肾功能衰竭大鼠超顺磁性氧化铁标记骨髓间充质干细胞肾脏移植MR活体示踪的研究

目的应用磁性氧化铁纳米粒子和多聚左旋赖氨酸（poly-L-lysine，PLL）的偶联物Fe2O3-PLL标记大鼠骨髓间充质干细胞（MSCs），MR活体示踪经肾动脉移植入肾功能衰竭（简称肾衰）大鼠肾脏的标记细胞。方法制备Fe2O3-PLL，分离、纯化并培养大鼠骨髓MSCs，Fe2O3-PLL标记细胞，普鲁士蓝染色显示细胞内铁。肌内注射甘油所致肾衰的大鼠分为2组，分别经左肾动脉移植入标记细胞（6只）和未标记细胞（5只），移植后即刻及第1、3、5、8天应用MRI对移植细胞进行活体示踪，并与肾脏组织切片普鲁士蓝染色和HE染色对照。结果MSCs的Fe2O3-PLL标记率近100％，普鲁士蓝染色显示蓝色铁颗粒位于MSCs胞质内。标记细胞移植后肾衰大鼠肾脏皮质区信号强度明显下降，T2＊WI信号改变最明显，而肾髓质及肾盂信号较细胞移植前无明显变化，信号改变随着时间的延长逐渐减轻一直持续到移植后第8天。组织学分析见绝大多数标记细胞分布于肾皮质肾小球内，与MRI信号改变区域基本一致。未标记细胞移植后未见肾脏信号改变。结论Fe2O3-PLL可以有效标记大鼠骨髓MSCs，临床应用型1．5T磁共振仪可对经肾动脉移植入肾衰大鼠肾脏的标记细胞进行初步活体示踪。     

R2 and R2* mapping for sensing cell-bound superparamagnetic nanoparticles: in vitro and murine in vivo testing

PURPOSE: To prospectively determine the cellular iron uptake by using R2 and R2* mapping with multiecho readout gradient-echo and spin-echo sequences. MATERIALS AND METHODS: All experiments were approved by the institutional animal care committee. Lung carcinoma cells were lipofected with superparamagnetic iron oxides (SPIOs). Agarose gel phantoms containing (a) 1 x 10(5) CCL-185 cells per milliliter of agarose gel with increasing SPIO load (0.01-5.00 mg of iron per milliliter in the medium), (b) different amounts (5.0 x 10(3) to 2.5 x 10(5) cells per milliliter of agarose gel) of identically loaded cells, and (c) free (non-cell-bound) SPIOs at the iron concentrations described for (b) were analyzed with 3.0-T R2 and R2* relaxometry. Iron uptake was analyzed with light microscopy, quantified with atomic emission spectroscopy (AES), and compared with MR data. For in vivo relaxometry, agarose gel pellets containing SPIO-labeled cells, free SPIO, unlabeled control cells, and pure agarose gel were injected into three nude mice each. Linear and nonlinear regression analyses were performed. RESULTS: Light microscopy and AES revealed efficient SPIO particle uptake (mean uptake: 0.22 pg of iron per cell +/- 0.1 [standard deviation] for unlabeled cells, 31.17 pg of iron per cell +/- 4.63 for cells incubated with 0.5 mg/mL iron). R2 and R2* values were linearly correlated with cellular iron load, number of iron-loaded cells, and content of freely dissolved iron (r(2) range, 0.92-0.99; P < .001). For cell-bound SPIO, R2* effects were significantly greater than R2 effects (P < .01); for free SPIO, R2 and R2* effects were similar. In vivo relaxometry enabled accurate prediction of the number of labeled cells. R2' (R2* - R2) mapping enabled differentiation between cell-bound and free iron in vitro and in vivo. CONCLUSION: Quantitative R2 and R2* mapping enables noninvasive estimations of cellular iron load and number of iron-labeled cells. Cell-bound SPIOs can be differentiated from free SPIOs with R2' imaging.     

Transferrin receptor upregulation: in vitro labeling of rat mesenchymal stem cells with superparamagnetic iron oxide

PURPOSE: To prospectively evaluate the influence of superparamagnetic iron oxide (SPIO) or ultrasmall SPIO (USPIO) particles on the surface epitope pattern of adult mesenchymal stem cells (MSCs) by regulating the expression of transferrin receptor and to prospectively evaluate the influence of transfection agents (TAs) on the uptake of SPIO or USPIO particles in MSCs. MATERIALS AND METHODS: The study was approved by the institutional animal care committee of the University of Tübingen. MSCs were isolated from the bone marrow of four rats. To obtain highly homogeneous MSC populations, MSCs from one rat were single-cell cloned. One MSC clone was characterized and selected for the labeling experiments. The MSCs, which were characterized with flow cytometry and in vitro differentiation, were labeled with 200 microg/mL SPIO or USPIO or with 60 microg/mL SPIO or USPIO in combination with TAs. Aggregations of labeled cells were accommodated inside a defined volume in an agar gel matrix. Magnetic resonance (MR) imaging was performed to measure SPIO- or USPIO-induced signal voids. Quantification of cellular total iron load (TIL) (intracellular iron plus iron coating the cellular surface), determination of cellular viability, and electron microscopy were also performed. RESULTS: Labeling of MSCs with SPIO or USPIO was feasible without affecting cell viability (91.1%-94.7%) or differentiation potential. For MR imaging, SPIO plus a TA was most effective, depicting 5000 cells with an average TIL of 76.5 pg per cell. SPIO or USPIO particles in combination with TAs coated the cellular surface but were not incorporated into cells. In nontransfected cells, SPIO or USPIO was taken up. MSCs labeled with SPIO or USPIO but without a TA showed enhanced expression of transferrin receptor, in contrary to both MSCs labeled with SPIO or USPIO and a TA and control cells. CONCLUSION: SPIO or USPIO labeling without TAs has an influence on gene expression of MSCs upregulating transferrin receptor. Furthermore, SPIO labeling with a TA will coat the cellular surface.     

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。     

磁性标记的小胶质细胞在大鼠脑内的MR示踪

目的 探讨超顺磁性氧化铁颗粒(SPIO)标记的小胶质细胞在正常大鼠及阿尔茨海默病(AD)大鼠体内移植后,MR活体示踪的可行性.方法 以日本血液凝集病毒包膜(HVJ-E)为标记载体,将SPIO标记的小胶质细胞经颈内动脉注入正常大鼠(5只)及AD大鼠动物模型(5只)体内,3 d后应用7.0 T MR行T2*序列扫描,并与脑组织切片组织化学染色结果对照.结果 在正常大鼠脑内,MRI可见数个点状的信号改变区,这些信号改变区散在地分布在脑内各处,脑组织切片显示铁颗粒标记细胞位置与信号改变部位一致.MRI能够检测到由数个标记细胞引起的信号强度的改变.在AD大鼠模型脑内,MRI可见β-淀粉样蛋白42(Aβ42)注射区信号强度明显下降,信号改变区面积较大.与之相比,生理盐水注射区信号改变的强度及面积均不如Aβ42注射区改变明显.Aβ42注射区的标记细胞数为(454±47)个/mm2,明显高于生理盐水注射区的标记细胞数(83±13)个/mm2(P<0.05).结论 MRI可作为一种非侵入性检测手段在活的动物体内追踪标记细胞,在AD细胞水平的治疗中具有一定临床应用前景.     

MR evaluation of the glomerular homing of magnetically labeled mesenchymal stem cells in a rat model of nephropathy

PURPOSE: To assess renal glomerular homing of intravenously injected superparamagnetic iron oxide (SPIO)-labeled mesenchymal stem cells (MSCs) at in vivo and ex vivo magnetic resonance (MR) imaging in an experimental rat model of mesangiolysis. MATERIALS AND METHODS: Animal procedures were performed in accordance with protocols approved by Institutional Animal Care and Use Committee. Fourteen rats were divided into two groups: one pathologic (n = 10), with persistent mesangiolysis following simultaneous injection of OX-7 monoclonal antibody and puromycin aminonucleoside in which 10(7) SPIO- and DiI-labeled MSCs were injected, and one control (n = 4). In vivo and ex vivo MR imaging examinations were performed with 4.7- and 9.4-T spectrometers, respectively, and T2*-weighted sequences. In vivo signal intensity variations were measured in the liver and kidney before and 6 days after MSC injection. Intrarenal signal intensity variations were correlated with histopathologic data by means of colocalization of DiI fluorescence, alpha-actin, and Prussian blue stain-positive cells. Histologic differences between the glomerular homing of MSCs in different kidney portions were correlated to the areas of MR signal intensity decrease with nonparametric statistical tests. RESULTS: On in vivo images, signal intensity measurements of pathologic kidneys following MSC injection did not show any signal intensity decrease (P = .7), whereas a 34% +/- 14 (mean +/- standard deviation) signal intensity decrease was observed in the liver (P < .01), where a substantial number of labeled cells were trapped. On ex vivo images, pathologic kidneys showed focal cortical (glomerular) areas of signal intensity loss, which was absent in controls. The areas of low signal intensity correlated well with alpha-actin and Prussian blue stain- and DiI-positive areas (P < .01), which indicates that MSCs specifically home to injured tissue. No MSCs were detected in the kidneys of control animals. CONCLUSION: Intravenously injected MSCs specifically home to focal areas of glomerular damage and can be detected at ex vivo MR imaging.     

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.     

Comparison of SPIO and USPIO for in vitro labeling of human monocytes: MR detection and cell function

PURPOSE: To label human monocytes with superparamagnetic iron oxide (SPIO) and compare labeling efficiency with that of ultrasmall SPIO (USPIO) and evaluate the effect of iron incorporation on cell viability, migratory capacity, and proinflammatory cytokine production. MATERIALS AND METHODS: The study was approved by the institutional ethics committee; informed consent was obtained from donors. Freshly isolated human monocytes were labeled with iron particles of two sizes, USPIOs of 30 nm and SPIOs of 150 nm, for 1.5 hours in culture medium containing 0.1, 0.5, 1.0, and 3.7 mg of iron per milliliter. Labeling efficiency was determined with relaxation time magnetic resonance (MR) imaging (4.7 T) and Prussian blue staining for presence of intracellular iron. Cell viability was monitored; migratory capacity of monocytes after labeling was evaluated by using an in vitro assay with monolayers of brain endothelial cells. Levels of proinflammatory cytokines, interleukin (IL) 1 and IL-6, were measured with enzyme-linked immunosorbent assay 24 hours after labeling. Data were analyzed with Student t test or two-way analysis of variance followed by a multiple-comparison procedure. RESULTS: R2 relaxation rates increased for cell samples incubated with SPIOs, whereas rates were not affected for samples incubated with highest concentration of USPIOs. Labeling monocytes with SPIOs (1.0 mg Fe/mL) resulted in an R2 of 13.1 sec(-1) +/- 0.8 (standard error of the mean) (7 sec(-1) +/- 0.2 for vehicle-treated cells, P < .05) and had no effect on cell viability. On the basis of T2 relaxation times, the in vitro MR detection limit of 58 labeled monocytes per 0.05 microL was calculated. Migration of labeled monocytes was not different from that of vehicle-treated cells. Intracellular iron had no effect on production of IL-1 and IL-6 24 hours after labeling. CONCLUSION: In vitro labeling of human monocytes is effective by using SPIOs, not USPIOs. Incubation with SPIOs (1.0 mg Fe/mL) results in efficient labeling detectable on MR images and does not affect cellular viability and activation markers such as cell migration and cytokine production.     

Iron oxide nanoparticle-labeled rat smooth muscle cells: cardiac MR imaging for cell graft monitoring and quantitation

PURPOSE: To perform a quantitative analysis of anionic maghemite nanoparticle-labeled cells in vitro and determine the effect of labeling on signal intensity at magnetic resonance (MR) imaging. MATERIALS AND METHODS: The study was approved by the institutional animal care and use committee at H?pital Bichat. In vitro cell proliferation, iron content per cell, and MR signal intensity of cells were measured in agarose phantoms for 0-14 days of culture after labeling of rat smooth muscle cells with anionic maghemite nanoparticles. Next, iron oxide-labeled smooth muscle cells were injected into healthy hearts and hearts with ischemic injury in seven live Fisher rats. Ex vivo MR imaging experiments in excised hearts 2 and 48 hours after injection were performed with a 1.5-T medical imaging system by using T2-weighted gradient-echo and spin-echo sequences. Histologic sections were obtained after MR imaging. Correlation analyses between division factor of iron load and cell amplification factor and between 1/T2 and number of labeled cells or number of days in culture were performed by using linear regression. RESULTS: Viability of smooth muscle cells was not affected by magnetic labeling. Transmission electron micrographs of cells revealed the presence of iron oxide nanoparticles in vesicles up to day 14 of culture. Intracellular iron concentration decreased in parallel with cell division (r2 = 0.99) and was correlated with MR signal intensity (r2 = 0.95). T2*-weighted MR images of excised rat hearts showed hypointense signal in myocardium at 2 and 48 hours after local injection of labeled cells. Subsequent histologic staining evidenced iron oxide nanoparticles within cells and confirmed the presence of the original cells at 2 and 48 hours after implantation. CONCLUSION: Magnetic labeling of smooth muscle cells with anionic maghemite nanoparticles allows detection of cells with MR imaging after local transplantation in the heart.     

MR tracking of transplanted cells with "positive contrast" using manganese oxide nanoparticles

Rat glioma cells were labeled using electroporation with either manganese oxide (MnO) or superparamagnetic iron oxide (SPIO) nanoparticles. The viability and proliferation of SPIO-labeled cells (1.9 mg Fe/ml) or cells electroporated with a low dose of MnO (100 microg Mn/ml) was not significantly different from unlabeled cells; a higher MnO dose (785 microg Mn/ml) was found to be toxic. The cellular ion content was 0.1-0.3 pg Mn/cell and 4.4 pg Fe/cell, respectively, with cellular relaxivities of 2.5-4.8 s(-1) (R(1)) and 45-84 s(-1) (R(2)) for MnO-labeled cells. Labeled cells (SPIO and low-dose MnO) were each transplanted in contralateral brain hemispheres of rats and imaged in vivo at 9.4T. While SPIO-labeled cells produced a strong "negative contrast" due to the increase in R(2), MnO-labeled cells produced "positive contrast" with an increased R(1). Simultaneous imaging of both transplants with opposite contrast offers a method for MR "double labeling" of different cell populations.     

磁标记大鼠骨髓间充质干细胞活体内移植后向肝癌细胞趋向性迁移的研究

目的 探讨磁标记大鼠骨髓间充质干细胞(BMSCs)活体内移植后对大鼠肝细胞癌的趋向性迁移及其机制.方法 培养大鼠BMSCs,超顺磁性氧化铁粒子标记.制备大鼠肝癌模型24只,数字表法随机分为3组:实验组(n=12)经脾植入磁标记的BMSCs;对照组A(n=6)移植未标记的BMSCs;对照组B(n=6)不作任何处理.分别于移植前及移植后1、3、7和14 d行MR扫描,选用T_2*WI序列进行移植细胞的示踪并测量肿瘤组织与正常肝组织的信号强度的比值(SI/SI*),结果行单因素方差分析;取肿瘤组织、瘤旁正常肝组织行普鲁士蓝染色,分析BMSCs在体内的分布并与MR对照.结果 BMSCs的磁标记率为90%以上.移植后实验组T_2*WI显示肿瘤信号强度值明显减低,移植前及移植后1、3、7和14 d的SI/SI*值分别为3.18±0.21、1.98±0.20、2.38±0.28、2.70±0.25及3.16±0.24,差异有统计学意义(F=56.65,P<0.05);与移植前相比,1、3、7 d肿瘤信号强度的减低有统计学意义(t值分别为1.20、0.79、0.48,P值均<0.05).对照组移植前后各SI/SI*值差异无统计学意义(P>0.05).免疫组织化学显示实验组肿瘤边缘及内部有大量监染的普鲁士蓝阳性细胞分布,标记细胞在肿瘤内的分布与MR信号改变基本一致.对照组肿瘤组织普鲁士蓝染色均为阴性结果.结论 BMSCs在活体内对肝癌细胞有明显的趋向迁移特性,有望成为基因治疗肝细胞癌的载体.     

大鼠骨髓间充质干细胞的钆-荧光双标记及MRI体外示踪的研究

目的 应用多聚胺载体,对大鼠骨髓间充质干细胞(MSCs)进行钆喷替酸葡甲胺(Gd-DTPA)及荧光双标记,探讨MSCs MR磁性标记及体外示踪的可行性.方法 以聚乙烯亚胺-罗丹明复合物(JetPEI-FluoR)为载体,制备Gd-DTPA双标记示踪剂,培养分离SD大鼠骨髓MSCs,以此示踪剂体外标记间MSCs.对标记后细胞行生物学性状检测及电镜、荧光镜观察.应用1.5 T MR仪,对标记的干细胞进行sE T1 WI及T2 WI及混合(mixed)回波序列的T1测量,标记细胞正常传代后进行MR检查,观察标记的持久性.标记细胞、未标记细胞的T1 WI信号强度、T1之间的比较使用t检验,台盼蓝拒染率采用两因素重复资料方差分析,不同浓度示踪下细胞吸光度比较采用单因素方差分析.结果双标记示踪剂标记5×105个MSCs,标记成功了4.25×105个,荧光镜下标记率为85%,电镜下钆(Gd)颗粒主要位于胞质内高尔基体周围.双标记示踪剂孵育3、6、12、24 h内标记细胞的台盼蓝拒染率分别为(96.55±2.90)%、(94.17±2.56)%、(97.16±3.12)%、(94.23±2.67)%,相应的未标记细胞的拒染率分别为(95.86±2.67)%、(92.04±2.21)%、(93.38±3.64)%、(92.12±2.53)%,24 h内标记细胞与未标记细胞拒染率差异无统学意义(F=4.523,P＞0.05).细胞增殖实验中,在2.5、5.0、10.0、20.0、30.0、40.0 μl不同浓度示踪剂时,标记细胞的吸光度分别为(0.1884±0.0151)、(0.1878±0.0190)、(0.1741±0.0160)、(0.1135±0.0215)、(0.1079±0.0145)、(0.0811±0.0079),未标记细胞为(0.1940±0.0116),Gd-DTPA 30.0 μl以下标记细胞与未标记细胞吸光度差异无统计学意义(q'=0.2225～0.9458,P＞0.05).标记后细胞凋亡指数为5.08%,对照组未标记细胞为3.86%.未标记细胞T1 WI平均信号强度及T1分别为240.3±24.7、(2457±56)ms,而标记细胞为336.2±20.7、(1102±64)ms,两者间差异有统计学意义(t值分别为12.656、17.889,P值均＜0.01),T1 WI可监测到最低密度为5×103个标记细胞.标记细胞正常传代后,MRI体外可持续显示至第4代标记细胞.结论应用多聚胺载体对大鼠间充质干细胞进行Gd-DTPA及荧光双标记,安全有效,MRI能示踪体外双标记的干细胞.     

Early radiation effects on the liver demonstrated on superparamegnetic iron oxide-enhanced T1-weighted MRI

Early radiation-induced liver injury during radiotherapy detected by a particulate reticuloendothelial MR contrast agent (superparamagnetic iron oxide; SPIO) is described in a patient with cholangiocarcinoma. The irradiated hepatic parenchyma appeared as a heterogeneous, less decreased signal intensity area than the nonirradiated area on MR images after SPIO administration. Resultant differences in signal intensity were better visualized on SPIO-enhanced T1-weighted images than SPIO-enhanced T2-weighted images, although SPIO-enhanced T2*-weighted fast field echo imaging was the most sensitive.     

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.     

Cell motility of neural stem cells is reduced after SPIO‐labeling,which is mitigated after exocytosis

MRI is used for tracking of superparamagnetic iron oxide (SPIO)‐labeled neural stem cells. Studies have shown that long‐term MR tracking of rapidly dividing cells underestimates their migration distance. Time‐lapse microscopy of random cellular motility and cell division was performed to evaluate the effects of SPIO‐labeling on neural stem cell migration. Labeled cells divided symmetrically and exhibited no changes in cell viability, proliferation, or apoptosis. However, SPIO‐labeling resulted in decreased motility of neural stem cells as compared with unlabeled controls. When SPIO‐labeled neural stem cells and human induced pluripotent stem cells were transplanted into mouse brain, rapid exocytosis of SPIO by live cells was observed as early as 48 h postengraftment, with SPIO‐depleted cells showing the farthest migration distance. As label dilution is negligible at this early time point, we conclude that MRI underestimation of cell migration can also occur as a result of reduced cell motility, which appears to be mitigated following SPIO exocytosis. Magn Reson Med, 2013. © 2012 Wiley Periodicals, Inc.     

Quantification of superparamagnetic iron oxide (SPIO)-labeled cells using MRI

PURPOSE: To show the feasibility of using magnetic resonance imaging (MRI) to quantify superparamagnetic iron oxide (SPIO)-labeled cells. MATERIALS AND METHODS: Lymphocytes and 9L rat gliosarcoma cells were labeled with ferumoxides-protamine sulfate complex (FE-PRO). The cells were labeled efficiently (more than 95%) and the iron concentration inside each cell was measured by spectrophotometry (4.77-30.21 pg). Phantom tubes containing different numbers of labeled or unlabeled cells, as well as different concentrations of FE-PRO, were made. In addition, labeled and unlabeled cells were injected into fresh and fixed rat brains. RESULTS: Cellular viability and proliferation of labeled and unlabeled cells were shown to be similar. T2-weighted images were acquired using 7T and 3T MRI systems, and R2 maps of the tubes containing cells, free FE-PRO, and brains were made. There was a strong linear correlation between R2 values and labeled cell numbers, but the regression lines were different for the lymphocytes and gliosarcoma cells. Similarly, there was strong correlation between R2 values and free iron. However, free iron had higher R2 values than the labeled cells for the same concentration of iron. CONCLUSION: Our data indicate that in vivo quantification of labeled cells can be done by careful consideration of different factors and specific control groups.     

MR Imaging Enables Measurement of Therapeutic Nanoparticle Uptake in Rat N1-S1 Liver Tumors after Nanoablation

PurposeTo test the hypothesis that magnetic resonance (MR) imaging can quantify intratumoral superparamagnetic iron oxide (SPIO) nanoparticle uptake after nanoablation.Materials and MethodsSPIO nanoparticles functionalized with doxorubicin were synthesized. N1-S1 hepatomas were successfully induced in 17 Sprague-Dawley rats distributed into three dosage groups. Baseline tumor R2* values (the reciprocal of T2*) were determined using 7-tesla (T) MR imaging. After intravenous injection of SPIO nanoparticles, reversible electroporation (1,300 V/cm, 8 pulses, 100-μs pulse duration) was applied. Imaging of rats was performed to determine tumor R2* values after the procedure, and change in R2* (ΔR2*) was calculated. Inductively coupled plasma mass spectrometry was used to determine intratumoral iron (Fe) concentration after the procedure, which served as a proxy for SPIO nanoparticle uptake. Mean tumor Fe concentration [Fe] and ΔR2* for each subject were assessed for correlation with linear regression, and mean [Fe] for each dosage group was compared with analysis of variance.ResultsΔR2* significantly correlated with tumor SPIO nanoparticle uptake after nanoablation (r = 0.50, P = .039). On average, each 0.1-ms⁻¹ increase in R2* corresponded to a 0.1394-mM increase in [Fe]. There was no significant difference in mean SPIO nanoparticle uptake among dosage groups (P = .57).ConclusionsIntratumoral SPIO nanoparticle uptake after nanoablation can be successfully quantified noninvasively with 7-T MR imaging. Imaging can be used as a method to estimate localized drug delivery after nanoablation.     

In Vivo MR Imaging of Magnetically Labeled Mesenchymal Stem Cells in a Rat Model of Renal Ischemia

Objective

This study was designed to evaluate in vivo MR imaging for the depiction of intraarterially injected superparamagnetic iron oxide (SPIO)-labeled mesenchymal stem cells (MSCs) in an experimental rat model of renal ischemia.

Materials and Methods

Left renal ischemia was induced in 12 male Sprague-Dawley rats by use of the catheter lodging method. In vivo MR signal intensity variations depicted on T2*-weighted sequences were evaluated in both the left and right kidneys prior to injection (n = 2), two hours (n = 4), 15 hours (n = 2), 30 hours (n = 2) and 72 hours (n = 2) after injection of SPIO-labeled MSCs in both kidneys. Signal intensity variations were correlated with the number of Prussian blue stain-positive cells as visualized in histological specimens.

Results

In an in vivo study, it was determined that there was a significant difference in signal intensity variation for both the left and right cortex (40.8 ± 4.12 and 26.4 ± 7.92, respectively) and for both the left and right medulla (23.2 ± 3.32 and 15.2 ± 3.31, respectively) until two hours after injection (p < 0.05). In addition, signal intensity variation in the left renal cortex was well correlated with the number of Prussian blue stain-positive cells per high power field (r = 0.98, p < 0.05).

Conclusion

Intraarterial injected SPIO-labeled MSCs in an experimental rat model of renal ischemia can be detected with the use of in vivo MR imaging immediately after injection.     

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。     

家兔超急性期放射性肝损伤MRI表现与病理对照研究

目的　探讨超急性期放射性肝损伤MRI表现及其病理基础 ,评估MRI平扫及菲立磁增强扫描检出放射性肝损伤的时间效能。材料与方法　 18只家兔随机分成 3组后均给予 4 0Gy单次X线半肝照射 ,第 1组于照射后第1d、第 2、3组分别于照射后第 2、3d行肝区MRITSE T2 WI及TSE T1WI两个序列的平扫及菲立磁增强扫描 ,同时取材做组织学检查。对MRI表现与病理组织学检查结果进行对照分析。结果　所有家兔T2 WI及T1WI平扫、T1WI菲立磁增强扫描肝组织信号强度均未发现变化。T2 WI菲立磁增强扫描对放射性肝损伤的检出时间为照射后第 3d(P <0 .0 1) ,表现为肝组织信号强度受照区与非受照区均较T2 WI平扫时降低 ,但受照区肝组织信号强度较非受照区高 ,两者间可见分界线。所有家兔受照区肝组织在光镜下未见明确组织水肿、纤维化及炎症细胞浸润等病理征象 ,但其单位视野面积内含有SPIO颗粒的Kupffer细胞数在照射后第 3d明显低于非受照区 (P <0 .0 1)。电镜下 ,照射后第 3d的受照区肝细胞及Kupffer细胞内见线粒体明显肿胀伴局部空泡样变。结论　T2 WI菲立磁增强扫描在照射后短时间内 (照射后第 3d)即可检出超急性期放射性肝损伤 ,并能提供直观、精细的影像学依据