Daryl Despres

Absolute quantitation of short TE brain 1H-MR spectra and spectroscopic imaging data.

A method for determining the concentrations of the materials that produce the well-resolved singlet signals in short TE brain 1H MR spectroscopic examinations is presented. Concentration determination is achieved by a water-referencing procedure. The ratios of the areas of the choline, total creatine, and N-acetyl signals to that of the water signal from the same volume of interest (VOI) are determined using acquisitions with and without water suppression. The tissue concentrations of the molecules producing the three signals can then be determined if the water concentration in the VOI can be found. This is done with a density-weighted MR study. The MR study provides the ratio of the mean MR signal amplitude from the VOI to that from an external standard containing a known water concentration. The methods flexibility is illustrated by using it with two different single-volume localization schemes and spectroscopic imaging. Preliminary evaluations of accuracy and reproducibility are made in phantom, animal, and limited human studies. The methods advantages and limitations are discussed.

Measuring random microscopic motion of water in tissues with MR imaging: a cat brain study.

Cat brain images sensitized to incoherent motion by additional gradient pulses were obtained on a 4.7 T magnetic resonance unit equipped with shielded gradient coils. The apparent diffusion coefficient of water in gray and white matter was accurately determined and imaged from the signal attenuation curve obtained as a function of gradient strength. Contrast in calculated diffusion images differed from typical T2-weighted contrast. Furthermore, in gray matter and in areas containing flowing CSF the attenuation curve was found to be biexponential. These results are interpreted in terms of a simple voxel model with microcirculation and diffusion contributions.

Short‐ vs. long‐circulating magnetoliposomes as bone marrow‐seeking MR contrast agents

We evaluated the relaxation enhancement and biodistribution of short‐ vs. long‐circulating magnetoliposomes as a new contrast agent for magnetic resonance (MR) imaging of bone marrow. Magnetoliposomes with (ML‐PEG) and without (ML) incorporation of polyethylene glycol (PEG, Mw 2000) were prepared, measuring 40 nm in diameter with 1–6 iron oxide crystals/vesicle. PEGylation selectively enhanced the T2 relaxivity of magnetoliposomes by 10% to 15%, with R1 and R2 values of 3 and 240 s‐1/mM at 1.5 T and 37°C. ML (n = 6) and ML‐PEG (n = 6) preparations were administered IV into young (6–8 weeks old) and adult (>1 year old) Sprague‐Dawley rats at 100 μmol Fe/kg. PEGylation increased blood half‐life (P < 0.05 for t > 30 minutes), following a biexponential clearance with a long half‐life of 53.2 ± 13.2 minutes. The clearance of ML was monoexponential, with a half‐life 7.4 ± 0.4 minutes. MR imaging revealed a pronounced uptake in bone marrow, including the iliac bone, femur, tibia, and upper and lower vertebrae. The bone marrow uptake of ML‐PEG was comparable to that of ML, with both reaching a plateau within 30 minutes following injection. Fast spin‐echo T2‐weighted imaging was found to provide optimal contrast enhancement and allowed a clear depiction of red to yellow marrow conversion due to normal aging. While the use of magnetoliposomes can provide the added benefit of therapeutic drug or gene delivery, further investigation is warranted to assess their usefulness in differentiating normal vs. abnormal marrow conditions.J. Magn. Reson. Imaging 1999;9:329–335.

Rgs5 Targeting Leads to Chronic Low Blood Pressure and a Lean Body Habitus

ABSTRACT RGS5 is a potent GTPase-activating protein for Giα and Gqα that is expressed strongly in pericytes and is present in vascular smooth muscle cells. To study the role of RGS5 in blood vessel physiology, we generated Rgs5-deficient mice. The Rgs5−/− mice developed normally, without obvious defects in cardiovascular development or function. Surprisingly, Rgs5−/− mice had persistently low blood pressure, lower in female mice than in male mice, without concomitant cardiac dysfunction, and a lean body habitus. The examination of the major blood vessels revealed that the aortas of Rgs5−/− mice were dilated compared to those of control mice, without altered wall thickness. Isolated aortic smooth muscle cells from the Rgs5−/− mice exhibited exaggerated levels of phosphorylation of vasodilator-stimulated phosphoprotein and extracellular signal-regulated kinase in response to stimulation with either sodium nitroprusside or sphingosine 1-phosphate. The results of this study, along with those of previous studies demonstrating that RGS5 stability is under the control of nitric oxide via the N-end rule pathway, suggest that RGS5 may balance vascular tone by attenuating vasodilatory signaling in vivo in opposition to RGS2, another RGS (regulator of G protein signaling) family member known to inhibit G protein-coupled receptor-mediated vasoconstrictor signaling. Blocking the function or the expression of RGS5 may provide an alternative approach to treat hypertension.

Thrombospondin-1 and CD47 regulate blood pressure and cardiac responses to vasoactive stress.

Nitric oxide (NO) locally regulates vascular resistance and blood pressure by modulating blood vessel tone. Thrombospondin-1 signaling via its receptor CD47 locally limits the ability of NO to relax vascular smooth muscle cells and increase regional blood flow in ischemic tissues. To determine whether thrombospondin-1 plays a broader role in central cardiovascular physiology, we examined vasoactive stress responses in mice lacking thrombospondin-1 or CD47. Mice lacking thrombospondin-1 exhibit activity-associated increases in heart rate, central diastolic and mean arterial blood pressure and a constant decrease in pulse pressure. CD47-deficient mice have normal central pulse pressure but elevated resting peripheral blood pressure. Both null mice show exaggerated decreases in peripheral blood pressure and increased cardiac output and ejection fraction in response to NO. Autonomic blockade also induces exaggerated hypotensive responses in awake thrombospondin-1 null and CD47 null mice. Both null mice exhibit a greater hypotensive response to isoflurane, and autonomic blockage under isoflurane anesthesia leads to premature death of thrombospondin-1 null mice. Conversely, the hypertensive response to epinephrine is attenuated in thrombospondin-1 null mice. Thus, the matricellular protein thrombospondin-1 and its receptor CD47 serve as acute physiological regulators of blood pressure and exert a vasopressor activity to maintain global hemodynamics under stress.

Bone marrow-derived cells do not repair endothelium in a mouse model of chronic endothelial cell dysfunction

Aims Bone marrow (BM)-derived endothelial progenitor cells (EPCs) in the circulation replace damaged vascular endothelium. We assessed the hypothesis that a BM transplant from healthy animals would restore normal arterial endothelium and prevent hypertension in young endothelial nitric oxide synthase-deficient (eNOS−/−) mice. Methods and results Radiation or busulfan-induced BM ablation in eNOS−/− mice on day 6, day 14, or day 28 was followed by a BM transplant consisting of enhanced green fluorescent protein positive (EGFP+) cells from C57BL/6J mice. Peripheral blood cell chimerism was always greater than 85% at 4 months after BM transplant. Molecular assays of heart, kidney, and liver revealed low-level chimerism in all treatment groups, consistent with residual circulating EGFP+ blood cells. When aorta, coronary, renal, hepatic, and splenic arteries in BM-transplanted eNOS−/− mice were examined by confocal microscopy, there were no EGFP- or eNOS-positive endothelial cells detected in these vessels in any of the treatment groups. Likewise, telemetry did not detect any reduction in blood pressure. Thus, no differences were observed in our measurements using several different treatment protocols. Conclusion We found no evidence for BM-derived EPC renewal of endothelium in this eNOS-deficient mouse model of a chronic vascular disease or in wild-type mice during postnatal growth. Hence, renewal of chronic dysfunctional endothelium and endothelial homeostasis may be dependent on resident vascular progenitor cells.

Rat model of metastatic breast cancer monitored by MRI at 3 tesla and bioluminescence imaging with histological correlation

BackgroundEstablishing a large rodent model of brain metastasis that can be monitored using clinically relevant magnetic resonance imaging (MRI) techniques is challenging. Non-invasive imaging of brain metastasis in mice usually requires high field strength MR units and long imaging acquisition times. Using the brain seeking MDA-MB-231BR transfected with luciferase gene, a metastatic breast cancer brain tumor model was investigated in the nude rat. Serial MRI and bioluminescence imaging (BLI) was performed and findings were correlated with histology. Results demonstrated the utility of multimodality imaging in identifying unexpected sights of metastasis and monitoring the progression of disease in the nude rat.MethodsBrain seeking breast cancer cells MDA-MB-231BR transfected with firefly luciferase (231BRL) were labeled with ferumoxides-protamine sulfate (FEPro) and 1-3 × 106 cells were intracardiac (IC) injected. MRI and BLI were performed up to 4 weeks to monitor the early breast cancer cell infiltration into the brain and formation of metastases. Rats were euthanized at different time points and the imaging findings were correlated with histological analysis to validate the presence of metastases in tissues.ResultsEarly metastasis of the FEPro labeled 231BRL were demonstrated onT2*-weighted MRI and BLI within 1 week post IC injection of cells. Micro-metastatic tumors were detected in the brain on T2-weighted MRI as early as 2 weeks post-injection in greater than 85% of rats. Unexpected skeletal metastases from the 231BRL cells were demonstrated and validated by multimodal imaging. Brain metastases were clearly visible on T2 weighted MRI by 3-4 weeks post infusion of 231BRL cells, however BLI did not demonstrate photon flux activity originating from the brain in all animals due to scattering of the photons from tumors.ConclusionA model of metastatic breast cancer in the nude rat was successfully developed and evaluated using multimodal imaging including MRI and BLI providing the ability to study the temporal and spatial distribution of metastases in the brain and skeleton.

Comparison of Fenestra VC Contrast-Enhanced Computed Tomography Imaging With Gadopentetate Dimeglumine and Ferucarbotran Magnetic Resonance Imaging for the In Vivo Evaluation of Murine Liver Damage After Ischemia and Reperfusion

Objectives:Comparison of intravenous Fenestra VC-enhanced computed tomography (CT) with gadopentetate dimeglumine and Ferucarbotran contrast-enhanced magnetic resonance imaging (MRI) for the in vivo imaging of hepatic ischemia/reperfusion injury (IRI) in a murine model. Material and Methods:After induction of hepatic IRI by left liver lobe (LLL) ischemia (30, 45, and 75 minutes) and reperfusion (4 hours and 24 hours), a total of 130 mice were imaged either by Fenestra VC-enhanced 3-D CT or by dynamic, T1-weighed gadopentetate dimeglumine or static, T2*-weighed Ferucarbotran 2-D MRI (4.7 T). Results:Detection of liver tissue damage as a consequence of IRI was not possible by CT or MRI without the use of contrast media. (1) Mice subjected to liver IRI (45 minutes of ischemia) and injected with Fenestra VC showed a distinct liver enhancement of the viable liver tissue or a nonenhancement of the necrotic tissue. The Fenestra VC CT-unenhanced liver volume increased as a function of time of ischemia and reperfusion. The unenhanced liver volume also correlated positively with serum liver enzyme activities and damage scores from liver histology. (2) The signal intensities (SI) between normal liver tissue and livers subjected to 30 minutes of ischemia were not different on dynamic gadopentetate dimeglumine-enhanced magnetic resonance images. More severe IRI as induced by 45 or 75 minutes of ischemia was characterized by (a) early hyperenhancement of regions in the LLL with rapid increase of SI higher than that observed in the undamaged liver within the first few minutes and (b) delayed hyperenhancement in the later course after gadopentetate dimeglumine injection, respectively. (3) Ferucarbotran MRI detected signs of IRI after only 30 minutes of liver ischemia and hence detected IRI earlier than Fenestra VC or gadopentetate dimeglumine. With longer duration of ischemia, Ferucarbotran SI increased in the LLL, but viable and necrotic tissues were not clearly distinguishable. Conclusions:MicroCT with Fenestra VC enhancement and MRI using either gadopentetate dimeglumine or Ferucarbotran enhancement of the liver revealed that all techniques allow in vivo determination of hepatic IRI as a function of the duration of ischemia and reperfusion of the liver. However, Fenestra VC-enhanced CT of the murine liver is superior to gadopentetate dimeglumine and Ferucarbotran for localization, quantification, and differentiation of viable from metabolically inactive/damaged liver tissue after hepatic ischemia/reperfusion but Fenestra VC is less sensitive than Ferucarbotran to detect the early onset of subtle consequences of hepatic IRI.

The New Zealand black mouse as a model for the development and progression of chronic lymphocytic leukemia

Similar to a subset of human patients who progress from monoclonal B lymphocytosis (MBL) to chronic lymphocytic leukemia (CLL), New Zealand Black (NZB) mice have an age‐associated progression to CLL. The murine disease is linked to a genetic abnormality in microRNA mir‐15a/16‐1 locus, resulting in decreased mature miR‐15a/16.

Cerebral blood flow in experimental ischemia assessed by 19F magnetic resonance spectroscopy in cats.

We evaluated a 19F magnetic resonance spectroscopic technique that detects Freon-23 washout as a means of measuring cerebral blood flow in halothane-anesthetized adult cats during and after transient cerebral ischemia produced by vascular occlusion. The experiments were performed to test the ability of this recently developed method to detect postischemic flow deficits. Results were consistent with postischemic hypoperfusion. The method also proved valuable for measuring small residual flow during vascular occlusion. Our experiments indicate that this method provides simple, rapid, and repeatable flow measurements that can augment magnetic resonance examinations of cerebral metabolic parameters in the study of ischemia.