Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers. / Henriksen, Jonas Rosager; Petersen, Anncatrine Luisa; Hansen, Anders Elias; Frankær, Christian Grundahl; Harris, Pernille; Elema, Dennis Ringkjøbing; Kristensen, Annemarie Thuri; Kjær, Andreas; Andresen, Thomas Lars.

In: A C S Applied Materials and Interfaces, Vol. 7, No. 41, 01.10.2015, p. 22796-22806.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Henriksen, JR, Petersen, AL, Hansen, AE, Frankær, CG, Harris, P, Elema, DR, Kristensen, AT, Kjær, A & Andresen, TL 2015, 'Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers', A C S Applied Materials and Interfaces, vol. 7, no. 41, pp. 22796-22806. https://doi.org/10.1021/acsami.5b04612

APA

Henriksen, J. R., Petersen, A. L., Hansen, A. E., Frankær, C. G., Harris, P., Elema, D. R., Kristensen, A. T., Kjær, A., & Andresen, T. L. (2015). Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers. A C S Applied Materials and Interfaces, 7(41), 22796-22806. https://doi.org/10.1021/acsami.5b04612

Vancouver

Henriksen JR, Petersen AL, Hansen AE, Frankær CG, Harris P, Elema DR et al. Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers. A C S Applied Materials and Interfaces. 2015 Oct 1;7(41):22796-22806. https://doi.org/10.1021/acsami.5b04612

Author

Henriksen, Jonas Rosager ; Petersen, Anncatrine Luisa ; Hansen, Anders Elias ; Frankær, Christian Grundahl ; Harris, Pernille ; Elema, Dennis Ringkjøbing ; Kristensen, Annemarie Thuri ; Kjær, Andreas ; Andresen, Thomas Lars. / Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers. In: A C S Applied Materials and Interfaces. 2015 ; Vol. 7, No. 41. pp. 22796-22806.

Bibtex

@article{67ce50d3149748cea403b9adbf06f2ab,
title = "Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers",
abstract = "Due to low ion permeability of lipid bilayers, it has been and still is common practice to use transporter molecules such as ionophores or lipophilic chelators to increase transmembrane diffusion rates and loading efficiencies of radionuclides into liposomes. Here, we report a novel and very simple method for loading the positron emitter (64)Cu(2+) into liposomes, which is important for in vivo positron emission tomography (PET) imaging. By this approach, copper is added to liposomes entrapping a chelator, which causes spontaneous diffusion of copper across the lipid bilayer where it is trapped. Using this method, we achieve highly efficient (64)Cu(2+) loading (>95%), high radionuclide retention (>95%), and favorable loading kinetics, excluding the use of transporter molecule additives. Therefore, clinically relevant activities of 200-400 MBq/patient can be loaded fast (60-75 min) and efficiently into preformed stealth liposomes avoiding subsequent purification steps. We investigate the molecular coordination of entrapped copper using X-ray absorption spectroscopy and demonstrate high adaptability of the loading method to pegylated, nonpegylated, gel- or fluid-like, cholesterol rich or cholesterol depleted, cationic, anionic, and zwitterionic lipid compositions. We demonstrate high in vivo stability of (64)Cu-liposomes in a large canine model observing a blood circulation half-life of 24 h and show a tumor accumulation of 6% ID/g in FaDu xenograft mice using PET imaging. With this work, it is demonstrated that copper ions are capable of crossing a lipid membrane unassisted. This method is highly valuable for characterizing the in vivo performance of liposome-based nanomedicine with great potential in diagnostic imaging applications.",
author = "Henriksen, {Jonas Rosager} and Petersen, {Anncatrine Luisa} and Hansen, {Anders Elias} and Frank{\ae}r, {Christian Grundahl} and Pernille Harris and Elema, {Dennis Ringkj{\o}bing} and Kristensen, {Annemarie Thuri} and Andreas Kj{\ae}r and Andresen, {Thomas Lars}",
year = "2015",
month = oct,
day = "1",
doi = "10.1021/acsami.5b04612",
language = "English",
volume = "7",
pages = "22796--22806",
journal = "ACS applied materials & interfaces",
issn = "1944-8244",
publisher = "American Chemical Society",
number = "41",

}

RIS

TY - JOUR

T1 - Remote loading of 64Cu2+ into liposomes without the use of ion transport enhancers

AU - Henriksen, Jonas Rosager

AU - Petersen, Anncatrine Luisa

AU - Hansen, Anders Elias

AU - Frankær, Christian Grundahl

AU - Harris, Pernille

AU - Elema, Dennis Ringkjøbing

AU - Kristensen, Annemarie Thuri

AU - Kjær, Andreas

AU - Andresen, Thomas Lars

PY - 2015/10/1

Y1 - 2015/10/1

N2 - Due to low ion permeability of lipid bilayers, it has been and still is common practice to use transporter molecules such as ionophores or lipophilic chelators to increase transmembrane diffusion rates and loading efficiencies of radionuclides into liposomes. Here, we report a novel and very simple method for loading the positron emitter (64)Cu(2+) into liposomes, which is important for in vivo positron emission tomography (PET) imaging. By this approach, copper is added to liposomes entrapping a chelator, which causes spontaneous diffusion of copper across the lipid bilayer where it is trapped. Using this method, we achieve highly efficient (64)Cu(2+) loading (>95%), high radionuclide retention (>95%), and favorable loading kinetics, excluding the use of transporter molecule additives. Therefore, clinically relevant activities of 200-400 MBq/patient can be loaded fast (60-75 min) and efficiently into preformed stealth liposomes avoiding subsequent purification steps. We investigate the molecular coordination of entrapped copper using X-ray absorption spectroscopy and demonstrate high adaptability of the loading method to pegylated, nonpegylated, gel- or fluid-like, cholesterol rich or cholesterol depleted, cationic, anionic, and zwitterionic lipid compositions. We demonstrate high in vivo stability of (64)Cu-liposomes in a large canine model observing a blood circulation half-life of 24 h and show a tumor accumulation of 6% ID/g in FaDu xenograft mice using PET imaging. With this work, it is demonstrated that copper ions are capable of crossing a lipid membrane unassisted. This method is highly valuable for characterizing the in vivo performance of liposome-based nanomedicine with great potential in diagnostic imaging applications.

AB - Due to low ion permeability of lipid bilayers, it has been and still is common practice to use transporter molecules such as ionophores or lipophilic chelators to increase transmembrane diffusion rates and loading efficiencies of radionuclides into liposomes. Here, we report a novel and very simple method for loading the positron emitter (64)Cu(2+) into liposomes, which is important for in vivo positron emission tomography (PET) imaging. By this approach, copper is added to liposomes entrapping a chelator, which causes spontaneous diffusion of copper across the lipid bilayer where it is trapped. Using this method, we achieve highly efficient (64)Cu(2+) loading (>95%), high radionuclide retention (>95%), and favorable loading kinetics, excluding the use of transporter molecule additives. Therefore, clinically relevant activities of 200-400 MBq/patient can be loaded fast (60-75 min) and efficiently into preformed stealth liposomes avoiding subsequent purification steps. We investigate the molecular coordination of entrapped copper using X-ray absorption spectroscopy and demonstrate high adaptability of the loading method to pegylated, nonpegylated, gel- or fluid-like, cholesterol rich or cholesterol depleted, cationic, anionic, and zwitterionic lipid compositions. We demonstrate high in vivo stability of (64)Cu-liposomes in a large canine model observing a blood circulation half-life of 24 h and show a tumor accumulation of 6% ID/g in FaDu xenograft mice using PET imaging. With this work, it is demonstrated that copper ions are capable of crossing a lipid membrane unassisted. This method is highly valuable for characterizing the in vivo performance of liposome-based nanomedicine with great potential in diagnostic imaging applications.

U2 - 10.1021/acsami.5b04612

DO - 10.1021/acsami.5b04612

M3 - Journal article

C2 - 26426093

VL - 7

SP - 22796

EP - 22806

JO - ACS applied materials & interfaces

JF - ACS applied materials & interfaces

SN - 1944-8244

IS - 41

ER -

ID: 160835096