Detection of 17O by Proton T1ρ Dispersion Imaging

Detection of H2(17)O with proton T1rho-dispersion imaging holds promise as a means of quantifying metabolism and blood flow with MRI. However, this technique requires a priori knowledge of the intrinsic T1rho dispersion of tissue. To investigate these properties, we implemented a T1rho imaging seque

Proton T1rho dispersion imaging is a recently described method for indirect detection of 17O. However, clinical implementation of this technique is hindered by the requirement for a high-amplitude spin-locking field (gammaB1 > 1 kHz) that exceeds current limitations in specific absorption rate (SAR)

## Abstract The purpose of this work is to demonstrate the feasibility of __T__~1ρ~‐weighted magnetic resonance imaging (MRI) to quantitatively measure changes in proteoglycan content in cartilage. The __T__~1ρ~ MRI technique was implemented in an in vivo porcine animal model with rapidly induced c

## Abstract Perfusion parameters, such as blood flow, are critical properties of tumors related to angiogenesis, drug delivery, radiosensitivity, bioenergetic status, and steady state levels of metabolites, such as lactate, that have been proposed as indices of tumor response to therapy. The existi

## Abstract In crystalline polyoxymethylene, a system with tightly coupled protons, it is shown experimentally that the averaging of the dipolar local field of protons by multipulse proton homonuclear decoupling leads to a decrease in the spin–spin contribution to the ^13^C rotating frame relaxatio