Nondestructive imaging of human cartilage glycosaminoglycan concentration by MRI

Despite the compelling need mandated by the prevalence and morbidity of degenerative cartilage diseases, it is extremely difficult to study disease progression and therapeutic efficacy, either in vitro or in vivo (clinically). This is partly because no techniques have been available for nondestructively visualizing the distribution of functionally important macromolecules in living cartilage. Here we describe and validate a technique to image the glycosaminoglycan concentration ([GAG]) of human cartilage nondestructively by magnetic resonance imaging (MRI). The technique is based on the premise that the negatively charged contrast agent gadolinium diethylene triamine pentaacetic acid (Gd(DTPA)2‐) will distribute in cartilage in inverse relation to the negatively charged GAG concentration. Nuclear magnetic resonance spectroscopy studies of cartilage explants demonstrated that there was an approximately linear relationship between T1 (in the presence of Gd(DTPA)2‐) and [GAG] over a large range of [GAG]. Furthermore, there was a strong agreement between the [GAG] calculated from [Gd(DTPA)2‐] and the actual [GAG] determined from the validated methods of calculations from [Na+] and the biochemical DMMB assay. Spatial distributions of GAG were easily observed in T1‐weighted and T1‐calculated MRI studies of intact human joints, with good histological correlation. Furthermore, in vivo clinical images of T1 in the presence of Gd(DTPA)2‐ (i.e., GAG distribution) correlated well with the validated ex vivo results after total knee replacement surgery, showing that it is feasible to monitor GAG distribution in vivo. This approach gives us the opportunity to image directly the concentration of GAG, a major and critically important macromolecule in human cartilage. Magn Reson Med 41:857–865, 1999. © 1999 Wiley‐Liss, Inc.

[1]  A. Maroudas,et al.  Effects of substrates and inhibitors of the tricarboxylic acid cycle on proximal tubular fluid transport in vitro. , 1970 .

[2]  D. Burstein,et al.  Determination of fixed charge density in cartilage using nuclear magnetic resonance , 1992, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[3]  E. Hunziker,et al.  Improved cartilage fixation by ruthenium hexammine trichloride (RHT). A prerequisite for morphometry in growth cartilage. , 1982, Journal of ultrastructure research.

[4]  D. L. Maude A simple physicochemical micromethod for determining fixed anionic groups in connective tissue. , 1970 .

[5]  W J Manning,et al.  Studies of Gd‐DTPA relaxivity and proton exchange rates in tissue , 1994, Magnetic resonance in medicine.

[6]  W Gründer,et al.  MR‐microscopic visualization of anisotropic internal cartilage structures using the magic angle technique , 1998, Magnetic resonance in medicine.

[7]  R S Balaban,et al.  Analysis of water‐macromolecule proton magnetization transfer in articular cartilage , 1993, Magnetic resonance in medicine.

[8]  D. Burstein,et al.  Gd‐DTPA2− as a measure of cartilage degradation , 1996, Magnetic resonance in medicine.

[9]  R Benacerraf,et al.  Intraarticular diffusion of Gd-DOTA after intravenous injection in the knee: MR imaging evaluation. , 1993, Radiology.

[10]  Yang Xia,et al.  Relaxation anisotropy in cartilage by NMR microscopy (μMRI) at 14‐μm resolution , 1998 .

[11]  P. J. Hoopes,et al.  MRI contrast enhanced study of cartilage proteoglycan degradation in the rabbit knee , 1997, Magnetic resonance in medicine.

[12]  D. Burstein,et al.  Magnetization transfer in cartilage and its constituent macromolecules , 1995, Magnetic resonance in medicine.

[13]  J. B. Kneeland,et al.  Sodium MRI of human articular cartilage in vivo , 1998, Magnetic resonance in medicine.

[14]  S. Erickson,et al.  In vitro and in vivo MR imaging of hyaline cartilage: zonal anatomy, imaging pitfalls, and pathologic conditions. , 1997, Radiographics : a review publication of the Radiological Society of North America, Inc.

[15]  P. Mansfield,et al.  High‐speed multislice T1 mapping using inversion‐recovery echo‐planar imaging , 1990, Magnetic resonance in medicine.

[16]  G. Navon,et al.  Detection of Anisotropy in Cartilage Using 2H Double-Quantum-Filtered NMR-Spectroscopy , 1995 .

[17]  C B Sledge,et al.  Enhancement of joint fluid with intravenously administered gadopentetate dimeglumine: technique, rationale, and implications. , 1993, Radiology.

[18]  D Matthaei,et al.  Inversion recovery snapshot FLASH MR imaging. , 1989, Journal of computer assisted tomography.

[19]  D. Buttle,et al.  Improved quantitation and discrimination of sulphated glycosaminoglycans by use of dimethylmethylene blue. , 1986, Biochimica et biophysica acta.

[20]  K. Gersonde,et al.  MR microimaging of articular cartilage and contrast enhancement by manganese ions , 1992, Magnetic resonance in medicine.

[21]  R M Henkelman,et al.  Effects of collagen orientation on MR imaging characteristics of bovine articular cartilage. , 1993, Radiology.

[22]  D. Burstein,et al.  Glycosaminoglycan in articular cartilage: in vivo assessment with delayed Gd(DTPA)(2-)-enhanced MR imaging. , 1997, Radiology.

[23]  W. Blackburn,et al.  Arthroscopic evaluation of knee articular cartilage: a comparison with plain radiographs and magnetic resonance imaging. , 1994, The Journal of rheumatology.