The Recent Advances of Magnetic Nanoparticles in Medicine

Guo, Ting; Lin, Mei; Huang, Junxing; Zhou, Chenglin; Tian, Weizhong; Yu, Hong; Jiang, Xingmao; Ye, Jun; Shi, Yujuan; Xiao, Yanhong; Bian, Xuefeng; Feng, Xiaoqian

doi:https://doi.org/10.1155/2018/7805147

Journal of Nanomaterials

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Abstract Introduction Conflicts of Interest Acknowledgments References Copyright Related Articles

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Application of Nanomaterials in Bioengineering

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Review Article | Open Access

Volume 2018 | Article ID 7805147 | https://doi.org/10.1155/2018/7805147

The Recent Advances of Magnetic Nanoparticles in Medicine

Ting Guo,¹Mei Lin,²Junxing Huang,³Chenglin Zhou,²Weizhong Tian,⁴Hong Yu,⁵Xingmao Jiang,⁶Jun Ye,¹Yujuan Shi,¹Yanhong Xiao,¹Xuefeng Bian,¹and Xiaoqian Feng¹

Academic Editor: Federica Paladini

Received28 Dec 2017

Accepted16 Apr 2018

Published29 Apr 2018

Abstract

With the progress of nanotechnology and molecular biology, nanoparticles have been widely studied and applied in biomedicine. Particularly, characterized by unique magnetic property, targeting, and biocompatibility, magnetic nanoparticles have become one of the research hotspots in the nanomedical field. Herein, we summarized the recent advances of magnetic nanoparticles in medicine, including the property, carrier function, MRI, and tumor magnetic inductive hyperthermia of magnetic nanoparticles.

1. Introduction

The constant development of medicine has rendered early diagnosis and precise treatment of its development direction. Nanotechnology has provided a new platform for medicine development. As a result of unique features, nanomaterials have been extensively studied and applied in the medical field [1]. As one kind of the nanomaterials, magnetic nanoparticles possess not only the general characteristics of nanoparticles but also the magnetic properties. After being modified surfacely, magnetic nanoparticles can possess excellent biocompatibility, which is suitable for medical application. For example, surface-modified magnetic nanoparticles can be used as vectors, allowing for drug or gene directional transportation under the action of the magnetic field to realize targeted therapy [2]. Moreover, under the action of applied magnetic field, magnetic nanoparticles have unique magnetic sensitivity, which can thus be applied in MRI [3]. Furthermore, the magnetocaloric effect of magnetic nanoparticles has also provided a new means for tumor treatment [4]. All in all, the application of magnetic nanoparticles will further promote the development of the medical field.

2. Category and Properties of Magnetic Nanoparticles

At present, magnetic nanoparticles (NPs) mainly include metal NPs, metal oxide NPs, and metal alloy NPs. The common NPs are gold [5], silver [6], iron, cobalt, and nickel. Metal oxide NPs mainly include iron oxides (γ-Fe₂O₃ and Fe₃O₄) and ferrites (CoFe₂O₄ and Mn_0.6Zn_0.4Fe₂O₄), and metal alloy NPs cover FeCo, FePt, and so on. Of them, metal oxide Fe₂O₃ and Fe₃O₄ magnetic nanoparticles are the most extensively used magnetic NPs [7], which can be handily prepared and easily controlled in particle size and shape [8]. Some metallic elements such as manganese (Mn) and Zn (Zn) can be added to nanosized iron oxide structure to prepare a variety of ferrite nanoparticles (Mn₃Zn₇Fe₂O₄, Mn_0.6Zn_0.4Fe₂O₄, and so on). These ferrite nanoparticles have a stronger magnetism and a higher relaxation rate, which contributes to their application for magnetic resonance imaging (MRI).

Magnetic NPs own the following properties. Firstly, magnetic nanometer materials have nonvirulence and nonimmunogenicity. Secondly, magnetic NPs possess the surface effect. In detail, they have great specific surface area, which is good for carrying a large amount of DNA fragments, drugs, and modified compounds. After modification, they can be used as vector. Thirdly, most modified magnetic NPs have excellent biocompatibility. Fourthly, some magnetic NPs have superparamagnetism.

General magnetic materials are a multimagnetic domain structure. When the size of magnetic materials is reduced to nanoscale, they have a single magnetic domain structure and their magnetism turns to paramagnetism [9]. Paramagnetic materials, in the external magnetic field, are macroscopically nonmagnetic, showing a very weak magnetic property. When the size of the magnetic material is smaller than the critical size (generally 20 nm), the magnetic spin of the magnetic nanomaterials will be disordered and superparamagnetic, which will be magnetized rapidly under the action of alternating magnetic field and can move in a directional manner with the magnetic field. But once the magnetic field is removed, the magnetization becomes zero, that is, it does not show magnetism when there is no external magnetic field [10]. The magnetic susceptibility of superparamagnetism in the presence of external magnetic field is much higher than that of general paramagnetic materials. Fifthly, magnetic NPs can be used for tumor thermotherapy since they can produce thermal effect under the action of alternating magnetic field (AMF). Sixthly, the magnetic NPs can be exploited for magnetic separation [11]. For instance, they can be served as vectors to bind biomolecules and then be separated from the biomolecules at the targeted area under the action of the magnetic field and thus used for targeted therapy or diagnosis. Since most PH outside tumor cells are usually low, most weak alkaline drugs can hardly enter the cells, showing drug resistance. In order to overcome such resistance, researchers have extensively studied the preparation and modification of multiple NPs. As superparamagnetic iron oxide (SPIO) NPs are being studied most extensively, Fe₂O₃ and Fe₃O₄ NPs have been widely applied in diagnosis and treatment for all kinds of tumors. Iron oxide NPs have many advantages such as excellent biodegradability, low cytotoxicity, the ability to be modified by multiple substances, the ability to bind with multiple targeted ligands or antibodies, and ease to prepare, and can enter cells through endocytosis. They have been used in MRI and tumor thermotherapy [7].

3. Modification of Magnetic Nanoparticles

As a result of the surface effect and interface effect of nanostructure, the exposed magnetic NPs are extremely unstable in structure and are apt to aggregation. After entering the human body, the magnetic NPs are subject to being absorbed with body proteins and phagocytosed by the vascular endothelial system. They thus cannot be applied in biomedicine. It has been confirmed that surface modification can better stabilize the nanostructure and improve the surface functionalization of nanoparticles. For instance, when coated by active material with hydroxyl and carboxyl, nanoparticles can bind DNA fragments, drugs, and proteins, thus exerting the function of transportation and targeted therapy. At present, numerous surface-modified compounds are available, including polyethylene glycol (PEG), polyethylenimine (PEI), folic acid (FA), liposome, noble metal, and inorganic materials (Table 1).

Surface modification can enhance the water solubility, biocompatibility, and stability of NPs; they thus can be served as vectors for drug delivery, gene transfer, MRI, and thermotherapy. Some surface-modified compounds such as PEG and carboxylated polyethyleneimine (PEI-COOH) have rendered favorable water solubility for magnetic NPs, leading to good application in MRI or other medical diagnosis and treatments [18, 19]. As one of the few polymers which can be used for in vivo injection, PEG has favorable water solubility, biocompatibility, and nontoxicity. It can bind onto the surface of NPs by end-group reactivity and thus be able to bind DNA fragments, drugs, and other biological fragments, extending the blood circulation time [20, 21]. PEG-modified ferrite NPs can enter cells through phagocytosis, which can suppress iron ion release when it is degraded in lysosome, lessening the binding of iron ion with catalase to reduce cell destruction [22]. PEI is a cationic polymer, which can carry gene fragments and drugs, thus carrying out drug or gene transfer. Tang et al. used PEI to modify Mn Zn ferrite and bound it with plasmid DNA. Agarose gel electrophoresis (AGE) suggested a reliable binding of PEI/Mn_0.5Zn_0.5Fe₂O₄/DNA [23]. In the applied magnetic field, PEI-modified magnetic NPs have remarkably improved gene transfection efficiency [24]. Additionally, magnetic NPs receiving specific surface modification can specifically bind with target cell, thus being served as the vector for contrast medium of MRI or nanoprobe for the early diagnosis of tumor. Inert metal NPs also have aroused extensive attention. On the one hand, the gold nanocoating can bind with sulfhydryl-containing ligand, which can be used as vectors of biomolecules. On the other hand, the gold-coating surface can enhance its optical property and thus can be used to trace the NPs. Methacrylate- (PDEA-) coating magnetic NPs can resist the degradation of DNase I to the carried gene during the gene transfection of G2 cell hepatitis, thus improving gene transfection efficiency [25].

4. Application of Magnetic NPs in MRI

In recent years, tumor morbidity is increasing and early tumor diagnosis is of vital importance. MRI is one of the common methods for tumor diagnosis. With the development of nanotechnology, nanometer materials have been gradually applied for the diagnosis and treatment of tumor. Particularly, the combination of nanotechnology with MRI to detect tumor has attained satisfactory effects. In MRI, magnetic NPs have displayed unique sensitivity to the magnetic field in the presence of applied magnetic field. They can alter T1 or T2 relaxation time of MRI, which can thereby greatly enhance the diagnostic efficiency of MRI [26]. However, water solubility of magnetic NPs has to be enhanced in the meantime in preserving their magnetic property so that they can be extensively applied in clinics [27]. Research has indicated that PEG-modified NPs have excellent water solubility and biocompatibility, which can extend the blood circulation time and enhance the MRI effect [28].

The application of nanoprobe in MRI is one of research hotspots in molecular imaging field. After NPs coupled with ligands or antibodies enter the human body, they may be bound with the specific receptors or antibodies of tumor cells and thus be phagocytosed by tumor cells or bind onto the tumor cell surface, resulting in NPs aggregating in tumor tissues. Under such circumstances, magnetic nanomaterials will generate magnetism under the action of applied magnetic field, which allows for early diagnosis and detection of small lesion through MRI. MRI research on magnetic ferrite NPs coated with carboxylated PEG suggests that the MR transverse relaxation time T2 has reduced with the increase in NP concentration, while signals on MR T2-weighted image have enhanced [29].

Chitosan (CS), a surface modification of cationic polymer also can render excellent water solubility and stability for magnetic NPs. Lactobionic acid (LA) modification allows them to bind with hepatic cell surface receptor, thus being phagocytosed by hepatic cells. After superparamagnetic iron oxide NPs (CS-LA@SPION) modified with CS and LA together were injected into nude mice, MRI showed remarkably lowered T2-weighted image in the liver within 1 h after, which indicated they can be used as liver-targeted MRI contrast medium [30]]. Applying PEG to modify Fe₃O₄ NPs and then coupling them with chloride channel buthotoxin (CTX), Sun et al. prepared glioma nanoprobe. It was shown in MRI that such nanoprobe could effectively bind with glioma cells [31]. Another study showed that NP-PEG-CTX-Cy5.5 nanoprobe prepared by using Fe₃O₄ NPs as core and then coating the core with PEG, subsequently binding it with fluorescence molecules Cy5.5 and CTX, could not only be used for MRI of glioma but also could be detected by fluorescence microscopy [32]. Anbarasu et al. labeled the PEG-coated Fe₃O₄ NPs with monoclonal antibody and then planted it into the colon cancer mouse model. They successfully conducted targeted localization by MRI [33]. In addition, adding metallic elements such as Mn and Zn into the nanometer ferrite structure can change the properties of NPs [33], enhancing the magnetism of NPs (such as Mn_0.5Zn_0.5Fe₂O₄ and Mn_0.6Zn_0.4Fe₂O₄), increasing the transverse relaxation time of ferrite NPs, elevating the T2 MRI imaging contrast, darkening the T2-weighted image, and it thus can be better applied in MRI [34].

Stem cell has attracted extensive attention in research on biomedicine owing to its excellent proliferative capacity and differentiation potential. In this way, an effective, nontoxic and stable cell labeling is required to better investigate the treatment mechanism of stem cell and to monitor differentiation and migration of stem cells. Currently, there are two methods to label stem cells using the superparamagnetic NPs. One is cell surface labeling and the other one is intracellular labeling. It was discovered that cell surface labeling is likely to be eliminated by the reticuloendothelial system (RES). In comparison, intracellular labeling has certain requirements on the concentration of NPs. Its effective safe concentration was 20–25 mg/L [35]. In the glioma mouse experiment, after superparamagnetic NP-labeled stem cells were injected into the mouse, labeled stem cell migration could be observed in the mouse under MRI within 10 days after injection. Furthermore, cells injected into the tumor tissue were identified histologically to be the superparamagnetic NP-labeled stem cells. The function and activity of these cells are not affected, suggesting that superparamagnetic NPs can be used for labeling stem cells [36].

Currently, most research on targeted therapy for tumor is based on single point. But the therapy effect of most targeted therapy based on single point is poor. Therefore, it remains a challenge to research and develop multitarget therapy for tumor cell, so as to further improve the efficacy of such therapy on tumor. As we all know, tumor tissue is associated with exuberant angiogenesis. Consequently, combined application of targeted magnetic induction thermotherapy targeting tumor cell and tumor vascular hyperplasia endothelial cell may contribute to enhancing the efficacy. Additionally, some genes overexpress in multiple tumors. For instance, CD44 excessively expresses in tumors in the reproductive system, digestive system, and respiratory system. If general targeted molecular probe is designed, the development of research in the field of tumor molecular imaging diagnosis may be greatly promoted. However, there is still a long way to go for developing a general gene-targeted probe due to the mutagenicity of tumor cell.

5. Research on Magnetic NPs as Vectors

Gene therapy is a treatment by transferring the exogenous gene or gene fragment into the target gene of patient [37]. It is another novel treatment for tumor after traditional surgery, radiotherapy, and chemotherapy [38]. But gene transfer method with safety, efficiency, and controllability is the key for gene therapy [39]. DNA is extremely unstable inside and outside the cell and is likely to be degraded by nucleotidase. Stably transferring exogenous gene into target cell for gene therapy depends on the gene transfer system [40], and stable and effective gene vector is of importance to gene therapy [41].

Gene vectors can be classified into two types, the viral and nonviral vectors. Viral gene vectors, such as adenovirus, herpes simplex virus, and smallpox virus [42], can transfer the target gene into cell by viral vector for gene expression [43]. Viral vector is linked with high transfection efficiency. However, it has the drawbacks of immune response, limited number of genes carried by virus, unavoidable random insertion of viral vector into the host chromosome during gene transfer, and high expenses [44]. In Europe, one gene therapy using viral vector has been applied in clinics, but its treatment expenses are as high as 1 million dollars [45]. All these unfavorable factors have restricted the extensive application of viral vector. Therefore, nonviral gene vector research has attracted wide attentions.

The common nonviral gene vectors include cationic liposome, cationic polymer, and NPs. Liposome and polymer are two gene vectors that are extensively applied. The structure and size of cationic liposome binding with DNA are related to its transfection efficiency [46]. Most nonviral gene vectors have low transfection efficiency, which lack targeting. PEI is the common cationic liposome, and its positive charge can absorb DNA, thus forming the structure similar to core-shell, which can maintain DNA stability.

Nanocarriers have attracted increasing attention with the booming of nanotechnology. NPs can be easily modified and have excellent biocompatibility and little immune response. They are likely to enter tissue after coupling with related ligands or antibodies, thus binding with the cell surface-specific receptors or specific antigens. Alternatively, they can be phagocytosed by target cell and thereby enter the cell to realize DNA transfer. Studies have shown that some nanocarriers modified specifically have high gene transfer efficiency [47]. Magnetic NPs can carry out directional movement under the action of AMF, thereby enhancing the transfer efficiency. Moreover magnetic NPs can be used as vectors to bind with biomolecules by magnetic separation. These biomolecules can separate from vectors under the action of applied magnetic field, thus contributing to achieve the goal of targeted therapy.

It was discovered that doxorubicin magnetic NPs (DOX MNPs) can remarkably increase DOX uptake by glioma cells in the magnetic field. MTT assay revealed that death rate of tumor cells after DOX MNP uptake is notably higher than that after DOX uptake only [48].The Fe3O4 @Alg-GA NPs synthesized and modified by sodium alginate and D-galactosamine can enhance their uptake by human hepatoma cells under the action of AMF. Moreover, they can produce the heating effect and kill 95% cells [49]. A research on pancreatic cancer showed that chemotherapeutic DOX can be rapidly transferred and released in pancreatic cancer cells by using superparamagnetic iron oxide (SPIO) NPs as the vectors monitored under electron microscope, X-ray, and optical microscope [50]. As we all know, most chemotherapeutics cannot pass the blood brain barrier (BBB). But a novel administration route has been discovered in brain tumor animal experiment. When paclitaxel- and curcumin-targeted therapies were carried out in glioma mouse using the DL-lactic acid-glycolic acid (PLGA) magnetic NPs, the chemotherapeutics could rapidly pass the BBB by the vectors [51]. In a research on colon tumor, PEG was applied in modifying the uperparamagnetic ferrite core and then connected with the amino terminal fragment hATF of human recombinant protein, forming the targeted probe hATF-SPIO with the diameter of about 30 nm. It was demonstrated that the probe can specifically bind with uPAR-expressing tumor cells in vitro and develop in a targeted manner in the colon tumor animal models with moderately expressed uPAR [52]. With the development of nanosensor technology, hepatitis viruses in human blood can be quantitatively detected [53]. In the quantitative detection of tumor markers, immunosensor has considerable potential in the early detection of tumor [54].

With regard to the toxicity of magnetic NPs, many studies demonstrate that most superparamagnetic NPs have excellent biocompatibility. But some other studies indicate that NPs have toxicity to neurons and glial cells and the toxicity is related to the compounds modified on the surface of magnetic NPs [55].

6. Tumor-Targeted Thermotherapy of Magnetic Nanometer Materials

Thermotherapy is a method to kill tumor cells with thermal energy at a certain temperature. It can be applied alone and also can be used in combination with other therapies such as surgery, radiotherapy, and chemotherapy, exerting good synergistic effect [56]. It is reported that the therapeutic efficacy of paclitaxel can increase by 10–100 folds at 43°C for 30 min. In addition, the killing capacity of chemotherapeutics with low cytotoxicity under normal temperature can be doubled after heated [57]. Jordan et al. [58] first applied magnetic NPs in tumor thermotherapy and invented magnetic fluid thermotherapy (MFH). Magnetic fluid is a liquid magnetic material, which possesses magnetic properties as well as water solubility. It is appropriate for clinical application. Under an AMF, the nanoparticle core of magnetic fluid can transform the magnetic energy into thermal energy, which can stably elevate the temperature of tumor tissue, thus inhibiting tumor growth or killing tumor cell or inducing tumor cell apoptosis [59–61].

Generally, tumor tissue is associated with rapid angiogenesis, which may result in incomplete structure of the capillary wall, disordered branch and distorted structure and fragility. With the addition of tumor compression, the above factors may lead to circulation blocking. Moreover, during magnetic thermotherapy for tumor, thermal dissipation is slow in tumor cells, which together with circulation blocking may give rise to local anaerobic metabolism. Consequently, the cancer cells are more sensitive to heat than normal cells [62]. Thermotherapy may kill tumor cells by reducing vascular endothelial cell regeneration to destroy vascular structure [63], reducing enzyme system activity on the tumor cell membrane, destroying mitochondrion resulting in energy supply disorder [64], inhibiting the activities of DNA polymerase and ligase in tumor cells resulting in DNA and RNA synthesis being disordered and regulating the expression of apoptosis-related genes to induce cell apoptosis [65]. Temperature at 42–45°C is considered to be the appropriate temperature for tumor thermotherapy, which can kill tumor cells, with no injury to normal tissues.

The magnetism of magnetic fluid depends on magnetic particles, among which Fe₃O₄ is the most extensively used magnetic fluid material. The magnetism of Fe₃O₄ nanoparticles can be enhanced by adding some metallic elements such Mn and Zn during preparation. By adjusting the proportion of Mn and Zn, the temperature-sensitive Mn_xZn_1-xFe₂O₄ (Mn Zn ferrite) invented in Southeast University can transform magnetic energy into thermal energy below the Curie temperature under the action of AMF, thus elevating the temperature. But when the temperature arrives at the Curie temperature, it becomes a nonmagnetic material, stopping absorbing magnetic energy, thus decreasing the temperature. So cyclically, the temperature always maintains around the Curie temperature [66]. In this way, such Mn Zn ferrite NPs are endowed with the self-controlled temperature ability. Moreover, the Mn Zn ferrite NPs have numerous advantages during magnetic thermotherapy, such as thermal bystander effect, universality, high-characteristic absorption rate, constant temperature, and excellent biocompatibility. MFH can effectively destroy cancer cells, with no injury to normal cells. It is considered as one of the most promising cancer therapies. A study on the safety of Mn Zn ferrite NPs indicated that the hemolytic rate of Mn Zn ferrite magnetic fluid was 1.0429% and the LD₅₀ was 7.186 g/kg. The bone marrow micronucleus formation rate had no significant difference between the experimental group and the negative control group [67].

It is discovered in a hepatoma cell research that when the constructed P[5HRE] AFPp-p53/PEI-Fe304 magnetic NPs were used to mediate gene therapy combined with MFH, they could distinctly suppress the proliferative activity of hepatoma HepG2 cells. The effect was markedly superior to that in control the NP group and negative control group [68]. Xie et al. [69] modified Mn Zn ferrite NPs (Mn_0.5Zn_0.5Fe₂O₄) with PEG lipid molecules through hydrophobic interaction. Such nanoparticles with core-shell structure rendered high magnetism, strong alternating magnetothermal effect, and good biocompatibility. In the early symptom liver metastasis mouse model of colorectal cancer, the oleic acid-wrapped ferrite RGF polypeptide complex (Fe₃O₄@PMAO_RGD) was injected into the hepatic artery to bind with the surface αVβ3 receptor of the tumor cell and then MFH was conducted under the action of AMF. It was found that the activity of colorectal cancer liver metastasis tumor cells was remarkably lowered [70]. Combined therapy of MFH with targeted chemotherapy and (or) gene therapy had shown a promising application prospect in the diagnosis and treatment for tumor. Using Mn0.5Zn0.5Fe2O4 as vector, Lin et al. combined radionuclide, suicide gene, and MFH organically to treat liver cancer. The results indicated an excellent effect, and the tumor inhibition rate of the combined therapy group was remarkably higher than that of any other single therapy [71]. Another research showed that magnetic cAs₂O₃/Fe₂O₃ nanocomposites adopted to thermochemotherapy for hepatoma had an evident higher effect than that of the single thermotherapy and the As₂O₃ chemotherapy alone and the equivalent dosage of chemotherapeutics was greatly lowed and has few side effects [72].

7. Problem and Prospect

With the development of nanoscience and nanotechnology, the research and application of magnetic NPs have made considerable progress in the biomedical field. For example, magnetic NPs have been extensively applied in biomolecule vectors, targeted localization, MRI, and thermotherapy. However, most studies remain at the laboratory research stage, and few have really been applied in clinics. Their toxicity, side effects, long-term efficacy, and in vivo metabolic mechanism still need to be further studied. A large amount of basic and clinical research needs to be done for their clinical application. Confidently, magnetic NPs will have a broad application prospect in the medical field, with the increasing development and the further intensive research of nanotechnology, biotechnology, and medicine.

Conflicts of Interest

The authors declare that there is no conflict of interests.

Acknowledgments

This work is financially supported by the National Natural Science Foundation of China (81571797), the 333 Plan Foundation of Jiangsu, China (BRA2017173), and the project of Taizhou People’s Hospital (ZL201734).

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Copyright © 2018 Ting Guo et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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