Magnetic-guided nanocarriers for ionizing/non-ionizing radiation synergistic treatment against triple-negative breast cancer.

IF 2.9 4区 医学 Q3 ENGINEERING, BIOMEDICAL BioMedical Engineering OnLine Pub Date : 2024-07-13 DOI:10.1186/s12938-024-01263-7
Yun Zhou, Junhao Kou, Yuhuang Zhang, Rongze Ma, Yao Wang, Junfeng Zhang, Chunhong Zhang, Wenhua Zhan, Ke Li, Xueping Li
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Abstract

Background: Triple-negative breast cancer (TNBC) is a subtype of breast cancer with the worst prognosis. Radiotherapy (RT) is one of the core modalities for the disease; however, the ionizing radiation of RT has severe side effects. The consistent development direction of RT is to achieve better therapeutic effect with lower radiation dose. Studies have demonstrated that synergistic effects can be achieved by combining RT with non-ionizing radiation therapies such as light and magnetic therapy, thereby achieving the goal of dose reduction and efficacy enhancement.

Methods: In this study, we applied FeCo NPs with magneto thermal function and phototherapeutic agent IR-780 to construct an ionizing and non-ionizing radiation synergistic nanoparticle (INS NPs). INS NPs are first subjected to morphology, size, colloidal stability, loading capacity, and photothermal conversion tests. Subsequently, the cell inhibitory and cellular internalization were evaluated using cell lines in vitro. Following comprehensive assessment of the NPs' in vivo biocompatibility, tumor-bearing mouse model was established to evaluate their distribution, targeted delivery, and anti-tumor effects in vivo.

Results: INS NPs have a saturation magnetization exceeding 72 emu/g, a hydrodynamic particle size of approximately 40 nm, a negatively charged surface, and good colloidal stability and encapsulation properties. INS NPs maintain the spectral characteristics of IR-780 at 808 nm. Under laser irradiation, the maximum temperature was 92 °C, INS NPs also achieved the effective heat temperature in vivo. Both in vivo and in vitro tests have proven that INS NPs have good biocompatibility. INS NPs remained effective for more than a week after one injection in vivo, and can also be guided and accumulated in tumors through permanent magnets. Later, the results exhibited that under low-dose RT and laser irradiation, the combined intervention group showed significant synergetic effects, and the ROS production rate was much higher than that of the RT and phototherapy-treated groups. In the mice model, 60% of the tumors were completely eradicated.

Conclusions: INS NPs effectively overcome many shortcomings of RT for TNBC and provide experimental basis for the development of novel clinical treatment methods for TNBC.

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磁引导纳米载体用于电离/非电离辐射协同治疗三阴性乳腺癌。
背景:三阴性乳腺癌(TNBC)是预后最差的乳腺癌亚型:三阴性乳腺癌(TNBC)是预后最差的乳腺癌亚型。放射治疗(RT)是治疗该病的核心方法之一,但RT的电离辐射具有严重的副作用。如何以较低的辐射剂量达到更好的治疗效果是放疗的一贯发展方向。研究表明,将 RT 与光疗、磁疗等非电离辐射疗法相结合,可产生协同效应,从而达到减少剂量、提高疗效的目的:本研究应用具有磁热功能的铁钴纳米粒子和光疗剂 IR-780 构建了一种电离和非电离辐射协同纳米粒子(INS NPs)。首先对 INS NPs 进行了形态、尺寸、胶体稳定性、负载能力和光热转换测试。随后,利用体外细胞系对细胞抑制和细胞内化进行了评估。在对 NPs 的体内生物相容性进行全面评估后,建立了肿瘤小鼠模型,以评估其体内分布、靶向递送和抗肿瘤效果:INS NPs 的饱和磁化率超过 72 emu/g,流体力学粒径约为 40 nm,表面带负电荷,具有良好的胶体稳定性和封装特性。INS NPs 在 808 纳米波长处保持了 IR-780 的光谱特性。在激光照射下,最高温度为 92 ℃,INS NPs 在体内也达到了有效发热温度。体内和体外试验均证明 INS NPs 具有良好的生物相容性。INS NPs 在体内注射一次后可维持一周以上的疗效,还可通过永磁体在肿瘤内引导和积聚。随后的研究结果表明,在低剂量 RT 和激光照射下,联合干预组显示出显著的协同效应,ROS 生成率远高于 RT 组和光疗组。在小鼠模型中,60%的肿瘤被完全根除:INS NPs有效克服了RT治疗TNBC的许多缺点,为TNBC新型临床治疗方法的开发提供了实验依据。
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来源期刊
BioMedical Engineering OnLine
BioMedical Engineering OnLine 工程技术-工程:生物医学
CiteScore
6.70
自引率
2.60%
发文量
79
审稿时长
1 months
期刊介绍: BioMedical Engineering OnLine is an open access, peer-reviewed journal that is dedicated to publishing research in all areas of biomedical engineering. BioMedical Engineering OnLine is aimed at readers and authors throughout the world, with an interest in using tools of the physical and data sciences and techniques in engineering to understand and solve problems in the biological and medical sciences. Topical areas include, but are not limited to: Bioinformatics- Bioinstrumentation- Biomechanics- Biomedical Devices & Instrumentation- Biomedical Signal Processing- Healthcare Information Systems- Human Dynamics- Neural Engineering- Rehabilitation Engineering- Biomaterials- Biomedical Imaging & Image Processing- BioMEMS and On-Chip Devices- Bio-Micro/Nano Technologies- Biomolecular Engineering- Biosensors- Cardiovascular Systems Engineering- Cellular Engineering- Clinical Engineering- Computational Biology- Drug Delivery Technologies- Modeling Methodologies- Nanomaterials and Nanotechnology in Biomedicine- Respiratory Systems Engineering- Robotics in Medicine- Systems and Synthetic Biology- Systems Biology- Telemedicine/Smartphone Applications in Medicine- Therapeutic Systems, Devices and Technologies- Tissue Engineering
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