Ex vivo cell labeling with 64Cu–pyruvaldehyde-bis(N4-methylthiosemicarbazone) for imaging cell trafficking in mice with positron-emission tomography

We have used copper-64-pyruvaldehyde-bis( N 4 -methylthiosemicarbazone) ( 64 Cu–PTSM) to radiolabel cells ex vivo for in vivo positron-emission tomography (PET) imaging studies of cell trafficking in mice and for eventual application in patients. 2-[ 18 F]-Fluoro-2-deoxy- d -glucose (FDG) cell label...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2002-03, Vol.99 (5), p.3030-3035
Hauptverfasser:	Adonai, Nona, Adonai, Nora, Nguyen, Khoi N, Walsh, Joseph, Iyer, M, Toyokuni, Tatsushi, Phelps, Michael E, McCarthy, Timothy, McCarthy, Deborah W, Gambhir, Sanjiv Sam
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Schlagworte:	Animals Biological Sciences Cell Movement - physiology Cells Copper Copper Radioisotopes Fluorodeoxyglucose F18 - metabolism Glioma Male Mice Mice, Nude Organometallic Compounds - metabolism Organometallic Compounds - toxicity Rats Rodents Thiosemicarbazones - metabolism Thiosemicarbazones - toxicity Tomography Tomography, Emission-Computed - methods Tumor Cells, Cultured
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container_title	Proceedings of the National Academy of Sciences - PNAS
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creator	Adonai, Nona Adonai, Nora Nguyen, Khoi N Walsh, Joseph Iyer, M Toyokuni, Tatsushi Phelps, Michael E McCarthy, Timothy McCarthy, Deborah W Gambhir, Sanjiv Sam
description	We have used copper-64-pyruvaldehyde-bis( N 4 -methylthiosemicarbazone) ( 64 Cu–PTSM) to radiolabel cells ex vivo for in vivo positron-emission tomography (PET) imaging studies of cell trafficking in mice and for eventual application in patients. 2-[ 18 F]-Fluoro-2-deoxy- d -glucose (FDG) cell labeling also was evaluated for comparison. 64 Cu–PTSM uptake by C6 rat glioma (C6) cells increased for 180 min and then stabilized. The labeling efficiency was directly proportional to 64 Cu–PTSM concentration and influenced negatively by serum. Label uptake per cell was greater with 64 Cu–PTSM than with FDG. However, both 64 Cu–PTSM- and FDG-labeled cells showed efflux of cell activity into supernatant. The 64 Cu–PTSM labeling procedure did not interfere significantly with C6 cell viability and proliferation rate. MicroPET images of living mice indicate that tail-vein-injected labeled C6 cells traffic to the lungs and liver. In addition, transient splenic accumulation of radioactivity was clearly detectable in a mouse scanned at 3.33 h postinfusion of 64 Cu–PTSM-labeled lymphocytes. In contrast, the liver was the principal organ of tracer localization after tail-vein administration of 64 Cu–PTSM alone. These results indicate that in vivo imaging of cell trafficking is possible with 64 Cu–PTSM-labeled cells. Given the longer t 1/2 of 64 Cu (12.7 h) relative to 18 F (110 min), longer cell-tracking periods (up to 24–36 h) should be possible now with PET. cell tracking‖Cu–PTSM‖PET‖cell labeling
doi_str_mv	10.1073/pnas.052709599
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The labeling efficiency was directly proportional to 64 Cu–PTSM concentration and influenced negatively by serum. Label uptake per cell was greater with 64 Cu–PTSM than with FDG. However, both 64 Cu–PTSM- and FDG-labeled cells showed efflux of cell activity into supernatant. The 64 Cu–PTSM labeling procedure did not interfere significantly with C6 cell viability and proliferation rate. MicroPET images of living mice indicate that tail-vein-injected labeled C6 cells traffic to the lungs and liver. In addition, transient splenic accumulation of radioactivity was clearly detectable in a mouse scanned at 3.33 h postinfusion of 64 Cu–PTSM-labeled lymphocytes. In contrast, the liver was the principal organ of tracer localization after tail-vein administration of 64 Cu–PTSM alone. These results indicate that in vivo imaging of cell trafficking is possible with 64 Cu–PTSM-labeled cells. 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The labeling efficiency was directly proportional to 64 Cu–PTSM concentration and influenced negatively by serum. Label uptake per cell was greater with 64 Cu–PTSM than with FDG. However, both 64 Cu–PTSM- and FDG-labeled cells showed efflux of cell activity into supernatant. The 64 Cu–PTSM labeling procedure did not interfere significantly with C6 cell viability and proliferation rate. MicroPET images of living mice indicate that tail-vein-injected labeled C6 cells traffic to the lungs and liver. In addition, transient splenic accumulation of radioactivity was clearly detectable in a mouse scanned at 3.33 h postinfusion of 64 Cu–PTSM-labeled lymphocytes. In contrast, the liver was the principal organ of tracer localization after tail-vein administration of 64 Cu–PTSM alone. These results indicate that in vivo imaging of cell trafficking is possible with 64 Cu–PTSM-labeled cells. 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The labeling efficiency was directly proportional to 64 Cu–PTSM concentration and influenced negatively by serum. Label uptake per cell was greater with 64 Cu–PTSM than with FDG. However, both 64 Cu–PTSM- and FDG-labeled cells showed efflux of cell activity into supernatant. The 64 Cu–PTSM labeling procedure did not interfere significantly with C6 cell viability and proliferation rate. MicroPET images of living mice indicate that tail-vein-injected labeled C6 cells traffic to the lungs and liver. In addition, transient splenic accumulation of radioactivity was clearly detectable in a mouse scanned at 3.33 h postinfusion of 64 Cu–PTSM-labeled lymphocytes. In contrast, the liver was the principal organ of tracer localization after tail-vein administration of 64 Cu–PTSM alone. These results indicate that in vivo imaging of cell trafficking is possible with 64 Cu–PTSM-labeled cells. Given the longer t 1/2 of 64 Cu (12.7 h) relative to 18 F (110 min), longer cell-tracking periods (up to 24–36 h) should be possible now with PET. cell tracking‖Cu–PTSM‖PET‖cell labeling</abstract><cop>United States</cop><pub>National Acad Sciences</pub><pmid>11867752</pmid><doi>10.1073/pnas.052709599</doi><tpages>6</tpages></addata></record>
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subjects	Animals Biological Sciences Cell Movement - physiology Cells Copper Copper Radioisotopes Fluorodeoxyglucose F18 - metabolism Glioma Male Mice Mice, Nude Organometallic Compounds - metabolism Organometallic Compounds - toxicity Rats Rodents Thiosemicarbazones - metabolism Thiosemicarbazones - toxicity Tomography Tomography, Emission-Computed - methods Tumor Cells, Cultured
title	Ex vivo cell labeling with 64Cu–pyruvaldehyde-bis(N4-methylthiosemicarbazone) for imaging cell trafficking in mice with positron-emission tomography
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