Detection of Degenerative Changes on MR Images of the Lumbar Spine with a Convolutional Neural Network: A Feasibility Study

Lehnen, Nils Christian; Haase, Robert; Faber, Jennifer; Rüber, Theodor; Vatter, Hartmut; Radbruch, Alexander; Schmeel, Frederic Carsten

doi:10.3390/diagnostics11050902

Cited by 27 publications

(20 citation statements)

References 45 publications

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“…The results of our work confirmed previously performed studies that dealt with the dynamic load of people in vehicles [ 5 , 10 , 19 , 25 , 26 ]. This issue needs to be further addressed.…”

Section: Discussionsupporting

confidence: 89%

“…As mentioned above, the dynamic loads and response of the vehicle crew are often an issue. This article develops the results of a pilot measurement carried out in 2019 [ 25 ]. An earlier pilot measurement proved the suitability of the set measuring chain as well as the suitability of the used acceleration sensors for measuring the dynamic load of the vehicle crew.…”

Section: Introductionmentioning

confidence: 99%

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Load Measurement of the Cervical Vertebra C7 and the Head of Passengers of a Car While Driving across Uneven Terrain

Svoboda

Chalupa

Jelen

et al. 2021

Sensors

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The article deals with the measurement of dynamic effects that are transmitted to the driver (passenger) when driving in a car over obstacles. The measurements were performed in a real environment on a defined track at different driving speeds and different distributions of obstacles on the road. The reaction of the human organism, respectively the load of the cervical vertebrae and the heads of the driver and passenger, was measured. Experimental measurements were performed for different variants of driving conditions on a 28-year-old and healthy man. The measurement’s main objective was to determine the acceleration values of the seats in the vehicle in the vertical movement of parts of the vehicle cabin and to determine the dynamic effects that are transmitted to the driver and passenger in a car when driving over obstacles. The measurements were performed in a real environment on a defined track at various driving speeds and diverse distributions of obstacles on the road. The acceleration values on the vehicle’s axles and the structure of the driver’s and front passenger’s seats, under the buttocks, at the top of the head (Vertex Parietal Bone) and the C7 cervical vertebra (Vertebra Cervicales), were measured. The result of the experiment was to determine the maximum magnitudes of acceleration in the vertical direction on the body of the driver and the passenger of the vehicle when passing a passenger vehicle over obstacles. The analysis of the experiment’s results is the basis for determining the future direction of the research.

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“…The results of our work confirmed previously performed studies that dealt with the dynamic load of people in vehicles [ 5 , 10 , 19 , 25 , 26 ]. This issue needs to be further addressed.…”

Section: Discussionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Load Measurement of the Cervical Vertebra C7 and the Head of Passengers of a Car While Driving across Uneven Terrain

Svoboda

Chalupa

Jelen

et al. 2021

Sensors

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“…According to the results of their study, the differences in BMD between subjects without and those with single or ≥2 sites of lumbar disc herniation were not statistically significant, and no associations between BMD and lumbar disc herniation were observed in either men or women [ 25 ]. The degenerative spine was also in the focus of a study by Lehnen et al, who aimed to detect a variety of different degenerative changes of the lumbar spine (including presence of disc herniation, disc bulging, spinal canal stenosis, nerve root compression, and spondylolisthesis) by means of a convolutional neural network (CNN) trained on multiple MRI-based features [ 26 ]. Including T2-weighted imaging with labeling of vertebrae and IVD segments in 146 patients, the CNN-based algorithm’s diagnostic accuracy and consistency in relation to visual radiological image reading was evaluated, revealing perfect accuracy for IVD detection and labeling (100%) and moderate to high diagnostic accuracy for the detection of disc herniations (87%) or bulgings (76%) [ 26 ].…”

mentioning

confidence: 99%

“…The degenerative spine was also in the focus of a study by Lehnen et al, who aimed to detect a variety of different degenerative changes of the lumbar spine (including presence of disc herniation, disc bulging, spinal canal stenosis, nerve root compression, and spondylolisthesis) by means of a convolutional neural network (CNN) trained on multiple MRI-based features [ 26 ]. Including T2-weighted imaging with labeling of vertebrae and IVD segments in 146 patients, the CNN-based algorithm’s diagnostic accuracy and consistency in relation to visual radiological image reading was evaluated, revealing perfect accuracy for IVD detection and labeling (100%) and moderate to high diagnostic accuracy for the detection of disc herniations (87%) or bulgings (76%) [ 26 ]. Furthermore, its accuracy for the detection of spinal canal stenosis (98%), nerve root compression (91%), and spondylolisthesis (87.6%) was also high [ 26 ].…”

mentioning

confidence: 99%

“…Including T2-weighted imaging with labeling of vertebrae and IVD segments in 146 patients, the CNN-based algorithm’s diagnostic accuracy and consistency in relation to visual radiological image reading was evaluated, revealing perfect accuracy for IVD detection and labeling (100%) and moderate to high diagnostic accuracy for the detection of disc herniations (87%) or bulgings (76%) [ 26 ]. Furthermore, its accuracy for the detection of spinal canal stenosis (98%), nerve root compression (91%), and spondylolisthesis (87.6%) was also high [ 26 ]. These results suggest that evaluation of the degenerative spine with support by a CNN-based algorithm may automate image assessments, thus potentially limiting time expenses and efforts by radiologists.…”

mentioning

confidence: 99%

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Editorial on Special Issue “Spine Imaging: Novel Image Acquisition Techniques and Analysis Tools”

Sollmann

Baum

2022

Diagnostics

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Deep Learning Model for Grading and Localization of Lumbar Disc Herniation on Magnetic Resonance Imaging

Xu,

Zheng,

Tian

et al. 2024

Magnetic Resonance Imaging

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BackgroundMethods for grading and localization of lumbar disc herniation (LDH) on MRI are complex, time‐consuming, and subjective. Utilizing deep learning (DL) models as assistance would mitigate such complexities.PurposeTo develop an interpretable DL model capable of grading and localizing LDH.Study TypeRetrospective.Subjects1496 patients (M/F: 783/713) were evaluated, and randomly divided into training (70%), validation (10%), and test (20%) sets.Field Strength/Sequence1.5T MRI for axial T2‐weighted sequences (spin echo).AssessmentThe training set was annotated by three spinal surgeons using the Michigan State University classification to train the DL model. The test set was annotated by a spinal surgery expert (as ground truth labels), and two spinal surgeons (comparison with the trained model). An external test set was employed to evaluate the generalizability of the DL model.Statistical TestsCalculated intersection over union (IoU) for detection consistency, utilized Gwet's AC1 to assess interobserver agreement, and evaluated model performance based on sensitivity and specificity, with statistical significance set at P < 0.05.ResultsThe DL model achieved high detection consistency in both the internal test dataset (grading: mean IoU 0.84, recall 99.6%; localization: IoU 0.82, recall 99.5%) and external test dataset (grading: 0.72, 98.0%; localization: 0.71, 97.6%). For internal testing, the DL model (grading: 0.81; localization: 0.76), Rater 1 (0.88; 0.82), and Rater 2 (0.86; 0.83) demonstrated results highly consistent with the ground truth labels. The overall sensitivity of the DL model was 87.0% for grading and 84.0% for localization, while the specificity was 95.5% and 94.4%. For external testing, the DL model showed an appreciable decrease in consistency (grading: 0.69; localization: 0.66), sensitivity (77.2%; 76.7%), and specificity (92.3%; 91.8%).Data ConclusionThe classification capabilities of the DL model closely resemble those of spinal surgeons. For future improvement, enriching the diversity of cases could enhance the model's generalization.Level of Evidence4.Technical EfficacyStage 2.

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Detection of Degenerative Changes on MR Images of the Lumbar Spine with a Convolutional Neural Network: A Feasibility Study

Cited by 27 publications

References 45 publications

Load Measurement of the Cervical Vertebra C7 and the Head of Passengers of a Car While Driving across Uneven Terrain

Load Measurement of the Cervical Vertebra C7 and the Head of Passengers of a Car While Driving across Uneven Terrain

Editorial on Special Issue “Spine Imaging: Novel Image Acquisition Techniques and Analysis Tools”

Deep Learning Model for Grading and Localization of Lumbar Disc Herniation on Magnetic Resonance Imaging

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