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1 – 2 of 2Dimitrios Markopoulos, Anastasios Tsolakidis, Ioannis Triantafyllou, Georgios A. Giannakopoulos and Christos Skourlas
This study aims to analyze a conspicuous corpus of literature related to the field of technology-based intensive care research and to develop an architecture model of the future…
Abstract
Purpose
This study aims to analyze a conspicuous corpus of literature related to the field of technology-based intensive care research and to develop an architecture model of the future smart intensive care unit (ICU).
Design/methodology/approach
Papers related to the topics of electronic health record (EHR), big data, data flow and clinical decision support in ICUs were investigated. These concepts have been analyzed in combination with secondary use of data, prediction models, data standardization and interoperability challenges. Based on the findings, an architecture model evaluated using MIMIC III is proposed.
Findings
Research identified issues regarding implementation of systems, data sources, interoperability, management of big data and free text produced in ICUs and lack of accuracy of prediction models. ICU should be treated as part of a greater system, able to intercommunicate with other entities.
Research limitations/implications
The research examines the current needs of ICUs in interoperability and data management. As environment changes dynamically, continuous assessment and evaluation of the model with other ICU databases is required.
Originality/value
The proposed model improves ICUs interoperability in national health system, ICU staff intercommunication, remote access and decision support. Its modular approach ensures that ICUs can have their own particularities and specialisms while ICU functions provide ongoing expertise and training to upgrade its staff.
Details
Keywords
Nikolaos Kladovasilakis, Paschalis Charalampous, Ioannis Kostavelis and Dimitrios Tzovaras
This paper aims to present an integrated system designed for quality control and inspection in additive manufacturing (AM) technologies.
Abstract
Purpose
This paper aims to present an integrated system designed for quality control and inspection in additive manufacturing (AM) technologies.
Design/methodology/approach
The study undertakes a comprehensive examination of the process in three distinct stages. First, the quality of the feedstock material is inspected during the preprocessing step. Subsequently, the main research topic of the study is directed toward the 3D printing process itself with real-time monitoring procedures using computer vision methods. Finally, an evaluation of the 3D printed parts is conducted, using measuring methods and mechanical experiments.
Findings
The main results of this technical paper are the development and presentation of an integrated solution for quality control and inspection in AM processes.
Originality/value
The proposed solution entails the development of a promising tool for the optimization of the quality in 3D prints based on machine learning algorithms.
Details