Ganesan Vaidyanathan

Astatine-211-Labeled Radiotherapeutics An Emerging Approach to Targeted Alpha-Particle Radiotherapy

Targeted radiotherapy or endoradiotherapy is an appealing approach to cancer treatment because of the potential for delivering curative doses of radiation to tumor while sparing normal tissues. Radionuclides that decay by the emission of alpha-particles such as the heavy halogen astatine-211 (211At) offer the exciting prospect of combining cell-specific molecular targets with radiation having a range in tissue of only a few cell diameters. Herein, the radiobiological advantages of alpha-particle targeted radiotherapy will be reviewed, and the rationale for using 211At for this purpose will be described. The chemistry of astatine is similar to that of iodine; however, there are important differences which make the synthesis and evaluation of 211At-labeled compounds more challenging. Perhaps the most successful approach that has been developed involves the astatodemetallation of tin, silicon or mercury precursors. Astatine-211 labeled agents that have been investigated for targeted radiotherapy include [211At]astatide, 211At- labeled particulates, 211At-labeled naphthoquinone derivatives, 211At-labeled methylene blue, 211At-labeled DNA precursors, meta-[211At]astatobenzylguanidine, 211At-labeled biotin conjugates, 211At-labeled bisphosphonates, and 211At-labeled antibodies and antibody fragments. The status of these 211At-labeled compounds will be discussed in terms of their labeling chemistry, cytotoxicity in cell culture, as well as their tissue distribution and therapeutic efficacy in animal models of human cancers. Finally, an update on the status of the first clinical trial with an 211At-labeled targeted therapeutic, 211At-labeled chimeric anti-tenascin antibody 81C6, will be provided.

Synthesis of N-succinimidyl 4-[18F]fluorobenzoate, an agent for labeling proteins and peptides with 18F

This protocol describes the step-by-step procedure for the synthesis of N-succinimidyl 4-[18F]fluorobenzoate ([18F]SFB), an agent widely used for labeling proteins and peptides with the positron-emitting radionuclide 18F. The protocols for the synthesis of unlabeled SFB and the quaternary salt precursor 4-formyl-N,N,N-trimethyl benzenaminium trifluoromethane sulfonate also are described. For the [18F]SFB synthesis, the quaternary salt is first converted to 4-[18F]fluorobenzaldehyde. Oxidation of the latter provides 4-[18F]fluorobenzoic acid, which is converted to [18F]SFB by treatment with N,N-disuccinimidyl carbonate. Using this method, [18F]SFB can be synthesized in decay-corrected radiochemical yields of 30%–35% and a specific radioactivity of 11–12 GBq μmol−1. The total synthesis and purification time required is about 80 min, starting from delivery of the [18F]fluoride. [18F]SFB remains an optimal reagent for labeling proteins and peptides with 18F because of good conjugation yields and metabolic stability.

Targeted therapy using alpha emitters

Radionuclides such as 211At and 212Bi which decay by the emission of alpha-particles are attractive for certain applications of targeted radiotherapy. The tissue penetration of 212Bi and 211At alpha-particles is equivalent to only a few cell diameters, offering the possibility of combining cell-specific targeting with radiation of similar range. Unlike the beta-particles emitted by radionuclides such as 131I and 90Y, alpha-particles are radiation of high linear energy transfer and thus greater biological effectiveness. Several approaches have been explored for targeted radiotherapy with 212Bi- and 211At-labelled substances including colloids, monoclonal antibodies, metabolic precursors, receptor-avid ligands and other lower molecular weight molecules. An additional agent which exemplifies the promise of alpha-emitting radiopharmaceuticals is meta-[211At]astatobenzylguanidine. The toxicity of this compound under single-cell conditions, determined both by [3H]thymidine incorporation and by limiting dilution clonogenic assays, for human neuroblastoma cells is of the order of 1000 times higher than that of meta-[131I] iodobenzylguanidine. For meta-[211At] astatobenzylguanidine, the Do value was equivalent to only 6-7 211At atoms bound per cell. These results suggest that meta-[211At] astatobenzylguanidine might be valuable for the targeted radiotherapy of micrometastatic neuroblastomas.

A Plasmonic Gold Nanostar Theranostic Probe for In Vivo Tumor Imaging and Photothermal Therapy.

Nanomedicine has attracted increasing attention in recent years, because it offers great promise to provide personalized diagnostics and therapy with improved treatment efficacy and specificity. In this study, we developed a gold nanostar (GNS) probe for multi-modality theranostics including surface-enhanced Raman scattering (SERS) detection, x-ray computed tomography (CT), two-photon luminescence (TPL) imaging, and photothermal therapy (PTT). We performed radiolabeling, as well as CT and optical imaging, to investigate the GNS probes biodistribution and intratumoral uptake at both macroscopic and microscopic scales. We also characterized the performance of the GNS nanoprobe for in vitro photothermal heating and in vivo photothermal ablation of primary sarcomas in mice. The results showed that 30-nm GNS have higher tumor uptake, as well as deeper penetration into tumor interstitial space compared to 60-nm GNS. In addition, we found that a higher injection dose of GNS can increase the percentage of tumor uptake. We also demonstrated the GNS probes superior photothermal conversion efficiency with a highly concentrated heating effect due to a tip-enhanced plasmonic effect. In vivo photothermal therapy with a near-infrared (NIR) laser under the maximum permissible exposure (MPE) led to ablation of aggressive tumors containing GNS, but had no effect in the absence of GNS. This multifunctional GNS probe has the potential to be used for in vivo biosensing, preoperative CT imaging, intraoperative detection with optical methods (SERS and TPL), as well as image-guided photothermal therapy.

Evaluation of anti-podoplanin rat monoclonal antibody NZ-1 for targeting malignant gliomas ☆

INTRODUCTION Podoplanin/aggrus is a mucin-like sialoglycoprotein that is highly expressed in malignant gliomas. Podoplanin has been reported to be a novel marker to enrich tumor-initiating cells, which are thought to resist conventional therapies and to be responsible for cancer relapse. The purpose of this study was to determine whether an anti-podoplanin antibody is suitable to target radionuclides to malignant gliomas. METHODS The binding affinity of an anti-podoplanin antibody, NZ-1 (rat IgG(2a)), was determined by surface plasmon resonance and Scatchard analysis. NZ-1 was radioiodinated with (125)I using Iodogen [(125)I-NZ-1(Iodogen)] or N-succinimidyl 4-guanidinomethyl 3-[(131)I]iodobenzoate ([(131)I]SGMIB-NZ-1), and paired-label internalization assays of NZ-1 were performed. The tissue distribution of (125)I-NZ-1(Iodogen) and that of [(131)I]SGMIB-NZ-1 were then compared in athymic mice bearing glioblastoma xenografts. RESULTS The dissociation constant (K(D)) of NZ-1 was determined to be 1.2 × 10(-10) M by surface plasmon resonance and 9.8 × 10(-10) M for D397MG glioblastoma cells by Scatchard analysis. Paired-label internalization assays in LN319 glioblastoma cells indicated that [(131)I]SGMIB-NZ-1 resulted in higher intracellular retention of radioactivity (26.3 ± 0.8% of initially bound radioactivity at 8 h) compared to that from the (125)I-NZ-1(Iodogen) (10.0 ± 0.1% of initially bound radioactivity at 8 h). Likewise, tumor uptake of [(131)I]SGMIB-NZ-1 (39.9 ± 8.8 %ID/g at 24 h) in athymic mice bearing D2159MG xenografts in vivo was significantly higher than that of (125)I-NZ-1(Iodogen) (29.7 ± 6.1 %ID/g at 24 h). CONCLUSIONS The overall results suggest that an anti-podoplanin antibody NZ-1 warrants further evaluation for antibody-based therapy against glioblastoma.

No-carrier-added synthesis of meta-[131I]iodobenzylguanidine.

No-carrier-added meta-[131I]iodobenzylguanidine ([131I]MIBG) was prepared starting with two different metallated precursors. Attempted preparation of 3-(tri-n-butylstannyl)benzylguanidine was not successful. An alternate two-step strategy using 3-(tri-n-butylstannyl)benzylamine could be used to prepare radio-iodinated [131I]MIBG in an overall radiochemical yield of 30-33%. Synthesis of [131I]MIBG via the radioiododesilylation of 3-trimethylsilylbenzylguanidine was also investigated. Yields were dependent on temperature, precursor concentration, solvent and nature of the oxidant. Radiochemical yields of 90% were obtained in 5 min at room temperature using either N-chlorosuccinimide or hydrogen peroxide in trifluoroacetic acid as oxidants. The percentage of specific binding in vitro of no-carrier-added MIBG to SK-N-SH neuroblastoma cells remained constant over a 2 log activity range, while the binding of MIBG prepared by isotopic exchange dropped by a factor of seven. In normal mice, heart and adrenal uptake of no-carrier-added [131I]MIBG was found to be higher than that of [131I]MIBG prepared by isotopic exchange.

Fluorine-18-labeled [Nle4,D-Phe7] -α-MSH, an α-melanocyte stimulating hormone analogue

Abstract The α-melanocyte stimulating hormone (α-MSH) analogue [Nle 4 , d -Phe 7 ]-α-MSH was labeled with 18 F using N -succinimidyl 4-[ 18 F]fluorobenzoate ([ 18 F]SFB) in >80% radiochemical yield. The IC 50 values of [Nle 4 , d -Phe 7 ]-α-MSH and para -fluorobenzoyl-[Nle 4 , d -Phe 7 ]-α-MSH ([Nle 4 , d -Phe 7 , Lys 11 -( 18 F)PFB]-α-MSH) for inhibiting the binding of meta -[ 131 I]iodobenzoyl-[Nle 4 , d -Phe 7 ]-α-MSH ([NIe 4 , d -Phe 7 , Lys 11 - 131 I)MIB]-α-MSH) to B16-F1 murine melanoma cells were 89 ± 9 pM and 112 ± 22 pM, respectively, suggesting that addition of 4-fluorobenzoate did not compromise α-MSH receptor binding affinity. Binding of [Nle 4 , d -Phe 7 ,Lys 11 -( 18 F)PFB]-α-MSH was influenced by the specific activity of the preparation (400–1000 Ci/mmol). The normal tissue clearance of [Nle 4 , d -Phe 7 ,Lys 11 -( 18 F)PFB]-α-MSH in mice was quite rapid, with little evidence for defluorination.

Uptake mechanisms of meta-[123I]iodobenzylguanidine in isolated rat heart

In order to clarify the uptake and retention mechanisms of radioiodinated meta-iodobenzylguanidine (MIBG) in heart, the kinetics of no-carrier-added [123I]MIBG were studied in the isolated working rat heart in interaction with pharmacologic agents. The tracer was administered in the perfusate as a 10-min pulse, followed by a 90-min washout period. Kinetic analysis of the externally monitored time-activity curves of control hearts showed avid uptake (Ki = 4.4 +/- 0.7 mL/min/g), and monoexponential clearance (ko = 0.0056 +/- 0.0017 l/min), indicating a distribution volume (Vd = Ki/ko) of 834 +/- 214 mL/g. Blocking experiments (n = 41) were performed with neuronal uptake (uptake-1) inhibitor desipramine (DMI; 50-100 nM) and the extraneuronal uptake (uptake-2) inhibitor N-(9-fluorenyl)-N-methyl-beta-chloroethylamine (SKF550; 0.4-0.8 microM). Uptake rate was 27% reduced (P < 0.05) by 50 nM DMI but not significantly affected by 0.4 microM SKF550. Distribution volume was 88% reduced (P < 0.0005) by 50 nM DMI and 28% reduced (P < 0.05) by 0.4 microM SKF550. In DMI-blocked hearts, uptake rate was dramatically decreased (-80%, P < 0.0005) by SKF550 (0.4 microM), indicating uptake-2 transport contributed predominantly to the extraneuronal uptake of the tracer. The slow uptake rate seen with concomitant inhibition of uptake-1 and uptake-2 was further decreased by addition of unlabeled MIBG (1-10 microM) in a concentration-dependent manner, yet unaffected by addition of the vesicular uptake inhibitor Ro 4-1284 (1 microM). Thus, the uptake rate of [123I]MIBG is primarily dependent on uptake-1 and uptake-2 activity. Other possible mechanisms of uptake such as passive diffusion in association with intracellular binding are significant only in conditions where uptake-1 and uptake-2 mechanisms are largely inhibited.

An efficient targeted radiotherapy/gene therapy strategy utilising human telomerase promoters and radioastatine and harnessing radiation-mediated bystander effects

Targeted radiotherapy achieves malignant cell‐specific concentration of radiation dosage by tumour‐affinic molecules conjugated to radioactive atoms. Combining gene therapy with targeted radiotherapy is attractive because the associated cross‐fire irradiation of the latter induces biological bystander effects upon neighbouring cells overcoming low gene transfer efficiency.

Targeting breast carcinoma with radioiodinated anti-HER2 Nanobody

INTRODUCTION With a molecular weight an order of magnitude lower than antibodies but possessing comparable affinities, Nanobodies (Nbs) are attractive as targeting agents for cancer diagnosis and therapy. An anti-HER2 Nb could be utilized to determine HER2 status in breast cancer patients prior to trastuzumab treatment. This provided motivation for the generation of HER2-specific 5F7GGC Nb, its radioiodination and evaluation for targeting HER2 expressing tumors. METHODS 5F7GGC Nb was radioiodinated with ¹²⁵I using Iodogen and with ¹³¹I using the residualizing agent N(ɛ)-(3-[¹³¹I]iodobenzoyl)-Lys⁵-N(α)-maleimido-Gly¹-GEEEK ([¹³¹I]IB-Mal-D-GEEEK) used previously successfully with intact antibodies. Paired-label internalization assays using BT474M1 cells and tissue distribution experiments in athymic mice bearing BT474M1 xenografts were performed to compare the two labeled Nb preparations. RESULTS The radiochemical yields for Iodogen and [¹³¹I]IB-Mal-D-GEEEK labeling were 83.6±5.0% (n=10) and 59.6±9.4% (n=15), respectively. The immunoreactivity of labeled proteins was preserved as confirmed by in vitro and in vivo binding to tumor cells. Biodistribution studies showed that Nb radiolabeled using [¹³¹I]IB-Mal-D-GEEEK, compared with the directly labeled Nb, had a higher tumor uptake (4.65±0.61% ID/g vs. 2.92±0.24% ID/g at 8h), faster blood clearance, lower accumulation in non-target organs except kidneys, and as a result, higher concomitant tumor-to-blood and tumor-to-tissue ratios. CONCLUSIONS Taken together, these results demonstrate that 5F7GGC anti-HER2 Nb labeled with residualizing [¹³¹I]IB-Mal-D-GEEEK had better tumor targeting properties compared to the directly labeled Nb suggesting the potential utility of this Nb conjugate for SPECT (¹²⁹I) and PET imaging (¹²⁴I) of patients with HER2-expressing tumors.