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 Table of Contents  
REVIEW ARTICLE
Year : 2018  |  Volume : 131  |  Issue : 6  |  Page : 721-730

Imaging Gliomas with Nanoparticle-Labeled Stem Cells


Department of Neurosurgical Oncology, The First Hospital of Jilin University, Changchun, Jilin 130021, China

Date of Submission04-Dec-2017
Date of Web Publication9-Mar-2018

Correspondence Address:
Prof. Gang Zhao
Department of Neurosurgical Oncology, The First Hospital of Jilin University, Changchun, Jilin 130021
China
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/0366-6999.226900

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  Abstract 


Objective: Gliomas are the most common neoplasm of the central nervous system (CNS); however, traditional imaging techniques do not show the boundaries of tumors well. Some researchers have found a new therapeutic mode to combine nanoparticles, which are nanosized particles with various properties for specific therapeutic purposes, and stem cells for tracing gliomas. This review provides an introduction of the basic understanding and clinical applications of the combination of stem cells and nanoparticles as a contrast agent for glioma imaging.
Data Sources: Studies published in English up to and including 2017 were extracted from the PubMed database with the selected key words of “stem cell,” “glioma,” “nanoparticles,” “MRI,” “nuclear imaging,” and “Fluorescence imaging.”
Study Selection: The selection of studies focused on both preclinical studies and basic studies of tracking glioma with nanoparticle-labeled stem cells.
Results: Studies have demonstrated successful labeling of stem cells with multiple types of nanoparticles. These labeled stem cells efficiently migrated to gliomas of varies models and produced signals sensitively captured by different imaging modalities.
Conclusion: The use of nanoparticle-labeled stem cells is a promising imaging platform for the tracking and treatment of gliomas.

  Abstract in Chinese 

纳米颗粒标记干细胞对胶质瘤进行成像的最新进展

摘要

目的:胶质瘤是中枢神经系统最常见的肿瘤,传统的显像方式对其边缘显像欠佳。有学者发现可通过利用具有纳米级别尺寸和针对特定治疗目的具有多种属性的纳米颗粒与干细胞相结合,从而对胶质瘤进行示踪。本文对利用纳米颗粒标记干细胞作为胶质瘤成像的显像剂这一策略进行了文献综述,并介绍其基本原理和临床应用。

数据源: 本文利用PubMed数据库对包括2017年以前的文献通过“干细胞”、 “胶质瘤”、 “核磁共振”、 “核成像”以及“荧光成像”等关键词进行文献筛选。

研究选择: 本文对纳入了有关纳米颗粒标记干细胞对胶质瘤进行成像的基础研究和临床前研究。

结果: 许多研究表明,纳米颗粒可成功地对干细胞进行标记。被标记的干细胞在不同胶质瘤模型中可有效地向胶质瘤迁移、产生信号并用多种影像学技术进行成像。

结论:利用纳米颗粒标记的干细胞是一种对胶质瘤进行显像和治疗的具有应用前景的技术平台。

Keywords: Glioma; Nanoparticle; Stem Cell


How to cite this article:
Deng SL, Li YQ, Zhao G. Imaging Gliomas with Nanoparticle-Labeled Stem Cells. Chin Med J 2018;131:721-30

How to cite this URL:
Deng SL, Li YQ, Zhao G. Imaging Gliomas with Nanoparticle-Labeled Stem Cells. Chin Med J [serial online] 2018 [cited 2018 Dec 10];131:721-30. Available from: http://www.cmj.org/text.asp?2018/131/6/721/226900




  Introduction Top


Gliomas are the most common neoplasm of the central nervous system (CNS), and poorly differentiated gliomas present invasive growth patterns. Patients with glioblastomas, the most malignant type, have been reported to exhibit a very low 5-year survival rate, and median survival times are only 12–24 months.[1] Compared to the breakthroughs in the treatment of many other cancers, the progresses of glioma therapies remain almost stagnant. The combination of microsurgery, with the latest chemotherapy such as temozolomide and radiation therapy with optimized designs, have not further significantly postponed disease recurrence in glioblastoma patients.[2],[3] Clinical evidence suggests that 80–90% of glioma recurrences occur within the original resection field.[4] Instead of removing the entire anatomical unit of the malignant organ, modern oncological neurosurgery focuses on maximizing the resection of the tumor by its subjectively judged margins, while protecting as many neural functions as possible. To obtain maximal resection and maximal protection, there is an urgent need for advances to be made to push the imaging accuracy of the lesions to a higher level for better treatment outcomes. Most recent examples of such advances have originated from the adoption of advanced imaging techniques to replace or reinforce the traditional ones, such as the integration of intraoperative magnetic resonance imaging (MRI), nuclear imaging, and fluorescence imaging modalities into surgeries. On the other hand, as the core of various types of imaging modalities, breakthroughs in the field of study of imaging agents to provide more accurate signals of the malignancies could extensively increase the efficacy of the treatment.

Nanoparticles of 1–100 nm in diameter [5] can be tailored and utilized as contrast agents for gliomas. The growth of glioma cells actively affects the integrity of the blood-brain barrier (BBB)[6] and invades the neurovasculature to cause these blood vessels to have a leaky nature during glioma development. Nanoparticles with tunable properties regarding their size, shape, and surface functionalization can greatly improve the factors affecting the contrast efficacy. With their controllable size, nanoparticles can gain a higher passage through a compromised BBB [7] and, together with shape and functionalization tailoring, can lead to a drastically increased circulation for an enhanced permeability and retention effect. Certain nanoparticles such as iron-based nanoparticles have an additional biological effect because iron metabolism itself is a normal physiological process; thus, contrast elimination follows normal physiology as well. Moreover, compared with traditional contrast agents such as gadolinium, they have shown advantages in terms of a slower elimination, more effective magnetic resonance relaxation, a better safety profile due to metabolization through the normal iron metabolism pathway, and better delineation of tumor margins possibly resulting from cellular uptake and aggregation of iron.[8],[9],[10]

Heterogeneity is a very important hallmark of high-grade gliomas as well as the trickiest problem in glioma management. Similar to glioma cell heterogeneity, the vasculature and BBB impairment throughout the entire tumor are inhomogeneous.[11],[12] This leaves a fatal flaw for conventional methods of nanoparticle contrast agent administration, as there always will be portions of gliomas without BBB impairment for nanoparticles to reach the tumor efficiently.[13] Studies that focus on facilitating the passage of nanoparticles through the BBB via receptor-mediated transcytosis [14] and adsorptive-mediated transcytosis [15] targeting specific glioma cell ligand molecules still lack the ability to cope efficiently with glioma cell heterogeneity, mutations, and evolution. One possible solution to the current limitations of nanoparticle-based glioma imaging contrast agents is the incorporation of cellular carriers to generate a dual-system platform. The rationale of this system originates from the discovery that stem cells, including neural stem cells (NSCs) and mesenchymal stem cells (MSCs), have an intrinsic ability to migrate to different pathologies such as inflammation, infarction, and tumors.[16],[17],[18],[19] Furthermore, there is also evidence that NSCs efficiently track glioma stem cells;[20] thus, the inability of nanoparticle contrast agents to reach escaped glioma stem cells could potentially be solved by the application of stem cells such as NSCs for active tracking. This review aims to describe the mechanism of this combination and to summarize its preclinical applications with the major imaging modalities for a more precise imaging of gliomas, which might potentially augment the current surgical protocol for the management of this disease [Figure 1].
Figure 1: Nanoparticle-labeled stem cells migrate across BBB toward glioma cells for imaging. Stem cells such as NSC or MSC could be labeled with nanoparticles loaded with imaging agents. Administered via venous or intracerebral injection, the transplanted labeled stem cells could transmigrate through BBB and home toward glioma cells and glioma stem cells, while emitting or producing imaging signals which could be captured by different imaging techniques including MRI, SPECT, NIR, and confocal microscopy. AuNP: Gold nanoparticle; MSN: Mesoporous silica nanoparticle; MNP: Magnetic nanoparticle; BBB: Blood-brain barrier; NSC: Neural stem cells; MSC: Mesenchymal stem cells; NP: Nanoparticle; MRI: Magnetic resonance imaging; SPECT: Single-photon emission computed tomography; NIR: Near infrared; SDF-1/CXCR4: Stromal derived factor-1/C-X-C chemokine receptor type 4.

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  Basic Rationale for Nanoparticle Stem Cell Carriers: The Tropism of Stem Cells Toward Glioma Top


NSCs and MSCs are currently the focus in the study of nanoparticle stem cell carriers in tracking gliomas. NSCs are the progenitor cells giving rise to the three major lineages of cells in the CNS,[21] and their migration capability during embryo development [22] is preserved throughout adulthood at certain CNS locations, thus retaining their neuroplasticity.[23],[24] The initial evidence of NSC glioma tropism was the striking discovery in the D74 and CNS-1 model of intracerebrally or intravenously administered migrating NSCs.[25] The phenomenon was later confirmed by numerous studies and quantified, with an estimated 70–90% coverage of the glioma tumor mass and the invasive tumor foci.[26],[27],[28],[29] Moreover, one recent study conducted an investigation into the quantification of NSC coverage in glioma tissue via different administration routes; they reported a homing rate of 50–60% of transplanted stem cells with intracerebral administration and 1.5% with intravenous administration. The coverage in the glioma sections could reach as high as 100% with intracerebral administration and 70% with intravenous administration.[30] Other studies on this topic have further developed the research on NSC-based drug administration,[31],[32] gene therapy,[33],[34] and application of the bystander effect.[35],[36],[37] Conversely, the incorporation of nanomedicine to NSCs has led to extensive research in this realm, including the effect of nanomaterials on NSC biology,[38],[39],[40],[41] enhanced material loading,[42],[43],[44],[45] stem cell tracking,[46],[47],[48],[49],[50],[51] and tumor treatment.[32],[52]

A huge challenge with the broad application of NSCs is the scarcity of its source, mainly fetal cells or autologous CNS cells from the patient. Immortalized cell lines with oncogenes [53] again raise safety concerns in transplantation.[54] As an alternative, MSCs with a broader source, including bone marrow-cultured cells [55] and other tissues,[56],[57],[58],[59],[60],[61] and an easier expansion protocol [61],[62] have been quantified to show a similar glioma-specific migration capability with slightly more nonspecific migration in multiple glioma cell lines and specimens.[17],[63] One drawback of MSCs exists, which is their inability to track glioma stem cells at a resting state.[64]

The mechanism of glioma tropism is partly shared by NSCs and MSCs. Stromal cell-derived factor 1, together with its receptor C-X-C chemokine receptor type 4 (CXCR4), has been confirmed as one of the most critical factors mediating the tropism.[65] Other mechanisms dictating the tropism include glioma extracellular matrix remodeling and hypoxia for NSCs [66] as well as glioma interleukin-8, platelet-derived growth factor-BB, and transforming growth factor-beta production for MSCs.[67],[68] Regarding the alternative sources of MSCs, one recent study has compared the migratory capacity toward glioma-conditioned medium between bone marrow-derived, adipose-derived, and synovial fluid-derived MSCs, among which synovial fluid-derived MSCs presented the strongest migration capacity. Activated lymphocyte cell adhesion molecule and N-cadherin were confirmed as participants of the responsible mechanisms, and they could be upregulated by microRNA-192 and -218 downregulation.[60]

Stem cells and cancer cells have diverse interactions based on the histological origin of the latter. While the cancer-promoting effect of stem cells has been observed in malignancies such as breast cancer [69] as well as head and neck cancers,[70] the existing evidence has generally supported the use of transplanted NSCs and MSCs as safe therapeutic platforms to treat gliomas. Several recent studies have suggested their inhibitory effects against gliomas, such as the reported study of NSCs directly inhibiting the invasion and proliferation of gliomas [71] and their association with a survival benefit.[72] Transplanted MSCs also have been reported to improve the survival of rats with U87MG xenografts, showing a reduction in tumor growth, cell proliferation, and microvascular density [73] as well as a cytotoxic effect toward C6 glioma cells through gap junctions.[74] Contrary to this evidence, the tumor-promoting effect of MSCs from certain sources cannot be completely ignored. One study published in 2016 investigated the effect of the secretome from adipose-derived stem cells on glioblastoma cells, which increased the migration capacity of the malignant cells.[75] Hence, caution is still needed in order to apply the homing capacity of stem cells for glioma treatment.


  Glioma Imaging Modalities and Labeling Nanoparticles for Stem Cells Top


Magnetic resonance imaging and magnetic nanoparticles

Magnetic nanoparticles

Upon its first development, iron-based nanoparticles, usually termed magnetic nanoparticles (MNPs), have shown potential for a wide range of applications as imaging contrast agents and therapeutic carriers. The so-called MNPs usually consist of nanoparticles with a magnetic core composed of magnetite (Fe3O4) or maghemite (Fe2O3), containing of a type of product termed superparamagnetic iron oxide nanoparticles (SPIONs). Miniaturizing the iron oxide particles to certain sizes in which each particle consists of a single magnetic domain with thermal energy high enough to overcome the energy barrier of magnetic flipping could generate local interactions with water protons that can induce proton dephasing and shorten transverse T2 relaxation.[76],[77] Thus, the aggravation of these iron oxide particles causes a reduced signal that is easily detected on the MRI T2 sequence, achieving a contrast effect. Multiple methods to synthesize iron oxide nanoparticles exist, including coprecipitation,[78] thermal decomposition,[79] and microemulsion,[80] which generally yield hydrophobic particles; therefore, different coatings to enhance biocompatibility are often needed. In the specific scenario of labeling stem cells with MNPs to track gliomas, the choice of the labeling agent depends on several factors. This often involves the selection of iron cores of different sizes and coatings to balance between imaging sensitivity and potential toxicity as well as the addition of different types of transfection methods to ensure proper carriage of the MNPs without leaking to scavengers such as macrophages, thus causing false positivity.

Labeling with standard superparamagnetic iron oxide nanoparticles

SPIONs can be categorized into three classes: standard SPIONs (50–180 nm), ultra-small superparamagnetic iron oxide-based nanoparticles (USPIONs, 10–50 nm), and very small SPIONs (<10 nm). The earliest application of labeling stem cells to track gliomas with SPIONs can be dated back to 2005. In this study, a standard SPION was applied to label endothelial precursor cells to track local glioma angiogenesis. After systemic administration, the labeled stem cells were distributed as a hypointensive dark ring circumscribing the glioma rim on both in vitro and in vivo MRI at about day 10.[81] A similar study imaged glioma angiogenesis using SPION-labeled human cord blood endothelial progenitor cell AC133 cells to track C6 gliomas in rats, and linear hypointense regions in the tumor could be observed at the periphery and the center of the tumor mass when reaching 1 cm, or 7 days after transplantation.[82] The standard SPION used in these two studies was Ferumoxide, which was initially approved by the U.S. Federal Drug Administration as an MRI contrast agent. Ferumoxide is a type of SPION coated by dextran with a hydrodynamic diameter of approximately 100 nm. The particles are biodegradable after entering into the body by joining the iron metabolism pathway and are eventually incorporated into hemoglobin in red cells within 30–40 days.[83],[84]

Besides tracking glioma angiogenesis, Ferumoxide also has been proven to label gliomas directly with NSCs and MSCs. With NSCs, it has been reported that more than 95% of the iron cores could be retained in NSCs after tissue culturing for 96 h, and the threshold reached nine labeled cells per voxel or as few as 600 NSCs in 300 μm thick slices to generate a detectable signal reduction on 7T T2-weighted multispin multiecho MRI.[85] This enables detecting U251 gliomas as small as 200–500 μm (resembling residual gliomas) by 7T MRI, with a signal reduction equivalent to that of 1 × 104–2.5 × 105-labeled NSCs, which is not possible by conventional 7T MRI.[85] Similar to NSCs, Ferumoxide could label MSCs with an average uptake of 9 pg of intracellular iron in each cell, which could migrate to the U87 glioma surrounding the tumor periphery and was distributed throughout the main tumor mass, resulting in a significant signal change on MRI.[86]

Enhancing the sensitivity of glioma imaging by standard SPION-labeled stem cells has also been studied. These enhancements include modifying SPION coating with carboxy dextran to enhance cellular uptake,[87] using the transfection agent poly-L-lysine [81] or protamine,[85] increasing the incubation concentration,[86] and doping the core of SPIONs.[88] These methods have increased the sensitivity of imaging and even the stem cell glioma tropism.

Labeling with ultra-small superparamagnetic iron oxide-based nanoparticles

In a study of stem cell labeling to track gliomas, Ferymoxytol was used because Ferumoxide was removed from the market in 2009.[89] Ferymoxytol is a colloidal suspension of carbohydrate-coated second-generation USPIONs and was approved to treat iron deficiency in anemic patients with chronic kidney disease. Compared to standard SPIONs, USPIONs have a longer half-life and are more often applied as an imaging contrast agent; even with gliomas, USPIONs exert a much higher penetration through an impaired BBB to enhance gliomas directly.[90] In a study using NSCs, Ferymoxytol with heparin and protamine sulfate achieved a satisfactory NSC-labeling efficiency and early migration to a U251 glioma xenograft across the midline on days 1–4 after intracerebral administration or 4 days after intravenous administration.[91] Another study also has reported successful transfection of NSCs with USPIONs synthesized in the laboratory with different coatings; in addition, efficient labeling and retention of NSC viability also have been reported.[92]

In labeling MSCs, USPIONs show advantages of more homogenous cell labeling compared with SPIONs as the latter are more prone to aggregation in the culture medium, resulting in localized uptake and nonhomogeneous labeling among the cell population.[93] A recent report has confirmed such labeling with MRI, and MSCs labeled with Ferymoxytol have been shown to migrate successfully in the brain.[94] Furthermore, a quantification study has determined the optimal lower limit of 21 h of incubation and 10 μg of USPIONs/105 MSCs for positive detection with 1.5 Tesla MRI.[95]


  Non-Magnetic Resonance Imaging-Based Imaging Top


Nuclear imaging

As a major nuclear imaging technique, single-photon emission computed tomography (SPECT) adopts γ-rays to image biochemical activities with a three-dimensional output of the imaging information. Conventional radionuclides for SPECT imaging include 111In (half-life, 67 h) and 99 metastable (mTc, half-life, 6 h), and their applications compensate for each other in terms of sensitivity and duration of cell tracking. Compared with conventional contrast MRI, SPECT has a higher sensitivity because the technique can directly record cellular metabolism or other bioactivities as long as the radionuclide tracers are marked correspondingly, instead of relying totally on vasculature abnormalities in the tumors. Some recent studies cover many advances of SPECT for the evaluation of gliomas, such as the assessment of glioma cell response to chemotherapy,[96] monoclonal antibodies,[97] and peptides targeting specific glioma cell markers.[97] The published literature regarding SPECT tracking stem cells mainly uses the direct application of 111In. In labeling MSCs and NSCs, their homing behaviors have thus been scrutinized in terms of neuroblastoma [98] and myocardial infarction.[99] Viability assessment has been reported as unaffected cell viability but a significantly reduced metabolic activity and migration.[100],[101] 111In still shows an advantage over 99mTc as clear evidence exists that the labeling significantly affects stem cell viability.[102]

Mesoporous silica nanoparticles (MSNs) are a type of homogeneously sized porous silica nanoparticles with a pore size ranging from 2 nm to 50 nm. MSNs have large surface areas and pore sizes to load a variety of agents for both therapy and imaging; the pore sizes are adjustable to control the loading and release processes, and the surface can be modified to reduce toxicity. MSNs also have shown good biocompatibility and thermal/hydrothermal stabilities.[103] These features make MSNs another important tool for glioma therapy and diagnosis. Currently, several types of radioisotopes have been studied for loading MSNs, including zirconium-89,[104] copper-64,[105] Ho-165,[106] fluorine-18,[107] and 111In.[108] For 111In as a SPECT isotope, one recent study has described the application of 70 nm MSNs in NSC labeling and glioma homing. MSNs were radiolabeled with 111In with a labeling efficiency of 95% and an average activity of 21.2 MBq/mg. NSCs were then uploaded with MSNs with an efficiency of 58% and a viability slightly affected by the 111In component of the MSN complex. Three-dimensional views of SPECT images revealed very early signs of NSC migration to the U87MG glioma xenograft at 4 h after cerebral injection of the labeled NSCs, and the signals were sustained at the tumor site for 2 days. Furthermore, systemic administration of MSN-labeled NSCs successfully migrated to the tumor site in 48 h with a peritumoral and partial intratumor distribution; compared with intracerebral administration, this finding is consistent with NSC dynamics crossing the BBB.[108] These results clearly indicate a significant sensitivity of SPECT in dynamic monitoring of NSC glioma tropism compared to MNP-based MRI monitoring, which has not been reported for very early stem cell migration.

Fluorescent imaging

Near-infrared imaging

Imaging modalities on a subcellular level are not usually a capability of conventional clinical imaging techniques such as MRI and positron-emission tomography (PET)/SPECT; therefore, they sometimes fail to provide a high-contrast image of pathologies at an early stage. Fluorescence imaging captures the light signal emitted by living cells with bioluminescent sources at a certain wavelength in response to excitation of light of a different wavelength. Among this type of imaging technique, near infrared (NIR) imaging achieves a higher penetration depth of up to several centimeters and provides more specific signals by capturing light of a NIR wavelength.[109],[110] Thus, this technique holds broad application potential in the in vivo imaging of physiological, metabolic, and molecular functions. NIR imaging requires NIR probes to emit a light signal under excitation. Currently, several categories of probes have been studied, which generally include organic NIR dyes such as cyanine dyes, rhodamine dyes, BODIPY-based NIR probes, squaraine-based NIR probes, phthalocyanines and porphyrin derivatives, and nanoprobes such as NIR dye-containing nonmetallic nanoparticles, gold nanostructures, and quantum dots.[111]

Several aspects of stem cell NIR imaging with nanoprobes have been described. NIR imaging of cardiac progenitor cells has been reported to track ischemic hearts,[112] adipose-derived stem cells in Alzheimer's disease,[113] and MSCs in a Parkinson's disease model.[114] For glioma imaging, a recent report by Kim et al.[115] offers the detailed tracking progress under NIR. MSCs labeled with fluorescent magnetic NEO-LIVE™-Magnoxide 675 nanoparticles were administered to a U-87MG glioma model with intravenous delivery. According to the study, the injected MSCs predominantly resided in the lung at the early stage, and then later migrated to the spleen and liver. Four days after MSC administration, the bioluminescence signal could be observed in the location of the tumor and was maintained until 7 days after injection, indicating MSC migration.[115] This successful example shows the value of NIR nanoparticle-labeled stem cells for glioma imaging.

Two-photon microscopy

Two-photon microscopy is another imaging modality based on fluorescence that uses infrared light. The advantage of two-photon microscopy compared with other fluorescence imaging modalities is that it uses the combination of the energy of two photons using a pulsed laser of high peak power to compact photons, therefore leading to higher chances of two photons simultaneously hitting the fluorophore. This achieves reduced background noise, photo-damage/toxicity, and photo-bleaching, which is more commonly encountered in NIR, and offers a high three-dimensional resolution of the observed tissue to observe cellular interactions as well as cells and structures at much higher depths within the tissue.[116] Zhang et al.[117] have reported the utility of MSCs with two-photon microscopy. They used gold nanocages to label MSCs. Gold nanoparticles or nanostructures have become another interest in the realm of nanomedicine in recent years because of their attractive optical properties known as localized surface plasmon resonance (LSPR), which is the scattering and absorption of light at resonant wavelengths due to the excitation of plasmon oscillations. Of the different types of gold nanostructures, gold nanocages can be readily tuned to have a LSPR peak in the NIR region that covers the transparent window of soft tissues to maximize the tissue penetration depth, increasing its clinical applicability.[118] In a recent report, gold nanocage-labeled MSCs did not significantly affect the cell viability or differentiation capacity, while they were distributed in the cytoplasm encompassed by endosome-like structures. A significant result of this study was the confirmation of the long-term stable retention of AuCN in the MSCs as the particles did not participate in cellular metabolism as with iron oxide MNPs. An increased two-photon intensity could be observed after the MSCs were injected into the tail vein and migrated to the subcutaneously implanted U87MG cells.[117]


  Perspectives Top


In this review, we briefly summarized the basic biology and mechanisms of stem cell glioma tropism. Numerous studies focusing on different imaging techniques and nanoparticle-labeled stem cells have been successfully performed [Table 1]. MNP labeling and imaging by MRI was a main focus. In addition, SPECT nuclear imaging, NIR fluorescence imaging, and two-photon microscopy possibly show a higher sensitivity than MRI. The reported studies describing these different imaging modalities presented different considerations, advantages, and limitations related to the complexity the labeling process, the effect of labeling on stem cell viability and migration, labeling efficiency, time from stem cell administration to the appearance of a positive signal at the tumor site, and the duration of positive signals in glioma models. These factors support the potential combination of these imaging modalities in clinical applications at every step of glioma therapy, as the whole process provides a gradually deepened understanding from gross anatomy to cellular and molecular biology. The integration of the applications of these modalities involves the combination of MRI and SPECT/PET in preoperative diagnosis, choosing the operation procedure, intraoperative surgery guidance, and postoperative residual tumor evaluation, forming an intact surgical evaluation and useful system. Another integration encompasses the combination of NIR with surgical microscopy for real-time optical detection of the tumor local infiltration, a concept that has already been demonstrated in several studies.[121],[122],[123] For these integrations to be effective, the stem cell platform and the nanoparticle used for labeling should be selected carefully for specific applications based on the different labeling and imaging characteristics of nanoparticles as well as the different glioma tropism between different stem cells. Therefore, studies to compare and quantify each of these factors under a standardized study protocol are warranted. Further studies focusing on stem cell glioma tropism, especially for the ability to cope with glioma heterogeneity and the active/quiescent state of glioma stem cells, are needed to figure out flaws of the platform and then to deal with these issues. Moreover, the development of multifunctional nanoparticles is required to enable simplified labeling of stem cells to label functions suitable for different imaging modalities simultaneously.
Table 1: Summary of preclinical studies of nanoparticle-labeled stem cell glioma tracking

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The dual-system imaging platform of stem cells labeled with nanoparticles is a powerful imaging tool that is applicable for various imaging modalities. Instead of totally relying on neurovascular and BBB leakage, nanoparticle-labeled stem cells bypass these restrictions and directly trace glioma cells and glioma microenvironment alterations, providing the option of nanoparticles and the corresponding imaging modalities to determine early glioma development and residual tumors, even tracing and imaging single cells. To improve the diagnosis and prognosis of gliomas, this platform needs to be further studied in clinical trials or used in clinical work.

Financial support and sponsorship

This work was supported by a grant from the Youth Development Foundation of the First Hospital of Jilin University (No. JDYY72016054).

Conflicts of interest

There are no conflicts of interest.



 
  References Top

1.
Gupta T, Sarin R. Poor-prognosis high-grade gliomas: Evolving an evidence-based standard of care. Lancet Oncol 2002;3:557-64. doi: 10.1016/S1470-2045(02)00853-7.  Back to cited text no. 1
    
2.
Chamberlain MC. Radiographic patterns of relapse in glioblastoma. J Neurooncol 2011;101:319-23. doi: 10.1007/s11060-010-0251-4.  Back to cited text no. 2
    
3.
Dobelbower MC, Burnett Iii OL, Nordal RA, Nabors LB, Markert JM, Hyatt MD, et al. Patterns of failure for glioblastoma multiforme following concurrent radiation and temozolomide. J Med Imaging Radiat Oncol 2011;55:77-81. doi: 10.1111/j.1754-9485.2010.02232.x.  Back to cited text no. 3
    
4.
Petrecca K, Guiot MC, Panet-Raymond V, Souhami L. Failure pattern following complete resection plus radiotherapy and temozolomide is at the resection margin in patients with glioblastoma. J Neurooncol 2013;111:19-23. doi: 10.1007/s11060-012-0983-4.  Back to cited text no. 4
    
5.
Hernández-Pedro NY, Rangel-López E, Magaña-Maldonado R, de la Cruz VP, del Angel AS, Pineda B, et al. Application of nanoparticles on diagnosis and therapy in gliomas. Biomed Res Int 2013;2013:351031. doi: 10.1155/2013/351031.  Back to cited text no. 5
    
6.
Upadhyay N, Waldman AD. Conventional MRI evaluation of gliomas. Br J Radiol 2011;84:S107-11. doi: 10.1259/bjr/65711810.  Back to cited text no. 6
    
7.
Sarin H, Kanevsky AS, Wu H, Sousa AA, Wilson CM, Aronova MA, et al. Physiologic upper limit of pore size in the blood-tumor barrier of malignant solid tumors. J Transl Med 2009;7:51. doi: 10.1186/1479-5876-7-51.  Back to cited text no. 7
    
8.
Manninger SP, Muldoon LL, Nesbit G, Murillo T, Jacobs PM, Neuwelt EA, et al. An exploratory study of ferumoxtran-10 nanoparticles as a blood-brain barrier imaging agent targeting phagocytic cells in CNS inflammatory lesions. AJNR Am J Neuroradiol 2005;26:2290-300.  Back to cited text no. 8
    
9.
Neuwelt EA, Várallyay CG, Manninger S, Solymosi D, Haluska M, Hunt MA, et al. The potential of ferumoxytol nanoparticle magnetic resonance imaging, perfusion, and angiography in central nervous system malignancy: A pilot study. Neurosurgery 2007;60:601-11. doi: 10.1227/01.NEU.0000255350.71700.37.  Back to cited text no. 9
    
10.
Neuwelt EA, Hamilton BE, Varallyay CG, Rooney WR, Edelman RD, Jacobs PM, et al. Ultrasmall superparamagnetic iron oxides (USPIOs): A future alternative magnetic resonance (MR) contrast agent for patients at risk for nephrogenic systemic fibrosis (NSF)? Kidney Int 2009;75:465-74. doi: 10.1038/ki.2008.496.  Back to cited text no. 10
    
11.
Di Ieva A, Grizzi F, Sherif C, Matula C, Tschabitscher M. Angioarchitectural heterogeneity in human glioblastoma multiforme: A fractal-based histopathological assessment. Microvasc Res 2011;81:222-30. doi: 10.1016/j.mvr.2010.12.006.  Back to cited text no. 11
    
12.
Yamada K, Ushio Y, Hayakawa T, Kato A, Yamada N, Mogami H, et al. Quantitative autoradiographic measurements of blood-brain barrier permeability in the rat glioma model. J Neurosurg 1982;57:394-8. doi: 10.3171/jns.1982.57.3.0394.  Back to cited text no. 12
    
13.
Valdiglesias V, Fernández-Bertólez N, Kiliç G, Costa C, Costa S, Fraga S, et al. Are iron oxide nanoparticles safe? Current knowledge and future perspectives. J Trace Elem Med Biol 2016;38:53-63. doi: 10.1016/j.jtemb.2016.03.017.  Back to cited text no. 13
    
14.
Pardridge WM. Drug delivery to the brain. J Cereb Blood Flow Metab 1997;17:713-31. doi: 10.1097/00004647-199707000-00001.  Back to cited text no. 14
    
15.
Hervé F, Ghinea N, Scherrmann JM. CNS delivery via adsorptive transcytosis. AAPS J 2008;10:455-72. doi: 10.1208/s12248-008-9055-2.  Back to cited text no. 15
    
16.
Osaka M, Honmou O, Murakami T, Nonaka T, Houkin K, Hamada H, et al. Intravenous administration of mesenchymal stem cells derived from bone marrow after contusive spinal cord injury improves functional outcome. Brain Res 2010;1343:226-35. doi: 10.1016/j.brainres.2010.05.011.  Back to cited text no. 16
    
17.
Ahmed AU, Tyler MA, Thaci B, Alexiades NG, Han Y, Ulasov IV, et al. A comparative study of neural and mesenchymal stem cell-based carriers for oncolytic adenovirus in a model of malignant glioma. Mol Pharm 2011;8:1559-72. doi: 10.1021/mp200161f.  Back to cited text no. 17
    
18.
Díaz-Coránguez M, Segovia J, López-Ornelas A, Puerta-Guardo H, Ludert J, Chávez B, et al. Transmigration of neural stem cells across the blood brain barrier induced by glioma cells. PLoS One 2013;8:e60655. doi: 10.1371/journal.pone.0060655.  Back to cited text no. 18
    
19.
Feng Y, Yu HM, Shang DS, Fang WG, He ZY, Chen YH, et al. The involvement of CXCL11 in bone marrow-derived mesenchymal stem cell migration through human brain microvascular endothelial cells. Neurochem Res 2014;39:700-6. doi: 10.1007/s11064-014-1257-7.  Back to cited text no. 19
    
20.
Zhang S, Xie R, Zhao T, Yang X, Han L, Ye F, et al. Neural stem cells preferentially migrate to glioma stem cells and reduce their stemness phenotypes. Int J Oncol 2014;45:1989-96. doi: 10.3892/ijo.2014.2629.  Back to cited text no. 20
    
21.
Brüstle O, Spiro AC, Karram K, Choudhary K, Okabe S, McKay RD, et al.In vitro-generated neural precursors participate in mammalian brain development. Proc Natl Acad Sci U S A 1997;94:14809-14. doi: 10.1073/pnas.94.26.14809.  Back to cited text no. 21
    
22.
Namba T, Huttner WB. Neural progenitor cells and their role in the development and evolutionary expansion of the neocortex. Wiley Interdiscip Rev Dev Biol 2017;6:e256. doi: 10.1002/wdev.256.  Back to cited text no. 22
    
23.
Alvarez-Buylla A, Lim DA. For the long run: Maintaining germinal niches in the adult brain. Neuron 2004;41:683-6. doi: 10.1016/S0896-6273(04)00111-4.  Back to cited text no. 23
    
24.
Zhao C, Deng W, Gage FH. Mechanisms and functional implications of adult neurogenesis. Cell 2008;132:645-60. doi: 10.1016/j.cell.2008.01.033.  Back to cited text no. 24
    
25.
Aboody KS, Brown A, Rainov NG, Bower KA, Liu S, Yang W, et al. Neural stem cells display extensive tropism for pathology in adult brain: Evidence from intracranial gliomas. Proc Natl Acad Sci U S A 2000;97:12846-51. doi: 10.1073/pnas.97.23.12846.  Back to cited text no. 25
    
26.
Liu S, Yin F, Zhao M, Zhou C, Ren J, Huang Q, et al. The homing and inhibiting effects of hNSCs-BMP4 on human glioma stem cells. Oncotarget 2016;7:17920-31. doi: 10.18632/oncotarget.7472.  Back to cited text no. 26
    
27.
Yamazoe T, Koizumi S, Yamasaki T, Amano S, Tokuyama T, Namba H, et al. Potent tumor tropism of induced pluripotent stem cells and induced pluripotent stem cell-derived neural stem cells in the mouse intracerebral glioma model. Int J Oncol 2015;46:147-52. doi: 10.3892/ijo.2014.2702.  Back to cited text no. 27
    
28.
Kim JH, Lee JE, Kim SU, Cho KG. Stereological analysis on migration of human neural stem cells in the brain of rats bearing glioma. Neurosurgery 2010;66:333-42. doi: 10.1227/01.NEU.0000363720.07070.A8.  Back to cited text no. 28
    
29.
Jurvansuu J, Zhao Y, Leung DS, Boulaire J, Yu YH, Ahmed S, et al. Transmembrane protein 18 enhances the tropism of neural stem cells for glioma cells. Cancer Res 2008;68:4614-22. doi: 10.1158/0008-5472.CAN-07-5291.  Back to cited text no. 29
    
30.
Barish ME, Herrmann K, Tang Y, Argalian Herculian S, Metz M, Aramburo S, et al. Human neural stem cell biodistribution and predicted tumor coverage by a diffusible therapeutic in a mouse glioma model. Stem Cells Transl Med 2017;6:1522-32. doi: 10.1002/sctm.16-0397.  Back to cited text no. 30
    
31.
Muroski ME, Morshed RA, Cheng Y, Vemulkar T, Mansell R, Han Y, et al. Controlled payload release by magnetic field triggered neural stem cell destruction for malignant glioma treatment. PLoS One 2016;11:e0145129. doi: 10.1371/journal.pone.0145129.  Back to cited text no. 31
    
32.
Cheng Y, Morshed R, Cheng SH, Tobias A, Auffinger B, Wainwright DA, et al. Nanoparticle-programmed self-destructive neural stem cells for glioblastoma targeting and therapy. Small 2013;9:4123-9. doi: 10.1002/smll.201301111.  Back to cited text no. 32
    
33.
Luo Y, Zhu D, Lam DH, Huang J, Tang Y, Luo X, et al. A double-switch cell fusion-inducible transgene expression system for neural stem cell-based antiglioma gene therapy. Stem Cells Int 2015;2015:649080. doi: 10.1155/2015/649080.  Back to cited text no. 33
    
34.
Bagó JR, Alfonso-Pecchio A, Okolie O, Dumitru R, Rinkenbaugh A, Baldwin AS, et al. Therapeutically engineered induced neural stem cells are tumour-homing and inhibit progression of glioblastoma. Nat Commun 2016;7:10593. doi: 10.1038/Ncomms10593.  Back to cited text no. 34
    
35.
Pu K, Li SY, Gao Y, Ma L, Ma W, Liu Y, et al. Bystander effect in suicide gene therapy using immortalized neural stem cells transduced with herpes simplex virus thymidine kinase gene on medulloblastoma regression. Brain Res 2011;1369:245-52. doi: 10.1016/j.brainres.2010.10.107.  Back to cited text no. 35
    
36.
Ito S, Natsume A, Shimato S, Ohno M, Kato T, Chansakul P, et al. Human neural stem cells transduced with IFN-beta and cytosine deaminase genes intensify bystander effect in experimental glioma. Cancer Gene Ther 2010;17:299-306. doi: 10.1038/cgt.2009.80.  Back to cited text no. 36
    
37.
Li S, Tokuyama T, Yamamoto J, Koide M, Yokota N, Namba H, et al. Bystander effect-mediated gene therapy of gliomas using genetically engineered neural stem cells. Cancer Gene Ther 2005;12:600-7. doi: 10.1038/sj.cgt.7700826.  Back to cited text no. 37
    
38.
Jiráková K, Šeneklová M, Jirák D, Turnovcová K, Vosmanská M, Babič M, et al. The effect of magnetic nanoparticles on neuronal differentiation of induced pluripotent stem cell-derived neural precursors. Int J Nanomedicine 2016;11:6267-81. doi: 10.2147/IJN.S116171.  Back to cited text no. 38
    
39.
Pongrac IM, Pavičić I, Milić M, Brkić Ahmed L, Babič M, Horák D, et al. Oxidative stress response in neural stem cells exposed to different superparamagnetic iron oxide nanoparticles. Int J Nanomedicine 2016;11:1701-15. doi: 10.2147/IJN.S102730.  Back to cited text no. 39
    
40.
Umashankar A, Corenblum MJ, Ray S, Valdez M, Yoshimaru ES, Trouard TP, et al. Effects of the iron oxide nanoparticle molday ION rhodamine B on the viability and regenerative function of neural stem cells: Relevance to clinical translation. Int J Nanomedicine 2016;11:1731-48. doi: 10.2147/IJN.S102006.  Back to cited text no. 40
    
41.
Lee U, Yoo CJ, Kim YJ, Yoo YM. Cytotoxicity of gold nanoparticles in human neural precursor cells and rat cerebral cortex. J Biosci Bioeng 2016;121:341-4. doi: 10.1016/j.jbiosc.2015.07.004.  Back to cited text no. 41
    
42.
Adams CF, Dickson AW, Kuiper JH, Chari DM. Nanoengineering neural stem cells on biomimetic substrates using magnetofection technology. Nanoscale 2016;8:17869-80. doi: 10.1039/c6nr05244d.  Back to cited text no. 42
    
43.
Pickard MR, Adams CF, Chari DM. Magnetic nanoparticle-mediated gene delivery to two- and three-dimensional neural stem cell cultures: Magnet-assisted transfection and multifection approaches to enhance outcomes. Curr Protoc Stem Cell Biol 2017;40:2D.19.1-2D.19.16. doi: 10.1002/cpsc.23.  Back to cited text no. 43
    
44.
Adams CF, Pickard MR, Chari DM. Magnetic nanoparticle mediated transfection of neural stem cell suspension cultures is enhanced by applied oscillating magnetic fields. Nanomedicine 2013;9:737-41. doi: 10.1016/j.nano.2013.05.014.  Back to cited text no. 44
    
45.
Bakhru SH, Altiok E, Highley C, Delubac D, Suhan J, Hitchens TK, et al. Enhanced cellular uptake and long-term retention of chitosan-modified iron-oxide nanoparticles for MRI-based cell tracking. Int J Nanomedicine 2012;7:4613-23. doi: 10.2147/IJN.S28294.  Back to cited text no. 45
    
46.
Ramos-Gómez M, Martínez-Serrano A. Tracking of iron-labeled human neural stem cells by magnetic resonance imaging in cell replacement therapy for Parkinson's disease. Neural Regen Res 2016;11:49-52. doi: 10.4103/1673-5374.169628.  Back to cited text no. 46
    
47.
Aswendt M, Henn N, Michalk S, Schneider G, Steiner MS, Bissa U, et al. Novel bimodal iron oxide particles for efficient tracking of human neural stem cells in vivo. Nanomedicine (Lond) 2015;10:2499-512. doi: 10.2217/NNM.15.94.  Back to cited text no. 47
    
48.
Ramos-Gómez M, Seiz EG, Martínez-Serrano A. Optimization of the magnetic labeling of human neural stem cells and MRI visualization in the hemiparkinsonian rat brain. J Nanobiotechnology 2015;13:20. doi: 10.1186/s12951-015-0078-4.  Back to cited text no. 48
    
49.
Adams CF, Rai A, Sneddon G, Yiu HH, Polyak B, Chari DM, et al. Increasing magnetite contents of polymeric magnetic particles dramatically improves labeling of neural stem cell transplant populations. Nanomedicine 2015;11:19-29. doi: 10.1016/j.nano.2014.07.001.  Back to cited text no. 49
    
50.
Shen Y, Shao Y, He H, Tan Y, Tian X, Xie F, et al. Gadolinium(3+)-doped mesoporous silica nanoparticles as a potential magnetic resonance tracer for monitoring the migration of stem cells in vivo. Int J Nanomedicine 2013;8:119-27. doi: 10.2147/IJN.S38213.  Back to cited text no. 50
    
51.
Kim TH, El-Said WA, An JH, Choi JW. ITO/gold nanoparticle/RGD peptide composites to enhance electrochemical signals and proliferation of human neural stem cells. Nanomedicine 2013;9:336-44. doi: 10.1016/j.nano.2012.08.006.  Back to cited text no. 51
    
52.
Mooney R, Weng Y, Garcia E, Bhojane S, Smith-Powell L, Kim SU, et al. Conjugation of pH-responsive nanoparticles to neural stem cells improves intratumoral therapy. J Control Release 2014;191:82-9. doi: 10.1016/j.jconrel.2014.06.015.  Back to cited text no. 52
    
53.
Pino-Barrio MJ, García-García E, Menéndez P, Martínez-Serrano A. V-myc immortalizes human neural stem cells in the absence of pluripotency-associated traits. PLoS One 2015;10:e0118499. doi: 10.1371/journal.pone.0118499.  Back to cited text no. 53
    
54.
Amariglio N, Hirshberg A, Scheithauer BW, Cohen Y, Loewenthal R, Trakhtenbrot L, et al. Donor-derived brain tumor following neural stem cell transplantation in an ataxia telangiectasia patient. PLoS Med 2009;6:e1000029. doi: 10.1371/journal.pmed.1000029.  Back to cited text no. 54
    
55.
Pittenger MF, Mackay AM, Beck SC, Jaiswal RK, Douglas R, Mosca JD, et al. Multilineage potential of adult human mesenchymal stem cells. Science 1999;284:143-7. doi: 10.1126/science.284.5411.143.  Back to cited text no. 55
    
56.
Rodriguez AM, Elabd C, Amri EZ, Ailhaud G, Dani C. The human adipose tissue is a source of multipotent stem cells. Biochimie 2005;87:125-8. doi: 10.1016/j.biochi.2004.11.007.  Back to cited text no. 56
    
57.
da Silva Meirelles L, Chagastelles PC, Nardi NB. Mesenchymal stem cells reside in virtually all post-natal organs and tissues. J Cell Sci 2006;119:2204-13. doi: 10.1242/jcs.02932.  Back to cited text no. 57
    
58.
Jiang Y, Vaessen B, Lenvik T, Blackstad M, Reyes M, Verfaillie CM, et al. Multipotent progenitor cells can be isolated from postnatal murine bone marrow, muscle, and brain. Exp Hematol 2002;30:896-904. doi: 10.1016/S0301-472X(02)00869-X.  Back to cited text no. 58
    
59.
Phinney DG, Prockop DJ. Concise review: Mesenchymal stem/multipotent stromal cells: The state of transdifferentiation and modes of tissue repair – Current views. Stem Cells 2007;25:2896-902. doi: 10.1634/stemcells.2007-0637.  Back to cited text no. 59
    
60.
Kim R, Park SI, Lee CY, Lee J, Kim P, Oh S, et al. Alternative new mesenchymal stem cell source exerts tumor tropism through ALCAM and N-cadherin via regulation of microRNA-192 and -218. Mol Cell Biochem 2017;427:177-85. doi: 10.1007/s11010-016-2909-5.  Back to cited text no. 60
    
61.
Hoch AI, Leach JK. Concise review: Optimizing expansion of bone marrow mesenchymal stem/stromal cells for clinical applications. Stem Cells Transl Med 2014;3:643-52. doi: 10.5966/sctm.2013-0196.  Back to cited text no. 61
    
62.
Liu TM, Ng WM, Tan HS, Vinitha D, Yang Z, Fan JB, et al. Molecular basis of immortalization of human mesenchymal stem cells by combination of p53 knockdown and human telomerase reverse transcriptase overexpression. Stem Cells Dev 2013;22:268-78. doi: 10.1089/scd.2012.0222.  Back to cited text no. 62
    
63.
Doucette T, Rao G, Yang Y, Gumin J, Shinojima N, Bekele BN, et al. Mesenchymal stem cells display tumor-specific tropism in an RCAS/Ntv-a glioma model. Neoplasia 2011;13:716-25. doi: 10.1593/neo.101680.  Back to cited text no. 63
    
64.
Liu Z, Jiang Z, Huang J, Huang S, Li Y, Sheng F, et al. Mesenchymal stem cells show little tropism for the resting and differentiated cancer stem cell-like glioma cells. Int J Oncol 2014;44:1223-32. doi: 10.3892/ijo.2014.2284.  Back to cited text no. 64
    
65.
Egea V, von Baumgarten L, Schichor C, Berninger B, Popp T, Neth P, et al. TNF-α respecifies human mesenchymal stem cells to a neural fate and promotes migration toward experimental glioma. Cell Death Differ 2011;18:853-63. doi: 10.1038/cdd.2010.154.  Back to cited text no. 65
    
66.
Kendall SE, Najbauer J, Johnston HF, Metz MZ, Li S, Bowers M, et al. Neural stem cell targeting of glioma is dependent on phosphoinositide 3-kinase signaling. Stem Cells 2008;26:1575-86. doi: 10.1634/stemcells.2007-0887.  Back to cited text no. 66
    
67.
Ma JC, Cheng P, Hu Y, Xue YX, Liu YH. Integrin α4 is involved in the regulation of glioma-induced motility of bone marrow mesenchymal stem cells. Oncol Rep 2015;34:779-86. doi: 10.3892/or.2015.4012.  Back to cited text no. 67
    
68.
Shinojima N, Hossain A, Takezaki T, Fueyo J, Gumin J, Gao F, et al. TGF-β mediates homing of bone marrow-derived human mesenchymal stem cells to glioma stem cells. Cancer Res 2013;73:2333-44. doi: 10.1158/0008-5472.CAN-12-3086.  Back to cited text no. 68
    
69.
Melzer C, von der Ohe J, Hass R. Enhanced metastatic capacity of breast cancer cells after interaction and hybrid formation with mesenchymal stroma/stem cells (MSC). Cell Commun Signal 2018;16:2. doi: 10.1186/s12964-018-0215-4.  Back to cited text no. 69
    
70.
Liu C, Feng X, Wang B, Wang X, Wang C, Yu M, et al. Bone marrow mesenchymal stem cells promote head and neck cancer progression through periostin-mediated phosphoinositide 3-kinase/Akt/mammalian target of rapamycin. Cancer Sci 2017. doi: 10.1111/cas.13479. [Epub ahead of print].  Back to cited text no. 70
    
71.
An J, Yan H, Li X, Tan R, Chen X, Zhang Z, et al. The inhibiting effect of neural stem cells on proliferation and invasion of glioma cells. Oncotarget 2017;8:76949-60. doi: 10.18632/oncotarget.20270.  Back to cited text no. 71
    
72.
Koide M, Kawahara Y, Tsuda T, Ishida Y, Shii K, Yokoyama M, et al. Stimulation of protein-tyrosine phosphorylation by endothelin-1 in cultured vascular smooth muscle cells. Atherosclerosis 1992;92:1-7. doi: 10.1016/0021-9150(92)90003-Y.  Back to cited text no. 72
    
73.
Pacioni S, D'Alessandris QG, Giannetti S, Morgante L, Coccè V, Bonomi A, et al. Human mesenchymal stromal cells inhibit tumor growth in orthotopic glioblastoma xenografts. Stem Cell Res Ther 2017;8:53. doi: 10.1186/s13287-017-0516-3.  Back to cited text no. 73
    
74.
Gabashvili AN, Baklaushev VP, Grinenko NF, Mel'nikov PA, Cherepanov SA, Levinsky AB, et al. Antitumor activity of rat mesenchymal stem cells during direct or indirect co-culturing with C6 glioma cells. Bull Exp Biol Med 2016;160:519-24. doi: 10.1007/s10517-016-3211-y.  Back to cited text no. 74
    
75.
Onzi GR, Ledur PF, Hainzenreder LD, Bertoni AP, Silva AO, Lenz G, et al. Analysis of the safety of mesenchymal stromal cells secretome for glioblastoma treatment. Cytotherapy 2016;18:828-37. doi: 10.1016/j.jcyt.2016.03.299.  Back to cited text no. 75
    
76.
Vuong QL, Gillis P, Gossuin Y. Monte Carlo simulation and theory of proton NMR transverse relaxation induced by aggregation of magnetic particles used as MRI contrast agents. J Magn Reson 2011;212:139-48. doi: 10.1016/j.jmr.2011.06.024.  Back to cited text no. 76
    
77.
Koenig SH, Kellar KE. Theory of 1/T1 and 1/T2 NMRD profiles of solutions of magnetic nanoparticles. Magn Reson Med 1995;34:227-33. doi: 10.1002/mrm.1910340214.  Back to cited text no. 77
    
78.
Ling D, Hyeon T. Chemical design of biocompatible iron oxide nanoparticles for medical applications. Small 2013;9:1450-66. doi: 10.1002/smll.201202111.  Back to cited text no. 78
    
79.
Sun S, Zeng H, Robinson DB, Raoux S, Rice PM, Wang SX, et al. Monodisperse MFe2O4 (M = Fe, Co, Mn) nanoparticles. J Am Chem Soc 2004;126:273-9. doi: 10.1021/ja0380852.  Back to cited text no. 79
    
80.
Truby RL, Emelianov SY, Homan KA. Ligand-mediated self-assembly of hybrid plasmonic and superparamagnetic nanostructures. Langmuir 2013;29:2465-70. doi: 10.1021/la3037549.  Back to cited text no. 80
    
81.
Anderson SA, Glod J, Arbab AS, Noel M, Ashari P, Fine HA, et al. Noninvasive MR imaging of magnetically labeled stem cells to directly identify neovasculature in a glioma model. Blood 2005;105:420-5. doi: 10.1182/blood-2004-06-2222.  Back to cited text no. 81
    
82.
Arbab AS, Pandit SD, Anderson SA, Yocum GT, Bur M, Frenkel V, et al. Magnetic resonance imaging and confocal microscopy studies of magnetically labeled endothelial progenitor cells trafficking to sites of tumor angiogenesis. Stem Cells 2006;24:671-8. doi: 10.1634/stemcells.2005-0017.  Back to cited text no. 82
    
83.
Arbab AS, Yocum GT, Kalish H, Jordan EK, Anderson SA, Khakoo AY, et al. Efficient magnetic cell labeling with protamine sulfate complexed to ferumoxides for cellular MRI. Blood 2004;104:1217-23. doi: 10.1182/blood-2004-02-0655.  Back to cited text no. 83
    
84.
Weissleder R, Stark DD, Engelstad BL, Bacon BR, Compton CC, White DL, et al. Superparamagnetic iron oxide: Pharmacokinetics and toxicity. AJR Am J Roentgenol 1989;152:167-73. doi: 10.2214/ajr.152.1.167.  Back to cited text no. 84
    
85.
Thu MS, Najbauer J, Kendall SE, Harutyunyan I, Sangalang N, Gutova M, et al. Iron labeling and pre-clinical MRI visualization of therapeutic human neural stem cells in a murine glioma model. PLoS One 2009;4:e7218. doi: 10.1371/journal.pone.0007218.  Back to cited text no. 85
    
86.
Menon LG, Pratt J, Yang HW, Black PM, Sorensen GA, Carroll RS, et al. Imaging of human mesenchymal stromal cells: Homing to human brain tumors. J Neurooncol 2012;107:257-67. doi: 10.1007/s11060-011-0754-7.  Back to cited text no. 86
    
87.
Chien LY, Hsiao JK, Hsu SC, Yao M, Lu CW, Liu HM, et al. In vivo magnetic resonance imaging of cell tropism, trafficking mechanism, and therapeutic impact of human mesenchymal stem cells in a murine glioma model. Biomaterials 2011;32:3275-84. doi: 10.1016/j.biomaterials.2011.01.042.  Back to cited text no. 87
    
88.
Huang X, Zhang F, Wang Y, Sun X, Choi KY, Liu D, et al. Design considerations of iron-based nanoclusters for noninvasive tracking of mesenchymal stem cell homing. ACS Nano 2014;8:4403-14. doi: 10.1021/nn4062726.  Back to cited text no. 88
    
89.
Thu MS, Bryant LH, Coppola T, Jordan EK, Budde MD, Lewis BK, et al. Self-assembling nanocomplexes by combining ferumoxytol, heparin and protamine for cell tracking by magnetic resonance imaging. Nat Med 2012;18:463-7. doi: 10.1038/nm.2666.  Back to cited text no. 89
    
90.
Varallyay P, Nesbit G, Muldoon LL, Nixon RR, Delashaw J, Cohen JI, et al. Comparison of two superparamagnetic viral-sized iron oxide particles ferumoxides and ferumoxtran-10 with a gadolinium chelate in imaging intracranial tumors. AJNR Am J Neuroradiol 2002;23:510-9.  Back to cited text no. 90
    
91.
Gutova M, Frank JA, D'Apuzzo M, Khankaldyyan V, Gilchrist MM, Annala AJ, et al. Magnetic resonance imaging tracking of ferumoxytol-labeled human neural stem cells: Studies leading to clinical use. Stem Cells Transl Med 2013;2:766-75. doi: 10.5966/sctm.2013-0049.  Back to cited text no. 91
    
92.
Eamegdool SS, Weible MW 2nd, Pham BT, Hawkett BS, Grieve SM, Chan-ling T, et al. Ultrasmall superparamagnetic iron oxide nanoparticle prelabelling of human neural precursor cells. Biomaterials 2014;35:5549-64. doi: 10.1016/j.biomaterials.2014.03.061.  Back to cited text no. 92
    
93.
Guldris N, Argibay B, Gallo J, Iglesias-Rey R, Carbó-Argibay E, Kolen'ko YV, et al. Magnetite nanoparticles for stem cell labeling with high efficiency and long-term in vivo tracking. Bioconjug Chem 2017;28:362-70. doi: 10.1021/acs.bioconjchem.6b00522.  Back to cited text no. 93
    
94.
Lee NK, Kim HS, Yoo D, Hwang JW, Choi SJ, Oh W, et al. Magnetic resonance imaging of ferumoxytol-labeled human mesenchymal stem cells in the mouse brain. Stem Cell Rev 2017;13:127-38. doi: 10.1007/s12015-016-9694-0.  Back to cited text no. 94
    
95.
Mathiasen AB, Hansen L, Friis T, Thomsen C, Bhakoo K, Kastrup J, et al. Optimal labeling dose, labeling time, and magnetic resonance imaging detection limits of ultrasmall superparamagnetic iron-oxide nanoparticle labeled mesenchymal stromal cells. Stem Cells Int 2013;2013:353105. doi: 10.1155/2013/353105.  Back to cited text no. 95
    
96.
Alexiou GA, Xourgia X, Gerogianni P, Vartholomatos E, Kalef-Ezra JA, Fotopoulos AD, et al. 99mTc-tetrofosmin uptake correlates with the sensitivity of glioblastoma cell lines to temozolomide. World J Nucl Med 2017;16:45-50. doi: 10.4103/1450-1147.181155.  Back to cited text no. 96
[PUBMED]  [Full text]  
97.
Chen L, Wang L, Yan J, Ma C, Lu J, Chen G, et al. 131I-labeled monoclonal antibody targeting neuropilin receptor type-2 for tumor SPECT imaging. Int J Oncol 2017;50:649-59. doi: 10.3892/ijo.2016.3808.  Back to cited text no. 97
    
98.
de Oliveira ÉA, Faintuch BL, Targino RC, Moro AM, Martinez RC, Pagano RL, et al. Evaluation of GX1 and RGD-GX1 peptides as new radiotracers for angiogenesis evaluation in experimental glioma models. Amino Acids 2016;48:821-31. doi: 10.1007/s00726-015-2130-y.  Back to cited text no. 98
    
99.
Chin BB, Nakamoto Y, Bulte JW, Pittenger MF, Wahl R, Kraitchman DL, et al. 111In oxine labelled mesenchymal stem cell SPECT after intravenous administration in myocardial infarction. Nucl Med Commun 2003;24:1149-54. doi: 10.1097/01.mnm.0000101606.64255.03.  Back to cited text no. 99
    
100.
Gildehaus FJ, Haasters F, Drosse I, Wagner E, Zach C, Mutschler W, et al. Impact of indium-111 oxine labelling on viability of human mesenchymal stem cells in vitro, and 3D cell-tracking using SPECT/CT in vivo. Mol Imaging Biol 2011;13:1204-14. doi: 10.1007/s11307-010-0439-1.  Back to cited text no. 100
    
101.
Bindslev L, Haack-Sørensen M, Bisgaard K, Kragh L, Mortensen S, Hesse B, et al. Labelling of human mesenchymal stem cells with indium-111 for SPECT imaging: Effect on cell proliferation and differentiation. Eur J Nucl Med Mol Imaging 2006;33:1171-7. doi: 10.1007/s00259-006-0093-7.  Back to cited text no. 101
    
102.
Gleave JA, Valliant JF, Doering LC. 99mTc-based imaging of transplanted neural stem cells and progenitor cells. J Nucl Med Technol 2011;39:114-20. doi: 10.2967/jnmt.111.087445.  Back to cited text no. 102
    
103.
Wang Y, Zhao Q, Han N, Bai L, Li J, Liu J, et al. Mesoporous silica nanoparticles in drug delivery and biomedical applications. Nanomedicine 2015;11:313-27. doi: 10.1016/j.nano.2014.09.014.  Back to cited text no. 103
    
104.
Chen F, Goel S, Valdovinos HF, Luo H, Hernandez R, Barnhart TE, et al. In vivo integrity and biological fate of chelator-free zirconium-89-labeled mesoporous silica nanoparticles. ACS Nano 2015;9:7950-9. doi: 10.1021/acsnano.5b00526.  Back to cited text no. 104
    
105.
Chen F, Nayak TR, Goel S, Valdovinos HF, Hong H, Theuer CP, et al. In vivo tumor vasculature targeted PET/NIRF imaging with TRC105(Fab)-conjugated, dual-labeled mesoporous silica nanoparticles. Mol Pharm 2014;11:4007-14. doi: 10.1021/mp500306k.  Back to cited text no. 105
    
106.
Di Pasqua AJ, Yuan H, Chung Y, Kim JK, Huckle JE, Li C, et al. Neutron-activatable holmium-containing mesoporous silica nanoparticles as a potential radionuclide therapeutic agent for ovarian cancer. J Nucl Med 2013;54:111-6. doi: 10.2967/jnumed.112.106609.  Back to cited text no. 106
    
107.
Lee SB, Kim HL, Jeong HJ, Lim ST, Sohn MH, Kim DW, et al. Mesoporous silica nanoparticle pretargeting for PET imaging based on a rapid bioorthogonal reaction in a living body. Angew Chem Int Ed Engl 2013;52:10549-52. doi: 10.1002/anie.201304026.  Back to cited text no. 107
    
108.
Cheng SH, Yu D, Tsai HM, Morshed RA, Kanojia D, Lo LW, et al. Dynamic in vivo SPECT imaging of neural stem cells functionalized with radiolabeled nanoparticles for tracking of glioblastoma. J Nucl Med 2016;57:279-84. doi: 10.2967/jnumed.115.163006.  Back to cited text no. 108
    
109.
Fukuoka S, Kawajiri H, Fushiki T, Takahashi K, Iwai K. Localization of pancreatic enzyme secretion-stimulating activity and trypsin inhibitory activity in zymogen granule of the rat pancreas. Biochim Biophys Acta 1986;884:18-24. doi: 10.1016/0304-4165(86)90221-7.  Back to cited text no. 109
    
110.
Bossolasco P, Cova L, Levandis G, Diana V, Cerri S, Lambertenghi Deliliers G, et al. Noninvasive near-infrared live imaging of human adult mesenchymal stem cells transplanted in a rodent model of Parkinson's disease. Int J Nanomedicine 2012;7:435-47. doi: 10.2147/IJN.S27537.  Back to cited text no. 110
    
111.
Yi X, Wang F, Qin W, Yang X, Yuan J. Near-infrared fluorescent probes in cancer imaging and therapy: An emerging field. Int J Nanomedicine 2014;9:1347-65. doi: 10.2147/IJN.S60206.  Back to cited text no. 111
    
112.
Ly HQ, Hoshino K, Pomerantseva I, Kawase Y, Yoneyama R, Takewa Y, et al. In vivo myocardial distribution of multipotent progenitor cells following intracoronary delivery in a swine model of myocardial infarction. Eur Heart J 2009;30:2861-8. doi: 10.1093/eurheartj/ehp322.  Back to cited text no. 112
    
113.
Feng L, Wu L, Qu X. New horizons for diagnostics and therapeutic applications of graphene and graphene oxide. Adv Mater 2013;25:168-86. doi: 10.1002/adma.201203229.  Back to cited text no. 113
    
114.
Armentero MT, Bossolasco P, Cova L. Labeling and tracking of human mesenchymal stem cells using near-infrared technology. Methods Mol Biol 2013;1052:13-28. doi: 10.1007/7651_2013_21.  Back to cited text no. 114
    
115.
Kim SM, Jeong CH, Woo JS, Ryu CH, Lee JH, Jeun SS, et al. In vivo near-infrared imaging for the tracking of systemically delivered mesenchymal stem cells: Tropism for brain tumors and biodistribution. Int J Nanomedicine 2016;11:13-23. doi: 10.2147/IJN.S97073.  Back to cited text no. 115
    
116.
Wang BG, König K, Halbhuber KJ. Two-photon microscopy of deep intravital tissues and its merits in clinical research. J Microsc 2010;238:1-20. doi: 10.1111/j.1365-2818.2009.03330.x.  Back to cited text no. 116
    
117.
Zhang YS, Wang Y, Wang L, Wang Y, Cai X, Zhang C, et al. Labeling human mesenchymal stem cells with gold nanocages for in vitro and in vivo tracking by two-photon microscopy and photoacoustic microscopy. Theranostics 2013;3:532-43. doi: 10.7150/thno.5369.  Back to cited text no. 117
    
118.
Zhang AW, Guo WH, Qi YF, Wang JZ, Ma XX, Yu DX, et al. Synergistic effects of gold nanocages in hyperthermia and radiotherapy treatment. Nanoscale Res Lett 2016;11:279. doi: 10.1186/s11671-016-1501-y.  Back to cited text no. 118
    
119.
Wu X, Hu J, Zhou L, Mao Y, Yang B, Gao L, et al. In vivo tracking of superparamagnetic iron oxide nanoparticle-labeled mesenchymal stem cell tropism to malignant gliomas using magnetic resonance imaging. Laboratory investigation. J Neurosurg 2008;108:320-9. doi: 10.3171/JNS/2008/108/2/0320.  Back to cited text no. 119
    
120.
Kim SJ, Lewis B, Steiner MS, Bissa UV, Dose C, Frank JA, et al. Superparamagnetic iron oxide nanoparticles for direct labeling of stem cells and in vivo MRI tracking. Contrast Media Mol Imaging 2016;11:55-64. doi: 10.1002/cmmi.1658.  Back to cited text no. 120
    
121.
Lee JY, Cho SS, Zeh R, Pierce JT, Martinez-Lage M, Adappa ND, et al. Folate receptor overexpression can be visualized in real time during pituitary adenoma endoscopic transsphenoidal surgery with near-infrared imaging. J Neurosurg 2017;1-4. doi: 10.3171/2017.2.JNS163191. [Epub ahead of print].  Back to cited text no. 121
    
122.
Cho SS, Zeh R, Pierce JT, Salinas R, Singhal S, Lee JY, et al. Comparison of near-infrared imaging camera systems for intracranial tumor detection. Mol Imaging Biol 2017. doi: 10.1007/s11307-017-1107-5. [Epub ahead of print].  Back to cited text no. 122
    
123.
Lee JY, Pierce JT, Thawani JP, Zeh R, Nie S, Martinez-Lage M, et al. Near-infrared fluorescent image-guided surgery for intracranial meningioma. J Neurosurg 2018:128:380-390. doi: 10.3171/2016.10.JNS161636.  Back to cited text no. 123
    


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