Your search keyword '"Çelik, Özer"' showing total 107 results

101. Kanser tedavisinde kullanılabilecek magnetik nanoparçacıkların üretilmesi

Author

Çelik, Özer, Fırat, Tezer, and Fizik Mühendisliği Anabilim Dalı

Subjects

Fizik ve Fizik Mühendisliği, Nano structure, Magnetism, Nanotechnology, Hyperthermia, Physics and Physics Engineering

Abstract

Hipertermi kanser tedavisinde umut veren bir yaklaşımdır. Özellikle, tümör sıcaklığını 42?48?C'ye yükseltebilen ve böylece tümör hücrelerini öldüren magnetik nanoakışkan hipertermi (MNH) önemli bir uygulamadır. MNH yöntemi 1950'li yıllarda başlamış olmasına rağmen kanser dokusunun tedavisi için henüz gelişiminin ilk evresindedir ve bu güne kadar hasta insanda başarılı bir uygulaması olmamıştır. Bunun temel nedeni uygulama için gerekli koşulları sağlayan magnetik nanoparçacıkların sentez edilememesidir.Bu metod, taşıyıcı akışkanlar içinde asılı ferromagnetik (FM) veya süperparamagnetik (SPM) nanoparçacıkların tümör dokuya sokulması ve sonra AA magnetik alanla ışınlanmasını kapsamaktadır. Parçacıklar birkaç fiziksel mekanizma ile AA magnetik alanın enerjisini ısıya dönüştürürler. Bu dönüşümün etkinliği kuvvetli şekilde dış alanın frekansına ve şiddetine bağlı olduğu kadar parçacıkların magnetizasyonu ve yüzey modifikasyonu gibi özelliklerine de bağlıdır. Bu nedenle, hastaya uygulanan maddeyi aza indirgemek için magnetik malzemenin büyük güç kaybının olması istenir. Günümüzde, magnetik malzemelerin ısıtma gücünü artırmak amacıyla, güç kaybı mekanizmaları üzerine yapılan çalışmalar yoğun şekilde cazibe kazanmıştır.yapılan bu tez çalışmasında, seri olarak Co-ferrit oksit nanoparçacıkları, yüksek sıcaklık ısıl-ayrıştırma metoduyla farklı boyutlarda hazırlanmıştır. Nanoparçacıkların boyutları hazırlama parametreleri değiştirilerek kontrol edildi, ve sonra faz oluşumları ve kristal yapıları spekroskopi (XRD, EDX) ve mikroskopi (SEM, TEM) çalışmaları ile teyit edildi.Önerilen bu tezin amacı SPM parçacıklar ile kararlı FM parçacıklar arasındaki magnetik nanoparçacıkların ısı üretim mekanizmaları üzerinde derin bir görüş kazanmak ve parçacık özellikleri ve elektro magnetik alan parametrelerinin ileriki uygulamalar için nasıl optimize edileceğine açıklık getirmektir. Hyperthermia is a promising approach to cancer therapy. In particular, magnetic nanofluid hyperthermia (MNH) is an important application, which can increase the temperature in tumors to 42?48?C and therefore kill tumor cells. Although MNH was initiated in the 1950s, it is still at an early stage of development in the treatment for cancer tumors and, to date, there have been no reports of the successful application of this technology to the treatment of a human patient. The main reason for this is the synthesis of the magnetic nanoparticles that have suitable properties for the applications has not been achieved.This method involves the introduction of ferromagnetic (FM) or superparamagnetic (SPM) nanoparticles suspended in carrier liquids, into the tumor tissue and then irradiation with an AC magnetic field. The particles transform the energy of the AC magnetic field into heat by several physical mechanisms, and the transformation efficiency strongly depends on the frequency of the external field as well as the nature of the particles such as magnetism and surface modification. Consequently, large power losses of the magnetic materials are desirable in order to reduce the amount of material to be applied to a patient. The study of the mechanism of power loss is of intense interest currently with the aim to enhance the heating power of magnetic materials without demaging the healty tissues.In this proposed thesis, a series of Co-ferrite nanoparticles with different sizes were prepared by high temperature decomposition method. The particle size of the nanoparticles controlled by varying preparation parameters and then the formation of phases and crystal structures had confirmed by spectroscopic (XRD, EDX) and microscopic (SEM, TEM) studies.The goal of the proposed project is to gain deeper insight into the heat generation mechanisms in magnetic nanoparticles over a broad size range from superparamagnetic to stable ferromagnetic particles and to clarify how the particle properties and the electromagnetic field parameters may be optimized for future applications. 114

Published

2010

102. A YOLO-V5 approach for the evaluation of normal fillings and overhanging fillings: an artificial intelligence study.

Author

Akgül N, Yilmaz C, Bilgir E, Çelik Ö, Baydar O, and Bayrakdar İŞ

Subjects

Humans, Reproducibility of Results, Artificial Intelligence, Reference Values, Algorithms, Radiography, Panoramic, Dental Restoration, Permanent methods

Abstract

Dental fillings, frequently used in dentistry to address various dental tissue issues, may pose problems when not aligned with the anatomical contours and physiology of dental and periodontal tissues. Our study aims to detect the prevalence and distribution of normal and overhanging filling restorations using a deep CNN architecture trained through supervised learning, on panoramic radiography images. A total of 10480 fillings and 2491 overhanging fillings were labeled using CranioCatch software from 2473 and 1850 images, respectively. After the data obtaining phase, validation (80%), training 10%), and test-groups (10%) were formed from images for both labelling. The YOLOv5x architecture was used to develop the AI model. The model's performance was assessed through a confusion matrix and sensitivity, precision, and F1 score values of the model were calculated. For filling, sensitivity is 0.95, precision is 0.97, and F1 score is 0.96; for overhanging were determined to be 0.86, 0.89, and 0.87, respectively. The results demonstrate the capacity of the YOLOv5 algorithm to segment dental radiographs efficiently and accurately and demonstrate proficiency in detecting and distinguishing between normal and overhanging filling restorations.

Published

2024

103. Classification of Periapical and Bitewing Radiographs as Periodontally Healthy or Diseased by Deep Learning Algorithms.

Author

Yavuz MB, Sali N, Kurt Bayrakdar S, Ekşi C, İmamoğlu BS, Bayrakdar İŞ, Çelik Ö, and Orhan K

Abstract

Objectives The aim of this artificial intelligence (AI) study was to develop a deep learning algorithm capable of automatically classifying periapical and bitewing radiography images as either periodontally healthy or unhealthy and to assess the algorithm's diagnostic success. Materials and methods The sample of the study consisted of 1120 periapical radiographs (560 periodontally healthy, 560 periodontally unhealthy) and 1498 bitewing radiographs (749 periodontally healthy, 749 periodontally ill). From the main datasets of both radiography types, three sub-datasets were randomly created: a training set (80%), a validation set (10%), and a test set (10%). Using these sub-datasets, a deep learning algorithm was developed with the YOLOv8-cls model (Ultralytics, Los Angeles, California, United States) and trained over 300 epochs. The success of the developed algorithm was evaluated using the confusion matrix method. Results The AI algorithm achieved classification accuracies of 75% or higher for both radiograph types. For bitewing radiographs, the sensitivity, specificity, precision, accuracy, and F1 score values were 0.8243, 0.7162, 0.7439, 0.7703, and 0.7821, respectively. For periapical radiographs, the sensitivity, specificity, precision, accuracy, and F1 score were 0.7500, 0.7500, 0.7500, 0.7500, and 0.7500, respectively. Conclusion The AI models developed in this study demonstrated considerable success in classifying periodontal disease. Future applications may involve employing AI algorithms for assessing periodontal status across various types of radiography images and for automated disease detection., Competing Interests: The authors have declared that no competing interests exist., (Copyright © 2024, Yavuz et al.)

Published

2024

104. [Segmentation of acute pulmonary embolism in computed tomography pulmonary angiography using the deep learning method].

Author

Aydın N, Cihan Ç, Çelik Ö, Aslan AF, Odabaş A, Alataş F, and Yıldırım H

Subjects

Humans, Middle Aged, Aged, Retrospective Studies, Tomography, X-Ray Computed, Acute Disease, Angiography methods, Deep Learning, Pulmonary Embolism diagnostic imaging

Abstract

Introduction: Pulmonary embolism is a type of thromboembolism seen in the main pulmonary artery and its branches. This study aimed to diagnose acute pulmonary embolism using the deep learning method in computed tomographic pulmonary angiography (CTPA) and perform the segmentation of pulmonary embolism data., Materials and Methods: The CTPA images of patients diagnosed with pulmonary embolism who underwent scheduled imaging were retrospectively evaluated. After data collection, the areas that were diagnosed as embolisms in the axial section images were segmented. The dataset was divided into three parts: training, validation, and testing. The results were calculated by selecting 50% as the cut-off value for the intersection over the union., Result: Images were obtained from 1.550 patients. The mean age of the patients was 64.23 ± 15.45 years. A total of 2.339 axial computed tomography images obtained from the 1.550 patients were used. The PyTorch U-Net was used to train 400 epochs, and the best model, epoch 178, was recorded. In the testing group, the number of true positives was determined as 471, the number of false positives as 35, and 27 cases were not detected. The sensitivity of CTPA segmentation was 0.95, the precision value was 0.93, and the F1 score value was 0.94. The area under the curve value obtained in the receiver operating characteristic analysis was calculated as 0.88., Conclusions: In this study, the deep learning method was successfully employed for the segmentation of acute pulmonary embolism in CTPA, yielding positive outcomes.

Published

2023

105. Performance of a convolutional neural network algorithm for tooth detection and numbering on periapical radiographs.

Author

Görürgöz C, Orhan K, Bayrakdar IS, Çelik Ö, Bilgir E, Odabaş A, Aslan AF, and Jagtap R

Subjects

Algorithms, Humans, Neural Networks, Computer, Retrospective Studies, Artificial Intelligence, Tooth

Abstract

Objectives: The present study aimed to evaluate the performance of a Faster Region-based Convolutional Neural Network (R-CNN) algorithm for tooth detection and numbering on periapical images., Methods: The data sets of 1686 randomly selected periapical radiographs of patients were collected retrospectively. A pre-trained model (GoogLeNet Inception v3 CNN) was employed for pre-processing, and transfer learning techniques were applied for data set training. The algorithm consisted of: (1) the Jaw classification model, (2) Region detection models, and (3) the Final algorithm using all models. Finally, an analysis of the latest model has been integrated alongside the others. The sensitivity, precision, true-positive rate, and false-positive/negative rate were computed to analyze the performance of the algorithm using a confusion matrix., Results: An artificial intelligence algorithm (CranioCatch, Eskisehir-Turkey) was designed based on R-CNN inception architecture to automatically detect and number the teeth on periapical images. Of 864 teeth in 156 periapical radiographs, 668 were correctly numbered in the test data set. The F1 score, precision, and sensitivity were 0.8720, 0.7812, and 0.9867, respectively., Conclusion: The study demonstrated the potential accuracy and efficiency of the CNN algorithm for detecting and numbering teeth. The deep learning-based methods can help clinicians reduce workloads, improve dental records, and reduce turnaround time for urgent cases. This architecture might also contribute to forensic science.

Published

2022

106. Contribution of artificial intelligence applications developed with the deep learning method to the diagnosis of COVID-19 pneumonia on computed tomography.

Author

Aydın N and Çelik Ö

Subjects

Artificial Intelligence, Humans, Retrospective Studies, SARS-CoV-2, Tomography, X-Ray Computed, COVID-19, Deep Learning

Abstract

Introduction: Computed tomography (CT) is an auxiliary modality in the diagnosis of the novel Coronavirus (COVID-19) disease and can guide physicians in the presence of lung involvement. In this study, we aimed to investigate the contribution of deep learning to diagnosis in patients with typical COVID-19 pneumonia findings on CT., Materials and Methods: This study retrospectively evaluated 690 lesions obtained from 35 patients diagnosed with COVID-19 pneumonia based on typical findings on non-contrast high-resolution CT (HRCT) in our hospital. The diagnoses of the patients were also confirmed by other necessary tests. HRCT images were assessed in the parenchymal window. In the images obtained, COVID-19 lesions were detected. For the deep Convolutional Neural Network (CNN) algorithm, the Confusion matrix was used based on a Tensorflow Framework in Python., Result: A total of 596 labeled lesions obtained from 224 sections of the images were used for the training of the algorithm, 89 labeled lesions from 27 sections were used in validation, and 67 labeled lesions from 25 images in testing. Fifty-six of the 67 lesions used in the testing stage were accurately detected by the algorithm while the remaining 11 were not recognized. There was no false positive. The Recall, Precision and F1 score values in the test group were 83.58, 1, and 91.06, respectively., Conclusions: We successfully detected the COVID-19 pneumonia lesions on CT images using the algorithms created with artificial intelligence. The integration of deep learning into the diagnostic stage in medicine is an important step for the diagnosis of diseases that can cause lung involvement in possible future pandemics.

Published

2021

107. Artificial intelligence system for automatic deciduous tooth detection and numbering in panoramic radiographs.

Author

Kılıc MC, Bayrakdar IS, Çelik Ö, Bilgir E, Orhan K, Aydın OB, Kaplan FA, Sağlam H, Odabaş A, Aslan AF, and Yılmaz AB

Subjects

Algorithms, Child, Humans, Radiography, Panoramic, Tooth, Deciduous, Turkey, Artificial Intelligence, Tooth

Abstract

Objective: This study evaluated the use of a deep-learning approach for automated detection and numbering of deciduous teeth in children as depicted on panoramic radiographs., Methods and Materials: An artificial intelligence (AI) algorithm (CranioCatch, Eskisehir-Turkey) using Faster R-CNN Inception v2 (COCO) models were developed to automatically detect and number deciduous teeth as seen on pediatric panoramic radiographs. The algorithm was trained and tested on a total of 421 panoramic images. System performance was assessed using a confusion matrix., Results: The AI system was successful in detecting and numbering the deciduous teeth of children as depicted on panoramic radiographs. The sensitivity and precision rates were high. The estimated sensitivity, precision, and F1 score were 0.9804, 0.9571, and 0.9686, respectively., Conclusion: Deep-learning-based AI models are a promising tool for the automated charting of panoramic dental radiographs from children. In addition to serving as a time-saving measure and an aid to clinicians, AI plays a valuable role in forensic identification.

Published

2021