Polymeric micelles and vesicles: biological behavior evaluation using radiolabeling techniques

Dimitrios PsimadasDepartment of Medical Instruments Technology, Technological Educational Institute of Athens Egaleo, AthensGreece;Institute of Nuclear and Radiological Sciences and Technology, Energy & Safety, NCSR “Demokritos” Aghia Paraskevi, AthensGreece;Department of Nuclear Medicine, University Hospital of Larissa Mezourlo, LarissaGreeceCorrespondence[email protected]

Hugo OliveiraIPB, ENSCBP, University of Bordeaux Pessac CedexFrance;Laboratory of Organic Chemistry Polymers (UMR5629), CNRS Pessac CedexFrance

Julie ThevenotIPB, ENSCBP, University of Bordeaux Pessac CedexFrance;Laboratory of Organic Chemistry Polymers (UMR5629), CNRS Pessac CedexFrance

Sebastien LecommandouxIPB, ENSCBP, University of Bordeaux Pessac CedexFrance;Laboratory of Organic Chemistry Polymers (UMR5629), CNRS Pessac CedexFrance

Penelope BouziotisInstitute of Nuclear and Radiological Sciences and Technology, Energy & Safety, NCSR “Demokritos” Aghia Paraskevi, AthensGreece

Alexandra D. VarvarigouInstitute of Nuclear and Radiological Sciences and Technology, Energy & Safety, NCSR “Demokritos” Aghia Paraskevi, AthensGreece

Panagiotis GeorgouliasDepartment of Nuclear Medicine, University Hospital of Larissa Mezourlo, LarissaGreece

George LoudosDepartment of Medical Instruments Technology, Technological Educational Institute of Athens Egaleo, AthensGreece

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Abstract

The application of combined diagnosis and therapy through nanotechnology applications is attracting increasing attention worldwide. Polymeric self-assembled nanoparticles (NPs) have been studied for this purpose. Micelles and vesicles with or without a magnetic core can efficiently carry diagnostic and/or therapeutic agents to a desired target. The biological behavior of these NPs has been evaluated in this study, after radiolabeling with ^99mTc. In vitro stability, in media that mimic the environment of the living body, was better for vesicles than for micelles at 1 h and decreased for both as time passed. After administration to healthy animals, all NPs presented major uptake at liver and spleen as expected. Biodistribution and imaging studies confirmed the higher uptake in these organs for the hybrid NPs and at higher extent for the ones with larger size, indicating that the magnetic load and size play an important role on in vivo distribution.

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Acknowledgements

The authors thank Stavros Xanthopoulos for his expert assistance with the animal studies and Dr Theodoros Tsotakos for constructive discussion.

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Polymeric micelles and vesicles: biological behavior evaluation using radiolabeling techniques

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