Implicit Solutions of the Electrical Impedance Tomography Inverse Problem in the Continuous Domain with Deep Neural Networks

Strauss, Thilo; Khan, Taufiquar

doi:10.3390/e25030493

Cited by 2 publications

(1 citation statement)

References 44 publications

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“…This difference in performance can be attributed to the complex processing chain involved in obtaining a conductivity map using GI methods. This process requires solving an ill-posed mathematical problem known as the EIT inverse problem [39]. This computational procedure introduces uncertainty in the conductivity map pixels, which are then aggregated to calculate the GI index.…”

Section: Discussionmentioning

confidence: 99%

Machine learning-based bioimpedance assessment of knee osteoarthritis severity

Muñoz,

Mosquera,

Rengifo

et al. 2024

Biomed. Phys. Eng. Express

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This study proposes a multiclass model to classify the severity of knee osteoarthritis (KOA) using bioimpedance measurements. The experimental setup considered three types of measurements using eight electrodes: global impedance with adjacent pattern, global impedance with opposite pattern, and direct impedance measurement, which were taken using an electronic device proposed by authors and based on the Analog Devices AD5933 impedance converter. The study comprised 37 participants, 25 with healthy knees and 13 with three different degrees of KOA. All participants performed 20 repetitions of each of the following five tasks: (i) sitting withthe knee bent, (ii) sitting with the knee extended, (iii) sitting and performing successive extensions and flexions of the knee, (iv) standing, and (v) walking. Data from the 15 experimental setups (3 types of measurements × 5 exercises) were used to train a multiclass random forest. The training and validation cycle was repeated 100 times using random undersampling. At each of the 100 cycles, 80% of the data were used for training and the rest for testing. The results showed that the proposed approach achieved average sensitivities and specificities of 100% for the four KAO severity grades in the extensión, cyclic, and gait tasks. This suggests that the proposed method can serve as a screening tool to determine which individuals should undergo X-rays or magnetic resonance imaging for further evaluation of KOA.

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Section: Discussionmentioning

confidence: 99%

Machine learning-based bioimpedance assessment of knee osteoarthritis severity

Muñoz,

Mosquera,

Rengifo

et al. 2024

Biomed. Phys. Eng. Express

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MUSCLE: Muscle Understanding through Synthetic Computation and Lesion Evaluation A Semi-Synthetic Dataset for Hamstring Injury Prediction Using Electrical Impedance

Youssef Baby,

Shehayib,

Maalouf

2024

Preprint

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Hamstring Injuries (HSIs) are common among athletes and necessitate extended rehabilitation before Return to Sport (RTS). Post-injury, athletes undergo physical examinations, which often fall short in assessing injury severity or guiding rehabilitation. Therefore, imaging techniques such as Magnetic Resonance Imaging (MRI) are used to evaluate the injury more comprehensively, aiding in the assessment of optimal rehabilitation and RTS timelines. Given the significant impact of HSIs on athletic careers, early prediction is essential. This article investigates the use of Electrical Impedance Tomography (EIT) for HSI prediction. EIT, a noninvasive method, involves injecting a current or voltage into the affected area to detect property changes, allowing for real-time monitoring and supporting its role in HSI prediction. A semi-synthetic dataset was created using MRI scans of patients with hamstring injuries. The dataset was developed by mapping the boundaries of the hamstring muscles (semimembranosus, semitendinosus, and biceps femoris) with Electrical Impedance Tomography and Diffuse Optical Tomography Reconstruction Software (EIDORS). EIDORS generated EIT voltage measurements by defining muscle boundaries and setting appropriate properties, forming the basis for the dataset. Machine Learning (ML) models were then employed to validate the dataset by distinguishing between injured and healthy hamstrings. The best-performing model, Random Forest (RF), achieved an accuracy of 98%, demonstrating the potential of EIT in predicting HSIs.

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Implicit Solutions of the Electrical Impedance Tomography Inverse Problem in the Continuous Domain with Deep Neural Networks

Cited by 2 publications

References 44 publications

Machine learning-based bioimpedance assessment of knee osteoarthritis severity

Machine learning-based bioimpedance assessment of knee osteoarthritis severity

MUSCLE: Muscle Understanding through Synthetic Computation and Lesion Evaluation A Semi-Synthetic Dataset for Hamstring Injury Prediction Using Electrical Impedance

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