Your search keyword '"Demi, L."' showing total 20 results

1. Deep learning approaches for automated classification of neonatal lung ultrasound with assessment of human-to-AI interrater agreement.

Author

Fatima N, Khan U, Han X, Zannin E, Rigotti C, Cattaneo F, Dognini G, Ventura ML, and Demi L

Subjects

Humans, Infant, Newborn, Female, Male, Image Interpretation, Computer-Assisted methods, Deep Learning, Lung diagnostic imaging, Ultrasonography methods

Abstract

Neonatal respiratory disorders pose significant challenges in clinical settings, often requiring rapid and accurate diagnostic solutions for effective management. Lung ultrasound (LUS) has emerged as a promising tool to evaluate respiratory conditions in neonates. This evaluation is mainly based on the interpretation of visual patterns (horizontal artifacts, vertical artifacts, and consolidations). Automated interpretation of these patterns can assist clinicians in their evaluations. However, developing AI-based solutions for this purpose is challenging, primarily due to the lack of annotated data and inherent subjectivity in expert interpretations. This study aims to propose an automated solution for the reliable interpretation of patterns in LUS videos of newborns. We employed two distinct strategies. The first strategy is a frame-to-video-level approach that computes frame-level predictions from deep learning (DL) models trained from scratch (F2V-TS) along with fine-tuning pre-trained models (F2V-FT) followed by aggregation of those predictions for video-level evaluation. The second strategy is a direct video classification approach (DV) for evaluating LUS data. To evaluate our methods, we used LUS data from 34 neonatal patients comprising of 70 exams with annotations provided by three expert human operators (3HOs). Results show that within the frame-to-video-level approach, F2V-FT achieved the best performance with an accuracy of 77% showing moderate agreement with the 3HOs. while the direct video classification approach resulted in an accuracy of 72%, showing substantial agreement with the 3HOs, our proposed study lays down the foundation for reliable AI-based solutions for newborn LUS data evaluation., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

2. Lung Ultrasound Spectroscopy Applied to the Differential Diagnosis of Pulmonary Diseases: An In Vivo Multicenter Clinical Study.

Author

Mento F, Perpenti M, Barcellona G, Perrone T, and Demi L

Subjects

Humans, Female, Male, Diagnosis, Differential, Middle Aged, Aged, Image Interpretation, Computer-Assisted methods, Adult, Ultrasonography methods, Lung diagnostic imaging, Lung Diseases diagnostic imaging, Artifacts

Abstract

Lung ultrasound (LUS) is an important imaging modality to assess the state of the lung surface. However, current LUS approaches are based on subjective interpretation of imaging artifacts, which results in poor specificity as quantitative evaluation lacks. The latter could be improved by adopting LUS spectroscopy of vertical artifacts. Indeed, parameterizing these artifacts with native frequency, bandwidth, and total intensity ( [Formula: see text]) already showed potentials in differentiating pulmonary fibrosis (PF). In this study, we acquired radio frequency (RF) data from 114 patients. These data (representing the largest LUS RF dataset worldwide) were acquired by utilizing a multifrequency approach, implemented with an ULtrasound Advanced Open Platform (ULA-OP). Convex (CA631) and linear (LA533) probes (Esaote, Florence, Italy) were utilized to acquire RF data at three (2, 3, and 4 MHz), and four (3, 4, 5, and 6 MHz) imaging frequencies. A multifrequency analysis was conducted on vertical artifacts detected in patients having cardiogenic pulmonary edema (CPE), pneumonia, or PF. These artifacts were characterized by the three abovementioned parameters, and their mean values were used to project each patient into a feature space having up to three dimensions. Binary classifiers were used to evaluate the performance of these three mean features in differentiating patients affected by CPE, pneumonia, and PF. Acquisitions of multifrequency data performed with linear probe lead to accuracies up to 85.43% in the differential diagnosis of these diseases (convex probes' maximum accuracy was 74.51%). Moreover, the results showed high potentials of mean [Formula: see text] (by itself or combined with other features) in improving LUS specificity.

Published

2024

3. FLUEnT: Transformer for detecting lung consolidations in videos using fused lung ultrasound encodings.

Author

Khan U, Thompson R, Li J, Etter LP, Camelo I, Pieciak RC, Castro-Aragon I, Setty B, Gill CC, Demi L, and Betke M

Subjects

Humans, Child, Child, Preschool, Image Interpretation, Computer-Assisted methods, Male, Female, Infant, Video Recording, Ultrasonography methods, Lung diagnostic imaging, Pneumonia diagnostic imaging

Abstract

Pneumonia is the leading cause of death among children around the world. According to WHO, a total of 740,180 lives under the age of five were lost due to pneumonia in 2019. Lung ultrasound (LUS) has been shown to be particularly useful for supporting the diagnosis of pneumonia in children and reducing mortality in resource-limited settings. The wide application of point-of-care ultrasound at the bedside is limited mainly due to a lack of training for data acquisition and interpretation. Artificial Intelligence can serve as a potential tool to automate and improve the LUS data interpretation process, which mainly involves analysis of hyper-echoic horizontal and vertical artifacts, and hypo-echoic small to large consolidations. This paper presents, Fused Lung Ultrasound Encoding-based Transformer (FLUEnT), a novel pediatric LUS video scoring framework for detecting lung consolidations using fused LUS encodings. Frame-level embeddings from a variational autoencoder, features from a spatially attentive ResNet-18, and encoded patient information as metadata combiningly form the fused encodings. These encodings are then passed on to the transformer for binary classification of the presence or absence of consolidations in the video. The video-level analysis using fused encodings resulted in a mean balanced accuracy of 89.3 %, giving an average improvement of 4.7 % points in comparison to when using these encodings individually. In conclusion, outperforming the state-of-the-art models by an average margin of 8 % points, our proposed FLUEnT framework serves as a benchmark for detecting lung consolidations in LUS videos from pediatric pneumonia patients., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:Libertario Demi is the co-founder of UltraAI. The rest of authors declare no conflict of interests., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

4. Dependence of lung ultrasound vertical artifacts on frequency, bandwidth, focus and angle of incidence: An in vitro study.

Author

Mento F and Demi L

Subjects

Phantoms, Imaging, Thorax, Ultrasonography, Artifacts, Lung diagnostic imaging

Abstract

Lung ultrasound (LUS) is nowadays widely adopted by clinicians to evaluate the state of the lung surface. However, being mainly based on the evaluation of vertical artifacts, whose genesis is still unclear, LUS is affected by qualitative and subjective analyses. Even though semi-quantitative approaches supported by computer aided methods can reduce subjectivity, they do not consider the dependence of vertical artifacts on imaging parameters, and could not be classified as fully quantitative. They are indeed mainly based on scoring LUS images, reconstructed with standard clinical scanners, through the sole evaluation of visual patterns, whose visualization depends on imaging parameters. To develop quantitative techniques is therefore fundamental to understand which parameters influence the vertical artifacts' intensity. In this study, we quantitatively analyzed the dependence of nine vertical artifacts observed in a thorax phantom on four parameters, i.e., center frequency, focal point, bandwidth, and angle of incidence. The results showed how the vertical artifacts are significantly affected by these four parameters, and confirm that the center frequency is the most impactful parameter in artifacts' characterization. These parameters should hence be carefully considered when developing a LUS quantitative approach.

Published

2021

5. Lung Ultrasound for COVID-19 Patchy Pneumonia: Extended or Limited Evaluations?

Author

Smargiassi A, Soldati G, Torri E, Mento F, Milardi D, Del Giacomo P, De Matteis G, Burzo ML, Larici AR, Pompili M, Demi L, and Inchingolo R

Subjects

Female, Humans, Male, Middle Aged, Reproducibility of Results, SARS-CoV-2, Severity of Illness Index, COVID-19 diagnostic imaging, Lung diagnostic imaging, Ultrasonography methods

Abstract

Objectives: The 2019 novel coronavirus (severe acute respiratory syndrome coronavirus 2) is causing cases of severe pneumonia. Lung ultrasound (LUS) could be a useful tool for physicians detecting a bilateral heterogeneous patchy distribution of pathologic findings in a symptomatic suggestive context. The aim of this study was to focus on the implications of limiting LUS examinations to specific regions of the chest., Methods: Patients were evaluated with a standard sequence of LUS scans in 14 anatomic areas. A scoring system of LUS findings was reported, ranging from 0 to 3 (worst score, 3). The scores reported on anterior, lateral, and posterior landmarks were analyzed separately and compared with each other and with the global findings., Results: Thirty-eight patients were enrolled. A higher prevalence of score 0 was observed in the anterior region (44.08%). On the contrary, 21.05% of posterior regions and 13.62% of lateral regions were evaluated as score 3, whereas only 5.92% of anterior regions were classified as score 3. Findings from chest computed tomography performed in 16 patients with coronavirus disease 2019 correlated with and matched the distribution of findings from LUS., Conclusions: To assess the quantity and severity of lung disease, a comprehensive LUS examination is recommended. Omitting areas of the chest misses involved lung., (© 2020 American Institute of Ultrasound in Medicine.)

Published

2021

6. Time for a new international evidence-based recommendations for point-of-care lung ultrasound.

Author

Soldati G, Smargiassi A, Inchingolo R, Buonsenso D, Perrone T, Briganti DF, Perlini S, Torri E, Mariani A, Mossolani EE, Tursi F, Mento F, and Demi L

Subjects

Humans, Point-of-Care Testing, Ultrasonography, Lung diagnostic imaging, Point-of-Care Systems

Published

2021

7. Lung ultrasonography for early management of patients with respiratory symptoms during COVID-19 pandemic.

Author

Smargiassi A, Soldati G, Borghetti A, Scoppettuolo G, Tamburrini E, Testa AC, Moro F, Natale L, Larici AR, Buonsenso D, Valentini P, Draisci G, Zanfini BA, Pompili M, Scambia G, Lanzone A, Franceschi F, Rapaccini GL, Gasbarrini A, Giorgini P, Richeldi L, Demi L, and Inchingolo R

Subjects

Algorithms, Betacoronavirus, COVID-19, Clinical Decision-Making, Coronavirus Infections therapy, Early Diagnosis, Hospitalization, Humans, Inservice Training, Medical Staff, Hospital education, Pandemics, Patient Isolation, Pneumonia, Viral therapy, SARS-CoV-2, Ultrasonography, Clinical Protocols, Coronavirus Infections diagnostic imaging, Emergency Service, Hospital organization & administration, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging

Abstract

COVID-19 pandemic is representing a serious challenge to worldwide public health. Lung Ultrasonography (LUS) has been signaled as a potential useful tool in this pandemic contest either to intercept viral pneumonia or to foster alternative paths. LUS could be useful in determining early lung involvement suggestive or not of COVID-19 pneumonia and potentially plays a role in managing decisions for hospitalization in isolation or admission in general ward. In order to face pandemic, in a period in which a large number of emergency room accesses with suspicious symptoms are expected, physicians need a standardized ultrasonographic approach, fast educational processes in order to be able to recognize both suggestive and not suggestive echographic signs and shared algorithms for LUS role in early management of patients.

Published

2020

8. Contrast-Enhanced Ultrasound in Patients With COVID-19: Pneumonia, Acute Respiratory Distress Syndrome, or Something Else?

Author

Soldati G, Giannasi G, Smargiassi A, Inchingolo R, and Demi L

Subjects

Adult, Aged, Diagnosis, Differential, Humans, Male, Middle Aged, COVID-19 diagnostic imaging, Contrast Media, Image Enhancement methods, Lung diagnostic imaging, Pneumonia diagnostic imaging, Respiratory Distress Syndrome diagnostic imaging, Ultrasonography methods

Abstract

Coronavirus disease 2019 (COVID-19) represents a very heterogeneous disease. Some aspects of COVID-19 pneumonia question the real nature of ground glass opacities and its consolidative lesions. It has been hypothesized that COVID-19 lung involvement could represent not only a viral effect but also an immune response induced by the infection, causing epithelial/endothelial lesions and coagulation disorders. We report 3 cases of COVID-19 pneumonia in which contrast-enhanced ultrasound was suggestive of consolidations with perfusion defects, at least in part caused by ischemic or necrotic changes and not only by inflammatory or atelectasis events., (© 2020 by the American Institute of Ultrasound in Medicine.)

Published

2020

9. Quantitative Lung Ultrasound Spectroscopy Applied to the Diagnosis of Pulmonary Fibrosis: The First Clinical Study.

Author

Mento F, Soldati G, Prediletto R, Demi M, and Demi L

Subjects

Aged, Aged, 80 and over, Female, Humans, Male, Middle Aged, Sensitivity and Specificity, Image Interpretation, Computer-Assisted methods, Lung diagnostic imaging, Pulmonary Fibrosis diagnostic imaging, Ultrasonography methods

Abstract

The application of ultrasound imaging to the diagnosis of lung diseases is nowadays receiving growing interest. However, lung ultrasound (LUS) is mainly limited to the analysis of imaging artifacts, such as B-lines, which correlate with a wide variety of diseases. Therefore, the results of LUS investigations remain qualitative and subjective, and specificity is obviously suboptimal. Focusing on the development of a quantitative method dedicated to the lung, in this work, we present the first clinical results obtained with quantitative LUS spectroscopy when applied to the differentiation of pulmonary fibrosis. A previously developed specific multifrequency ultrasound imaging technique was utilized to acquire ultrasound images from 26 selected patients. The multifrequency imaging technique was implemented on the ULtrasound Advanced Open Platform (ULA-OP) platform and an LA533 (Esaote, Florence, Italy) linear-array probe was utilized. RF data obtained at different imaging frequencies (3, 4, 5, and 6 MHz) were acquired and processed in order to characterize B-lines based on their frequency content. In particular, B-line native frequencies (the frequency at which a B-line exhibits the highest intensity) and bandwidth (the range of frequencies over which a B-line shows intensities within -6 dB from its highest intensity), as well as B-line intensity, were analyzed. The results show how the analysis of these features allows (in this group of patients) the differentiation of fibrosis with a sensitivity and specificity equal to 92% and 92%, respectively. These promising results strongly motivate toward the extension of the clinical study, aiming at analyzing a larger cohort of patients and including a broader range of pathologies.

Published

2020

10. Automatic Pleural Line Extraction and COVID-19 Scoring From Lung Ultrasound Data.

Author

Carrer L, Donini E, Marinelli D, Zanetti M, Mento F, Torri E, Smargiassi A, Inchingolo R, Soldati G, Demi L, Bovolo F, and Bruzzone L

Subjects

Algorithms, COVID-19, Humans, Pandemics, Signal Processing, Computer-Assisted, Support Vector Machine, Coronavirus Infections diagnostic imaging, Image Interpretation, Computer-Assisted methods, Lung diagnostic imaging, Pleura diagnostic imaging, Pneumonia, Viral diagnostic imaging, Ultrasonography methods

Abstract

Recent works highlighted the significant potential of lung ultrasound (LUS) imaging in the management of subjects affected by COVID-19. In general, the development of objective, fast, and accurate automatic methods for LUS data evaluation is still at an early stage. This is particularly true for COVID-19 diagnostic. In this article, we propose an automatic and unsupervised method for the detection and localization of the pleural line in LUS data based on the hidden Markov model and Viterbi Algorithm. The pleural line localization step is followed by a supervised classification procedure based on the support vector machine (SVM). The classifier evaluates the healthiness level of a patient and, if present, the severity of the pathology, i.e., the score value for each image of a given LUS acquisition. The experiments performed on a variety of LUS data acquired in Italian hospitals with both linear and convex probes highlight the effectiveness of the proposed method. The average overall accuracy in detecting the pleura is 84% and 94% for convex and linear probes, respectively. The accuracy of the SVM classification in correctly evaluating the severity of COVID-19 related pleural line alterations is about 88% and 94% for convex and linear probes, respectively. The results as well as the visualization of the detected pleural line and the predicted score chart, provide a significant support to medical staff for further evaluating the patient condition.

Published

2020

11. Lung ultrasound: The future ahead and the lessons learned from COVID-19.

Author

Demi L

Subjects

Animals, Betacoronavirus pathogenicity, COVID-19, Coronavirus Infections virology, Host-Pathogen Interactions, Humans, Lung virology, Pandemics, Pneumonia, Viral virology, Predictive Value of Tests, SARS-CoV-2, Coronavirus Infections diagnostic imaging, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging, Ultrasonography

Abstract

Lung ultrasound (LUS) is a rapidly evolving field of application for ultrasound technologies. Especially during the current pandemic, many clinicians around the world have employed LUS to assess the condition of the lung for patients suspected and/or affected by COVID-19. However, LUS is currently performed with standard ultrasound imaging, which is not designed to cope with the high air content present in lung tissues. Nowadays LUS lacks standardization and suffers from the absence of quantitative approaches. To elevate LUS to the level of other ultrasound imaging applications, several aspects deserve attention from the technical and clinical world. This overview piece tries to provide the reader with a forward-looking view on the future for LUS.

Published

2020

12. Real-time multi-frequency ultrasound imaging for quantitative lung ultrasound - first clinical results.

Author

Demi L, Demi M, Prediletto R, and Soldati G

Subjects

Phantoms, Imaging, Sound, Ultrasonography, Artifacts, Lung diagnostic imaging

Abstract

Lung ultrasound imaging is a fast-evolving field of application for ultrasound technologies. However, most diagnoses are currently performed with imaging protocols that assume a quasi-homogeneous speed of sound in the volume of interest. When applied to the lung, due to the presence of air, this assumption is unrealistic. Consequently, diagnoses are often based on imaging artifacts and thus qualitative and subjective. In this paper, we present an image formation protocol that is capable of capturing the frequency dependence of well-known artifacts (B-lines) and visualizing it in real time, ultimately providing a quantitative assessment of the signals received from the lung. Previous in vitro studies have shown the potential of B-lines native-frequency for the characterization of bubbly medium, but this paper presents the first results on clinical data. The image formation process has been designed to work on lung tissue, and ultrasound images generated with four orthogonal bands centered at 3, 4, 5 and 6 MHz can be acquired and displayed in real time. Results show that B-lines can be characterized on the basis of their native frequency in vivo and open the way toward real-time quantitative lung ultrasound imaging.

Published

2020

13. The diagnosis of pneumonia in a pregnant woman with coronavirus disease 2019 using maternal lung ultrasound.

Author

Inchingolo R, Smargiassi A, Moro F, Buonsenso D, Salvi S, Del Giacomo P, Scoppettuolo G, Demi L, Soldati G, and Testa AC

Subjects

Betacoronavirus, COVID-19, COVID-19 Testing, Clinical Laboratory Techniques, Coronavirus Infections diagnosis, Female, Humans, Pandemics, Pregnancy, Pregnancy Complications, Infectious virology, Radiography, Thoracic, SARS-CoV-2, Ultrasonography, Coronavirus Infections diagnostic imaging, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging, Pregnancy Complications, Infectious diagnostic imaging

Abstract

Lung ultrasound examination has been demonstrated to be an accurate imaging method to detect pulmonary and pleural conditions. During pregnancy, there is a need for rapid assessment of the maternal lung in patients with suspected coronavirus disease 2019. We report our experience on lung ultrasound examination in the diagnosis of coronavirus disease 2019 pneumonia in a pregnant woman. Typical ultrasound features of this pulmonary pathology, including diffuse hyperechoic vertical artifacts with thickened pleural line and "white lung" with patchy distribution, were observed. We suggest point-of-care lung ultrasound examination as a diagnostic imaging tool in pregnant women with suspected coronavirus disease 2019., (Copyright © 2020. Published by Elsevier Inc.)

Published

2020

14. Is There a Role for Lung Ultrasound During the COVID-19 Pandemic?

Author

Soldati G, Smargiassi A, Inchingolo R, Buonsenso D, Perrone T, Briganti DF, Perlini S, Torri E, Mariani A, Mossolani EE, Tursi F, Mento F, and Demi L

Subjects

COVID-19, Humans, Pandemics, SARS-CoV-2, Betacoronavirus, Coronavirus Infections diagnostic imaging, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging, Ultrasonography methods

Published

2020

15. Proposal for International Standardization of the Use of Lung Ultrasound for Patients With COVID-19: A Simple, Quantitative, Reproducible Method.

Author

Soldati G, Smargiassi A, Inchingolo R, Buonsenso D, Perrone T, Briganti DF, Perlini S, Torri E, Mariani A, Mossolani EE, Tursi F, Mento F, and Demi L

Subjects

Anatomic Landmarks, Artificial Intelligence, COVID-19, Databases, Factual, Forecasting, Humans, Image Processing, Computer-Assisted, Internationality, Pandemics, Point-of-Care Systems, Reproducibility of Results, SARS-CoV-2, Betacoronavirus, Coronavirus Infections diagnostic imaging, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging, Ultrasonography standards

Abstract

Growing evidence is showing the usefulness of lung ultrasound in patients with the 2019 new coronavirus disease (COVID-19). Severe acute respiratory syndrome coronavirus 2 has now spread in almost every country in the world. In this study, we share our experience and propose a standardized approach to optimize the use of lung ultrasound in patients with COVID-19. We focus on equipment, procedure, classification, and data sharing., (© 2020 by the American Institute of Ultrasound in Medicine.)

Published

2020

16. How to perform lung ultrasound in pregnant women with suspected COVID-19.

Author

Moro F, Buonsenso D, Moruzzi MC, Inchingolo R, Smargiassi A, Demi L, Larici AR, Scambia G, Lanzone A, and Testa AC

Subjects

COVID-19, Coronavirus Infections complications, Female, Humans, Pandemics, Pneumonia, Viral complications, Pregnancy, SARS-CoV-2, Ultrasonography, Betacoronavirus, Coronavirus Infections diagnostic imaging, Lung diagnostic imaging, Pneumonia, Viral diagnostic imaging, Pregnancy Complications, Infectious diagnostic imaging

Abstract

Under certain circumstances, such as during the current COVID-19 outbreak, pregnant women can be a target for respiratory infection, and lung examination may be required as part of their clinical evaluation, ideally while avoiding exposure to radiation. We propose a practical approach for obstetricians/gynecologists to perform lung ultrasound examination, discussing potential applications, semiology and practical aspects, which could be of particular importance in emergency situations, such as the current pandemic infection of COVID-19. Copyright © 2020 ISUOG. Published by John Wiley & Sons Ltd., (Copyright © 2020 ISUOG. Published by John Wiley & Sons Ltd.)

Published

2020

17. Localizing B-Lines in Lung Ultrasonography by Weakly Supervised Deep Learning, In-Vivo Results.

Author

van Sloun RJG and Demi L

Subjects

Artifacts, Humans, Lung Diseases diagnostic imaging, Phantoms, Imaging, Deep Learning, Image Interpretation, Computer-Assisted methods, Lung diagnostic imaging, Supervised Machine Learning, Ultrasonography methods

Abstract

Lung ultrasound (LUS) is nowadays gaining growing attention from both the clinical and technical world. Of particular interest are several imaging-artifacts, e.g., A- and B- line artifacts. While A-lines are a visual pattern which essentially represent a healthy lung surface, B-line artifacts correlate with a wide range of pathological conditions affecting the lung parenchyma. In fact, the appearance of B-lines correlates to an increase in extravascular lung water, interstitial lung diseases, cardiogenic and non-cardiogenic lung edema, interstitial pneumonia and lung contusion. Detection and localization of B-lines in a LUS video are therefore tasks of great clinical interest, with accurate, objective and timely evaluation being critical. This is particularly true in environments such as the emergency units, where timely decision may be crucial. In this work, we present and describe a method aimed at supporting clinicians by automatically detecting and localizing B-lines in an ultrasound scan. To this end, we employ modern deep learning strategies and train a fully convolutional neural network to perform this task on B-mode images of dedicated ultrasound phantoms in-vitro, and on patients in-vivo. An accuracy, sensitivity, specificity, negative and positive predictive value equal to 0.917, 0.915, 0.918, 0.950 and 0.864 were achieved in-vitro, respectively. Using a clinical system in-vivo, these statistics were 0.892, 0.871, 0.930, 0.798 and 0.958, respectively. We moreover calculate neural attention maps that visualize which components in the image triggered the network, thereby offering simultaneous weakly-supervised localization. These promising results confirm the capability of the proposed method to identify and localize the presence of B-lines in clinical lung ultrasonography.

Published

2020

18. Physical Mechanisms Providing Clinical Information From Ultrasound Lung Images: Hypotheses and Early Confirmations.

Author

Demi M, Prediletto R, Soldati G, and Demi L

Subjects

Artifacts, Humans, Lung pathology, Lung Diseases diagnostic imaging, Lung Diseases pathology, Phantoms, Imaging, Image Interpretation, Computer-Assisted methods, Lung diagnostic imaging, Ultrasonography methods

Abstract

In standard B mode imaging, a set of ultrasound pulses is used to reconstruct a 2-D image even though some of the assumptions needed to do this are not fully satisfied. For this reason, ultrasound medical images show numerous artifacts which physicians recognize and evaluate as part of their diagnosis since even one artifact can provide clinical information. Understanding the physical mechanisms at the basis of the formation of an artifact is important to identify the physiopathological state of the biological medium which generated the artifact. Ultrasound lung images are a significant example of this challenge since everything that is represented beyond the thickness of the chest wall ( ≈ 2 cm) is artifactual information. A convincing physical explanation of the genesis of important ultrasound lung artifacts does not exist yet. Physicians simply base their diagnosis on a correlation observed over the years between the manifestation of some artifacts and the occurrence of particular lung pathologies. In this article, a plausible genesis of some important lung artifacts is suggested.

Published

2020

19. The role of ultrasound lung artifacts in the diagnosis of respiratory diseases.

Author

Soldati G, Demi M, Smargiassi A, Inchingolo R, and Demi L

Subjects

Artifacts, Humans, Lung diagnostic imaging, Lung Diseases diagnostic imaging, Respiration Disorders diagnostic imaging, Ultrasonography

Abstract

Introduction: Thoracic ultrasound is employed for the diagnosis of many thoracic diseases and is an accepted detection tool of pleural effusions, atelectasis, pneumothorax, and pneumonia. However, the use of ultrasound for the evaluation of parenchymal lung disease, when the organ is still aerated, is a relatively new application. Areas covered: The diagnosis of a normal lung and the differentiation between a normally aerated lung and a lung with interstitial pathology is based on the interpretation of ultrasound artifacts universally known as A and B-Lines. Even though the practical role of lung ultrasound artifacts is accepted by many clinicians, their physical basis and the correlations between these signs and the causal pathology is not known in depth. Expert commentary: In this review, we discuss the meaning of A- and B-Lines in the diagnostic ultrasound imaging of the lung and the acoustic properties of the pleural plane which are at the basis of their generation.

Published

2019

20. Determination of a potential quantitative measure of the state of the lung using lung ultrasound spectroscopy.

Author

Demi L, van Hoeve W, van Sloun RJG, Soldati G, and Demi M

Subjects

Microbubbles, Phantoms, Imaging, Video Recording, Lung diagnostic imaging, Spectrum Analysis, Ultrasonography

Abstract

B-lines are ultrasound-imaging artifacts, which correlate with several lung-pathologies. However, their understanding and characterization is still largely incomplete. To further study B-lines, lung-phantoms were developed by trapping a layer of microbubbles in tissue-mimicking gel. To simulate the alveolar size reduction typical of various pathologies, 170 and 80 µm bubbles were used for phantom-type 1 and 2, respectively. A normal alveolar diameter is approximately 280 µm. A LA332 linear-array connected to the ULA-OP platform was used for imaging. Standard ultrasound (US) imaging at 4.5 MHz was performed. Subsequently, a multi-frequency approach was used where images were sequentially generated using orthogonal sub-bands centered at different frequencies (3, 4, 5, and 6 MHz). Results show that B-lines appear predominantly with phantom-type 2. Moreover, the multi-frequency approach revealed that the B-lines originate from a specific portion of the US spectrum. These results can give rise to significant clinical applications since, if further confirmed by extensive in-vivo studies, the native frequency of B-lines could provide a quantitative-measure of the state of the lung.

Published

2017