The manganese(II) ion has many favorable properties that lead to its potential use as an MRI contrast agent: high spin number, long electronic relaxation time, labile water exchange. The present work describes the design, synthesis, and evaluation of a novel Mn(II) complex (MnL1) based on EDTA and also contains a moiety that noncovalently binds the complex to serum albumin, the same moiety used in the gadolinium based contrast agent MS-325. Ultrafiltration albumin binding measurements (0.1 mM, pH 7.4, 37 degrees C) indicated that the complex binds well to plasma proteins (rabbit: 96 +/- 2% bound, human: 93 +/- 2% bound), and most likely to serum albumin (rabbit: 89 +/- 2% bound, human 98 +/- 2% bound). Observed relaxivities (+/- 5%) of the complex were measured (20 MHz, 37 degrees C, 0.1 mM, pH 7.4) in HEPES buffer (r(1) = 5.8 mM(-)(1) s(-)(1)), rabbit plasma (r(1) = 51 mM(-)(1) s(-)(1)), human plasma (r(1) = 46 mM(-)(1) s(-)(1)), 4.5% rabbit serum albumin (r(1) = 47 mM(-)(1) s(-)(1)), and 4.5% human serum albumin (r(1) = 48 mM(-)(1) s(-)(1)). The water exchange rate was near optimal for an MRI contrast agent (k(298) = 2.3 +/- 0.9 x 10(8) s(-)(1)). Variable temperature NMRD profiles indicated that the high relaxivity was due to slow tumbling of the albumin-bound complex and fast exchange of the inner sphere water. The concept of a high relaxivity Mn(II)-based contrast agent was validated by imaging at 1.5 T. In a rabbit model of carotid artery injury, MnL1 clearly delineated both arteries and veins while also distinguishing between healthy tissue and regions of vessel damage.
Rationale and objectives-The observed relaxivity of gadolinium based contrast agents has contributions from the water molecule(s) that bind directly to the gadolinium ion (inner-sphere water), long lived water molecules and exchangeable protons that make up the second-sphere of coordination, and water molecules that diffuse near the contrast agent (outer-sphere). Inner-and second-sphere relaxivity can both be increased by optimization of the lifetimes of the water molecules and protons in these coordination spheres, the rotational motion of the complex, and the electronic relaxation of the gadolinium ion. We sought to identify new high relaxivity contrast agents by systematically varying the donor atoms that bind directly to gadolinium to increase inner-sphere relaxivity and concurrently including substituents that influence the second-sphere relaxivity.Methods-Twenty GdDOTA derivatives were prepared and their relaxivity determined in presence and absence of human serum albumin as a function of temperature and magnetic field. Data was analyzed to extract the underlying molecular parameters influencing relaxivity. Each compound had a common albumin-binding group and an inner-sphere donor set comprising the 4 tertiary amine N atoms from cyclen, an α-substituted acetate oxygen atom, two amide oxygen atoms, an inner-sphere water oxygen atom, and a variable donor group. Each amide nitrogen was substituted with different groups to promote hydrogen bonding with second-sphere water molecules.Results-Relaxivites at 0.47T and 1.4T, 37 °C, in serum albumin ranged from 16.0 to 58.1 mM −1 s −1 and from 12.3 to 34.8 mM −1 s −1 respectively. The reduction of inner-sphere water exchange typical of amide donor groups could be offset by incorporating a phosphonate or phenolate oxygen atom donor in the first coordination sphere resulting in higher relaxivity. Amide nitrogen substitution with pendant phosphonate or carboxylate groups increased relaxivity by as much as 88% compared to the N-methyl amide analog. Second-sphere relaxivity contributed as much as 24 mM −1 s −1 and 14 mM −1 s −1 at 0.47 and 1.4T respectively.Conclusions-Water/proton exchange dynamics in the inner-and second-coordination sphere can be predictably tuned by choice of donor atoms and second-sphere substituents resulting in high relaxivity agents.
Rationale and objectives The donor atoms that bind to gadolinium in contrast agents influence inner-sphere water exchange and electronic relaxation, both of which determine observed relaxivity. These molecular parameters impact relaxivity greatest when the contrast agent is protein bound. We sought to determine an optimal donor atom set to yield high relaxivity compounds. Methods Thirty-eight Gd-DOTA derivatives were prepared and relaxivity determined in presence and absence of human serum albumin as a function of temperature and magnetic field. Each compound had a common albumin-binding group and differed only by substitution of different donor groups at one of the macrocycle nitrogens. O-17 relaxometry at 7.05T was performed to estimate water exchange rates. Results Changing a single donor atom resulted in changes in water exchange rates ranging across 3 orders of magnitude. Donor groups increased water exchange rate in the order: phosphonate ~ phenolate > α-substituted acetate > acetate > hydroxamate ~ sulfonamide > amide ~ pyridyl ~ imidazole. Relaxivites at 0.47T and 1.4T, 37 °C, ranged from 12.3 to 55.6 mM-1s-1 and from 8.3 to 32.6 mM-1s-1 respectively. Optimal relaxivities were observed when the donor group was an α-substituted acetate. Electronic relaxation was slowest for the acetate derivatives as well. Conclusions Water exchange dynamics and relaxivity can be predictably tuned by choice of donor atoms
Amphiphilic gadolinium complexes were investigated as potential magnetic resonance imaging (MRI) contrast agents. A series of complexes was synthesized in order to study the effect of hydrophilic phosphodiester groups on albumin binding, relaxivity, and blood half-life in rats. Thus, compound 11a, a diethylenetriaminepentaacetato aquo gadolinium(III) (Gd-DTPA) derivative with an octyl substituent, was synthesized and compared to 5b, the analogous octyl derivative containing a phosphodiester linkage between the gadolinium chelate and the alkyl chain. Likewise, 11b, a naphthyl Gd-DTPA derivative, was compared to the naphthyl phosphodiester derivative 5c. A direct comparison is not available for 5a, a 4,4-diphenylcyclohexyl phosphodiester Gd-DTPA derivative; however, its pharmacokinetic properties mirror those of the other phosphodiester derivatives. Although the introduction of the phosphodiester moiety decreased log P by approximately 1.7 units, albumin binding data obtained in 4.5% human serum albumin (HSA) indicated that derivatives containing the phosphodiester group exhibited somewhat higher albumin affinity than their alkyl analogues (54 +/- 5 and 44 +/- 4% for 5b and 11a, respectively; 40 +/- 4 and 30 +/- 3% for 5c and 11b, respectively). Both classes of agents were characterized by enhanced relaxivity in the presence of 4.5% HSA (r1 = 16-42 mM(-1) s(-1) at 20 MHz and 37 degrees C) as compared with the relaxivity values measured in phosphate-buffered saline (PBS) alone (r1 = 4.6-6.6 mM(-1) s(-1) at 20 MHz and 37 degrees C). Pharmacokinetic data indicated that compound 5b had a half-life of 14.3 +/- 1.8 min in the rat as compared with a half-life of 6.20 +/- 0.04 min for the non-phosphodiester analogue 11a. Similarly, the half-life obtained for the phosphodiester 5c was 14.3 +/- 1.7 min as compared with a half-life of 6.80 +/- 0.03 min for 11b. The percent biliary excretion was significantly lower for the phosphodiester compounds than for non-phosphodiester analogues (17.7 +/- 4.0 and 66.9 +/- 3.4% for 5b and 11a, respectively; 17.0 +/- 1.6 and 64.3 +/- 9.0% for 5c and 11b, respectively). The percent biliary excretion (15.8 +/- 4.4%) and plasma half-life in the rat (23.1 +/- 2.9 min) for 5a are consistent with the extended plasma half-life of the other phosphodiester derivatives. Taken together, the enhanced relaxivity and extended blood half-life of the phosphodiester derivatives support the concept of using endogenous albumin binding to achieve blood pool-like properties for small-molecule magnetic resonance imaging (MRI) contrast agents.
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