Development of FAPI Tetramers to Improve Tumor Uptake and Efficacy of FAPI Radioligand Therapy

FAP-targeted delivery of radioiodinated probes: A progressive albumin-driven strategy for tumor theranostics

Fibroblasts activated protein (FAP) appears to be a promising target for tumor theranostics. However, the development of radioiodinated probes for FAP has been slow. In this study, a progressive abumin-driven strategy was adopted to improve the FAP-targeted delivery of radioiodinated probes for tumor theranostics. A series of FAP-targeted probes (namely [131I]IPB-FAPI, [131I]IPB-FAPI-A1, [131I]IPB-FAPI-A3, [131I]FSDD3I) were synthesized by incorporating an albumin-binding moiety (4-(p-iodophenyl)butyric acid, 4-IPBA) labeled with radioiodine. The specificity and binding characteristics of the radiotracers to FAP and human serum albumin (HSA) were confirmed. SPECT imaging results showed that the [131I]FSDD3I had more prominent tumor retention property and superior target-to-nontarget ratio, which were consistent with the biodistribution results. As expected, the FAP-targeted therapy with 11.1 MBq [131I]FSDD3I significantly inhibited tumor growth. In conclusion, this proof-of-concept study employed a progressive design strategy to enhance pharmacokinetics of radioiodinated FAP-targeted probes. Among these radioiodinated FAPI probes, 131I-labeled FSDD3I ([131I]FSDD3I) emerged as a standout candidate with superior competitive advantages for application in radioiodine-guided internal irradiation therapy.

A heterodimeric radioligand labeled with gallium-68 targeting fibroblast activation protein

BACKGROUND

Fibroblast activation protein (FAP) targeting radiotracers have emerged as promising agents for cancer imaging and therapy. Recent advancements have focused on optimizing these agents for better tumor targeting and enhanced theranostic efficacy. In this study, we introduced a novel heterodimeric radioligand labeled with gallium-68, which targets FAP. We aimed to evaluate its in vitro and in vivo performance, comparing its efficacy with monomeric FAPI derivatives.

RESULTS

The heterodimeric ligand BiFAPI was synthesized by conjugating a cyclic peptide with a quinoline-based motif via a DOTA chelator. [68 Ga]Ga-BiFAPI demonstrated high radiochemical purity (> 95%) and exceptional stability in physiological conditions, as well as in both PBS and serum. In vitro studies revealed that the binding affinity of BiFAPI was comparable to that of FAP2286 and FAPI-04. Notably, [68 Ga]Ga-BiFAPI exhibited superior cellular uptake, with rapid internalization and slower efflux rates. Micro-PET/CT imaging in tumor-bearing mice demonstrated significantly higher tumor uptake than [68 Ga]Ga-FAP2286 and [68 Ga]Ga-FAPI-04. Co-injection with a FAP inhibitor reduced tumor uptake, confirming the tracer's FAP specificity. In vitro autoradiography, immunohistochemistry, and Western blotting confirmed the correlation between radioactive tracer accumulation and FAP-positive regions. Biodistribution studies revealed high tumor-to-blood ratios and rapid clearance from non-target tissues, further supporting the tracer's favorable pharmacokinetics.

CONCLUSION

[68 Ga]Ga-BiFAPI demonstrated superior tumor-targeting properties, higher tumor uptake, and favorable pharmacokinetics compared to [68 Ga]Ga-FAP2286 and [68 Ga]Ga-FAPI-04. Its promising performance in preclinical models positioned it as a potentially valuable agent for FAP-targeted PET imaging and cancer theranostics.

177Lu-LNC1004 Radioligand Therapy in Patients with End-stage Metastatic Cancers: A Single-Center, Single-Arm, Phase II Study

PURPOSE

Fibroblast activation protein (FAP) is highly expressed in cancer-associated fibroblasts and certain tumor cells, making it a promising therapeutic target for various malignancies. This study evaluated the efficacy and safety of 177Lu-Evans blue-FAP inhibitor (177Lu-LNC1004) radioligand therapy (RLT) for treating end-stage metastatic tumors.

PATIENTS AND METHODS

This single-arm, single-center, phase II trial included 28 patients with progressive metastatic malignancies (11 types) and high FAP expression (defined as a maximum standardized uptake value ≥10 in >50% of tumors) who had exhausted all approved therapies, screened between June 2022 and April 2024. Patients were scheduled to receive four 177Lu-LNC1004 RLT cycles at 3.33 GBq/cycle every 6 weeks. The primary endpoint was post-RLT radiologic response. The secondary endpoints were progression-free survival (PFS), overall survival (OS), dosimetry, and safety.

RESULTS

Eastern Cooperative Oncology Group scores >2 were observed in 68% of patients. Overall, 63 177Lu-LNC1004 RLT cycles were performed, with 19 (68%) patients undergoing ≥2 cycles. Disease control was achieved in 13 (13/28, 46%) patients, with 4 and 9 patients demonstrating partial response and stable disease, respectively, and associated with improved PFS and OS (P < 0.001). The mean absorbed dose in tumors was 4.69 ± 3.83 Gy/GBq (1.18-25.03 Gy/GBq). Treatment-related grade 3/4 hematotoxicity was observed in six (21%) patients, with thrombocytopenia, leukopenia, and neutropenia most prevalent. No grade 3/4 hepatotoxicity or nephrotoxicity was observed.

CONCLUSIONS

FAP-directed RLT using 177Lu-LNC1004 at 3.33 GBq/cycle was well tolerated with an acceptable toxicity profile. Nearly half of patients achieved disease control, which was associated with prolonged PFS and OS.

Preclinical Characterization of Novel FAP-2286-Based Radioligand with Albumin Binder for Improved Tumor Retention

Fibroblast activation protein (FAP) is an attractive biomarker for tumor-targeting agents in cancer diagnosis and therapy. FAP-2286 shows retention in FAP-expressing tumors and is known as a promising FAP-targeting radioligand. In this study, we aimed to develop a FAP-2286 derivative that demonstrates higher tumor retention than FAP-2286. We designed DOTAGA-FAP-2286 and DOTAGA-FAP-2286-ALB by replacing DO3A with 2-(4,7,10-tris(carboxymethyl)-1,4,7,10-tetraazacyclododecan-1-yl)pentanedioic acid (DOTAGA) and introducing an albumin binder. Both compounds were successfully radiolabeled with 111In. Compared with [111In]In-DOTAGA-FAP-2286, [111In]In-DOTAGA-FAP-2286-ALB showed higher stability in murine plasma. In the cell competition binding study, In-DOTAGA-FAP-2286-ALB exhibited a higher FAP-binding affinity than In-DOTAGA-FAP-2286. In the albumin-binding assay, [111In]In-DOTAGA-FAP-2286-ALB showed a high binding rate in the solution with albumin. The biodistribution assay revealed marked tumor retention of [111In]In-DOTAGA-FAP-2286-ALB, resulting in the enhancement of predicted tumor AUC values of [225Ac]Ac-DOTAGA-FAP-2286-ALB. These results suggest advantages of the introduction of an albumin binder to FAP-2286.

Design and preclinical evaluation of 99mTc-Labeled dimer FAPI-46 derivatives as potential tumor radiotracers

Fibroblast activation protein (FAP) is a crucial target for tumor diagnosis and treatment. FAP inhibitors (FAPIs) can selectively bind to FAP, and ligands with multiple targeting groups are anticipated to improve tumor-specific uptake. A dimeric FAPI ligand (L2) with high affinity for FAP was selected. Four hydrophilic 99mTc-labeled complexes ([99mTc]Tc-L2-TPPTS, [99mTc]Tc-L2-TPPMS, [99mTc]Tc-L2-PDA, and [99mTc]Tc-L2-NIC) were successfully prepared and exhibited good stability in vitro. Among them, [99mTc]Tc-L2-TPPTS and [99mTc]Tc-L2-PDA showed superior cellular uptake and specific binding to FAP. They displayed minimal nontarget uptake in normal mice and exhibited significant tumor uptake (22.01 ± 1.38 % ID/g and 26.58 ± 2.17 % ID/g at 1 h post-injection) with high specificity for FAP in U87MG tumor-bearing mice. SPECT/CT imaging experiments revealed specific accumulation of both complexes at the U87MG, PANC-1, and HT-1080-FAP tumor sites, suggesting their excellent specificity for FAP. In particular, [99mTc]Tc-L2-TPPTS has lower nontarget uptake in various tumor models and accelerated blood clearance. Additionally, an L2-TPPTS kit was successfully prepared providing convenient conditions for subsequent clinical transformation research.

99mTc-Labeled Quinolone-Based Novel Skeletal Tracers for Tumor Visualization through Fibroblast Activation Protein

Fibroblast activation protein (FAP) has emerged as a prominent target for tumor diagnosis. Quinoline-based FAP PET tracers demonstrated clinical feasibility. However, there is a relative scarcity of clinical studies on 99mTc-labeled FAP SPECT tracers. The existing quinoline-derived 99mTc-FAPI tracer exhibits relatively low tumor uptake and suboptimal pharmacokinetic properties, which restrict its clinical application. Consequently, it is necessary to alter the pharmacophores to improve its druggability. In this study, a novel quinolone-based pharmacophore was developed by utilizing scaffold hopping and conformational constrained strategies. Serial screening and preclinical evaluations were conducted. The 99mTc-FAPI-YQ3 showed extremely high tumor uptake and excellent pharmacokinetic properties. Additionally, 99mTc-FAPI-YQ3 demonstrated reliable safety characteristics and clinical efficacy on four different oncology patients. In conclusion, 99mTc-FAPI-YQ3 was a promising radiotracer for FAP-targeted cancer diagnosis, shedding light on substantially advancing SPECT molecular imaging.

Determining the Multivalent Effects of d-Peptide-Based Radiotracers

Dextrorotary (d) peptides, composed of d-amino acids, are hyper-resistant to proteolytic hydrolysis, making them valuable ligands with excellent in vivo stability for radiopharmaceutical development. Multimerization is a well-established strategy for enhancing the in vivo performance of l-peptide-based radiopharmaceuticals. However, the effect of multimerization on the in vivo fate of d-peptide-based radiopharmaceuticals remains largely unexplored. Here, we synthesized the d-peptide DPA, which targets PD-L1, along with its dimer (DP2) and trimer (DP3). PET/CT imaging and ex vivo biodistribution studies were performed to delineate the pharmacokinetics and target interactions of [68Ga]DPA, [68Ga]DP2, and [68Ga]DP3 in both normal and tumor-bearing mice. Our results revealed that tumor uptake and kidney retention increased with higher valency ([68Ga]DP3 > [68Ga]DP2 > [68Ga]DPA). No significant differences were observed in the liver, heart, lung, spleen, intestine, or bone among the three radiotracers. Interestingly, a significant reduction of radioactivity in the bloodstream was detected for the [68Ga]DP3-treated group compared to the other two groups. Data analysis revealed that chiral configuration of amino acids and the linking chemistry used in multimerization are the two dominant factors in the in vivo fate of d-peptide multimers. These findings indicate that d-peptide multimerization exerts a distinct influence on in vivo profiles compared to l-peptide multimerization. This study deepens our understanding of how mirror-imaged peptides/proteins interact with the living systems, paving the way for the development of radiopharmaceuticals that harness d-peptides as targeting moieties.

[64Cu]Cu(DDC)2 NPs: A Novel PET Probe for Noninvasive Visualization of NPL4 Expression in Tumors In Vivo

Nuclear protein localization 4 (NPL4) plays a key role in the ubiquitination pathway and has emerged as a promising target for cancer therapy. The ditiocarb-copper complex, Cu(DDC)2, an anticancer metabolite derived from the antialcoholism drug disulfiram (DSF), exhibits a high affinity for NPL4. Thus, quantifying NPL4 expression in tumors is crucial for ubiquitination research and for developing NPL4-targeted diagnostic and therapeutic strategies. In this study, we replaced the cold copper ion in Cu(DDC)2 with the positron-emitting isotope copper-64 and developed three methods for visualizing NPL4 in tumors in vivo using positron emission tomography/computed tomography (PET/CT): (1) an in vivo "synthesis-free" method for preparing [64Cu]Cu(DDC)2, (2) an in vitro synthesis method, and (3) a stabilization method using PEG5000-PLA5000 (PP) to enhance [64Cu]Cu(DDC)2's hydrophilicity by preparing [64Cu]Cu(DDC)2 NPs. Micro-PET/CT imaging showed minimal uptake of [64Cu]Cu(DDC)2 in NPL4-positive tumors with the in vivo "synthesis-free" method, resulting in poor lesion visualization. However, in vitro synthesized [64Cu]Cu(DDC)2 and [64Cu]Cu(DDC)2 NPs successfully visualized NPL4-positive U87MG tumors. Compared to [64Cu]Cu(DDC)2, [64Cu]Cu(DDC)2NPs demonstrated significantly higher tumor uptake (7.2 ± 0.7% ID/g vs 3.8 ± 0.6% ID/g at 12 h postinjection, P = 0.001) and tumor-to-muscle (T/M) ratio (7.8 ± 1.2 vs. 3.2 ± 0.7, P = 0.001). Tumor uptake of [64Cu] Cu (DDC)2NPs was consistent with NPL4 expression levels and was inhibited by an excess of Cu(DDC)2. The optimal PP stabilizer concentration was determined to be 0.0005%. This study successfully developed a PET probe, [64Cu]Cu(DDC)2NPs, and established a novel imaging modality for in vivo visualization of NPL4 expression, potentially guiding future NPL4-targeted therapies.

Preclinical and First-In-Human Imaging of Novel [18F]F-FAPI-FUSCC-07 Tracer: Comparative Prospective Study with [18F]F-FAPI-42 and [18F]F-FAPI-74

This study aimed to develop and evaluate a novel fibroblast activation protein (FAP)-specific tracer, fluorine-18-labeled fibroblast activation protein inhibitor-FUSCC-07 ([18F]F-FAPI-FUSCC-07), for use in both preclinical and clinical settings. Preclinical evaluations were conducted to assess the stability and partition coefficient of [18F]F-FAPI-FUSCC-07. Experiments involving human glioma U87MG cells demonstrated its cellular uptake and inhibitory properties. Further investigations included biodistribution analysis and micropositron emission tomography/computed tomography (PET/CT) imaging in U87MG tumor-bearing mice, which revealed strong tumor uptake and prolonged retention. In the clinical setting, [18F]F-FAPI-FUSCC-07 was compared directly with [18F]F-FAPI-42 and [18F]F-FAPI-74 to evaluate its performance in imaging various cancers. By expanding the patient cohort, the study provided a more comprehensive assessment of tracer uptake in lesions. The findings demonstrated that [18F]F-FAPI-FUSCC-07 exhibited high stability in phosphate-buffered saline and fetal bovine serum, as well as hydrophilic properties. Clinical imaging results indicated significantly higher tumor uptake and improved target-to-blood pool ratios compared to the other tracers. Moreover, PET imaging of patients with diverse cancers showed that [18F]F-FAPI-FUSCC-07 consistently provided superior image contrast in most cases. These results represent the first clinical evidence supporting the feasibility of [18F]F-FAPI-FUSCC-07 for imaging across multiple tumor types. The study highlights its potential as a promising tracer for FAPI PET imaging, offering enhanced diagnostic precision and broader applicability in oncology.

FAPI PET in the Management of Lung Tumors

Fibroblast activation protein (FAP), selectively expressed on activated fibroblasts in proliferating tissues, is emerging as a promising target in oncology. In lung cancer, the leading cause of cancer-related deaths worldwide, [18F]FDG PET/CT has set the bar high and earned widespread recognition in clinical guidelines for its essential role in staging and follow-up. Yet, FAP-targeted imaging agents like FAPI PET/CT have demonstrated significant potential due to their high tumor specificity, rapid tracer uptake, and low background activity. This review focuses on the role of FAPI PET/CT in lung cancer, highlighting its applications in staging, biomarker evaluation, and clinical management. FAP expression correlates with cancer associated fibroblast-driven tumorigenesis in lung cancer, showing higher expression in nonsmall cell lung cancer (NSCLC) than in small cell lung cancer (SCLC) subtypes. Studies reveal that FAPI PET/CT provides comparable or superior detection rates for primary tumors and metastases compared to [18F]FDG PET/CT, particularly in brain, pleural, and bone lesions. It also enhances accuracy in lymph node staging, influencing disease management by enabling surgical resection in cases misclassified by [18F]FDG PET/CT. Despite these advantages, several challenges remain, such as differentiating benign from malignant lesions, assessing FAPI's prognostic implications or its role in treatment response monitoring. Future directions include exploring FAPI-based theranostics, standardizing radiopharmaceuticals, and conducting well-designed, adequately powered prospective trials. FAPI PET/CT represents a transformative diagnostic tool, complementing or potentially surpassing [18F]FDG PET/CT in precision lung cancer care.

Development of Novel 99mTc-Labeled Hydrazinoicotinamide-Modified Ubiquicidin 29-41 Complexes with Improved Target-to-Nontarget Ratios for Bacterial Infection Imaging

To develop novel 99mTc-labeled ubiquicidin 29-41 derivatives for bacterial infection SPECT imaging aiming at achieving a high target-to-nontarget ratio and lower nontarget organ uptake, a novel 6-hydrazinoicotinamide (HYNIC) ubiquicidin 29-41 derivative (HYNIC-UBI 29-41) was designed and synthesized. It was then radiolabeled with ternary ligands, including TPPTS, PDA, 2,6-PDA, NIC, ISONIC, PSA, 4-PSA, and PES, to obtain eight 99mTc-labeled HYNIC-UBI 29-41 complexes. All the complexes demonstrated hydrophilicity, exhibited good in vitro stability, and specifically bound Staphylococcus aureus in vitro. Biodistribution studies in mice with bacterial infection demonstrated that [99mTc]Tc-tricine/TPPTS-HYNIC-UBI 29-41 resulted in increased abscess-to-muscle and abscess-to-blood ratios as well as decreased nontarget organ uptake. Furthermore, it was able to distinguish between bacterial infection and sterile inflammation. Single-photon emission computed tomography (SPECT) imaging studies in mice with bacterial infection revealed visible accumulation at the site of infection, indicating that [99mTc]Tc-tricine/TPPTS-HYNIC-UBI 29-41 is a potential radiotracer for imaging bacterial infection.

Preclinical Evaluation of 68Ga/177Lu-Labeled FAP-Targeted Peptide for Tumor Radiopharmaceutical Imaging and Therapy

Fibroblast activation protein (FAP) has been considered a promising target for tumor imaging and therapy. This study designed a novel peptide, FAP-HXN, specifically targeting FAP and exhibiting significant potential as a radionuclide-labeled theranostic agent. Preclinical studies were conducted to evaluate the potency, selectivity, and efficacy of FAP-HXN. Methods: FAP-HXN was synthesized and characterized for selectivity and specificity toward FAP. Cellular uptake of the radiolabeled FAP-HXN in human embryonic kidney (HEK)-293-FAP cells with high expressions of FAP was evaluated. The diagnostic and therapeutic potential of 68Ga- and 177Lu-labeled radioligands was evaluated in HEK-293-FAP tumor-bearing mice compared with the FAP-targeting peptide FAP-2286. Results: FAP-HXN demonstrated high binding ability to human and mouse sources of FAP. Moreover, the in vivo studies confirmed the high affinity and specificity of radiolabeled FAP-HXN. Small-animal PET imaging demonstrated that [68Ga]Ga-FAP-HXN had continuous tumor uptake in FAP-positive tumors after administration compared with [68Ga]Ga-FAP-2286. In the therapeutic experiments, [177Lu]Lu-FAP-HXN showed significant antitumor activity in HEK-293-FAP xenografts at well-tolerated doses, which also exhibited longer tumor retention and better tumor growth inhibition compared with [177Lu]Lu-FAP-2286. Conclusion: The preclinical studies revealed that radiolabeled FAP-HXN had high tumor uptake, prolonged retention, and significant anticancer efficacy in HEK-293-FAP xenografts. FAP-HXN shows promising potential as a novel theranostic radioligand for FAP-positive tumors.

Advances in Preclinical Research of Theranostic Radiopharmaceuticals in Nuclear Medicine

Theranostics of nuclear medicine refers to the combination of radionuclide imaging and internal irradiation therapy, which is currently a research hotspot and an important direction for the future development of nuclear medicine. Radiopharmaceutical is a vital component of nuclear medicine and serves as one of the fundamental pillars of molecular imaging and precision medicine. At present, a variety of radiopharmaceuticals have been developed for various targets such as fibroblast activation protein (FAP), prostate-specific membrane antigen (PSMA), somatostatin receptor 2 (SSTR2), C-X-C motif chemokine receptor 4 (CXCR4), human epidermal growth factor-2 (HER2), and integrin αvβ3, and some of them have been successfully applied in clinical practice. The radiopharmaceutical with theranostic function plays an important role in the diagnosis, treatment, efficacy evaluation, and prognosis prediction of cancers and is the key to realize the personalized treatment of tumors. This Review summarizes the preclinical research progress of theranostic radiopharmaceuticals toward the above targets in the field of nuclear medicine and discusses the prospects and development directions of radiopharmaceuticals in the future.

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.

Development of [68Ga]Ga/[177Lu]Lu-DOTA-NI-FAPI-04 Containing a Nitroimidazole Moiety as New FAPI Radiotracers with Improved Tumor Uptake and Retention

Fibroblast activation protein (FAP), which is overexpressed in cancer-associated fibroblasts (CAFs), represents a promising target for cancer diagnosis and therapy. Hypoxia is a common feature of solid tumors. A bivalent agent, DOTA-NI-FAPI-04 (1), was developed by incorporating hypoxia-sensitive nitroimidazole (NI) into the FAP-targeting agent FAPI-04. Compound 1 exhibited a strong FAP binding affinity with an IC50 of 7.44 nM. Radiolabeled [68Ga]Ga-1 and [177Lu]Lu-1 demonstrated enhanced in vitro cell uptake. In vivo positron emission tomography/computed tomography (PET/CT) imaging showed that [68Ga]Ga-1 displayed significantly higher specific uptake and retention in U87MG tumor-bearing mice compared to [68Ga]Ga-FAPI-04 (SUVavg: 7.87 vs 1.99% ID/mL at 120 min). Biodistribution studies confirmed superior tumor uptake of [68Ga]Ga-1 (48.15 vs 5.72% ID/g at 120 min). Similarly, [177Lu]Lu-1 exhibited higher tumor uptake than [177Lu]Lu-FAPI-04 (50.75 vs 20.48% ID/g at 120 min). These preliminary results suggest that a nitroimidazole-containing bivalent-targeting agent, [68Ga]Ga/[177Lu]Lu-1, is a promising candidate for tumor theranostics.

Monovalent and Divalent Designs of Copper Radiotheranostics Targeting Fibroblast Activation Protein in Cancer

Background: Fibroblast activation protein (FAP)-targeted theranostic radiopharmaceuticals have shown desired tumor-to-background organ selectivity due to the ubiquitous presence of FAP within the tumor microenvironment. However, suboptimal tumor retention and fast clearance have hindered their use to deliver effective cancer therapies. With well-documented FAP-targeting moieties and linkers appending them to optimal chelators, the development of copper radiopharmaceuticals has attracted considerable interest, given the fact that an ideal theranostic pair of copper radionuclides (64Cu: t1/2 = 12.7 h; 17.4% β+; Eβ+max = 653 keV and 67Cu: t1/2 = 2.58 d; 100% β-; Eβ-max = 562 keV) are available. Herein, we report our design, synthesis, and comparative evaluation of monovalent and divalent FAP-targeted theranostic conjugates constructed from our previously reported bifunctional chelator scaffold (BFS) based on 1,4,8,11-tetraaza-bicyclo [6.6.2]hexadecane-4,11-diacetic acid (CB-TE2A), which forms the most stable complex with Cu(II). Methods: After synthesis and characterization, the monovalent and divalent conjugates were radiolabeled with 64Cu for in vitro cell assays, followed by in vivo positron emission tomography (PET) imaging evaluation in relevant mouse models. Results: Both 64Cu-labeled conjugates showed high in vitro stability and anticipated FAP-mediated cell binding and internalization. The divalent one showed significantly higher FAP-specific tumor uptake than its monovalent counterpart. Conclusions: Our results demonstrate that the BFS-based multivalent approach can be practically used to generate FAP-targeted radiotheranostic agents for effective cancer diagnosis and treatment.

Synthesis and Evaluation of 99mTc-Labeled l-Aspartic Acid as a EuK Polymer Linker for Targeting PSMA to a Novel SPECT Tumor Tracer

The development of novel tracers targeting prostate-specific membrane antigen (PSMA) has great potential for improving the diagnosis and treatment of prostate cancer (PCa). This study aimed to improve the absolute tumor uptake and tumor-to-background ratios (TBRs) of this novel PSMA tracer by increasing the number of pharmacophores, Glu-urea-Lys (EuK), that specifically bind to PSMA. We successfully synthesized four radioligands and prepared a total of 12 stable radiotracers by coordinating 99mTc with various coligands. [99mTc]Tc-EUKD-EDDA showed the best pharmacokinetic properties both in vitro and in vivo. It effectively increased the absolute uptake in tumors and resulted in good tumor retention. Rapid clearance in nontarget organs resulted in high TBRs. High-contrast SPECT/CT images were obtained within 2-6 h after injection, suggesting that [99mTc]Tc-EUKD-EDDA has great application potential in time-lapse imaging of PCa, which is important for improving the diagnostic accuracy of PCa in clinical practice.

Development of a homotrimeric PSMA radioligand based on the NOTI chelating platform

BACKGROUND

The NOTI chelating scaffold can readily be derivatized for bioconjugation without impacting its metal complexation/radiolabeling properties making it an attractive building block for the development of multimeric/-valent radiopharmaceuticals. The objective of the study was to further explore the potential of the NOTI chelating platform by preparing and characterizing homotrimeric PSMA radioconjugates in order to identify a suitable candidate for clinical translation.

RESULTS

Altogether, three PSMA conjugates based on the NOTI-TVA scaffold with different spacer entities between the chelating unit and the Glu-CO-Lys PSMA binding motif were readily prepared by solid phase-peptide chemistry. Cell experiments allowed the identification of the homotrimeric conjugate 9 comprising NaI-Amc spacer with high PSMA binding affinity (IC50 = 5.9 nM) and high PSMA-specific internalization (17.8 ± 2.5%) compared to the clinically used radiotracer [68Ga]Ga-PSMA-11 with a IC50 of 18.5 nM and 5.2 ± 0.2% cell internalization, respectively. All 68Ga-labeled trimeric conjugates showed high metabolic stability in vitro with [68Ga]Ga-9 exhibiting high binding to human serum proteins (> 95%). Small-animal PET imaging revealed a specific tumor uptake of 16.0 ± 1.3% IA g-1 and a kidney uptake of 67.8 ± 8.4% IA g-1 for [68Ga]Ga-9. Clinical PET imaging allowed identification of all lesions detected by [68Ga]Ga-PSMA-11 together with a prolonged blood circulation as well as a significantly lower kidney and higher liver uptake of [68Ga]Ga-9 compared to [68Ga]Ga-PSMA-11.

CONCLUSIONS

Trimerization of the Glu-CO-Lys binding motif for conjugate 9 resulted in a ~ threefold higher binding affinity and cellular uptake as well as in an altered biodistribution profile compared to the control [68Ga]Ga-PSMA-11 due to its intrinsic high binding to serum proteins. To fully elucidate its biodistribution, future studies in combination with long-lived radionuclides, such as 64Cu, are warranted. Its prolonged biological half-life and favorable tumor-to-kidney ratio make this homotrimeric conjugate also a potential candidate for future radiotherapeutic applications in combination with therapeutic radionuclides such as 67Cu.

Visualizing the Tumor Microenvironment: Molecular Imaging Probes Target Extracellular Matrix, Vascular Networks, and Immunosuppressive Cells

The tumor microenvironment (TME) is a critical factor in cancer progression, driving tumor growth, immune evasion, therapeutic resistance, and metastasis. Understanding the dynamic interactions within the TME is essential for advancing cancer management. Molecular imaging provides a non-invasive, real-time, and longitudinal approach to studying the TME, with techniques such as positron emission tomography (PET), magnetic resonance imaging (MRI), and fluorescence imaging offering complementary strengths, including high sensitivity, spatial resolution, and intraoperative precision. Recent advances in imaging probe development have enhanced the ability to target and monitor specific components of the TME, facilitating early cancer diagnosis, therapeutic monitoring, and deeper insights into tumor biology. By integrating these innovations, molecular imaging offers transformative potential for precision oncology, improving diagnostic accuracy and treatment outcomes through a comprehensive assessment of TME dynamics.

Preclinical Study of a Dual-Target Molecular Probe Labeled with 68Ga Targeting SSTR2 and FAP

OBJECTIVE

Currently, 68Ga-labeled somatostatin analogs (SSAs) are the most commonly used imaging agents for patients with neuroendocrine tumors (NETs) in clinical practice, demonstrating good results in tumor diagnosis. For applications in peptide receptor radionuclide therapy (PRRT), targeted drugs should have high tumor uptake and prolonged tumor retention time. To enhance the uptake and retention of tracers in NETs, our goal is to design a 68Ga-labeled heterodimer for optimizing pharmacokinetics and assess whether this form is more efficacious than its monomeric equivalents.

METHODS

Using the somatostatin analog TATE and quinoline-based compound FAPI-46 as raw materials, we designed and synthesized 68Ga-labeled TATE-46. The labeling efficiency and stability were verified by Radio-HPLC. The receptor binding properties and tumor targeting were examined both in vitro and in vivo by using NCI-H727 (SSTR2/FAP, positive) and Mc38 (SSTR2/FAP, negative) cell lines and tumor-bearing mouse models. Preclinical evaluation was performed through cell uptake, pharmacokinetics, Micro PET, and biodistribution studies, and the results were compared with [68Ga]Ga-DOTA-TATE and [68Ga]Ga -FAPI-46. Immunohistochemistry and HE staining were performed on tumor tissues from tumor-bearing mice for further validation.

RESULTS

[68Ga]Ga-TATE-46 showed comparable SSTR2 and FAP targeting ability to monomeric TATE and FAPI-46 in cell uptake and PET imaging studies. [68Ga]Ga-TATE-46 exhibited significantly higher uptake in NCI-H727 (SSTR2/FAP, positive) tumors compared to [68Ga]Ga-DOTA-TATE (p < 0.001) and [68Ga]Ga-FAPI-46 (p < 0.001). No increased uptake of [68Ga]Ga-TATE-46 was observed in MC38 tumors (SSTR2/FAP, negative). Additionally, excess DOTA-TATE and/or unlabeled FAPI-46 significantly blocked the uptake of [68Ga]Ga-TATE-46 in NCI-H727 tumors (p < 0.001), confirming its dual-receptor targeting characteristics. The ex vivo biodistribution, immunofluorescence and immunohistochemistry results were in line with the in vivo imaging findings.

CONCLUSION

Compared with 68Ga-labeled FAPI-46 and DOTA-TATE mono-specific tracers, the dual-target tracer [68Ga]Ga-TATE-46 improves tumor uptake, extends tumor retention, and enhances pharmacokinetics. It is an effective probe for non-invasive detection of tumors expressing FAP and SSTR2, and it is worth further studying its application in the expression of sstr2 and FAP-related tumors.

Comparison Length of Linker in Compound for Nuclear Medicine Targeting Fibroblast Activation Protein as Molecular Target

Novel nuclear medicine therapeutics are being developed by labeling medium-molecular-weight compounds with short-lived alpha-emitting radionuclides. Fibroblast activation protein α (FAPα) is recognized as a highly useful molecular target, and its inhibitor, FAPI, is a compound capable of theranostics, both therapeutic and diagnostic, for cancer treatment. In this study, we compared the functions of two compounds that target FAPα: 211At-FAPI1 and 211At-FAPI2. First, in vitro screening procedures are generally accepted because of the low endogenous expression of FAPα. We suggest the usefulness of this 3D culture system for in vitro screening. Second, when FAPIs are used therapeutically, the expected therapeutic effects are often not achieved. Therefore, we compared the accumulation and excretion in tumor tissues and the anti-tumor effects based on the length of the linker in the compounds. The compounds were rapidly labeled using the Shirakami reaction. Doubling the linker length increased tumor retention. Additionally, the excretion pathway was altered, suggesting a potential reduction in toxicity. Although no significant differences were observed in the anti-tumor effects of 211At-FAPI1 and 211At-FAPI2, it was confirmed that the linker length affects the biological half-life.

Development of fibroblast activation protein-α radiopharmaceuticals: Recent advances and perspectives

Fibroblast activation protein-α (FAP) has emerged as a promising target in the field of radiopharmaceuticals due to its selective expression in cancer-associated fibroblasts (CAFs) and other pathological conditions involving fibrosis and inflammation. Recent advancements have focused on developing FAP-specific radioligands for diagnostic imaging and targeted radionuclide therapy. This perspective summarized the latest progress in FAP radiopharmaceutical development, highlighting novel radioligands, preclinical evaluations, and potential clinical applications. Additionally, we analyzed the advantages and existing problems of targeted FAP radiopharmaceuticals, and discussed the key breakthrough directions of this target, so as to improve the development and conversion of FAP-targeted radiopharmaceuticals.

Trends in cancer imaging

Molecular imaging of cancer is a collaborative endeavor, uniting scientists and physicians from diverse fields. Such collaboration is actively developing and translating cutting-edge molecular imaging approaches to enhance the diagnostic landscape of human malignancies. The advent of positron emission tomography (PET) and PET imaging tracers has realized non-invasive target annotation and tumor characterization at the molecular level. In surgical procedures, novel imaging techniques, such as fluorescence or Cherenkov luminescence, help identify tumors and enhance surgical precision. Simultaneously, progress in imaging equipment, innovative algorithms, and artificial intelligence has opened avenues for next-generation cancer screening and imaging, augmenting the efficiency and accuracy of cancer diagnosis. In this review, we provide a panorama of molecular cancer imaging and ongoing developments in the field.

Recent Clinical Implications of FAPI: Imaging and Therapy

ABSTRACT

The fibroblast activation protein (FAP) is a biomarker that is selectively overexpressed on cancer-associated fibroblasts (CAFs) in various types of tumoral tissues and some nonmalignant diseases, including fibrosis, arthritis, cardiovascular, and metabolic diseases. FAP plays a critical role in tumor microenvironment through facilitating proliferation, invasion, angiogenesis, immunosuppression, and drug resistance. Recent studies reveal that FAP might be regarded as a promising target for cancer diagnosis and treatment. FAP-targeted imaging modalities, especially PET, have shown high sensitivity and specificity in detecting FAP-expressing tumors. FAP-targeted imaging can potentially enhance tumor detection, staging, and monitoring of treatment response, and facilitate the development of personalized treatment strategies. This study provides a comprehensive view of FAP and its function in the pathophysiology of cancer and nonmalignant diseases. It also will discuss the characteristics of radiolabeled FAP inhibitors, particularly those based on small molecules, their recent clinical implications in imaging and therapy, and the associated clinical challenges with them. In addition, we present the results of imaging and biodistribution radiotracer 68 Ga-FAPI-46 in patients with nonmalignant diseases, including interstitial lung disease, primary biliary cirrhosis, and myocardial infarction, who were referred to our department. Our results show that cardiac FAP-targeted imaging can provide a novel potential biomarker for managing left ventricle remodeling. Moreover, this study has been organized and presented in a manner that offers a comprehensive overview of the current status and prospects of FAPI inhibitors in the diagnosis and treatment of diseases.

68Ga/177Lu-Labeled Theranostic Pair for Targeting Fibroblast Activation Protein with Improved Tumor Uptake and Retention

Fibroblast activation protein (FAP) is specifically expressed on cancer-associated fibroblasts in over 90% of tumors and is considered a promising target for cancer theranostics. Here, we developed a novel tracer, DOTA-FAPT, and labeled it with gallium-68 and lutetium-177 as a theranostic pair. [68Ga]Ga/[177Lu]Lu-FAPT exhibited high stability and hydrophilicity, as well as strong affinity to the FAP target. Micro-PET/CT imaging revealed that [68Ga]Ga-FAPT exhibited significantly increased uptake in tumors and extended retention in A549-FAP and U87MG tumor xenografts as compared to [68Ga]Ga-FAPI-04, demonstrating favorable pharmacokinetic characteristics in vivo. Therapeutic studies showed that [177Lu]Lu-FAPT had higher tumor accumulation compared to [177Lu]Lu-FAPI-04, leading to stronger tumor growth inhibition. The first-in-human evaluation also revealed that [68Ga]Ga-FAPT has good in vivo distribution and superior diagnostic efficacy on primary and lymph node metastases in a patient with lung cancer. Our encouraging results suggest that 68Ga/177Lu-labeled DOTA-FAPT is a theranostic pair with broad application prospect.

From biology to the clinic - exploring liver metastasis in prostate cancer

Liver metastases from prostate cancer are associated with an aggressive disease course and poor prognosis. Results from autopsy studies indicate a liver metastasis prevalence of up to 25% in patients with advanced prostate cancer. Population data estimate that ~3-10% of patients with metastatic castration-resistant prostate cancer harbour liver metastases at the baseline, rising to 20-30% in post-treatment cohorts, suggesting that selective pressure imposed by novel therapies might promote metastatic spread to the liver. Liver metastases are associated with more aggressive tumour biology than lung metastases. Molecular profiling of liver lesions showed an enrichment of low androgen receptor, neuroendocrine phenotypes and high genomic instability. Despite advancements in molecular imaging modalities such as prostate-specific membrane antigen PET-CT, and liquid biopsy markers such as circulating tumour DNA, early detection of liver metastases from prostate cancer remains challenging, as both approaches are hampered by false positive and false negative results, impeding the accurate identification of early liver lesions. Current therapeutic strategies showed limited efficacy in this patient population. Emerging targeted radionuclide therapies, metastasis-directed therapy, and novel systemic agents have shown preliminary activity against liver metastases, but require further validation. Treatment with various novel prostate cancer therapies might lead to an increase in the prevalence of liver metastasis, underscoring the urgent need for coordinated efforts across preclinical and clinical researchers to improve characterization, monitoring, and management of liver metastases from prostate cancer. Elucidating molecular drivers of liver tropism and interactions with the liver microenvironment might ultimately help to identify actionable targets to enhance survival in this high-risk patient group.

Preclinical Evaluation of 177Lu-OncoFAP-23, a Multivalent FAP-Targeted Radiopharmaceutical Therapeutic for Solid Tumors

Fibroblast activation protein (FAP) is abundantly expressed in the stroma of most human solid tumors. Clinical-stage radiolabeled FAP ligands are increasingly used as tools for the detection of various cancer lesions. To unleash the full therapeutic potential of FAP-targeting agents, ligands need to remain at the tumor site for several days after administration. We recently described the discovery of OncoFAP, a high-affinity small organic ligand of FAP with a rapid accumulation in tumors and low uptake in healthy tissues in cancer patients. Trimerization of OncoFAP provided a derivative (named TriOncoFAP, or OncoFAP-23) with improved FAP affinity. In this work, we evaluated the tissue biodistribution profile and the therapeutic performance of OncoFAP-23 in tumor-bearing mice. Methods: OncoFAP-23 was radiolabeled with the theranostic radionuclide 177Lu. Preclinical experiments were conducted on mice bearing SK-RC-52.hFAP (BALB/c nude mice) or CT-26.hFAP (BALB/c mice) tumors. 177Lu-OncoFAP and 177Lu-FAP-2286 were included in the biodistribution study as controls. Toxicologic evaluation was performed on Wistar rats and CD1 mice by injecting high doses of OncoFAP-23 or its cold-labeled counterpart, respectively. Results: 177Lu-OncoFAP-23 emerged for its best-in-class biodistribution profile, high and prolonged tumor uptake (i.e., ∼16 percentage injected dose/g at 96 h), and low accumulation in healthy organs, which correlates well with its potent single-agent anticancer activity at low levels of administered radioactivity. Combination treatment with the tumor-targeted interleukin 2 (L19-IL2, a clinical-stage immunocytokine) further expands the therapeutic window of 177Lu-OncoFAP-23 by potentiating its in vivo antitumor activity. Proteomics studies revealed a potent tumor-directed immune response on treatment with the combination. OncoFAP-23 and natLu-OncoFAP-23 exhibited a favorable toxicologic profile, without showing any side effects or signs of toxicity. Conclusion: OncoFAP-23 presents enhanced tumor uptake and tumor retention and low accumulation in healthy organs, findings that correspond to a strongly improved in vivo antitumor efficacy. The data presented in this work support the clinical development of 177Lu-OncoFAP-23 for the treatment of FAP-positive solid tumors.

Development and Evaluation of DOTA-FAPI-Maleimide as a Novel Radiotracer for Tumor Theranostic with Extended Circulation

This study aimed to evaluate a novel albumin-binding strategy for addressing the challenge of insufficient tumor retention of fibroblast activation protein inhibitors (FAPIs). Maleimide, a molecule capable of covalent binding to free thiol groups, was modified to conjugate with FAPI-04 in order to enhance its binding to endogenous albumin, resulting in an extended blood circulation half-life and increased tumor uptake. DOTA-FAPI-maleimide was prepared and radiolabeled with Ga-68 and Lu-177, followed by cellular assays, pharmacokinetic analysis, PET/CT, and SPECT/CT imaging to assess the probe distribution in various tumor-bearing models. Radiolabeling of the modified probe was successfully achieved with a radiochemical yield of over 99% and remained stable for 144 h. Cellular assays showed that the ligand concentration required for 50% inhibition of the probe was 1.20 ± 0.31 nM, and the Kd was 0.70 ± 0.07 nM with a Bmax of 7.94 ± 0.16 fmol/cell, indicative of higher specificity and affinity of DOTA-FAPI-maleimide compared to other FAPI-04 variants. In addition, DOTA-FAPI-maleimide exhibited a persistent blood clearance half-life of 7.11 ± 0.34 h. PET/CT images showed a tumor uptake of 2.20 ± 0.44%ID/g at 0.5 h p.i., with a tumor/muscle ratio of 5.64 in HT-1080-FAP tumor-bearing models. SPECT/CT images demonstrated long-lasting tumor retention. At 24 h p.i., the tumor uptake of [177Lu]Lu-DOTA-FAPI-maleimide reached 5.04 ± 1.67%ID/g, with stable tumor retention of 3.40 ± 1.95%ID/g after 4 days p.i. In conclusion, we developed and evaluated the thiol group-attaching strategy, which significantly extended the circulation and tumor retention of the adapted FAPI tracer. We envision its potential application for clinical cancer theranostics.

FAP Radioligand Linker Optimization Improves Tumor Dose and Tumor-to-Healthy Organ Ratios in 4T1 Syngeneic Model

Fibroblast activation protein (FAP) has attracted considerable attention as a possible target for the radiotherapy of solid tumors. Unfortunately, initial efforts to treat solid tumors with FAP-targeted radionuclides have yielded only modest clinical responses, suggesting that further improvements in the molecular design of FAP-targeted radiopharmaceutical therapies (RPT) are warranted. In this study, we report several advances on the previously described FAP6 radioligand that increase tumor retention and accelerate healthy tissue clearance. Seven FAP6 derivatives with different linkers or albumin binders were synthesized, radiolabeled, and investigated for their effects on binding and cellular uptake. The radioligands were then characterized in 4T1 tumor-bearing Balb/c mice using both single-photon emission computed tomography (SPECT) and ex vivo biodistribution analyses to identify the conjugate with the best tumor retention and tumor-to-healthy organ ratios. The results reveal an optimized FAP6 radioligand that exhibits efficacy and safety properties that potentially justify its translation into the clinic.

Clinical translation of a novel FAPI dimer [68Ga]Ga-LNC1013

Fibroblast activation protein (FAP) has emerged as a highly promising target for cancer diagnostic imaging and targeted radionuclide therapy. To exploit the therapeutic potential of suitably radiolabeled FAP inhibitors (FAPIs), this study presents the design and synthesis of a series of FAPI dimers to increase tumor uptake and retention. Preclinical evaluation and a pilot clinical PET imaging study were conducted to screen the lead compound with the potential for radionuclide therapy.

METHODS

Three new FAPI dimers were synthesized by linking two quinoline-based FAPIs with different spacers. The in vitro binding affinity and preclinical small animal PET imaging of the compounds were compared with their monomeric counterparts, FAPI-04 and FAPI-46. The lead compound, [68Ga]Ga -LNC1013, was then evaluated in a pilot clinical PET imaging study involving seven patients with gastrointestinal cancer.

RESULTS

The three newly synthesized FAPI homodimers had high binding affinity and specificity in vitro and in vivo. Small animal PET imaging and biodistribution studies showed that [68Ga]Ga-LNC1013 had persistent tumor retention for at least 4 h, also higher uptake than the other two dimers and the monomer counterparts, making it the lead compound to enter clinical investigation. In the pilot clinical PET imaging study, seven patients were enrolled. The effective dose of [68Ga]Ga-LNC1013 was 8.24E-03 mSv/MBq. The human biodistribution of [68Ga]Ga-LNC1013 demonstrated prominent tumor uptake and good tumor-to-background contrast. [68Ga]Ga-LNC1013 PET imaging showed potential in capturing primary and metastatic lesions and outperforming 18F-FDG PET in detecting pancreatic and esophageal cancers. The SUVmax for lesions with [68Ga]Ga-FAPI-46 decreased over time, whereas [68Ga]Ga-LNC1013 exhibited persistently high tumor uptake from 1 to 4 h post-injection.

CONCLUSION

Dimerization is an effective strategy to produce FAPI derivatives with favorable tumor uptake, long tumor retention, and imaging contrast over its monomeric counterpart. We demonstrated that [68Ga]Ga-LNC1013, the lead compound without any piperazine moiety, had superior diagnostic potential over [68Ga]Ga-FAPI-46 and 18F-FDG, suggesting the future potential of LNC1013 for radioligand therapy of FAP-positive cancers.

Rational Design and Pharmacomodulation of 18F-Labeled Biotin/FAPI-Conjugated Heterodimers

Due to the complex heterogeneity in different cancer types, the heterodimeric strategy has been intensively practiced to improve the effectiveness of tumor diagnostics. In this study, we developed a series of novel 18F-labeled biotin/FAPI-conjugated heterobivalent radioligands ([18F]AlF-NSFB, [18F]AlF-NSFBP2, and [18F]AlF-NSFBP4), synergistically targeting both fibroblast activation protein (FAP) and biotin receptor (BR), to enhance specific tumor uptake and retention. The in vitro and in vivo biological properties of these dual-targeting tracers were evaluated, with a particular focus on positron emission tomography imaging in A549 and HT1080-FAP tumor-bearing mice. Notably, in comparison to the corresponding FAP-targeted monomer [18F]AlF-NSF, biotin/FAPI-conjugated heterodimers exhibited a high uptake in tumor and prolong retention. In conclusion, as a proof-of-concept study, the findings validated the superiority of biotin/FAPI-conjugated heterodimers and the positive influence of biotin and linker on pharmacokinetics of radioligands. Within them, the bispecific [18F]AlF-NSFBP4 holds significant promise as a candidate for further clinical translational studies.

Rational Design and Comparison of Novel 99mTc-Labeled FAPI Dimers for Visualization of Multiple Tumor Types

Recognizing the significance of SPECT in nuclear medicine and the pivotal role of fibroblast activation protein (FAP) in cancer diagnosis and therapy, this study focuses on the development of 99mTc-labeled dimeric HF2 with high tumor uptake and image contrast. The dimeric HF2 was synthesized and radiolabeled with 99mTc in one pot using various coligands (tricine, TPPTS, EDDA, and TPPMS) to yield [99mTc]Tc-TPPTS-HF2, [99mTc]Tc-EDDA-HF2, and [99mTc]Tc-TPPMS-HF2 dimers. SPECT imaging results indicated that [99mTc]Tc-TPPTS-HF2 exhibited higher tumor uptake and tumor-to-normal tissue (T/NT) ratio than [99mTc]Tc-EDDA-HF2 and [99mTc]Tc-TPPMS-HF2. Notably, [99mTc]Tc-TPPTS-HF2 exhibited remarkable tumor accumulation and retention in HT-1080-FAP and U87-MG tumor-bearing mice, thereby surpassing the monomeric [99mTc]Tc-TPPTS-HF. Moreover, [99mTc]Tc-TPPTS-HF2 achieved acceptable T/NT ratios in the hepatocellular carcinoma patient-derived xenograft (HCC-PDX) model, which provided identifiable contrast and imaging quality. In conclusion, this study presents proof-of-concept research on 99mTc-labeled FAP inhibitor dimers for the visualization of multiple tumor types. Among these candidate compounds, [99mTc]Tc-TPPTS-HF2 showed excellent clinical potential, thereby enriching the SPECT tracer toolbox.

Fibroblast Activation Protein Inhibitor Tracers and Their Preclinical, Translational, and Clinical Status in China

Quinoline-based fibroblast activation protein (FAP) inhibitors (FAPIs) have recently emerged as a focal point in global nuclear medicine, underscored by their promising applications in cancer theranostics and the diagnosis of various nononcological conditions. This review offers an in-depth summary of the existing literature on the evolution and use of FAPI tracers in China, tracing their journey from preclinical to clinical research. Moreover, this review also assesses the diagnostic accuracy of FAPI PET for the most common cancers in China, analyzes its impact on oncologic management paradigms, and investigates the potential of FAP-targeted radionuclide therapy in patients with advanced or metastatic cancer. This review also summarizes studies using FAPI PET for nononcologic disorders in China. Thus, this qualitative overview presents a snapshot of China's engagement with FAPI tracers, aiming to guide future research endeavors.

Development, preclinical evaluation and preliminary dosimetry profiling of SB03178, a first-of-its-kind benzo[h]quinoline-based fibroblast activation protein-α-targeted radiotheranostic for cancer imaging and therapy

Fibroblast activation protein-α (FAP) is a marker of cancer-associated fibroblasts (CAFs) that constitute a significant portion of most carcinomas. Since it plays a critical role in tumor growth and metastasis, its timely detection to identify tumor lesions in early developmental stages using targeted radiopharmaceuticals has gained significant impetus. In the present work, two novel FAP-targeted precursors SB03178 and SB04033 comprising of an atypical benzo[h]quinoline construct were synthesized and either chelated to diagnostic radionuclide gallium-68 or therapeutic radionuclide lutetium-177, with ≥90% radiochemical purities and 22-76% decay-corrected radiochemical yields. natGa-labeled complexes displayed dose-dependent FAP inhibition, with binding potency of natGa-SB03178 being ∼17 times higher than natGa-SB04033. To evaluate their pharmacokinetic profiles, PET imaging and ex vivo biodistribution analyses were executed in FAP-overexpressing HEK293T:hFAP tumor-bearing mice. While both tracers displayed clear tumor visualization that was primarily FAP-arbitrated, with negligible uptake in most peripheral tissues, [68Ga]Ga-SB03178 demonstrated higher tumor uptake and superior tumor-to-background contrast ratios than [68Ga]Ga-SB04033. 177Lu-labeled SB03178 was subjected to tumor retention studies, mouse dosimetry profiling and mouse-to-human dose extrapolations also using the HEK293T:hFAP tumor model. [177Lu]Lu-SB03178 exhibited a combination of high and sustained tumor uptake, with excellent tumor-to-critical organ uptake ratios resulting in a high radiation absorbed dose to the tumor and a low estimated whole-body dose to humans. Our preliminary findings are considerably encouraging to support clinical development of [68Ga]Ga-/[177Lu]Lu-SB03178 theranostic pair for use in a vast majority of FAP-overexpressing neoplasms, particularly carcinomas.

68 Ga-FAPI-04 PET/CT in Assessment of Fibroblast Activation in Keloids : A Prospective Pilot Study

PURPOSE

Keloids are benign fibroproliferative disorders characterized by the massive proliferation of fibroblasts. Fibroblast activation plays a key role in the invasive growth of keloids. Therefore, a prospective pilot study was conducted to explore the value of 68 Ga-FAPI-04 PET/CT in the assessment of keloids activity.

PATIENTS AND METHODS

Twenty-five patients with keloid were enrolled to conduct 68 Ga-FAPI-04 PET/CT. All patients accepted surgery to remove part of the lesions within 1 week. SUV mean and SUV max were measured for semiquantitative analysis and compared with the Vancouver Scar Scale, Laser Speckle Contrast Imaging, pathology, and immunohistochemical stains.

RESULTS

A total of 123 lesions were detected in 25 patients, most of which were distributed in the anterior chest wall. The 68 Ga-FAPI-04 uptake was significantly different at different sites ( P < 0.0001). There was uptake heterogeneity within the keloid lesions, and a significant difference was found between the edge and center of some large lesions. The SUV max of 68 Ga-FAPI-04 showed significantly correlation with the Vancouver Scar Scale ( r = 0.565, P < 0.0001) moderately and the Laser Speckle Contrast Imaging parameters mildly. The SUV max of 68 Ga-FAPI-04 had a moderate correlation with FAPI expression ( r = 0.520, P = 0.022). Moreover, collagen, fibroblast activator protein, and Ki-67 expression were found higher at the edges of keloid tissue than in the center.

CONCLUSIONS

68 Ga-FAPI-04 PET/CT can reflect the distribution characteristics of activated fibroblasts in keloid tissue and may provide a novel method for keloid evaluation for further fibroblast-related therapies.

Development and Characterization of Novel FAP-Targeted Theranostic Pairs: A Bench-to-Bedside Study

Fibroblast activation protein (FAP) is among the most popular targets in nuclear medicine imaging and cancer theranostics. Several small-molecule moieties (FAPI-04, FAPI-46, etc.) are used for developing FAP-targeted theranostic agents. Nonetheless, the circulation time of FAP inhibitors is relatively short, resulting in rapid clearance via kidneys, low tumor uptake, and associated unsatisfactory treatment efficacy. To address the existing drawbacks, we engineered 3 peptides named FD1, FD2, and FD3 with different circulation times through solid-phase peptide synthesis. All the 3 reported peptides bind to human and murine FAP with single-digit nanomolar affinity measured by surface plasmon resonance. The diagnostic and therapeutic potential of the agents labeled with 68Ga and 177Lu was assessed in several tumor models exhibiting different levels of FAP expression. While radiolabeled FD1 was rapidly excreted from kidneys, radiolabeled FD2/FD3 have significantly prolonged circulation, increased tumor uptake, and decreased kidney accumulation. Our findings indicated that [68Ga]Ga-DOTA-FD1 positron emission tomography (PET) effectively detected FAP dynamics, whereas [177Lu]Lu-DOTA-FD2 and [177Lu]Lu-DOTA-FD3 exhibited remarkable therapeutic efficacy in FAP-overexpressing tumor models, including pancreatic cancer cell models characterized by abundant stroma. Moreover, a pilot translational investigation demonstrated that [68Ga]Ga-DOTA-FD1 had the capability to identify both primary and metastatic tumors with precision and distinction. In summary, we developed [68Ga]Ga-DOTA-FD1 for same-day PET imaging of FAP dynamics and [177Lu]Lu-DOTA-FD2 and [177Lu]Lu-DOTA-FD3 for effective radioligand therapy of FAP-overexpressing tumors.

Design, Synthesis, and Evaluation of 18F-Labeled Tracers Targeting Fibroblast Activation Protein for Brain Imaging

Fibroblast activation protein (FAP) is closely related to central nervous system diseases such as stroke and brain tumors, but PET tracers that can be used for brain imaging have not been reported. Here, we designed, synthesized, and evaluated 18F-labeled UAMC1110 derivatives suitable for brain imaging targeting FAP. By substituting the F atom for the H atom on the aromatic ring of compound UAMC1110, 1a-c were designed and prepared. 1a-c were confirmed to have a high affinity for FAP through molecular docking and enzyme assay. [18F]1a-c were successfully prepared and confirmed to have high affinity. The stability in vivo indicates that no obvious metabolites of [18F]1a,b were found in the plasma 1 h after injection, which is beneficial for brain imaging. In vitro cell uptake experiments showed that [18F]1a,b and [68Ga]FAPI04 exhibited similar uptake and internalization rates. PET imaging of U87MG subcutaneous tumor showed that [18F]1a,b could penetrate the blood-brain barrier with higher uptake and longer retention time than [68Ga]FAPI04 (uptake at 62.5 min, 1.06 ± 0.23, 1.09 ± 0.25% ID/g vs 0.21 ± 0.10% ID/g, respectively). The brain-to-blood ratios of [18F]1a,b were better than [68Ga]FAPI04. Biodistribution and PET imaging showed that [18F]1a had better uptake on tumors and a higher tumor-to-muscle ratio than [18F]1b and [68Ga]FAPI04. Further imaging of U87MG intracranial glioma showed that [18F]1a outlined high-contrast gliomas in a short period of time compared to [18F]1b. Therefore, [18F]1a is expected to be useful in the diagnosis of FAP-related brain diseases.