Your search keyword '"Faisal, Almisned"' showing total 4 results

1. Utilization of artificial intelligence approach for prediction of DLP values for abdominal CT scans: A high accuracy estimation for risk assessment

Author

H. O. Tekin, Faisal Almisned, T. T. Erguzel, Mohamed M. Abuzaid, W. Elshami, Antoaneta Ene, Shams A. M. Issa, and Hesham M. H. Zakaly

Subjects

artificial intelligence (AI), computed tomography, DLP, abdominal, artificial neural network (ANN), Public aspects of medicine, RA1-1270

Abstract

PurposeThis study aimed to evaluate Artificial Neural Network (ANN) modeling to estimate the significant dose length product (DLP) value during the abdominal CT examinations for quality assurance in a retrospective, cross-sectional study.MethodsThe structure of the ANN model was designed considering various input parameters, namely patient weight, patient size, body mass index, mean CTDI volume, scanning length, kVp, mAs, exposure time per rotation, and pitch factor. The aforementioned examination details of 551 abdominal CT scans were used as retrospective data. Different types of learning algorithms such as Levenberg-Marquardt, Bayesian and Scaled-Conjugate Gradient were checked in terms of the accuracy of the training data.ResultsThe R-value representing the correlation coefficient for the real system and system output is given as 0.925, 0.785, and 0.854 for the Levenberg-Marquardt, Bayesian, and Scaled-Conjugate Gradient algorithms, respectively. The findings showed that the Levenberg-Marquardt algorithm comprehensively detects DLP values for abdominal CT examinations. It can be a helpful approach to simplify CT quality assurance.ConclusionIt can be concluded that outcomes of this novel artificial intelligence method can be used for high accuracy DLP estimations before the abdominal CT examinations, where the radiation-related risk factors are high or risk evaluation of multiple CT scans is needed for patients in terms of ALARA. Likewise, it can be concluded that artificial learning methods are powerful tools and can be used for different types of radiation-related risk assessments for quality assurance in diagnostic radiology.

Published

2022

2. Computer Simulation for Shielding Properties of SiC and TiC Reinforced Composites

Author

Faisal Almisned

Abstract

Composites are important materials and can be produced adding different types of materials on it. These are used in different kind of purposes and also radiation shielding purposes. In this study composites where SiC and TiC added, were produced and radiation shielding performance were investigated. The produced composites were formulated as (95-x) Al–5SiC–xTiC where x = 0, 5,10,15,20 (wt%). The results show that by increasing the TiC rate on composite from S-0 to S-20, the ascending trend is observed for the linear attenuation coefficient (LAC, cm− 1) of the studied composites, and the best shielding performance is seen for S-20.

Published

2022

3. Prediction of Dose Length Product for chest CT Examinations using Artificial Neural Networks (ANN)

Author

H. O. Tekin, Faisal Almisned, T. T. Erguzel, Mohamed M. Abuzaid, W. Elshami, Antoaneta Ene, shams A.M. Issa, and Hesham M.H. Zakaly

Abstract

This study aimed to design an Artificial Neural Network modelling to estimate the remarkable dose length product (DLP) value during the chest computed tomography (CT) examinations for quality assurance in a retrospective, cross-sectional study. The structure of artificial neural networks model was designed considering various input parameters, namely patient weight, patient size, body mass index, mean CT dose index, scanning length, kVp, mAs, exposure time per rotation and pitch factor. The examination details of 1897 chest CT scans were used as retrospective data. Different types of learning algorithms such as Levenberg-Marquardt, Bayesian and Scaled-Conjugate Gradient were checked in terms of the accuracy of the test data. The R-value or the test data was representing the correlation coefficient for the real system and system output is given as 0.97328, 0.82263 and 0.90574 for the Levenberg-Marquardt, Bayesian and Scaled-Conjugate Gradient algorithms, respectively. The findings showed that the Levenberg-Marquardt algorithm comprehensively detects DLP values for chest CT examinations. To meet CT efficiency standards, it may be an effective to use simplified methodology. It can be deduced that artificial intelligence methods can be used to perform high precision DLP on the chest CT exams where the radiation-related risks are particularly great or highly relevant for patients. This type of approaches are effective instruments and can be applied to risk evaluations in the field of diagnostic radiology.

Published

2022

4. Requirements Analysis: Evaluating KAOS Models.

Author

Faisal Almisned and Jeroen Keppens

Published

2010