Abstract
Nowadays, magnetic resonance imaging (MRI) is the first diagnostic imaging modality for numerous indications able to provide anatomical information with high spatial resolution through the use of magnetic fields and gradients. Indeed, thanks to the characteristic relaxation time of each tissue, it is possible to distinguish between healthy and pathological ones. However, the need to have brighter images to increase differences and catch important diagnostic details has led to the use of contrast agents (CAs). Among them, Gadolinium-based CAs (Gd-CAs) are routinely used in clinical MRI practice. During these last years, FDA highlighted many risks related to the use of Gd-CAs such as nephrotoxicity, heavy allergic effects, and, recently, about the deposition within the brain. These alerts opened a debate about the opportunity to formulate Gd-CAs in a different way but also to the use of alternative and safer compounds to be administered, such as manganese- (Mn-) based agents. In this review, the physical principle behind the role of relaxivity and the T1 boosting will be described in terms of characteristic correlation times and inner and outer spheres. Then, the recent advances in the entrapment of Gd-CAs within nanostructures will be analyzed in terms of relaxivity boosting obtained without the chemical modification of CAs as approved in the chemical practice. Finally, a critical evaluation of the use of manganese-based CAs will be illustrated as an alternative ion to Gd due to its excellent properties and endogenous elimination pathway.
Highlights
Magnetic resonance imaging (MRI) is a diagnostic technique used to obtain anatomical images from the human body
MRI is based on the intrinsic properties of hydrogen protons, which act like charged particles whose rotation generates a magnetic moment [1,2,3]
Magnetic dipoles are oriented randomly but, when exposed to a high external magnetic field B0, they align in the same direction of the applied field. erefore, dipoles orientation leads to a resultant vector, called
Summary
Magnetic resonance imaging (MRI) is a diagnostic technique used to obtain anatomical images from the human body. MRI Contrast Agents e extensive use of contrast agents is based on their property to induce additional contrast to MRI image making visible anatomical details otherwise not appreciable At molecular level, this enhancement is explained by the presence of unpaired electrons nearby water molecule that, having a magnetic moment 658 times higher than hydrogen proton, shorten the return to equilibrium position [4, 5]. ΤR is the rotational correlation time of the metal ion-water proton vector, T1e and T2e are the longitudinal and transverse electron spin relaxation time of the metal ion, and τm is the lifetime of a water molecule in the inner sphere (it is the reciprocal of the water exchange rate km). Where q2jnd is the number of water molecules in a specific site j with a lifetime τ2mnjd and T21njd is its relaxation time that can be estimated using the inner sphere equations
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