Manganese-Enhanced MRI in Patients with Multiple Sclerosis.

BACKGROUND AND PURPOSE: Cellular uptake of the manganese ion, when administered as a contrast agent for MR imaging, can noninvasively highlight cellular activity and disease processes in both animals and humans. The purpose of this study was to explore the enhancement profile of manganese in patients with multiple sclerosis. MATERIALS AND METHODS: Mangafodipir is a manganese chelate that was clinically approved for MR imaging of liver lesions. We present a case series of 6 adults with multiple sclerosis who were scanned at baseline with gadolinium, then injected with mangafodipir, and followed at variable time points thereafter. RESULTS: Fourteen new lesions formed during or shortly before the study, of which 10 demonstrated manganese enhancement of varying intensity, timing, and spatial pattern. One gadolinium-enhancing extra-axial mass, presumably a meningioma, also demonstrated enhancement with manganese. Most interesting, manganese enhancement was detected in lesions that formed in the days after mangafodipir injection, and this enhancement persisted for several weeks, consistent with contrast coming from intracellular uptake of manganese. Some lesions demonstrated a diffuse pattern of manganese enhancement in an area larger than that of both gadolinium enhancement and T2-FLAIR signal abnormality. CONCLUSIONS: This work demonstrates the first use of a manganese-based contrast agent to enhance MS lesions on MR imaging. Multiple sclerosis lesions were enhanced with a temporal and spatial profile distinct from that of gadolinium. Further experiments are necessary to uncover the mechanism of manganese contrast enhancement as well as cell-specific uptake.

Manganese-Enhanced MRI of the Brain in Healthy Volunteers.

BACKGROUND AND PURPOSE: The manganese ion is used as an intracellular MR imaging contrast agent to study neuronal function in animal models, but it remains unclear whether manganese-enhanced MR imaging can be similarly useful in humans. Using mangafodipir (Teslascan, a chelated manganese-based contrast agent that is FDA-approved), we evaluated the dynamics of manganese enhancement of the brain and glandular structures in the rostral head and neck in healthy volunteers. MATERIALS AND METHODS: We administered mangafodipir intravenously at a rate of 1 mL/minute for a total dose of 5 µmol/kg body weight. Nine healthy adult volunteers (6 men/3 women; median age, 43 years) completed baseline history and physical examination, 3T MR imaging, and blood work. MR imaging also followed mangafodipir administration at various time points from immediate to 7 days, with delayed scans at 1-3 months. RESULTS: The choroid plexus and anterior pituitary gland enhanced within 10 minutes of infusion, with enhancement persisting up to 7 and 30 days, respectively. Exocrine (parotid, submandibular, sublingual, and lacrimal) glands also enhanced avidly as early as 1 hour postadministration, generally resolving by 1 month; 3 volunteers had residual exocrine gland enhancement, which resolved by 2 months in 1 and by 3 months in the other 2. Mangafodipir did not affect clinical parameters, laboratory values, or T1-weighted signal in the basal ganglia. CONCLUSIONS: Manganese ions released from mangafodipir successfully enable noninvasive visualization of intra- and extracranial structures that lie outside the blood-brain barrier without adverse clinical effects, setting the stage for future neuroradiologic investigation in disease.

Transverse relaxation of cerebrospinal fluid depends on glucose concentration.

PURPOSE: To evaluate the biophysical processes that generate specific T2 values and their relationship to specific cerebrospinal fluid (CSF) content. MATERIALS AND METHODS: CSF T2s were measured ex vivo (14.1T) from isolated CSF collected from human, rat and non-human primate. CSF T2s were also measured in vivo at different field strength in human (3 and 7T) and rodent (1, 4.7, 9,4 and 11.7T) using different pulse sequences. Then, relaxivities of CSF constituents were measured, in vitro, to determine the major molecule responsible for shortening CSF T2 (2s) compared to saline T2 (3s). The impact of this major molecule on CSF T2 was then validated in rodent, in vivo, by the simultaneous measurement of the major molecule concentration and CSF T2. RESULTS: Ex vivo CSF T2 was about 2.0s at 14.1T for all species. In vivo human CSF T2 approached ex vivo values at 3T (2.0s) but was significantly shorter at 7T (0.9s). In vivo rodent CSF T2 decreased with increasing magnetic field and T2 values similar to the in vitro ones were reached at 1T (1.6s). Glucose had the largest contribution of shortening CSF T2in vitro. This result was validated in rodent in vivo, showing that an acute change in CSF glucose by infusion of glucose into the blood, can be monitored via changes in CSF T2 values. CONCLUSION: This study opens the possibility of monitoring glucose regulation of CSF at the resolution of MRI by quantitating T2.

Shape-changing magnetic assemblies as high-sensitivity NMR-readable nanoprobes.

Fluorescent and plasmonic labels and sensors have revolutionized molecular biology, helping visualize cellular and biomolecular processes. Increasingly, such probes are now being designed to respond to wavelengths in the near-infrared region, where reduced tissue autofluorescence and photon attenuation enable subsurface in vivo sensing. But even in the near-infrared region, optical resolution and sensitivity decrease rapidly with increasing depth. Here we present a sensor design that obviates the need for optical addressability by operating in the nuclear magnetic resonance (NMR) radio-frequency spectrum, where signal attenuation and distortion by tissue and biological media are negligible, where background interferences vanish, and where sensors can be spatially located using standard magnetic resonance imaging (MRI) equipment. The radio-frequency-addressable sensor assemblies presented here comprise pairs of magnetic disks spaced by swellable hydrogel material; they reversibly reconfigure in rapid response to chosen stimuli, to give geometry-dependent, dynamic NMR spectral signatures. The sensors can be made from biocompatible materials, are themselves detectable down to low concentrations, and offer potential responsive NMR spectral shifts that are close to a million times greater than those of traditional magnetic resonance spectroscopies. Inherent adaptability should allow such shape-changing systems to measure numerous different environmental and physiological indicators, thus providing broadly generalizable, MRI-compatible, radio-frequency analogues to optically based probes for use in basic chemical, biological, medical and engineering research.

Lambda exonuclease digestion of CGG trinucleotide repeats.

Fragile X syndrome and other trinucleotide diseases are characterized by an elongation of a repeating DNA triplet. The ensemble-averaged lambda exonuclease digestion rate of different substrates, including one with an elongated FMR1 gene containing 120 CGG repeats, was measured using absorption and fluorescence spectroscopy. By use of magnetic tweezers sequence-dependent digestion rates and pausing was measured for individual lambda exonucleases. Within the triplet repeats a lower average and narrower distribution of rates and a higher frequency of pausing was observed.

Arterial spin labeling demonstrates that focal amygdalar glutamatergic agonist infusion leads to rapid diffuse cerebral activation.

OBJECTIVES: To investigate acute effects of intra-amygdalar excitatory amino acid administration on blood flow, relaxation time and apparent diffusion coefficient in rat brain. MATERIALS AND METHODS: Several days after MR-compatible cannula placement in right basolateral amygdala, anesthetized rats were imaged at 7 T. Relative cerebral blood flow (CBF) was measured before and 60 min after infusion of 10 nmol KA, cAMPA, ATPA, or normal saline using arterial spin labeling. Quantitative T(2) and diffusion-weighted images were acquired. rCBF, T(2) and ADC values were evaluated in bilateral basolateral amygdala, hippocampus, basal ganglia, frontal and parietal regions. RESULTS: KA led to the highest, and ATPA lowest bilateral rCBF increases. Time courses varied among drugs. T(2) for KA and AMPA was higher while ADC was lower for KA. CONCLUSIONS: Intra-amygdalar injection of GluR agonists evoked bilateral seizure activity and increased rCBF, greater for KA and AMPA than selective ATPA GluR5 activation.

The fabrication of uniform cylindrical nanoshells and their use as spectrally tunable MRI contrast agents.

A new form of tunable magnetic resonance imaging agent based on precisely dimensioned cylindrical magnetic nanoshells is introduced. Using top-down prepatterned substrates, the nanoshells are fabricated by exploiting what is usually regarded as a detrimental processing side-effect, namely the redeposition of material back-sputtered during ion-milling. The well-resolved nuclear magnetic resonance peaks of the resulting nanostructures attest to the nanoscale fabrication control and the general feasibility of such sputter redeposition for fabrication of a variety of self-supporting, highly monodisperse nanoscale structures.

Induction and apoptotic regression of lung adenocarcinomas by regulation of a K-Ras transgene in the presence and absence of tumor suppressor genes.

To investigate the role of an activated K-Ras gene in the initiation and maintenance of lung adenocarcinomas, we developed transgenic mice that express murine K-Ras4b(G12D) under the control of doxycycline in type II pneumocytes. Focal proliferative lesions of alveolar type II pneumocytes were observed as early as seven days after induction with doxycycline; after two months of induction, the lungs contained adenomas and adenocarcinomas, with focal invasion of the pleura at later stages. Removal of doxycycline caused a rapid fall in levels of mutant K-Ras RNA and concomitant apoptotic regression of both the early proliferative lesions and the tumors. Tumor burden was dramatically decreased by three days after withdrawal, and tumors were undetectable after one month. When similar experiments were performed with animals deficient in either the p53 gene or the Ink4A/Arf locus, tumors arose more quickly (within one month of exposure to doxycycline) and displayed more obvious histological features of malignancy; nevertheless, these tumors also regressed rapidly when the inducer was removed, implying that continued production of mutant K-Ras is necessary to maintain the viability of tumor cells in the absence as well as the presence of tumor suppressor genes. We also show that the appearance and regression of these pulmonary tumors can be readily monitored in anesthetized transgenic animals by magnetic resonance imaging.

Compensatory changes in Ca(2+) and myocardial O(2) consumption in beta-tropomyosin transgenic hearts.

Transgenic mice overexpressing beta-tropomyosin have increased myofilament Ca(2+) sensitivity that we hypothesized would result in altered relationships among pressure and heart rates, intracellular Ca(2+), and myocardial O(2) consumption. In perfused hearts from transgenic mice there was a marked negative force-frequency response between 6 and 10 Hz with a 30 +/- 3% reduction in peak-positive first derivative of pressure development over time (dP/dt) compared with 14 +/- 2% in wild-type mice (P < 0.001). At 8 Hz systolic pressures were normal, though peak systolic intracellular Ca(2+) was significantly reduced in transgenic mice versus wild type (726 +/- 61 vs. 936 +/- 67 nM, P < 0.05) indicating an alteration in the pressure-Ca(2+) relationship. Over a wide range of positive and negative inotropic interventions there were normal developed pressures, though marked elevations in myocardial O(2) consumption (15-54%). Because pressures are normal and intracellular Ca(2+) decreased and myocardial O(2) consumption increased, this suggests that these abnormalities are at least in part compensatory mechanisms to the altered myofilament function.

Manganese-enhanced MRI of mouse heart during changes in inotropy.

Recently the dual properties of manganese ion (Mn(2+)) as an MRI contrast agent and a calcium analogue to enter excitable cells has been used to mark specific cells in brain and as a potential intracellular cardiac contrast agent. Here the hypothesis that in vivo manganese-enhanced MRI (MEMRI) can detect changes in inotropy in the mouse heart has been tested. T(1)-weighted images were acquired every minute during an experimental time course of 75 min. Varying doses of Mn(2+) (3.3-14.0 nmoles/min/g BW) were infused during control and altered inotropy with dobutamine (positive inotropy due to increased calcium influx) and the calcium channel blocker diltiazem (negative inotropy). Infusion of MnCl(2) led to a significant increase in signal enhancement in mouse heart that saturated above 3.3 +/- 0.1 nmoles/min/g BW Mn(2+) infusion. At the highest Mn(2+) dose infused there was a 41-47% increase in signal intensity with no alteration in cardiac function as measured by MRI-determined ejection fractions. Dobutamine increased both the steady-state level of enhancement and the rate of MRI signal enhancement. Diltiazem decreased both the steady-state level of enhancement and the rate of MRI signal enhancement. These results are consistent with the model that Mn(2+)-induced enhancement of cardiac signal is indicative of the rate of calcium influx into the heart. Thus, the simultaneous measurement of global function and calcium influx using MEMRI may provide a useful method of evaluating in vivo responses to inotropic therapy.

High calcium and dobutamine positive inotropy in the perfused mouse heart: myofilament calcium responsiveness, energetic economy, and effects of protein kinase C inhibition.

BACKGROUND: In perfused hearts, high calcium-induced inotropy results in less developed pressure relative to myocardial oxygen consumption compared to the beta-adrenergic agonist dobutamine. Calcium handling is an important determinant of myocardial oxygen consumption. Therefore, we hypothesized that this phenomenon was due to reduced myofilament responsiveness to calcium, related to protein kinase C activation. RESULTS: Developed pressure was significantly higher with dobutamine compared to high perfusate calcium of 3.5 mM (73 +/- 10 vs 63 +/- 10 mmHg, p < 0.05), though peak systolic intracellular calcium was not significantly different, suggesting reduced myofilament responsiveness to intracellular calcium with high perfusate calcium. The ratio of developed pressure to myocardial oxygen consumption, an index of economy of contraction, was significantly increased with dobutamine compared to high perfusate calcium (1.35 +/- 0.15 vs 1.15 +/- 0.15 mmHg/micromoles/min/g dry wt, p < 0.05), suggesting energetic inefficiency with high perfusate calcium. The specific protein kinase C inhibitor, chelerythrine, significantly attenuated the expected increase in developed pressure when increasing perfusate calcium from 2.5 to 3.5 mM (3.5 mM: 64 +/- 8 vs 3.5 mM + chelerythrine: 55 +/- 5 mmHg, p < 0.05), though had no effects on dobutamine, or lower levels of perfusate calcium (1.5 to 2.5 mM). CONCLUSIONS: By measuring intracellular calcium, developed pressures and myocardial oxygen consumption in perfused mouse hearts, these results demonstrate that high perfusate calcium positive inotropy compared to dobutamine results in reduced myofilament responsiveness to intracellular calcium, which is associated with energetic inefficiency and evidence of protein kinase C activation.

Identification of mucosal injury in the murine nasal airways by magnetic resonance imaging: site-specific lesions induced by 3-methylindole.

A magnetic resonance imaging (MRI) technique was developed to identify mucosal damage to the nasal passages of mice resulting from exposure to respiratory toxicants. 3-Methylindole (3-MI) was chosen as a model nasal toxicant because systemic administration of this compound in mice results in a well-characterized necrotizing nasal lesion that is restricted to the olfactory mucosa. MRI technology allows imaging of the same mice before and at time points after injection. In addition, morphological alterations and increases in the area of sinus cavity airspace can be followed as a function of dose and time following exposure. For 3-MI, the cross-sectional area of the sinus airspaces increased by 1.7-fold in mice injected with 200 mg/kg and 2.6-fold in mice injected with 300 mg/kg at 3 days after injection. Alterations in the nasal turbinates lined by olfactory mucosa were identified 1, 3, and 6 days postadministration of 3-MI using MRI. Postmortem histological examination of the nasal tissue confirmed the intranasal location and distribution of the 3-MI-induced lesions observed by MRI. MRI can be a useful technique to identify toxicant-induced mucosal injury in the nasal passages at an in-plane resolution less than 60 microm.

Changes in the mitochondrial proteome from mouse hearts deficient in creatine kinase.

Creatine kinase (CK) is an abundant enzyme, important for maintenance of high-energy phosphate homeostasis in many tissues including heart. Double-knockout CK (DbKO-CK) mice missing both the muscle (MM) and sarcomeric mitochondrial (ScMit) isoforms of CK have recently been studied. Despite a large change in skeletal muscle function in DbKO-CK mice, there is little functional change in the heart. To investigate whether there are specific changes in cardiac mitochondrial proteins associated with the loss of MM- and ScMit-CK isoforms, we have used difference gel electrophoresis (DIGE) to compare mitochondrial proteins from wild-type and DbKO-CK mice. Mass spectrometry fingerprinting was used to identify 40 spots as known mitochondrial proteins. We have discovered that the loss of MM- and ScMit-CK isoforms did not cause large scale changes in heart mitochondrial proteins. The loss of ScMit-CK was readily detected in the DbKO-CK samples. We have also detected a large decrease in the precursor form of aconitase. Furthermore, two mitochondrial protein differences have been found in the parent mouse strains of the DbKO-CK mice.

Perfusion imaging using dynamic arterial spin labeling (DASL).

Recently, a technique based on arterial spin labeling, called dynamic arterial spin labeling (DASL (Magn Reson Med 1999;41:299-308)), has been introduced to measure simultaneously the transit time of the labeled blood from the labeling plane to the exchange site, the longitudinal relaxation time of the tissue, and the perfusion of the tissue. This technique relies on the measurement of the tissue magnetization response to a time varying labeling function. The analysis of the characteristics of the tissue magnetization response (transit time, filling time constant, and perfusion) allows for quantification of the tissue perfusion and for transit time map computations. In the present work, the DASL scheme is used in conjunction with echo planar imaging at 4.7 T to produce brain maps of perfusion and transit time in the anesthetized rat, under graded hypercapnia. The data obtained show the variation of perfusion and transit time as a function of arterial pCO2. Based on the data, CO2 reactivity maps are computed. Published 2001 Wiley-Liss, Inc.

Calibration of the calcium dissociation constant of Rhod(2)in the perfused mouse heart using manganese quenching.

Both theoretical and experimental results are presented for in vivo calibration of the dissociation constant K(Ca)(d)of the calcium-sensitive fluorescent dye Rhod(2)in the perfused mouse heart, using manganese quenching of fluorescence transients. An analytical model is derived, based on the biochemical equilibrium of manganese competition with calcium for Rhod(2)binding. Expressing the differential of the changes between systole and diastole in fluorescence transient (delta Delta F(sys-dia)). delta DeltaF(sys-dia)in a beating heart as a function of the perfusate manganese concentration [Mn(2+)](p)allows correlation of the measured differential transient changes delta Delta F(sys-dia)with the calcium dissociation constant K(Ca)(d)of Rhod(2)and the calcium concentration in the heart. Numerical modeling indicates that the K(Ca)(d)predominantly affects the asymptotic slope of the delta Delta F(sys-dia)versus [Mn(2+)](p)curve at certain manganese concentrations, which suggests that the K(Ca)(d)can be inversely calculated by partially fitting the delta Delta F(sys-dia)distribution as a function of the perfusate manganese concentration. The feasibility of this approach is confirmed by quenching of calcium transients by manganese infusion into isolated perfused beating mouse hearts. The resulting calculated dissociation constant K(Ca)(d)of Rhod(2)is 720nM. Using the same approach, we are able to also estimate intracellular calcium concentrations of 700nM at peak systole and 300nM in diastole. This is in good agreement with values obtained by calibration of fluorescence values with a calcium saturation tetanization procedure in the same perfused mouse heart model.

Ischemic dysfunction in transgenic mice expressing troponin I lacking protein kinase C phosphorylation sites.

To determine the in vivo functional significance of troponin I (TnI) protein kinase C (PKC) phosphorylation sites, we created a transgenic mouse expressing mutant TnI, in which PKC phosphorylation sites at serines-43 and -45 were replaced by alanine. When we used high-perfusate calcium as a PKC activator, developed pressures in transgenic (TG) perfused hearts were similar to wild-type (WT) hearts (P = not significant, NS), though there was a 35% and 32% decrease in peak-systolic intracellular calcium (P < 0.01) and diastolic calcium (P < 0.005), respectively. The calcium transient duration was prolonged in the TG mice also (12-27%, ANOVA, P < 0.01). During global ischemia, TG hearts developed ischemic contracture to a greater extent than WT hearts (41 +/- 18 vs. 69 +/- 10 mmHg, perfusate calcium 3.5 mM, P < 0.01). In conclusion, expression of mutant TnI lacking PKC phosphorylation sites results in a marked alteration in the calcium-pressure relationship, and thus susceptibility to ischemic contracture. The reduced intracellular calcium and prolonged calcium transients suggests that a potent feedback mechanism exists between the myofilament and the processes controlling calcium homeostasis.

Rhod-2 based measurements of intracellular calcium in the perfused mouse heart: cellular and subcellular localization and response to positive inotropy.

We have demonstrated a method of measuring intracellular calcium in the perfused mouse heart with the red fluorescent dye rhod-2. In Langendorff perfused isolated mouse hearts, rhod-2 is bolused through the perfusate, resulting in a 6.2+/-1.9-fold increase in fluorescence over background, and calcium transients with a transient amplitude to diastolic fluorescence ratio of 33+/-9%. Quantification of the relative amount of rhod-2 in the heart was done by taking the ratio of absorbance at 524 nm (rhod-2 sensitive) to 589 nm (rhod-2 insensitive). Maximal calcium saturated fluorescence was measured during tetanization of the heart with calcium chloride (20 mM) and cyclopiazonic acid (10 microM). Electron microscopy was used to determine the subcellular localization of rhod-2, by fixing rhod-2 in the heart with a carbodiimide compound, and then using a double antibody technique to stain rhod-2. These images demonstrated prominent cytosolic rhod-2 localization. Fluorescence and confocal fluorescence microscopy were consistent with the electron microscopy data. Endothelial cell uptake of rhod-2 was shown with fluorescence microscopy, though functional studies with bradykinin infusion (3 microM), which increases endothelial cell calcium, had no effects on mean fluorescence (N=4, p=NS), suggesting that endothelial uptake was small relative to total fluorescence. Calculated values of intracellular calcium were 686+/-237 nM at peak systole, and 360+/-101 nM in diastole, and with high perfusate calcium (3.5 mM) were 1199+/-215 and 544+/-53 nM, respectively. Thus, this appears a valid method of measuring cytosolic calcium in the perfused mouse heart, which will help determine the mechanisms of altered contractility in genetically engineered mice.

Calcium measurements in perfused mouse heart: quantitating fluorescence and absorbance of Rhod-2 by application of photon migration theory.

Both theoretical and experimental results are presented for the quantitative detection of calcium transients in the perfused mouse heart loaded with the calcium-sensitive fluorescent dye Rhod-2. Analytical models are proposed to calculate both the reflected absorbance and fluorescence spectra detected from the mouse heart. These models allow correlation of the measured spectral intensities with the relative quantity of Rhod-2 in the heart and measurement of the changes in quantum yield of Rhod-2 upon binding calcium in the heart in which multiple scattering effects are predominant. Theoretical modeling and experimental results demonstrate that both reflected absorbance and fluorescence emission are attenuated linearly with Rhod-2 washout. According to this relation, a ratiometric method using fluorescence and absorbance is validated as a measure of the quantum yield of calcium-dependent fluorescence, enabling determination of the dynamics of cytosolic calcium in the perfused mouse heart. The feasibility of this approach is confirmed by experiments quantifying calcium transients in the perfused mouse heart stimulated at 8 Hz. The calculated cytosolic calcium concentrations are 368 +/- 68 nM and 654 +/- 164 nM in diastole and systole, respectively. Spectral distortions induced by tissue scattering and absorption and errors induced by the geometry of the detection optics in the calcium quantification are shown to be eliminated by using the ratio method. Methods to effectively minimize motion-induced artifacts and to monitor the oxygenation status of the whole perfused heart are also discussed.

Inotropic and energetic effects of altering the force-calcium relationship: mechanisms, experimental results, and potential molecular targets.

Conventional positive inotropy with beta-adrenergic agonists or phosphodiesterase inhibitors increases the amplitude of the calcium transient and is associated with increases in myocardial oxygen consumption that may not be desirable when used in heart failure. Alternatively, agents that increase the sensitivity of the contractile apparatus without increasing the amplitude of the calcium transient have been shown to increase contractility without increasing energy consumption. Also, agents that result in negative inotropy while maintaining the amplitude of the calcium transient result in more energy-inefficient negative inotropy in comparison with agents that cause negative inotropy though a decrease in the amplitude of the calcium transient. These experiments suggest that calcium handling is responsible for a large proportion of the total energy expenditure associated with changes in inotropy. Problems that remain with the use of calcium-sensitizing agents include uncertainty regarding the site of action, adverse effects on systemic and coronary vasculature and diastolic function, and concomitant phosphodiesterase-inhibiting activity. One alternative is to use genetically engineered mouse models in which specific mutations selective to the myocyte can be produced. Potential molecular targets include the protein kinase A and C phosphorylation sites on troponin I, which, when phosphorylated, mediate a reduction in calcium sensitivity and a reduction in maximal actomyosin adenosinetriphosphatase activity, respectively. Mutations at these sites, by altering the relationship between force and calcium, may provide significant insights into the molecular mechanisms controlling the energetics of positive inotropy.