Cascade polymeric MRI contrast media derived from poly(ethylene glycol) cores: initial syntheses and characterizations.

Diagnostic contrast media for magnetic resonance imaging (MRI) are often applied to enhance the signal of blood allowing for quantitative definition of vascular functional characteristics including tissue blood volume, flow, and leakiness. Well-tolerated and safe macromolecular formulations are currently being sought that remain in the blood for a relatively long period and that leak selectively from diseased vessels, particularly cancer vessels. We synthesized a new class of macromolecular, water-soluble MRI contrast media by introducing two diverging polylysine cascade amplifiers at each end of a poly(ethylene glycol) (PEG) backbone, followed by substitution of terminal lysine amino groups with Gd-DTPA chelates.

Dendritic iodinated contrast agents with PEG-cores for CT imaging: synthesis and preliminary characterization.

The purpose of this study was to design, synthesize, and initially characterize a representative set of novel constructs for large-molecular radiographic/computed tomography (CT) contrast agents, intended for a primarily intravascular distribution. A new assembly of well-known and biocompatible components consists of paired, symmetrical dendritic polylysines initiated from both ends of a poly(ethylene glycol) (PEG) core, yielding an array of multiple free amino groups to which were conjugated highly soluble and stable triiodophthalamide ("triiodo") moieties. An array of six dendritic contrast agents was synthesized originally, using three different PEG cores (3, 6, 12 kDa) with t-Boc lysine-generated dendrimer "amplifiers" (from three to five generations) containing 16 to 64 amino groups for conjugation with reactive triiodo moieties.