Background
Positron emission tomography (PET) is capable of assessing tumor proliferation quantitatively, non-invasively, and reproducibly [
1]. Proliferation is a key feature of tumor progression and the principal mechanism underlying 3′-deoxy-3′-[
18F]-fluorothymidine (
18F-FLT) PET imaging [
2,
3].
18F-FLT crosses the cell membrane via specific nucleoside transporters [
4]. The principal mechanism underlying
18F-FLT PET imaging is the uptake by proliferating cells of the tracer into the pyrimidine exogenous salvage pathway or endogenous de novo pathway. Aside from phosphorylation in proliferating cells, the compound is metabolically stable in vivo,
18F is not released from FLT and hence the free atom poses no risk of accumulation in sensitive tissues [
5]. However, selective uptake of FLT in the bone marrow, a tissue with a high proliferative rate, has considerably limited investigations on its potential use as a theranostic agent administered intravenously (
i.v.) [
6].
Similar to thymidine,
18F-FLT once internalized into the cytoplasm is phosphorylated into
18F-FLT monophosphate by thymidine kinase 1 (TK1) that has the particularity to become trapped inside the cell without being incorporated into the DNA [
7]. Alternatively, in the de novo synthesis pathway, deoxyuridine monophosphate is converted to thymidine monophosphate by thymidine synthase which can be phosphorylated and incorporated into DNA [
8]. The accumulation of
18F-FLT is dependent on the presence of TK1, which is closely associated with cellular proliferation [
7], and poor prognosis for cancer patients [
9].
18F-FLT has therefore the unique potential to preferably target this group of poor prognosis cancers. Preclinical and clinical studies have demonstrated a considerable interest in
18F-FLT as a PET tracer in breast, lung, and brain cancer imaging [
4,
7,
10‐
12].
18F-FLT PET has been previously shown to provide valuable information for response assessment of tumor therapies [
3,
7], and it has found limited use for tumor therapy follow-up in clinical trials [
8,
13].
18F-FLT tumor uptake is generally lower than that of 2-deoxy-2-[
18F]-fluoro-D-glucose (
18F-FDG), but its selectivity for tumor versus inflammatory cells often makes it a better marker of tumor cells than the glucose analog,
18F-FDG [
7]. Moreover,
18F-FLT showed low uptake in the brain and heart, in contrast to
18F-FDG, confirming its higher tumor specificity [
14]. The only limitation remains the detection and measurement of bone tumors and metastases, due to the high
18F-FLT uptake in healthy bone marrow.
Positron-labeled radionuclides are beginning to be widely used in combined diagnostic and therapeutic applications, which are also known as the theranostic feature of nuclear medicine [
15]. The average kinetic energy of the positron emitted by
18F is about a quarter of that generated by its annihilation [
11]. However, due to the physical properties of
18F radioactive decay, targeted radionuclide therapy (TRT) by emission of the positron is expected to be highly effective, since radiation damage from positrons can be localized within ~ 1 to 2 mm [
11] from their source. On the other hand, the 511 keV photons from annihilation, which provide the tomographic images, have almost a three orders of magnitude longer penetration depth in tissues [
16]. These physical characteristics imply that, in TRT, the dose densities absorbed by the body are negligible compared to that absorbed locally in the targeted cancer cells (i.e., radiation flux decreases as the square of the distance from the annihilation point), unless some tissues express a particularly high uptake, such as the bone marrow [
6] after
i.v. administration.
Moadel et al. investigated cancer cell affinity of PET radiotracers. They have shown, for the first time at a cellular level, the radiotherapeutic potential of
i.v. administration of
18F-FDG [
17,
18]. Although
18F-FDG significantly slowed tumor growth and prolonged survival in comparison with non-treated animals, high cardiac and brain uptakes, as well as an important renal radiotoxicity, were observed, partially offsetting the benefits of this novel approach. This barrier to such a theranostic clinical application could be overcome to a large extent by
18F-FLT. The latter has been developed to accumulate specifically in tumors, proportionally to the proliferation rate of the active cells [
2,
3], and showed low uptake in the brain and heart, compared to
18F-FDG [
14]. Moreover, utilizing
18F-FLT in cancer treatment not only allows improving the determination of tumor prognosis and monitoring tumor response to anti-cancer treatment, but also may offer some advantages of a positron-labeled radiopharmaceutical as a therapeutic agent. Combined with
i.t. injection, these benefits may partly offset the dose delivered to the bone marrow by
18F-FLT.
Here, we investigate the potential of metabolic TRT with
18F-FLT in an animal model of human colon cancer derived from HCT116 cells, which are known to be highly proliferative, when implanted in immuno-deficient mice [
19]. Considering that the therapeutic properties of
18F-FLT may be dependent on the mode of administration, we explore the biodistribution by PET and TRT of
18F-FLT in mice, after direct infusion of the radioactive compound in a primary tumor by convection-enhanced delivery (CED) [
20].
18F-FLT was administered directly into one tumor, while contralateral tumors simulated distant metastases. As a predictive tool in assessing radiotherapy efficacy, tumor uptake was monitored by PET following
18F-FLT and
18F-FDG
i.t. infusion under identical conditions. The results were compared to those obtained from a single 15 Gy dose of external beam radiotherapy (EBRT), considered equivalent to the 25 fractions of 2 Gy [
21] frequently used in cancer treatment. To highlight the full potential of
i.t. 18F-FLT treatment, such comparisons were also made in combination with the chemotherapeutic agent 5FU.
Methods
18F-FDG and 18F-FLT
18F-FDG (CYCLODX, CIUSSS de l’Estrie - Centre Hospitalier Universitaire de Sherbrooke, Canada) and
18F-FLT were prepared by the Sherbrooke Molecular Imaging Center (CIMS, Sherbrooke, Quebec, Canada).
18F-FLT was produced using the protected nosylate precursor and the method of Yun et al. [
22].
Cell culture
The HCT116 human colorectal carcinoma cell line obtained from ATCC was routinely cultured in modified Eagle’s medium (Sigma-Aldrich, Oakville, Canada) supplemented with 10% fetal bovine serum, 2 mM glutamine,1 mM sodium pyruvate, 100 units/ml penicillin, and 100 μM streptomycin in a fully humidified incubator at 37 °C in an atmosphere containing 5% CO2.
Human colorectal cancer xenograft mouse model
Experiments were performed with outbred male nude mice at 4–6 weeks of age (Charles River Laboratories, Saint-Constant, QC, Canada). The animals were maintained in an animal facility, under specific pathogen-free conditions. Housing and all procedures involving animals were performed according to the protocol approved by the Université de Sherbrooke Animal Care and Use Committee (protocol number 235-14B). Human colorectal HCT116 tumor cells (2 × 106, 0.1 mL) were inoculated subcutaneously (s.c.) into each rear thigh and one on the right shoulder. During each animal handling implantation, the animals were anesthetized with an intraperitoneal injection of ketamine/xylazine (87/13 mg/mL) at 1 mL/kg. Tumor size measurements began 1-week post-injection and continued biweekly. Tumor volumes were calculated with the following formula: V (mm3) = π/6 × a (mm) × b2 (mm2), where a and b were the largest and smallest perpendicular tumor diameters, respectively. All experiments began when tumor volumes reached a diameter of about 5–7 mm. The tumor-bearing animals were randomized into different groups of two to four animals each.
Distribution kinetics and tumor clearance of i.t.18F-FLT and 18F-FDG
The animals were anesthetized by inhalation of 1.5% isoflurane and 1.5 L/min oxygen during i.t. injection and PET imaging procedures. The single i.t. infusion of 5 MBq of 18F-FLT or 18F-FDG solution was applied into the tumor on one side of the rear thigh, whereas the contralateral tumors were not treated. The solution was introduced into the central section area of the tumor. For each injection, the needle tip placement was at approximately one-third depth in the tumor along with the needle insertion direction. The leakage of the radiolabeled compound is the main concern for i.t. injection. To avoid this complication, the i.t. infusion was performed at a slow infusion rate (10 μL/min) over 10 min and the needle was left in place within the tumor for about 5 min following completion of the i.t. infusion to reduce any backflow of the 18F-FLT or 18F-FDG solution. Total infusion volume for each tumor was limited to about 30–50% of the tumor volume from caliper measurements, which were determined on the day of the study.
The administration of 18F-FLT or 18F-FDG by i.t. injection was performed with the animal placed inside the scanner, at the start of data acquisition at time 0. Dynamic PET data were acquired in list mode from time 0 to 120 min post-injection using the Triumph/LabPET8™ platform (Gamma Medica, Northridge, CA) at the CIMS.
PET images were reconstructed on a 120 × 120 × 128 matrix with a 0.5 × 0.5 × 0.6 mm3 voxel size using the standard LabPET 3D maximum likelihood expectation maximization algorithm implementing a 3D model of the physical detector response. Frame durations for the reconstructed images were 10 × 1 min, 10 × 5 min, and 4 × 15 min. All PET images were corrected for physical radionuclide decay, dead time, and differences in crystal detection efficiency.
To quantify the radiotracer uptake, regions of interest (ROI) were drawn around tumors, organs, and whole body in the last image frame using the Amide software [
23]. These ROIs were then applied to all frames to obtain time-activity curves (TAC) for each organ. The ROI activity was expressed as percent injected dose per gram of tissue (%IA/g) with the whole body radioactivity measured by PET. The residency time (in hours) for each organ was calculated using decay-uncorrected TAC as follows [
24]:
$$ {\tau}_{\mathrm{h}}=\frac{\underset{0}{\overset{2\mathrm{h}}{\int }}\mathrm{TAC}(t) dt+\mathrm{TAC}\left(2\mathrm{h}\right)\underset{2\mathrm{h}}{\overset{\infty }{\int }}{e}^{-\lambda t} dt}{A_0} $$
where TAC(t) is the activity in the organ at time t, TAC(2 h) is the activity in the organ at the last time point of measurement (2 h), λ is the physical decay constant of 18F, and A0 is the injected activity in the main tumor. Trapezoidal rule was used to numerically integrate the organ TAC over the measurement time, while the analytical integration was performed on the exponential decay term.
In order to assess the radiation burden of 18F-FLT to bone and bone marrow, the uptake of 18F-FLT following i.t. (n = 3) and i.v. (n = 1) administration of 18F-FLT was compared from PET acquisitions by tracing ROI on the forepaw long bones and on the spine. The relative exposure of the bone marrow was estimated from the area under the non-decay-corrected time-activity curves (AUC) extrapolated to infinity with the physical decay of 18F.
Determination of the tumor response after i.t. infusion of 18F-FLT and 18F-FDG radiotherapy and EBRT
In order to determine the dose dependence of tumor response, single i.t. injections of 15 and 25 MBq 18F-FLT or 18F-FDG were administered into the tumor on one side of the rear thigh, whereas the contralateral tumors were left untreated. All experiments began when tumor volumes reached a diameter of about 5–7 mm.
External beam gamma radiation was performed with a 4C Gamma Knife (Elekta Instruments AB, Stockholm, Sweden). A single
i.t. injection of 0.9% saline was administered into the tumor to emulate the radiotracer administration. Mice were anesthetized and positioned in our in-house stereotactic frame designed for the 4C Gamma Knife [
25]. The radiation treatment (15 Gy, dose rate of 3.6 Gy/min) using 8-mm collimators was delivered at predetermined coordinates targeting the tumor. Radiation was applied to the tumor located on one side of the rear thigh, whereas the other side was kept as the non-irradiated control tumor.
Tumor growth was measured after treatment twice a week. Tumor volumes were calculated as described in the mouse model section. Fivefold growth delay (5Td) was considered to be the time required for the tumor volume to increase by a factor of 5, compared to the initial volume at the beginning of treatment. Tumor growth delay (TGD) was calculated by subtracting the 5Td value of the treated group from the 5Td of the control group. An enhancement factor (EF) was also calculated by dividing the 5Td of the treated group by the 5Td of the non-treated control group.
Assessment of absorbed dose from PET imaging by Fricke dosimetry
The mean
18F-FDG activity in different tissues measured in our mouse model by PET imaging was correlated to the absorbed dose assessed in vitro by Fricke dosimetry [
26,
27], as described by Tippayamontri et al. [
28]. Briefly, the dose-response of the Fricke dosimeter and total activity measured by PET were determined at different times for a 3 mL Fricke solution and a 3 mL of deionized water that contained 60 MBq of
18F-FDG. The total absorbed dose in the Fricke solution was assessed at 1450 min. The dose was correlated to the activity measured by PET for the same solution. The characteristics of the LabPET8™ scanner (Gamma Medica) was previously described in [
29]. During the calibration procedure, PET imaging was performed at time 0, 0.5, 1, 2, 3, and 4 h after adding
18F-FDG into the Fricke solution, with scanning times of 3, 5.12, 9.50, 16.24, and 30.06 min, respectively. The optical density and radioactivity were measured prior to and after the PET scans. CT imaging of the vials was performed for attenuation correction of the emission data. The raw data were reconstructed and corrected relative to the reconstructed resolution of the PET scanner. The decay, dead time, random subtraction, and differences in crystal detection efficiencies were also included in the correction factor. A region of interest (ROIs) analysis was carried out with the built-in function in the LabPET image analysis software. The radioactivity in the subject vial (Fisherbrand 15 × 45 mm, 1DR, Fisher Scientific) was obtained as cps/mL from reconstructed PET images. The relationship of absorbed dose (Gy) and time-integrated activity (MBq.h) with administered activity (MBq) is shown in the Additional file
1: Figure S1 and Additional file
2: Figure S2, respectively.
To obtain quantitative radioactivity data with mice, the PET system was calibrated by acquiring data from a mouse phantom filled with an
18F-FDG solution of known radioactivity. Thus, the pixel counts of the PET image in cps/mL could be converted into the activity concentration (MBq/mL) by multiplying the ROIs with known added activity of
18F-FDG. Total accumulated absorbed dose in the tumor tissue and normal organs can be calculated by following Eq.
1.
$$ D\left(\mathrm{Gy}\right)=\breve{A}\left(\mathrm{MBq}.\mathrm{h}/\mathrm{g}\right)\times M\ \left(\mathrm{g}\right)\times C\left(\mathrm{Gy}/\mathrm{MBq}.\mathrm{h}\right) $$
(1)
where:
Ă is the time-integrated activity per gram of tissue (MBq.h/g)
M is the tissue mass (g)
D is the absorbed dose (Gy)
C is the conversion factor of 0.09 Gy/MBq.h, derived from the relationship between Fricke dosimetry and PET imaging (Additional file
3: Conversion factor for absorbed dose estimated by the Fricke chemical primary standard dosimeter).
Prostaglandin E2 quantification by liquid chromatography/tandem mass spectrometry
PGE
2 has been quantified to assess inflammation [
30]. Muscle tissues nearby the irradiated area were extracted and snapped frozen with liquid nitrogen after 4 h of either
i.t. injection of 5 MBq
18F-FLT or 15 Gy gamma irradiation. Tissues were homogenized with a Dounce homogenizer in 2 mL of acetone-saline solution (2:1), containing 10 ng of the internal standard prostaglandin E
2d
4 (PGE
2-d
4), which contains four deuterium atoms at the 3, 3′,4, and 4′ positions (internal standard, Cayman Chemical, Ann Arbor, MI, USA) and 0.05% butylated hydroxytoluene to prevent the oxidation of prostanoids. The homogenate was transferred to a screw-top tube, vortexed for 1 min, and centrifuged (10 min, 1800 g, room temperature). The supernatant was transferred to another tube and mixed with 2 mL hexane by vortexing for 1 min. After centrifugation (10 min, 1800 g, room temperature), the upper phase containing lipids was discarded. The lower phase was acidified with 30 μL of 2 M formic acid and then 2 mL of chloroform containing 0.05% butylated hydroxytoluene were added. The mixture was vortexed and again centrifuged (10 min, 1800 g, room temperature) to separate the two phases. The lower phase containing chloroform was transferred to a conical centrifuge tube for evaporation with a SpeedVac Concentrator (Sarant, Nepean, ON, Canada). Samples were reconstituted in 100 μL methanol:10 mM ammonium acetate buffer, pH 8.5 (70:30), and filtered with Spin-X centrifuge tube filter 0.45 μm (10 min, 1300 g, room temperature). Samples were stored at − 20 °C for later analyses.
PGE
2 was quantified by LC/MS/MS using the same procedure as reported by Desmarais et al. [
31]. Briefly, the apparatus consisted of an API 3000 mass spectrometer (Applied Biosystem, Streesville, ON, Canada) equipped with a Sciex turbo ion spray (AB Sciex, Concord, ON, Canada) and a Shimadzu pump and controller (Columbia, MD, USA). Prostaglandins were chromatographically resolved using a Kromasil column 100-3.5C18, 150 × 2.1 mm (EKa Chemicals, Valleyfields, QC, Canada). A linear acetonitrile gradient from 45 to 90% during 12 min at a flow rate of 200 μL/min was used. The mobile phase consisted of water buffered with 0.05% acetic acid and acetonitrile 90% with acetic acid 0.05%. The injection volume was 10 μL per sample, which were kept at 4 °C during analysis. Individual products were detected using negative ionization and the monitoring of the transition m/z 351 ➔ 271 for PGE
2 and 355 ➔ 275 for PGE
2d
4 with a collision voltage of − 25 V. For quantification of specific ions, the area under the curves was measured.
Mitotic activity assessed by immunohistochemistry of Ki67
Animals were euthanized 4 h after combined i.t. treatment with 5FU and 5 MBq 18F-FLT or 15 Gy gamma irradiation. Tumor samples were removed and fixed in 10% buffered formalin. The 5-μm sections from paraffin-embedded blocks were stained with conventional hematoxylin-eosin.
For Ki67 staining, 5-μm sections from paraffin-embedded blocks were deparaffinized in xylene, rehydrated using graded alcohol, and washed with PBS buffer (pH 7.4). For antigen retrieval, sections were placed in 0.01 M sodium citrate buffer (pH 6.0) for 10 min inside a steamer cooker. Sections were cooled to room temperature and washed with PBS buffer. Endogenous peroxide was blocked by 3% H2O2 for 15 min. Sections were incubated in 10% bovine serum albumin (BSA) for 1 h at room temperature. Thereafter, sections were incubated in overnight at 4 °C with the primary mouse monoclonal antibody Ki67 diluted in 0.5% BSA (PM375 AA Biocare Medical, Concord, California, USA). Sections were treated with the second anti-rabbit antibody (PM375 AA Biocare Medical, Concord, California, USA) diluted in 0.5% BSA for 1 h at room temperature. Diaminobenzidine tetrahydrochloride (0.6 mg/mL in Tris buffer saline, pH 7.6 containing 0.04% hydrogen peroxide) was used to develop the brown color. Methyl green was used to counterstain the slides. A negative control (with primary antibody omitted) was taken along with each batch. Counting of Ki67-positive cells was carried out in ten consecutive fields of 20×. The Ki67 index was estimated by the percentage of Ki67-positive cells in all the counted tumor cells.
Statistical analysis
All statistical analyses were performed using Prism 7.03 for Windows (GraphPad software). All results are reported as mean ± SD. The number of animals ranged from 2 to 4: (control untreated, i.t. 5FU, 15 Gy EBRT, i.t. 5FU + 15 Gy, i.t. 5FU + i.t. 18F-FLT 15 MBq, i.t. 5FU + i.t. 18F-FDG 15 MBq, n = 4), (PET i.t. 18F-FLT, i.t. FLT, i.t. 18F-FDG 15 MBq, untreated distant tumor (i.t. 18F-FLT 10 MBq), n = 3), and (PET i.t. 18F-FDG, i.t. 18F-FLT 15 MBq, i.t. 18F-FLT 25 MBq, n = 2). Statistical analyses were performed as described in the figures and table legends. Ordinary one-way ANOVA with a Dunnett’s multiple comparisons test was used to compare the residence time of 18F-FLT in the infused tumor to that of non-target tissues and to compare the 5Td of the non-treated animal to that of the different experimental groups. Ordinary one-way ANOVA with a Tukey’s multiple comparison test was used to compare the 5TD values of the (i.t. 5FU + 15 Gy EBRT) to those of the (i.t. 5FU + i.t. 18F-FLT 15 MBq) and (i.t. 5FU + i.t. 18F-FDG 15 MBq) groups. Differences were considered statistically significant at p ≤ 0.05.
Discussion
The ratios in Table
3 provide a comparison of the radiospecificity of
18F-FLT and
18F-FDG relative to the kidneys, liver, brain, and heart. The distribution of
18F-FLT after
i.t. injection could be followed by PET imaging in the primary tumor and the contralateral tumors, which simulated distant metastasis sites. We demonstrated that while uptakes were similar in the injected tumor following the
i.t. 18F-FLT and
18F-FDG infusion, only
18F-FLT provided increased accumulation and residence time in distant tumors, coupled with low and slow uptakes in non-targeted organs.
18F-FLT demonstrated a higher specificity for the detection of primary and contralateral tumors than
18F-FDG following
i.t. administration. Indeed, tumor-to-normal tissue ratios for the primary tumor were generally more favorable after
i.t. infusion of
18F-FLT than with
18F-FDG (Table
3). More importantly, all tumor-to-tissue ratios for the contralateral tumors increased over time and were always superior to those of
i.t. 18F-FDG, confirming a higher tumor specificity for
18F-FLT. One should note that the contralateral tumor
18F-FLT residence time, which is predictive of the therapy tumor-absorbed dose, significantly exceeded that of the muscle (
p = 0.0001), brain (
p ≤ 0.0001), and bone (
p = 0.0034); it was also higher than that of the liver and heart, although the difference is not statistically significant for these tissues (Fig.
4). By contrast, the largest residence time for
18F-FDG was found in the brain, bone, kidneys, and heart, which are all particularly sensitive to ionizing radiation.
Table 3
Tumor-to-tissue ratios of 18F-FLT and 18F-FDG at three different times post injection after i.t. infusion of 5 MBq into a single tumor
Kidneys | 30 | 111 ± 45 | 50.2 ± 4.5 | 0.49 ± 0.21 | 0.16 ± 0.04 |
60 | 53 ± 25 | 19.9 ± 0.5 | 0.96 ± 0.48 | 0.18 ± 0.01 |
120 | 23 ± 19 | 14.2 ± 6.3 | 1.56 ± 0.75 | 0.26 ± 0.02 |
Liver | 30 | 162 ± 90 | 135 ± 21 | 0.66 ± 0.19 | 0.41 ± 0.07 |
60 | 69 ± 33 | 71.4 ± 3.4 | 1.17 ± 0.41 | 0.63 ± 0.06 |
120 | 26 ± 17 | 49 ± 14 | 1.84 ± 0.58 | 0.92 ± 0.08 |
Brain | 30 | 1100 ± 656 | 129 ± 41 | 4.42 ± 1.21 | 0.39 ± 0.01 |
60 | 334 ± 207 | 40.8 ± 6.3 | 5.37 ± 1.17 | 0.36 ± 0.04 |
120 | 105 ± 50 | 19.8 ± 6.7 | 7.62 ± 2.04 | 0.36 ± 0.02 |
Heart | 30 | 155 ± 88 | 46 ± 41 | 0.63 ± 0.18 | 0.13 ± 0.08 |
60 | 70 ± 34 | 13.4 ± 13.1 | 1.18 ± 0.37 | 0.11 ± 0.11 |
120 | 28 ± 17 | 3.8 ± 2.8 | 1.96 ± 0.58 | 0.09 ± 0.08 |
As expected,
18F-FLT bone uptake was lower at early times following
i.t. infusion and similar to that of
i.v. administration 2 h after (Fig.
5). However, the difference in radiation exposure as estimated from the area under the extrapolated curves is not statistically significant. Considering the low statistics involved, further studies are needed to evaluate the risk of radiation exposure of the bone marrow following metabolic TRT with
18F-FLT.
Currently, there is a growing interest in the use of nuclear medicine compounds not only for qualitative and quantitative evaluation of oncological pathologies, but also as treating agents [
32]. The present investigations highlight the benefits of PET imaging to predict and measure the
18F-FLT treatment efficacy. The treatment with
i.t. administration of
18F-FLT shows several key advantages compared to EBRT. The local radiation exposure associated with
18F-FLT arises from slowing down of the
18F-emitted positrons, with a mean energy of 250 keV, resulting in an average range in tissue of ~ 1 to 2 mm [
11]. This latter property makes positron emission particularly suitable for local irradiation in the tumor tissue, while preventing damage to healthy tissues. The positrons lose their kinetic energy in tissue in the same manner as electrons [
17], producing along their paths a considerable density of highly reactive ions and secondary low energy electrons [
33]. In addition, “cross-fire” and “bystander” effects could potentiate tumor damage by such short-range positrons [
34]. These unique properties of TRT may contribute to overcome the radio-resistance of solid tumors containing oxygen-deficient hypoxic, as higher radiation dose can potentially be delivered to tumor cells, while still preserving peritumoral healthy tissues.
The risk of radiation-induced late normal tissue injury, caused by chronic oxidative stress or inflammation, limits the dose of radiation that can be delivered safely to cancer patients [
35]. In this study, we observed a low accumulation of
i.t. administered
18F-FLT in healthy tissues and a low level of PGE
2 and inflammation to healthy tissues surrounding the tumor. These data suggest that TRT with this radio-ligand has less off-target effects, making it more attractive for cancer radiotherapy. Moreover,
i.t. infusion of
18F-FLT may allow higher doses of radiation to be locally delivered to target tissues than with EBRT, where the typical dose is in the range from 60 to 80 Gy [
36]. The reported high selective uptake of
18F-FLT in the bone marrow represents a challenge for TRT using this radiopharmaceutical [
6]. However, our results show that with an
i.t. protocol, the radiation exposure is of the same order as for other sensitive tissues such as the brain, heart, and liver. It is also noteworthy that the radiation burden to bone and bone marrow is significantly lower than for
i.t. administration of
18F-FDG.
Previous studies have demonstrated the therapeutic potential of positrons in the colon, breast carcinoma, and lung metastases upon
i.v. or intraperitoneal (
i.p.) injection of
18F-FDG [
17,
37‐
39]. Fang et al. reported an improvement of tumor response in a mouse model, compared to a control group, in colon cancer treated with 55.5 to 222 MBq of
18F-FDG via
i.p. administration. However, no significant difference between treated groups was observed [
38]. In the present study, the dose range of
18F-FLT used in
i.t. injection was an order of magnitude lower than in these earlier studies. Nevertheless, a significant tumor growth delay relative to the control group was observed after
i.t. injection of 15 MBq
18F-FLT. Similar TGDs and EFs were observed for tumors treated with 15 MBq of
18F-FLT and those receiving 15 Gy EBRT. Despite a similar response to treatment, it is somewhat difficult to correlate these two results together. Our experiment with the Fricke dosimeter demonstrated that the radiation dose delivered to the tumor from the
i.t. injection of 15 MBq of
18F-FLT (assuming that all the radiation energy of
18F-FLT remains in the tumor) is received lower than that from EBRT for the same biological effect. Therefore, our results suggest that a therapeutic benefit from direct exposure to positron emitting agents can be achieved with local
18F-radiotherapy.
TRT can be enhanced even further by the concurrent administration of the radiosensitizing agent 5FU [
39]. Tumor cell proliferation assessed by Ki67 labeling index was evaluated based on previous studies [
40] at 4 h post-combined treatment of
i.t. 5FU with either
i.t. injection of
18F-FLT or 15 Gy EBRT (Fig.
8). The concurrent
i.t. administration of the chemotherapeutic agent 5FU with
18F-FLT reduced considerably tumor cell proliferation induced by
18F-FLT even at a suboptimal 5 MBq dose, as compared to the combined treatment of
i.t. 5FU with 15 Gy radiation. Moreover, this combined treatment did not induce any body weight loss in mice at any doses (Table
4), indicating that it was well tolerated. Thus, adding 5FU to
18F-FLT could considerably enhance TGD and EF, without significantly increasing damage to healthy tissues, including the bone marrow.
Table 4
Change in body weight of nude mice after different treatment conditions
Control | 27.0 ± 0.7 | 26.2 ± 2.4 | 29.9 ± 2.2 |
i.t. FLT | 26.5 ± 1.5 | 27.2 ± 1.3 | 30.4 ± 1.6 |
i.t. 18F-FLT 15 MBq | 30.0 ± 1.1 | 28.4 ± 0.5 | 32.7 ± 1.1 |
i.t. 18F-FLT 25 MBq | 27.3 ± 2.2 | 26.7 ± 0.9 | 28.9 ± 2.2 |
15 Gy EBRT | 25.8 ± 2.8 | 26.4 ± 0.5 | 27.9 ± 2.4 |
i.t. 5FU | 26.5 ± 2.9 | 26.0 ± 2.8 | 29.5 ± 4.3 |
i.t. 5FU + 15 Gy EBRT | 23.8 ± 3.4 | 25.6 ± 0.6 | 28.1 ± 1.2 |
i.t. 5FU + i.t. 18F-FLT 15 MBq | 23.1 ± 0.3 | 23.6 ± 0.4 | 24.8 ± 1.0 |
i.t. 18F-FDG 15 MBq | 27.3 ± 1.9 | 28.1 ± 1.6 | 29.9 ± 2.9 |
i.t. 5FU + i.t. 18F-FDG 15 MBq | 30.6 ± 0.8 | 30.0 ± 1.7 | 32.3 ± 1.0 |
i.v. 18F-FLT 10 MBq | 26.8 ± 1.9 | 27.6 ± 0.5 | 29.3 ± 0.6 |
Since local tumor recurrence and metastases are a major concern in cancer treatment, the fast transfer of
18F-FLT from the treated tumor to non-injected tumors may be a significant benefit after
i.t. infusion (Fig.
1) via convection-enhanced delivery (CED) [
20]. This is indicative of fast distribution and circulation rates for
18F-FLT through tumor vascularization and blood circulation. More generally, CED of radiopharmaceuticals in combination with radiosensitizers, such as
18F-FLT and 5FU, may provide a new effective treatment option for localized tumors and their metastases.
Moreover, considering the advances in TRT [
41,
42], other radionuclides bound to molecules capable of reaching preferentially cancer cells could be injected directly into the primary tumor by CED, which is a clinical practice being increasingly applied to chemotherapy [
20]. Recent developments in targeted PET imaging based on metabolism, angiogenesis, receptor-mediated antibodies, etc., may offer promising theranostic options, as already pointed out by others [
43‐
45]. As in the present work, combining CED to the increased cancer cell specificity of these tracers relative to
18F-FDG could widen the range of PET radiopharmaceuticals potentially useful for therapy of not only well-localized tumors, but also their metastases.