Bioresponsive, cell-penetrating, and multimeric MR contrast agents

Activatable magnetic resonance imaging agents for myeloperoxidase sensing: mechanism of activation, stability, and toxicity

Myeloperoxidase (MPO) is increasingly being recognized as an important factor in many inflammatory diseases, particularly cardiovascular and neurological diseases. MPO-specific imaging agents would thus be highly useful to diagnose early disease, monitor disease progression, and quantify treatment effects. This study reports in vitro and in vivo characterizations of the mechanism of interaction between MPO and paramagnetic enzyme substrates based on physical and biological measurements. We show that these agents are activated through a radical mechanism, which can combine to form oligomers and, in the presence of tyrosine-containing peptide, bind to proteins. We further identified two new imaging agents, which represent the near extremes in either oligomerization (mono-5HT-DTPA-Gd) or protein-binding in their activation mechanism (bis-o-dianisidine-DTPA-Gd). On the other hand, we found that the agent bis-5HT-DTPA-Gd utilizes both mechanisms when activated. These properties yield distinct in vivo pharmacokinetics profiles for each of these agents that may be exploited for different applications. Specificity studies show that only MPO, but not eosinophil peroxidase, can highly activate these agents, and that MPO activity as low as 0.005 U/mg of tissue can be detected. Gd kinetic lability and cytotoxicity studies further confirm stability of the Gd ion and low toxicity for the 5HT-based agents, suggesting that these agents are suitable for translational in vivo studies.

Gd(III)-nanodiamond conjugates for MRI contrast enhancement

A Gd(III)-nanodiamond conjugate [Gd(III)-ND] was prepared and characterized, enabling detection of nanodiamonds by MR imaging. The Gd(III)-ND particles significantly reduced the T(1) of water protons with a per-Gd(III) relaxivity of 58.82 +/- 1.18 mM(-1) s(-1) at 1.5 T (60 MHz). This represents a 10-fold increase compared to the monomer Gd(III) complex (r(1) = 5.42 +/- 0.20 mM(-1) s(-1)) and is among the highest per-Gd(III) relaxivities reported.

A copper-activated magnetic resonance imaging contrast agent with improved turn-on relaxivity response and anion compatibility

We present the synthesis and characterization of Copper-Gad-7 (CG7), a new copper-activated magnetic resonance imaging (MRI) contrast agent that possesses a Gd(3+)-DO3A scaffold with an appended thioether-rich receptor for copper recognition. Installation of additional carboxylate groups on the periphery of the CG scaffold affords a practical strategy to increase the absolute relaxivity of these types of copper-responsive MRI sensors as well as reduce their sensitivity to biologically abundant anions. Due in large part to restricted access of inner-sphere water molecules to the paramagnetic Gd(3+) core, in the absence of copper ions, CG7 exhibits a relatively low relaxivity value of r(1) = 2.6 mM(-1) s(-1); addition of Cu(+) triggers a 340% enhancement in relaxivity to r(1) = 11.4 mM(-1) s(-1). For comparison, the relaxivity of the analogous CG2 sensor without peripheral carboxylates increases from r(1) = 1.5 to 6.9 mM(-1) s(-1) upon Cu(+) binding. CG7 features high selectivity for Cu(+) over a range of biologically relevant metal ions, including the cellular abundant alkali and alkaline earth cations and d-block ions Zn(2+) and Cu(2+). Moreover, the Cu(+)-response of the CG7 sensor is not significantly affected by bicarbonate, phosphate, citrate, and lactate anions at cellular levels. (17)O NMR dysprosium-induced shift (DIS) and nuclear magnetic relaxation dispersion (NMRD) experiments suggest that the origin of the improved anion compatibility of CG7 is a reduced q modulation compared to previous members of the CG family, and T(1)-weighted phantom images confirm that CG7 can monitor changes in copper levels by MRI at clinically relevant field strengths.

Responsive magnetic resonance imaging contrast agents as chemical sensors for metals in biology and medicine

This tutorial review highlights progress in the development of responsive magnetic resonance imaging (MRI) contrast agents for detecting and sensing biologically relevant metal ions. Molecular imaging with bioactivatable MRI indicators offers a potentially powerful methodology for studying the physiology and pathology of metals by capturing dynamic three-dimensional images of living systems for research and clinical applications. This emerging area at the interface of inorganic chemistry and the life sciences offers a broad palette of opportunities for researchers with interests ranging from coordination chemistry and spectroscopy to supramolecular chemistry and molecular recognition to metals in biology and medicine.