ALBERT

Description: Backgrounds Positron emission tomography using 18F-fluorodeoxyglucose (FDG-PET) is a well known imaging technique that has been proven being useful in staging and response to treatment assessment of Hodgkin and non-Hodgkin lymphomas, providing information about the metabolic behaviour of tissues independently of morphological criteria. At the moment its role in Post Transplant Lymphoproliferative Disorders (PTLDs) remains unclear, because large series of patients evaluated with FDG-PET and compared with conventional imaging still lack. Aims To establish the usefulness of FDG-PET in staging, remission assesment and follow-up of PTLD in comparison to the conventional imaging (CT) findings in terms of sensitivity, specificity, accuracy, positive predictive value (PPV) and negative predictive value (NPV). Methods Between February 2003 and July 2008, 79 FDG-PET were performed in 31 patients who developed PTLD after solid organ transplantation. According to WHO classifications, patients could be divided as follow: 1 Plasmacytic Hyperplasia, 9 Polymorphic Lymphoproliferative Disorder, 20 Malignant Lymphoma; in one case histological diagnosis was not obtained. We retrospectively compared results from 46/79 FDG-PET to findings obtained from conventional imaging performed at the same time. Thirty-three/79 more FDG-PET scans were performed as follow up assesment and results were compared according to disease status as defined on the basis of clinical signs and symptoms, biochemical markers and imaging technique. Results When compared to conventional imaging (46 scans), FDG-PET showed the same results as CT in 34/46 cases, while discordant results were found in 12/46 cases (data are reported in the table). No differences in FDG-PET sensitivity were observed in the different histological subtypes of PTLD. According to disease status FDG-PET showed good sensitivity, specificity and accuracy; when compared to CT, FDG-PET had lower sensitivity (81% vs 97%), but higher specificity (96% vs 78%) and accuracy (92% vs 85%). Moreover, this technique provided a high PPV (90%) and NPV (93%) Conclusions: Our data support the role of FDG-PET as diagnostic tool in PTLD as well as other FDG-avid lymphomas. The histological PTLD subtype doesn’t seem to have any impact on FDG avidity, even though in our analysis ML were the prevalent forms. In the majority of cases FDG-PET can well identify all disease areas seen at standard imaging modalities. Moreover, avoiding contrast medium related nephrotoxicity, this imaging modality can even be considered as a safe procedure in the setting of frail PTLD patients whose renal function is often impaired. In our analysis FDG-PET has higher PPV when compared to CT (90% vs 72%): the absence of metabolic activity at FDG-PET can rule out a supposed residual disease revealed at CT on the basis of morphological criteria. So while CT can still be considered the gold standard in staging assessment, due to its higher sensitivity, FDGPET may be better employed in the follow up, due to its capacity to detect the persistence of active disease in residual lesions described by conventional imaging. CONCORDANT (34/46) DISCORDANT (12/46) Disease present Disease absent Disease present Disease absent PET pos PET neg PET neg PET pos PET neg CT pos CT neg CT pos CT neg CT pos 15 19 4 2 6

Description: The EU Center of Excellence for Exascale in Solid Earth (ChEESE) develops exascale transition capabilities in the domain of Solid Earth, an area of geophysics rich in computational challenges embracing different approaches to exascale (capability, capacity, and urgent computing). The first implementation phase of the project (ChEESE-1P; 2018–2022) addressed scientific and technical computational challenges in seismology, tsunami science, volcanology, and magnetohydrodynamics, in order to understand the phenomena, anticipate the impact of natural disasters, and contribute to risk management. The project initiated the optimisation of 10 community flagship codes for the upcoming exascale systems and implemented 12 Pilot Demonstrators that combine the flagship codes with dedicated workflows in order to address the underlying capability and capacity computational challenges. Pilot Demonstrators reaching more mature Technology Readiness Levels (TRLs) were further enabled in operational service environments on critical aspects of geohazards such as long-term and short-term probabilistic hazard assessment, urgent computing, and early warning and probabilistic forecasting. Partnership and service co-design with members of the project Industry and User Board (IUB) leveraged the uptake of results across multiple research institutions, academia, industry, and public governance bodies (e.g. civil protection agencies). This article summarises the implementation strategy and the results from ChEESE-1P, outlining also the underpinning concepts and the roadmap for the on-going second project implementation phase (ChEESE-2P; 2023–2026).

Description: EU

Description: Published

Description: 47-61

Description: OSV1: Verso la previsione dei fenomeni vulcanici pericolosi

Description: JCR Journal