Phase I Study of 68Ga-HER2-Nanobody for PET/CT Assessment of HER2 Expression in Breast Carcinoma

Radiolabeled HER2-targeted molecular probes in breast cancer imaging: current knowledge and future prospective

Breast cancer is the most frequent non-dermatologic malignancy in women. Breast cancer is characterized by the expression of the human epidermal growth factor receptor type 2 (HER2), and the presence or lack of estrogen receptor (ER) and progesterone receptor (PR) expression. HER2 overexpression is reported in about 20 to 25% of breast cancer patients, which is usually linked to cancer progression, metastases, and poor survival. Immunohistochemistry (IHC) and fluorescence in situ hybridization (FISH) are the gold standards for determining HER2 status, even though IHC has largely focused on quantifying HER2+ status versus "other" HER2 status (including variants with low or no expression). Recent findings regarding the beneficial therapeutic effects of anti-HER2 monoclonal antibodies (mAb) in HER2low metastatic patients lead to changes in the classic definition of advanced breast cancer, and methods for precise assessment of HER2 status are being developed. As a result, various radiolabeled HER-targeted mAbs and antibody fragments have been designed to avoid repeated biopsies with potential bias due to tumor heterogeneity, including single-chain variable fragment (scFv), F(ab')2, affibody, and nanobody. These small targeting radiotracers displayed favorable biodistributions, clearance, and stability, allowing for higher image quality, shorter circulation half-life, and lower immunogenicity. This study aimed to comprehensively review the application of radiolabeled anti-HER2 antibody fragments in breast cancer in vivo imaging and provide a better understanding of targeted HER2 quantification.

Radiotheranostic landscape: A review of clinical and preclinical development

BACKGROUND

Radiotheranostics combines diagnostic imaging with targeted radionuclide therapy, representing a transformative approach in precision oncology. Landmark approvals of Lutathera® and Pluvicto® have catalyzed significant advancements in this field, driving research into novel radionuclides, targeting strategies, and clinical applications. This review evaluates the evolving clinical and preclinical landscape of radiotheranostics, highlighting advancements, emerging trends, and persistent challenges in radionuclide therapy.

METHODS

A comprehensive analysis was performed, encompassing active clinical trials as of December 2024, sourced from ClinicalTrials.gov and TheranosticTrials.org. Preclinical developments were evaluated through a review of recent literature, focusing on innovations in radionuclide production, targeting molecules, and radiochemistry.

RESULTS

In reviewing the clinical landscape, agents targeting somatostatin receptors (SSTR) and prostate-specific membrane antigen (PSMA) still dominate the field, but new targets such as fibroblast activation protein (FAP), integrins, and gastrin-releasing peptide receptors (GRPR) are gaining traction in both clinical and preclinical development. While small molecules and peptides remain the most common radionuclide carriers, antibody-based carriers including bispecific antibodies, immunoglobin-derived antigen-binding fragments, and antibody-mimetic proteins are on the rise due to their specificity and adaptability. Innovations in radioligand design are driving a shift from agonists to antagonists, accompanied by the development of modified peptides with enhanced pharmacokinetics and tumor-targeting properties. Next-generation therapeutic radionuclides, such as the beta-emitter terbium-161 and alpha-emitters actinium-225 and lead-212, are under investigation to complement or replace lutetium-177, addressing the need for improved efficacy and reduced toxicity. Paired isotopic radionuclides are gaining popularity for their ability to optimize imaging and therapeutic dosimetry as they offer near-identical specificity, biodistribution, and metabolism. Additionally, radiohybrid systems represent an innovative approach to chelating chemically distinct radionuclide pairs within a single molecule, further enhancing flexibility in radiotheranostic design.

CONCLUSION

Radiotheranostics has transformed cancer care through its precision and adaptability, but challenges in radionuclide production, regulatory frameworks, and workforce training hinder broader adoption. Advances in isotopic pairing, next-generation radionuclides, and radiohybrid systems in preclinical and clinical settings hold promise to overcome these barriers. Collaborative efforts among academia, industry, and regulatory bodies are critical to accelerating innovation and optimizing clinical outcomes.

Visualization of the Spiral Ganglion Neuron in Vivo Using a Novel 177Lu Nuclear Molecule Label

For patients with severe and profound hearing loss, cochlear implant (CI), a common and effective modality for restoring hearing, directly stimulates spiral ganglion neurons (SGNs) to generate electrical activity and form auditory perception. However, the postoperative outcome of CI is significantly influenced by the number of surviving SGNs, ​​which is a key focus of preoperative evaluation​​. Existing audiologic function and radiographic tests cannot directly demonstrate the integrity of inner ear primary neurons. In this study, ​​we developed and validated​​ a radionuclide-labeled anti-vesicular glutamate transporter 1 (anti-VGLUT1) antibody-drug and achieved animal-level in vivo imaging of cochlear SGNs using nuclear imaging. By screening the public single-cell sequencing database, it is found that VGLUT1 can serve as a representative cell membrane marker for SGN in the cochlea. The potential of anti-VGLUT1 conjugated to the long half-life 177Lu as a molecular probe to detect the relative number of SGNs in SGN-injured mouse and pig models is explored. The study provides a novel method for assessing cochlear nerve integrity in vivo by visualizing target antigen expression levels through nuclear imaging. This approach is promising to help CI candidates with preoperative inner ear SGN integrity assessment, contributing to clinical decision-making.

Sensitizing solid tumors to CAR-mediated cytotoxicity by lipid nanoparticle delivery of synthetic antigens

Chimeric antigen receptor (CAR) T cell immunotherapy relies on CAR targeting of tumor-associated antigens; however, heterogenous antigen expression, interpatient variation and off-tumor expression by healthy cells remain barriers. Here we develop synthetic antigens to sensitize solid tumors for recognition and elimination by CAR T cells. Unlike tumor-associated antigens, we design synthetic antigens that are orthogonal to endogenous proteins to eliminate off-tumor targeting and that have a small genetic footprint to facilitate efficient tumor delivery to tumors by lipid nanoparticles. Using a camelid single-domain antibody (VHH) as a synthetic antigen, we show that adoptive transfer of anti-VHH CAR T cells to female mice bearing VHH-expressing tumors reduced tumor burden in multiple syngeneic and xenograft models of cancer, improved survival, induced epitope spread, protected against tumor rechallenge and mitigated antigen escape in heterogenous tumors. Our work supports the in situ delivery of synthetic antigens to treat antigen-low or antigen-negative tumors with CAR T cells.

Development of a novel anti-CEACAM5 VHH for SPECT imaging and potential cancer therapy applications

PURPOSE

In this study, we investigated the utility of a novel developed anti-CEACAM5 VHH for cancer diagnosis and its potential of being a targeting-moiety of VHH-drug conjugates for cancer therapy.

METHODS

Anti-CEACAM5 VHH (6B11) affinity and specific cellular binding was confirmed by ELISA, FACS and immunofluorescence in cancer cell lines with varying CEACAM5 expression levels. Intracellular penetration ability within tumor spheroids was tested with Oregon Green 488 labeled 6B11 (OG488-6B11). Biodistribution and binding specificity of 99mTc-radiolabeled 6B11 was tested in A549 CEACAM5 overexpressing (A549-CEA5-OV) and knockout (A549-CEA5-KO) tumor-bearing mice upon SPECT/CT imaging, γ-counting and autoradiography. The therapeutic efficacy of 6B11 and 6F8 (anti-CEACAM5 VHH with lower binding affinity) was tested by viability, wound healing and adhesion assays. To verify the potential of VHHs as a warhead for VHH-drug conjugation, an internalization assay with OG488 labeled VHH was performed.

RESULT

6B11 demonstrated high binding affinity (EC50 0.5nM) and cellular binding. OG488-6B11 penetrated tumor spheroids completely at 24 h, while a conventional antibody was only visible at the spheroid periphery. SPECT imaging indicated higher uptake (p < 0.05) in A549-CEA5-OV tumors, resulting in increased tumor-to-blood ratios especially at 4 (2.0016 ± 1.1893, p = 0.035) and 24 (2.9371 ± 2.0683, p = 0.003) hpi compared to A549-CEA5-KO tumors at 4 (0.5640 ± 0.3576) and 24 (0.8051 ± 0.4351) hpi. 99mTc-6B11 was predominantly renally cleared. Autoradiography and immunohistochemistry confirmed these uptake patterns. 6B11 nor 6F8 did exhibit significant anti-cancer therapeutic efficacy in vitro. OG488-6B11 was effectively internalized and accumulated in cells in a time-dependent manner, to end up in the lysosomes.

CONCLUSION

The anti-CEACAM5 VHH 6B11 is a good candidate for SPECT-based cancer diagnosis and can be potentially used as targeting moiety in the development of VHH-based drug conjugates for cancer treatments.

Research trends in the use of nanobodies for cancer therapy

Although there are many challenges in using nanobodies for treating various complex tumor diseases, including rapid renal clearance and the complex blood-brain barrier environment, nanobodies have shown great potential due to their high antigen affinity, excellent tumor penetration ability, and favorable safety profile. Since the discovery of the variable domain (VHH) of camelid heavy-chain antibodies in 1993, nanobodies have been progressively applied to various cancer therapy platforms, such as antagonistic drugs and targeting agents for effector domains. In recent years, several nanobody-based drugs, including Caplacizumab, KN-035, and Ozoralizumab, have been approved for clinical use. Among them, KN-035 is used for treating advanced solid tumors, and these advancements have propelled nanobody development to new heights. Currently, nanobodies are being rapidly applied to the treatment of a wide range of diseases, from viral infections to cancer, demonstrating strong advantages in areas such as targeted protein degradation, bioimaging, nanobody-drug conjugation, bispecific T-cell engagers, and vaccine applications. Bibliometric tools, including CiteSpace, HisCite Pro, and Alluvial Generator, were employed to trace the historical development of nanobodies in cancer research. The contributions of authors, countries, and institutions in this field were analyzed, and research hotspots and emerging trends were identified through keyword analysis and influential articles. Future trends were also predicted. This study provides a unique, comprehensive, and objective perspective on the use of nanobodies in tumor research, laying a foundation for future research directions and offering valuable insights for researchers in the field.

Synthesis and preclinical evaluation of an Al18F radio-fluorinated bivalent PD-L1 nanobody

Immunotherapy targeting the programmed death 1/programmed death ligand 1 (PD-1/PD-L1) pathway has achieved remarkable clinical success, but there is a shortage of effective approaches for screening suitable patients. Recently developed PD-L1 nanobody probes have limitations, including limited availability of radionuclides, short tumor retention times, and accumulation in non-target organs. To enhance tumor retention and improve tumor-to-normal tissue contrast, we herein report the synthesis and preclinical evaluation of two Al18F-labeled bivalent PD-L1 nanobody probes ([18F]TzTCO-BINb109 and [18F]RESCA-BINb109). Preliminary results indicated that [18F]TzTCO-BINb109 had a greater affinity for PD-L1 and better stability than [18F]RESCA-BINb109. Micro-PET/CT revealed that [18F]TzTCO-BINb109 uptake in A549-PDL1 tumors peaked at 240 min post-injection (3.19 ± 0.49 %ID/g) and demonstrated sustained retention without in vivo defluorination. In contrast, [18F]RESCA-BINb109 exhibited shorter tumor retention (at 60 and 240 min, 2.08 ± 0.22 and 1.37 ± 0.26 %ID/g, respectively) and significant defluorination in vivo. Ex vivo biodistribution studies revealed that the tumor uptake of [18F]TzTCO-BINb109 was consistent with the PET results, with the highest uptake by A549-PDL1 tumor cells (3.43 ± 0.94 %ID/g) compared with H1975 (0.93 ± 0.18 %ID/g) and A549 (0.68 ± 0.12 %ID/g) cells observed at 240 min post-injection. Compared with the previously reported monomeric PD-L1-targeting nanobody probe, [68Ga]NOTA-Nb109, [18F]TzTCO-BINb109 demonstrated enhanced tumor uptake, prolonged retention, and superior tumor-to-normal tissue contrast, contributing to higher imaging quality. These results confirmed that the bivalent PD-L1 nanobody radioligand, [18F]TzTCO-BINb109, was a promising diagnostic probe for PD-L1 detection, efficacy evaluation, and prescription optimization of immune checkpoint inhibitor therapies.

Trends in nanobody radiotheranostics

As the smallest antibody fragment with specific binding affinity, nanobody-based nuclear medicine has demonstrated significant potential to revolutionize the field of precision medicine, supported by burgeoning preclinical investigations and accumulating clinical evidence. However, the visualization of nanobodies has also exposed their suboptimal biodistribution patterns, which has spurred collaborative efforts to refine their pharmacokinetic and pharmacodynamic profiles for improved therapeutic efficacy. In this review, we present clinical results that exemplify the benefits of nanobody-based molecular imaging in cancer diagnosis. Moreover, we emphasize the indispensable role of molecular imaging as a tool for evaluating and optimizing nanobodies, thereby expanding their therapeutic potential in cancer treatment in the foreseeable future.

Pre-treatment metastatic biopsy: a step towards precision oncology for urothelial cancer

Early metastatic spread and clonal expansion of individual mutations result in a heterogeneous tumour landscape in metastatic urothelial cancer (mUC). Substantial molecular heterogeneity of common drug targets, such as membranous NECTIN4, FGFR3 mutations, PDL1 or immune phenotypes, has been documented between primary and metastatic tumours. However, translational and clinical studies frequently do not account for such heterogeneity and often investigate primary tumour samples that might not be representative in patients with mUC. We propose this as a potential factor for why many biomarkers for mUC have failed to be integrated into clinical practice. Fresh pre-treatment metastatic biopsies enable the capturing of prevailing tumour biology in real time. The characterization of metastatic tumour samples can improve response prediction to immunotherapy, the anti-NECTIN4 antibody-drug conjugate enfortumab vedotin and the FGFR inhibitor erdafitinib. Routine metastatic biopsy can thus improve the precision of identifying driver druggable alterations, thus improving treatment selection for patients with mUC.

Immuno-PET Imaging of a 68Ga-Labeled Single-Domain Antibody for Detecting Tumor TIGIT Expression

Preclinical studies have shown that the expression of T cell immunoglobulin and the immunoreceptor tyrosine-based inhibitory motif domain (TIGIT) in the tumor microenvironment is associated with the efficacy of anti-TIGIT-based immunotherapy. This study aimed to develop a TIGIT single-domain antibody (sdAb)-based positron emission tomography (PET) radiotracer, [68Ga]Ga-NOTA-NABT3A1, and evaluate its characteristics. The NABT3A1 was modified with a NOTA derivative and radiolabeled with 68Ga. In vitro stability of [68Ga]Ga-NOTA-NABT3A1 was assessed in phosphate-buffered saline (PBS) and fetal bovine serum (FBS), along with its specificity for TIGIT stably transfected A375 Human melanoma cells (A375-TIGIT) was performed. In vivo imaging was conducted on A375-TIGIT tumor-bearing nude mice at different time points after the injection of [68Ga]Ga-NOTA-NABT3A1. The synthesized [68Ga]Ga-NOTA-NABT3A1 achieved a radiochemical yield of 70.56 ± 1.14% and purity levels of 95.80 ± 0.58% in PBS and 96.79 ± 1.69% in FBS at 2 h. Immuno-PET imaging revealed specific accumulation of [68Ga]Ga-NOTA-NABT3A1 in A375-TIGIT tumor-bearing nude mice, with a maximum uptake of 3.86 ± 0.29% injected dose/g at 0.5 h. Biodistribution and immunohistochemical analyses confirmed the in vivo imaging results. In conclusion, we successfully synthesized an NABT3A1-derived PET radiotracer with the potential to noninvasively assess TIGIT expression in tumors.

Applications of Nanobodies in Biological Imaging

Background: Nanobodies (Nbs), derived from Camelidae heavy-chain antibodies, are single-domain fragments (15 kDa) with high antigen-binding specificity, enhanced tissue penetration, and low immunogenicity. These attributes address limitations of conventional antibodies, positioning Nbs as pivotal tools for targeted molecular imaging in diagnostics and therapeutics. Methods: Nbs are screened through phage/mRNA display or single B-cell sequencing, expressed in prokaryotic or yeast systems, and humanized via CDR grafting. Functional probes are engineered by conjugating Nbs with radionuclides (68Ga, 99mTc) or fluorophores (IRDye 800CW) for compatibility with PET, SPECT, NIRF, and ultrasound modalities. Results: Clinical trials validated Nb efficacy: 68Ga-HER2-Nb PET/CT achieved tumor-specific uptake in HER2+ cancers (NCT04467515), while 99mTc-PD-L1-Nb enabled quantitative SPECT-guided immunotherapy in NSCLC. NIRF-Nb conjugates (e.g., 11A4-800CW) enhanced intraoperative tumor delineation in murine models. Dual-targeted ultrasound microbubbles demonstrated multi-biomarker imaging via acoustic pressure modulation. Conclusion: Nbs advance biological imaging through superior resolution and rapid pharmacokinetics. Challenges persist in optimizing probe stability, minimizing immunogenicity, and scaling production. Future priorities include integrating multi-modal platforms, expanding applications to neurodegenerative disorders, and refining personalized diagnostic paradigms, underscoring their transformative potential in precision medicine.

Pure drug nanomedicines - where we are?

Pure drug nanomedicines (PDNs) encompass active pharmaceutical ingredients (APIs), including macromolecules, biological compounds, and functional components. They overcome research barriers and conversion thresholds associated with nanocarriers, offering advantages such as high drug loading capacity, synergistic treatment effects, and environmentally friendly production methods. This review provides a comprehensive overview of the latest advancements in PDNs, focusing on their essential components, design theories, and manufacturing techniques. The physicochemical properties and in vivo behaviors of PDNs are thoroughly analyzed to gain an in-depth understanding of their systematic characteristics. The review introduces currently approved PDN products and further explores the opportunities and challenges in expanding their depth and breadth of application. Drug nanocrystals, drug-drug cocrystals (DDCs), antibody-drug conjugates (ADCs), and nanobodies represent the successful commercialization and widespread utilization of PDNs across various disease domains. Self-assembled pure drug nanoparticles (SAPDNPs), a next-generation product, still require extensive translational research. Challenges persist in transitioning from laboratory-scale production to mass manufacturing and overcoming the conversion threshold from laboratory findings to clinical applications.

Nanobodies targeting the tumor microenvironment and their formulation as nanomedicines

Among the emerging strategies for cancer theranostics, nanomedicines offer significant promise in advancing both patients' diagnosis and treatment. In combination with nanobodies, nanomedicines can potentially enhance the precision and efficiency of drug or imaging agent delivery, addressing key limitations of current approaches, such as off-target toxicities. The development of nanomedicines will be further accelerated by the creation of smart nanoparticles, and their integration with immunotherapy. Obviously, the success of nano-immunotherapy will depend on a comprehensive understanding of the tumor microenvironment, including the complex interplay of mechanisms that drive cancer-mediated immunosuppression and immune escape. Hence, effective therapeutic targeting of the tumor microenvironment requires modulation of immune cell function, overcoming resistance mechanisms associated with stromal components or the extracellular matrix, and/or direct elimination of cancer cells. Identifying key molecules involved in cancer progression and drug resistance is, therefore, essential for developing effective therapies and diagnostic tools that can predict patient responses to treatment and monitor therapeutic outcomes. Current nanomedicines are being designed with careful consideration of factors such as the choice of carrier (e.g., biocompatibility, controlled cargo release) and targeting moiety. The unique properties of nanobodies make them an effective engineering tool to target biological molecules with high affinity and specificity. In this review, we focus on the latest applications of nanobodies for targeting various components of the tumor microenvironment for diagnostic and therapeutic purposes. We also explore the main types of nanoparticles used as a carrier for cancer immunotherapies, as well as the strategies for formulating nanoparticle-nanobody conjugates. Finally, we highlight how nanobody-nanoparticle formulations can enhance current nanomedicines.

Human dose-escalation study of PET imaging CD8+ T-cell infiltration in solid malignancies with [68Ga]Ga -NODAGA-SNA006

PURPOSE

A noninvasive method for evaluating the infiltration of CD8+ T cells in tumors is urgently needed to monitor the response to immunotherapy. This study investigated the performance of a [68Ga]Ga-NODAGA-SNA006 in positron emission tomography (PET) imaging of CD8+ T cells in patients with solid malignancies.

METHODS

This human dose-escalation PET imaging study involved eleven patients (lung cancer, 8; gastric carcinoma, 1; esophageal carcinoma, 2). Approximately 150 MBq of [68Ga]Ga-NODAGA-SNA006 with varying nanobody masses (100 µg, 300 µg, 500 µg, 800 µg) was administered, and PET/computed tomography (CT) scans were performed at 15-30, 60-90 and 120 min postinjection (p.i.). Data regarding biodistribution, pharmacokinetics and radiation dosimetry were evaluated. CD8+ T-cell infiltration in biopsy samples was also measured via immunohistochemistry (IHC) for correlation analysis with the tumor uptake of [68Ga]Ga-NODAGA-SNA006 PET.

RESULTS

[68Ga]Ga-NODAGA-SNA006 was well tolerated by all eleven subjects. The highest radioactive uptake was observed in the spleen, followed by the kidneys and bladder. Liver uptake decreased with increasing nanobody mass. Rapid clearance (t1/2<30 min) of [68Ga]Ga-NODAGA-SNA006 from whole blood and serum was observed. Furthermore, 68Ga uptake in tumors (SUVmean) exhibited a linear relationship with CD8+ T-cell infiltration in biopsy samples (R2 = 0.757, p = 0.011), suggesting that the tumor uptake of [68Ga]Ga-NODAGA-SNA006 may represent the degree of CD8+ T-cell infiltration in the tumor.

CONCLUSION

The use of [68Ga]Ga-NODAGA-SNA006 is safe, feasible, and well tolerated. [68Ga]Ga-NONAGA-SNA006 PET imaging can accurately detect CD8 expression inside tumors with favorable pharmacokinetics, thus providing a feasible method for noninvasive quantitative assessment of CD8+ T-cell tumor infiltration and monitoring the response to immunotherapy.

TRIAL REGISTRATION

NCT05126927 (19 November 2021, retrospectively registered).

Development and First-in-Human evaluation of a Site-Specific [18F]-Labeled PD-L1 nanobody PET radiotracer for noninvasive imaging in NSCLC

Immunohistochemistry (IHC) for PD-L1 detection is limited by its invasiveness and heterogeneity of tumors. To address these challenges, a new PD-L1-targeted nanobody-based immune-PET radiotracer [18F]AlF-APN09 was developed using the site-specific radiolabeling method with the complexing agent (Mal-RESCA) under mild conditions. [18F]AlF-APN09 was prepared at room temperature (pH 4.6-4.8) within 20 min with satisfactory radiochemical yields (45.8 ± 4.48 %, non-decay corrected), high radiochemical purity (>98 %) and moderate apparent molar activity (15-35 GBq/μmol), and remained stable in both PBS and 5 % HSA after 4 h (>90 %). Cell uptake studies indicated variable levels of surface PD-L1 expression in the following order: A549PD-L1 > H1975 > A549. In micro-PET/CT imaging, A549PD-L1 and H1975 tumors were distinctly visualized in a 6.0:1 and 3.2:1 ratios over PD-L1-negative A549 tumors in vivo. Ex vivo biodistribution studies showed tumor uptake values of 6.47 ± 1.06 %ID/g (A549PD-L1) and 2.27 ± 0.19 %ID/g (H1975), significantly higher than 0.90 ± 0.28 %ID/g in A549 tumors. The estimated effective radiation dose in humans was 8.65E-03 mSv/MBq, lower than that of conventional [18F]FDG. First-in-human imaging was conducted on a single resectable non-small cell lung cancer (NSCLC) subject without any adverse reactions. The radiotracer exhibited renal excretion with minimal hepatobiliary clearance. Tumor uptake reached SUVmax 4.20 at 2 h post-injection, demonstrating high contrast and rapid clearance. After PD-1 inhibitor immunotherapy and chemotherapy, the subject showed a therapeutic response and postoperative pathological specimens confirmed a major pathological response (MPR). These results suggest that we have successfully developed a new PD-L1-targeted nanobody PET tracer using the site-specific labeling method with the complexing agent (Mal-RESCA) within 20 min under mild conditions and [18F]AlF-APN09 is a promising noninvasive PET radiotracer for visualizing PD-L1 expression in tumors, offering rapid tumor targeting, excellent signal-to-noise ratios, and favorable clearance properties.

Dual-Functional Nanobody Optical Probes for In Vivo Fluorescence Imaging and Photodynamic Therapy

Nanobodies have gained significant attention as promising tools for cancer diagnostics and treatment due to their unique ability to precisely target specific cancer cells. However, a major challenge lies in the site-specific incorporation of multifunctional molecules into nanobodies, as it is essential to link these molecules in a manner that preserves the nanobody's function and stability while retaining the desired therapeutic or diagnostic properties. This study outlines the development of dual-functional nanobody optical probes for enhanced cancer diagnostics and therapeutic interventions. We designed a dual-functional clickable linker that enables site-specific functionalization of the nanobody, facilitating the simultaneous conjugation of two dyes: indocyanine green for imaging and chlorin e6 for photodynamic therapy. In vitro cellular assays confirmed the successful labeling of the dual-functional dyes, with the nanobody probe exhibiting high cellular binding specificity. In vivo imaging of mice bearing Hep3B tumors revealed clear visualization with a high signal-to-noise ratio. Furthermore, PEGylated probes significantly improved tumor retention, enhancing both imaging contrast and photodynamic therapy efficacy as compared to free chlorin e6. These dual-functional nanobody probes show great promise for the precise diagnosis and treatment of malignant tumors.

Development and evaluation of Hsp90-targeting nanobodies for visualisation of extracellular Hsp90 in tumours using PET imaging

BACKGROUND

The extracellular localisation of the Heat shock protein 90 (Hsp90) is associated with the diseased state and wound healing and presents a promising opportunity for cancer targeting using Positron Emission Tomography (PET) imaging and molecularly targeted radiotherapy. The aim of this work is to develop a radiotracer with low nanomolar binding affinity to target the extracellular and particularly membrane pool of Hsp90, evaluate it in vitro, and conduct preliminary PET studies in vivo in mouse tumour models. Variable Heavy domain of Heavy chain antibodies, often referred to as Nanobodies, are suitable targeting vectors for the extracellular targets due to their favourable pharmacokinetic properties and low nanomolar target affinities. The main objective of the study is to target tumours expressing extracellular and membrane Hsp90 phenotype with minimal tracer accumulation in the non-target organs, which limited the translation of previously studied small molecule cytosolic Hsp90 tracers suffering from high non-Hsp90 specific background in the abdominal area.

RESULTS

Six nanobodies were obtained after llama immunization with recombinant Hsp90α and ELISA biopanning, produced in E. coli and screened for stability and affinity. We selected one nanobody, 4DAM26, with good thermal stability, no aggregation at elevated temperatures, and low nanomolar affinity towards Hsp90α and Hsp90β isoforms for translation as a PET radiotracer. The nanobody was bioconjugated to p-NCS-NODAGA and radiolabeled with gallium-68 with 75 ± 11% radiochemical yield and > 99% radiochemical purity and remained stable up to 3 h in phosphate buffered saline and mouse serum. Pilot in vivo evaluation using µPET/CT and ex vivo biodistribution demonstrated a favourable pharmacokinetic profile, but the tumour uptake was non-distinguishable from the background tissue.

CONCLUSION

Compared to the small molecule Hsp90 tracers, the studied Nb-based tracer has improved pharmacokinetics properties including renal clearance and almost no accumulation in the non-target organs. Tumour uptake, on the other hand, was minimal and could not be differentiated from the background in µPET/CT. Our experiments indicate that in the studied models, membrane and extracellular expression of Hsp90 is majorly an artifact of cellular death, as only dead/dying cells had accessible pools of Hsp90 by flow cytometry, a consequence of a leaky membrane. More fundamental research is required to reassess the role of extracellular Hsp90 in cancer, and our future efforts will be focused on improving our inventory of cytosolic Hsp90 tracers with proven Hsp90-specific tumour accumulation.

Approaches to Radiolabeling Nanobodies for Biomedical Applications

Molecular imaging plays a vital role in diagnosing diseases, monitoring treatments, and evaluating therapeutic efficacy by enabling noninvasive visualization of biological processes. Nanobodies, single-domain antibodies derived from camelids, have emerged as promising candidates for a wide range of biomedical applications due to their unique properties, including small size, high affinity, rapid clearance, and deep-tissue penetration. While effective radiolabeling techniques remain a major challenge to fully realize their clinical potential, this review aims to present recent advances in nanobody radiolabeling, focusing on radionuclides like 64Cu, 68Ga, 89Zr, and 111In, along with their associated chelators and conjugation methods. We highlight the development of innovative chelators, including p-SCN-Bn-HOPO and desferrioxamine derivatives that enhance specificity and stability, as well as advances in conjugation techniques that influence biodistribution and pharmacokinetics. These findings highlight the essential role of nanobody-based molecular imaging for precise diagnostics and targeted therapy.

A Highly Sensitive Immunoassay to Enable Quantification of a Nanobody-Based Imaging Agent in Human Serum

Immuno-positron emission tomography (i-PET) is a non-invasive imaging technique that combines the specificity of monoclonal antibodies with the sensitivity of positron emission tomography to visualize and quantify the distribution of target antigens in vivo, providing detailed spatial information about the presence and localization of specific biomarkers. Due to the crucial role that cytotoxic T cells play in antitumor responses, a new tracer consisting of a humanized anti-CD8 nanobody labeled with fluorine-18 was developed to inform immuno-oncology treatments and support medical decision-making. Nanobodies are single-domain antibodies with low molecular weight and fast peripheral blood clearance, both of which are advantageous properties for same-day imaging. However, these unique characteristics pose bioanalytical challenges when developing clinical pharmacokinetic (PK) assays, including the need for high assay sensitivity. This manuscript focuses on overcoming bioanalytical challenges related to sensitivity and matrix interference during the development of a method to quantify this novel anti-CD8 nanobody tracer in human serum. Out of the three immunoassay platforms evaluated (ELISA, SMCxPRO™ and Gyrolab®), a Gyrolab method was ultimately selected due to its superior sensitivity, equal detectability of both conjugated and unconjugated forms of the nanobody and its ability to minimize matrix interference. By selecting the right assay format, along with the appropriate critical reagents for capture and detection, matrix interference was diminished. This novel PK method was successfully qualified demonstrating acceptable performance across all parameters. The acquired bioanalytical insights gained could be applied to nanobody-derived conjugates or other modalities that require high sensitivity in the clinical settings.

Engineered Nanobodies Bind Bismuth, Indium and Gallium for Applications in Theranostics

Targeted theranostics heavily rely on metal isotopes conjugated to antibodies. Single-domain antibodies, known as nanobodies, are much smaller in size without compromising specificity and affinity. The conventional way of conjugating metals to nanobodies involves non-specific modification of amino acid residues with bifunctional chelating agents. We demonstrate that mutagenesis of a single residue in a nanobody creates a triple cysteine motif that selectively binds bismuth which is, for example, used in targeted alpha therapy. Two mutations create a quadruple cysteine mutant specific for gallium and indium used in positron emission tomography and single-photon emission computed tomography, respectively. Labelling is quantitative within a few minutes. The metal nanobodies maintain structural integrity and stability over weeks, resist competition from endogenous metal binders like glutathione, and retain functionality.

Polymeric nanoparticles in radiopharmaceutical delivery strategies

The potential applications of polymer nanoparticles (NPs) in the biomedical field have been the subject of extensive research. Radiopharmaceuticals that combine radionuclides and drugs using polymer nanoparticles (NPs) as carriers can be externally labelled, internally labelled or interfacially labelled with radionuclides at different sites. Consequently, they can be employed as delivery agents for a range of diseases. Currently, polymeric nanoparticles can deliver isotopes via active targeting, passive targeting and stimuli-responsive release systems. The objective is to deliver drugs and nuclides to the target site in an efficient manner, thereby maximizing efficacy and minimizing side effects. The development of drug release systems has the potential to address the growing social and economic challenges currently facing modern healthcare. This paper presents a detailed synthesis of the methods used to create polymer nanoparticles (NPs) and strategies for the targeted delivery of radiopharmaceuticals with radionuclides labelled at different locations. Additionally, the paper outlines the current progress of polymer NPs for use in imaging and therapeutic applications, as well as the future challenges that lie ahead in this field.

Impact of HER2-targeted PET/CT imaging in patients with breast cancer and therapeutic response monitoring

BACKGROUND

Patients with breast cancer exhibit heterogeneity in the expression of the human epithelial growth factor receptor 2 (HER2). Clinically, re-biopsying recurrent or metastatic lesions presents substantial challenges. This study aimed to evaluate the efficacy of HER2-targeted PET/CT imaging in identifying HER2 expression in breast cancer lesions and monitoring therapeutic responses.

PATIENTS AND METHODS

This exploratory analysis used data from a prospective study that included adult patients with breast cancer who underwent both Al18F-NOTA-HER2-BCH and 18F-FDG PET/CT imaging at Beijing Cancer Hospital between June 2020 and July 2023 (NCT04547309).

RESULTS

Fifty-nine participants, with a median age of 55 years, were analyzed. Lesions imaged with HER2-targeted PET/CT before anti-HER2 therapy exhibited higher SUVmax values than after therapy in HER2 immunohistochemistry (IHC) 3 + lesions (19.9, 95% CI: 15.7-25.3 vs 9.8, 95% CI: 5.6-14.7; P = .006). A significant positive correlation was observed between SUVmax on HER2-targeted PET/CT and IHC before therapy (P = .034), with higher SUVmax values noted in lesions with positive HER2 pathology compared to those with negative HER2 status (17.9 ± 13.2 vs 1.1 ± 0.3; P = .007). HER2 expression heterogeneity was confirmed both between primary and metastatic lesions (22.9%) and among different metastatic sites (26.7%) as assessed by HER2-targeted PET/CT. A superior therapeutic response correlated with higher pretreatment SUVmax values. The HER2-targeted PET/CT procedure was well-tolerated by all patients.

CONCLUSION

HER2-targeted PET/CT imaging offers a practical, non-invasive, and quantitative approach for assessing HER2 status in breast cancer patients, facilitating the optimization and personalization of therapeutic strategies by oncologists.

Framework Nucleic Acid-Nanobody Fusion Probe-Based Pharmacokinetics Modulation and Analysis for Efficient Positron Emission Tomography Imaging

Nanobodies are promising for immunoPET imaging due to their excellent antigen recognition and tumor targeting, yet rapid clearance limits their tumor accumulation. Although multimerization and albumin binding can extend their circulation time and improve tumor targeting, a simple and universal method for creating protein multimers is still needed. Here, we leveraged the facile synthesis, controllable size, and precise assembly of DNA nanotechnology to construct CD47-targeted framework nucleic acid-nanobody fusion probes with multiple valences and sizes. Following comprehensive structural characterization, in vitro specificity assessment and in vivo PET/CT imaging analysis were conducted on a colorectal cancer LS174T mouse model. Furthermore, a pharmacokinetic model was developed and fitted with considerable in vivo data to prove its rationality, followed by testing the effects on tumor uptake prediction by changing different pharmacokinetic parameters. Indeed, by manipulating the size of the nucleic acid scaffolding and the number of attached nanobodies, we could precisely modulate the accumulation of probes at the tumor site. Overall, this study not only developed an efficient strategy for constructing nanobody multimers but also provided a pharmacokinetic model, allowing profound insight into the multidimensional data obtained experimentally and informing the design of future imaging probes with predictable delivery efficacies.

A phase Ia study of a novel anti-HER2 antibody-drug conjugate GQ1001 in patients with previously treated HER2 positive advanced solid tumors

BACKGROUND

A novel anti-human epidermal growth factor receptor 2 (HER2) antibody-drug conjugate (ADC) GQ1001 was assessed in patients with previously treated HER2 positive advanced solid tumors in a global multi-center phase Ia dose escalation trial.

METHODS

In this phase Ia trial, a modified 3 + 3 study design was adopted during dose escalation phase. Eligible patients were enrolled, and GQ1001 monotherapy was administered intravenously every 3 weeks. The starting dose was 1.2 mg/kg, followed by 2.4, 3.6, 4.8, 6.0, 7.2 and 8.4 mg/kg. Extra patients were enrolled into 6.0, 7.2, and 8.4 mg/kg cohorts as dose expansion phase. The primary endpoints were safety and to determine the maximum tolerated dose (MTD) based on dose limiting toxicities (DLTs). Pharmacokinetics and anti-tumor efficacy of GQ1001 were assessed. The plasma concentration of free DM1, the payload of GQ1001, was quantitated.

RESULTS

A total of 32 patients were enrolled, predominantly in breast (9), gastric or gastro-esophageal junction (9) and salivary gland cancer (4). Median number of prior-line of therapies was 3 (0-11) and 37.5% patients received ≥ 2 lines of anti-HER2 therapies. No DLT was observed during dose escalation. MTD was not reached and dose recommended for dose expansion (DRDE) was determined as 8.4 mg/kg. Grade ≥ 3 treatment-related adverse events rate was 28.1% (9/32) and platelet count decreased (4/32, 12.5%) was the most common one. No drug-related death was observed. Objective response rate and disease control rate of 15 evaluable patients in 7.2 mg/kg and 8.4 mg/kg cohorts were 40.0% (6/15) and 60.0% (9/15). Pharmacokinetics analysis showed low exposure and accumulation of free DM1 in circulation.

CONCLUSION

GQ1001 is well tolerated and shows promising efficacy in previously treated HER2-positive advanced solid tumors. DRDE was determined as 8.4 mg/kg for following trials. Trial registration NCT, NCT04450732, Registered 23 June 2020, https://clinicaltrials.gov/study/NCT04450732.

Comparative Kidney Uptake of Nanobody-Based PET Tracers Labeled with Various Fluorine-18-Labeled Prosthetic Groups

Nanobodies, or single-domain antibody fragments, are promising candidates for molecular imaging due to their small size, rapid tissue penetration, and high target specificity. However, a significant challenge in their use is high renal uptake and retention, which can limit the therapeutic efficacy and complicate image interpretation. This study compares five different fluorine-18-labeled prosthetic groups for nanobodies, aiming to optimize pharmacokinetics and minimize kidney retention while maintaining tumor targeting. Using an epidermal growth factor receptor (EGFR) targeting nanobody as a model, two labeling approaches were evaluated; direct labeling of RESCA (with and without polyethylene glycol (PEG))-conjugated nanobody using Al[18F]F and indirect labeling using ([18F]F-fluoropyridine ([18F]F-FPy)-based prosthetic groups (site-specific and nonsite-specific). Labeled nanobodies were characterized in vitro for binding affinity and cell uptake with in vivo behavior assessed in EGFR + A431 tumor-bearing mice using PET imaging and biodistribution studies. Labeling with Al[18F]F showed high renal retention, which was partially mitigated by PEGylation. However, PEGylation also led to a decreased tumor uptake, particularly with longer PEG chains. Labeling using [18F]F-FPy prosthetic groups exhibited the most favorable pharmacokinetics, with rapid renal clearance and minimal kidney retention while maintaining high tumor uptake. These constructs showed excellent tumor-to-background contrast as early as 1 h postinjection. The study confirms that the selection of the prosthetic group significantly impacts the in vivo behavior of nanobodies, particularly regarding kidney accumulation. [18F]F-FPy-based prosthetic groups show the most promising results, with high tumor and minimal kidney uptake. Robust production of [18F]F-FPy on Sep-Pak is adaptable to clinical translation. Moreover, the potential substitution of 18F with therapeutic radioisotopes such as 131I or 211At could expand the application of these nanobodies from diagnostics to targeted radionuclide therapy while maintaining a low kidney exposure. These findings have important implications for optimizing nanobody-based radiopharmaceuticals for molecular imaging and targeted radionuclide therapy.

Radiopharmaceuticals and their applications in medicine

Radiopharmaceuticals involve the local delivery of radionuclides to targeted lesions for the diagnosis and treatment of multiple diseases. Radiopharmaceutical therapy, which directly causes systematic and irreparable damage to targeted cells, has attracted increasing attention in the treatment of refractory diseases that are not sensitive to current therapies. As the Food and Drug Administration (FDA) approvals of [177Lu]Lu-DOTA-TATE, [177Lu]Lu-PSMA-617 and their complementary diagnostic agents, namely, [68Ga]Ga-DOTA-TATE and [68Ga]Ga-PSMA-11, targeted radiopharmaceutical-based theranostics (radiotheranostics) are being increasingly implemented in clinical practice in oncology, which lead to a new era of radiopharmaceuticals. The new generation of radiopharmaceuticals utilizes a targeting vector to achieve the accurate delivery of radionuclides to lesions and avoid off-target deposition, making it possible to improve the efficiency and biosafety of tumour diagnosis and therapy. Numerous studies have focused on developing novel radiopharmaceuticals targeting a broader range of disease targets, demonstrating remarkable in vivo performance. These include high tumor uptake, prolonged retention time, and favorable pharmacokinetic properties that align with clinical standards. While radiotheranostics have been widely applied in tumor diagnosis and therapy, their applications are now expanding to neurodegenerative diseases, cardiovascular diseases, and inflammation. Furthermore, radiotheranostic-empowered precision medicine is revolutionizing the cancer treatment paradigm. Diagnostic radiopharmaceuticals play a pivotal role in patient stratification and treatment planning, leading to improved therapeutic outcomes in targeted radionuclide therapy. This review offers a comprehensive overview of the evolution of radiopharmaceuticals, including both FDA-approved and clinically investigated agents, and explores the mechanisms of cell death induced by radiopharmaceuticals. It emphasizes the significance and future prospects of theranostic-based radiopharmaceuticals in advancing precision medicine.

Preclinical evaluation and pilot clinical study of [68Ga]Ga-NOTA-H006 for non-invasive PET imaging of 5T4 oncofetal antigen

PURPOSE

Trophoblast glycoprotein, the so-called 5T4, is an oncofetal antigen expressed in many different cancers. However, no 5T4-specific radioligand is employed in the clinic for non-invasive diagnosis. Thus, the aim of the current study was to develop a PET radiotracer for imaging 5T4 expression in preclinical and clinical stages.

METHODS

A VHH library was constructed by camel immunization. The specificity of the VHHs toward 5T4 antigen was screened through phage display biopanning and periplasmic extract enzyme-linked immunosorbent assay. 1,4,7-Triazacyclononane-1,4,7-triacetate acid (NOTA) derivative was conjugated to the selected VHH. After radiolabeling, microPET/CT and ex vivo biodistribution were conducted using BxPC-3 and MDA-MB-468 tumor-bearing mice. Cold VHH was co-injected with the tracer to challenge its binding in vivo. For the pilot clinical study, PET/CT images were acquired at 1 h after injection of tracer in patients with pathologically confirmed primary and metastatic tumors.

RESULTS

A library with a capacity of 1.2 × 1012 colony-forming units was constructed after successful camel immunization. Nb1-40 with a median effect concentration of 0.43 nM was selected. After humanization, the resulting H006 maintained a high affinity towards 5T4. [68Ga]Ga-NOTA-H006 with the molar activities of 6.48-54.2 GBq/µmol was prepared with high radiochemical purity (> 98%). Using [68Ga]Ga-NOTA-H006, microPET/CT revealed a clear visualization of 5T4 expression in BxPC-3 tumor-bearing mice. Ex vivo biodistribution showed that the highest tumor-to-blood ratio (∼ 3-fold) and tumor-to-muscle ratio (∼ 5-fold) were achieved at 60 min post-injection. Co-injection of the cold H006 at a dose of 1.5 mg/kg significantly reduced the tumor uptake (p < 0.0001). In the pilot clinical study, [68Ga]Ga-NOTA-H006 demonstrated its capacity to map 5T4-positive lesions in humans and yielded a mean effective dose of 3.4 × 10- 2 mSv/MBq.

CONCLUSIONS

[68Ga]Ga-NOTA-H006, which can visualize 5T4 expression in vivo, has been successfully developed. This opens up opportunities for non-invasively studying 5T4 expression through nuclear medicine. Further clinical investigations are warranted to explore its clinical value in disease progression and companion diagnosis.

Imaging of tumor-associated macrophage dynamics during immunotherapy using a CD163-specific nanobody-based immunotracer

Immunotherapies have emerged as an effective treatment option for immune-related diseases, such as cancer and inflammatory diseases. However, variations in patient responsiveness limit the broad applicability and success of these immunotherapies. Noninvasive whole-body imaging of the immune status of individual patients during immunotherapy could enable the prediction and monitoring of the patient's response, resulting in more personalized treatments. In this study, we developed a nanobody-based immunotracer targeting CD163, a receptor specifically expressed on macrophages. This anti-CD163 immunotracer bound to human and mouse CD163 with high affinity and specificity without competing for ligand binding. Furthermore, the tracer showed no unwanted immune cell activation and was nonimmunogenic. Upon radiolabeling of the anti-CD163 immunotracer, specific imaging of CD163+ macrophages using micro-single-photon emission computerized tomography/computed tomography or micro-positron emission tomography/CT was performed. The anti-CD163 immunotracer was able to stratify immunotherapy responders from nonresponders (NR) by visualizing differences in the intratumoral CD163+ TAM distribution in Lewis lung carcinoma-ovalbumin tumor-bearing mice receiving an anti-programmed cell death protein-1 (PD-1)/CSF1R combination treatment. Immunotherapy-responding mice showed a more homogeneous distribution of the PET signal in the middle of the tumor, while CD163+ TAMs were located at the tumor periphery in NR. As such, visualization of CD163+ TAM distribution in the tumor microenvironment could allow a prediction or follow-up of therapy response. Altogether, this study describes an immunotracer, specific for CD163+ macrophages, that allows same-day imaging and follow-up of these immune cells in the tumor microenvironment, providing a good basis for the prediction and follow-up of immunotherapy responses in cancer patients.

Novel Molecular Classification of Breast Cancer with PET Imaging

Breast cancer is a heterogeneous disease characterized by a wide range of biomarker expressions, resulting in varied progression, behavior, and prognosis. While traditional biopsy-based molecular classification is the gold standard, it is invasive and limited in capturing tumor heterogeneity, especially in deep or metastatic lesions. Molecular imaging, particularly positron emission tomography (PET) imaging, offering a non-invasive alternative, potentially plays a crucial role in the classification and management of breast cancer by providing detailed information about tumor location, heterogeneity, and progression. This narrative review, which focuses on both clinical patients and preclinical studies, explores the latest advancements in PET imaging for breast cancer, emphasizing the development of new tracers targeting hormone receptors such as the estrogen alpha receptor, progesterone receptor, androgen receptor, estrogen beta receptor, as well as the ErbB family of receptors, VEGF/VEGFR, PARP1, PD-L1, and markers for indirectly assessing Ki-67. These innovative radiopharmaceuticals have the potential to guide personalized treatment approaches based on the unique tumor profiles of individual patients. Additionally, they may improve the assessment of treatment efficacy, ultimately leading to better outcomes for those diagnosed with breast cancer.

Development and evaluation of a single domain antibody targeting folate receptor alpha for radioligand therapy

BACKGROUND

Folate receptor alpha (FRα) overexpression is seen in many cancers. Radioligand therapy (RLT) has emerged as a promising tool to target FRα and has been investigated previously, but further progression was limited due to high kidney retention and, subsequently, toxicity. To circumvent this, we present here the development of a [131I]I-GMIB-conjugated anti-human FRα (hFRα) single-domain antibody (sdAb), with intrinsically fast renal clearance and concomitant low kidney retention. We report the hit-to-lead development of an anti-hFRα sdAb. We evaluated its potential in vitro and assessed its targeting ability using SPECT imaging in hFRα-knockin and tumour-bearing mice. The toxicity and therapeutic efficacy of the [131I]I-GMIB-sdAb were investigated in mouse models.

RESULTS

The lead anti-hFRα sdAb 2BD42 was developed with picomolar affinities, low koff, and radiolabelled using [131I]I with yields of > 41% and purity > 99%. [131I]I-GMIB-2BD42 retained tumour uptake (> 5%IA/g at 1 h p.i. and > 1.5%IA/g at 24 h p.i.) and fast kidney clearance (< 1%IA/g at 24 h p.i.) in athymic and hFRα-knock-in mice. Athymic mice bearing hFRα-positive xenografts treated with [131I]I-GMIB-2BD42 showed prolonged survival without toxicity compared to animals that received the vehicle solution or radioactive control.

CONCLUSION

The therapeutic lead radiopharmaceutical [131I]I-GMIB-2BD42 showed fast pharmacokinetics with specific retention in hFRα + tumours. In addition, we report therapeutic efficacy with no signs of toxicity. In this study, we successfully designed a new drug for RLT, overcoming previous limitations, such as high kidney retention, which could aid in revitalising FRα-targeted radiotherapy.

[64Cu]Cu-NOTA-Trastuzumab and [89Zr]Zr-DFO-Trastuzumab in Xenografts with Varied HER2 Expression

Positron emission tomography (PET) has potential as a complementary technique to biomarker analysis, especially for human epidermal growth factor receptor 2 (HER2)-expressing tumors characterized by high heterogeneity. In this study, zirconium-89 (89Zr) and copper-64 (64Cu) labeled trastuzumab were employed to monitor varying levels of tumoral HER2 expression. Additionally, we studied the use of the cholesterol-depleting lovastatin as a pharmacological approach to enhance cell-surface HER2 expression in tumors with moderate to low HER2 levels, aiming to increase antibody accumulation in these tumor types. Both 89Zr- and 64Cu-labeled trastuzumab effectively monitor HER2 expression levels in xenografts exhibiting varying HER2 expression. No significant difference in tumor uptake was observed between 89Zr- or 64Cu-labeled trastuzumab, and tumor uptake for both radioimmunoconjugates positively correlated with HER2 protein levels. These findings underscore the potential of PET to monitor HER2 protein levels across heterogeneous tumors. Furthermore, our results suggest that further optimization of statin dosing and timing could offer a promising strategy to enhance trastuzumab accumulation in HER2-high, HER2-moderate, and HER2-low tumors.

Comparative analysis of positron emitters for theranostic applications based on small bioconjugates highlighting 43Sc, 61Cu and 45Ti

BACKGROUND

Targeted radionuclide therapy with 177Lu-labelled small conjugates is expanding rapidly, and its success is linked to appropriate patient selection. Companion diagnostic conjugates are usually labelled with 68Ga, offering good imaging up to ≈2 h post-injection. However, the optimal tumor-to-background ratio is often reached later. This study examined promising positron-emitting radiometals with half-lives between 3 h and 24 h and β+ intensity (Iβ+) ≥ 15% and compared them to 68Ga. The radiometals included: 43Sc, 44Sc, 45Ti, 55Co, 61Cu, 64Cu, 66Ga, 85mY, 86Y, 90Nb, 132La, 150Tb and 152Tb. 133La (7.2% Iβ+) was also examined because it was recently discussed, in combination with 132La, as a possible diagnostic match for 225Ac.

METHODS

Total electron and photon doses per decay and per positron; possibly interfering γ-ray emissions; typical activities to be injected for same-day imaging; positron range; and available production routes were examined.

RESULTS

For each annihilation process useful for PET imaging, the total energy released (MeV) is: 45Ti (1.5), 43Sc (1.6), 61Cu and 64Cu (1.8), 68Ga (1.9), 44Sc and 133La (2.9), 55Co (3.2), 85mY (3.3), 132La (4.8), 152Tb (6.5), 150Tb (7.1), 90Nb (8.6), and 86Y (13.6). Significant amounts (≥ 10%) of ≈0.5 MeV photons that may fall into the acceptance window of PET scanners are emitted by 55Co, 66Ga, 85mY, 86Y, 132La, and 152Tb. Compton background from more energetic photons would be expected for 44Sc, 55Co, 66Ga, 86Y, 90Nb, 132La,150Tb, and 152Tb. The mean positron ranges (mm) of 64Cu (0.6), 85mY (1.0), 45Ti (1.5), 133La (1.6), 43Sc and 61Cu (1.7), 55Co (2.1), 44Sc and 86Y (2.5), and 90Nb (2.6) were lower than that of 68Ga (3.6). DOTA chelation is applicable for most of the radiometals, though not ideal for 61Cu/64Cu. Recent data showed that chelation of 45Ti with DOTA is feasible. 90Nb requires different complexing agents (e.g., DFO). Finally, they could be economically produced by proton-induced reactions at medical cyclotrons.

CONCLUSION

In particular, 43Sc, 45Ti, and 61Cu have overall excellent β+ decay-characteristics for theranostic applications complementing 177Lu-labelled small conjugates, and they could be sustainably produced. Like Lu, 43Sc, 45Ti and to a lesser extent 61Cu could be labelled with DOTA.

Automated radiofluorination of HER2 single domain antibody: the road towards the clinical translation of [18F]FB-HER2 sdAb

BACKGROUND

With the next generation of Human Epidermal Growth Factor Receptor 2 (HER2) -targeting therapies, such as antibody-drug conjugates, showing benefit in "HER2 low" and even "HER2 ultralow" patients, the need for novel methods to quantify HER2 expression accurately becomes even more important for clinical decision making. A HER2 PET/CT imaging assessment could evaluate HER2 positive disease locations while improving patient care, reducing the need for invasive biopsies. A single-domain antibody (sdAb)-based PET tracer could combine the high specificity of sdAbs with short-lived radionuclides such as fluorine-18 (18F) and gallium-68 (68Ga). SdAb-based PET tracers have clinically been used via a 68Ga-chelator approach. However, the distribution of 68Ga-labelled pharmaceuticals to peripheral PET centres is more challenging to organize due to the short half-life of 68Ga, most certainly when the available activity is limited by a generator. Cyclotron produced 68Ga has removed this limitation. Distribution of 18F-labelled pharmaceuticals remains less challenging due to its slightly longer half-life, and radiofluorination of sdAbs via N-succinimidyl-4-[18F]fluorobenzoate ([18F]SFB) has shown to be a promising strategy for developing sdAb-based PET tracers. Although [18F]SFB automation has been reported, automating protein conjugation proves challenging. Herein we report the fully automated, cartridge-based production of [18F]FB-HER2 sdAb on a single synthesis module.

RESULTS

[18F]FB-HER2 sdAb (> 6 GBq) was obtained after a fully automated production (95 min), with a RCP > 95%, apparent molar activity > 20 GBq/µmol and decay-corrected radiochemical yield (RCY d.c.) of 14 ± 2% (n = 4). Further upscaling amounted to production batches of 16 GBq with an apparent molar activity > 40 GBq/µmol and RCY d.c. of 8 ± 1% (n = 4). Ex vivo biodistribution and PET imaging showed specific HER2-positive tumour targeting and low kidney retention.

CONCLUSION

The [18F]FB-HER2 sdAb tracer was produced with clinically relevant activities using a fully automated production method. The automated production method was designed to ease the translation to the clinic and has the potential to be used not only in mono-centre but also multi-centre clinical trials with one central production site. [18F]FB-HER2 sdAb showed a favourable biodistribution pattern and could be a valuable alternative to 68Ga-labelled sdAb-based PET tracers in the clinic.

Molecular imaging of renal cell carcinomas: ready for prime time

The clinical diagnosis of renal cell carcinoma (RCC) is constantly evolving. Diagnostic imaging of RCC relying on enhanced computed tomography (CT) and magnetic resonance imaging (MRI) is commonly used for renal mass characterization and assessment of tumour thrombosis, whereas pathology is the gold standard for establishing diagnosis. However, molecular imaging is rapidly improving the clinical management of RCC, particularly clear-cell RCC. Molecular imaging aids in the non-invasive visualization and characterization of specific biomarkers such as carbonic anhydrase IX and CD70 within the tumours, which help to assess tumour heterogeneity and status. Target-specific molecular imaging of RCCs will substantially improve the diagnostic landscape of RCC and will further facilitate clinical decision-making regarding initial staging and re-staging, monitoring of recurrence and metastasis, patient stratification and selection, and the prediction and evaluation of treatment responses.

Unlocking the Gates: Therapeutic Agents for Noninvasive Drug Delivery Across the Blood-Brain Barrier

The blood-brain barrier (BBB) is a highly selective network of various cell types that acts as a filter between the blood and the brain parenchyma. Because of this, the BBB remains a major obstacle for drug delivery to the central nervous system (CNS). In recent years, there has been a focus on developing various modifiable platforms, such as monoclonal antibodies (mAbs), nanobodies (Nbs), peptides, and nanoparticles, as both therapeutic agents and carriers for targeted drug delivery to treat brain cancers and diseases. Methods for bypassing the BBB can be invasive or noninvasive. Invasive techniques, such as transient disruption of the BBB using low pulse electrical fields and intracerebroventricular infusion, lack specificity and have numerous safety concerns. In this review, we will focus on noninvasive transport mechanisms that offer high levels of biocompatibility, personalization, specificity and are regarded as generally safer than their invasive counterparts. Modifiable platforms can be designed to noninvasively traverse the BBB through one or more of the following pathways: passive diffusion through a physio-pathologically disrupted BBB, adsorptive-mediated transcytosis, receptor-mediated transcytosis, shuttle-mediated transcytosis, and somatic gene transfer. Through understanding the noninvasive pathways, new applications, including Chimeric Antigen Receptors T-cell (CAR-T) therapy, and approaches for drug delivery across the BBB are emerging.

Preclinical research progress in HER2-targeted small-molecule probes for breast cancer

Breast cancer is a malignant tumor that has the highest morbidity and mortality in women worldwide. Human epidermal growth factor receptor 2 (HER2) is a key driver of breast cancer development. Therefore, accurate assessment of HER2 expression in cancer patients and timely initiation or termination of anti-HER2 treatment are crucial for the prognosis of breast cancer patients. The emergence of radiolabeled molecular probes targeting HER2 makes this assessment possible. This article describes different types of small-molecule probes that target HER2 and are used in current preclinical applications and summarizes their advantages and disadvantages.

Diagnostic Performance of MRI and FDG PET/CT for Preoperative Locoregional Staging of Colon Cancer: Systematic Review and Meta-Analysis

BACKGROUND. CT is the standard-of-care test for preoperative locoregional staging of colon cancer (CC) but has limited diagnostic performance. More accurate preoperative staging would guide selection among expanding patient-tailored treatment options. OBJECTIVE. The purpose of this study was to evaluate through systematic review the diagnostic performance of MRI for T and N staging and that of FDG PET/CT for N staging in the locoregional staging of CC. EVIDENCE ACQUISITION. PubMed, Embase, and the Cochrane Library were searched through December 31, 2023, for studies reporting the diagnostic performance of MRI or FDG PET/CT for primary (nonrectal) CC before resection without neoadjuvant therapy, with histopathology used as the reference standard. Study quality was assessed using the QUADAS-2 tool. Publication bias was assessed using the Deeks funnel plot asymmetry test. Primary outcomes were estimated pooled predictive values, which were stratified by T and N categories for MRI and by N categories for PET/CT. Secondary outcomes were pooled sensitivity and specificity. EVIDENCE SYNTHESIS. The systematic review included 11 MRI studies (686 patients) and five PET/CT studies (408 patients). Thirteen studies had at least one risk of bias or concern of applicability. The Deek funnel plot asymmetry test indicated possible publication bias in MRI studies for differentiation of T3cd-T4 disease from T1-T3ab disease and differentiation of node-negative disease from node-positive disease. For MRI, for discriminating T1-T2 from T3-T4 disease, PPV was 64.8% (95% CI, 52.9-75.5%) and NPV was 88.9% (95% CI, 82.7-93.7%); for discriminating T1-T3ab from T3cd-T4 disease, PPV was 83.4% (95% CI, 75.0-90.3%) and NPV was 74.6% (95% CI, 58.2-86.7%); for discriminating T1-T3 from T4 disease, PPV was 94.0% (95% CI, 89.4-97.3%) and NPV was 39.9% (95% CI, 24.9-56.6%); for discriminating node-negative from node-positive disease, PPV was 74.9% (95% CI, 69.3-80.0%) and NPV was 53.9% (95% CI, 45.3-62.0%). For PET/CT, for discriminating node-negative from node-positive disease, PPV was 76.4% (95% CI, 67.9-85.1%) and NPV was 68.2% (95% CI, 56.8-78.6%). Across outcomes, MRI and PET/CT showed pooled sensitivity of 55.1-81.4% and pooled specificity of 70.3-88.1%. CONCLUSION. MRI had the strongest predictive performance for T1-T2 and T4 disease. MRI and PET/CT otherwise had limited predictive values, sensitivity, and specificity for evaluated outcomes related to T and N staging. CLINICAL IMPACT. MRI and FDG PET/CT had overall limited utility for preoperative locoregional staging of colon cancer. TRIAL REGISTRATION. PROSPERO (International Prospective Register of Systematic Reviews) CRD42022326887.

Targeting HER2 in solid tumors: Unveiling the structure and novel epitopes

Human epidermal growth factor receptor-2 (HER2) is overexpressed in various solid tumor types, acting as an established therapeutic target. Over the last three decades, the fast-paced development of diverse HER2-targeted agents, notably marked by the introduction of the antibody-drug conjugate (ADC), yielding substantial improvements in survival rates. However, resistance to anti-HER2 treatments continues to pose formidable challenges. The complex structure and dynamic dimerization properties of HER2 create significant hurdles in the development of novel targeted therapeutics. In this review, we synthesize the latest insights into the structural intricacies of HER2 and present an unprecedented overview of the epitope characteristics of HER2-targeted antibodies and their derivatives. Furthermore, we delve into the correlation between anti-HER2 antibody binding epitopes and their respective functions, with a particular focus on their efficacy against resistant tumors. In addition, we highlight the potential of emerging anti-HER2 agents that target specific sites or non-overlapping epitopes, poised to transform the therapeutic landscape for HER2-positive tumors in the foreseeable future.

Astatine-211 radiolabelling chemistry: from basics to advanced biological applications

BACKGROUND

211At-radiopharmaceuticals are currently the subject of growing studies for targeted alpha therapy of cancers, which leads to the widening of the scope of the targeting vectors, from small molecules to peptides and proteins. This has prompted, during the past decade, to a renewed interest in developing novel 211At-labelling approaches and novel prosthetic groups to address the diverse scenarios and to reach improved efficiency and robustness of procedures as well as an appropriate in vivo stability of the label.

MAIN BODY

Translated from the well-known (radio)iodine chemistry, the long preferred electrophilic astatodemetallation using trialkylaryltin precursors is now complemented by new approaches using electrophilic or nucleophilic At. Alternatives to the astatoaryl moiety have been proposed to improve labelling stability, and the range of prosthetic groups available to label proteins has expanded.

CONCLUSION

In this report, we cover the evolution of radiolabelling chemistry, from the initial strategies developed in the late 1970's to the most recent findings.

Optimizing the Therapeutic Index of sdAb-Based Radiopharmaceuticals Using Pretargeting

Single-domain antibodies (sdAbs) demonstrate favorable pharmacokinetic profiles for molecular imaging applications. However, their renal excretion and retention are obstacles for applications in targeted radionuclide therapy (TRT). Methods: Using a click-chemistry-based pretargeting approach, we aimed to reduce kidney retention of a fibroblast activation protein α (FAP)-targeted sdAb, 4AH29, for 177Lu-TRT. Key pretargeting parameters (sdAb-injected mass and lag time) were optimized in healthy mice and U87MG (FAP+) xenografts. A TRT study in a pancreatic ductal adenocarcinoma (PDAC) patient-derived xenograft (PDX) model was performed as a pilot study for sdAb-based pretargeting applications. Results: Modification of 4AH29 with trans-cyclooctene (TCO) moieties did not modify the sdAb pharmacokinetic profile. A 200-µg injected mass of 4AH29-TCO and an 8-h lag time for the injection of [177Lu]Lu-DOTA-PEG7-tetrazine resulted in the highest kidney therapeutic index (2.0 ± 0.4), which was 5-fold higher than that of [177Lu]Lu-DOTA-4AH29 (0.4 ± 0.1). FAP expression in the tumor microenvironment was validated in a PDAC PDX model with both immunohistochemistry and PET/CT imaging. Mice treated with the pretargeting high-activity approach (4AH29-TCO + [177Lu]Lu-DOTA-PEG7-tetrazine; 3 × 88 MBq, 1 injection per week for 3 wk) demonstrated prolonged survival compared with the vehicle control and conventionally treated ([177Lu]Lu-DOTA-4AH29; 3 × 37 MBq, 1 injection per week for 3 wk) mice. Mesangial expansion was reported in 7 of 10 mice in the conventional cohort, suggesting treatment-related kidney morphologic changes, but was not observed in the pretargeting cohort. Conclusion: This study validates pretargeting to mitigate sdAbs' kidney retention with no observation of morphologic changes on therapy regimen at early time points. Clinical translation of click-chemistry-based pre-TRT is warranted on the basis of its ability to alleviate toxicities related to biovectors' intrinsic pharmacokinetic profiles. The absence of representative animal models with extensive stroma and high FAP expression on cancer-associated fibroblasts led to a low mean tumor-absorbed dose even with high injected activity and consequently to modest survival benefit in this PDAC PDX.

Next Generation of Solid Target Radionuclide Antibody Conjugates for Tumor Immuno-Therapy

Immune checkpoint therapy has emerged as an effective treatment option for various types of cancers. Key immune checkpoint molecules, such as cytotoxic T-lymphocyte-associated protein 4 (CTLA-4), programmed cell death protein 1 (PD-1), and lymphocyte activation gene 3 (LAG-3), have become pivotal targets in cancer immunotherapy. Antibodies designed to inhibit these molecules have demonstrated significant clinical efficacy. Nevertheless, the ability to monitor changes in the immune status of tumors and predict treatment response remains limited. Conventional methods, such as assessing lymphocytes in peripheral blood or conducting tumor biopsies, are inadequate for providing real-time, spatial information about T-cell distributions within heterogeneous tumors. Positron emission tomography (PET) using T-cell specific probes represents a promising and noninvasive approach to monitor both systemic and intratumoral immune changes during treatment. This technique holds substantial clinical significance and potential utility. In this paper, we review the applications of PET probes that target immune cells in molecular imaging.

Synthesis, preclinical evaluation and pilot clinical translation of [68Ga]Ga-PMD22, a novel nanobody PET probe targeting CLDN18.2 of gastrointestinal cancer

PURPOSE

Claudin18.2 (CLDN18.2) is a novel target for diagnosis and therapy of gastrointestinal cancer. This study aimed to evaluate the safety and feasibility of a novel CLDN18.2-targeted nanobody, PMD22, labeled with gallium-68 ([68Ga]Ga), for detecting CLDN18.2 expression in patients with gastrointestinal cancer using PET/CT imaging.

METHODS

[68Ga]Ga-PMD22 was synthesized based on the nanobody, and its cell binding properties were assayed. Preclinical pharmacokinetics were determined in CLDN18.2-positive xenografts using microPET/CT. Effective dosimetry of [68Ga]Ga-PMD22 was evaluated in 5 gastrointestinal cancer patients, and PET/CT imaging of [68Ga]Ga-PMD22 and [18F]FDG were performed head-to-head in 16 gastrointestinal cancer patients. Pathological tissues were obtained for CLDN18.2 immunohistochemical (IHC) staining and comparative analysis with PET/CT findings.

RESULTS

Cell binding assay showed that [68Ga]Ga-PMD22 had a higher binding ability to AGSCLDN18.2 and BGC823CLDN18.2 cells than to AGS and BGC823 cells (p < 0.001). MicroPET/CT images showed that [68Ga]Ga-PMD22 rapidly accumulated in AGSCLDN18.2 and BGC823CLDN18.2 tumors, and high contrast tumor to background imaging was clearly observed. In the pilot study, the effective dose of [68Ga]Ga-PMD22 was 1.68E-02 ± 1.45E-02 mSv/MBq, and the CLDN18.2 IHC staining result was highly correlated with the SUVmax/BKGstomach of [68Ga]Ga-PMD22 (rs = 0.848, p < 0.01).

CONCLUSION

A novel [68Ga]Ga-labeled nanobody probe targeting CLDN18.2, [68Ga]Ga-PMD22, was established and preliminarily proved to be safe and effective in revealing CLDN18.2-positive gastrointestinal cancer, providing a basis for the clinical translation of the agent.

CLINICAL TRIAL REGISTRATION

This study was registered on the ClinicalTrials.gov (NCT05937919).

Radiotracer Innovations in Breast Cancer Imaging: A Review of Recent Progress

This review focuses on the pivotal role of radiotracers in breast cancer imaging, emphasizing their importance in accurate detection, staging, and treatment monitoring. Radiotracers, labeled with radioactive isotopes, are integral to various nuclear imaging techniques, including positron emission tomography (PET) and positron emission mammography (PEM). The most widely used radiotracer in breast cancer imaging is 18F-fluorodeoxyglucose (18F-FDG), which highlights areas of increased glucose metabolism, a hallmark of many cancer cells. This allows for the identification of primary tumors and metastatic sites and the assessment of tumor response to therapy. In addition to 18F-FDG, this review will explore newer radiotracers targeting specific receptors, such as estrogen receptors or HER2, which offer more personalized imaging options. These tracers provide valuable insights into the molecular characteristics of tumors, aiding in tailored treatment strategies. By integrating radiotracers into breast cancer management, clinicians can enhance early disease detection, monitor therapeutic efficacy, and guide interventions, ultimately improving patient outcomes. Ongoing research aimed at developing more specific and sensitive tracers will also be highlighted, underscoring their potential to advance precision medicine in breast cancer care.

Combining poly-epitope MoonTags and labeled nanobodies for signal amplification in cell-specific PET imaging in vivo

Immunorecognition provides an excellent basis for targeted imaging techniques covering a wide range from basic research to diagnostics and from single cells to whole organisms. Fluorescence- or radioisotope-labeled antibodies, antibody fragments or nanobodies enable a direct signal readout upon binding and allow for versatile imaging from microscopy to whole-body imaging. However, as the signal intensity directly correlates with the number of labeled antibodies bound to their epitopes (1:1 binding), sensitivity for low-expressing epitopes can be limiting for visualization. For the first time, we developed poly-epitope tags with multiple copies (1 to 7) of a short peptide epitope, specifically the MoonTag, that are recognized by a labeled nanobody and aimed at signal amplification in microscopy and cell-specific PET imaging. In transiently transfected HeLa cells or stably transduced A4573 cells we characterized complex formation and in vitro signal amplification. Indeed, using fluorescently and radioactively labeled nanobodies we found an approximately linear signal amplification with increasing numbers of epitope copies in vitro. To test the poly-epitope approach in vivo, A4573 tumor cells were injected subcutaneously into the shoulder of NSG mice, with A4573 tumor cells expressing a poly-epitope of 7 MoonTags on one side and WT cells on the other side. Using a [68Ga]-labeled NODAGA-conjugated MoonTag nanobody, we performed PET/CT imaging at day 8-9 after tumor implantation. Specific binding of a [68Ga]-labeled NODAGA-conjugated MoonTag nanobody was observed in 7xMoonTag tumors (1.7 ± 0.5%ID/mL) by PET imaging, showing significantly higher radiotracer accumulation compared to the WT tumors (1.1 ± 0.3%ID/mL; p < 0.01). Ex vivo gamma counter measurements confirmed significantly higher uptake in 7xMoonTag tumors compared to WT tumors (p < 0.001). In addition, MoonTag nanobody binding was detected by autoradiography which was spatially matched with histological analysis of the tumor tissues. In conclusion, we expect nanobody-based poly-epitope tag strategies to be widely applicable for multimodal imaging techniques given the advantageous properties of nanobodies and their amenability to genetic and chemical engineering.

Advancements in nuclear imaging using radiolabeled nanobody tracers to support cancer immunotherapy

The evolving landscape of cancer immunotherapy has revolutionized cancer treatment. However, the dynamic tumor microenvironment has led to variable clinical outcomes, indicating a need for predictive biomarkers. Noninvasive nuclear imaging, using radiolabeled modalities, has aided in patient selection and monitoring of their treatment response. This approach holds promise for improving diagnostic accuracy, providing a more personalized treatment regimen, and enhancing the clinical response. Nanobodies or single-domain antibodies, derived from camelid heavy-chain antibodies, allow early timepoint detection of targets with high target-to-background ratios. To date, a plethora of nanobodies have been developed for nuclear imaging of tumor-specific antigens, immune checkpoints, and immune cells, both at a preclinical and clinical level. This review comprehensively outlines the recent advancements in nanobody-based nuclear imaging, both on preclinical and clinical levels. Additionally, the impact and expected future advancements on the use of nanobody-based radiopharmaceuticals in supporting cancer diagnosis and treatment follow-up are discussed.

Claudin18.2-Targeted SPECT/CT Imaging for Gastric Cancer: Preclinical Evaluation and Clinical Translation of the 99mTc-Labeled Nanobody (PHG102) Radiotracer

Claudin18.2 (CLDN18.2) has emerged as a significant target in the treatment of advanced gastric cancer. The screening of patients positive for CLDN18.2 is crucial for the effective application of targeted therapies specific to CLND18.2. In this study, we developed a novel nanobody-based probe, [99mTc]Tc-PHG102, for use in nuclear medicine. We analyzed its radiochemical yield and stability to ensure accurate probe characterization. Additionally, we assessed the probe's affinity and specificity toward the CLDN18.2 target and evaluated its efficacy in the BGC82318.2 xenograft model for SPECT/CT imaging of gastric cancer. The binding of [99mTc]Tc-PHG102 to HEK-293T18.2 and BGC82318.2 cells was notably higher than its binding to HEK-293T18.1, HEK-293T, and BGC823 cells, with bound values of 12.87 ± 1.46%, 6.16 ± 0.34%, 1.25 ± 0.22%, 1.14 ± 0.26%, and 1.32 ± 0.07% AD, respectively. The binding ability of [99mTc]Tc-PHG102 was significantly different between CLDN18.2-positive and negative cells (P < 0.001). Imaging results demonstrated a time-dependent tumor accumulation of the radiotracer. Notably, at 0.5 h postinjection, rapid accumulation was observed with an average tumor uptake of 4.63 ± 0.81% ID/cc (n = 3), resulting in clear tumor visualization. By 1 h postinjection, as [99mTc]Tc-PHG102 was rapidly metabolized, a decrease in uptake by other organs was noted. Preliminary clinical imaging trials further confirmed the safety and effectiveness of the probe, indicating specificity for lesions expressing CLDN18.2 in gastric cancer and favorable in vivo metabolic properties. In conclusion, the nanobody-based probe [99mTc]Tc-PHG102 proves to be a safe and effective tool for detecting CLDN18.2 expression levels in gastric cancer tumors and for screening CLDN18.2-positive patients.

Imaging and Monitoring HER2 Expression in Tumors during HER2 Antibody-Drug Conjugate Therapy Utilizing a Radiolabeled Site-Specific Single-Domain Antibody Probe: 68Ga-NODAGA-SNA004-GSC

The overexpression of HER2 is pivotal in the initiation and progression of breast cancer. Developing HER2-targeted radiotracers is crucial for noninvasive assessment of HER2 expression, patient selection for HER2-targeted therapy, monitoring treatment response, and identifying resistance. Here, we reported a nonsite-specific coupled radiotracer, 68Ga-NOTA-SNA004-His6, and a site-specific coupled radiotracer, 68Ga-NODAGA-SNA004-GSC, based on a novel HER2 nanobody, SNA004. Both radiotracers exhibited high affinity, specific targeting, and rapid clearance in vitro and in vivo. Additionally, these tracers and trastuzumab showed noncompetitive binding to HER2. Compared to 68Ga-NOTA-SNA004-His6, 68Ga-NODAGA-SNA004-GSC demonstrated significantly reduced renal and liver uptake. PET/CT imaging with 68Ga-NODAGA-SNA004-GSC sensitively detected the responsiveness of various tumor models to trastuzumab and its antibody-drug conjugates (ADCs). Overall, the site-specific coupled radiotracer 68Ga-NODAGA-SNA004-GSC offered significant advantages in biodistribution and signal-to-noise ratio, making it a valuable tool for monitoring HER2 expression levels before, during, and after trastuzumab and ADC treatment.

Generic semi-automated radiofluorination strategy for single domain antibodies: [18F]FB-labelled single domain antibodies for PET imaging of fibroblast activation protein-α or folate receptor-α overexpression in cancer

BACKGROUND

Radiofluorination of single domain antibodies (sdAbs) via N-succinimidyl-4-[18F]fluorobenzoate ([18F]SFB) has shown to be a promising strategy in the development of sdAb-based PET tracers. While automation of the prosthetic group (PG) [18F]SFB production, has been successfully reported, no practical method for large scale sdAb labelling has been reported. Therefore, we optimized and automated the PG production, enabling a subsequently efficient manual conjugation reaction to an anti-fibroblast activation protein (FAP)-α sdAb (4AH29) and an anti-folate receptor (FR)-α sdAb (2BD42). Both the alpha isoform of FAP and the FR are established tumour markers. FAP-α is known to be overexpressed mainly by cancer-associated fibroblasts in breast, ovarian, and other cancers, while its expression in normal tissues is low or undetectable. FR-α has an elevated expression in epithelial cancers, such as ovarian, brain and lung cancers. Non-invasive imaging techniques, such as PET-imaging, using tracers targeting specific tumour markers can provide molecular information over both the tumour and its environment, which aides in the diagnosis, therapy selection and assessment of the cancer treatment.

RESULTS

[18F]SFB was synthesized using a fully automated three-step, one-pot reaction. The total procedure time was 54 min and results in [18F]SFB with a RCP > 90% and a RCY d.c. of 44 ± 4% (n = 13). The manual conjugation reaction after purification produced [18F]FB-sdAbs with a RCP > 95%, an end of synthesis activity > 600 MBq and an apparent molar activity > 10 GBq/µmol. Overall RCY d.c., corrected to the trapping of [18F]F- on the QMA, were 9% (n = 1) and 5 ± 2% (n = 3) for [18F]FB-2BD42 and [18F]FB-4AH29, respectively.

CONCLUSION

[18F]SFB synthesis was successfully automated and upscaled on a Trasis AllInOne module. The anti-hFAP-α and anti-hFR-α sdAbs were radiofluorinated, yielding similar RCYs d.c. and RCPs, showing the potential of this method as a generic radiofluorination strategy for sdAbs. The radiofluorinated sdAbs showed a favourable biodistribution pattern and are attractive for further characterization as new PET tracers for FAP-α and FR-α imaging.

Screening and optimization of shark nanobodies against SARS-CoV-2 spike RBD

SARS-CoV-2 continues to threaten human health, antibody therapy is one way to control the infection. Because new SARS-CoV-2 mutations are constantly emerging, there is an urgent need to develop broadly neutralizing antibodies to block the viral entry into host cells. VNAR from sharks is the smallest natural antigen binding domain, with the advantages of small size, flexible paratopes, good stability, and low manufacturing cost. Here, we used recombinant SARS-CoV-2 Spike-RBD to immunize sharks and constructed a VNAR phage display library. VNAR R1C2, selected from the library, efficiently binds to the RBD domain and blocks the infection of ACE2-positive cells by pseudovirus. Next, homologous bivalent VNARs were constructed through the tandem fusion of two R1C2 units, which enhanced both the affinity and neutralizing activity of R1C2. R1C2 was predicted to bind to a relatively conserved region within the RBD. By introducing mutations at four key binding sites within the CDR3 and HV2 regions of R1C2, the affinity and neutralizing activity of R1C2 were significantly improved. Furthermore, R1C2 also exhibits an effective capacity of binding to the Omicron variants (BA.2 and XBB.1). Together, these results suggest that R1C2 could serve as a valuable candidate for preventing and treating SARS-CoV-2 infections.

Brain metastasis: An insight into novel molecular targets for theranostic approaches

Brain metastases (BrM) are common malignant lesions in the central nervous system, and pose a significant threat in advanced-stage malignancies due to delayed diagnosis and limited therapeutic options. Their distinct genomic profiles underscore the need for molecular profiling to tailor effective treatments. Recent advances in cancer biology have uncovered molecular drivers underlying tumor initiation, progression, and metastasis. This, coupled with the advances in molecular imaging technology and radiotracer synthesis, has paved the way for the development of innovative radiopharmaceuticals with enhanced specificity and affinity for BrM specific targets. Despite the challenges posed by the blood-brain barrier to effective drug delivery, several radiolabeled compounds have shown promise in detecting and targeting BrM. This manuscript provides an overview of the recent advances in molecular biomarkers used in nuclear imaging and targeted radionuclide therapy in both clinical and preclinical settings. Additionally, it explores potential theranostic applications addressing the unique challenges posed by BrM.