Sibylle Pochon

Molecular Imaging of Human Thrombus With Novel Abciximab Immunobubbles and Ultrasound

Background and Purpose— Molecular imaging of therapeutic interventions with targeted agents that simultaneously carry drugs or genes for local delivery is appealing. We investigated the ability of a novel microbubble carrier (immunobubble) for abciximab, a glycoprotein IIb/IIIa receptor inhibitor, for ultrasonographic molecular imaging of human clots. Methods— Human thrombi were incubated with immunobubbles conjugated with abciximab. Control clots were incubated in either saline or with immunobubbles conjugated with nonspecific antibody. We evaluated immunobubble suspensions with variable concentrations of encapsulated gas and measured mean acoustic intensity of the incubated clots. In vivo molecular imaging of human thrombi with abciximab immunobubbles was evaluated in a rat model of carotid artery occlusion. Results— Mean acoustic intensity was significantly higher for abciximab immunobubbles as compared with control immunobubbles under all conditions tested with maximum difference in intensity at a gas volume of 0.2 &mgr;L (P=0.0013 for mechanical index 0.05, P=0.0001 for mechanical index 0.7). Binding of abciximab immunobubbles to clots in vitro led to enhanced echogenicity dependent on bubble concentration. In vivo ultrasonic detectability of carotid thrombi was significantly higher for clots targeted with abciximab immunobubbles (P<0.05). Quantification of in vivo contrast enhancement displayed a highly significant increment for abciximab immunobubble-targeted clots compared with nonspecific immunobubble-targeted clots (P<0.0001) and to native clots (P<0.0001). Conclusions— This study demonstrates the feasibility of using a therapeutic agent for selective targeting in vascular imaging. Abciximab immunobubbles improve visualization of human clots both in vitro and in an in vivo model of acute arterial thrombotic occlusion.

Ultrasound molecular imaging contrast agent binding to both E- and P-selectin in different species.

ObjectivesUltrasound molecular imaging is increasingly used in preclinical studies to measure the expression of vascular markers during inflammation process. In this context, a new ultrasound contrast agent functionalized with a recombinant P-selectin glycoprotein ligand-1 analogue (rPSGL-Ig) was developed (MBrPSGL-Ig). This agent was assayed in vitro and in vivo to evaluate its binding performance and potential to image expression of inflammatory markers E- and P-selectin. Performance of this newly developed agent was compared with that of antibody (MBAb) or sialyl Lewis X (MBsLex) containing microbubbles and with control microbubbles (MBC). Materials and MethodsThe targeted ultrasound contrast agents were prepared by coupling biotin-conjugated ligands onto streptavidin-functionalized microbubbles. First, in vitro experiments were performed to measure the adhesion efficiency of these microbubble constructs under static or flow conditions (114 sec−1), on cell monolayer (human umbilical vein endothelial cells and bEnd.5), or coatings of E- or P-selectin of various animal species, respectively. Second, molecular imaging studies were performed in a rat inflammatory model 24 hours after intramuscular injection of lipopolysaccharide in the hind limb. Finally, immunohistochemistry staining of rat inflamed muscle tissue was performed to assess expression of E- and P-selectin. ResultsMicrobubbles functionalized with rPSGL-Ig (MBrPSGL-Ig) displayed firm in vitro binding on the coating of both recombinant E- or P-selectin, with an efficiency similar to microbubbles comprising antibody specific for E-selectin (MBE) or P-selectin (MBP). In contrast, lower binding capacity was measured with MBsLex. At the surface of inflamed endothelial cells, MBrPSGL-Ig were able to interact specifically with E- and P-selectin. Binding specificity was demonstrated by performing blocking experiments with target-specific antibodies, resulting in an 80% to 95% decrease in binding. Ten minutes after microbubble injection, echo signal measured with MBrPSGL-Ig in the inflamed muscles was 20-fold higher compared with MBC. Moreover, the in vivo adhesion of MBrPSGL-Ig was 2- and 7-fold higher compared with P-selectin or E-selectin-specific microbubbles, respectively. Immunohistochemistry revealed a temporal coexpression of E- and P-selectin in the vascular bed of inflamed rat muscle 24 hours after lipopolysaccharide injection. ConclusionThe molecular imaging study demonstrates that MBrPSGL-Ig provide imaging signal higher than those measured with antibody or sialyl Lewis X containing microbubbles. These results suggest that MBrPSGL-Ig is a powerful agent to image the expression of both E- and P-selectin in the context of an inflammatory process.

Gd-BOPTA transport into rat hepatocytes: Pharmacokinetic analysis of dynamic magnetic resonance images using a hollow-fiber bioreactor

Rationale and Objectives:To investigate the transport of the hepatobiliary magnetic resonance (MR) imaging contrast agent Gd-BOPTA into rat hepatocytes. Materials and Methods:In a MR-compatible hollow-fiber bioreactor containing hepatocytes, MR signal intensity was measured over time during the perfusion of Gd-BOPTA. For comparison, the perfusion of an extracellular contrast agent (Gd-DTPA) was also studied. A compartmental pharmacokinetic model was developed to describe dynamic signal intensity-time curves. Results:The dynamic signal intensity-time curves of the hepatocyte hollow-fiber bioreactor during Gd-BOPTA perfusion were adequately fitted by 2 compartmental models. Modeling permitted to discriminate between the behaviors of the extracellular contrast agent (Gd-DTPA) and the hepatobiliary contrast agent (Gd-BOPTA). It allowed the successfully quantification of the parameters involved in such differences. Gd-BOPTA uptake was saturable at high substrate concentrations. Conclusions:The transport of Gd-BOPTA into rat hepatocytes was successfully described by compartmental analysis of the signal intensity recorded over time and supported the hypothesis of a transporter-mediated uptake.

Liver Dysplasia: US Molecular Imaging with Targeted Contrast Agent Enables Early Assessment

PURPOSE To investigate the ability of vascular endothelial growth factor receptor type 2 (VEGFR2)-targeted ultrasonographic (US) microbubbles for the assessment of liver dysplasia in transgenic mice. MATERIALS AND METHODS Animal experiments were approved by the governmental review committee. Nuclear factor-κB essential modulator knock-out mice with liver dysplasia and wild-type mice underwent liver imaging by using a clinical US system. Two types of contrast agents were investigated: nontargeted, commercially available, second-generation microbubbles (SonoVue) and clinically translatable PEGylated VEGFR2-targeted microbubbles (BR55). Microbubble kinetics was investigated over the course of 4 minutes. Targeted contrast material-enhanced US signal was quantified 5 minutes after injection. Competitive in vivo binding experiments with BR55 were performed in knock-out mice. Immunohistochemical and hematoxylin-eosin staining of liver sections was performed to validate the in vivo US results. Groups were compared by using the Mann-Whitney test. RESULTS Peak enhancement after injection of SonoVue and BR55 did not differ in healthy and dysplastic livers (SonoVue, P = .46; BR55, P = .43). Accordingly, immunohistochemical findings revealed comparable vessel densities in both groups. The specificity of BR55 to VEGFR2 was proved by in vivo competition (P = .0262). While the SonoVue signal decreased similarly in healthy and dysplastic livers during the 4 minutes, there was an accumulation of BR55 in dysplastic livers compared with healthy ones. Furthermore, targeted contrast-enhanced US signal indicated a significantly higher site-specific binding of BR55 in dysplastic than healthy livers (P = .005). Quantitative immunohistologic findings confirmed significantly higher VEGFR2 levels in dysplastic livers (P = .02). CONCLUSION BR55 enables the distinction of early stages of liver dysplasia from normal liver.

Detection of experimental hepatic tumors using long circulating superparamagnetic particles.

Sayegh Y, Pochon S, Vallée J-P, et al. Detection of experimental hepatic tumors using long circulating superparamagnetic particles. Invest Radiol 2001;36:15–21. RATIONALE AND OBJECTIVES.To evaluate the potential of an iron oxide-based MR contrast agent for the detection and delineation of experimental liver tumors during the early vascular phase of the compound. METHODS.Superparamagnetic blood pool agent (SBPA) was administered intravenously to rabbits bearing VX2 tumors. Images were acquired before the injection, immediately after, and 1 or 3 weeks later. The variations of signal intensity were measured in the tumors and in several tissues for various T1-weighted spin-echo, T2-weighted fast spin-echo, and T2-weighted gradient-recalled-echo sequences. RESULTS.Fourteen and 12 of the 16 tumors were detected immediately after SBPA injection using, respectively, the T2-weighted fast spin-echo and T2-weighted gradient-recalled-echo sequences. A significant decrease in signal intensity was observed in well-perfused organs, and blood signal was abolished even at the lowest injected dose and using a T1-weighted sequence. In the late phase, the loss in signal intensity of the liver was even more pronounced. CONCLUSION.The dominant T2 effect of SBPA induces an increase in the tumor-to-liver and tumor-to-blood contrast during the vascular phase, improving the detection of the tumors and allowing the distinction between small lesions and vessels through plane. This effect on the liver signal persists for several days because of the incorporation of SBPA in the reticuloendothelial system.

Nilotinib Enhances Tumor Angiogenesis and Counteracts VEGFR2 Blockade in an Orthotopic Breast Cancer Xenograft Model with Desmoplastic Response

Vascular endothelial growth factor (VEGF)/VEGF receptor (VEGFR)-targeted therapies predominantly affect nascent, immature tumor vessels. Since platelet-derived growth factor receptor (PDGFR) blockade inhibits vessel maturation and thus increases the amount of immature tumor vessels, we evaluated whether the combined PDGFR inhibition by nilotinib and VEGFR2 blockade by DC101 has synergistic therapy effects in a desmoplastic breast cancer xenograft model. In this context, besides immunohistological evaluation, molecular ultrasound imaging with BR55, the clinically used VEGFR2-targeted microbubbles, was applied to monitor VEGFR2-positive vessels noninvasively and to assess the therapy effects on tumor angiogenesis. DC101 treatment alone inhibited tumor angiogenesis, resulting in lower tumor growth and in significantly lower vessel density than in the control group after 14 days of therapy. In contrast, nilotinib inhibited vessel maturation but enhanced VEGFR2 expression, leading to markedly increased tumor volumes and a significantly higher vessel density. The combination of both drugs led to an almost similar tumor growth as in the DC101 treatment group, but VEGFR2 expression and microvessel density were higher and comparable to the controls. Further analyses revealed significantly higher levels of tumor cell–derived VEGF in nilotinib-treated tumors. In line with this, nilotinib, especially in low doses, induced an upregulation of VEGF and IL-6 mRNA in the tumor cells in vitro, thus providing an explanation for the enhanced angiogenesis observed in nilotinib-treated tumors in vivo. These findings suggest that nilotinib inhibits vessel maturation but counteracts the effects of antiangiogenic co-therapy by enhancing VEGF expression by the tumor cells and stimulating tumor angiogenesis.