Development and dosimetry of ²⁰³Pb/²¹²Pb-labelled PSMA ligands: bringing “the lead” into PSMA-targeted alpha therapy?

Alpha radiation therapy with the “bone-seeker” ²²³RaCl₂ has been shown to result in a survival benefit in patients with bone metastatic prostate cancer, but its beta-emitting analogue ⁸⁹SrCl₂ shows no such effect [1]. Well in line with these findings, two recent studies have shown higher response rates to ²²⁵Ac-PSMA-617 than to ¹⁷⁷Lu-PSMA-617 [2, 3]. It has already been demonstrated in patients with neuroendocrine tumours that alpha-emitting ²¹³Bi-DOTATOC can overcome resistance to beta-emitting ⁹⁰Y/¹⁷⁷Lu-DOTATOC [4]. Thus, interest in alpha emitter-based radionuclide therapy is increasing. However, there are only a few alpha emitters with an appropriate half-life between hours and days suitable for routine clinical use.

Despite being interesting for research, the short physical half-lives of ²¹³Bi (0.8 h), ²¹²Bi (1.0 h), ¹⁴⁹Tb ( 4.1 h) and ²¹¹At (7.2 h) make their possible clinical application challenging. On the other hand, alpha emitters with long half-lives such as ²²⁷Th (18.7 days), that may be necessary to cope with the slow pharmacokinetics of full-length antibodies, may accumulate in the environment and may be associated with problems related to waste disposal if used on a large scale, e.g. for the treatment of epidemiologically important tumours. We consider that a physical half-life in the range 10 h to 10 days is favourable for clinical routine; this range includes ²¹²Pb (t_½ 10.6 h) and ²²⁵Ac (t_½ 9.9 days). Therefore, we were interested in determining whether ²¹²Pb might be a possible alternative in addition to ²²⁵Ac for PSMA-targeted alpha therapy (PSMA-TαT), a field that is becoming increasingly important.

Fortunately, the pharmacokinetic data needed to estimate the dosimetry of ²¹²Pb-labelled radiopharmaceuticals can be acquired using ²⁰³Pb, which decays by emission of 279 keV gamma rays (80% abundance) that can be imaged in a conventional Anger camera and has a sufficient half-life (52 h) to cover four half-lives of its therapeutic analogue (²¹²Pb; t_½ 10.6 h).

Both 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) and 1,4,7,10-tetra-(2-carbamoyl-methyl)-cyclododecane (TCMC) are known to form stable complexes with lead(II), TCMC at pH >2, DOTA at pH >3.5 [5‐7]. Thus, regarding the physiologically relevant range (i.e. endosomes pH 4.5–6.5, blood pH 7.4), both chelators seem appropriate. DOTA-containing PSMA ligands can also form stable complexes with +3 metals at pH >1–2 [6], and several have already been evaluated [8]. In contrast, TCMC is more specific for Pb²⁺ and has not yet been systematically evaluated in the context of PSMA ligands. However, it has been reported that hydrophobic entities at the chelator or linker moiety can mediate the internalization efficiency of PSMA ligands [9], arousing interest in the evaluation of a new group of PSMA ligands that exploit the lower polarity of TCMC. This chelator could be conjugated to the root structure of PSMA-617 either via an SCN linker or using one of its four coordination arms.

The aim of this work was to develop PSMA ligands containing the chelators p-SCN-Bn-TCMC or DO3AM for labelling with different radioisotopes of lead. Using gamma-emitting ²⁰³Pb as an imaging surrogate, the dosimetry of a hypothetical ²¹²Pb-PSMA-TαT ligand (using our most promising preclinical candidate) was projected.

All solvents and chemicals were purchased from Sigma Aldrich, Merck KGaA, Iris Biotech, or CheMatech, and used without further purification.

The aim of this work was to develop PSMA ligands containing the chelators p-SCN-Bn-TCMC or DO3AM suitable for labelling with different isotopes of lead. Except the chelator, the ligands follow the lead structure of PSMA-617 [8] which belongs to the class Glu-ureido PSMA inhibitors bearing the 2-naphthylalanine and cyclohexanecarboxylic acid linker, to target the catalytic domain of PSMA [17] and to interact favourably with its lipophilic accessory pocket [18] and arene-binding site [19]. The development of PSMA-617 and its favourable interaction with the PSMA protein crystal has recently been reviewed [20, 21]. However, the optimal hydrophilicity of the chelator region has not yet been systematically elaborated.

In vitro all new ligands show low two-digit nanomolar affinity, slightly inferior to the single-digit affinity of the reference compound PSMA-617 [8]. Nevertheless, comparison of PSMA-10 and PSMA-11 has already demonstrated that (once a sufficient level has been reached) moderate differences in affinity alone are not sufficient to predict the respective in vivo performance of one particular high-affinity ligand [22]. Another important parameter for the therapeutic appropriateness of a ligand, especially with a radiolabel that decays through unstable daughter nuclides, is internalization. ²⁰³Pb-CA009 and ²⁰³Pb-CA012 were specifically internalized with uptake values of approximately 27%ID and 16%ID per 10⁶cells, comparable to the 18%ID per 10⁶cells that we have previously determined for ¹⁷⁷Lu-PSMA-617 [8].

In mice, ²⁰³Pb-PSMA-CA012 was found to be the most promising of our candidates and showed a high tumour uptake of 8.4 ± 3.7%ID/g at 1 h after injection, which is nearly identical to the tumour uptake of 8.5 ± 4.1%ID/g reported for ⁶⁸Ga-PSMA-617 [8]. The early kidney accumulation of CA012 at 1 h after injection was markedly lower (5.1 ± 2.5%ID/g) than that of PSMA-617 (113.3 ± 24.4%ID/g); however, this advantage was less after 24 h (CA012 2%, PSMA-617 1%). Thus, regarding a possible clinical benefit, the dedicated combination of CA012 and a short half-life nuclide such as ²¹²Pb is most promising.

In humans, the accuracy of our dosimetry estimate was limited by the low count rate that could be achieved with the injected 250–300 MBq ²⁰³Pb-CA012. Consequently, we were only able to assess the activity distribution on planar scans and not on SPECT scans. It is reasonable that without any clinical data available in the first-in-human studies, the activities had to be chosen very cautiously. However, our preliminary (i.e. planar) dosimetry estimate, with an effective dose of 2.4 mSv per 100 MBq ²⁰³Pb-CA012, suggest that it would be reasonable to inject up to 750 MBq (approximately 18 mSv effective dose) in future dosimetry studies. These studies could then use the SPECT technique, which allows volume segmentation of activity and would also make the application of other techniques suggested for state-of-the-art dosimetry studies reasonable [23].

The extrapolation of the dosimetry from diagnostic ²⁰³Pb-CA012 to therapeutic ²¹²Pb-CA012 also has limitations: The most relevant uncertainty of the model used is the simplification that the residence time of ²¹²Pb-CA012 can be forwarded directly to all daughter nuclides, neglecting the possibility of interim translocation. As illustrated in Fig. 2, the initial beta decay of ²¹²Pb-CA012 – only the location of this decay step is perfectly traced by the gamma emission from the imaging surrogate ²⁰³Pb-CA012 – contributes less than 1% to the summed dose of the whole ²¹²Pb decay chain, which is dominated by the alpha emissions from the succeeding daughter nuclides. Although DOTA and TCMA form stable complexes with both lead(II) and bismuth(III) isotopes and the recoil beta emission is negligible in comparison to alpha emission, it has been reported that during the decay from ²¹²Pb to ²¹²Bi, 36% of the daughter nuclide can be lost from the chelator [24].

Therefore, it is mandatory that our projected dosimetry approximations are verified before moving forward from ²⁰³Pb to ²¹²Pb in future studies. As the effect of losing daughter nuclides from the chelator complex and redistribution according to the inherent characteristics of these elements is most relevant during the extracellular circulation phase, organs from mice or blood samples from patients treated with ²¹²Pb-CA012 should be characterized in vitro regarding the ratio of complexed lead and free bismuth. However, due to the rapid tumour targeting and fast internalization of low molecular weight PSMA ligands, the circulation time is much shorter than that of full-length antibodies evaluated for radioimmunotherapy [8, 25, 26].

Once internalized, precipitation with organic anions from cytosolic proteins may sufficiently decelerate the efflux of metal ions and even the 1-h half-life of ²¹²Bi might be short enough to consider most (but presumably not all) of it “functionally trapped”. Due to the extremely short half-life of ²¹²Po (0.3 μs) and the physiological intracellular accumulation of ²⁰⁸Tl (t_½ 3.1 min; due to its rapid intracellular accumulation ²⁰¹Tl is even used in perfusion scintigraphy [27]), it is reasonable to assume that translocation of the intracellularly generated succeeding daughter nuclides is of secondary relevance or even negligible. At this point it should be mentioned, that more than 50 patients have already been successfully treated with ²²⁵Ac-PSMA-617, even though ²²⁵Ac decays with four alpha and two beta decays, which make the possible translocation of its various daughter nuclides an even more critical issue in comparison to ²¹²Pb [3, 28]. ²²³RaCl₂, another radiopharmaceutical with several daughter nuclides, targets the extracellular bone matrix and the first decay product, ²¹⁹Rn, is a freely diffusible inert gas with a half-life of 4.0 s. However, mobility and diffusion back to the systemic circulation were not relevant issues even for extracellularly generated decay products [29]. As even 1.11 MBq of free ²¹²Pb could be injected into mice with body weights in the range 19–28 g without relevant toxicity on days 7 and 90 [30], there are remarkable safety margins regarding the in vivo stability of the lead complex and some redistribution of daughter radionuclides.

The clinical value of dosimetry modelling of therapeutic radiopharmaceuticals is that it provides an approximation of their maximum tolerable doses (MTD) that would allow empirical dose-escalation trials to be shortened or eventually even omitted. With the clinical introduction of alpha emitters, we are now facing new challenges because historically the tolerance limits of normal tissue reported in gray have been evaluated using beta and gamma radiation, and due to different RBEs of alpha emitters these thresholds are not valid if the physically exact unit for the absorbed dose (gray) is applied directly. Regarding statistical radiation effects a weighting factor of 20 is recommended for converting to the equivalent dose in sieverts. However, we want to predict antitumour activity and side effects, i.e. deterministic radiation effects, and no generally accepted nomenclature for this kind of equivalent dose is yet available.

As all alpha emitters considered clinically have different ratios of alpha, beta and gamma emissions, it does not make sense to report summed absorbed doses in gray, because it does not seem practicable to apply one weighting factor to a mixture of various, biologically different, kinds of radiation. Thus, we recently introduced a proprietary metric in which the absorbed doses of alpha, beta and gamma radiation are first multiplied by their most appropriate weighting factor and then summed. The correction factors used are provided as indices. However, we have to emphasize that the RBE is not a formal SI unit. Also the RBE factor of 5 for alpha radiation reflects only an average factor found in the literature [13, 14] and individual results can vary. Nevertheless, this concept has already been used to project the MTD of ²²⁵Ac-PSMA-617 [2] and ²¹³Bi-PSMA-617 [16]. The results of empirical dose escalation accompanying the clinical translation of ²²⁵Ac-PSMA-617 [2] and the successful clinical application of ²¹³Bi-PSMA-617 [31] without the need for amending empirical data have confirmed the practical usefulness of this approach.

In using the RBE5 metric to compare the dosimetry approximations of ²¹²Pb-CA012 with those of ²¹³Bi-PSMA-617 and ²²⁵Ac-PSMA-617 (Table 3), we assume that the MTD of ²¹²Pb-CA012 would be approximately 150 MBq per cycle regarding acute haematological toxicity and xerostomia, while the cumulative dose to the kidneys, the dose-limiting organ, could be about 400–600 MBq. However, due to the methodological limitations discussed, these approximations are still preliminary, and we need more experience with other nuclide/tracer combinations and long-term follow-up regarding delayed toxicities to refine our model. Presently, an empirical phase 2 study still appears necessary to evaluate the dose range between 50 and 150 MBq for single doses of ²¹²Pb-CA012. ²¹²Pb-TCMC-trastuzumab is so far the only ²¹²Pb-labelled radiopharmaceutical to have been evaluated in a formal clinical trial [32, 33], but it is administered intraperitoneally, and there is neither a strong demand for imaging-based dosimetry, nor can the development of a systemically administered radiopharmaceutical be guided by dose escalation of this local therapy. However, other small molecules, e.g. for therapy of melanoma [34, 35] and neuroendocrine tumours [36], are currently on the way to clinical translation, and due to their encouraging fast pharmacokinetics they are considered suitable candidates for labelling with ²¹²Pb.

Comparing the potentially achievable tumour absorbed doses of ²¹²Pb-CA012 with those of other alpha emitter-labelled PSMA ligands (Table 3), there seems to be a small advantage for ²²⁵Ac-PSMA-617. However, taking into account the limited precision of our planar dosimetry especially for small metastases, the random error related to the fact that data were obtained from only two patients, and the still limited knowledge about the potential impact of different dose rates, it is too early to draw a final conclusion.

In summary, due to the theoretically well scalable on-demand production of ²⁰³Pb in cyclotrons and of ²¹²Pb from ²²⁴Ra generators [37] and after demonstration of automated cassette-based labelling procedures suitable for clinical use [38], the ²⁰³Pb/²¹²Pb tandem approach is a reasonable option for overcoming the current supply limitation of appropriate medical alpha emitters.