1.5 T magnetic resonance imaging generates accurate 3D proximal femoral models: Surgical planning implications for femoroacetabular impingement

Malloy, Philip; Gasienica, Jacob; Dawe, Robert J.; Orías, Alejandro A. Espinoza; Nwachukwu, Benedict U.; Inoue, Nozomu; Yanke, Adam B.; Nho, Shane J.

doi:10.1002/jor.24596

Cited by 21 publications

(70 citation statements)

References 35 publications

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“…On the one hand, MRI can visualize the cartilage surface. Besides, recent developments in image analysis techniques have enabled 3D morphological analysis based on MRI both from other groups and our own research [30,31]. Further investigations, which are based on an evaluation method that considers cartilage thickness, such as MRI, are necessary to validate the present results.…”

Section: Plos Onementioning

confidence: 72%

Three-dimensional curvature mismatch of the acetabular radius to the femoral head radius is increased in borderline dysplastic hips

et al. 2020

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Whether borderline hip dysplasia is pathologic remains unclear. In order to evaluate the three-dimensional joint congruity, this study sought to answer the question: are borderline dysplastic hip curvature mismatch and eccentricity between the acetabulum and the femoral head different from dysplastic or control hips three-dimensionally? The 113 hips, categorized as: dysplastic (LCEA � 20˚), 47 hips; borderline (20˚� LCEA < 25˚), 32 hips; and control (25˚� LCEA < 35˚), 34 hips; were evaluated. Three-dimensional (3D) femoral and coxal bone models were reconstructed from CT images. Using a custom-written Visual C++ routine, the femoral head and acetabular radii of curvature, and the femoral head and the acetabular curvature center were calculated. Then the ratio of the acetabular radius to the femoral head radius (3D curvature mismatch ratio), and the distance between the acetabular curvature center and the femoral head center (3D center discrepancy distance) were calculated. These indices were compared statistically among the three groups using Tukey's post hoc test. The mean 3D curvature mismatch ratio in the borderline (1.13 ± 0.05) was smaller than in the dysplasia (1.23 ± 0.08, p < 0.001), and larger than in the control (1.07 ± 0.02, p < 0.001). The mean 3D center discrepancy distance in the borderline (3.2 ± 1.4 mm) was smaller than in the dysplasia (4.8 ± 2.3, p < 0.001) and larger than in the control (1.6 ± 0.7, p < 0.001). These results demonstrated that three-dimensional congruity of the borderline dysplastic hip is impaired, but its incongruity is not as severe as in dysplastic hips. The 3D curvature mismatch ratio and the 3D center discrepancy distance can be valuable signs of joint congruity in patients with borderline dysplasia. However, future studies are necessary to clarify any associations between curvature mismatch and pathogenesis of osteoarthritis in borderline dysplasia.

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Section: Plos Onementioning

confidence: 72%

Three-dimensional curvature mismatch of the acetabular radius to the femoral head radius is increased in borderline dysplastic hips

et al. 2020

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“…Comparisons showed absolute agreement of signed surface-to-surface distances between all 3D models and that the 1.5-T MRI 3D model most closely represented the actual bone surface. 7 In a study evaluating the accuracy of automatic deep learning segmentation of 3D MRI models for planning periacetabular osteotomy in hip dysplasia, there was excellent correlation for femoral head coverage anteversion and inclination between manual segmentation of CT-based and automatic segmentation of MRI-based 3D models. 47 Specific software developed for the planning of periacetabular osteotomy was used to calculate anterior, posterior, and total femoral head coverage, anteversion, inclination, and the extrusion index.…”

Section: Hipmentioning

confidence: 99%

“…Through these preparatory processes, CT-like contrasts of osseous structures can be synthesized using image subtraction postprocessing of dual gradient-recalled echo (GRE) pulse sequences such as with the Dixon technique 7 or mathematical and artificial intelligence (AI)-based processing, [10][11][12] bias-correction algorithm, and rescaling the images using an inverse-logarithmical algorithm in zero echo time (ZTE) MRI techniques. 5 Other volumetric 3D MRI techniques typically do not need preparatory processing before segmentation, such as balanced 3D steady-state coherent pulse sequences (e.g., True-FISP), 3D GRE sequences (e.g., volumetric interpolated breath-hold examination [VIBE]), and 3D fast spin and turbo spin-echo pulse sequences, for example, CUBE from GE Healthcare; Volume Isotropic Turbo Spin Echo Acquisition (VISTA) from Philips, and Sampling Perfection with Application Optimized Contrasts Using Different Flip Angle Evolution (SPACE) from Siemens.…”

Section: Mri Techniques and Postprocessingmentioning

confidence: 99%

“…2 The higher isotropic quality of improved 3D MRI acquisitions enables creating high-quality 3D MRI volume-and surface-rendered models that are more readily available and increasingly being adopted in clinical practice by many institutions. [3][4][5][6][7][8] A practical consideration for creating 3D MRI models is the need for additional time and expertise that can be limiting factors for the widespread use of 3D models. Nevertheless, 3D model postprocessing has become much more efficient over the last 20 years and is expected to improve further with newer and cutting-edge technology.Using 3D CT data, most automated bone segmentation techniques of stand-alone postprocessing software, such as Aquarius (TeraRecon), Vitrea (Vital images), and SyngoVia (Siemens), produce accurate 3D surface depictions of the bony structures based on the large difference of Hounsfield unit values of cortical bone and the surrounding soft tissues.…”

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3D MRI Models of the Musculoskeletal System

Samim

2021

Semin Musculoskelet Radiol

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Computed tomography (CT) is most commonly used to produce three-dimensional (3D) models for evaluating bone and joint morphology in clinical practice. However, 3D models created from magnetic resonance imaging (MRI) data can be equally effective for comprehensive and accurate assessment of osseous and soft tissue structure morphology and pathology. The quality of 3D MRI models has steadily increased over time, with growing potential to replace 3D CT models in various musculoskeletal (MSK) applications. In practice, a single MRI examination for two-dimensional and 3D assessments can increase the value of MRI and simplify the pre- and postoperative imaging work-up. Multiple studies have shown excellent performance of 3D MRI models in shoulder injuries, in the hip in the setting of femoroacetabular impingement, and in the knee for the creation of bone surface models. Therefore, the utility of 3D MRI postprocessed models is expected to continue to rise and broaden in applications. Computer-based and artificial intelligence–assisted postprocessing techniques have tremendous potential to improve the efficiency of 3D model creation, opening many research avenues to validate the applicability of 3D MRI and establish 3D-specific quantitative assessment criteria. We provide a practice-focused overview of 3D MRI acquisition strategies, postprocessing techniques for 3D model creation, MSK applications of 3D MRI models, and an illustration of cases from our daily clinical practice.

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Magnetic Resonance Imaging Versus Computed Tomography for Three‐Dimensional Bone Imaging of Musculoskeletal Pathologies: A Review

Florkow

Willemsen

Mascarenhas

et al. 2022

Magnetic Resonance Imaging

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Magnetic resonance imaging (MRI) is increasingly utilized as a radiation‐free alternative to computed tomography (CT) for the diagnosis and treatment planning of musculoskeletal pathologies. MR imaging of hard tissues such as cortical bone remains challenging due to their low proton density and short transverse relaxation times, rendering bone tissues as nonspecific low signal structures on MR images obtained from most sequences. Developments in MR image acquisition and post‐processing have opened the path for enhanced MR‐based bone visualization aiming to provide a CT‐like contrast and, as such, ease clinical interpretation. The purpose of this review is to provide an overview of studies comparing MR and CT imaging for diagnostic and treatment planning purposes in orthopedic care, with a special focus on selective bone visualization, bone segmentation, and three‐dimensional (3D) modeling. This review discusses conventional gradient‐echo derived techniques as well as dedicated short echo time acquisition techniques and post‐processing techniques, including the generation of synthetic CT, in the context of 3D and specific bone visualization. Based on the reviewed literature, it may be concluded that the recent developments in MRI‐based bone visualization are promising. MRI alone provides valuable information on both bone and soft tissues for a broad range of applications including diagnostics, 3D modeling, and treatment planning in multiple anatomical regions, including the skull, spine, shoulder, pelvis, and long bones. Level of Evidence 3 Technical Efficacy Stage 3

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1.5 T magnetic resonance imaging generates accurate 3D proximal femoral models: Surgical planning implications for femoroacetabular impingement

Cited by 21 publications

References 35 publications

Three-dimensional curvature mismatch of the acetabular radius to the femoral head radius is increased in borderline dysplastic hips

Three-dimensional curvature mismatch of the acetabular radius to the femoral head radius is increased in borderline dysplastic hips

3D MRI Models of the Musculoskeletal System

Magnetic Resonance Imaging Versus Computed Tomography for Three‐Dimensional Bone Imaging of Musculoskeletal Pathologies: A Review

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