Toni L. Ceckler scite author profile

A major factor contributing to proton (1H) spin-lattice relaxation in biological tissues is believed to be magnetization transfer between 1H in free bulk water and 1H restricted motion associated with macromolecules. We have shown recently that saturation transfer is an effective approach for studying this magnetization transfer process. Herein the determination of magnetization transfer rates in biological tissues is further analyzed by considering the time and power dependencies of saturation transfer. Following these analyses, quantitative magnetization transfer rate constant image maps were collected from the kidney in vivo. These rate constant images may prove useful in quantitative tissue characterization and in the determination of tissue-specific 1H relaxation mechanisms.

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Analysis of water‐macromolecule proton magnetization transfer in articular cartilage

Kim

Ceckler

Hascall

et al. 1993

Magnetic Resonance in Med

166

116

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These studies were designed to establish which structural elements of cartilage are responsible for proton magnetization transfer between water (Hf) and macromolecules (Hr) observed in MRI studies on articular cartilage. Saturation transfer techniques were used to monitor magnetization transfer in vitro on samples of the two major constituents of cartilage: collagen and proteoglycan. Articular cartilage samples were also evaluated in vitro before and after the removal of the proteoglycan fraction. Isolated hydrated collagen exhibited a significant proton magnetization transfer rate with water. In contrast, proteoglycans exhibited no proton magnetization transfer. Articular cartilage, in vitro, exhibited a high degree of magnetization transfer with water protons consistent with previous MRI studies in vivo. Enzymatic removal of proteoglycan from the cartilage did not alter the magnetization transfer rate between Hr and Hf. These data demonstrate that the structure and concentration of the collagen matrix are the predominant determinants of the magnetization transfer process in articular cartilage with little or no contribution from proteoglycans. This specificity of the magnetization transfer effect may prove useful in the noninvasive evaluation of cartilage composition and structure in vivo.

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Visualizing manganese in the primate basal ganglia with magnetic resonance imaging

Newland

Ceckler

Kordower

et al. 1989

Experimental Neurology

218

102

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Toni L. Ceckler

Quantitative ¹H magnetization transfer imaging in vivo

Analysis of water‐macromolecule proton magnetization transfer in articular cartilage

Visualizing manganese in the primate basal ganglia with magnetic resonance imaging

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Toni L. Ceckler

Quantitative 1H magnetization transfer imaging in vivo

Analysis of water‐macromolecule proton magnetization transfer in articular cartilage

Visualizing manganese in the primate basal ganglia with magnetic resonance imaging

Contact Info

Product

Resources

About

Quantitative ¹H magnetization transfer imaging in vivo