Your search keyword '"Oudeman, J."' showing total 7 results

1. Reliability of in vivo determination of forearm muscle volume using 3.0 T magnetic resonance imaging

Author

Smeulders, M.J.C., primary, van den Berg, S., additional, Oudeman, J., additional, Nederveen, A.J., additional, Kreulen, M., additional, and Maas, M., additional

Published

2010

2. Zusatz zu meinen Beobachtungen der Bellona und Amphitrite

Author

Oudeman, J. A. C., primary

Published

1854

3. Diffusion tensor imaging and quantitative T2 mapping to monitor muscle recovery following hamstring injury.

Author

Monte JR, Hooijmans MT, Froeling M, Oudeman J, Tol JL, Strijkers GJ, Nederveen AJ, and Maas M

Subjects

Male, Female, Humans, Young Adult, Adult, Prospective Studies, Diffusion Magnetic Resonance Imaging methods, Magnetic Resonance Imaging, Diffusion Tensor Imaging methods, Hamstring Muscles diagnostic imaging

Abstract

MRI examinations are accurate for diagnosing sports-related acute hamstring injuries. However, sensitive imaging methods for assessing recovery of these injuries are lacking. Diffusion tensor imaging (DTI) and quantitative T2 (qT2) mapping have both shown promise for assessing recovery of muscle micro trauma and exercise effects. The purpose of this study was to explore the potential of DTI and qT2 mapping for monitoring the muscle recovery processes after acute hamstring injury. In this prospective study, athletes with an acute hamstring injury underwent a 3-T MRI examination of the injured and contralateral hamstrings including DTI and qT2 measurements at three time points: (1) within 1 week after sustaining the injury, (2) 2 weeks after time point 1, and (3) return to play (RTP). A linear mixed model was used for time-effect analysis and paired t-tests for the detection of differences between injured and uninjured muscles. Forty-one athletes (age 27.8 ± 7 years; two females and 39 males) were included. Mean RTP time was 50 (range 12-169) days. A significant time effect was found for mean diffusivity, radial diffusivity, and the second and third eigenvalues (p ≤ 0.001) in the injured muscles. Fractional anisotropy (p = 0.40), first eigenvalue (p = 0.02), and qT2 (p = 0.61) showed no significant time effect. All DTI indices, except for fractional anisotropy, were significantly elevated compared with control muscles right after the injury (p < 0.001). Values normalized during the recovery period, with no significant differences between control and injured muscles at RTP (p values ranged from 0.08 to 0.51). Mean qT2 relaxation times in injured muscles were not significantly elevated compared with control muscles at any time point (p > 0.04). In conclusion, DTI can be used to monitor recovery after an acute hamstring injury. Future work should explore the potential of DTI indices to predict RTP and recovery times in athletes after an acute strain injury., (© 2023 The Authors. NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published

2023

4. Water and fat separation in real-time MRI of joint movement with phase-sensitive bSSFP.

Author

Mazzoli V, Nederveen AJ, Oudeman J, Sprengers A, Nicolay K, Strijkers GJ, and Verdonschot N

Subjects

Computer Systems, Female, Humans, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Male, Reproducibility of Results, Sensitivity and Specificity, Subtraction Technique, Young Adult, Adipose Tissue diagnostic imaging, Body Water diagnostic imaging, Joints diagnostic imaging, Joints physiology, Magnetic Resonance Imaging methods, Range of Motion, Articular physiology, Signal Processing, Computer-Assisted

Abstract

Purpose: To introduce a method for obtaining fat-suppressed images in real-time MRI of moving joints at 3 Tesla (T) using a bSSFP sequence with phase detection to enhance visualization of soft tissue structures during motion., Methods: The wrist and knee of nine volunteers were imaged with a real-time bSSFP sequence while performing dynamic tasks. For appropriate choice of sequence timing parameters, water and fat pixels showed an out-of-phase behavior, which was exploited to reconstruct water and fat images. Additionally, a 2-point Dixon sequence was used for dynamic imaging of the joints, and resulting water and fat images were compared with our proposed method., Results: The joints could be visualized with good water-fat separation and signal-to-noise ratio (SNR), while maintaining a relatively high temporal resolution (5 fps in knee imaging and 10 fps in wrist imaging). The proposed method produced images of moving joints with higher SNR and higher image quality when compared with the Dixon method., Conclusions: Water-fat separation is feasible in real-time MRI of moving knee and wrist at 3 T. PS-bSSFP offers movies with higher SNR and higher diagnostic quality when compared with Dixon scans. Magn Reson Med 78:58-68, 2017. © 2016 International Society for Magnetic Resonance in Medicine., (© 2016 International Society for Magnetic Resonance in Medicine.)

Published

2017

5. Skeletal muscle diffusion tensor-MRI fiber tracking: rationale, data acquisition and analysis methods, applications and future directions.

Author

Damon BM, Froeling M, Buck AK, Oudeman J, Ding Z, Nederveen AJ, Bush EC, and Strijkers GJ

Subjects

Algorithms, Animals, Humans, Image Enhancement methods, Reproducibility of Results, Sensitivity and Specificity, Diffusion Tensor Imaging methods, Forecasting, Image Interpretation, Computer-Assisted methods, Muscle Fibers, Skeletal cytology, Muscle, Skeletal cytology, Muscle, Skeletal diagnostic imaging

Abstract

The mechanical functions of muscles involve the generation of force and the actuation of movement by shortening or lengthening under load. These functions are influenced, in part, by the internal arrangement of muscle fibers with respect to the muscle's mechanical line of action. This property is known as muscle architecture. In this review, we describe the use of diffusion tensor (DT)-MRI muscle fiber tracking for the study of muscle architecture. In the first section, the importance of skeletal muscle architecture to function is discussed. In addition, traditional and complementary methods for the assessment of muscle architecture (brightness-mode ultrasound imaging and cadaver analysis) are presented. Next, DT-MRI is introduced and the structural basis for the reduced and anisotropic diffusion of water in muscle is discussed. The third section discusses issues related to the acquisition of skeletal muscle DT-MRI data and presents recommendations for optimal strategies. The fourth section discusses methods for the pre-processing of DT-MRI data, the available approaches for the calculation of the diffusion tensor and the seeding and propagating of fiber tracts, and the analysis of the tracking results to measure structural properties pertinent to muscle biomechanics. Lastly, examples are presented of how DT-MRI fiber tracking has been used to provide new insights into how muscles function, and important future research directions are highlighted. Copyright © 2016 John Wiley & Sons, Ltd., (Copyright © 2016 John Wiley & Sons, Ltd.)

Published

2017

6. Assessment of passive muscle elongation using Diffusion Tensor MRI: Correlation between fiber length and diffusion coefficients.

Author

Mazzoli V, Oudeman J, Nicolay K, Maas M, Verdonschot N, Sprengers AM, Nederveen AJ, Froeling M, and Strijkers GJ

Subjects

Adult, Humans, Male, Reproducibility of Results, Sensitivity and Specificity, Statistics as Topic, Tensile Strength physiology, Diffusion Tensor Imaging methods, Image Interpretation, Computer-Assisted methods, Muscle Fibers, Skeletal cytology, Muscle Fibers, Skeletal physiology, Muscle, Skeletal anatomy & histology, Muscle, Skeletal diagnostic imaging, Muscle, Skeletal physiology

Abstract

In this study we investigated the changes in fiber length and diffusion parameters as a consequence of passive lengthening and stretching of the calf muscles. We hypothesized that changes in radial diffusivity (RD) are caused by changes in the muscle fiber cross sectional area (CSA) as a consequence of lengthening and shortening of the muscle. Diffusion Tensor MRI (DT-MRI) measurements were made twice in five healthy volunteers, with the foot in three different positions (30° plantarflexion, neutral position and 15° dorsiflexion). The muscles of the calf were manually segmented on co-registered high resolution anatomical scans, and maps of RD and axial diffusivity (AD) were reconstructed from the DT-MRI data. Fiber tractography was performed and mean fiber length was calculated for each muscle group. Significant negative correlations were found between the changes in RD and changes in fiber length in the dorsiflexed and plantarflexed positions, compared with the neutral foot position. Changes in AD did not correlate with changes in fiber length. Assuming a simple cylindrical model with constant volume for the muscle fiber, the changes in the muscle fiber CSA were calculated from the changes in fiber length. In line with our hypothesis, we observed a significant positive correlation of the CSA with the measured changes in RD. In conclusion, we showed that changes in diffusion coefficients induced by passive muscle stretching and lengthening can be explained by changes in muscle CSA, advancing the physiological interpretation of parameters derived from skeletal muscle DT-MRI., (Copyright © 2016 John Wiley & Sons, Ltd.)

Published

2016

7. Reproducibility of diffusion tensor imaging in human forearm muscles at 3.0 T in a clinical setting.

Author

Froeling M, Oudeman J, van den Berg S, Nicolay K, Maas M, Strijkers GJ, Drost MR, and Nederveen AJ

Subjects

Adult, Female, Humans, Image Enhancement methods, Male, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Diffusion Magnetic Resonance Imaging methods, Forearm anatomy & histology, Image Interpretation, Computer-Assisted methods, Muscle, Skeletal anatomy & histology

Abstract

The aim of the present study was to evaluate a fast clinical protocol to enable diffusion tensor imaging of the human forearm and assess the reproducibility of six diffusion tensor imaging parameters, i.e., the tensor eigenvalues (λ(1), λ(2), and λ(3)), mean diffusivity, fractional anisotropy, and ellipsoid eccentricity. The right forearms of 10 healthy volunteers were scanned twice, with a 1-week interval. Reproducibility of the diffusion tensor imaging parameters was interpreted using Bland-Altman plots, coefficient of repeatability, repeatability index, and the intraclass correlation coefficient. Analysis was done for three regions of interest: the whole muscle volume, flexor digitorum profundus, and extensor digitorum. The Bland-Altman analysis showed that there is good agreement between the two measurements. Based on the intraclass correlation coefficients, agreement was substantial (0.59 < intraclass correlation coefficient < 0.92) for all six parameters of the whole muscle volume and flexor digitorum profundus but only fair (0.18 < intraclass correlation coefficient < 0.64) for the extensor digitorum. Using a 7 min 40 sec scan protocol, which was well tolerated by the volunteers, the reproducibility of diffusion tensor imaging parameters was demonstrated. However, repeatability varies, depending on the region of interest and diffusion tensor imaging parameters. This should be taken into account when a longitudinal study is designed.

Published

2010