Biodistribution of radiolabelled human dendritic cells injected by various routes

Biodistribution of radiolabelled human dendritic cells injected by various routes

The purpose of this study was to investigate the biodistribution of mature dendritic cells (DCs) injected by various routes, during a cell therapy protocol. In the context of a vaccine therapy protocol for melanoma, DCs matured with Ribomunyl and interferon-gamma were labelled with( 111)In-oxine and...

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Bibliographic Details
Published in:European journal of nuclear medicine and molecular imaging Vol. 32; no. 7; pp. 731 - 741
Main Authors: Quillien, Véronique, Moisan, Annick, Carsin, Andre, Lesimple, Thierry, Lefeuvre, Claudia, Adamski, Henri, Bertho, Nicolas, Devillers, Anne, Leberre, Claudine, Toujas, Louis
Format: Journal Article
Language:English
Published: Germany Springer Nature B.V 01-07-2005
Springer Verlag (Germany) [1976-....]
Subjects:
Antigens, Bacterial - pharmacology
Cancer Vaccines
Cell Movement
Cell Survival
Cell Transplantation - methods
Cell- and Tissue-Based Therapy
Chemokine CCL21
Chemokines, CC - metabolism
Clinical Trials as Topic
Dendritic Cells - cytology
Dendritic Cells - pathology
Humans
Immunoassay
Interferon-gamma - metabolism
Interleukin-12 - metabolism
Life Sciences
Lymph Nodes - pathology
Lymphocytes - metabolism
Lymphocytes - pathology
Melanoma - drug therapy
Neoplasm Metastasis
Phenotype
Protein Subunits - metabolism
Radionuclide Imaging
Receptors, CCR7
Receptors, Chemokine - metabolism
Th1 Cells
Time Factors
Dendritic cells -111 In-oxine -Clinical trial -Migration -CC chemokine receptor 7
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Summary:The purpose of this study was to investigate the biodistribution of mature dendritic cells (DCs) injected by various routes, during a cell therapy protocol. In the context of a vaccine therapy protocol for melanoma, DCs matured with Ribomunyl and interferon-gamma were labelled with( 111)In-oxine and injected into eight patients along various routes: afferent lymphatic vessel (IL) (4 times), lymph node (IN) (5 times) and intradermally (ID) (6 times). Scintigraphic investigations showed that the IL route allowed localisation of 80% of injected radioactivity in eight to ten nodes. In three cases of IN injection, the entire radioactivity stagnated in the injected nodes, while in two cases, migration to adjacent nodes was observed. This migration was detected rapidly after injection, as with IL injections, suggesting that passive transport occurred along the physiological lymphatic pathways. In two of the six ID injections, 1-2% of injected radioactivity reached a proximal lymph node. Migration was detectable in the first hour, but increased considerably after 24 h, suggesting an active migration mechanism. In both of the aforementioned cases, DCs were strongly CCR7-positive, but this feature was not a sufficient condition for effective migration. In comparison with DCs matured with TNF-alpha, IL-1beta, IL-6 and PGE2, our DCs showed a weaker in vitro migratory response to CCL21, despite comparable CCR7 expression, and higher allostimulatory and TH1 polarisation capacities. The IL route allowed reproducible administration of specified numbers of DCs. The IN route sometimes yielded fairly similar results, but not reproducibly. Lastly, we showed that DCs matured without PGE2 that have in vitro TH1 polarisation capacities can migrate to lymph nodes after ID injection.
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ISSN:1619-7070
1619-7089
DOI:10.1007/s00259-005-1825-9