Your search keyword '"LABELED RECEPTOR LIGANDS"' showing total 3 results

1. New positron emission tomography tracer [C-11]carvedilol reveals P-glycoprotein modulation kinetics

Subjects

GRAPHICAL ANALYSIS, CARVEDILOL, positron emission tomography, DOXORUBICIN, BLOOD-BRAIN-BARRIER, [C-11]carvedilol, P-glycoprotein, blood-brain barrier, chemotherapy, radiopharmacology, modelling, cyclosporin A, PET, multidrug resistance, BINDING, LABELED RECEPTOR LIGANDS, pharmacokinetic, distribution volume, COMBINATION, IN-VIVO, RESISTANCE

Abstract

1 Imaging of P-glycoprotein (P-gp) function in the blood-brain barrier (BBB) may support evelopment of strategies, which will improve drug delivery to the brain. [C-11] verapamil has been developed as a positron emission tomography ( PET) tracer, to image P-gp function in vivo. Ideally, for the purpose of brain imaging, tracers should have a log P between 0.9 and 2.5. The beta-receptor antagonist carvedilol is a P-gp substrate with a log P = 2.0, and can be labeled with [C-11]. The aim of this study was to determine whether the P-gp substrate [C-11] carvedilol can be used as a PET tracer for visualisation and quantification of the P-gp function in the BBB. 2 Cellular [C-11] carvedilol accumulation in GLC(4), GLC(4)/P-gp, and GLC(4)/Adr cells increased three-fold in the GLC(4)/P-gp cells after pretreatment with cyclosporin A (CsA) whereas no effect of MK571 could be determined in the GLC4/Adr cells. 3 Ex vivo [C-11] carvedilol biodistribution studies showed that [C-11] carvedilol uptake in the brain was increased by CsA. [C-11] carvedilol uptake in other organs was not affected by CsA. 4 Autoradiography studies of rat brains showed that [ C-11] carvedilol was homogeneously distributed over the brain and that pretreatment with CsA increased [C-11] carvedilol uptake. 5 In vivo PET experiments were performed with and without P-gp modulation by CsA. P-gp mediated transport was quantified by Logan analysis of the PET data, calculating the distribution volume (DV) of [C-11] carvedilol in the brain. Logan analysis resulted in excellent fits, revealing that [C-11] carvedilol is not trapped in the brain. Brain DV of [C-11] carvedilol showed a dose-dependent increase of maximal three-fold after CsA pretreatment. Above 15 mg kg(-1), no change in DV was found. Compared to [C-11] verapamil less CsA was needed to reach maximal DV, suggesting that [C-11] carvedilol kinetics is a more sensitive tool to in vivo measure P-gp function.

Published

2005

2. New positron emission tomography tracer [C-11]carvedilol reveals P-glycoprotein modulation kinetics

Subjects

GRAPHICAL ANALYSIS, CARVEDILOL, positron emission tomography, DOXORUBICIN, BLOOD-BRAIN-BARRIER, [C-11]carvedilol, P-glycoprotein, blood-brain barrier, chemotherapy, radiopharmacology, modelling, cyclosporin A, PET, multidrug resistance, BINDING, LABELED RECEPTOR LIGANDS, pharmacokinetic, distribution volume, COMBINATION, IN-VIVO, RESISTANCE

Abstract

1 Imaging of P-glycoprotein (P-gp) function in the blood-brain barrier (BBB) may support evelopment of strategies, which will improve drug delivery to the brain. [C-11] verapamil has been developed as a positron emission tomography ( PET) tracer, to image P-gp function in vivo. Ideally, for the purpose of brain imaging, tracers should have a log P between 0.9 and 2.5. The beta-receptor antagonist carvedilol is a P-gp substrate with a log P = 2.0, and can be labeled with [C-11]. The aim of this study was to determine whether the P-gp substrate [C-11] carvedilol can be used as a PET tracer for visualisation and quantification of the P-gp function in the BBB.2 Cellular [C-11] carvedilol accumulation in GLC(4), GLC(4)/P-gp, and GLC(4)/Adr cells increased three-fold in the GLC(4)/P-gp cells after pretreatment with cyclosporin A (CsA) whereas no effect of MK571 could be determined in the GLC4/Adr cells.3 Ex vivo [C-11] carvedilol biodistribution studies showed that [C-11] carvedilol uptake in the brain was increased by CsA. [C-11] carvedilol uptake in other organs was not affected by CsA.4 Autoradiography studies of rat brains showed that [ C-11] carvedilol was homogeneously distributed over the brain and that pretreatment with CsA increased [C-11] carvedilol uptake.5 In vivo PET experiments were performed with and without P-gp modulation by CsA. P-gp mediated transport was quantified by Logan analysis of the PET data, calculating the distribution volume (DV) of [C-11] carvedilol in the brain. Logan analysis resulted in excellent fits, revealing that [C-11] carvedilol is not trapped in the brain. Brain DV of [C-11] carvedilol showed a dose-dependent increase of maximal three-fold after CsA pretreatment. Above 15 mg kg(-1), no change in DV was found. Compared to [C-11] verapamil less CsA was needed to reach maximal DV, suggesting that [C-11] carvedilol kinetics is a more sensitive tool to in vivo measure P-gp function.

Published

2005

3. New positron emission tomography tracer [C-11]carvedilol reveals P-glycoprotein modulation kinetics

Author

Bart, J, Dijkers, ECF, Wegman, TD, de Vries, EGE, van der Graaf, WTA, Groen, HJM, Vaalburg, W, Willemsen, ATM, Hendrikse, NH, Damage and Repair in Cancer Development and Cancer Treatment (DARE), Guided Treatment in Optimal Selected Cancer Patients (GUTS), and Targeted Gynaecologic Oncology (TARGON)

Subjects

GRAPHICAL ANALYSIS, CARVEDILOL, positron emission tomography, DOXORUBICIN, BLOOD-BRAIN-BARRIER, [C-11]carvedilol, P-glycoprotein, blood-brain barrier, chemotherapy, radiopharmacology, modelling, cyclosporin A, PET, multidrug resistance, BINDING, LABELED RECEPTOR LIGANDS, pharmacokinetic, distribution volume, COMBINATION, IN-VIVO, RESISTANCE

Abstract

1 Imaging of P-glycoprotein (P-gp) function in the blood-brain barrier (BBB) may support evelopment of strategies, which will improve drug delivery to the brain. [C-11] verapamil has been developed as a positron emission tomography ( PET) tracer, to image P-gp function in vivo. Ideally, for the purpose of brain imaging, tracers should have a log P between 0.9 and 2.5. The beta-receptor antagonist carvedilol is a P-gp substrate with a log P = 2.0, and can be labeled with [C-11]. The aim of this study was to determine whether the P-gp substrate [C-11] carvedilol can be used as a PET tracer for visualisation and quantification of the P-gp function in the BBB. 2 Cellular [C-11] carvedilol accumulation in GLC(4), GLC(4)/P-gp, and GLC(4)/Adr cells increased three-fold in the GLC(4)/P-gp cells after pretreatment with cyclosporin A (CsA) whereas no effect of MK571 could be determined in the GLC4/Adr cells. 3 Ex vivo [C-11] carvedilol biodistribution studies showed that [C-11] carvedilol uptake in the brain was increased by CsA. [C-11] carvedilol uptake in other organs was not affected by CsA. 4 Autoradiography studies of rat brains showed that [ C-11] carvedilol was homogeneously distributed over the brain and that pretreatment with CsA increased [C-11] carvedilol uptake. 5 In vivo PET experiments were performed with and without P-gp modulation by CsA. P-gp mediated transport was quantified by Logan analysis of the PET data, calculating the distribution volume (DV) of [C-11] carvedilol in the brain. Logan analysis resulted in excellent fits, revealing that [C-11] carvedilol is not trapped in the brain. Brain DV of [C-11] carvedilol showed a dose-dependent increase of maximal three-fold after CsA pretreatment. Above 15 mg kg(-1), no change in DV was found. Compared to [C-11] verapamil less CsA was needed to reach maximal DV, suggesting that [C-11] carvedilol kinetics is a more sensitive tool to in vivo measure P-gp function.

Published

2005