Magnetic resonance imaging detects differences in migration between primary and immortalized neural stem cells

RATIONALE AND OBJECTIVES: The study was performed to evaluate the effect of magnetic resonance imaging (MRI) contrast agent (super paramagnetic iron oxide [SPIO]) on differentiation and migration of primary murine neural stem cells (NSCs) in comparison to a neural stem cell line (C17.2). Because detection of labeled cells depends on the concentration of SPIO particles per imaging voxel, the study was performed at various concentrations of SPIO particles to determine the concentration that could be used for in vivo detection of small clusters of grafted cells. MATERIALS AND METHODS: Murine primary NSCs or C17.2 cells were labeled with different concentrations of SPIO particles (0, 25, 100, and 250 mug Fe/mL) and in vitro assays were performed to assess cell differentiation. In vivo MRI was performed 7 weeks after neonatal transplantation of labeled cells to evaluate the difference in migration capability of the two cell populations. RESULTS: Both the primary NSCs and the C17.2 cells differentiated to similar number of neurons (Map2ab-positive cells). Similar patterns of engraftment of C17.2 cells were seen in transplanted mice regardless of the SPIO concentration used. In vivo MRI detection of grafted primary and C17.2 cells was only possible when cells were incubated with 100 mug/mL or higher concentration of SPIO. Extensive migration of C17.2 cells throughout the brain was observed, whereas the migration of the primary NSCs was more restricted. CONCLUSIONS: Engraftment of primary NSCs can be detected noninvasively by in vivo MRI, and the presence of SPIO particles do not affect the viability, differentiation, or engraftment pattern of the donor cells.     

胎鼠神经干细胞超顺磁性氧化铁颗粒标记移植后MRI研究

目的:探讨超顺磁性氧化铁颗粒(SPIO)标记神经干细胞的方法,以及标记细胞正常大鼠脑内移植后MR成像的方法学研究。方法:多聚左旋赖氨酸介导的SPIO标记胎鼠神经干细胞,进行台盼兰染色和普鲁士兰染色分别检测标记细胞的存活率和标记率。选取SD大鼠15只,简单随机法分为3组:第1组于大鼠右侧尾状核移植未标记的NSCs,第2组于大鼠右侧尾状核移植标记的NSCs,第3组右侧尾状核移植游离的SPIO颗粒,移植后第1、4、8周进行MRI。8周后处死大鼠,行组织切片普鲁士兰染色。结果:体外标记的神经干细胞普鲁士兰染色发现铁颗粒聚集于细胞浆内,标记率为100%;标记细胞与未标记细胞的台盼兰染色结果无显著差异。移植后MRI,第1组注射点未见低信号影;第2组注射点T2WI及GRE序列均可见类圆形低信号影;第3组大鼠注射后1周注射点可见低信号影,4周后低信号影变淡且边缘变模糊,8周后低信号影T2WI已不明显。与T2WI序列比较,GRE序列显示标记细胞更清晰,但显示范围较扩散。脑组织切片的普鲁士兰染色显示,第1组大鼠脑组织切片未见异常蓝染细胞,第2组注射点可见蓝染细胞,第3组注射点可见稍许散在蓝色颗粒状物质。结论:多聚左旋赖氨酸介导下SPIO可用于标记神经干细胞,标记细胞移植后MRI可以无创性观察移植神经干细胞的位置及分布情况。     

In vivo serial evaluation of superparamagnetic iron‐oxide labeled stem cells by off‐resonance positive contrast

MRI is emerging as a diagnostic modality to track iron‐oxide‐labeled stem cells. This study investigates whether an off‐resonance (OR) pulse sequence designed to generate positive contrast at 1.5T can assess the location, quantity, and viability of delivered stem cells in vivo. Using mouse embryonic stem cell transfected with luciferase reporter gene (luc‐mESC), multimodality validation of OR signal was conducted to determine whether engraftment parameters of superparamagnetic iron‐oxide labeled luc‐mESC (SPIO‐luc‐mESC) could be determined after cell transplantation into the mouse hindlimb. A significant increase in signal‐ and contrast‐to‐noise of the SPIO‐luc‐mESC was achieved with the OR technique when compared to a gradient recalled echo (GRE) sequence. A significant correlation between the quantity of SPIO‐luc‐mESC and OR signal was observed immediately after transplantation (R² = 0.74, P < 0.05). The assessment of transplanted cell viability by bioluminescence imaging (BLI) showed a significant increase of luciferase activities by day 16, while the MRI signal showed no difference. No significant correlation between BLI and MRI signals of cell viability was observed. In conclusion, using an OR sequence the precise localization and quantitation of SPIO‐labeled stem cells in both space and time were possible. However, the OR sequence did not allow evaluation of cell viability. Magn Reson Med 60:1269–1275, 2008. © 2008 Wiley‐Liss, Inc.     

Magnetosonoporation: Instant magnetic labeling of stem cells

The purpose of this study was to develop an instant MR cell labeling technique, called magnetosonoporation. First, a magnetosonoporation apparatus was successfully established for MR labeling of stem cells. Then, the safety of this new cell labeling approach was confirmed by evaluation of cell viability, proliferation, and differentiation of magnetosonoporation‐labeled and unlabeled C17.2 neural stem cells. Subsequently, the feasibility of using in vivo MRI to detect magnetosonoporation/Feridex‐labeled stem cells was validated in living animals and confirmed by histologic correlation. The magnetosonoporation technique is expected to be convenient, efficient, and safe for future clinical application of MRI‐guided cell therapies. Magn Reson Med 63:1437–1441, 2010. © 2010 Wiley‐Liss, Inc.     

Low‐intensity pulsed ultrasound increases cellular uptake of superparamagnetic iron oxide nanomaterial: Results from human osteosarcoma cell line U2OS

Purpose:

To determine whether low‐intensity pulsed ultrasound (LIPUS) is able to facilitate the uptake of a superparamagnetic iron oxide (SPIO) nanomaterial by cells that do not express high endocytosis capacity.

Materials and Methods:

The human osteosarcoma cell line U2OS and a silica‐coated SPIO functionalized peripherally with amines groups (overall diameter 8 nm) were used in this study. Adherent U2OS cells were labeled with SPIO by incubating with culture media containing the SPIO at 4.5 μg[Fe]/mL. LIPUS with the same parameters as those used in clinical application to accelerate bone fracture healing (1.5 MHz, duty cycle 1:4, spatial‐average temporal‐average intensity 30 mW/cm²) was applied to the cells at the beginning of the labeling process for 0, 0.5, 1, or 3 hours. The total incubation time with SPIO was 12 hours. SPIO labeling efficiency was evaluated with Prussian blue staining and a blueness measurement method, and magnetic resonance imaging (MRI) of cell pellets via measuring areas of SPIO‐induced signal void.

Results:

Both Prussian blue staining and in vitro MRI demonstrated that LIPUS application increased the SPIO nanomaterial labeling efficiency for U2OS cells in an exposure‐duration‐dependent manner.

Conclusion:

This study is a “proof of concept” that LIPUS can facilitate the cellular take‐up of SPIO nanomaterial. J. Magn. Reson. Imaging 2010;31:1508–1513. © 2010 Wiley‐Liss, Inc.     

Gene expression profiling reveals early cellular responses to intracellular magnetic labeling with superparamagnetic iron oxide nanoparticles

With MRI (stem) cell tracking having entered the clinic, studies on the cellular genomic response toward labeling are warranted. Gene expression profiling was applied to C17.2 neural stem cells following superparamagnetic iron oxide/PLL (poly‐L ‐lysine) labeling over the course of 1 week. Relative to unlabeled cells, less than 1% of genes (49 total) exhibited greater than 2‐fold difference in expression in response to superparamagnetic iron oxide/PLL labeling. In particular, transferrin receptor 1 (Tfrc) and heme oxygenase 1 (Hmox1) expression was downregulated early, whereas genes involved in lysosomal function (Sulf1) and detoxification (Clu, Cp, Gstm2, Mgst1) were upregulated at later time points. Relative to cells treated with PLL only, cells labeled with superparamagnetic iron oxide/PLL complexes exhibited differential expression of 1399 genes. Though these differentially expressed genes exhibited altered expression over time, the overall extent was limited. Gene ontology analysis of differentially expressed genes showed that genes encoding zinc‐binding proteins are enriched after superparamagnetic iron oxide/PLL labeling relative to PLL only treatment, whereas members of the apoptosis/programmed cell death pathway did not display increased expression. Overexpression of the differentially expressed genes Rnf138 and Abcc4 were confirmed by quantitative real‐time polymerase chain reaction. These results demonstrate that, although early reactions responsible for iron homeostasis are induced, overall neural stem cell gene expression remains largely unaltered following superparamagnetic iron oxide/PLL labeling. Magn Reson Med 63:1031–1043, 2010. © 2010 Wiley‐Liss, Inc.     

Monitoring bone marrow‐originated mesenchymal stem cell traffic to myocardial infarction sites using magnetic resonance imaging

How stem cells promote myocardial repair in myocardial infarction (MI) is not well understood. The purpose of this study was to noninvasively monitor and quantify mesenchymal stem cells (MSC) from bone marrow to MI sites using magnetic resonance imaging (MRI). MSC were dual‐labeled with an enhanced green fluorescent protein and micrometer‐sized iron oxide particles prior to intra‐bone marrow transplantation into the tibial medullary space of C57Bl/6 mice. Micrometer‐sized iron oxide particles labeling caused signal attenuation in T₂*‐weighted MRI and thus allowed noninvasive cell tracking. Longitudinal MRI demonstrated MSC infiltration into MI sites over time. Fluorescence from both micrometer‐sized iron oxide particles and enhanced green fluorescent protein in histology validated the presence of dual‐labeled cells at MI sites. This study demonstrated that MSC traffic to MI sites can be noninvasively monitored in MRI by labeling cells with micrometer‐sized iron oxide particles. The dual‐labeled MSC at MI sites maintained their capability of proliferation and differentiation. The dual‐labeling, intra‐bone marrow transplantation, and MRI cell tracking provided a unique approach for investigating stem cells' roles in the post‐MI healing process. This technique can potentially be applied to monitor possible effects on stem cell mobilization caused by given treatment strategies. Magn Reson Med, 2011. © 2011 Wiley‐Liss, Inc.     

心脏磁共振在体示踪移植细胞的可行性研究

目的：寻找一种能够对移植细胞进行在体示踪的标记方法,为移植细胞存留、迁移提供重要观察手段。方法：从中华小型猪髂骨处抽取骨髓,体外培养扩增骨髓间充质干细胞（MSCs）。将SPIO和MSCs共同孵育培养36h。普鲁士蓝染色评价细胞的标记效率;通过MTT比色实验评价SPIO对细胞生长能力的影响;台盼蓝染色检验标记后细胞的活性;使用Costar Transwell方法评价铁离子对细胞迁移能力的影响;用细胞分化诱导液培养标记后的细胞评价其向成脂肪细胞和成骨细胞的分化能力。在体内实验中将SPIO标记或未标记的自体MSCs注射到心肌内,通过心脏磁共振检查对移植细胞进行在体示踪观察,取材动物心脏行病理检查观察移植细胞的存活、存留。结果：MSCs经铁离子标记后普鲁士蓝染色阳性率在98%以上,可见蓝色颗粒位于细胞浆内,标记细胞电镜切片可见高密度铁颗粒位于细胞浆内。随着培养液中SPIO浓度的增加细胞增殖能力没有明显改变;标记后98%的细胞保持活性;SPIO标记后的细胞保持原有的形态,可继续培养、传代;SDF-1和VEGF诱导的迁移实验发现标记细胞迁移能力没有降低;铁离子标记后细胞仍可向成脂肪细胞和成骨细胞分化。注射到心肌内的SPIO标记的MSCs可通过心脏磁共振检查进行在体示踪,动态观察显示SPIO标记细胞在磁共振图像上表现为低信号,并且在移植后4周仍可成像。病理学检查可以看到移植细胞呈普鲁士蓝染色阳性,并和影像学有很好的一致性。结论：临床使用的SPIO磁共振对比剂可以安全、有效地标记MSCs,心脏磁共振检查可以实现SPIO标记的移植细胞的在体示踪。     

Clinically applicable labeling of mammalian and stem cells by combining superparamagnetic iron oxides and transfection agents

PURPOSE: To label mammalian and stem cells by combining commercially available transfection agents (TAs) with superparamagnetic iron oxide (SPIO) magnetic resonance (MR) imaging contrast agents. MATERIALS AND METHODS: Three TAs were incubated with ferumoxides and MION-46L in cell culture medium at various concentrations. Human mesenchymal stem cells, mouse lymphocytes, rat oligodendrocyte progenitor CG-4 cells, and human cervical carcinoma cells were incubated 2-48 hours with 25 microg of iron per milliliter of combined TAs and SPIO. Cellular labeling was evaluated with T2 relaxometry, MR imaging of labeled cell suspensions, and Prussian blue staining for iron assessment. Proliferation and viability of mesenchymal stem cells and human cervical carcinoma cells labeled with a combination of TAs and ferumoxides were evaluated. RESULTS: When ferumoxides-TA or MION-46L-TA was used, intracytoplasmic particles stained with Prussian blue stain were detected for all cell lines with a labeling efficiency of nearly 100%. Limited or no uptake was observed for cells incubated with ferumoxides or MION-46L alone. For TA-SPIO-labeled cells, MR images and relaxometry findings showed a 50%-90% decrease in signal intensity and a more than 40-fold increase in T2s. Cell viability varied from 103.7% +/- 9 to 123.0% +/- 9 compared with control cell viability at 9 days, and cell proliferation was not affected by endosomal incorporation of SPIO nanoparticles. Iron concentrations varied with ferumoxides-TA combinations and cells with a maximum of 30.1 pg +/- 3.7 of iron per cell for labeled mesenchymal stem cells. CONCLUSION: Magnetic labeling of mammalian cells with use of ferumoxides and TAs is possible and may enable cellular MR imaging and tracking in experimental and clinical settings.     

In vivo MR imaging tracking of transplanted mesenchymal stem cells in a rabbit model of acute peripheral nerve traction injury

Purpose

To investigate in vivo MRI tracking mesenchymal stem cells (MSCs) in peripheral nerve injures using a clinically available paramagnetic contrast agent (Gd‐DTPA) and commercially available rhodamine‐incorporated transfection reagents (PEI‐FluoR).

Materials and Methods

After bone marrow MSCs were labeled with Gd‐DTPA and PEI‐FluoR complex, the labeling efficacy and longevity of Gd‐DTPA maintenance were measured and cell viability, proliferation, and apoptosis were assessed. Thirty‐six rabbits with acute sciatic nerve traction injury randomly received 1 × 10⁶ labeled (n = 12) or unlabeled MSCs (n = 12) or vehicle alone injection. The distribution and migration of implanted cells was followed by MRI and correlated with histology. The relative signal intensity (RSL) of the grafts was measured.

Results

The labeling efficiency was 76 ± 4.7% and the labeling procedure did not in?uence cell viability, proliferation, and apoptosis. A persistent higher RSL in grafts was found in the labeled group compared with the unlabeled and vehicle groups until 10 days after transplantation (P < 0.05). The distribution and migration of labeled cells could be tracked by MRI until 10 days after transplantation. Transplanted MSCs were not found to transdifferentiate into Schwann‐like cells within 14‐day follow‐up.

Conclusion

Labeling MSCs with the dual agents may enable cellular MRI of the engraftment in the experimental peripheral nerve injury. J. Magn. Reson. Imaging 2010;32:1076–1085. © 2010 Wiley‐Liss, Inc.

     

Magnetic nanoparticles for imaging dendritic cells

We report the development of superparamagnetic iron oxide (SPIOs) nanoparticles and investigate the migration of SPIO‐labeled dendritic cells (DCs) in a syngeneic mouse model using magnetic resonance (MR) imaging. The size of the dextran‐coated SPIO is roughly 30 nm, and the DCs are capable of independent uptake of these particles, although not at levels comparable to particle uptake in the presence of a transfecting reagent. On average, with the assistance of polylysine, the particles were efficiently delivered inside DCs within one hour of incubation. The SPIO particles occupy approximately 0.35% of cell surface and are equivalent to 34.6 pg of iron per cell. In vivo imaging demonstrated that the labeled cells migrated from the injection site in the footpad to the corresponding popliteal lymph node. The homing of labeled cells in the lymph nodes resulted in a signal drop of up to 79%. Furthermore, labeling DCs with SPIO particles did not compromise cell function, we demonstrated that SPIO‐enhanced MR imaging can be used to track the migration of DCs effectively in vivo. Magn Reson Med 63:1383–1390, 2010. © 2010 Wiley‐Liss, Inc.     

Serial in vivo MR tracking of magnetically labeled neural spheres transplanted in chronic EAE mice.

Neural stem cell (NSC) transplantation has been shown to attenuate the severity of experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis (MS). Central to the future success of NSC transplantation in MS is the ability of transplanted cells to migrate from the site of transplantation to relevant foci of disease. Using magnetically labeled mouse neurospheres and human embryonic stem cell (hESC)-derived neurospheres, we applied serial magnetic resonance imaging (MRI) to assess the biodynamics of transplanted cell migration in a chronic mouse EAE model. Magnetic labeling did not affect the in vitro and in vivo characteristics of cells as multipotential precursors. Cell migration occurred along white matter (WM) tracts (especially the corpus callosum (CC), fimbria, and internal capsule), predominantly early in the acute phase of disease, and in an asymmetric manner. The distance of cell migration correlated well with clinical severity of disease and the number of microglia in the WM tracts, supporting the notion that inflammatory signals promote transplanted cell migration. This study shows for the first time that hESC-derived neural precursors also respond to tissue signals in an MS model, similarly to rodent cells. The results are directly relevant for designing and optimizing cell therapies for MS, and achieving a better understanding of in vivo cell dynamics and cell-tissue interactions.     

Long‐term MR cell tracking of neural stem cells grafted in immunocompetent versus immunodeficient mice reveals distinct differences in contrast between live and dead cells

Neural stem cell (NSC)‐based therapy is actively being pursued in preclinical and clinical disease models. Magnetic resonance imaging (MRI) cell tracking promises to optimize current cell transplantation paradigms, however, it is limited by dilution of contrast agent during cellular proliferation, transfer of label from dying cells to surrounding endogenous host cells, and/or biodegradation of the label. Here, we evaluated the applicability of magnetic resonance imaging for long‐term tracking of transplanted neural stem cells labeled with superparamagnetic iron oxide and transfected with the bioluminescence reporter gene luciferase. Mouse neural stem cells were transplanted into immunodeficient, graft‐accepting Rag2 mice or immunocompetent, graft‐rejecting Balb/c mice. Hypointense voxel signals and bioluminescence were monitored over a period of 93 days. Unexpectedly, in mice that rejected the cells, the hypointense MR signal persisted throughout the entire time‐course, whereas in the nonrejecting mice, the contrast cleared at a faster rate. In immunocompetent, graft‐rejecting Balb/c mice, infiltrating leukocytes, and microglia were found surrounding dead cells and internalizing superparamagnetic iron oxide clusters. The present results indicate that live cell proliferation and associated label dilution may dominate contrast clearance as compared with cell death and subsequent transfer and retention of superparamagnetic iron oxide within phagocytes and brain interstitium. Thus, interpretation of signal changes during long‐term MR cell tracking is complex and requires caution. Magn Reson Med, 2011. © 2010 Wiley‐Liss, Inc.     

In vivo “hot spot” MR imaging of neural stem cells using fluorinated nanoparticles

To optimize ¹⁹F MR tracking of stem cells, we compared cellular internalization of cationic and anionic perfluoro‐15‐crown‐5‐ether (PFCE) nanoparticles using cell culture plates with different surface coatings. The viability and proliferation of anionic and cationic PFCE‐labeled neural stem cells (NSCs) did not differ from unlabeled cells. Cationic PFCE nanoparticles (¹⁹F T1/T2 = 580/536 ms at 9.4 Tesla) were superior to anionic particles for intracellular fluorination. Best results were obtained with modified polystyrene culture dishes coated with both carboxylic and amino groups rather than conventional carboxyl‐coated dishes. After injecting PFCE‐labeled NSCs into the striatum of mouse brain, cells were readily identified in vivo by ¹⁹F MRI without changes in signal or viability over a 2‐week period after grafting. These results demonstrate that neural stem cells can be efficiently fluorinated with cationic PFCE nanoparticles without using transfection agents and visualized in vivo over prolonged periods with an MR sensitivity of approximately 140 pmol of PFCE/cell. Magn Reson Med 60:1506–1511, 2008. © 2008 Wiley‐Liss, Inc.     

In vivo MRI of embryonic stem cells in a mouse model of myocardial infarction.

The therapeutic potential of administering stem cells to promote angiogenesis and myocardial tissue regeneration after infarction has recently been demonstrated. Given the advantages of using embryonic stem cells and mouse models of myocardial infarction for furthering the development of this therapeutic approach, the purpose of this study was to determine if embryonic stem cells could be loaded with superparamagnetic iron oxide (SPIO) particles and imaged in a mouse model of myocardial infarction over time using MRI. Mouse embryonic stem cells were labeled with SPIO particles. When incubated with 11.2, 22.4, and 44.8 microg Fe/ml of SPIO particles, cells took up increasing amounts of iron oxide. Embryonic stem cells loaded with SPIO compared to unlabeled cells had similar viability and proliferation profiles for up to 14 days. Free SPIO injected into infarcted myocardium was not observable within 12 hr after injection. After injection of three 10-microl aliquots of 10(7) SPIO-loaded cells/ml into infarcted myocardium, MRI demonstrated that the mouse embryonic stem cells were observable and could be seen for at least 5 weeks after injection. These findings support the ability of MRI to test the long-term therapeutic potential of embryonic stem cells in small animals in the setting of myocardial infarction.     

新型超顺磁性氧化铁标记SD大鼠脂肪干细胞的有效性及安全性研究

目的：采用新型超顺磁性氧化铁对 SD 大鼠来源的脂肪干细胞（ADSCs）进行标记,并与既往商用 SPIO 标记效果进行对比,探讨这种新型超顺磁性氧化铁标记的有效性及安全性。方法：分离、纯化、鉴定 SD 大鼠来源的 ADSCs,然后分不同浓度组（0、6、12、25、50和100μg／mL）和时间组（6、12、24和48 h）进行标记,通过普鲁士蓝染色测定铁标记率;在不影响细胞形态的前提下,对达到95％以上铁染色率的孵育浓度、时间进行标记安全性检测,包括活力、增殖力、细胞表面抗原表达;采用透射电子显微镜观察标记细胞的超微结构,采用 ICP-AES 对标记细胞内的铁含量进行测定,并与商用SPIO 标记效果进行对比。结果：在无细胞毒性的前提下,新型 SPIO 达到95％以上铁染色率的孵育浓度是12和25μg／mL,孵育时间是12 h;ICP-AES 检测显示具有表面正电荷的聚乙二醇（PEG）／聚乙烯亚胺（PEI）修饰的 SPIO 标记后细胞内的铁含量达到35．4 pg／cell（25μg／mL 中孵育12h 后）和20．16 pg／cell（12μg／mL 中孵育12h 后）,并随着孵育浓度的增加,细胞内的铁含量增加;而具有表面零电荷的 PEG／聚乙烯吡咯烷酮（PVP）修饰的 SPIO 标记后的铁含量仅为6．96 pg／cell（25μg／mL 中孵育12h 后）;透射电子显微镜显示标记后细胞器结构完整,内吸收的 SPIO 主要位于细胞质内的囊泡和溶酶体中。结论：新型 SPIO 在适当孵育浓度和时间下可以安全、快速标记 ADSCs;PEG／PEI 修饰的 SPIO 标记效果要远远比既往商用的 SPIO 快速有效,可作为一种优势的新型磁性标记物用于干细胞标记;而 PEG／PVP 修饰的SPIO 比起既往商用的 SPIO 并无明显优势,说明表面电荷在细胞标记中占有极其重要的角色。     

Cell tracking using iron oxide fails to distinguish dead from living transplanted cells in the infarcted heart

Recently, debate has arisen about the usefulness of cell tracking using iron oxide–labeled cells. Two important issues in determining the usefulness of cell tracking with MRI are generally overlooked; first, the effect of graft rejection in immunocompetent models, and second, the necessity for careful histological confirmation of the fate of the labeled cells in the presence of iron oxide. Therefore, both iron oxide–labeled living as well as dead epicardium‐derived cells (EPDCs) were investigated in ischemic myocardium of immunodeficient non‐obese diabetic (NOD)/acid: non‐obese diabetic severe combined immunodeficient (NOD/scid) mice with 9.4T MRI until 6 weeks after surgery, at which time immunohistochemical analysis was performed. In both groups, voids on MRI scans were observed that did not change in number, size, or localization over time. Based on MRI, no distinction could be made between living and dead injected cells. Prussian blue staining confirmed that the hypointense spots on MRI corresponded to iron‐loaded cells. However, in the dead‐EPDC recipients, all iron‐positive cells appeared to be macrophages, while the living‐EPDC recipients also contained engrafted iron‐loaded EPDCs. Iron labeling is inadequate for determining the fate of transplanted cells in the immunodeficient host, since dead cells produce an MRI signal indistinguishable from incorporated living cells. Magn Reson Med 63:817–821, 2010. © 2010 Wiley‐Liss, Inc.     

In vivo MR imaging of intravascularly injected magnetically labeled mesenchymal stem cells in rat kidney and liver

PURPOSE: To evaluate in vivo magnetic resonance (MR) imaging with a conventional 1.5-T system for depiction and tracking of intravascularly injected superparamagnetic iron oxide (SPIO)-labeled mesenchymal stem cells (MSCs). MATERIALS AND METHODS: This study was conducted in accordance with French law governing animal research and met guidelines for animal care and use. Rat MSCs were labeled with SPIO and transfection agent. Relaxation rates at 1.5 T, cell viability, proliferation, differentiation capacity, and labeling stability were assessed in vitro as a function of SPIO concentration. MSCs were injected into renal arteries of healthy rats (labeled cells in four, unlabeled cells in two) and portal veins of rats treated with carbon tetrachloride to induce centrolobular liver necrosis (labeled cells and unlabeled cells in two each). Follow-up serial T2*-weighted gradient-echo MR imaging and R2* mapping were performed. MR imaging findings were compared histologically. RESULTS: SPIO labeling caused a strong R2* effect that increased linearly with iron dose; R2* increase for cells labeled for 48 hours with 50 microg of iron per milliliter was 50 sec(-1) per million cells per milliliter. R2* was proportional to iron load of cells. SPIO labeling did not affect cell viability (P > .27). Labeled cells were able to differentiate into adipocytes and osteocytes. Proliferation was substantially limited for MSCs labeled with 100 microg Fe/mL or greater. Label half-life was longer than 11 days. In normal kidneys, labeled MSCs caused signal intensity loss in renal cortex. After labeled MSC injection, diseased liver had diffuse granular appearance. Cells were detected for up to 7 days in kidney and 12 days in liver. Signal intensity loss and fading over time were confirmed with serial R2* mapping. At histologic analysis, signal intensity loss correlated with iron-loaded cells, primarily in renal glomeruli and hepatic sinusoids; immunohistochemical analysis results confirmed these cells were MSCs. CONCLUSION: MR imaging can aid in monitoring of intravascularly administered SPIO-labeled MSCs in vivo in kidney and liver.     

Chondrocyte gene expression is affected by very small iron oxide particles-labeling in long-term in vitro MRI tracking

Purpose:

To investigate the effect and dose response of very small iron oxide particles (VSOP) labeling of human chondrocytes for long‐term in vitro MRI tracking.

Materials and Methods:

Chondrocytes were isolated from cartilage biopsies from four patients. The cells for the dose–response study were labeled with 25, 50, or 100 μg/mL VSOP. Quantitative gene expression and cellular proliferation were compared with unlabeled controls at day 1, 3, and 7. The cells suited for MRI tracking were labeled with 50 μg/mL VSOP and embedded in alginate beads, followed by MRI (using T2‐weighted sequences) at day 0, 1, 3, 7, 14, 21, 28, and histology was performed at each time‐point.

Results:

Histology revealed that VSOP particles were intracellularly confined at all time‐points, whereas no extracellular VSOPs were observed. A mean reduction in T2‐value of 25.1 ms (±SD 3.5 ms) was found on T2‐maps. The chondrocyte‐specific genes aggrecan, collagen type 2, and sox9 were all affected by labeling, the two latter in a dose‐dependent manner. VSOPs had no effect on proliferation.

Conclusion:

VSOP labeling of chondrocytes affected gene expression but not proliferation. The labeled chondrocytes could be recognized by MRI for 4 weeks without significant changes in the T2 relaxation time. J. Magn. Reson. Imaging 2011;33:724–730. © 2011 Wiley‐Liss, Inc.     

Depicting adoptive immunotherapy for prostate cancer in an animal model with magnetic resonance imaging

Genetically modified natural killer (NK) cells that recognize tumor‐associated surface antigens have recently shown promise as a novel approach for cancer immunotherapy. To determine NK cell therapy response early, a real‐time, noninvasive method to quantify NK cell homing to the tumor is desirable. The purpose of this study was to evaluate if MR imaging could provide a noninvasive, in vivo diagnosis of NK cell accumulation in epithelial cell adhesion molecule (EpCAM)‐positive prostate cancers in a rat xenograft model. Genetically engineered NK‐92‐scFv(MOC31)‐ζ cells, which express a chimeric antigen receptor specific to the tumor‐associated EpCAM antigen, and nontargeted NK‐92 cells were labeled with superparamagnetic particles of iron‐oxides (SPIO) ferumoxides. Twelve athymic rats with implanted EpCAM positive DU145 prostate cancers received intravenous injections of 1.5 × 10⁷ SPIO labeled NK‐92 and NK‐92‐scFv(MOC31)‐ζ cells. EpCAM‐positive prostate cancers demonstrated a progressive and a significant decline in contrast‐to‐noise‐ratio data at 1 and 24 h after injection of SPIO‐labeled NK‐92‐scFv(MOC31)‐ζ cells. Conversely, tumor contrast‐to‐noise‐ratio data did not change significantly after injection of SPIO‐labeled parental NK‐92 cells. Histopathology confirmed an accumulation of the genetically engineered NK‐92‐scFv(MOC31)‐ζ cells in prostate cancers. Thus, the presence or absence of a tumor accumulation of therapeutic NK cells can be monitored with cellular MR imaging. EpCAM‐directed, SPIO labeled NK‐92‐scFv(MOC31)‐ζ cells accumulate in EpCAM‐positive prostate cancers. Magn Reson Med, 2011. © 2010 Wiley‐Liss, Inc.