Dual‐Nuclide Radiopharmaceuticals for Positron Emission Tomography Based Dosimetry in Radiotherapy

Improvement of the accuracy of dosimetry in radionuclide therapy has the potential to increase patient safety and therapeutic outcomes. Although positron emission tomography (PET) is ideally suited for acquisition of dosimetric data because PET is inherently quantitative and offers high sensitivity...

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Veröffentlicht in:	Chemistry : a European journal 2018-01, Vol.24 (3), p.547-550
Hauptverfasser:	Wurzer, Alexander, Seidl, Christof, Morgenstern, Alfred, Bruchertseifer, Frank, Schwaiger, Markus, Wester, Hans‐Jürgen, Notni, Johannes
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Sprache:	eng
Schlagworte:	Animals Aza Compounds - chemistry Bismuth isotopes Cations chelate ligands Chelating agents Chelating Agents - chemistry Chemical synthesis Chemistry click chemistry Communication Communications Conjugates Copper Cyclams Dipeptides - chemistry Dosimeters Dosimetry Heterocyclic Compounds - chemistry Heterografts Humans Male Metals Mice, SCID molecular imaging molecular radiotherapy Neoplasm Transplantation Phosphatidylinositol Phosphates - chemistry Phosphinic Acids - chemistry Piperidines - chemistry Positron emission Positron emission tomography Positrons Prostate Prostate cancer Prostate carcinoma Prostatic Neoplasms - radiotherapy Radiation therapy Radioisotopes radionuclides Radiopharmaceuticals - chemistry Radiopharmaceuticals - pharmacology Spatial discrimination Spatial resolution Structure-Activity Relationship Tomography Trivalent ions Urea Xenografts
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creator	Wurzer, Alexander Seidl, Christof Morgenstern, Alfred Bruchertseifer, Frank Schwaiger, Markus Wester, Hans‐Jürgen Notni, Johannes
description	Improvement of the accuracy of dosimetry in radionuclide therapy has the potential to increase patient safety and therapeutic outcomes. Although positron emission tomography (PET) is ideally suited for acquisition of dosimetric data because PET is inherently quantitative and offers high sensitivity and spatial resolution, it is not directly applicable for this purpose because common therapeutic radionuclides lack the necessary positron emission. This work reports on the synthesis of dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, which are based on common and widely available metal radionuclides. Dual‐chelator conjugates, featuring interlinked cyclen‐ and triazacyclononane‐based polyphosphinates DOTPI and TRAP, allow for strictly regioselective complexation of therapeutic (e.g., 177Lu, 90Y, or 213Bi) and PET (e.g., 68Ga) radiometals in the same molecular framework by exploiting the orthogonal metal ion selectivity of these chelators (DOTPI: large cations, such as lanthanide(III) ions; TRAP: small trivalent ions, such as GaIII). Such DOTPI–TRAP conjugates were decorated with 3 Gly‐urea‐Lys (KuE) motifs for targeting prostate‐specific membrane antigen (PSMA), employing Cu‐catalyzed (CuAAC) as well as strain‐promoted (SPAAC) click chemistry. These were labeled with 177Lu or 213Bi and 68Ga and used for in vivo imaging of LNCaP (human prostate carcinoma) tumor xenografts in SCID mice by PET, thus proving practical applicability of the concept. Take two: Dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, derived from common and widely available metal radionuclides, enable a precise PET‐based dosimetry for improvement of individual therapeutic outcome and increased patient safety in molecular radiotherapy.
doi_str_mv	10.1002/chem.201702335
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Although positron emission tomography (PET) is ideally suited for acquisition of dosimetric data because PET is inherently quantitative and offers high sensitivity and spatial resolution, it is not directly applicable for this purpose because common therapeutic radionuclides lack the necessary positron emission. This work reports on the synthesis of dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, which are based on common and widely available metal radionuclides. Dual‐chelator conjugates, featuring interlinked cyclen‐ and triazacyclononane‐based polyphosphinates DOTPI and TRAP, allow for strictly regioselective complexation of therapeutic (e.g., 177Lu, 90Y, or 213Bi) and PET (e.g., 68Ga) radiometals in the same molecular framework by exploiting the orthogonal metal ion selectivity of these chelators (DOTPI: large cations, such as lanthanide(III) ions; TRAP: small trivalent ions, such as GaIII). Such DOTPI–TRAP conjugates were decorated with 3 Gly‐urea‐Lys (KuE) motifs for targeting prostate‐specific membrane antigen (PSMA), employing Cu‐catalyzed (CuAAC) as well as strain‐promoted (SPAAC) click chemistry. These were labeled with 177Lu or 213Bi and 68Ga and used for in vivo imaging of LNCaP (human prostate carcinoma) tumor xenografts in SCID mice by PET, thus proving practical applicability of the concept. 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Although positron emission tomography (PET) is ideally suited for acquisition of dosimetric data because PET is inherently quantitative and offers high sensitivity and spatial resolution, it is not directly applicable for this purpose because common therapeutic radionuclides lack the necessary positron emission. This work reports on the synthesis of dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, which are based on common and widely available metal radionuclides. Dual‐chelator conjugates, featuring interlinked cyclen‐ and triazacyclononane‐based polyphosphinates DOTPI and TRAP, allow for strictly regioselective complexation of therapeutic (e.g., 177Lu, 90Y, or 213Bi) and PET (e.g., 68Ga) radiometals in the same molecular framework by exploiting the orthogonal metal ion selectivity of these chelators (DOTPI: large cations, such as lanthanide(III) ions; TRAP: small trivalent ions, such as GaIII). 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Although positron emission tomography (PET) is ideally suited for acquisition of dosimetric data because PET is inherently quantitative and offers high sensitivity and spatial resolution, it is not directly applicable for this purpose because common therapeutic radionuclides lack the necessary positron emission. This work reports on the synthesis of dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, which are based on common and widely available metal radionuclides. Dual‐chelator conjugates, featuring interlinked cyclen‐ and triazacyclononane‐based polyphosphinates DOTPI and TRAP, allow for strictly regioselective complexation of therapeutic (e.g., 177Lu, 90Y, or 213Bi) and PET (e.g., 68Ga) radiometals in the same molecular framework by exploiting the orthogonal metal ion selectivity of these chelators (DOTPI: large cations, such as lanthanide(III) ions; TRAP: small trivalent ions, such as GaIII). Such DOTPI–TRAP conjugates were decorated with 3 Gly‐urea‐Lys (KuE) motifs for targeting prostate‐specific membrane antigen (PSMA), employing Cu‐catalyzed (CuAAC) as well as strain‐promoted (SPAAC) click chemistry. These were labeled with 177Lu or 213Bi and 68Ga and used for in vivo imaging of LNCaP (human prostate carcinoma) tumor xenografts in SCID mice by PET, thus proving practical applicability of the concept. Take two: Dual‐nuclide labeled radiopharmaceuticals with therapeutic and PET functionality, derived from common and widely available metal radionuclides, enable a precise PET‐based dosimetry for improvement of individual therapeutic outcome and increased patient safety in molecular radiotherapy.</abstract><cop>Germany</cop><pub>Wiley Subscription Services, Inc</pub><pmid>28833667</pmid><doi>10.1002/chem.201702335</doi><tpages>4</tpages><orcidid>https://orcid.org/0000-0002-3964-3391</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Animals Aza Compounds - chemistry Bismuth isotopes Cations chelate ligands Chelating agents Chelating Agents - chemistry Chemical synthesis Chemistry click chemistry Communication Communications Conjugates Copper Cyclams Dipeptides - chemistry Dosimeters Dosimetry Heterocyclic Compounds - chemistry Heterografts Humans Male Metals Mice, SCID molecular imaging molecular radiotherapy Neoplasm Transplantation Phosphatidylinositol Phosphates - chemistry Phosphinic Acids - chemistry Piperidines - chemistry Positron emission Positron emission tomography Positrons Prostate Prostate cancer Prostate carcinoma Prostatic Neoplasms - radiotherapy Radiation therapy Radioisotopes radionuclides Radiopharmaceuticals - chemistry Radiopharmaceuticals - pharmacology Spatial discrimination Spatial resolution Structure-Activity Relationship Tomography Trivalent ions Urea Xenografts
title	Dual‐Nuclide Radiopharmaceuticals for Positron Emission Tomography Based Dosimetry in Radiotherapy
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