一种使用9.4特斯拉磁共振成像区分椎间盘内部组成结构的无损方法。

A Nondestructive Method to Distinguish the Internal Constituent Architecture of the Intervertebral Discs Using 9.4 Tesla Magnetic Resonance Imaging.

作者信息

Wijayathunga Vithanage N, Ridgway John P, Ingham Eileen, Treanor Darren, Carey Duane, Bulpitt Andy, Magee Derek, Damion Robin, Wilcox Ruth K

机构信息

*Institute of Medical and Biological Engineering, University of Leeds, Leeds, United Kingdom†Division of Medical Physics, University of Leeds, Leeds, United Kingdom‡The Leeds Institute of Cancer and Pathology, Leeds Teaching Hospitals NHS Trust, St James's University Hospital, Beckett Street, Leeds, United Kingdom§School of Computing, University of Leeds, Leeds, United Kingdom¶School of Physics and Astronomy, University of Leeds, Leeds, United Kingdom.

出版信息

Spine (Phila Pa 1976). 2015 Dec;40(24):E1315-22. doi: 10.1097/BRS.0000000000001075.

DOI:10.1097/BRS.0000000000001075

PMID:26244404

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4684101/

Abstract

STUDY DESIGN

An in vitro study of the intervertebral disc (IVD) structure using 9.4T magnetic resonance imaging (MRI).

OBJECTIVE

Investigate the potential of ultrahigh-field strength MRI for higher quality 3-dimensional (3D) volumetric MRI datasets of the IVD to better distinguish structural details.

SUMMARY OF BACKGROUND DATA

MRI has the advantages of being nondestructive and 3D in comparison to most techniques used to obtain the structural details of biological tissues, however, its poor image quality at higher resolution is a limiting factor. Ultrahigh-field MRI could improve the imaging of biological tissues but the current understanding of its application for spinal tissue is limited.

METHODS

2 ovine spinal segments (C7-T1, T2-T3) containing the IVD were separately imaged using 2 sequences; 3D spin echo (multislice-multiecho) pulse sequence for the C7-T1 sample and 3D gradient echo (fast-low-angle-shot) pulse sequence for the T2-T3 sample. The C7-T1 sample was subsequently decalcified and imaged again using the same scanning parameters. Histological sections obtained from the decalcified sample were stained followed by digital scanning. Observations from corresponding MRI slices and histological sections were compared as a method of confirmation of morphology captured under MRI. The signal-to-noise ratio (SNR), contrast-to-noise ratio (CNR) and relative-contrast values were calculated for quantitative evaluation of image quality.

RESULTS

Measurements from histology sections and corresponding MRI slices matched well. Both sequences revealed finer details of the IVD structure. Under the spin echo sequence, the annulus lamellae architecture was distinguishable and the SNR and CNR values were higher. The relative contrast was considerably higher between high (nucleus) and low (bone) signal constituents, but between the nucleus and the annulus the relative contrast was low. Under the gradient echo sequence, although the relative contrasts between constituents were poor, the fiber orientation was clearly manifested.

CONCLUSION

The obtained positive results demonstrate the potential of ultrahigh-field strength MRI to nondestructively capture the IVD structure.

LEVEL OF EVIDENCE

N/A.

摘要

研究设计

使用9.4T磁共振成像（MRI）对椎间盘（IVD）结构进行体外研究。

目的

研究超高场强MRI获取更高质量的IVD三维（3D）容积MRI数据集以更好区分结构细节的潜力。

背景数据总结

与大多数用于获取生物组织结构细节的技术相比，MRI具有无损和三维的优点，然而，其在高分辨率下较差的图像质量是一个限制因素。超高场MRI可以改善生物组织的成像，但目前对其在脊柱组织中的应用了解有限。

方法

使用2种序列分别对包含IVD的2个羊脊柱节段（C7-T1、T2-T3）进行成像；对C7-T1样本使用3D自旋回波（多层多回波）脉冲序列，对T2-T3样本使用3D梯度回波（快速低角度激发）脉冲序列。随后对C7-T1样本进行脱钙处理，并使用相同的扫描参数再次成像。从脱钙样本中获取组织学切片，进行染色后进行数字扫描。将相应MRI切片和组织学切片的观察结果进行比较，作为确认MRI下捕获形态的方法。计算信噪比（SNR）、对比噪声比（CNR）和相对对比度值，以定量评估图像质量。

结果

组织学切片和相应MRI切片的测量结果匹配良好。两种序列都揭示了IVD结构的更精细细节。在自旋回波序列下，纤维环板层结构可区分，SNR和CNR值更高。高（髓核）低（骨骼）信号成分之间的相对对比度相当高，但髓核和纤维环之间的相对对比度较低。在梯度回波序列下，尽管成分之间的相对对比度较差，但纤维方向清晰显示。