Improving the detection specificity of endogenous MRI for reactive oxygen species (ROS)

Abstract

Background: The detection of tissue reactive oxygen species (ROS) using endogenous MRI methods has great potential applications in research and the clinic. We recently demonstrated that ROS produce a significant T₁ -shortening effect. However, T₁ or T₁ -weighted contrast is not specific, as there are many other factors that alter tissue T₁ .

Purpose: To investigate whether the presence of ROS alters tissue environmental conditions such as the proton exchange rate (K _ex ) to improve the detection specificity of endogenous ROS MRI.

Study type: Prospective.

Subjects/phantom: The ROS-producing phantoms consisted of fresh egg white treated with H₂ O₂ and healthy mice injected with pro-oxidative rotenone.

Field strength/sequence: T₁ mapping was performed based on fast spin-echo sequence and K _ex was evaluated using chemical exchange saturation transfer (CEST) MRI with varied saturation power (QUESP) on a 9.4 T animal scanner.

Assessment: Phantom experiments were conducted to evaluate the overall K _ex of CEST-expressing metabolites in fresh egg white treated with H₂ O₂ of various concentrations (0, 0.025, 0.05, 0.1, and 0.25 v/v%). The egg white phantom continuously produced ROS for more than 3 hours. Various experiments were performed to rule out potential contributing factors to the observed K _ex changes. In addition, in vivo MRI study was conducted with a well-established rotenone-exposed mouse model.

Statistical tests: Student's t-test.

Results: Egg white phantoms treated with H₂ O₂ of various concentrations showed a 26-85% increase in K _ex compared with controls. In addition, the K _ex of egg white is negligibly affected by other potential confounding factors, including paramagnetic contrast agents (<11%), oxygen (2.3%), and iron oxidation (<10%). Changes in temperature (<1°C) and pH (ΔpH <0.1) in H₂ O₂ -treated egg white were also negligible. Results from the in vivo rotenone study were consistent with the phantom studies by showing reduced T₁ relaxation time (6%) and increased K _ex (9%) in rotenone-treated mice.

Data conclusion: We demonstrate that the specificity of endogenous ROS MRI can be improved with the aid of proton exchange rate mapping.

Level of evidence: 2 Technical Efficacy Stage: 2 J. Magn. Reson. Imaging 2019;50:583-591.

Keywords: CEST MRI; T1 relaxation time; free radicals; oxidative stress; proton exchange rate; reactive oxygen species.