A multimodal computer‐aided diagnostic system for precise identification of renal allograft rejection: Preliminary results

Shehata, Mohamed; Shalaby, Ahmed; Switala, Andrew E.; El-Baz, Maryam; Ghazal, Mohammed; Fraiwan, Luay; Khalil, Ashraf; El-Ghar, Mohamed Abou; Badawy, Mohamed A.; Bakr, Ashraf M.; Dwyer, Amy C.; Elmaghraby, Adel; Giridharan, Guruprasad A.; Keynton, Robert; El‐Baz, Ayman

doi:10.1002/mp.14109

Cited by 15 publications

(10 citation statements)

References 34 publications

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“…For instance, instead of using generic loss functions from computer vision tasks, like the mean squared error, one could use loss functions that better target the specificities of our medical problem, such as including mutual information for the conversion of different image modalities [90,193] or dose-volume histograms for radiotherapy dose predictions [212]. Regarding the injection of domain-specific knowledge as input to the models, some examples include the addition of electronic health records and clinical data, like text and laboratory results, to the image data [213][214][215], or having first-order prior or approximations of the expected output [175,[216][217][218][219] Integrating domain-specific knowledge cannot only serve to improve the performances of state-of-the-art AI models, but also to increase the interpretability of the results, which is one of the well-acknowledged limitations of the current ML/DL methods [220][221][222][223]. This is the idea behind the so-called Expert Augmented Machine Learning (EAML), whose goal is to develop algorithms capable of extracting human knowledge from a panel of experts and use it to establish constraints for the model's prediction [224].…”

Section: Discussion and Concluding Remarks: Where Do We Go Next?mentioning

confidence: 99%

Artificial intelligence and machine learning for medical imaging: A technology review

Montero¹,

Javaid²,

Valdés

et al. 2021

Physica Medica

164

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Artificial intelligence (AI) has recently become a very popular buzzword, as a consequence of disruptive technical advances and impressive experimental results, notably in the field of image analysis and processing. In medicine, specialties where images are central, like radiology, pathology or oncology, have seized the opportunity and considerable efforts in research and development have been deployed to transfer the potential of AI to clinical applications. With AI becoming a more mainstream tool for typical medical imaging analysis tasks, such as diagnosis, segmentation, or classification, the key for a safe and efficient use of clinical AI applications relies, in part, on informed practitioners. The aim of this review is to present the basic technological pillars of AI, together with the state-of-the-art machine learning methods and their application to medical imaging. In addition, we discuss the new trends and future research directions. This will help the reader to understand how AI methods are now becoming an ubiquitous tool in any medical image analysis workflow and pave the way for the clinical implementation of AI-based solutions.

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Section: Discussion and Concluding Remarks: Where Do We Go Next?mentioning

confidence: 99%

Artificial intelligence and machine learning for medical imaging: A technology review

Montero¹,

Javaid²,

Valdés

et al. 2021

Physica Medica

164

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“…Three additional papers from the same group examined the utility of computer-aided diagnostic (CAD) systems for the diagnosis of acute rejection[ 7 - 9 ]. In their first study[ 7 ], the authors used deep-learning algorithms, namely, ‘stacked non-negative constrained auto-encoders’, for the prediction of acute rejection.…”

Section: Application Of Ai In Kidney Transplantationmentioning

confidence: 99%

“…In a third study[ 9 ], they again assessed the utility of the CAD system for the diagnosis of acute rejection using DW-MRI and blood oxygen level-dependent MRI as the image-based sources. The authors also used laboratory data consisting of creatinine and creatinine clearance.…”

Section: Application Of Ai In Kidney Transplantationmentioning

confidence: 99%

“…The authors also used laboratory data consisting of creatinine and creatinine clearance. In addition, they utilized a deep learning-based classifier, namely, ‘stacked autoencoders’, to differentiate non-rejection from acute rejection in renal transplants[ 9 ]. The overall accuracy of the CAD system in detection of acute rejection was around 90%[ 9 ].…”

Section: Application Of Ai In Kidney Transplantationmentioning

confidence: 99%

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Artificial intelligence and kidney transplantation

Seyahi¹,

Özcan²

2021

WJT

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Artificial intelligence and its primary subfield, machine learning, have started to gain widespread use in medicine, including the field of kidney transplantation. We made a review of the literature that used artificial intelligence techniques in kidney transplantation. We located six main areas of kidney transplantation that artificial intelligence studies are focused on: Radiological evaluation of the allograft, pathological evaluation including molecular evaluation of the tissue, prediction of graft survival, optimizing the dose of immunosuppression, diagnosis of rejection, and prediction of early graft function. Machine learning techniques provide increased automation leading to faster evaluation and standardization, and show better performance compared to traditional statistical analysis. Artificial intelligence leads to improved computer-aided diagnostics and quantifiable personalized predictions that will improve personalized patient care.

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“…This vector was then used as the BOLD-MRI markers (B mrks ) to identify renal allograft status. At 2ms, the BOLD-MRI is at its baseline ET; therefore, the pixel-wise T2* and R2* may be calculated as [18,32]:…”

Section: Diffusion Weighted Image Markersmentioning

confidence: 99%

A Deep Learning-Based Cad System For Renal Allograft Assessment: Diffusion, Bold, And Clinical Biomarkers

Shehata

Ghazal

Khalifeh

et al. 2020

2020 IEEE International Conference on Image Processing (ICIP)

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Recently, studies for non-invasive renal transplant evaluation have been explored to control allograft rejection. In this paper, a computer-aided diagnostic system has been developed to accommodate with an early-stage renal transplant status assessment, called RT-CAD. Our model of this system integrated multiple sources for a more accurate diagnosis: two image-based sources and two clinical-based sources. The image-based sources included apparent diffusion coefficients (ADCs) and the amount of deoxygenated hemoglobin (R2*). More specifically, these ADCs were extracted from 47 diffusion weighted magnetic resonance imaging (DW-MRI) scans at 11 different b-values (b0, b50, b100, …, b1000 s/mm 2 ), while the R2* values were extracted from 30 blood oxygen level-dependent MRI (BOLD-MRI) scans at 5 different echo times (2ms, 7ms, 12ms, 17ms, and 22ms). The clinical sources included serum creatinine (SCr) and creatinine clearance (CrCl). First, the kidney was segmented through the RT-CAD system using a geometric deformable model called a level-set method. Second, both ADCs and R2* were estimated for common patients (N = 30) and then were integrated with the corresponding SCr and CrCl. Last, these integrated biomarkers were considered the discriminatory features to be used as trainers and testers for future deep learning-based classifiers such as stacked auto-encoders (SAEs). We used a k-fold cross-validation criteria to evaluate the RT-CAD system diagnostic performance, which achieved the following scores: 93.3%, 90.0%, and 95.0% in terms of accuracy, sensitivity, and specificity in differentiating between acute renal rejection (AR) and non-rejection (NR). The reliability and completeness of the RT-CAD system was further accepted by the area under the curve score of 0.92. The conclusions ensured that the presented RT-CAD system has a high reliability to diagnose the status of the renal transplant in a non-invasive way.

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A multimodal computer‐aided diagnostic system for precise identification of renal allograft rejection: Preliminary results

Cited by 15 publications

References 34 publications

Artificial intelligence and machine learning for medical imaging: A technology review

Artificial intelligence and machine learning for medical imaging: A technology review

Artificial intelligence and kidney transplantation

A Deep Learning-Based Cad System For Renal Allograft Assessment: Diffusion, Bold, And Clinical Biomarkers

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