Abstract
Purpose
Multiple myeloma (MM) remains incurable and its diagnosis relies heavily on bone marrow aspiration and biopsy. CD38 is a glycoprotein highly specific for MM. Antibody therapeutics (e.g., daratumumab) targeting CD38 have shown encouraging efficacy in treating MM, either as a monotherapy agent or in combination with other regimens. However, efficient stratification of patients who might benefit from daratumumab therapy and timely monitoring of the therapeutic responses are still clinical challenges. This work aims to devise a CD38-targeted imaging strategy and assess its value in diagnosing MMs.
Methods
By labeling a CD38-specific single domain antibody (Nb1053) with 68Ga (t1/2 = 1.1 h), we developed a CD38-targeted immuno-positron emission tomography (immunoPET) imaging probe [68Ga]Ga-NOTA-Nb1053. The probe was developed with good radiochemical yield (> 50%), excellent radiochemical purity (> 99%), and immunoreactivity (> 95%). The diagnostic accuracy of the probe was thoroughly investigated in preclinical MM models.
Results
ImmunoPET imaging with [68Ga]Ga-NOTA-Nb1053 specifically depicted all the subcutaneous and orthotopic MM lesions, outperforming the traditional 18F-fluorodeoxyglucose PET and the nonspecific [68Ga]Ga-NOTA-NbGFP immunoPET. More importantly, daratumumab preloading significantly reduced [68Ga]Ga-NOTA-Nb1053 uptake in the disseminated bone lesions, indicating the overlapping targeting epitopes of [68Ga]Ga-NOTA-Nb1053 with that of daratumumab. Furthermore, premedication with sodium maleate or fructose significantly decreased kidney retention of [68Ga]Ga-NOTA-Nb1053 and improved the diagnostic value of the probe in lymphoma models.
Conclusion
This work successfully developed a novel CD38-targeted immunoPET imaging approach that enabled precise visualization of CD38 and diagnosis of MMs. Upon clinical translation, [68Ga]Ga-NOTA-Nb1053 immunoPET may serve as a valuable CD38-targeted molecular imaging toolbox, facilitating early diagnosis of MM and precise assessment of the therapeutic responses.
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Introduction
Multiple myeloma (MM) is a hematological neoplasm of B cell lineage and is characterized by uniform overexpression of CD38 [1]. Daratumumab is a monoclonal antibody (mAb) targeting CD38 and has been approved for treating patients with either newly diagnosed or relapsed/refractory MMs [2]. Several factors synergistically dictate the efficacy of daratumumab, predominantly the CD38 expression levels [3]. Besides efficiently selecting patients before the onset of CD38-targeted therapies, precisely monitoring the therapeutic responses is equally important. At the present stage, flow cytometry examination of the biopsied samples is the only way to detect the CD38 expression. However, the biopsy is invasive and limited to assess the localized myeloma lesion. Moreover, current imaging methods are less robust in detecting and quantifying minimal residual disease (MRD) [4]. To this end, there is an urgent need to develop sensitive new techniques that can noninvasively annotate CD38 expression and describe the response depth following CD38-targeted therapies.
Immuno-positron emission tomography (immunoPET) is a paradigm-shifting molecular imaging technique that can detect human malignancies, inflammatory diseases, and immune cells [5,6,7]. We have developed several immunoPET probes to facilitate the early diagnosis of advanced thyroid cancer and melanoma, among others [8,9,10,11]. In the meanwhile, daratumumab has been radiolabeled for imaging CD38 in preclinical MM models [12, 13], and more recently in clinical trials [14, 15]. However, the size of mAb (150 kDa) exceeds the cutoff value of glomerular filtration (60 kDa) and therefore long-lived radionuclides such as 89Zr (t1/2 = 78.4 h) and 64Cu (t1/2 = 12.7 h) are needed to match the lengthy circulation. Besides, repeated imaging at several time-points is obligatory to yield optimal tumor-to-background ratio (TBR). From a clinical perspective, a feasible and reproducible imaging protocol needs to be established before carrying out mAb-based immunoPET imaging. It should not be neglected that unbound 89Zr is a bone-seeking radiometal [9], potentially compromising the accuracy of 89Zr-mAb in detecting disseminated MMs [14]. In this setting, molecular imaging probes with enhanced stability and smaller size would be more beneficial for clinical translation.
Owing to their smaller size (~15 kDa) and excellent antigen recognition ability, Nanobody (a trade name of Ablynx) or single-domain antibody (sdAb) has emerged as powerful alternatives for molecular imaging [16]. Nanobody-derived immunoPET probes targeting human epidermal growth factor receptor 2 and programmed death ligand-1 have been successfully translated to the bedside [17, 18]. Over the past years, we have been focusing on investigating the catalytic functions of CD38 and developing CD38-targeted therapeutics [19,20,21]. In this process, we produced a CD38-targeting sdAb (i.e., Nb1053) that shares similar binding epitopes with the daratumumab [19], indicating that Nb1053-based molecular imaging probes may select patients suitable for daratumumab treatment. In this work, we aim to develop [68Ga]Ga-NOTA-Nb1053 and characterize the diagnostic value of [68Ga]Ga-NOTA-Nb1053 immunoPET in preclinical MM and lymphoma models.
Materials and methods
Cell lines and flow cytometry
A few solid cancer cell lines (i.e., A375, A549, BCPAP, TPC-1, FTC-133, and THJ-16T) and hematological neoplasm cell lines (i.e., Daudi and MM.1S) were used in the work. All the cell lines were cultured under the recommended protocols. To detect the expression of CD38 on the surface of the included cell lines, flow cytometry was carried out following the protocol we previously described [9, 10]. Briefly, 1 × 106 cells for each sample were collected and washed with cold phosphate-buffered saline (PBS, HyClone). The washed cells were re-suspended in flow cytometry staining buffer (Invitrogen) and incubated with a FITC-conjugated anti-human CD38 monoclonal antibody (Catalog#: 11-0388-42; eBioscience™) on ice for 45 min in the dark, with a concentration of 0.25 μg/mL or 0.5 μg/mL, respectively. The samples were washed again, resuspended in PBS, and analyzed with a CytoFLEX Flow Cytometer (Beckman Coulter, Inc). The results were analyzed with the FlowJo software (FlowJo LLC).
Production and characterization of radiolabeled sdAbs
Production details and sequences of Nb1053 and NbGFP are described in our previous report [19] and in the work by Kubala et al. [22]. Briefly, a llama was immunized with recombinant human CD38 (residue 45–300) and phage display technology was used to obtain the positive clones. The sequences of Nb1053, a positive clone, and NbGFP, a sdAb against the green fluorescent protein (GFP) serving as the negative control, were cloned into pET28a. The proteins with His6-tags were expressed in E. coli BL21 (DE3) and purified by affinity chromatography (Ni-Excel, GE Cytiva) and anion-exchange chromatography (HiTrap Q, GE Cytiva). To facilitate 68Ga-labeling, the sdAbs were first conjugated with a bifunctional chelator 2-S-(4-Isothiocyanatobenzyl)-1,4,7-triazacyclononane-1,4,7-triacetic acid (p-SCN-Bn-NOTA; Macrocyclics). Briefly, 1 mg of sdAb (i.e., Nb1053 or NbGFP) in the PBS was prepared and the pH of the sdAb solution was adjusted to 9.0–10 by adding 0.1 M Na2CO3 buffer. The chelator was freshly dissolved in dimethyl sulfoxide (DMSO) and immediately added to the sdAb solution with a chelator/sdAb molar ratio of 10:1. The reaction was incubated at room temperature for 2 h, followed by purification with equilibrated PD-10 desalting columns (GE Healthcare) and concentration with Amicon™ Ultra Centrifugal Filter (10 kDa, Merck). The concentrated antibody solution was stored at 4 °C and was stable for at least 3 months.
For radiolabeling, 370–555 MBq of freshly eluted 68Ga in 0.1 M hydrogen chloride (pH = 1) was mixed with equal volume of 1 M sodium acetate (pH = 5). The radiometal solution with a final volume of 2 mL (pH = 4.0–4.5) was added to 100–200 μg of NOTA-sdAb, followed by incubation of the mixture at 37 °C for 5–10 min under constant shaking (600 rpm). The final radiopharmaceuticals were purified using equilibrated PD-10 columns and the radiochemical purity was assessed by instant thin-layer chromatography (iTLC; Eckert & Ziegler Radiopharma Inc.) and high-performance liquid chromatography (HPLC; Agilent). Analytical HPLC has been performed with Agilent 1260 Infinity II with a Superdex™ 75 Increase 5/15 GL column (5 × 153–158 mm2, ~9 μm). Absorbance was detected at 280 nm and radioactive signal was detected with an in-line Packard A-100 detector. To assess the immunoreactivity of [68Ga]Ga-NOTA-Nb1053, 200–250 μCi of the probe in 200 μL of PBS was added to 50 μg of recombinant human CD38 protein (CD8-H5224; ACROBiosystems). The binding reaction was incubated for 15 min followed by HPLC analysis with PBS as the mobile phase at a flow rate of 0.5 mL/min.
Subcutaneous and disseminated multiple myeloma models
All animal experimental procedures and protocols had been approved by the Institutional Animal Care and Use Committee (Renji Hospital, School of Medicine, Shanghai Jiao Tong University). To establish subcutaneous and disseminated MM models, the well-recognized MM cell line MM.1S was used [23]. For subcutaneous models, 2 × 106 MM.1S cells were suspended in sterile PBS and matrigel matrix (Corning) with a volume ratio of 1:1 and then injected into the right posterior flanks of female NOD-Prkdcem26Cd52Il2rgem26Cd22/Nju mice (NCG, 4–5 weeks; GemPharmatech). For orthotopic MM models, 0.5 × 106 MM.1S cells in 100 μL of sterile PBS were injected via tail vein to the NCG mice. The subcutaneous and orthotopic models were ready for PET imaging 3 weeks after tumor cell inoculation. For the subcutaneous models, the average diameter of the tumor was 0.6–1.0 cm before imaging.
PET imaging and data analyses
On average, 9.05 ± 3.47 MBq (n = 16) of [68Ga]Ga-NOTA-Nb1053 or 3.31 ± 0.654 MBq (n = 5) of [68Ga]Ga-NOTA-NbGFP was administered to the tumor-bearing NCG mice. For mAb premedication studies, daratumumab (1 mg/mouse; Janssen Biotech, Inc.) was administered to the disseminated MM models 10 h before [68Ga]Ga-NOTA-Nb1053 injection. For one specific disseminated MM model, daratumumab was administered 2 days before injection of the radiotracer. On average, 5.56 ± 0.179 MBq (n = 5) of 18F-fluorodeoxyglucose (18F-FDG) was injected via tail vein to the fasted mice, and images were acquired 1 h after tracer injection. 18F-FDG PET imaging was performed according to a previously reported protocol with minor modification [9]. In the 1-h uptake phase, the fasted mice were warmed and kept awake to reduce brown tissue uptake and minimize unexpected deaths.
To test whether lysine and/or gelofusine could reduce kidney accumulation of [68Ga]Ga-NOTA-Nb1053, nine normal ICR mice (Shanghai SLAC Laboratory Animal Co., Ltd) were randomly divided into three groups: the control group, gelofusine group (150 mg/kg), and gelofusine + lysine group (150 mg/kg of gelofusine and 400 mg/kg of lysine, respectively). The injected activity for each group was 15.5 ± 0.50 MBq (n = 3), 11.41 ± 0.60 MBq (n = 3), and 10.87 ± 0.96 MBq (n = 3), respectively. The effect of mannitol, fructose, and sodium maleate on the kidney accumulation of [68Ga]Ga-NOTA-Nb1053 was further evaluated and compared with another group of control mice [24]. The average injected dose of [68Ga]Ga-NOTA-Nb1053 in these four groups was 2.640 ± 0.6511 MBq (n = 3), 1.092 ± 0.2312 MBq (n = 4), 5.542 ± 1.509 MBq (n = 4), and 6.717 ± 1.211 MBq (n = 3), respectively. The detailed injection information is summarized in Table S1.
The mice were anesthetized and placed in the prone position on the scanning bed. PET/CT data were acquired in sequence with an IRIS PET/CT system (Inviscan Imaging Systems). PET data were reconstructed using a non-scatter-corrected 3D-ordered subset expectation optimization/maximum a posteriori (OSEM3D/MAP) algorithm and subsequently analyzed using the OsiriX Lite software (Pixmeo SARL) and the Inveon Research Workplace (Siemens Preclinical Solutions).
Biodistribution and histopathological studies
After termination of the immunoPET imaging studies, the mice were sacrificed and samples including blood were freshly collected and weighed. The radioactivity of the samples was counted using an automated γ-counter (Perkin-Elmer) and the uptake of the radiotracers in different organs/tissues was calculated and given as percent of injected dose per gram of tissue (%ID/g, mean ± SD).
To rigorously evaluate the tumor burden in the MM models, both subcutaneous tumors and bone tissues (humerus, femur, and tibia) of representative NCG mice were fixed in 10% neutral buffered formalin and used for hematoxylin and eosin (H&E) and immunohistochemistry (IHC) staining. The bone tissues were decalcified in ethylene diamine tetraacetic acid and then processed in a similar way to the subcutaneous tumor samples. Sections of 10 μm were cut and stained for H&E, CD38 (Catalog#: 10818-R128, SinoBiological, and ab183326, Abcam), and CD138 (MCA2459GA, BIO-RAD) using standard protocols. To detect the location of the pre-injected daratumumab (also served as the primary antibody), a horseradish peroxidase (HRP)-labeled rabbit anti-human IgG H&L (ab6759, Abcam) was used as the secondary antibody.
Statistical analysis
Statistical analysis was performed using the GraphPad software. Data are presented as means ± SD as stated in the figure legends. P < 0.05 was considered statistically significant.
Results
Flow cytometry screening
We screened a range of cancer cell lines by flow cytometry and found that CD38 was positively expressed on two hematological malignancy cell lines (MM.1S and Daudi) (Supplemental Fig. 1). In line with the result from a previous work [25], positive expression of CD38 was also found on the A549 cell line. Besides, CD38 was negative on four thyroid cancer cell lines (BCPAP, TPC-1, FTC-133, and THJ-16T) and a melanoma cell line (A375).
Development and characterization of radiotracers
To design immunoPET imaging probes, two sdAbs targeting either GFP or human CD38 were first modified with the chelator NOTA and then radiolabeled with 68Ga (t1/2 = 1.1 h). The non-decay corrected radiolabeling yield of [68Ga]Ga-NOTA-Nb1053 and [68Ga]Ga-NOTA-NbGFP was 47.84 ± 12.2% (n = 8) and 26.43% (n = 1), respectively. The radiochemical purities of the two radiotracers were > 99% and remained >99% in the saline in 3 h (Supplemental Fig. 2). The in vivo stability of these two tracers was tested at different time points post-injection. The results showed that both the tracers were intact at 30 min and 1 h in blood and urine (data not shown). The stability of [68Ga]Ga-NOTA-Nb1053 meets translational requirements because PET imaging with 68Ga-labeled tracers usually finishes within 2 h. As shown by HPLC analysis (Fig. 1), more than 95% of [68Ga]Ga-NOTA-Nb1053 complexed with its target protein CD38 and migrated rapidly than the standalone [68Ga]Ga-NOTA-Nb1053 in the size exclusion chromatography study. The antibody and radioactivity retention time of [68Ga]Ga-NOTA-Nb1053 were 3.506 min and 3.872 min, respectively (Fig. 1a, b). In comparison, the corresponding retention time of [68Ga]Ga-NOTA-Nb1053 incubated with an excess of the extracellular domain of CD38 were 2.646 min and 2.806 min, respectively (Fig. 1c, d). These results together indicated the excellent stability and immunoreactivity of the developed [68Ga]Ga-NOTA-Nb1053, warranting subsequent in vivo imaging studies.
[68Ga]Ga-NOTA-Nb1053 immunoPET imaging of subcutaneous multiple myelomas
The diagnostic value of [68Ga]Ga-NOTA-Nb1053 immunoPET was first interrogated in mice bearing subcutaneous MM.1S xenografts. [68Ga]Ga-NOTA-Nb1053 rapidly accumulated in the tumors with excellent TBR at 1 h post-injection (Fig. 2a). In general, the probe underwent rapid renal clearance, accompanied by moderate hepatobiliary clearance. Region of interest (ROI) analysis of the PET data showed an average tumor uptake of 1.76 ± 0.305 (n = 5) in terms of %ID/g. A comparable liver uptake (2.2 ± 0.16%ID/g, n = 5) and a significantly higher kidney uptake (39.46 ± 11.77%ID/g, n = 5) was derived from the analysis (Fig. 2b). In comparison, uptake in the bone and muscle was exceptionally low, leading to a tumor-to-muscle ratio of 10.90 and a tumor-to-bone ratio of 5.79. Subsequent biodistribution study confirmed the highest uptake in the kidney (187 ± 43.0%ID/g, n = 5), followed by the uptake in the liver (4.77 ± 0.197%ID/g, n = 5) and tumor (3.02 ± 0.509%ID/g, n = 5) (Fig. 2c). Staining of the resected tumor tissue showed prominent membrane expression of CD38 on MM.1S tumor cells (Fig. 2d, e). CD138 is another established biomarker for MM and positive staining of CD138 was also observed on the tumor tissue, confirming the plasmacytic differentiation of the MM.1S cell line (Fig. 2e). The histopathological staining results matched well with the above imaging data and together indicated the good tumor-targeting affinity of [68Ga]Ga-NOTA-Nb1053. The sharp delineation of MM.1S tumors by [68Ga]Ga-NOTA-Nb1053 prompted us to compare its diagnostic value with other nonspecific imaging agents.
[68Ga]Ga-NOTA-NbGFP immunoPET and 18F-FDG PET imaging of subcutaneous multiple myelomas
ImmunoPET imaging with [68Ga]Ga-NOTA-NbGFP, a nonspecific radiotracer targeting GFP, failed to delineate the subcutaneous MM.1S tumors (Fig. 3a). When compared to [68Ga]Ga-NOTA-Nb1053, [68Ga]Ga-NOTA-NbGFP had significantly lower tumor uptake (0.343 ± 0.072%ID/g vs. 1.76 ± 0.305%ID/g, P < 0.0001) and higher liver uptake (5.98 ± 1.29%ID/g vs. 2.2 ± 0.158%ID/g, P = 0.0002). However, the two radiotracers had comparable kidney accumulation based on the ROI analysis (40.3 ± 8.39%ID/g, n = 5 vs. 39.5 ± 11.8%ID/g, n = 5; P = 0.9022; Fig. 3b). Prominent renal and hepatobiliary clearance of [68Ga]Ga-NOTA-NbGFP was further supported by the biodistribution study (Supplemental Fig. 3). After analyzing the biodistribution data, we confirmed that [68Ga]Ga-NOTA-NbGFP had significantly lower tumor uptake than [68Ga]Ga-NOTA-Nb1053 (0.289 ± 0.0437%ID/g, n = 4 vs. 3.02 ± 0.509%ID/g, n = 5; P < 0.0001). Consistently, the kidney had the highest accumulation of [68Ga]Ga-NOTA-Nb1053 (35.4 ± 18.5%ID/g, n = 4), followed by the uptake in the liver (9.10 ± 0.805%ID/g, n = 4). The disparities of kidney uptake of the two radiotracers on the biodistribution data were unknown. We assume that differences in the injection dose and sbAb sequences are potential reasons.
To further show the merits of [68Ga]Ga-NOTA-Nb1053, 18F-FDG PET imaging was carried out in another five subcutaneous MM.1S models. Despite its ability in delineating the tumors with an average uptake of 3.82 ± 0.766%ID/g (n = 5; Fig. 3c), 18F-FDG had high nonspecific uptake in the normal tissues or organs (Fig. 3d), such as the bone marrow, muscle, and brown tissue. The high nonspecific uptake of 18F-FDG resulted in a lower tumor-to-muscle ratio of 1.25 and a tumor-to-bone ratio of 0.39. From a diagnostic perspective, the high bone uptake of 18F-FDG unavoidably impedes accurate diagnosis of disseminated MM diseases. Taken together, [68Ga]Ga-NOTA-Nb1053 showed distinct advantages over [68Ga]Ga-NOTA-NbGFP and 18F-FDG in diagnosing subcutaneous MMs.
[68Ga]Ga-NOTA-Nb1053 immunoPET imaging of disseminated multiple myelomas
Next, we assessed the potency of [68Ga]Ga-NOTA-Nb1053 immunoPET in imaging disseminated (i.e., orthotopic) MMs. [68Ga]Ga-NOTA-Nb1053 immunoPET readily delineated all the bone lesions 3 weeks (data not shown) and 4 weeks after the tumor cell inoculation. Specifically, [68Ga]Ga-NOTA-Nb1053 immunoPET precisely visualized MM lesions in the skull, humeri, sternum, scapulae, vertebrae, femora, tibiae, and pelvis bones (Fig. 4a, b). Quantitative analysis showed that uptake of [68Ga]Ga-NOTA-Nb1053 in the humerus, femur, and tibia was 2.250 ± 0.866%ID/g, 2.625 ± 0.877%ID/g, and 2.325 ± 0.932%ID/g (n = 4), respectively. Premedication with the full-length mAb daratumumab substantially reduced [68Ga]Ga-NOTA-Nb1053 uptake in these involved bones (Fig. 4c, d), with the corresponding uptake of 0.839 ± 0.243%ID/g, 0.712 ± 0.305%ID/g, and 0.580 ± 0.288%ID/g (n = 3), respectively. Interestingly, one subcutaneous MM.1S model developed spontaneous metastases. In this case, [68Ga]Ga-NOTA-Nb1053 immunoPET visualized all the involved bones in addition to the subcutaneous MM.1S tumor. With an interval of 2 days, daratumumab premedication substantially reduced the retention of [68Ga]Ga-NOTA-Nb1053 in the subcutaneous and disseminated MM lesions (Supplemental Fig. 4). Quantitative analysis showed that premedication using daratumumab increased liver uptake of [68Ga]Ga-NOTA-Nb1053, but the increase was not statistically significant (Supplemental Fig. 5). These data demonstrated the efficacy and merits of [68Ga]Ga-NOTA-Nb1053 in imaging disseminated MMs.
H&E staining of a representative humerus showed diffuse bone marrow involvement by plasma cells (Fig. 5a). As illustrated by the IHC staining results (Fig. 5b), the CD138 and CD38 double-positive plasma cells diffusely replaced the normal bone marrow. We then asked if the pre-injected daratumumab dispersed into the bone marrow and bound to the plasma cells. As expected, staining of a representative humerus of the daratumumab treatment group showed bone marrow involvement by massive plasma cells (Fig. 5c). Deposition of daratumumab-bound plasma cells was found in the osteoepiphysis and diaphysis of the humerus (Fig. 5d), indicating the deposition of daratumumab in the disseminated MMs. These results together demonstrated the successful establishment of the orthotopic MM.1S models and the superior accuracy of [68Ga]Ga-NOTA-Nb1053 immunoPET in delineating disseminated MMs.
Strategies reducing kidney accumulation of [68Ga]Ga-NOTA-Nb1053
Although high kidney accumulation of a radioligand may not affect the diagnostic decision, it will cause unexpected nephrotoxicity when the radioligand is used for therapeutic purposes. A recent clinical trial has shown the therapeutic potential of 131I-labeled sdAb [26]. The high kidney accumulation of [68Ga]Ga-NOTA-Nb1053 largely resided in the renal cortex (Fig. 6a), which may still appear when swapping 68Ga with therapeutic radionuclides (e.g., 177Lu). We explored several strategies to circumvent this potential drawback at the diagnostic stage (Supplemental Table 1). It has been reported that co-injection of gelofusine and lysine could reduce kidney uptake [27]. We tested but failed to observe such an effect in our case (Supplemental Fig. 6). The osmotic diuretic mannitol also did not affect the overall and kidney uptake of [68Ga]Ga-NOTA-Nb1053 (Fig. 6b). We further tested the potential role of sodium maleate and fructose in manipulating the kidney uptake, both of which can decrease ATP production in the kidneys. Administration of these two compounds substantially reduced kidney uptake of [68Ga]Ga-NOTA-Nb1053 (Fig. 6c, d). A higher dose of maleate (14.4 mg/mouse compared to 9.6 mg/mouse) more robustly reduced kidney accumulation of [68Ga]Ga-NOTA-Nb1053 (Supplemental Fig. 7) but was associated with severe toxicity.
As revealed by the ROI analysis (Fig. 7a), the kidney uptake in the fructose intervention group and the maleate intervention group was 26.150 ± 7.948%ID/g (n = 4) and 18.725 ± 11.092%ID/g (n = 4), respectively. The uptake in the above two groups was significantly lower than that in the control group (39.100 ± 1.153%ID/g, n = 3) or the mannitol intervention group (39.467 ± 5.918%ID/g, n = 3). Moreover, sodium maleate decreased the kidney accumulation of the radiotracer more prominently than fructose (P = 0.012). These results were further consolidated by the biodistribution studies (Fig. 7b). Intraperitoneal injection of fructose slightly prolonged the circulation of [68Ga]Ga-NOTA-Nb1053 and the retention of the radiotracer in several organs such as the lung, but the increase was not statistically significant compared to the other groups. These data suggest that sodium maleate is preferred when it is necessary to reduce the undesired kidney uptake of radiometal-labeled Nb1053.
Optimized [68Ga]Ga-NOTA-Nb1053 immunoPET imaging of lymphomas
A previous study has indicated the potency of CD38-targeted immunoPET in imaging lymphomas [28]. Our flow cytometry results also revealed positive CD38 expression on Daudi cells. With the above information in mind, we explored the diagnostic utility of [68Ga]Ga-NOTA-Nb1053 immunoPET in lymphoma xenografts in the context of maleate premedication. As shown in Supplemental Fig. 8a, [68Ga]Ga-NOTA-Nb1053 immunoPET readily delineated subcutaneous Daudi tumors. The overall distribution and uptake features of [68Ga]Ga-NOTA-Nb1053 were similar to that observed in the subcutaneous MM.1S models. Owing to the maleate premedication, the kidney uptake reduced substantially in the Daudi models when compared to that in the subcutaneous MM.1S models, with the value dropped from 39.460 ± 11.770%ID/g (n = 5) to 14.167 ± 4.609%ID/g (n = 3) (Supplemental Fig. 8b). The effect of maleate premedication on the kidney uptake of [68Ga]Ga-NOTA-Nb1053 was further confirmed by comparing the biodistribution data of the two groups (Supplemental Fig. 8c), where the kidney uptake decreased more than 3.5 times (52.9 ± 28.9%ID/g [n = 3] vs. 187 ± 43.0%ID/g [n = 5], P = 0.0032). Although tumor uptake of [68Ga]Ga-NOTA-Nb1053 was higher in the Daudi tumors than in the MM.1S tumors based on the biodistribution data (3.43 ± 1.61%ID/g [n = 3] vs. 3.02 ± 0.509%ID/g [n = 5]), the increase was not statistically significant (P = 0.5954). Finally, IHC staining further revealed intense CD38 and CD138 expression on the Daudi tumor (Supplemental Fig. 8d, e), visually more intensive than the staining intensity of the subcutaneous MM.1S tumor (Fig. 2e). These results together demonstrated the value of [68Ga]Ga-NOTA-Nb1053 immunoPET in diagnosing lymphomas and the potency of maleate premedication in optimizing the TBR.
Discussion
Currently, whole-body low-dose computed tomography is preferred for detecting lytic bone lesions and magnetic resonance imaging is the method of choice for detecting bone marrow involvement by MM [29]. 18F-FDG PET is also used to detect MRD [30, 31], but its value is limited when a low hexokinase-2 expression or high background uptake occurs [32]. With the development and future clinical translation of [68Ga]Ga-NOTA-Nb1053, clinicians can detect MM at earlier stages. [68Ga]Ga-NOTA-Nb1053 immunoPET may detect MM-involved bones without obvious bone destruction, allowing for efficient patient stratification and selection. Additionally, this novel imaging approach can help assess treatment response and disease recurrence in a CD38-dependent manner. Different from traditional mAb-based probes, the sdAb-derived [68Ga]Ga-NOTA-Nb1053 will permit same-day imaging with higher TBR. This improvement eliminates the concern of nonspecific bone accumulation in the course of tedious 89Zr-mAb immunoPET imaging [9, 14]. The spleen may not capture sdAbs due to the lack of Fc fragments. Therefore, another potential merit of [68Ga]Ga-NOTA-Nb1053 is that there is no need to administrate unlabeled Nb1053 to saturate the extremely high spleen uptake. As a companion diagnostic tool, [68Ga]Ga-NOTA-Nb1053 immunoPET may optimize CD38-targeted radioimmunotherapy as well [33, 34]. Considering that CD38 is an alternative tumor marker for other hematological malignancies [28], it is rational to expand the application scenarios of [68Ga]Ga-NOTA-Nb1053. Indeed, [68Ga]Ga-NOTA-Nb1053 immunoPET realized the precise diagnosis of lymphomas in the current work, it may also aid in the diagnosis and stratification of other solid tumors [25, 35].
As seen from the data, [68Ga]Ga-NOTA-Nb1053 was largely excreted from the urinary system, reabsorbed in the proximal tubule cells, and degraded by the lysosomes. The metabolic mechanism resulted in the accumulation of the radioactive catabolites in the renal cortex (Fig. 6 and Supplemental Fig. 6). Megalin is an endocytic receptor in the proximal tubule cells and is involved in the reabsorption of proteins and peptides [36]. The plasma expander gelofusine and the positively charged basic amino acid lysine are the targets of megalin. Co-injection of gelofusine and lysine inhibited renal uptake of 99mTc-labeled sdAb [37], but failed to reduce the kidney uptake of 68Ga-NOTA-Nb1053 in our study. Of the several compounds tested, sodium maleate and fructose showed a robust effect in reducing kidney accumulation of [68Ga]Ga-NOTA-Nb1053, presumably by decreasing ATP production in the proximal tubule cells. These observations indicate that different mechanisms are involved in the uptake of differently radiolabeled sdAbs. This knowledge may help develop new strategies to reduce renal retention of Nb1053-derived radioligands and alleviate the nephrotoxicity. We are exploring other strategies (e.g., PEGylation) to increase the tumor uptake while simultaneously reducing the kidney uptake [38]. Besides, our unpublished data showed that 18F-labeled Nb1053 shifted its excretion pathway from the urinary system to the hepatobiliary system. Such improvement is clinically relevant when radiolabeled Nb1053 is used for treatment purposes.
The treatment landscape of MM has incrementally improved in the past three decades. This success was achieved through the clinical use of proteasome inhibitors and immunomodulatory drugs, including the daratumumab. Despite the encouraging results, 40% of MM patients responded poorly to daratumumab treatment. In this setting, [68Ga]Ga-NOTA-Nb1053 immunoPET may help visualize fluctuating CD38 expression, select patients, predict response, and monitor drug resistance. Since Nb1053 competes with daratumumab in binding to CD38, radiotracers binding to CD38 independently of the daratumumab (or isatuximab) will more precisely monitor the dynamic change of CD38 following the antibody therapies [39]. Although the rapid clinical translation of two mAb-based CD38-targeted immunoPET probes [14, 15], the development of immunoPET imaging technique with sdAbs is still in this infancy. We have demonstrated the feasibility of [68Ga]Ga-NOTA-Nb1053 immunoPET in imaging MMs in preclinical models. Clinical translation of this novel CD38-targeted imaging strategy is underway. Along with the progress, we and others have developed B cell maturation antigen (BCMA)-targeting chimeric antigen receptor-modified T (CAR-T) and treatment of relapsed and refractory MMs with CAR-T cell infusion resulted in a revolutionary overall response rate [40]. Therefore, alternative MM biomarkers such as BCMA and CD138 may also be leveraged in developing MM-specific molecular imaging tracers. Development and clinical translation of these state-of-the-art companion diagnostic agents will hopefully improve the clinical management of patients with MM.
To summarize, we have successfully developed [68Ga]Ga-NOTA-Nb1053 and immunoPET imaging with this radiotracer visualized MM niduses with excellent clarity and accuracy.
Data availability
All the raw data and materials involved in the work can be obtained from Prof. Wei upon rational request.
Code availability
Not applicable.
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Acknowledgements
The authors want to thank all the clinical and research staff at the Department of Nuclear Medicine, Renji Hospital, Shanghai Jiao Tong University for their technical assistance and helpful discussions.
Funding
This work was supported in part by the National Key Research and Development Program of China (Grant No. 2020YFA0909000), National Natural Science Foundation of China (Grant Nos. 81771858, 81830052, 81530053, 31871403, and 82001878), Shanghai Key Laboratory of Molecular Imaging (Grant No. 18DZ2260400), Shanghai Rising-Star Program (Grant No. 20QA1406100), Foundation for Basic Research of Science and Technology Project in Shenzhen (Grant No. JCYJ20190808163411340), Construction Project of Shanghai Key Laboratory of Molecular Imaging (Grant No. 18DZ2260400), and Shanghai Municipal Education Commission (Class II Plateau Disciplinary Construction Program of Medical Technology of SUMHS, 2018–2020).
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W. Wei, J. Liu, and Y. J. Zhao collaboratively conceived and designed the project. C. Wang, Y. Chen, W. Wei, Q. Liu, and D. Zhang performed the experiments and wrote most of the manuscript. Y. N. Hou produced the sdAbs and contributed to the writing. S. An, Y. Zhang, and H. Zhao helped in the radiolabeling and characterization of the radiotracers. J. Hou and G. Huang provided inputs in the initial design of the project and revised the manuscript. W. Wei, J. Liu, and Y. J. Zhao supervised the study, revised, and finalized the manuscript.
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W. Wei and J. Liu are co-inventors on a provisional patent application (Application No. 202011131233.7) encompassing the technology described in this manuscript.
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Wang, C., Chen, Y., Hou, Y.N. et al. ImmunoPET imaging of multiple myeloma with [68Ga]Ga-NOTA-Nb1053. Eur J Nucl Med Mol Imaging 48, 2749–2760 (2021). https://doi.org/10.1007/s00259-021-05218-1
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DOI: https://doi.org/10.1007/s00259-021-05218-1