MRI of Bone Marrow in the Distal Radius: in Vivo Precision of Effective Transverse Relaxation Times

Overview

Journal Eur Radiol

Specialty Radiology

Date 1995 Jan 1

PMID 11539927

Citations 4

Authors

S Grampp

S Majumdar

M Jergas

P Lang

A Gies

H K Genant

Affiliations

Soon will be listed here.

Abstract

The effective transverse relaxation time T2* is influenced by the presence of trabecular bone, and can potentially provide a measure of bone density as well as bone structure. We determined the in vivo precision of T2* in repeated bone marrow measurements. The T2* measurements of the bone marrow of the distal radius were performed twice within 2 weeks in six healthy young volunteers using a modified water-presaturated 3D Gradient-Recalled Acquisition at Steady State (GRASS) sequence with TE 7, 10, 12, 20, and 30; TR 67; flip angle (FA) 90 degrees. An axial volume covering a length of 5.6 cm in the distal radius was measured. Regions of interest (ROIs) were determined manually and consisted of the entire trabecular bone cross-section extending proximally from the radial subchondral endplate. Reproducibility of T2* and area measurements was expressed as the absolute precision error (standard deviation [SD] in ms or mm2) or as the relative precision error (SD/mean x 100, or coefficient of variation [CV] in %) between the two-point measurements. Short-term precision of T2* and area measurements varied depending on section thickness and location of the ROI in the distal radius. Absolute precision errors for T2* times were between 1.3 and 2.9 ms (relative precision errors 3.8-9.5 %) and for area measurements between 20 and 55 mm2 (relative precision errors 5.1-16.4%). This MR technique for quantitative assessment of trabecular bone density showed reasonable reproducibility in vivo and is a promising future tool for the assessment of osteoporosis.

Citing Articles

Quantitative MR Analysis of Changes in the Radius Bone Marrow in Osteoporosis.

De-Levie T, Schiffenbauer Y, Druckmann I, Rouach V, Stern N, Binderman I J Osteoporos. 2024; 2023:7861495.

PMID: 38179189 PMC: 10764646. DOI: 10.1155/2023/7861495.

The Investigation of Bio-impedance Analysis at a Wrist Phantom with Two Pulsatile Arteries.

Yu Y, Lowe A, Anand G, Kalra A, Zhang H Cardiovasc Eng Technol. 2023; 14(6):810-826.

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Towards Estimating Arterial Diameter Using Bioimpedance Spectroscopy: A Computational Simulation and Tissue Phantom Analysis.

Yu Y, Anand G, Lowe A, Zhang H, Kalra A Sensors (Basel). 2022; 22(13).

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A fully automated trabecular bone structural analysis tool based on T2* -weighted magnetic resonance imaging.

Kraiger M, Martirosian P, Opriessnig P, Eibofner F, Rempp H, Hofer M Comput Med Imaging Graph. 2011; 36(2):85-94.

PMID: 21862288 PMC: 3989537. DOI: 10.1016/j.compmedimag.2011.07.006.

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