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Tumor-Targeted Polydopamine-Based Nanoparticles for Multimodal Mapping Following Photothermal Therapy of Metastatic Lymph Nodes
Authors Liang Y , Guo W, Li C, Shen G, Tan H , Sun P, Chen Z, Huang H, Li Z, Li Z, Ren Y, Li G, Hu Y
Received 5 May 2022
Accepted for publication 7 September 2022
Published 29 September 2022 Volume 2022:17 Pages 4659—4675
DOI https://doi.org/10.2147/IJN.S367975
Checked for plagiarism Yes
Review by Single anonymous peer review
Peer reviewer comments 2
Editor who approved publication: Prof. Dr. Anderson Oliveira Lobo
Yanrui Liang,1,* Weihong Guo,1,* Chuangji Li,1,* Guodong Shen,1,* Haoxian Tan,2 Peiwen Sun,2 Zhian Chen,1 Huilin Huang,1 Zhenhao Li,1 Zhenyuan Li,1 Yingxin Ren,1 Guoxin Li,1 Yanfeng Hu1
1Department of General Surgery & Guangdong Provincial Key Laboratory of Precision Medicine for Gastrointestinal Tumor, Nanfang Hospital, Southern Medical University, Guangzhou, People’s Republic of China; 2The First School of Clinical Medicine, Southern Medical University, Guangzhou, People’s Republic of China
*These authors contributed equally to this work
Correspondence: Guoxin Li; Yanfeng Hu, Department of General Surgery & Guangdong Provincial Key Laboratory of Precision Medicine for Gastrointestinal Tumor, Nanfang Hospital, Southern Medical University, No. 1838 North Guangzhou Ave, Baiyun District, Guangzhou, 510515, People’s Republic of China, Tel +86-20-6164-1681 ; +86-20-6164-1682, Fax +86-20-6164-1681, Email [email protected]; [email protected]
Purpose: Lymphadenectomy with lymph node (LN) mapping is essential for surgical removal of solid tumors. Existing agents do not provide accurate multimodal mapping and antitumor therapy for metastatic LNs; therefore, we fabricated a polydopamine (PDA) nanoparticle (NP)-based tumor-targeted LN mapping agent capable of multimodal mapping and guided photothermal therapy (PTT) for metastatic LNs.
Materials and Methods: PDA NPs modified with polyethylene glycol (PEG) were obtained by polymerization under alkaline conditions. The PEG-PDA NPs were loaded with the circular tripeptide Arg-Gly-Asp (cRGD) to achieve tumor-targeting capacity and with the fluorescent dye IR820 and magnetic resonance imaging (MRI) contrast Gd(NH2)2 for in situ detection. The resulting cRGD-PEG-PDA@IR820/Gd(NH2)2 (cRGD-PPIG) NPs were tested for their biosafety and metastatic LN mapping ability. They were drained specifically into LNs and selectively taken up by gastric MKN45 cells via αvβ 3 integrin-mediated endocytosis.
Results: This phenomenon enabled MR/optical/near-infrared fluorescence multimodal metastatic LN mapping, guiding the creation of accurate and highly efficient PTT for gastric cancer metastatic LNs in mice.
Conclusion: In summary, we fabricated tumor-targeted cRGD-PPIG NPs with MR/optical/near-infrared fluorescence multimodal metastatic LN mapping capacity for surgery and efficient PTT guidance post-surgery.
Keywords: multimodal imaging, lymph node mapping, metastatic lymph node, photothermal therapy
Introduction
Cancer is one of the main global public health issues, with 24.5 billion cases and 9.6 million deaths reported worldwide in 2017.1 Radical lymphadenectomy is essential for solid tumor removal, but to succeed, it requires perioperative visualization and identification of lymph nodes (LNs).2–5 LN mapping is important for gastrointestinal tumors, owing to the complex lymphatic drainage system of the digestive tract.6 Patient prognosis is improved if more LNs, especially metastatic LNs, are resected.7–9 Thus, targeted metastatic LN mapping and treatment should be more accurate and efficient.
Several methods have been applied to map LNs. Magnetic resonance imaging (MRI) has been widely used to diagnose LNs before surgery due to the sensitivity of the technique to soft tissue lesions.10,11 Primary and metastatic lesions show an increase in signal intensity on diffusion-weighted imaging compared to normal structures.12 Dyes such as nanocarbon particles and indocyanine green are used during surgery to visualize LNs. Nanocarbon particles enable convenient optical imaging of LNs, whereas indocyanine green can stain both LNs and the lymphatic route.13–16 Nevertheless, existing LN mapping agents have intrinsic defects, which limit their clinical application. First, the lack of a multimodal LN mapping ability lowers the accuracy.17 Second, the lack of tumor-targeting ability prevents their use in precision medicine.18 Finally, the lack of therapeutic effects hinders their clinical application.19 Thus, a tumor-targeted multimodal LN mapping agent is required to successfully integrate the diagnosis and treatment of solid tumors.
The clinical requirements of LN mapping agents may be met through nanotechnology, as suggested by the numerous nanoprobes designed for multimodal LN mapping and treatment. Yang et al20 designed perylene diimide probes of different sizes for LN positron emission tomography and photoacoustic imaging. Shi et al19 designed tumor-targeted CuS nanoparticles (NPs) for LN fluorescence/computed tomography imaging and guided photothermal therapy (PTT). Ideally, to facilitate greater convenience in clinical applications, multimodal imaging should include optical imaging, for which NPs with a natural black color may be good candidates. Polydopamine (PDA) NPs, with their non-toxic semiconducting dopamine molecules, have emerged as a promising and powerful nanoplatform with broad biological application prospects.21 Owing to their relevant physicochemical properties, such as coloration,22 easy functionalization,23 elevated drug loading efficacy,24 high metal-chelation ability,25 and ultrafast thermal relaxation,26 PDA NPs have been widely applied in tumor imaging. Furthermore, PDA NPs of different sizes can be easily obtained by adjusting the pH during dopamine self-assembly.27,28
In this study, we aimed to produce multimodal NPs that can meet the requirements for accuracy, efficacy, and ease of use necessary in clinical tumor imaging. We synthesized PDA-based NPs containing polyethylene glycol (PEG), a tumor-targeted ligand consisting of a circular-arginine-glycine-aspartic acid sequence (cRGD), a near-infrared (NIR) organic dye (IR820) and clinical MRI contrast Gd(NH2)2. The size of the resulting cRGD- PEG-PDA@IR820/Gd(NH2)2 (cRGD-PPIG) NPs (50–250 nm) aided specific draining into lymph vessels rather than the bloodstream, as reported previously.28,29 Owing to their coloration and good photothermal conversion efficiency, PDA NPs were employed as probes for the optical diagnosis of metastatic LNs and PTT. In addition, PDA NPs loaded with Gd(NH2)2 and IR820 were used for metastatic LN MR and fluorescence imaging. Essentially, this study demonstrates the application of PDA NPs for MR/optical/NIR fluorescence multimodal tumor-targeted LN mapping and PTT.
Materials and Methods
Chemistry
Reagents and Instrumentation
Dopamine hydrochloride (98%; Aladdin, Shanghai, China), gadodiamide (Gd(NH2)2, OMNISCAN, GE Healthcare, Cork, Ireland), and IR820 (C46H50ClN2NaO6S2, 80%; Macklin, Shanghai, China) were purchased from Casmart and Rjmart platforms. The cRGD ligand and PEG (NH2-mPEG-COOH, MW 5000, 98%) were purchased from Guangzhou Tanshui Co., Ltd. (Guangzhou, China). Fetal bovine serum (FBS), Dulbecco’s modified Eagle medium (DMEM), penicillin-streptomycin solution, and trypsin-EDTA were obtained from Thermo Fisher Scientific (Waltham, MA, USA). Phosphate-buffered saline (PBS), 5-ethynyl-2’ DNA nucleoside uracil (EdU), 4ʹ,6-diamidino-2-phenylindole (DAPI), reactive oxygen species (ROS) test kit, and Cell Counting Kit-8 (CCK-8) were purchased from Beyotime (Shanghai, China). Transmission electron microscopy (TEM) images were acquired using a JEM-2100F microscope (JEOL, Japan). Dynamic light scattering (DLS) and zeta potential were measured on a Zetasizer Nano ZS (Malvern, UK). A UV-2600 spectrophotometer (Shimadzu, Japan) was used to acquire UV-vis absorption spectra. Semiconductor lasers at 808 nm were purchased from Shanghai Xilong Optoelectronics Technology Co., Ltd. (Shanghai, China). Optical and NIR fluorescence imaging of nude mouse LNs were performed using white (380–665 nm) and NIR (810–1200 nm) light via a dual-channel image-guided device. An infrared thermal camera (E50; FLIR, USA) was used to acquire thermal images.
1H NMR spectra were recorded using a 500 MHz Bruker Avance III spectrometer (Bruker, Billerica, MA, USA).
Synthesis of PDA NPs
Briefly, 432 mg dopamine hydrochloride (2.28 mmol) was dissolved in 216 mL deionized water. PDA NPs were obtained upon addition of 2280 μL NaOH (1 N) and vigorous stirring at 50 °C for 10 h. The solution was then centrifuged at 14000 rpm and 26 °C for 10 min, followed by three washes with deionized water.
Surface Modification of PDA NPs with NH2-PEG5000-COOH
We adjusted the pH of a 10 mL PDA aqueous solution (2 mg/mL in water) to 9, and added 30 mg NH2-PEG5000-COOH. PEG-modified PDA was retrieved via centrifugation at 14,000 rpm after vigorous stirring, and was then washed several times with deionized water. After freeze-drying, the aqueous solvent was removed and powdered PEG-PDA NPs were obtained.
Loading of the cRGD Ligand
We mixed 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (EDC) and N-hydroxysulfosuccinimide sodium salt (sulfo-NHS) with PEG-PDA NPs. The mixture was stirred at 26 °C for 4 h and then washed several times. NH2-cRGD (4 mg) was added to the suspension at room temperature. Finally, the unreacted cRGD was removed, and the solution was washed several times with PBS.
Loading of PEG-PDA NPs with IR820 and Gd(NH2)2
We mixed the IR820 solution with a PEG-PDA NP aqueous solution or cRGD-PEG-PDA NP aqueous solution and allowed it to react for 6 h in the dark. The IR820:PEG-PDA NP weight ratio was 0.04:1, the same as the IR820:cRGD-PEG-PDA NP weight ratio. The formed NPs were centrifuged at 14,000 rpm and 26 °C for 10 min and then washed several times with deionized water. The loading efficiency (weight of loaded IR820/weight of added IR820 × 100%) and loading content (weight of loaded IR820/[weight of loaded IR820 + weight of NPs] × 100%) of IR820 on NPs were calculated by measuring unloaded and free IR820 in a UV-vis-NIR spectrophotometer. Thereafter, Gd(NH2)2 was loaded onto PEG-PDA@IR820 NPs. Briefly, freshly prepared Gd(NH2)2 solution was mixed with PEG-PDA@IR820 NPs at a Gd(NH2)2/PEG-PDA@IR820 NP weight ratio of 0.04:1. After 6 h of reaction, the mixture was centrifuged at 14,000 rpm and 26 °C for 10 min to remove free Gd(NH2)2. We analyzed the amount of Gd(NH2)2 loaded onto the NPs using inductively coupled plasma mass spectrometry. The photothermal properties of NPs of different sizes were measured in 200 μL PBS inside Eppendorf tubes after irradiation with a NIR laser at 808 nm (FC-808-10W-MM; Xilong Company, China) and a power density of 0.25–1 W/cm2 for 5 min. Real-time thermal images were recorded with an IR thermal camera (225–1; Fotric, China) and the corresponding temperature was determined. The generated NPs were denoted as PEG-PDA@IR820/ Gd(NH2)2 NPs (PPIG NPs) and cRGD-PEG-PDA@IR820/ Gd(NH2)2 NPs (cRGD-PPIG NPs).
In vitro Experiments
Cell Culture
Mouse axillary lymph node/vascular epithelial cells (SVEC4-10), human normal gastric epithelial cells (GES-1), and gastric cancer cells (MKN45) were purchased from the American Type Culture Collection (USA). All three cell lines were cultured and maintained in DMEM supplemented with 10% FBS and antibiotics (100 U/mL) at 37 °C in 5% CO2. Cells were seeded in 6- or 96-well plates.
Confocal Laser Scanning Microscopy
MKN45 cells were seeded in confocal laser scanning microscopy (CLSM) dishes and cultured for 24 h in DMEM supplemented with 10% FBS. To determine whether integrin alpha V beta 3 (αvβ3) was expressed on the cell surface, MKN45 cells were washed, fixed with 4% paraformaldehyde, and incubated with 5% bovine serum albumin (Gibco, USA). The cells were then incubated with anti-integrin αvβ3 antibody (LM609; Abcam, China) overnight at 4 °C. After incubation with secondary antibodies, the cells were stained with DAPI (Beyotime) and observed using CLSM (Olympus, Japan). To assess cRGD-PPIG NP absorption, MKN45 cells were incubated with PPIG NPs or cRGD-PPIG NPs for 24 h, washed, fixed with 4% paraformaldehyde, stained with DAPI, and observed using CLSM.
Flow Cytometry
MKN45 cells were seeded in 6-well plates (1 X 106 cells) and cultured for 24 h. The cells were then incubated with PPIG NPs (100 ug/mL) or cRGD-PPIG NPs (100 ug/mL) for 24 h, harvested, suspended, and analyzed using flow cytometry.
CCK-8 Assay
SVEC4-10 cells were seeded in 96 well plates at 5×105 cells/well and cultured for 24 h, and then incubated with cRGD-PPIG NPs at varying concentrations (range from 0–100 ug/mL) for an other 24 h. Thereafter, the biosafety of cRGD-PPIG NPs was assayed using a CCK-8 detection kit following the manufacturer’s instructions. Biosafety was determined based on the cell viability ratio of exposed cells relative to the blank control.
To detect the antitumor effect of cRGD-PPIG NPs, MNK45 cells were seeded in 96-well plates at 5×105 cells/well and cultured for 24 h. Subsequently, the cells were divided into equal groups and exposed to one of the six following treatments: the control treatment (DMEM with 10% FBS), PPIG treatment (free PPIG NPs at varying concentrations (ranging from 0–100 µg/mL)), cRGD-PPIG treatment (free cRGD-PPIG NPs at varying concentrations (ranging from 0–100 µg/mL)), NIR treatment (DMEM with 10% FBS, and irradiation at 1 W/cm2 for 5 min), PPIG at varying concentrations (ranging from 0–100 µg/mL) + NIR treatment (1 W/cm2, 5 min), and cRGD-PPIG at varying concentrations (ranging from 0–100 µg/mL) + NIR treatment (1 W/cm2 for 5 min). After treatment, we used the CCK-8 assay to determine cell viability.
EdU Assay
The antitumor effect of cRGD-PPIG NPs with and without NIR was assessed using an EdU assay (KeyGen, China). Briefly, 6×105 MKN45 cells were seeded in 12-well plates and cultured overnight. Thereafter, the cells were incubated with the same concentrations of PPIG NPs (100 µg/mL) and cRGD-PPIG NPs (100 µg/mL), and subjected or not subjected to NIR irradiation (1 W/cm2, 5 min). Based on the manufacturer’s instructions, treated cells were labeled, fixed, stained, and finally monitored using CLSM.
ROS Assay
MKN45 cells were seeded in 6-well plates (1 X 106 cells) and cultured for 24 h. The cells were treated with PPIG NPs (100 µg/mL) or cRGD-PPIG NPs (100 µg/mL) for 24 h, with or without NIR irradiation (1 W/cm2, 5 min). Finally, the cells were incubated with ROS Assay Kit reagents (Beyotime) and analyzed using flow cytometry.
In vivo Experiments
Animals
Nude mice and Sprague-Dawley rats were obtained from the Biomedical Research Institute of Southern Medical University. Animal experiments and euthanasia were performed following approval by the Institutional Animal Care and Use Committee of Southern Medical University (Certification No. K2020015). All procedures conducted in animals complied with the Animal Welfare Act, the Guide for the Care and Use of Laboratory Animals, and the Office of Laboratory Animal Welfare.
In vivo PTT Effect
To clarify the therapeutic effect of cRGD-PPIG NPs, we first established tumor-bearing mice by injecting MKN45 cells (50 µL, 2×107 cells/mL) into the left hind foot sole of nude mice (n =30). After 28 days, the left popliteal LNs were swollen, indicating the presence of metastatic LNs. PBS (in the control group), PPIG NPs, or cRGD-PPIG NPs were injected peritumorally once, with or without NIR irradiation, into the metastatic LNs (1 W /cm2, 5 min, once). An infrared 225–1 thermal camera was used to record real-time temperature changes in vivo. Ten days after NIR irradiation, metastatic LNs were excised for immunofluorescence staining using terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL; Abcam, USA).
In vivo Biodistribution and Biosafety
For in vivo biodistribution analysis, we injected the left rear footpad of nude mice (n = 3/group) with 50 μL PBS containing 50 μg of cRGD-PPIG NPs or PPIG NPs. One hour after injection, the mice were sacrificed using an overdose of pentobarbital. Thereafter, the major organs were excised and imaged. To quantitatively evaluate and compare the toxicity of cRGD-PPIG NPs, Sprague-Dawley rats (n = 3/group) were injected with 100 µL PBS containing 350 μg cRGD-PPIG NPs or PPIG NPs. Thereafter, biochemical blood indices, including alanine transaminase, aspartate transaminase, blood urea nitrogen, and creatinine, were measured using enzyme-linked immunosorbent assay kits.
Statistical Analysis
Data are expressed as the mean ± standard deviation. All experiments were repeated at least thrice. We used the unpaired Student’s t-test or analysis of variance followed by Scheffe’s post-hoc test to evaluate the data. Differences were considered statistically significant at p < 0.05.
Results and Discussion
Design of cRGD-PPIG MR/NPs for Optical/NIR Fluorescence Multimodal Tumor-Targeted LN Mapping and PTT
Scheme 1 shows the design and polymerization of PDA NPs, their functionalization with PEG, and cRGD ligand, MRI contrast (Gd(NH2)2), and NIR dye (IR820) loading. PDA NPs were selected as optical imaging agents because of their black coloration, easy functionalization, and low systemic toxicity.21 Hydrophilic PEG5000 was introduced into the outer shell of PDA NPs to improve biocompatibility,30 the cRGD ligand conferred tumor-targeting capability, and Gd(NH2)2 and IR820 facilitated sensitive LN MR/fluorescence imaging in vivo.31 The generated cRGD-PPIG NPs were injected locally and specifically mapped to the left metastatic popliteal LN to aid MR, optical and NIR fluorescence imaging, and PTT.
Preparation and Characterization of cRGD-PPIG NPs
First, PDA NPs were synthesized via oxidation polymerization in an alkaline environment. To improve their solubility in PBS, PDA NPs were modified with PEG. Measurements of particle stability using PDA NPs, PPIG NPs, and cRGD-PPIG NPs of different sizes at 0, 1, 6, 12, and 24 h are summarized in Supplementary Figure S1. PPIG NPs and cRGD-PPIG NPs remained stable in PBS after 24 h, whereas PDA NPs had precipitated. These results confirmed the improved stability of PDA NPs upon PEG modification. To load cRGD on PEG-PDA NPs, EDC (50 mg) and sulfo-NHS (30 mg) were added to a solution containing PEG-PDA NPs (15 mg) and the mixture was stirred at room temperature for 4 h. The mixture was then washed with PBS to remove excess EDC and sulfo-NHS. Next, NH2-cRGD (2 mg) was added to the mixture, and the reaction was proceeded at 4 °C for 10 h with continuous stirring. After washing and centrifugation, the MRI contrast (Gd(NH2)2) and NIR dye (IR820) were loaded on cRGD-PEG-PDA NPs. The resulting cRGD-PPIG NPs were characterized using TEM, DLS, zeta potential measurement, nuclear magnetic resonance (NMR) spectroscopy, and UV-vis spectral analysis. TEM and DLS confirmed that the synthesized cRGD-PPIG NPs were 79.2 ± 31.6 nm in diameter (Figure 1A and B) and had a zeta potential of −42.5 ± 8.3 eV (Figure 1C). Evaluation by 1H NMR revealed a specific peak for cRGD peptides (Figure 1D, blue box).32 Together, these results indicated the successful loading of cRGD peptides on the NPs.
NIR imaging and photothermal performance of cRGD-PPIG NPs were evaluated. The broadband UV-vis absorption spectra of cRGD-PPIG NPs are shown in Figure 2A. A distinctive absorbance peak was detected at ~820 nm owing to IR820 loading. In the MRI performance evaluation, the cRGD-PPIG NPs became brighter with increasing NP concentration. A linear relationship can be identified in Figure 2B. The temperature of laser-exposed cRGD-PPI NP solutions increased with increasing NP concentration and laser power density (Figure 2C–F). The temperature of the cRGD-PPIG NP solution (400 μg/mL) reached 38.6 °C ± 2.3 °C rapidly at a power density of 1 W/cm2 after which the temperature increased further. The thermal image became brighter as the NP concentration or laser power density increased. The photothermal effect of cRGD-PPIG NPs was stable over five irradiation cycles (Figure 2E). These results indicate that cRGD-PPIG NPs are effective PTT agents.
Biosafety and Cellular Uptake of cRGD-PPIG NPs in vitro
Melanin and its analogs have been shown to possess strong biocompatibility, making them widely used as drug delivery platforms.21 Previously, we identified PDA as another highly biocompatible molecule.33 To assess the biocompatibility of the cRGD-PPIG NPs generated in the present study, we used the CCK-8 assay. Biosafety measurements of PPIG NPs and cRGD-PPIG NPs in normal SVEC4-10 cells revealed viability above 85% (Figure 3A). Therefore, we hypothesized that both PPIG NPs and cRGD-PPIG NPs were safe for use as drug delivery systems in biomedical applications.
Integrin αvβ3 is specifically overexpressed on cancer cell membranes. Because the cRGD peptide targets integrin αvβ3,34–36 cRGD-conjugated NPs were expected to have a higher affinity for tumor cells. For this purpose, MKN45 cells were selected as in vitro models because the integrin αvβ3 was significantly upregulated in these cells compared with GES-1 cells (Supplementary Figure S2). To confirm the synergistic uptake of cRGD-PPIG NPs, MKN45 cells were exposed separately to PPIG NPs and cRGD-PPIG NPs for 4 h and then analyzed using flow cytometry and CLSM. Using flow cytometry to assess the accumulation of IR820 in MKN45 cells, we found that the uptake of IR820 at 24 h was three times higher following treatment with cRGD-PPIG NPs compared to PPIG NPs (Figure 3B). Consequently, according to the CLSM results, the red fluorescence intensity of IR820 increased in both PPIG and cRGD-PPIG groups (Figure 3C), although it was stronger in the latter (Figure 3D), indicating that cRGD helped increase the cell uptake ratio after binding to the highly expressed integrin αvβ3 receptor in MKN45 cells.
cRGD-PPIG NPs Have a Combined PTT/Photodynamic Therapy (PDT) Effect on Gastric Cancer Cells
PDA NPs are potential PTT/PDT agents with intrinsic NIR-responsive properties.33 IR820 was previously reported to be a promising NIR dye for PTT and PDT.37 Here, we hypothesized that combining cRGD-PPIG NPs with NIR irradiation could cause oxidative stress with combined PTT and PDT effects. To test the synergistic PTT/PDT effect of these NPs, MKN45 cells were incubated with cRGD-PPIG NPs at different concentrations. The MKN45 cells were then subjected or not to NIR irradiation (1 W/cm2, 5 min). After culturing for 24 h, treated MKN45 cells were analyzed using CCK-8 and EdU staining kits. No significant change in cell viability was observed with increasing concentrations of PPIG NPs, cRGD-PPIG NPs, or NIR irradiation alone compared to the control (Figure 4A). However, combinations of PPIG NPs + NIR irradiation and cRGD-PPIG NPs + NIR irradiation achieved a desirable therapeutic effect, with the latter causing the highest rate of gastric cancer cell death. NIR-irradiated and either PPIG NP-treated or cRGD-PPIG NP-treated cells showed fewer EdU-positive cells than the control or cells treated with only PPIG NPs, cRGD-PPIG NPs, and NIR (Figure 4B and D).
High levels of intracellular ROS can damage mitochondria and cause apoptosis. Emerging evidence indicates that the NIR-mediated phototherapeutic effect can activate the endogenous oxidative stress signaling pathway, promoting intracellular ROS production.38,39 To clarify whether cRGD-PPIG NPs could exert a PDT effect, treated MKN45 cells were analyzed using a dichloro-dihydro-fluorescein diacetate probe to quantify intracellular ROS. CLSM revealed no significant ROS changes in the PPIG, cRGD-PPIG, or NIR-only irradiation groups compared to the control. Interestingly, ROS generation was significantly increased in cells treated with PPIG NPs + NIR. Overall, MKN45 cells treated with cRGD-PPIG NPs + NIR exhibited the highest ROS production and, hence, cytotoxic effect (Figure 4C and E). Collectively, these findings suggest that cRGD-PPIG NPs promote PTT and PDT effects against MKN45 cells.
In vivo Tumor-Targeted Multimodal LN Mapping Using cRGD-PPIG NPs
MRI has proven valuable in the preoperative GC Tumour Node Metastasis classification.40 However, its low accuracy for N staging, ranging from 52.17% to 71%, hampers its clinical application in GC diagnoses.41–44 Intravenous MRI contrast agents may not be suitable for MRI detection of LNs because of their relatively small size. However, indirect magnetic resonance lymphangiography (MR-LAG), in which MRI contrast agents are injected peritumorally, might be valuable for identifying nodal micrometastases or high-risk nodal regions. Indirect MR-LAG explains local lymphatic drainage with a high-resolution MRI. Thus, this technique has been used to characterize cervical LNs in patients with head and neck cancer.45 Current MRI agents cannot differentiate metastatic LNs because of their lack of tumor-targeting ability.46 In the present study, we investigated the tumor-targeted metastatic LN mapping ability of cRGD-PPIG NPs in a mouse model bearing an MKN-45 tumor using indirect MR-LAG. Proper volume samples (50 μL containing 50 μg of cRGD-PPIG or PPIG NPs per mouse) were injected into the left rear footpad of nude mice bearing MKN45 tumors (n = 3/group). Thereafter, mice were anesthetized, and cRGD-PPIG and PPIG NP accumulation in the metastatic LN and normal LN were investigated using MRI before and at 1, 2, and 4 h after injection (Figure 5). The relative intensity of the MR signal in LN is shown in Supplementary Figure S3. At 1 h post-injection, popliteal LN was visualized in all groups. The cRGD-PPIG NP metastatic LN group displayed the highest MR signal intensity and remained high for 4 h after injection. For the PPIG NP metastatic LN group, lower signal intensity was observed relative to that of the cRGD-PPIG NP metastatic LN group. For the cRGD-PPIG NPs and PPIG NP normal LN groups, the lowest MR signal intensity was observed after injection. Therefore, by using cRGD-PPIG NPs, we might achieve targeted indirect MR-LAG.
Optical LN mapping is convenient because of its ease of use and reliance on readily accessible equipment. Nanocarbon NPs have been applied in clinical settings owing to their natural black color, which is easy to detect. If properly sized, nanocarbon NPs could specifically enter lymphatic vessels and stain LNs rather than traverse blood endothelial cell junctions.47–49 However, the lack of multimodal LN mapping and targeting of specific pathological outcomes, including inflammation, fibrosis, and tumorigenesis, has limited the application of nanocarbon NPs in clinical diagnosis and therapy.50 In the present study, we used cRGD-PPIG NPs to overcome the limitations of nanocarbon NPs. After cRGD-PPIG NPs and PPIG NPs were injected locally into mice, the animals were sacrificed for optical imaging (Figure 6). In the cRGD-PPIG group, metastatic LNs were stained 1 h after injection and the staining persisted for 4 h. A relatively weaker coloration of LNs was observed when metastatic LNs were stained with PPIG NPs or when non-metastatic LNs were stained with cRGD-PPIG NPs and PPIG NPs. These results show that cRGD-PPIG NPs aided tumor-targeted LN optical imaging.
Recent scientific and technological developments have brought increasing attention to NIR fluorescent dyes because of their optimal tissue penetration in biological samples, low light scattering, and ability to stain both LNs and the lymphatic route.14 Despite these advantages, the actual application of NIR fluorescent dyes in clinical practice remains limited. Some clinical studies have associated LN detection using indocyanine green with a high rate of false-negative results.6,51–53 This could be attributed to the lack of multimodal LN mapping ability of this dye. Moreover, nonspecific NIR fluorescence dyes may not accurately map metastatic LNs during surgery. Here, we used cRGD-PPIG NPs to achieve tumor-targeted LN NIR fluorescence imaging. The LN mapping ability of cRGD-PPIG NPs and PPIG NPs in LNs was also explored. Briefly, equal amounts of cRGD-PPIG NPs and PPIG NPs were injected locally followed by NIR fluorescence LN imaging before and 1, 2, and 4 h after injection (Figure 7). The NIR fluorescence intensity of LNs was also measured (Supplementary Figure S4). Similar to the optical imaging results, the cRGD-PPIG metastatic LN group attained the highest NIR fluorescence intensity 1 h after injection, and the signal intensity lasted for 4 h. In the other groups, NIR fluorescence intensities were relatively weak. Multimodal LN mapping agents such as cRGD-PPIG NPs show strong clinical application potential as tumor-targeting therapeutics.
cRGD-PPIG NPs Could Inhibit the Growth of Metastatic LNs in vivo
PTT has emerged as an effective therapeutic method against solid tumors. By using NIR light-absorbing agents under 808 nm laser irradiation, PTT can raise the local tumor temperature, causing irreversible cell death to neoplastic tissues while sparing healthy tissues from unnecessary damage.54,55 Therefore, PTT has been investigated as an alternative to surgical resection of metastatic LNs.56,57
The in vivo biodistribution of cRGD-PPIG NPs revealed good fluorescence and optical imaging, as well as thermal capacity toward metastatic LNs. Guided by multimodal LN imaging, the phototherapeutic efficacy of cRGD-PPIG NPs was further evaluated in MKN45 tumor-bearing mice. One hour after peritumoral PBS injection (control group), PPIG NPs, or cRGD-PPIG NPs, metastatic LNs were irradiated at 1 W/cm2 with an 808 nm laser for 5 min. Subsequently, in vivo images were captured with an infrared thermal camera. As shown in Figure 8A, the tumor temperature of the metastatic LNs in the cRGD-PPIG + NIR group increased from ∼32 °C to ∼55 °C within 3 min and was then maintained at ∼55 °C to 57 °C for the next 2 min to ensure sufficient PTT effect. This temperature was markedly higher than that observed in the PPIG + NIR group (approximately 51 °C) and the control group (approximately 39 °C) (Figure 8B). Therefore, our results demonstrate that cRGD-PPIG NPs can remarkably raise the temperature during PTT.
Figure 8 In vivo photothermal treatment of LNs in mice. (A) Representative thermal images of mice treated with PBS, PPIG NPs, and cRGD-PPIG NPs under irradiation at 1 W/cm² with an 808 nm laser. (B) Temperature change in metastatic LNs treated with PBS, PPIG NPs, or cRGD-PPIG NPs under irradiation at 1 W/cm² with an 808 nm laser. (C) Images of non-metastatic LNs and metastatic LNs collected from mice 10 days after the indicated treatment. (D) Average weights of LNs from Figure 7C. *p < 0.05. Error bars represent the standard deviations (n = 5). (E) TUNEL staining of metastatic LN tissue slices collected from mice on day 3 after various treatments. |
To further analyze the antitumor effect of cRGD-PPIG NPs on metastatic LNs in vivo, we randomly divided the mice into six groups and treated them with PBS (negative control), PBS + NIR, PPIG NPs, PPIG NPs + NIR, cRGD-PPIG NPs, or cRGD-PPIG NPs + NIR. Ten days after treatment, the morphology of metastatic LNs was similar among the PBS, PBS + NIR, PPIG, and cRGD-PPIG groups. In contrast, the tumor growth rates in the PPIG + NIR and cRGD-PPIG + NIR groups were approximately 60% and 80% lower, respectively, compared to the control group (Figure 8C). The cRGD-PPIG + NIR group showed the most significant weight loss, whereas no significant differences were observed among the PBS, PBS + NIR, PPIG, and cRGD-PPIG groups (Figure 8D).
Isolated metastatic LNs were subjected to immunofluorescence staining. TUNEL is a classic marker of DNA fragmentation in apoptotic tumor cells. Immunofluorescence revealed significantly stronger TUNEL staining in the cRGD-PPIG + NIR group (Figure 8E). Consequently, in vivo PTT consistently highlighted the superiority of cRGD-PPIG NPs in inhibiting metastatic LN growth through PTT and PDT effects.
In vivo Biodistribution and Biosafety of cRGD-PPIG NPs
Finally, we injected cRGD-PPIG and PPIG NPs locally into nude mice to evaluate their biodistribution during LN mapping. At 1 h after injection (corresponding to the highest NIR fluorescence signal), mice were sacrificed via an overdose of pentobarbital, and the major organs, including the heart, liver, spleen, lungs, kidneys, brain, and LNs, were excised for imaging (Supplementary Figure S5A). NIR fluorescence images indicate that cRGD-PPIG NPs accumulated mainly in LNs, whereas only a small amount of NIR fluorescence was observed in the liver and kidneys. Histological examination revealed no apparent histopathological damage in the major organs of animals treated with PPIG NPs (Supplementary Figure S5B). Furthermore, brown-yellow NPs were observed in the metastatic LNs. These findings demonstrate that cRGD-PPIG NPs are retained in LNs.
To evaluate the biosafety of cRGD-PPIG NPs in vivo, we measured blood biochemical indices, including blood urea nitrogen and creatinine for kidney function, and alanine transaminase and aspartate transaminase for liver function.56,58 No significant differences were observed in the indices in treated versus untreated rats over 1 month (Supplementary Figure S6). These findings suggest that PPIG NPs exert no noticeable toxicity on liver and kidney function.
Conclusion
In this study, a cRGD-PPIG NP tumor-targeted LN mapping agent was successfully developed. The generated cRGD-PPIG NPs facilitated MR/optical/NIR fluorescence multimodal targeted mapping of gastric cancer metastatic LNs. Furthermore, accurate guided PTT was achieved by locally injecting cRGD-PPIG NPs. The loaded cRGD ligand on the surface of NPs was selectively taken up by cancerous MKN45 cells overexpressing integrin αvβ3. Importantly, cRGD-PPIG NPs specifically targeted metastatic MKN45 LNs, enabling MR/optical/NIR fluorescence multimodal gastric cancer metastatic LN mapping and PTT in vivo. Accordingly, the proposed NPs represent an alternative to surgical resection of LN metastases. Future studies on the long-term toxicology of cRGD-PPIG NPs in vivo would explain the potential clinical applications of these antitumor agents.
Abbreviations
CLSM, confocal laser scanning microscopy; cRGD, circular-arginine-glycine-aspartic acid sequence; DLS, dynamic light scattering; EDC, ethylcarbodiimide hydrochloride; LN, lymph node; MRI, magnetic resonance imaging; MR-LAG, magnetic resonance lymphangiography; NIR, near-infrared; NMR, nuclear magnetic resonance; NP, nanoparticle; PDA, polydopamine; PEG, polyethylene glycol; PPIG, PEG-PDA@IR820/Gd(NH2)2; PPT, photothermal therapy; TEM, transmission electron microscopy.
Acknowledgments
The authors would like to thank Dr. Bingquan Lin, Dr. Bingxia Zhao, and Dr. Peng Zhao from Southern Medical University for providing technical support. We would also like to thank Editage for English language editing. This research was funded by the National Natural Science Foundation of China (grant numbers 82001948 and 81971746); the Natural Science Foundation of Guangdong Province, China (grant number 2017A030306023); the Guangdong Provincial Key Laboratory of Precision Medicine for Gastrointestinal Cancer (grant number 2020B121201004); the Guangdong Provincial Major Talents Project (grant number 2019JC05Y361); the Outstanding Youths Development Scheme of Nanfang Hospital, Southern Medical University (grant number 2017J006); the Medical Scientific Research Foundation of Guangdong Province of China (grant number A2020297); President Foundation of Nanfang Hospital, Southern Medical University (grant number 2021C041); the Special Funds for Cultivation of Guangdong College Students’ Scientific and Technological Innovation (grant numbers pdjh2020a0108, pdjh2020a0106, and pdjh2020a0109); and the College Students’ Innovative Entrepreneurial Training Plan Program (grant numbers S202012121020 and 595 S202012121051).
Disclosure
The authors report no conflicts of interest in this work.
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