The effects of clinically used MRI contrast agents on the biological properties of human mesenchymal stem cells

This study was undertaken to compare the labeling efficiencies of three iron‐oxide based MRI contrast agents [Feridex, Resovist and monocrystalline iron oxide (MION)] and to evaluate their effects on the biological properties of human mesenchymal stem cells (hMSCs). The hMSCs were cultivated for 1 and 7 days after 24‐h labeling with iron oxide nanoparticles (12.5 µg Fe/mL) in the presence of poly‐L‐lysine (0.75 µg/mL). The hMSCs were labeled more efficiently with use of Feridex, Resovist as compared to MION. No significant differences were observed in terms of viability and proliferation of labeled hMSCs. The level of Oct‐4 mRNA increased in labeled hMSCs at day 1 and the cellular phenotype changed from CD45‐/CD44+/CD29+ to CD45low/CD44+/CD29+ at day 7, which closely resembles the phenotype of fresh bone marrow‐derived hMSCs. Our study has demonstrated that the Feridex or Resovist is the preferred labeling agent for hMSCs. There was a change in Oct‐4 and CD45 expression after labeling. Copyright © 2010 John Wiley & Sons, Ltd.     

<Emphasis Type="Italic">In vivo</Emphasis> MR Imaging of Tissue-engineered Human Mesenchymal Stem Cells Transplanted to Mouse: a Preliminary Study

Current progress integrating stem cell biology and tissue engineering techniques has been invaluable to clinical applications. Prior to the application of celluar transplantation technique to patients, we need to establish techniques that can monitor their tissue biodistribution non-invasively. In this study, we proposed an imaging modality using MRI to not only monitor implanted scaffold in vivo, but also to track transplanted cells and behavior around the implant. For this purpose, human bone marrow-derived mesenchymal stem cells (hMSCs) were labeled with superparamagnetic iron oxide (Feridex) and then labeled hMSCs were cultured in a gelatin sponge used as a scaffold to support cell growth and proliferation. Histological assessment and MTT assay showed that cell labeling with MR contrast agent did not harm cell viability. Also, Feridex-labeled hMSCs showed a significant decrease in T2 signal intensity, even within the gelatin sponge in vitro. After implanting the sponge/cell complex in vivo, we could visualize cellular behavior around the implant over time using a noninvasive MRI modality and this finding was correlated with histological study, which illustrates the potential of a new approach proposed here for in vivo monitoring of implanted cell-based tissue-engineered product.     

超顺磁性氧化铁纳米粒子标记人骨髓和脐带间充质干细胞

背景：优化人源细胞安全、有效的标记参数及细胞移植后的定位是评价其治疗效果至关重要的环节。 目的：比较核磁影像对比剂超顺磁性氧化铁纳米粒子体外标记人骨髓和脐带间充质干细胞的细胞活率、标记效率及核磁共振T2*WI成像的效果,优化标记细胞处理细节。 方法：培养第3代人骨髓和脐带间充质干细胞,以5-30 mg/L菲立磁(Feridex Ⅳ)结合硫酸鱼精蛋白标记细胞。 结果与结论：人骨髓和脐带间充质干细胞标记前后细胞的存活率接近(P > 0.05)。以5-30 mg/L菲立磁标记骨髓间充质干细胞的阳性标记率差异无显著性意义(P > 0.05);而5 mg/L菲立磁标记脐带间充质干细胞的阳性标记率与20和30 mg/L菲立磁标记的差异有显著性意义(P < 0.05);10 mg/L菲立磁标记脐带间充质干细胞的阳性标记率低于骨髓间充质干细胞(P < 0.05)。当≥20 mg/L菲立磁标记细胞时,2种来源的细胞悬液中均出现不易洗脱和过滤去除的氧化铁颗粒。标记后细胞在3.0T MR GRE T2*WI扫描均见随菲立磁的浓度升高,信号强度减弱。提示这2种组织来源的间充质干细胞,以10 mg/L的菲立磁-硫酸鱼精蛋白复合物标记是安全有效的,可用临床T2* WI的MR成像观察。     

Magnetic resonance imaging of ferumoxide-labeled mesenchymal stem cells seeded on collagen scaffolds-relevance to tissue engineering

Mesenchymal stem cells (MSCs) are a promising candidate cell for tissue engineering. Magnetic resonance imaging (MRI) has been proven effective in visualizing iron-labeled stem cells; however, the efficiency of this approach for visualization of cells seeded on scaffolds intended for use as tissue-engineered heart valves has not been assessed. MSCs were labeled by incubating for 48 h with ferumoxide and poly-L-lysine as transfecting agent. Any detrimental effect of iron labeling on cell viability, proliferation, and differentiation was examined using appropriate functional assays. Change in the nuclear magnetic relaxation properties of labeled cells was determined using in vitro relaxometry of cells seeded in 3-dimensional collagen gels. Images of labeled and non-labeled cells seeded onto 1% type I bovine collagen scaffolds were obtained using MRI. The presence of intracellular iron in labeled cells was demonstrated using Prussian blue staining, confocal microscopy, and electron microscopy. Cell viability, proliferation, and differentiation were comparable in labeled and non-labeled cells. The T2 relaxation time was 40% to 50% shorter in ferumoxide-labeled cells. Labeled cells seeded on scaffolds appeared as areas of reduced signal intensity in T2 weighted images. Ferumoxide labeling persisted and remained effective even on scans performed 4 weeks after the labeling procedure. Ferumoxide labeling of human MSCs seeded on collagen scaffolds is an effective, non-toxic technique for visualization of these cells using MRI. This technique appears promising for cell tracking in future tissue-engineering applications.     

Multiparametric MRI analysis for the evaluation of MR‐guided high intensity focused ultrasound tumor treatment

For the clinical application of high intensity focused ultrasound (HIFU) for thermal ablation of malignant tumors, accurate treatment evaluation is of key importance. In this study, we have employed a multiparametric MRI protocol, consisting of quantitative T₁, T₂, ADC, amide proton transfer (APT), T_1ρ and DCE‐MRI measurements, to evaluate MR‐guided HIFU treatment of subcutaneous tumors in rats. K‐means clustering using all different combinations of the endogenous contrast MRI parameters (feature vectors) was performed to segment the multiparametric data into tissue populations with similar MR parameter values. The optimal feature vector for identification of the extent of non‐viable tumor tissue after HIFU treatment was determined by quantitative comparison between clustering‐derived and histology‐derived non‐viable tumor fractions. The highest one‐to‐one correspondence between these clustering‐based and histology‐based non‐viable tumor fractions was observed for the feature vector {ADC, APT‐weighted signal} (R² to line of identity (R²_y=x) = 0.92) and the strongest agreement was seen 3 days after HIFU (R²_y=x = 0.97). To compare the multiparametric MRI analysis results with conventional HIFU monitoring and evaluation methods, the histology‐derived non‐viable tumor fractions were also quantitatively compared with non‐perfused tumor fractions (derived from the level of contrast enhancement in the DCE‐MRI measurements) and 240 CEM tumor fractions (i.e. thermal dose > 240 cumulative equivalent minutes at 43 °C). The correlation between histology‐derived non‐viable tumor fractions directly after HIFU and the 240 CEM fractions was high, but not significant. The non‐perfused fractions overestimated the extent of non‐viable tumor tissue directly after HIFU, whereas an underestimation was observed 3 days after HIFU. In conclusion, we have shown that a multiparametric MR analysis, especially based on the ADC and the APT‐weighted signal, can potentially be used to determine the extent of non‐viable tumor tissue 3 days after HIFU treatment. We expect that this method can be incorporated in the current clinical workflow of MR–HIFU ablation therapies. Copyright © 2015 John Wiley & Sons, Ltd.     

Measuring SPIO and Gd contrast agent magnetization using 3 T MRI

Traditional methods of measuring magnetization in magnetic fluid samples, such as vibrating sample magnetometry (VSM), are typically limited to maximum field strengths of about 1 T. This work demonstrates the ability of MRI to measure the magnetization associated with two commercial MRI contrast agents at 3 T by comparing analytical solutions to experimental imaging results for the field pattern associated with agents in cylindrical vials. The results of the VSM and fitted MRI data match closely. The method represents an improvement over VSM measurements since results are attainable at imaging field strengths. The agents investigated are Feridex, a superparamagnetic iron oxide suspension used primarily for liver imaging, and Magnevist, a paramagnetic, gadolinium‐based compound used for tumors, inflammation and vascular lesions. MR imaging of the agents took place in sealed cylindrical vials in the presence of a surrounding volume of deionized water where the effects of the contrast agents had a measurable effect on the water's magnetization in the vicinity of the compartment of contrast agent. A pair of phase images were used to reconstruct a B₀ fieldmap. The resultant B₀ maps in the water region, corrected for shimming and container edge effects, were used to predict the agent's magnetization at 3 T. The results were compared with the results from VSM measurements up to 1.2 T and close correlation was observed. The technique should be of interest to those seeking quantification of the magnetization associated with magnetic suspensions beyond the traditional scope of VSM. The magnetization needs to be sufficiently strong (M_s ? 50 Am²/kg Fe for Feridex and X_m ? 5 × 10^?5 m³/kg Gd for Magnevist) for a measurable dipole field in the surrounding water. For this reason, the technique is mostly suitable for undiluted agents. Copyright © 2009 John Wiley & Sons, Ltd.     

In vivo MRI for effective non‐invasive detection and follow‐up of an orthotopic mouse model of lung cancer

One of the main reasons for the dismal prognosis of lung cancer is related to the late diagnosis of this pathology. In this study, we evaluated the potential of optimized lung MRI techniques as a completely non‐invasive approach for non‐small‐cell lung cancer (NSCLC) MRI in vivo detection and follow‐up in a mouse model of lung adenocarcinoma expressing the luciferase gene. Bioluminescent lung tumour cells were orthotopically implanted in immuno‐deficient mice. Ultra‐short echo‐time (UTE) MRI free‐breathing acquisitions were compared with standard gradient‐echo lung MRI (FLASH) using both respiratory‐gated and free‐breathing protocols. The MRI findings were validated against bioluminescence imaging (BLI) and gold‐standard histopathology analysis. Adenocarcinoma‐like pathological tissue was successfully identified in all the mice with gated‐FLASH and non‐gated UTE MRI, and good tumour co‐localization was found between MRI, BLI and histological analyses. An excellent or good correlation was found between the measured bioluminescent signal and the total tumour volumes quantified with UTE MRI or gated‐FLASH MRI, respectively. No significant correlation was found when the tumours were segmented on non‐gated MR FLASH images. MRI was shown to be a powerful imaging tool able to detect, quantify and longitudinally monitor the development of sub‐millimetric NSCLCs. To our knowledge, this is the first study which proves the feasibility of a completely non‐invasive MRI quantitative detection of lung adenocarcinoma in freely breathing mice. The absence of ionizing radiation and the high‐resolution of MRI, along with the complete non‐invasiveness and good reproducibility of the proposed non‐gated protocol, make this imaging tool ideal for direct translational applications. Copyright © 2014 John Wiley & Sons, Ltd.     

超微超顺磁性纳米氧化铁标记犬口腔黏膜上皮细胞与磁共振成像实验

BACKGROUND: Epithelial cells are commonly used as the seed cell in tissue engineering; however, there is still a lack of an effective in vivo noninvasive trace technology. OBJECTIVE: To investigate the feasibility of labeling canine oral epithelial cells with ultrasmall superparamagnetie iron oxide (USPIO) and magnetic resonance imaging (MRI) in vitro.  METHODS: Oral epithelial cells from beagles were primary cultured, and then labeled by 0.75 mg/L poly-L-lysine combined with USPIO (0, 5, 10, 25, 50 and 100 mg/L), respectively. To determine the optimal dosage, the intracellular iron expression was identified by Prussian blue staining, and the cell viability in different groups was detected by cell counting kit-8. Finally, 2×105 labeled cells were suspended with 1 mL PBS buffer, and were screened using 3.0 T MR on T2*WI sequences in vitro.  RESULTS AND CONCLUSION: USPIO prepared with 0.75 mg/L poly-L-lysine could successfully label dog oral epithelial cells. Prussian blue staining showed intracellular blue spots, and the intracellular blue spots became more with the concentration increasing and saturated at the concentration of 25 mg/L. Cell counting kit-8 indicated that the cell viability did not change when the concentration < 25 mg/L. Among the T2*WI sequences, the MRI signal intensity decreased with the concentration increasing. In conclusion, canine oral epithelial cells can be effectively labeled with USPIO making no impact on cell viability when the concentration < 25 mg/L, and MRI can be used to track these labeled cells in vitro．     

Diffusion‐weighted MRI monitoring of pancreatic cancer response to radiofrequency heat‐enhanced intratumor chemotherapy

The aim of this study was to evaluate the feasibility of using diffusion‐weighted MRI to monitor the early response of pancreatic cancers to radiofrequency heat (RFH)‐enhanced chemotherapy. Human pancreatic carcinoma cells (PANC‐1) in different groups and 24 mice with pancreatic cancer xenografts in four groups were treated with phosphate‐buffered saline (PBS) as a control, RFH at 42 °C, gemcitabine and gemcitabine plus RFH at 42 °C. One day before and 1, 7 and 14 days after treatment, diffusion‐weighted MRI and T₂‐weighted imaging were applied to monitor the apparent diffusion coefficients (ADCs) of tumors and tumor growth. MRI findings were correlated with the results of tumor apoptosis analysis. In the in vitro experiments, the quantitative viability assay showed lower relative cell viabilities for treatment with gemcitabine plus RFH at 42 °C relative to treatment with RFH only and gemcitabine only (37 ± 5% versus 65 ± 4% and 58 ± 8%, respectively, p < 0.05). In the in vivo experiments, the combination therapy resulted in smaller relative tumor volumes than RFH only and chemotherapy only (0.82 ± 0.17 versus 2.23 ± 0.90 and 1.64 ± 0.44, respectively, p = 0.003). In vivo, 14‐T MRI demonstrated a remarkable decrease in ADCs at day 1 and increased ADCs at days 7 and 14 in the combination therapy group. The apoptosis index in the combination therapy group was significantly higher than those in the chemotherapy‐only, RFH‐only and PBS treatment groups (37 ± 6% versus 20 ± 5%, 8 ± 2% and 3 ± 1%, respectively, p < 0.05). This study confirms that it is feasible to use MRI to monitor RFH‐enhanced chemotherapy in pancreatic cancers, which may present new options for the efficient treatment of pancreatic malignancies using MRI/RFH‐integrated local chemotherapy. Copyright © 2013 John Wiley & Sons, Ltd.     

Feridex labeling of mesenchymal stem cells inhibits chondrogenesis but not adipogenesis or osteogenesis

Magnetic resonance (MR) tracking of superparamagnetic iron oxide (SPIO)-labeled cells is a relatively new technique to non-invasively determine the biodistribution and migration of transplanted stem cells. A number of studies have recently reported encouraging results in the use of bone marrow-derived mesenchymal stem cells (MSCs) for repair of a variety of tissues. For MR tracking of SPIO-labeled MSCs, it is important to determine the effect that the magnetic labeling procedure may have on the differentiation capacity of labeled MSCs. Human MSCs were labeled with poly-L-lysine (PLL)-coated Feridex, with Feridex being an FDA-approved SPIO formulation in an off-label application, and assayed for cellular differentiation using five different assays. As compared with unlabeled controls, labeled MSCs exhibited an unaltered viability, proliferated similarly, and underwent normal adipogenic and osteogenic differentiation. However, there was a marked inhibition of chondrogenesis. The blocking of chondrogenic activity was mediated by the Feridex, rather than by the transfection agent (PLL). This is the first report showing Feridex blocking of cellular differentiation down a specific pathway (while not affecting viability and proliferation), and caution should thus be exercised when using Feridex-labeled MSCs for chondrogenic MR tracking studies. On the other hand, no detrimental effects of Feridex-labeling are anticipated for MR-guided osteogenic or adipogenic transplantation studies.     

Determination of cell expansion and surface molecule expression on anti‐CD3/28 expanded CD4+ T cells

CD4⁺ T cell immunotherapy has potential for treatment in HIV‐infected patients. A large number of expanded CD4⁺ T cells and confirmation of functional‐related phenotypes are required for ensuring the successful outcomes of treatment. Freshly isolated CD4⁺ T cells from healthy donors were activated with anti‐CD3/28‐coated magnetic beads at different bead‐to‐cell ratios and cultured in the absence and presence of IL‐2 supplementation for 3 weeks. Fold expansion, cell viability, growth kinetic and lymphocyte subset identities were determined. Data demonstrated that a 1:1 bead‐to‐cell ratio rendered the highest expansion of 1044‐fold with 88% viability and 99.5% purity followed by the 2:1 and 0.5:1 ratios. No significant difference in proliferation and phenotypes was found between non–IL‐2 and IL‐2 supplementation groups. Several specific surface molecule expressions of the expanded cells including chemokine receptors, adhesion molecules, co‐stimulatory molecules, activation molecules, maturation markers, cytokine receptors and other molecules were altered when compared to the unexpanded cells. This optimized expansion protocol using the 1:1 bead‐to‐cell ratio of anti‐CD3/28‐coated magnetic beads and culture condition without IL‐2 supplementation provided the satisfactory yield with good reproducibility. Specific surface molecule expressions of the expanded cells presented potential roles in proliferation, differentiation, homeostasis, apoptosis and organ homing.     

T-zone localized monocyte-derived dendritic cells promote Th1 priming to Salmonella

Control of intracellular Salmonella infection requires Th1 priming and IFN‐γ production. Here, we show that efficient Th1 priming after Salmonella infection requires CD11c⁺CD11b^hiF4/80⁺ monocyte‐derived dendritic cells (moDCs). In non‐infected spleens, moDCs are absent from T‐cell zones (T zones) of secondary lymphoid tissues, but by 24 h post‐infection moDCs are readily discernible in these sites. The accumulation of moDCs is more dependent upon bacterial viability than bacterial virulence. Kinetic studies showed that moDCs were necessary to prime but not sustain Th1 responses, while ex vivo studies showed that antigen‐experienced moDCs were sufficient to induce T‐cell proliferation and IFN‐γ production via a TNF‐α‐dependent mechanism. Importantly, moDCs and cDCs when co‐cultured induced superior Th1 differentiation than either subset alone, and this activity was independent of TNF‐α. Thus, optimal Th1 development to Salmonella requires the rapid accumulation of moDCs within T zones and their collaboration with cDCs.     

Viability and MR detectability of iron labeled mesenchymal stem cells used for endoscopic injection into the porcine urethral sphincter

Direct stem cell therapies for functionally impaired tissue require a sufficient number of cells in the target region and a method for verifying the fate of the cells in the subsequent time course. In vivo MRI of iron labeled mesenchymal stem cells has been suggested to comply with these requirements. The study was conducted to evaluate proliferation, migration, differentiation and adhesion effects as well as the obtained iron load of an iron labeling strategy for mesenchymal stem cells. After injection into the porcine urethral sphincter, the labeled cells were monitored for up to six months using MRI. Mesenchymal stem cells were labeled with ferucarbotran (60/100/200 µg/mL) and ferumoxide (200 µg/mL) for the analysis of migration and viability. Phantom MR measurements were made to evaluate effects of iron labeling. For short and long term studies, the iron labeled cells were injected into the porcine urethral sphincter and monitored by MRI. High resolution anatomical images of the porcine urethral sphincter were applied for detection of the iron particles with a turbo‐spin‐echo sequence and a gradient‐echo sequence with multiple T_E values. The MR images were then compared with histological staining. The analysis of cell function after iron labeling showed no effects on proliferation or differentiation of the cells. Although the adherence increases with higher iron dose, the ability to migrate decreases as a presumed effect of iron labeling. The iron labeled mesenchymal stem cells were detectable in vivo in MRI and histological staining even six months after injection. Labeling with iron particles and subsequent evaluation with highly resolved three dimensional data acquisition allows sensitive tracking of cells injected into the porcine urethral sphincter for several months without substantial biological effects on mesenchymal stem cells. Copyright © 2015 John Wiley & Sons, Ltd.     

Quantitative assessment of gene methylation in neoplastic and non‐neoplastic gastric epithelia using methylation‐specific DNA microarray

A fiber‐type DNA microarray was used to calculate methylation rates (MR) of four tumor suppressor genes, lysyl oxidase (LOX), p16, RUNX3, and tazarotene‐induced gene 1 (TIG1). MR were calculated in 26 primary gastric cancers and corresponding non‐neoplastic gastric epithelia, and the results were compared to those of conventional methylation‐specific polymerase chain reaction (MSP). MR ranged from 0.1% to 69.1% (mean, 18.3%) for LOX, 0.5–74.1% (mean, 15.7%) for p16, 0.2–76.5% (mean, 22.7%) for RUNX3, and 0.6–41.2% (mean, 5.8%) for TIG1 in primary gastric cancers, and from 0.1% to 25.8% (mean, 8.7%) for LOX, 1.0– 23.2% (mean, 10.3%) for p16, 0.7–25.1% (mean, 5.5%) for RUNX3, and 1.8–27.6% (mean, 11.4%) for TIG1 in corresponding non‐neoplastic gastric epithelia. Although MR varied significantly across different samples for both neoplastic and non‐neoplastic gastric epithelia, high‐level methylation (MR >40%) was cancer specific and was observed in 19.2%, 19.2%, 30.8%, and 3.8% of primary gastric cancers for LOX, p16, RUNX3, and TIG1, respectively. All samples with high‐level methylation, as well as some samples with low MR (particularly <10%) were judged to be methylation positive on conventional MSP. Quantitative analysis of gene methylation using methylation‐specific DNA microarray is a promising method for cancer diagnosis.     

Magnetic resonance imaging of activated proliferating rhesus macaque T cells labeled with superparamagnetic monocrystalline iron oxide nanoparticles

Imaging of adoptively transferred cells in vivo by magnetic resonance imaging (MRI) could provide important information on disease-related patterns of lymphocyte homing in nonhuman primate models of AIDS. As a preliminary study to assess the feasibility of visualizing activated rhesus T cells by MRI, anti-CD3/CD28-expanded CD4+ T lymphocytes were labeled in vitro with monocrystalline iron oxide nanoparticles (MION). Intracellular incorporation of MION was determined by transmission electron microscopy (TEM) and inductively coupled plasma mass spectrography (ICP-MS). Pretreatment with colchicine did not affect MION labeling, suggesting that cellular uptake of MION occurred by adsorptive pinocytosis or receptor-mediated endocytosis. TEM analysis revealed that MION were intracellularly compartmentalized exclusively in the cytoplasm and did not cause any measurable physiologic effects on T-cell function, including viability, proliferation, synthesis of select cytokines (interleukin [IL]-2, IL-4, IL-6, IL-10, tumor necrosis factor-alpha, and interferon-gamma), activation antigens (CD25 and CD69), adhesion molecules (alpha4beta7 and CD49d), and susceptibility to in vitro infection with simian immunodeficiency virus mac239. A sensitivity of 0.05% (1 MION-labeled T cell in 2000 unlabeled cells) could be achieved using T2-weighted gradient echo imaging. Furthermore, under these experimental conditions, the MRI signal did not decrease in proliferating MION-labeled CD4+ T cells over a period of 120 hours. These results indicate that intracellular labeling with MION can be a useful technique for noninvasively monitoring trafficking patterns of adoptively transferred leukocyte subsets in real-time by MRI in nonhuman primate models of AIDS.     

Monitoring dynamic alterations in calcium homeostasis by T1‐mapping manganese‐enhanced MRI (MEMRI) in the early stage of small intestinal ischemia–reperfusion injury

Manganese‐enhanced MRI studies have proven to be useful in monitoring physiological activities associated with calcium ions (Ca²⁺) due to the paramagnetic property of the manganese ion (Mn²⁺), which makes it an excellent probe of Ca²⁺. In this study, we developed a method in which a Mn²⁺‐enhanced T₁‐map MRI could enable the monitoring of Ca²⁺ influx during the early stages of intestinal ischemia–reperfusion (I/R) injury. The Mn²⁺ infusion protocol was optimized by obtaining dose‐dependent and time‐course wash‐out curves using a Mn²⁺‐enhanced T₁‐map MRI of rabbit abdomens following an intravenous infusion of 50 mmol/l MnCl₂ (5–10 nmol/g body weight (BW)). In the rabbit model of intestinal I/R injury, T₁ values were derived from the T₁ maps in the intestinal wall region and revealed a relationship between the dose of the infused MnCl₂ and the intestinal wall relaxation time. Significant Mn²⁺ clearance was also observed over time in control animals after the infusion of Mn²⁺ at a dose of 10 nmol/g BW. This technique was also shown to be sensitive enough to monitor variations in calcium ion homeostasis in vivo after small intestinal I/R injury. The T₁ values of the intestinal I/R group were significantly lower (P < 0.05) than that of the control group at 5, 10, and 15 min after Mn²⁺ infusion. Our data suggest that MnCl₂ has the potential to be an MRI contrast agent that can be effectively used to monitor changes in intracellular Ca²⁺ homeostasis during the early stages of intestinal I/R injury. Copyright © 2015 John Wiley & Sons, Ltd.     

Cell layers and neuropil: contrast‐enhanced MRI of mouse brain in vivo

Contrast‐enhanced T₁‐ and T₂‐weighted MRI at 9.4 T and in‐plane resolutions of 25 and 30 µm has been demonstrated to differentiate between neural tissues in mouse brain in vivo, including granule cell layers, principal cell layers, general neuropil, specialized neuropil and white matter. In T₁‐weighted MRI of the olfactory bulb, hippocampus and cerebellum, contrast obtained by the intracranial administration of gadopentetate dimeglumine (Gd‐DTPA) reflects the extra‐ and intracellular spaces of gray matter in agreement with histological data. General neuropil areas are highlighted, whereas other tissues present with lower signal intensities. The induced contrast is similar to that in plain T₂‐weighted MRI, but offers a 16–30‐fold higher contrast‐to‐noise ratio. Systemic administration of manganese chloride increases the signal‐to‐noise ratio in T₁‐weighted MRI to a significantly greater extent in principal cell layers and specialized neuropil than in granule cell layers, whereas gadolinium‐enhanced MRI indicates no larger intracellular spaces in these tissues. Granule cell layers are enhanced no more than general neuropil by manganese, whereas gadolinium‐enhanced MRI indicates significantly larger intracellular spaces in the cell layers. These discrepancies suggest that the signal increase after manganese administration reflects cellular activity which is disproportionate to the intracellular space. As a result, principal cell layers and specialized neuropil become highlighted, whereas granule cell layers, general neuropil and white matter present with lower signal intensities. Copyright © 2013 John Wiley & Sons, Ltd.     

A guide for effective anatomical vascularization studies: useful ex vivo methods for both CT and MRI imaging before dissection

The objective of this study was to develop a simple and useful injection protocol for imaging cadaveric vascularization and dissection. Mixtures of contrast agent and cast product should provide adequate contrast for two types of ex vivo imaging (MRI and CT) and should harden to allow gross dissection of the injected structures. We tested the most popular contrast agents and cast products, and selected the optimal mixture composition based on their availability and ease of use. All mixtures were first tested in vitro to adjust dilution parameters of each contrast agent and to fine‐tune MR imaging acquisition sequences. Mixtures were then injected in 24 pig livers and one human pancreas for MR and computed tomography (CT) imaging before anatomical dissection. Colorized latex, gadobutrol and barite mixture met the above objective. Mixtures composed of copper sulfate (CuSO₄) gadoxetic acid (for MRI) and iodine (for CT) gave an inhomogeneous signal or extravasation of the contrast agent. Agar did not harden sufficiently for gross dissection but appears useful for CT and magnetic resonance imaging (MRI) studies without dissection. Silicone was very hard to inject but achieved the goals of the study. Resin is particularly difficult to use but could replace latex as an alternative for corrosion instead of dissection. This injection protocol allows CT and MRI images to be obtained of cadaveric vascularization and anatomical casts in the same anatomic specimen. Post‐imaging processing software allow easy 3D reconstruction of complex anatomical structures using this technique. Applications are numerous, e.g. surgical training, teaching methods, postmortem anatomic studies, pathologic studies, and forensic diagnoses.     

Calcium homeostasis and glucose uptake of murine myotubes exposed to insulin,caffeine and 4‐chloro‐m‐cresol

The modulation of glucose uptake by cytosolic calcium and the role of insulin on calcium homeostasis in insulin‐target cells are incompletely understood and results are contradictory. To address this issue, we used the C2C12 murine skeletal muscle cell line model and examined the influence of caffeine and 4‐chloro‐m‐cresol, two ryanodine receptor agonists known to mobilize intracellular calcium stores and increase cytosolic free calcium concentration. We followed ⁴⁵calcium efflux, a validated indicator of cytosolic calcium concentration, and 3‐O‐methyl‐[1–³H]‐d ‐glucose uptake in parallel. We also determined if insulin incubation affected ⁴⁵calcium influx rate. A 30‐min treatment by 1 μm insulin highly significantly increased ⁴⁵calcium efflux by 8.5% (P = 0.0014), despite a significant reduction of ⁴⁵Ca²⁺ influx already measurable after 20 and 30 min of insulin stimulation (?16.6%, P = 0.0119 and ?21.3%, P = 0.0047, respectively). Caffeine (1–20 mm ) and 4‐chloro‐m‐cresol (0.05–10 mm ) concentration‐dependently increased ⁴⁵calcium efflux, the latter being more potent and efficacious. These agents, in a concentration‐dependent manner, inhibited both basal and, more potently, insulin‐stimulated glucose uptake. This resulted in a negative correlation of glucose uptake and ⁴⁵calcium efflux (r > 0.95, P < 0.001). This effect was ～5 times greater for caffeine than for 4‐chloro‐m‐cresol, suggesting a calcium‐independent part of the glucose uptake inhibition by caffeine. In our in vitro model of cultured muscle cells, insulin appears to prevent calcium overload by both stimulating efflux and inhibiting cell storage. This effect, taken together with the observed inhibitory, inverse relationship between ⁴⁵calcium efflux and glucose uptake, contributes to describing the complex insulin–calcium interplay involved in target cells.