Targeted Radionuclide Therapy: New Advances for Improvement of Patient Management and Response

Compared to external beam radiotherapy, targeted radionuclide therapy (TRT) allows for systemic radiation treatment of metastatic lesions. Published work on recent strategies to improve patient management and response to TRT through individualising patient treatment, modifying treatment pharmacokinetics and increasing anticancer potency are discussed in this review, with a special focus on the application of clinically evaluated radiolabelled ligands and peptides in the treatment of neuroendocrine and prostate cancers.


Introduction
There is an unmet need to treat minimal residual disease and micrometastatic spread of tumour cells, as the current cancer treatment options like surgery and external beam radiotherapy are less effective once a tumour has disseminated. Targeted radionuclide therapy (TRT) involves the use of a radio-labelled biologic or other vehicle to target and deliver a cytotoxic amount of radiation to inoperable or disseminated disease by emitting Auger, βor α-particles. In the past five years, three radiopharmaceuticals have been approved by the FDA for clinical use of TRT: Radium-223 ( 223 Ra)-dichloride (Xofigo ® ) for the treatment of metastatic castration-resistant prostate cancer (mCRPC patients) with symptomatic bone metastases without visceral metastases, Lutetium-177 ( 177 Lu)-DOTA-TATE (LUTATHERA ® ) for the treatment of somatostatin receptor-positive (SSTR) gastroenteropancreatic neuroendocrine tumours (NETs) and Iodine-131 ( 131 I)-iobguane (AZEDRA ® ) for the treatment of patients with metastatic pheochromocytoma or paraganglioma. Although today, uncomplicated local or locoregional tumour control can be achieved in many patients, distant relapse rates are still substantial among some groups of patients, opening research avenues for TRT developments.
This Review discusses three main developments for widening the therapeutic index of TRT: Improvement in selection of patient groups who are likely to experience maximum benefit with minimal normal tissue toxicity, modification of radiopharmaceutical pharmacokinetics (PK) to increase tumour uptake and decrease normal tissue uptake and improvements in the anticancer potency of radiopharmaceuticals. These developments will be discussed with a special emphasis on metastatic castration-resistant prostate (mCRPC) and neuroendocrine (NET) cancers.

Developments in Individualisation of Treatment
As TRT becomes more available, clinically heterogeneous patient groups are being treated and there is increasing value in the identification of imaging or metabolic markers to predict tumour The level of uptake in tumour on the baseline, the PET scan has been explored as a predictor of response in SSTR-positive NETs with inconclusive evidence. 68 Ga-DOTATOC measured as standard uptake value (SUV) on baseline PET/CT was correlated with time to progression, however this relationship could not be confirmed in the patient cohort of Soydal et al. [3]. As an alternative, the expression of SSTR quantified by SSTR-PET has been explored as a potential predictor of response to 177 Lu-DOTA-TATE. Werner et al. [4] determined baseline intratumoural SSTR heterogeneity as assessed by SSTR-PET ( 68 Ga-DOTATOC) and concluded that the four heterogeneity parameters of Entropy, Correlation, Short Zone Emphasis and Homogeneity outperform conventional PET parameters, such as mean and maximum standardized uptake value SUV mean/max in distinguishing between responders from non-responders in a retrospective cohort of 142 patients. Werner et al. further showed that an intratumoural textural feature (TF) analysis of a baseline SSTR-PET can differentiate high-risk from low-risk groups of patients with pancreatic NET tumours (pNET) scheduled for peptide receptor radionuclide therapy (PRRT) [5]. Aside from 68 Ga-PET, SPECT scans provide an alternative imaging option. Wetz et al. showed that an 111 In-DTPA0 octreotide SPECT scan of the spatial SSRT distribution in NET metastases as quantified by asphericity was predictive of response to PRRT [6].
In contradistinction to pre-treatment 68 Ga-DOTA-peptide imaging of NET, where the uptake level in the tumour correlates with tumour differentiation, the uptake level in prostate cancer on pre-treatment 68 Ga-PSMA PET/CT reflects the expression of prostate specific membrane antigen (PSMA), which increases as the tumour becomes metastatic and more aggressive. Limited data in the literature have shown prostate cancers with low uptake on 68 Ga-PSMA PET/CT responds poorly to treatment [7].

Patient Clinical Parameters
Patient clinical parameters have also been assessed as predictive biomarkers for the TRT response. Ferdinandus et al. determined that low platelet counts and permanent use of an analgesic medication for bone pain are negative predictors of therapy response to 177 Lu-PSMA-617 among mCRPC patients [8]. In addition to this response, a study by Ahmadzadehar et al. showed prostate-specific antigen (PSA) level was highly predictive of overall survival (OS) following the first cycle [9]. Compared to other clinical parameters of alkaline phosphatase, lactate dehydrogenase and C-reactive protein, a decline in PSA levels of more than 14%, measured two months after the first cycle of TRT was the most important response parameter with regard to OS.
Indices composed of a combination of clinical parameters have been explored as predictive of response to TRT for NET. The 'PRRT predictive quotient' (PPQ) was introduced by Bodei et al. as an attempt to use whole blood gene-expression profiling, tumour grade and circulating Chromogranin A (CgA) levels to predict PRRT responders and non-responders [10]. In a cohort of 72 patients, the PPQ displayed an effectiveness of 95% with responders correctly predicted in 94-97% and non-responders in 93-100% of cases. In an attempt to address the technical and financial barriers to PPQ, Black et al. introduced the inflammation-based index (IBI), derived from the serum C-reactive protein and albumin levels, both markers of systemic inflammation, to predict progression free survival (PFS) and OS of NET patients treated with 177 Lu-DOTA-TATE [11]. Another patient characteristic-based index was reported by Weiner et al. who identified that clinical parameters of lower aspartate transaminase (AST; ≤40 IU/L), lower carcinoembryonic antigen (CEA; ≤20 ng/mL), lower neutrophil-lymphocyte ratio (NLR; <5), and absence of the extrahepatic tumour burden were independently associated with higher OS after yttirum-90 ( 90 Y) hepatic radioembolization in colorectal cancer patients [12].

Patient-Individualised Dosimetry
There are currently no universally accepted standardized protocols for tumour dosimetry, however several centres have successfully integrated dosimetry as part of TRT [13,14]. For a summary of the main dosimetry methodologies for TRT in NET, their drawbacks and appropriate use followed by a structured overview of clinical applications readers are directed to these recent review articles [15,16].
Individualised dosimetry using patient-based radiopharmaceutical biodistribution, tissue densities and anatomical geometry may allow a safe increase of administered activity of 177 Lu-DOTA-TATE in NET patients.
Del Prete et al. compared an empiric, fixed activity treatment protocol (7.4 GBq per cycle) to a personalised patient-specific treatment protocol during a four-cycle course in a retrospective study of 36 NET patients [17]. He found the personalised protocol resulted in an average 1.48-fold increase in cumulative maximum tumour absorbed dose compared to empiric PRRT. In a larger study of 200 NET patients, Garske-Román et al. highlighted the importance of individualised kidney dosimetry in planning 177 Lu-DOTA-TATE treatments [18]. Patients in whom the absorbed dose to the kidneys reached 23 Gy had a longer OS than those in whom it did not. Dosimetric analysis has also been shown to be feasible for concurrent treatment of 177 Lu-DOTA-TATE plus radio-sensitising chemotherapy (capecitabine and temozolomide) [19]. While quantitative SPECT/CT techniques can provide verification of radiation dose delivered from each cycle of PRRT, PET/CT-based dosimetry has the potential for greater quantitative capability for individualised prospective dosimetry due to its comparatively higher resolution. However, the short half-life of 68 Ga-DOTA-TATE is too short to model the retention and clearance kinetics required for accurate dosimetry estimation in individual patients. In a first-in-human prospective trial of 10 NET patients, Hicks et al. showed the utility of 64 Cu-SARTATE as a suitable PET tracer for multiple time-point prospective dosimetry estimation with the quality of images obtained twenty-four hours following 64 Cu-SARTATE being superior to those obtained at 1 hour with 68 Ga-DOTA-TATE [20].

Developments in Modifying Pharmacokinetics
These advancements have focused on increasing tumour uptake and at the same time decreasing uptake in normal healthy tissues that express physiologic levels of the target, and on reducing concentration of the therapeutic radiopharmaceutical in excretory organs such as the kidney.

Albumin Binding
Human serum albumin targeting is ideal for compartmentalising radiopharmaceuticals because the protein is abundant in blood serum, has a long physiologic half-life, and is known to reversibly bind small negatively charged or hydrophobic molecules. This strategy may enable less frequent administration and a reduction in the amount of administered radioactivity compared to the current vehicles. Several pre-clinical studies have shown significantly higher uptake and retention with novel 177 Lu and 90 Y-labelled constructs for albumin binding using an Evans blue (EB) derivative for albumin [21][22][23]. Kuo et al. designed and evaluated a novel albumin-binder-conjugated to PSMA-617 derivative labelled with 177 Lu, 177 Lu-HTK01169 [24]. This was shown in a murine model (LNCaP tumour xenografts expressing PSMA) to have an extended blood retention time, with delivery of an 8.3-fold higher absorbed radiation dose compared to 177 Lu-PSMA-617. In a first-in-human study with eight patients, Zhang et al. showed that 177 Lu-DOTA-EB-TATE extended circulation in the blood and achieved a 7.9-fold increase in tumour dose delivery compared to 177 Lu-DOTA-TATE with no reported adverse symptoms [25]. However, with the enhanced tumour dose from increased circulation time, there was an 18.2-fold increase in red-marrow dose; which decreases the ratio of tumour to dose-limiting organ dose.
A potential drawback to the use of low-molecular-weight small-molecule PSMA inhibitors in the treatment of prostate cancer, relates to their rapid redistribution in the body and localization to the parotid, salivary, and lacrimal glands as well as to the kidney, leading to dose-limiting toxicities. To facilitate prolonged circulation time and greater tumour targeting, a dual-target binding approach, 131 I-RPS-027, using a urea-based ligand with high affinity for PSMA and human serum albumin (HAS) has been proposed [26]. In a preclinical model of prostate cancer 131 I-RPS-027 demonstrated a higher therapeutic index relative to MIP-1095 (a PSMA ligand in current clinical use). 131 I was replaced by the therapeutic radiohalogen 211 At, allowing this ligand to be considered for treatment of prostate cancer by targeted α-therapy.

Antagonists
Somatostatin receptors have been successfully used as targets for both imaging and therapy in patients with NET neoplasia's for over 20 years [27]. A relatively new development is the use of SSTR antagonists, which seem to confer greater specificity, more favourable pharmacokinetics and better tumour visualization than agonists [28]. Recently, two novel agents have been evaluated in the clinical setting: 68 Ga-OPS202 ( 68 Ga-NODAGA-JR11) and 68 Ga-DOTA-JR11 are companion PET imaging agents to a therapeutic counterpart, 177 Lu-OPS201 ( 177 Lu-DOTA-JR11).
The superiority of the SSTR antagonist, 68 Ga-OPS202, over the agonist, 68 Ga-DOTATOC, was first demonstrated in a phase I study and recently confirmed in a prospective phase I/II study [29,30]. Not only did the antagonist have significantly higher lesion-based overall sensitivity than the agonist-based scans: 94% and 88% for 50 µg and 15 µg 68 Ga-OPS202 and 59% for 15 µg 68 Ga-DOTATOC, respectively (p < 0.001), but there were also no significant differences in image contrast, sensitivity, or positive predictive values between the two 68 Ga-OPS202 peptide doses used. The corresponding therapeutic agent, 177 Lu-OPS201, was associated with tumour doses that were 1.7-to 10.6-fold higher than those observed with the SSTR agonist 177 Lu-DOTA-TATE in four patients with metastatic NET [31]. Furthermore, 177 Lu-OPS201 exhibited higher tumour uptake, longer tumour residence time, and improved tumour-to-kidney dose ratio compared to 177 Lu-DOTA-TATE and 90 Y-OPS201 [32]. These findings gave rise to an international multi-centre, open-label study opened in March 2017 with an estimated completion date of May 2022, to evaluate the safety, tolerability, biodistribution, dosimetry and preliminary efficacy of 177 Lu-OPS201 (ClinicalTrials.gov identifier: NCT02592707) in patients with SSTR-positive NET. In addition, the evaluation of the theranostic pair 68 Ga-OPS202 and 177 Lu-OPS201 in patients with SSTR-positive NETs, is currently ongoing in a single centre study (ClinicalTrials.gov identifier: NCT02609737).
In a prospective study, 20 patients with advanced NET were evaluated using another antagonist PET imaging tracer, 68 Ga-DOTA-JR11 [33]. As with 68 Ga-OPS202, 68 Ga-DOTA-JR11 showed rapid tumour uptake, high tumour/background ratios and rapid blood clearance. Interestingly, little or no uptake above background was seen in the pituitary gland, spleen, adrenals and uninvolved liver compared to the known biodistribution of somatostatin receptor agonists. This pattern was also observed with 68 Ga-OPS202 and confirms the potential to improve current imaging and therapy practices for NET. Due to the superior affinity of SSTR antagonists for the receptor compared to agonists, an important aspect that warrants further investigation is the extension of this approach to tumour types with lower SSTR expression that are not currently investigated or treated with SSTR-targeted agents, such as breast, small cell lung, renal and medullary thyroid cancer, non-Hodgkin lymphomas, pheochromocytomas and lung NETs [28].
An interesting new theranostic option for gastrin-releasing peptide receptor (GRPR) positive cancers, is 68 Ga-or 177 Lu-labelled NeoBOMB1, a DOTA coupled GRPR antagonist with high GRPR affinity and in vivo stability [34]. GRPR, also known as bombesin receptor subtype 2, is a G-protein-coupled receptor mostly expressed in organs of the gastrointestinal tract and the pancreas but also in various cancers including breast and prostate cancer. Dalm et al. reported excellent tumour uptake and favourable pharmacokinetics in a human prostate cancer xenograft model in mice [34]. This highlights GRPR as an interesting target for radionuclide therapy of prostate cancer, especially with regards to its low expression in the salivary glands, unlike PSMA, which is known to result in xerostomia. However, one downside of this target is its high expression in low grade prostate cancer compared with high grade tumours, which are a greater challenge for treatment. Never the less, this radiotracer holds promise for imaging and therapy of GRPR-expressing tumours.

Radioprotectors
Protection of normal organs through reduction of off-target uptake allows greater amounts of radioactivity to be delivered, which may increase the efficacy of treatment. For TRT, the kidneys represent a major organ at risk. Kristiannson et al. showed in BALB/c mice that a radical scavenger and antioxidant, human protein α1-microglobulin (A1M), may be used as a radioprotector for kidneys during clinical PRRT with 177 Lu-DOTA-TATE, potentially improving tumour control by allowing higher treatment activities, an increased number of fractions and obviating the need for amino acid infusions [35]. Therapy with radionuclides that emit high linear energy transfer (LET) particles, such as alpha emitters, while increasing the potency of tumour radiation, also exposes normal organs like the kidney and liver to a potentially higher dose of radiation. In a pre-clinical study, Chan et al. demonstrated renal protection in rats bearing AR42J (pancreatic) tumours, as measured by neutrophil gelatinase-associated lipocalin (NGAL) levels, when L-lysine was administered immediately prior to 213 Bi-DOTA-TATE. In a dose escalation study L-Lysine-treated rats experienced prolonged survival compared to those without pre-administration of L-lysine, providing substantial evidence for pharmacological protection to mitigate nephrotoxicity [36].
Salivary gland toxicity is the most common side effect of PSMA-targeted radionuclide therapy, particularly 225 Ac-PSMA therapy. Preventative approaches to mitigate this side effect have included intraglandular injection of botulinum toxin [37] and monosodium glutamate [38].

Developments in Increasing Anticancer Potency
Recent developments to increase the lethality of a radiopharmaceutical once it has been delivered to the tumour have been centred on the use of high LET radiation and combinations with other forms of radiation and pharmaceutical agents.

High LET Radiation
β-emitting radionuclides dominate the scene as far as the targeting of solid tumours in TRT is concerned. However, targeting small metastatic disease presents a challenge as the long physical range (0.2-12 mm) of β-particles results in energy deposition beyond the boundary of small metastases. Systemic targeting with α-particle emitting radionuclides circumvents this range limitation problem, as energy deposition occurs over the same scale range as the dimension of the metastases (40-100 µm). In addition, α-particles confer a greater biological effect, due to the higher energy and LET of α-emissions (50-230 keV/µm) compared to β-particles (0.2 keV/µm).
In recent years, targeting prostate cancer metastasis with high LET α-particles has seen success, with the first integration of an α-emitter, 223 RaCl 2 , into treatment algorithms for patients with mCRPC following publication of the results of the ALSYMPCA trial [39]. Where mCRPC was previously associated with a very poor prognosis, there is now a drive to use α-therapy not only at an earlier stage of the disease but with curative intent [40]. High response rates with limited toxicity have been reported by several authors using the α-emitter, 225 Ac-PSMA [41,42]. PSMA-directed α-therapy in conjunction with synergistic pharmacologic approaches such as inhibitors of DNA double-strand break repair or inhibitors of the androgen receptor may enhance radiation delivery by increasing PSMA expression in tumour cells and potentiating treatment.
The first-in-human experience of 213 Bi-DOTATOC in the treatment of multi-resistant NET tumours that were refractory to 90 Y-/ 177 Lu-DOTATOC showed enduring responses with favourable acute and mid-term toxicity at therapeutic effective doses [43]. This study provided clinical justification for the use of TAT in patients refractory to β-therapy and paved the way for subsequent studies with 225 Ac-DOTATOC using dose escalation to define the maximum tolerated dose (MDT) for single cycle and fractionated delivery [44]. Another α-emitting somatostatin analogue, 212 Pb-DOTAMTATE (AlphaMedix™), is currently being evaluated in subjects with unresectable, metastatic SSTR-positive NETs. A phase 1 trial launched earlier this year (ClinicalTrials.gov NCT number: NCT03466216) aims to assess the safety and dose limiting toxicity using ascending doses of AlphaMedix TM and to assess the pharmacokinetic properties and preliminary effectiveness of the construct.
It is generally acknowledged that mAbs are suboptimal vehicles for α-emitting radionuclides due to a long serum half-life resulting in higher bone marrow toxicity and liver accumulation [45]. Advances in antibody engineering have led to antibody derivatives that are more rapidly cleared from the circulation. In particular, nanobodies-antigen-binding fragments from antibodies of Camelidae, exhibit high affinity and specificity, fast diffusion and clearance kinetics in vivo, high tumour-to-normal-tissue ratios, and good serum stability [46]. The utility of nanobodies has been demonstrated in a recent first-in-human PET study with a GMP-grade 68 Ga-labeled anti-HER2 nanobody in HER2 positive breast carcinoma [47]. This study confirmed the fast clearance of nanobodies in patients, with only 10% of the injected activity remaining in the blood at 1 h p.i. The same group have now developed an 225 Ac conjugated version for therapy and preliminary in vitro results show that 225 Ac-DOTA-Nb is a promising new radio-conjugate for TAT [48].

Combinations with Other Pharmaceuticals
There is a distinct advantage in combining systemically delivered targeted radionuclides and synergistic pharmacologic therapies in an adjuvant setting [49]. This was first proven in the treatment of thyroid cancer, where adjuvant radionuclide therapy in combination with hormone therapy has shown the potential to cure micrometastatic disease [50,51]. This same approach was taken to improve the therapeutic ratio of 223 Ra in the treatment of mCRPC. The ERA-224 trial initiated in 2016 evaluated the efficacy of concurrent administration of 223 Ra dichloride and the antiandrogen, abiraterone acetate, in men with castration-resistant prostate cancer (CRPC) with symptomatic bone metastases (ClinicalTrials. gov identifier: NCT03325127). This trial was the precursor to the design of the adjuvant treatment of Prostate Cancer-ADRAD trial (ClinicalTrials.gov identifier: NCT00653848), where Docetaxel is given prior to 223 Ra. Higher PSMA expression has been seen in tumour cells exposed to anti-hormonal treatment [52,53]. Recently Luckerath and co-workers evaluated this phenomenon in a murine mCRPC model [54]. An androgen receptor blockade (ARB)-mediated increase in PSMA expression was observed with 68 Ga-PSMA11 PET imaging and flow cytometry. However, although pre-treatment with ARB significantly increased DNA damage, it did not translate to a synergistic effect when combined with 177 Lu-PSMA617.
Although 177 Lu-DOTA-TATE is one of the most promising targeted therapeutic options in NET patients, it rarely achieves a cure. Thus, different approaches are being tested to increase efficacy. The recent randomized phase III (NETTER-1) trial, showed a clear clinical advantage for the combination of PRRT, 177 Lu-DOTA-TATE with Octreotide over Octreotide monotherapy for treating patients with unresectable GEP-NETs [27]. However, it is unclear whether the combination of PRRT and somatostatin analogues (SSA) such as Octreotide and Lanreotide provides a survival benefit when compared with PRRT alone. In a retrospective study by Yordanova et al. patients with GEP-NET who underwent PRRT and received SSA as a combination therapy with PRRT and/or as a maintenance therapy showed a significantly higher rate of clinical benefit compared to the PRRT monotherapy [55]. PRRT has also shown durable objective responses in patients with advanced progressive grade 1 or 2 pancreatic neuroendocrine tumours (pNET), who were followed up for a period of 4 years after 4 cycles in a combined 177 Lu-DOTA-TATE-capecitabine-temozolomide regimen [56]. This confirmed the role of PRRT-chemotherapy combinations as an effective outpatient regimen for control of pNET. PARP inhibitors as potentiators of 177 Lu-DOTA-TATE have shown huge potential. In human NET cell lines, PARPi potentiates PRRT via augmenting the downstream effect of 177 Lu-octreotate-induced DNA damage [57]. This was also confirmed in explants of fresh human pancreatic neuroendocrine tissue [58]. As more data emerges, it may soon become common place to administer radionuclide therapy with other systemic therapies such as chemotherapy and immunotherapy.

Combinations with Other Types of Radiation
Several studies have looked at increasing the cytotoxicity of TRT through combination with photon external beam radiation therapy (EBRT) [59,60]. Recently, the impact of scheduling of this type of combination on tumour response has been revisited by Corroyer et al., whose findings emphasized the importance of treatment scheduling according to pathophysiological criteria such as tumour vessel permeability and tumour growth kinetics for TRT-photon EBRT combinations [61]. Melzig et al. found that combining the radiopharmaceuticals 131 I-Benzamide or 131 I-cetuximab with high LET carbon ion radiation increased their cytotoxic effects in in vivo models, B16F10 (melanoma) and A431 (skin epidermoid cancer), respectively [62]. The carbon ions activated the immune-response and the DNA damage and cell-cycle control pathways with marked enhancement of the effect of the TRT agents. Combinations of different radiopharmaceuticals may have a positive impact on response to therapy, although the attendant increased radiation exposure carries the risk of normal tissue side-effects. Ahmadzadehfar et al., however, found that administering repeated cycles of 177 Lu-PSMA-617 for metastatic prostate cancer patients after 223 Ra-dichloride was safe with only a small probability of heamatotoxicity [63].

Future Directions
The chemokine receptor subtype-4 (CXCR4) is an interesting new target for TRT, as it is overexpressed in more than 70% of human solid tumours, including breast, prostate, and cervical cancers and B-cell lymphoma, neuroblastoma, melanoma and gliomas. It also represents an additional molecular target for the theranostic approach in patients with SSTR-negative tumours [64]. The first use of cyclic pentapeptide, 68 Ga-Pentixafor for CXCR4 PET imaging and its therapeutic analog 177 Lu-Pentixather, in a patient with multiple myeloma showed high tumour-to-kidney and tumour-to-liver uptake ratios of 3.1 and 6.4 [65]. In addition, targeting of the tumour micro-environment is emerging as a promising strategy for overcoming heterogeneous intratumoural radiopharmaceutical distribution. Jin et al. proposed the use of 64 Cu-RaftRGD which accumulates in regions of angiogenesis and 64 Cu-ATSM in regions of hypoxic metabolism for glioblastoma [66]. Despite using the same total radioactivity dose of 37 MBq, these authors found the combined use of 64 Cu-RaftRGD and 64 Cu-ATSM to cause more efficient inhibition of tumour growth and tumour cell proliferation, and to prolong survival, than either single agent. Targeting efforts against fibroblast activation protein (FAP) present another promising strategy for targeting of the microenvironment of tumours. FAP is expressed in a subpopulation of stromal cells of many solid tumours, and overexpression is associated with poor prognosis in solid tumours [67]. Using radiolabelled FAP-Inhibitors (FAPI) FAPI-02 and FAPI-04, the Haberkorn group demonstrated proof of concept for the clinical use of 68 Ga-labeled FAPI PET/CT in various cancers with significant lower background uptake in the liver and brain compared to 18 F-FDG [68,69]. In a proof of principal approach, the therapeutic application of FAP inhibitors was demonstrated in a patient with metastasized breast cancer treated with 2.9 GBq 90 Y-FAPI-04, which led to a reduction in pain medication at a considerably low dose [70]. FAP is a molecular target that holds great potential for tumour imaging and therapy.

Conclusions
TRT offers an excellent therapeutic option for many cancer patients. We have paid particular attention in this review to the application of TRT to metastatic NET and prostate cancers, areas that have seen the most promising advances in the last five years. Recent developments have focused on ensuring uptake of a cytotoxic amount of radioactivity into the tumour while minimising the burden on normal healthy tissue through modification of drug specificity and pharmacokinetics. Future avenues of research include incorporation of information about the radiobiological effects of TRT agents into individual dosimetry-based treatment planning.