Accelerated 4D self‐gated MRI of tibiofemoral kinematics

Mazzoli, Valentina; Schoormans, Jasper; Froeling, Martijn; Sprengers, Amj; Coolen, Bram F.; Strijkers, Gustav J.; Nederveen, Aart J.

doi:10.1002/nbm.3791

Cited by 15 publications

(13 citation statements)

References 34 publications

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“…More recently, screen printed MRI coils 129,130 and adaptive image receive (AIR) coils 131 have been developed to further enhance the flexibility of coils to conform to multiple forms of anatomy while being inherently lightweight. In addition, new high‐impedance detectors 132 and stretchable RF conductors 133 formed by liquid metal have been incorporated into wearable and even stretchable coils, which may not only optimize SNR for an anatomy of interest, but also optimize imaging during movement in order to assess tissue biomechanics 134 . In combination with more efficient pulse sequences, improved hardware promises better access and flexibility for imaging bones and joints while improving scan times and patient comfort.…”

Section: Hardware Improvementsmentioning

confidence: 99%

Rapid Knee MRI Acquisition and Analysis Techniques for Imaging Osteoarthritis

Chaudhari

Kogan

Pedoia

et al. 2019

Magnetic Resonance Imaging

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Osteoarthritis (OA) of the knee is a major source of disability that has no known treatment or cure. Morphological and compositional MRI is commonly used for assessing the bone and soft tissues in the knee to enhance the understanding of OA pathophysiology. However, it is challenging to extend these imaging methods and their subsequent analysis techniques to study large population cohorts due to slow and inefficient imaging acquisition and postprocessing tools. This can create a bottleneck in assessing early OA changes and evaluating the responses of novel therapeutics. The purpose of this review article is to highlight recent developments in tools for enhancing the efficiency of knee MRI methods useful to study OA. Advances in efficient MRI data acquisition and reconstruction tools for morphological and compositional imaging, efficient automated image analysis tools, and hardware improvements to further drive efficient imaging are discussed in this review. For each topic, we discuss the current challenges as well as potential future opportunities to alleviate these challenges. Level of Evidence 5 Technical Efficacy Stage 3

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Section: Hardware Improvementsmentioning

confidence: 99%

Rapid Knee MRI Acquisition and Analysis Techniques for Imaging Osteoarthritis

Chaudhari

Kogan

Pedoia

et al. 2019

Magnetic Resonance Imaging

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“…Although using a robotic trolley or gantry carrying the fluoroscopic system following the movement of subject extends the FOV, the radiation exposure to the subject remains inevitable. Recently advanced four-dimensional (4D) MRI [30][31][32] and CT [33,34] techniques have been reported to track the bone motion and to quantify the respective joint kinematics inside the scanners [30][31][32]. The disadvantages of this method are the limited FOV, limited sample rate, and the inability to measure kinematics during daily activities.…”

Section: Introductionmentioning

confidence: 99%

A Novel Ultrasound-Based Lower Extremity Motion Tracking System

Niu¹,

Sluiter²,

Homminga³

et al. 2018

Advances in Experimental Medicine and Biology

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Tracking joint motion of the lower extremity is important for human motion analysis. In this study, we present a novel ultrasoundbased motion tracking system for measuring three-dimensional (3D) position and orientation of the femur and tibia in 3D space and quantifying tibiofemoral kinematics under dynamic conditions. As ultrasound is capable of detecting underlying bone surface noninvasively through multiple layers of soft tissues, an integration of multiple A-mode ultrasound transducers with a conventional motion tracking system provides a new approach to track the motion of bone segments during dynamic conditions. To demonstrate the technical and clinical feasibilities of this concept, an in vivo experiment was conducted. For this purpose the kinematics of healthy individuals were determined in treadmill walking conditions and stair descending tasks. The results clearly demonstrated the potential of tracking skeletal motion of the lower extremity and measuring

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“…8,9 This kind of evoked contractions can be used for the study of specific muscles or muscle groups. Often, gated sequences are used that combine data acquired from multiple contractions, 1,8,10 and therefore periodicity is necessary. However, in this case, the exercise is defined not by the load or the distance but by the force induced, so repeatability of the contraction presents a bigger challenge.…”

Section: Introductionmentioning

confidence: 99%

OpenForce MR: A low‐cost open‐source MR‐compatible force sensor

Santini

Bieri

Deligianni

2018

Concepts Magn Reson

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Measuring the force exerted by muscles during dynamic MR acquisition (either imaging or spectroscopy) provides important information for the standardization of the exercise performed in the scanner and is therefore important for reproducible results in musculoskeletal imaging. However, existing commercial solutions for such measurements are often very expensive and impractical. In this work, a novel, open‐source, versatile force sensor made of non‐magnetic, off‐the‐shelf components is presented. The sensor is based on four aluminum Wheatstone bridge load cells enclosed in a custom‐built aluminum frame. These cells are connected to an Arduino microcontroller for data acquisition and serial communication with a host computer, on which a dedicated program visualizes and logs the recorded force in real time. All components were chosen to be compatible with the MR environment, commercially available, and low cost. The sensor was calibrated with a commercial dynamometer and subsequently tested in multiple MR acquisition scenarios (static morphological imaging, cine imaging during contraction, velocity‐encoded imaging). The sensor correctly recorded data during all tested sequences, without cross‐interference between the MR and the force acquisitions. Minor susceptibility artifacts are visible in the immediate vicinity of the sensor, but they did not impair the evaluation of the muscle of interest. In conclusion, the development of a low‐cost, MR‐compatible force sensor is feasible, and its usage does not interfere with MR acquisition. The full specifications of the sensor, including hardware design, firmware and host software are publicly released as open‐source for the potential benefit of the whole community.

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Accelerated 4D self‐gated MRI of tibiofemoral kinematics

Cited by 15 publications

References 34 publications

Rapid Knee MRI Acquisition and Analysis Techniques for Imaging Osteoarthritis

Rapid Knee MRI Acquisition and Analysis Techniques for Imaging Osteoarthritis

A Novel Ultrasound-Based Lower Extremity Motion Tracking System

OpenForce MR: A low‐cost open‐source MR‐compatible force sensor

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