Pretargeted imaging beyond the blood-brain barrier

Research output: Contribution to journalJournal articleResearchpeer-review

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Pretargeted imaging beyond the blood-brain barrier. / Shalgunov, Vladimir; Lopes van den Broek, Sara; Vang Andersen, Ida; García Vázquez, Rocío; Raval, Nakul Ravi; Palner, Mikael; Mori, Yuki; Schäfer, Gabriela; Herrmann, Barbara; Mikula, Hannes; Beschorner, Natalie; Nedergaard, Maiken; Syvänen, Stina; Barz, Matthias; Moos Knudsen, Gitte; Battisti, Umberto Maria; Herth, Matthias Manfred.

In: RSC Medicinal Chemistry, Vol. 14, No. 3, 2022, p. 444-453.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Shalgunov, V, Lopes van den Broek, S, Vang Andersen, I, García Vázquez, R, Raval, NR, Palner, M, Mori, Y, Schäfer, G, Herrmann, B, Mikula, H, Beschorner, N, Nedergaard, M, Syvänen, S, Barz, M, Moos Knudsen, G, Battisti, UM & Herth, MM 2022, 'Pretargeted imaging beyond the blood-brain barrier', RSC Medicinal Chemistry, vol. 14, no. 3, pp. 444-453. https://doi.org/10.1039/d2md00360k

APA

Shalgunov, V., Lopes van den Broek, S., Vang Andersen, I., García Vázquez, R., Raval, N. R., Palner, M., Mori, Y., Schäfer, G., Herrmann, B., Mikula, H., Beschorner, N., Nedergaard, M., Syvänen, S., Barz, M., Moos Knudsen, G., Battisti, U. M., & Herth, M. M. (2022). Pretargeted imaging beyond the blood-brain barrier. RSC Medicinal Chemistry, 14(3), 444-453. https://doi.org/10.1039/d2md00360k

Vancouver

Shalgunov V, Lopes van den Broek S, Vang Andersen I, García Vázquez R, Raval NR, Palner M et al. Pretargeted imaging beyond the blood-brain barrier. RSC Medicinal Chemistry. 2022;14(3):444-453. https://doi.org/10.1039/d2md00360k

Author

Shalgunov, Vladimir ; Lopes van den Broek, Sara ; Vang Andersen, Ida ; García Vázquez, Rocío ; Raval, Nakul Ravi ; Palner, Mikael ; Mori, Yuki ; Schäfer, Gabriela ; Herrmann, Barbara ; Mikula, Hannes ; Beschorner, Natalie ; Nedergaard, Maiken ; Syvänen, Stina ; Barz, Matthias ; Moos Knudsen, Gitte ; Battisti, Umberto Maria ; Herth, Matthias Manfred. / Pretargeted imaging beyond the blood-brain barrier. In: RSC Medicinal Chemistry. 2022 ; Vol. 14, No. 3. pp. 444-453.

Bibtex

@article{1b73b791527d4aa0bac38be99a9144db,
title = "Pretargeted imaging beyond the blood-brain barrier",
abstract = "Pretargeting is a powerful nuclear imaging strategy to achieve enhanced imaging contrast for nanomedicines and reduce the radiation burden to healthy tissue. Pretargeting is based on bioorthogonal chemistry. The most attractive reaction for this purpose is currently the tetrazine ligation, which occurs between trans-cyclooctene (TCO) tags and tetrazines (Tzs). Pretargeted imaging beyond the blood-brain barrier (BBB) is challenging and has not been reported thus far. In this study, we developed Tz imaging agents that are capable of ligating in vivo to targets beyond the BBB. We chose to develop 18F-labeled Tzs as they can be applied to positron emission tomography (PET) - the most powerful molecular imaging technology. Fluorine-18 is an ideal radionuclide for PET due to its almost ideal decay properties. As a non-metal radionuclide, fluorine-18 also allows for development of Tzs with physicochemical properties enabling passive brain diffusion. To develop these imaging agents, we applied a rational drug design approach. This approach was based on estimated and experimentally determined parameters such as the BBB score, pretargeted autoradiography contrast, in vivo brain influx and washout as well as on peripheral metabolism profiles. From 18 initially developed structures, five Tzs were selected to be tested for their in vivo click performance. Whereas all selected structures clicked in vivo to TCO-polymer deposited into the brain, [18F]18 displayed the most favorable characteristics with respect to brain pretargeting. [18F]18 is our lead compound for future pretargeted neuroimaging studies based on BBB-penetrant monoclonal antibodies. Pretargeting beyond the BBB will allow us to image targets in the brain that are currently not imageable, such as soluble oligomers of neurodegeneration biomarker proteins. Imaging of such currently non-imageable targets will allow early diagnosis and personalized treatment monitoring. This in turn will accelerate drug development and greatly benefit patient care.",
author = "Vladimir Shalgunov and {Lopes van den Broek}, Sara and {Vang Andersen}, Ida and {Garc{\'i}a V{\'a}zquez}, Roc{\'i}o and Raval, {Nakul Ravi} and Mikael Palner and Yuki Mori and Gabriela Sch{\"a}fer and Barbara Herrmann and Hannes Mikula and Natalie Beschorner and Maiken Nedergaard and Stina Syv{\"a}nen and Matthias Barz and {Moos Knudsen}, Gitte and Battisti, {Umberto Maria} and Herth, {Matthias Manfred}",
note = "Publisher Copyright: {\textcopyright} 2023 RSC.",
year = "2022",
doi = "10.1039/d2md00360k",
language = "English",
volume = "14",
pages = "444--453",
journal = "RSC Medicinal Chemistry",
issn = "2040-2503",
publisher = "Royal Society of Chemistry",
number = "3",

}

RIS

TY - JOUR

T1 - Pretargeted imaging beyond the blood-brain barrier

AU - Shalgunov, Vladimir

AU - Lopes van den Broek, Sara

AU - Vang Andersen, Ida

AU - García Vázquez, Rocío

AU - Raval, Nakul Ravi

AU - Palner, Mikael

AU - Mori, Yuki

AU - Schäfer, Gabriela

AU - Herrmann, Barbara

AU - Mikula, Hannes

AU - Beschorner, Natalie

AU - Nedergaard, Maiken

AU - Syvänen, Stina

AU - Barz, Matthias

AU - Moos Knudsen, Gitte

AU - Battisti, Umberto Maria

AU - Herth, Matthias Manfred

N1 - Publisher Copyright: © 2023 RSC.

PY - 2022

Y1 - 2022

N2 - Pretargeting is a powerful nuclear imaging strategy to achieve enhanced imaging contrast for nanomedicines and reduce the radiation burden to healthy tissue. Pretargeting is based on bioorthogonal chemistry. The most attractive reaction for this purpose is currently the tetrazine ligation, which occurs between trans-cyclooctene (TCO) tags and tetrazines (Tzs). Pretargeted imaging beyond the blood-brain barrier (BBB) is challenging and has not been reported thus far. In this study, we developed Tz imaging agents that are capable of ligating in vivo to targets beyond the BBB. We chose to develop 18F-labeled Tzs as they can be applied to positron emission tomography (PET) - the most powerful molecular imaging technology. Fluorine-18 is an ideal radionuclide for PET due to its almost ideal decay properties. As a non-metal radionuclide, fluorine-18 also allows for development of Tzs with physicochemical properties enabling passive brain diffusion. To develop these imaging agents, we applied a rational drug design approach. This approach was based on estimated and experimentally determined parameters such as the BBB score, pretargeted autoradiography contrast, in vivo brain influx and washout as well as on peripheral metabolism profiles. From 18 initially developed structures, five Tzs were selected to be tested for their in vivo click performance. Whereas all selected structures clicked in vivo to TCO-polymer deposited into the brain, [18F]18 displayed the most favorable characteristics with respect to brain pretargeting. [18F]18 is our lead compound for future pretargeted neuroimaging studies based on BBB-penetrant monoclonal antibodies. Pretargeting beyond the BBB will allow us to image targets in the brain that are currently not imageable, such as soluble oligomers of neurodegeneration biomarker proteins. Imaging of such currently non-imageable targets will allow early diagnosis and personalized treatment monitoring. This in turn will accelerate drug development and greatly benefit patient care.

AB - Pretargeting is a powerful nuclear imaging strategy to achieve enhanced imaging contrast for nanomedicines and reduce the radiation burden to healthy tissue. Pretargeting is based on bioorthogonal chemistry. The most attractive reaction for this purpose is currently the tetrazine ligation, which occurs between trans-cyclooctene (TCO) tags and tetrazines (Tzs). Pretargeted imaging beyond the blood-brain barrier (BBB) is challenging and has not been reported thus far. In this study, we developed Tz imaging agents that are capable of ligating in vivo to targets beyond the BBB. We chose to develop 18F-labeled Tzs as they can be applied to positron emission tomography (PET) - the most powerful molecular imaging technology. Fluorine-18 is an ideal radionuclide for PET due to its almost ideal decay properties. As a non-metal radionuclide, fluorine-18 also allows for development of Tzs with physicochemical properties enabling passive brain diffusion. To develop these imaging agents, we applied a rational drug design approach. This approach was based on estimated and experimentally determined parameters such as the BBB score, pretargeted autoradiography contrast, in vivo brain influx and washout as well as on peripheral metabolism profiles. From 18 initially developed structures, five Tzs were selected to be tested for their in vivo click performance. Whereas all selected structures clicked in vivo to TCO-polymer deposited into the brain, [18F]18 displayed the most favorable characteristics with respect to brain pretargeting. [18F]18 is our lead compound for future pretargeted neuroimaging studies based on BBB-penetrant monoclonal antibodies. Pretargeting beyond the BBB will allow us to image targets in the brain that are currently not imageable, such as soluble oligomers of neurodegeneration biomarker proteins. Imaging of such currently non-imageable targets will allow early diagnosis and personalized treatment monitoring. This in turn will accelerate drug development and greatly benefit patient care.

U2 - 10.1039/d2md00360k

DO - 10.1039/d2md00360k

M3 - Journal article

AN - SCOPUS:85145705810

VL - 14

SP - 444

EP - 453

JO - RSC Medicinal Chemistry

JF - RSC Medicinal Chemistry

SN - 2040-2503

IS - 3

ER -

ID: 395082486