzoni

Subjects
parameter estimation, fitness landscape manipulation, stochastic simulation, biochemical models, Fourier surrogate modeling, dilation functions, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

The parameter estimation (PE) of biochemical reactions is one of the most challenging tasks in systems biology given the pivotal role of these kinetic constants in driving the behavior of biochemical systems. PE is a non-convex, multi-modal, and non-separable optimization problem with an unknown fitness landscape; moreover, the quantities of the biochemical species appearing in the system can be low, making biological noise a non-negligible phenomenon and mandating the use of stochastic simulation. Finally, the values of the kinetic parameters typically follow a log-uniform distribution; thus, the optimal solutions are situated in the lowest orders of magnitude of the search space. In this work, we further elaborate on a novel approach to address the PE problem based on a combination of adaptive swarm intelligence and dilation functions (DFs). DFs require prior knowledge of the characteristics of the fitness landscape; therefore, we leverage an alternative solution to evolve optimal DFs. On top of this approach, we introduce surrogate Fourier modeling to simplify the PE, by producing a smoother version of the fitness landscape that excludes the high frequency components of the fitness function. Our results show that the PE exploiting evolved DFs has a performance comparable with that of the PE run with a custom DF. Moreover, surrogate Fourier modeling allows for improving the convergence speed. Finally, we discuss some open problems related to the scalability of our methodology.

Published
2022
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4. Surfing on Fitness Landscapes: A Boost on Optimization by Fourier Surrogate Modeling

Author

Luca Manzoni, Daniele M. Papetti, Paolo Cazzaniga, Simone Spolaor, Giancarlo Mauri, Daniela Besozzi, and Marco S. Nobile

Subjects
global optimization, particle swarm optimization, fuzzy self-tuning pso, fourier transform, surrogate modeling, Science, Astrophysics, QB460-466, Physics, QC1-999
Abstract

Surfing in rough waters is not always as fun as wave riding the “big one”. Similarly, in optimization problems, fitness landscapes with a huge number of local optima make the search for the global optimum a hard and generally annoying game. Computational Intelligence optimization metaheuristics use a set of individuals that “surf” across the fitness landscape, sharing and exploiting pieces of information about local fitness values in a joint effort to find out the global optimum. In this context, we designed surF, a novel surrogate modeling technique that leverages the discrete Fourier transform to generate a smoother, and possibly easier to explore, fitness landscape. The rationale behind this idea is that filtering out the high frequencies of the fitness function and keeping only its partial information (i.e., the low frequencies) can actually be beneficial in the optimization process. We prove our theory by combining surF with a settings free variant of Particle Swarm Optimization (PSO) based on Fuzzy Logic, called Fuzzy Self-Tuning PSO. Specifically, we introduce a new algorithm, named F3ST-PSO, which performs a preliminary exploration on the surrogate model followed by a second optimization using the actual fitness function. We show that F3ST-PSO can lead to improved performances, notably using the same budget of fitness evaluations.

Published
2020
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15. 506 TECHNIQUES OF ARTIFICIAL INTELLIGENCE FOR THE DETERMINATION OF THE OPTIMAL INVERSION TIME: THE THAITI PROJECT

Author

Camilla Torlasco, Daniele M Papetti, Maria Sabatini, Giuseppe Muscogiuri, Silvia Castelletti, Hui Xue, Peter Kellman, Gianfranco Parati, Luigi P Badano, Marco S Nobile, and Daniela Besozzi

Subjects
Cardiology and Cardiovascular Medicine
Abstract

Introduction Identifying the optimal Inversion Time (TI) is pivotal to null the myocardium and obtain high quality cardiac magnetic resonance (CMR) late gadolinium enhancement (LGE) imaging. Setting the optimal TI can be challenging in some diseases and for less experienced operators. We propose an Artificial Intelligence (AI) tool to automatically predict the optimal TI in CMR-LGE imaging. Methods The AI tool, named THAITI, consists of a Random Forest regression model whose hyperparametrs were optimized by means of evolutionary computation. The model considers as input parameters patient-specific TI determinants, such as age, gender, weight, height, kidney function, heart rate, contrast dose, and time from injection to image acquisition. THAITI was trained on 155 patients (2588 CMR-LGE images) with mixed cardiac conditions who underwent CMR (1.5T Siemens AvantoFit; Gadovist; averaged, motion-corrected, free-breathing true-FISP IR). Clinical testing was performed on 55 matched patients, randomized to experimental (THAITI-set TI) vs control (experienced operator-set TI) group. A user interface was developed for clinical testing. Image quality was assessed blindly by 2 independent experienced operators. Results THAITI Mean Squared Error (MSE) in the validation set was 4.7 and percentage of mispredicted TI of 4.5%. During clinical testing, LGE quality did not differ between the experimental vs control group: quality was “optimal” or “good” in 96% vs 93%, “poor” in 4% vs 7%. The average number of LGE images acquired and LGE imaging duration were similar (experimental vs control group: 17 ± 3 vs 16 ± 3 LGE images per patient; 12:14 vs 12:20 mm:ss, respectively). Conclusion THAITI efficiently predicts optimal TI for CMR-LGE imaging. Further development is needed to increase generalizability (multi-vendor, multi-sequence, multi-contrast) and to test its potential to improve LGE image quality and reduce the need for repeated imaging for inexperienced operators. Figure 1. Top panel: THAITI interface. Bottom panel: examples of experimental group LGE imaging. Table 1. Control vs experimental group. Data expressed as absolute number (%), mean ±SD

Published
2022
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16. An accurate and time-efficient deep learning-based system for automated segmentation and reporting of cardiac magnetic resonance-detected ischemic scar

Author

Daniele M Papetti, Kirsten Van Abeelen, Rhodri Davies, Roberto Menè, Francesca Heilbron, Francesco P Perelli, Jessica Artico, Andreas Seraphim, James C Moon, Gianfranco Parati, Hui Xue, Peter Kellman, Luigi P Badano, Daniela Besozzi, Marco S Nobile, Camilla Torlasco, Papetti, D, Van Abeelen, K, Davies, R, Menè, R, Heilbron, F, Perelli, F, Artico, J, Seraphim, A, Moon, J, Parati, G, Xue, H, Kellman, P, Badano, L, Besozzi, D, Nobile, M, and Torlasco, C

Subjects
Cardiac magnetic resonance, Cardiovascular imaging, Deep learning, Image processing, Myocardial ischemic scar, Settore INF/01 - Informatica, Settore MED/36 - Diagnostica per Immagini e Radioterapia, INF/01 - INFORMATICA, Health Informatics, MED/11 - MALATTIE DELL'APPARATO CARDIOVASCOLARE, Software, Computer Science Applications
Abstract

Background and objectives: Myocardial infarction scar (MIS) assessment by cardiac magnetic resonance provides prognostic information and guides patients’ clinical management. However, MIS segmentation is time-consuming and not performed routinely. This study presents a deep-learning-based computational workflow for the segmentation of left ventricular (LV) MIS, for the first time performed on state-of-the-art dark-blood late gadolinium enhancement (DB-LGE) images, and the computation of MIS transmurality and extent. Methods: DB-LGE short-axis images of consecutive patients with myocardial infarction were acquired at 1.5T in two centres between Jan 1, 2019, and June 1, 2021. Two convolutional neural network (CNN) models based on the U-Net architecture were trained to sequentially segment the LV and MIS, by processing an incoming series of DB-LGE images. A 5-fold cross-validation was performed to assess the performance of the models. Model outputs were compared respectively with manual (LV endo- and epicardial border) and semi-automated (MIS, 4-Standard Deviation technique) ground truth to assess the accuracy of the segmentation. An automated post-processing and reporting tool was developed, computing MIS extent (expressed as relative infarcted mass) and transmurality. Results: The dataset included 1355 DB-LGE short-axis images from 144 patients (MIS in 942 images). High performance (> 0.85) as measured by the Intersection over Union metric was obtained for both the LV and MIS segmentations on the training sets. The performance for both LV and MIS segmentations was 0.83 on the test sets. Compared to the 4-Standard Deviation segmentation technique, our system was five times quicker (

Published
2022

17. Dark blood ischemic LGE segmentation using a deep learning approach

Author

Jessica Artico, Peter Kellman, R Mene, Marco S. Nobile, Luigi P. Badano, Andreas Seraphim, James C. Moon, Daniele M. Papetti, Gianfranco Parati, Camilla Torlasco, Hui Xue, Torlasco, C, Papetti, D, Mene, R, Artico, J, Seraphim, A, Badano, L, Moon, J, Parati, G, Xue, H, Kellman, P, and Nobile, M

Subjects
medicine.medical_specialty, Short axis, Settore INF/01 - Informatica, myocardium, ischemia, architecture, cicatrix, heart, cardiac mri, health care decision making, convolutional neural networks, business.industry, Deep learning, Ischemia, Settore MED/11 - Malattie dell'Apparato Cardiovascolare, General Medicine, medicine.disease, Linear gingival erythema, Internal medicine, Dark blood, Cardiology, Medicine, Radiology, Nuclear Medicine and imaging, Segmentation, Artificial intelligence, Cardiology and Cardiovascular Medicine, business
Abstract

Funding Acknowledgements Type of funding sources: None. Introduction The extent of ischemic scar detected by Cardiac Magnetic Resonance (CMR) with late gadolinium enhancement (LGE) is linked with long-term prognosis, but scar quantification is time-consuming. Deep Learning (DL) approaches appear promising in CMR segmentation. Purpose: To train and apply a deep learning approach to dark blood (DB) CMR-LGE for ischemic scar segmentation, comparing results to 4-Standard Deviation (4-SD) semi-automated method. Methods: We trained and validated a dual neural network infrastructure on a dataset of DB-LGE short-axis stacks, acquired at 1.5T from 33 patients with ischemic scar. The DL architectures were an evolution of the U-Net Convolutional Neural Network (CNN), using data augmentation to increase generalization. The CNNs worked together to identify and segment 1) the myocardium and 2) areas of LGE. The first CNN simultaneously cropped the region of interest (RoI) according to the bounding box of the heart and calculated the area of myocardium. The cropped RoI was then processed by the second CNN, which identified the overall LGE area. The extent of scar was calculated as the ratio of the two areas. For comparison, endo- and epi-cardial borders were manually contoured and scars segmented by a 4-SD technique with a validated software. Results: The two U-Net networks were implemented with two free and open-source software library for machine learning. We performed 5-fold cross-validation over a dataset of 108 and 385 labelled CMR images of the myocardium and scar, respectively. We obtained high performance (> ∼0.85) as measured by the Intersection over Union metric (IoU) on the training sets, in the case of scar segmentation. With regards to heart recognition, the performance was lower (> ∼0.7), although improved (∼ 0.75) by detecting the cardiac area instead of heart boundaries. On the validation set, performances oscillated between 0.8 and 0.85 for scar tissue recognition, and dropped to ∼0.7 for myocardium segmentation. We believe that underrepresented samples and noise might be affecting the overall performances, so that additional data might be beneficial. Figure1: examples of heart segmentation (upper left panel: training; upper right panel: validation) and of scar segmentation (lower left panel: training; lower right panel: validation). Conclusion: Our CNNs show promising results in automatically segmenting LV and quantify ischemic scars on DB-LGE-CMR images. The performances of our method can further improve by expanding the data set used for the training. If implemented in a clinical routine, this process can speed up the CMR analysis process and aid in the clinical decision-making. Abstract Figure.

Published
2021
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18. On the automatic calibration of fully analogical spiking neuromorphic chips

Author

Marco S. Nobile, Marco Antoniotti, Simone Spolaor, Daniela Besozzi, Paolo Cazzaniga, Daniele M. Papetti, Papetti, D, Spolaor, S, Besozzi, D, Cazzaniga, P, Antoniotti, M, Nobile, M, and Information Systems IE&IS

Subjects
Computer science, Topology (electrical circuits), Spikey, 02 engineering and technology, PyNN, Fuzzy Self-Tuning PSO, modeling and simulation, global op-timization, 0202 electrical engineering, electronic engineering, information engineering, Membrane potential, Artificial neural network, Settore INF/01 - Informatica, swarm intelligence, global optimization, 05 social sciences, 050301 education, Complex network, neural networks, neuromorphic chip, Neuromorphic engineering, Computer engineering, 020201 artificial intelligence & image processing, Spikey, neuromorphic chip, neural networks, PyNN, Fuzzy Self-Tuning PSO, swarm intelligence, global optimization, modeling and simulation, 0503 education, Biological network
Abstract

Nowadays, understanding the topology of biological neural networks and sampling their activity is possible thanks to various laboratory protocols that provide a large amount of experimental data, thus paving the way to accurate modeling and simulation. Neuromorphic systems were developed to simulate the dynamics of biological neural networks by means of electronic circuits, offering an efficient alternative to classic simulations based on systems of differential equations, from both the points of view of the energy consumed and the overall computational effort. Spikey is a configurable neuromorphic chip based on the Leaky Integrate-And-Fire model, which gives the user the possibility to model an arbitrary neural topology and simulate the temporal evolution of membrane potentials. To accurately reproduce the behavior of a specific biological network, a detailed parameterization of all neurons in the neuromorphic chip is necessary. Determining such parameters is a hard, error-prone, and generally time consuming task. In this work, we propose a novel methodology for the automatic calibration of neuromorphic chips that exploits a given neural activity as target. Our results show that, in the case of small networks with a low complexity, the method can estimate a vector of parameters capable of reproducing the target activity. Conversely, in the case of more complex networks, the simulations with Spikey can be highly affected by noise, which causes small variations in the simulations outcome even when identical networks are simulated, hindering the convergence to optimal parameterizations.

Published
2020

19. Which random is the best random? A study on sampling methods in Fourier surrogate modeling

Author

Daniela Besozzi, Marco S. Nobile, Daniele M. Papetti, Paolo Cazzaniga, Daniel Ashlock, Luca Manzoni, Simone Spolaor, Information Systems IE&IS, Nobile, M, Spolaor, S, Cazzaniga, P, Papetti, D, Besozzi, D, Ashlock, D, and Manzoni, L

Subjects
quasi-random numbers generation, Computer science, Fitness landscape, chaotic system, 0211 other engineering and technologies, Computational intelligence, 02 engineering and technology, quantum computing, Fuzzy Self-Tuning PSO, logistic map, symbols.namesake, Local optimum, 0202 electrical engineering, electronic engineering, information engineering, Global optimization, Pseudorandom number generator, 021103 operations research, Settore INF/01 - Informatica, global optimization, Sampling (statistics), chaotic systems, surrogate modeling, point packing, Fourier transform, symbols, 020201 artificial intelligence & image processing, Logistic map, Algorithm, pseudo-random numbers generation
Abstract

Global optimization problems can be effectively solved by means of Computational Intelligence methods. However, there are several areas in which the effectiveness of these algorithms can be hampered by the computational costs of the fitness evaluations, or by specific features of the fitness landscape that can be characterized by noise and by the presence of several (even infinite) local optima. These issues bring about the necessity of defining specific techniques to replace the original problem with a surrogate representation. Fourier surrogate modeling represents a novel and effective approach to generate smoother, and possibly easier to explore, fitness landscapes, and to reduce the computational effort. Fourier surrogates require an initial sampling of the search space that must be performed to calculate the Fourier transforms. In this paper we investigate the impact on the quality of the surrogate models of the hyper-parameters of the methodology, and of several methods that can be employed for the initial sampling of the fitness landscape (i.e., pseudorandom numbers, low discrepancy sequences, a logistic map in chaotic regime, true random positions generated by a quantum computer, and point packing). Our results show that semistructured approaches like quasi-random sequences and point packing can outperform the other sampling methods.

Published
2020

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