Antibody-labeled liposomes for CT imaging of atherosclerotic plaques: in vitro investigation of an anti-ICAM antibody-labeled liposome containing iohexol for molecular imaging of atherosclerotic plaques via computed tomography.

We evaluated the specific binding of anti-intercellular adhesion molecule 1 (ICAM-1) conjugated liposomes (immunoliposomes, or ILs) to activated human coronary artery endothelial cells (HCAEC) with the purpose of designing a computed tomographic imaging agent for early detection of atherosclerotic plaques. Covalent attachment of anti-ICAM-1 monoclonal antibodies to pre-formed liposomes stabilized with polyethylene glycol yielded ILs, with a coupling efficiency of the ICAM-1 to the liposomes of 10% to 24%. The anti-ICAM-1-labeled ILs had an average diameter of 136 nm as determined by dynamic light-scattering and cryogenic electron microscopy. The ILs' encapsulation of 5-[N-acetyl-(2,3-dihydroxypropyl)-amino)-N, N'-bis(2,3-dihydroxypropyl)-2,4,6-triiodo-benzene-1,3-dicarboxamide (iohexol) was determined to be 18% to 19% by a dialysis technique coupled with ultraviolet detection of free iohexol. This encapsulation corresponded to 30 to 38 mg iodine per mL IL solution, and the ILs exhibited 91% to 98.5% iohexol retention at room temperature and under physiologic conditions. The specific binding of the ILs to cultured, activated HCAEC was measured using flow cytometry, enzyme-linked immunosorbent assays, and fluorescence microscopy. The immunosorbent assays demonstrated the specificity of binding of anti-ICAM-1 to ICAM-1 compared with control studies using nonspecific immunoglobulin G-labeled ILs. Flow cytometry and fluorescence microscopy experiments demonstrated the expression of ICAM-1 on the surface of activated HCAEC. Therefore, our iohexol-filled ILs demonstrated potential for implementation in computed tomographic angiography to noninvasively detect atherosclerotic plaques that are prone to rupture.

An iodinated liposomal computed tomographic contrast agent prepared from a diiodophosphatidylcholine lipid.

Herein we report a novel vesicle-forming iodinated contrast agent for applications in computed tomographic (CT) imaging and drug delivery. Specifically, we have chemically modified a phosphatidylcholine lipid that is commonly used in liposome formation to create an iodinated lipid that self-assembles into approximately 50-150 nm iodoliposomes possessing as-prepared imaging contrast functionality. These iodoliposomes are structurally organized such that the iodinated moieties are contained within the vesicle's bilayer, leaving the liposomal interior unoccupied and thus available for encapsulating drugs. The iodoliposomes were characterized using electron microscopy and dynamic light scattering. We also calculated the iodoliposomes' iodine encapsulation efficiency, which was sufficient for use in current CT imaging protocols. These iodinated liposomes could also serve as multifunctional carriers upon the encapsulation of pharmaceutical agents, permitting simultaneous CT imaging and therapeutic treatment. Alternatively, the commercially available iodinated contrast agent iohexol could be encapsulated inside the iodoliposomes' aqueous core to further enchance their imaging contrast.

Fatty alcohol phosphates are subtype-selective agonists and antagonists of lysophosphatidic acid receptors.

A more complete understanding of the physiological and pathological role of lysophosphatidic acid (LPA) requires receptor subtype-specific agonists and antagonists. Here, we report the synthesis and pharmacological characterization of fatty alcohol phosphates (FAP) containing saturated hydrocarbon chains from 4 to 22 carbons in length. Selection of FAP as the lead structure was based on computational modeling as a minimal structure that satisfies the two-point pharmacophore developed earlier for the interaction of LPA with its receptors. Decyl and dodecyl FAPs (FAP-10 and FAP-12) were specific agonists of LPA(2) (EC(50) = 3.7 +/- 0.2 microM and 700 +/- 22 nM, respectively), yet selective antagonists of LPA(3) (K(i) = 90 nM for FAP-12) and FAP-12 was a weak antagonist of LPA(1). Neither LPA(1) nor LPA(3) receptors were activated by FAPs; in contrast, LPA(2) was activated by FAPs with carbon chains between 10 and 14. Computational modeling was used to evaluate the interaction between individual FAPs (8 to 18) with LPA(2) by docking each compound in the LPA binding site. FAP-12 displayed the lowest docked energy, consistent with its lower observed EC(50). The inhibitory effect of FAP showed a strong hydrocarbon chain length dependence with C12 being optimum in the Xenopus laevis oocytes and in LPA(3)-expressing RH7777 cells. FAP-12 did not activate or interfere with several other G-protein-coupled receptors, including S1P-induced responses through S1P(1,2,3,5) receptors. These data suggest that FAPs are ligands of LPA receptors and that FAP-10 and FAP-12 are the first receptor subtype-specific agonists for LPA(2).