Steady-state responses to concurrent melodies: source distribution, top-down, and bottom-up attention.

Humans can direct attentional resources to a single sound occurring simultaneously among others to extract the most behaviourally relevant information present. To investigate this cognitive phenomenon in a precise manner, we used frequency-tagging to separate neural auditory steady-state responses (ASSRs) that can be traced back to each auditory stimulus, from the neural mix elicited by multiple simultaneous sounds. Using a mixture of 2 frequency-tagged melody streams, we instructed participants to selectively attend to one stream or the other while following the development of the pitch contour. Bottom-up attention towards either stream was also manipulated with salient changes in pitch. Distributed source analyses of magnetoencephalography measurements showed that the effect of ASSR enhancement from top-down driven attention was strongest at the left frontal cortex, while that of bottom-up driven attention was dominant at the right temporal cortex. Furthermore, the degree of ASSR suppression from simultaneous stimuli varied across cortical lobes and hemisphere. The ASSR source distribution changes from temporal-dominance during single-stream perception, to proportionally more activity in the frontal and centro-parietal cortical regions when listening to simultaneous streams. These findings are a step forward to studying cognition in more complex and naturalistic soundscapes using frequency-tagging.

Auditory steady-state responses during and after a stimulus: Cortical sources, and the influence of attention and musicality.

The auditory steady-state response (ASSR) is an oscillatory brain response generated by periodic auditory stimuli and originates mainly from the temporal auditory cortices. Recent data show that while the auditory cortices are indeed strongly activated by the stimulus when it is present (ON ASSR), the anatomical distribution of ASSR sources involves also parietal and frontal cortices, indicating that the ASSR is a more complex phenomenon than previously believed. Furthermore, while the ASSR typically continues to oscillate even after the stimulus has stopped (OFF ASSR), very little is known about the characteristics of the OFF ASSR and how it compares to the ON ASSR. Here, we assessed whether the OFF and ON ASSR powers are modulated by the stimulus properties (i.e. volume and pitch), selective attention, as well as individual musical sophistication. We also investigated the cortical source distribution of the OFF ASSR using a melody tracking task, in which attention was directed between uniquely amplitude-modulated melody streams that differed in pitch. The ON and OFF ASSRs were recorded with magnetoencephalography (MEG) on a group of participants varying from low to high degree of musical sophistication. Our results show that the OFF ASSR is different from the ON ASSR in nearly every aspect. While the ON ASSR was modulated by the stimulus properties and selective attention, the OFF ASSR was not influenced by any of these factors. Furthermore, while the ON ASSR was generated primarily from temporal sources, the OFF ASSR originated mainly from the frontal cortex. These findings challenge the notion that the OFF ASSR is merely a continuation of the ON ASSR. Rather, they suggest that the OFF ASSR is an internally-driven signal that develops from an initial sensory processing state (ON ASSR), with both types of ASSRs clearly differing in cortical representation and character. Furthermore, our results show that the ON ASSR power was enhanced by selective attention at cortical sources within each of the bilateral frontal, temporal, parietal and insular lobes. Finally, the ON ASSR proved sensitive to musicality, demonstrating positive correlations between musical sophistication and ASSR power, as well as with the degree of attentional ASSR modulation at the left and right parietal cortices. Taken together, these results show new aspects of the ASSR response, and demonstrate its usefulness as an effective tool for analysing how selective attention interacts with individual abilities in music perception.

Attentional modulation of the auditory steady-state response across the cortex.

Selective auditory attention allows us to focus on relevant sounds within noisy or complex auditory environments, and is essential for the processing of speech and music. The auditory steady-state response (ASSR) has been proposed as a neural measure for tracking selective auditory attention, even within continuous and complex soundscapes. However, the current literature is inconsistent on how the ASSR is influenced by selective attention, with findings based primarily on attention being directed to either ear rather than to sound content. In this experiment, a mixture of melody streams was presented to both ears identically (diotically) as we examined if selective auditory attention to sound content influences the ASSR. Using magnetoencephalography (MEG), we assessed the stream-specific ASSRs from three frequency-tagged melody streams when attention was directed between each melody stream, based on their respective pitch and timing. Our main results showed that selective attention enhances the ASSR power of an attended melody stream by 14% at a general sensor level. This ability to readily capture attentional changes in a stimuli-precise manner makes the ASSR a useful tool for studying selective auditory attention, especially in complex auditory environments. As a secondary aim, we explored the distribution of cortical ASSR sources and their respective attentional modulation using a distributed source model of the ASSR activity. Notably, we uncovered the existence of ASSR attentional modulation outside the temporal cortices. Across-subject averages of the attentional enhancement over the cortical surface suggest that frontal regions show up to ~80% enhancement, while temporal and parietal cortices were enhanced by 20-25%. Importantly, this work advocates a novel 'beyond the temporal cortex' perspective on ASSR modulation and also serves as a template for future studies to precisely pin-point which cortical sites are more susceptible to ASSR attentional modulation.

Nanoparticulate Contrast Agents for Multimodality Molecular Imaging.

Molecular imaging is rapidly developing as a powerful tool in research and medical diagnostic. By integrating complementary signal reporters into a single nanoparticulate contrast agent, multimodal molecular imaging can be performed as scalable images with high sensitivity, resolution and specificity. In this review, multifunctional nanoparticles (MFNPs) are classified into four types: conjugation, encapsulation, core/shell, and co-doping. Further, new constructs of MFNPs were reported recently which have used nanoparticulate contrast agent such as quantum dots (QDs), iron oxide nanoparticles (IONPs), Upconversion nanoparticles (UCNPs), carbon based nanoparticles, gold nanoparticles (Au-NPs), Metal-Organic Frameworks (MOFs), dendrimers and porphyrins based nanoparticles. Different surface modification strategies were also developed as well as ligands are attached to those NPs to render the biocompatibility and enable specific targeting. These new development in MFNPs are expected to introduce a paradigm shift in multi-modal molecular imaging and thereby opening up an era of personalized medicine and new diagnostic medical imaging tools.

Imaging of the striatal and extrastriatal dopamine transporter with (18)F-LBT-999: quantification, biodistribution, and radiation dosimetry in nonhuman primates.

UNLABELLED: The aim of this study was to evaluate the quantification, biodistribution, and radiation dosimetry of the novel dopamine transporter (DAT) radioligand (18)F-(2S,3S)-methyl 8-((E)-4-fluorobut-2-en-1-yl)-3-(p-tolyl)-8-azabicyclo[3.2.1]octane-2-carboxylate ((18)F-LBT-999) in nonhuman primates. METHODS: The brain study was conducted in 4 female rhesus monkeys. PET measurements were conducted for 243 min using the high-resolution research tomograph (HRRT) with the measurement of the metabolite-corrected arterial input function and protein binding. Quantification was performed with kinetic analysis using 2-tissue- and 1-tissue-compartment models, with Logan graphical analysis and with different reference tissue models. The outcome measures were total distribution volume (V(T)), nondisplaceable distribution volume (V(ND)), binding potential relative to the free concentration of radioligand in plasma (BP(F)), and binding potential relative to the concentration of nondisplaceable radioligand in tissue (BP(ND)) = V(T) - V(ND)/V(ND) using the cerebellum as a reference region. For the biodistribution and radiation dosimetry, 2 female cynomolgus monkeys were studied. Whole-body PET scans were obtained using a PET/CT system for approximately 250 min. Estimates of the absorbed radiation dose in humans were calculated using OLINDA/EXM software. RESULTS: (18)F-LBT-999 showed good brain uptake (300% standardized uptake value) and regional distribution according to known DAT density. The 2-tissue-compartment model was the preferred model for the quantification. Late peak equilibrium (120-140 min) and slow washout were observed in the striatum, with high variability of V(T), BP(F), and BP(ND). When the different models were compared with the 2-tissue-compartment model, the underestimation of V(T) or BP(ND) was larger in the caudate and putamen than in the midbrain and thalamus. The reference tissue models were suitable for the quantification. The whole-body distribution study showed that the main routes of excretion of (18)F-LBT-999 were the urinary and gastrointestinal systems, with the bladder being the critical organ. Accumulation of (18)F-LBT-999 was found in the bone and skull, with a relatively high dose estimated for the osteogenic cells. The range of calculated effective dose was 0.021-0.022 mSv/MBq. CONCLUSION: (18)F-LBT-999 seemed to be a suitable PET radioligand for the DAT quantification, particularly for extrastriatal regions. The skull uptake did not seem to be a limitation for brain imaging. The calculated dosimetry estimates based on data in nonhuman primates seemed comparable with those of other clinically used (18)F-labeled radioligands, for example, (18)F-FDG (0.024-0.027 mSv/MBq).

The norepinephrine transporter (NET) radioligand (S,S)-[18F]FMeNER-D2 shows significant decreases in NET density in the human brain in Alzheimer's disease: a post-mortem autoradiographic study.

Earlier post-mortem histological and autoradiographic studies have indicated a reduction of cell numbers in the locus coeruleus (LC) and a corresponding decrease in norepinephrine transporter (NET) in brains obtained from Alzheimer's disease (AD) patients as compared to age-matched healthy controls. In order to test the hypothesis that the regional decrease of NET is a disease specific biomarker in AD and as such, it can be used in PET imaging studies for diagnostic considerations, regional differences in the density of NET in various anatomical structures were measured in whole hemisphere human brain slices obtained from AD patients and age-matched control subjects in a series of autoradiographic experiments using the novel selective PET radioligand for NET (S,S)-[(18)F]FMeNER-D(2). (S,S)-[(18)F]FMeNER-D(2) appears to be a useful imaging biomarker for quantifying the density of NET in various brain structures, including the LC and the thalamus wherein the highest densities are found in physiological conditions. In AD significant decreases of NET densities can be demonstrated with the radioligand in both structures as compared to age-matched controls. The decreases in AD correlate with the progress of the disease as indicated by Braak grades. As the size of the LC is below the spatial resolution of the PET scanners, but the size of the thalamus can be detected with appropriate spatial accuracy in advanced scanners, the present findings confirm our earlier observations with PET that the in vivo imaging of NET with (S,S)-[(18)F]FMeNER-D(2) in the thalamus is viable. Nevertheless, further studies are warranted to assess the usefulness of such an imaging approach for the early detection of changes in thalamic NET densities as a disease-specific biomarker and the possible use of (S,S)-[(18)F]FMeNER-D(2) as a molecular imaging biomarker in AD.

Investigation of the metabolites of (S,S)-[(11)C]MeNER in humans, monkeys and rats.

INTRODUCTION: (S,S)-[(11)C]MeNER ((S,S)-2-(alpha-(2-[(11)C]methoxyphenoxy)benzyl)morpholine) is a positron emission tomography (PET) radioligand recently applied in clinical studies of norepinephrine transporters (NETs) in the human brain in vivo. In view of further assessment of the suitability of (S,S)-[(11)C]MeNER as a NET radioligand, its metabolism and the identity of the in vivo radiometabolites of (S,S)-[(11)C]MeNER are of great interest. MATERIALS AND METHODS: Thus, PET studies were used to measure brain dynamics of (S,S)-[(11)C]MeNER, and plasma reverse-phase radiochromatographic analysis was performed to monitor and quantify its rate of metabolism. Eighteen healthy human volunteers, five cynomolgus monkeys, and five rats were studied. RESULTS AND DISCUSSION: In human subjects, the plasma radioactivity representing (S,S)-[(11)C]MeNER decreased from 88 +/- 5% at 4 min after injection to 82 +/- 7% at 40 min, while a polar radiometabolite increased from 3 +/- 3% to 16 +/- 7% at the same time-points, respectively. A more lipophilic radiometabolite than (S,S)-[(11)C]MeNER decreased from 9 +/- 5% at 4 min to 1 +/- 2% at 40 min. In monkeys, plasma radioactivity representing (S,S)-[(11)C]MeNER decreased from 97 +/- 2% at 4 min to 74 +/- 7% at 45 min, with a polar fraction as the major radiometabolite. A more lipophilic radiometabolite than (S,S)-[(11)C]MeNER, constituted 3 +/- 2% of radioactivity at 4 min and was not detectable later on. In rats, 17 +/- 4% of plasma radioactivity was parent radioligand at 30 min with the remainder comprising mainly a polar radiometabolite. (S,S)-[(11)C]MeNER in rat brain and urine at 30 min after injection were 90% and 4%, respectively. On a brain regional level, parent radioligand ranged from 87.5 +/- 3.9% (57.2 +/- 14.2% SUV [standard uptake values, %injected radioactivity per mL multiplied with animal weight (in g)]; cerebellum) to 92.9 +/- 1.8% (36.1 +/- 4.7% SUV; striatum), with differential distribution of the radiometabolite in the cerebellum (6.7 +/- 0.3% SUV) and the striatum (2.5 +/- 0.3% SUV). Liquid chromatography-mass spectrometry analysis of rat urine identified a hydroxylation product of the methoxyphenoxy ring of (S,S)-MeNER as the main metabolite. In the brain, the corresponding main metabolite was the product from O-de-methylation of (S,S)-MeNER. PET measurements were performed in rats as well as in wild-type and P-gp-knock-out mice. In rats, the brain peak level of radioactivity was found to be very low (65%SUV). In mice, there was only a small difference in peak brain accumulation between P-gp knock-out and wild-type mice (145 vs. 125%SUV) with the following rank order of regional brain radioactivity: cerebellum x thalamus > cortical regions > striatum. CONCLUSION: It can be concluded that radiometabolites of (S,S)-[(11)C]MeNER are of minor importance in rat and monkey brain imaging. The presence of a transient lipophilic radiometabolite in peripheral human plasma may induce complications with brain imaging, but its kinetics appear favorable in relation to the slow kinetics of (S,S)-[(11)C]MeNER in humans.

Evaluation of [11C]PipISB and [18F]PipISB in monkey as candidate radioligands for imaging brain cannabinoid type-1 receptors in vivo.

N-(4-Fluorobenzyl)-4-[3-(piperidin-1-yl)indole-1-sulfonyl]benzamide] (PipISB, 3) is a selective and high-potency cannabinoid subtype-1 (CB1) receptor inverse agonist. We have previously reported radiosyntheses of [11C]3 and [18F]3. Here, we aimed to evaluate the uptake and CB(1) receptor-specific binding of each radioligand in monkey brain in vivo with positron emission tomography (PET). [11C]3 or [18F]3 was injected intravenously into rhesus or cynomolgus monkey, respectively, and examined with PET at baseline or after pretreatment with a receptor-saturating dose of CB1 receptor-selective ligand (3 for [11C]3 or 8 for [18F]3). In one PET experiment, the dose of 3 was administered at 100 min after [11C]3. Relative plasma concentrations of radioligand and radiometabolites were concurrently measured in baseline experiments with high-performance liquid chromatography. Brain radioactivity uptake was highest in striatum and cerebellum, and it reached 170-270% standardized uptake value (SUV) at 120 min after injection of [11C]3 and 180% SUV at 240 min after injection of [18F]3. Radioactivity was well retained in all CB1 receptor-rich regions. No reference region could be identified for nonspecifically bound radioligand. Under CB1 receptor pretreatment and displacement conditions, initial brain uptakes of radioactivity were similar to those at baseline. Regional brain radioactivity concentrations then became homogeneous and diminished to between 70 and 80% SUV at 120 min after injection of [11C]3 and to 25% SUV at 240 min after injection of [18F]3. [18F]3 was not defluorinated but was metabolized to less lipophilic radiometabolites, as was [11C]3. Hence, [11C]3 and [18F]3 showed high CB1 receptor-specific binding in monkey brain in vivo and merit further investigation as prospective PET radioligands in humans.

A comparative autoradiography study in post mortem whole hemisphere human brain slices taken from Alzheimer patients and age-matched controls using two radiolabelled DAA1106 analogues with high affinity to the peripheral benzodiazepine receptor (PBR) system.

The binding of two radiolabelled analogues (N-(5-[125I]Iodo-2-phenoxyphenyl)-N-(2,5-dimethoxybenzyl)acetamide ([125I]desfluoro-DAA1106) and N-(5-[125I]Fluoro-2-phenoxyphenyl)-N-(2-[125I]Iodo-5-methoxybenzyl)acetamide ([125I]desmethoxy-DAA1106) of the peripheral benzodiazepine receptor (PBR) (or TSPO, 18kDa translocator protein) ligand DAA1106 was examined by in vitro autoradiography on human post mortem whole hemisphere brain slices obtained from Alzheimer's disease (AD) patients and age-matched controls. Both [(125)I]desfluoro-IDAA1106 and [(125)I]desmethoxy-IDAA1106 were effectively binding to various brain structures. The binding could be blocked by the unlabelled ligand as well as by other PBR specific ligands. With both radiolabelled compounds, the binding showed regional inhomogeneity and the specific binding values proved to be the highest in the hippocampus, temporal and parietal cortex, the basal ganglia and thalamus in the AD brains. Compared with age-matched control brains, specific binding in several brain structures (temporal and parietal lobes, thalamus and white matter) in Alzheimer brains was significantly higher, indicating that the radioligands can effectively label-activated microglia and the up-regulated PBR/TSPO system in AD. Complementary immunohistochemical studies demonstrated reactive microglia activation in the AD brain tissue and indicated that increased ligand binding coincides with increased regional microglia activation due to neuroinflammation. These investigations yield further support to the PBR/TSPO binding capacity of DAA1106 in human brain tissue, demonstrate the effective usefulness of its radio-iodinated analogues as imaging biomarkers in post mortem human studies, and indicate that its radiolabelled analogues, labelled with short half-time bioisotopes, can serve as prospective in vivo imaging biomarkers of activated microglia and the up-regulated PBR/TSPO system in the human brain.

Synthesis of 11C-labelled (R)-OHDMI and CFMME and their evaluation as candidate radioligands for imaging central norepinephrine transporters with PET.

(R)-1-(10,11-Dihydro-dibenzo[b,f]azepin-5-yl)-3-methylamino-propan-2-ol ((R)-OHDMI) and (S,S)-1-cyclopentyl-2-(5-fluoro-2-methoxy-phenyl)-1-morpholin-2-yl-ethanol (CFMME) were synthesized and found to be potent inhibitors of norepinephrine reuptake. Each was labelled efficiently in its methyl group with carbon-11 (t(1/2)=20.4 min) as a prospective radioligand for imaging brain norepinephrine transporters (NET) with positron emission tomography (PET). The uptake and distribution of radioactivity in brain following intravenous injection of each radioligand into cynomolgus monkey was examined in vivo with PET. After injection of (R)-[(11)C]OHDMI, the maximal whole brain uptake of radioactivity was very low (1.1% of injected dose; I.D.). For occipital cortex, thalamus, lower brainstem, mesencephalon and cerebellum, radioactivity ratios to striatum at 93 min after radioligand injection were 1.35, 1.35, 1.2, 1.2 and 1.0, respectively. After injection of [(11)C]CFMME, radioactivity readily entered brain (3.5% I.D.). Ratios of radioactivity to cerebellum at 93 min for thalamus, occipital cortex, region of locus coeruleus, mesencephalon and striatum were 1.35, 1.3, 1.3, 1.2 and 1.2, respectively. Radioactive metabolites in plasma were measured by radio-HPLC. (R)-[(11)C]OHDMI represented 75% of plasma radioactivity at 4 min after injection and 6% at 30 min. After injection of [(11)C]CFMME, 84% of the radioactivity in plasma represented parent at 4 min and 20% at 30 min. Since the two new hydroxylated radioligands provide only modest regional differentiation in brain uptake and form potentially troublesome lipophilic radioactive metabolites, they are concluded to be inferior to existing radioligands, such as (S,S)-[(11)C]MeNER, (S,S)-[(18)F]FMeNER-D(2) and (S,S)-[(18)F]FRB-D(4), for the study of brain NETs with PET in vivo.

Cerebral uptake of [ethyl-11C]vinpocetine and 1-[11C]ethanol in cynomolgous monkeys: a comparative preclinical PET study.

PET provides the potential to quantify the distribution of radiolabelled drugs in the human body. In cases when radiolabelled compounds undergo metabolic transformation after administration in vivo, it is necessary to examine the kinetics and distribution of both the labeled mother compound and labeled metabolites. The objective of this study was to assess the extent by which 11C-labeled ethanol, the product arising from the de-esterification of the neuroprotective drug vinpocetine (ethyl-apovincaminate), might contribute to the regional cerebral radioactivity measured by PET after the administration of [ethyl-11C]vinpocetine. In three cynomolgous monkeys PET measurements were made after intravenous bolus injection of both [11C]vinpocetine and 1-[11C]ethanol. There was a marked difference between the regional time-activity curves of [11C]ethanol and [11C]vinpocetine. The distribution pattern obtained with [11C]ethanol was similar to that observed with blood flow tracers such as [15O]water and [15O]butanol. The study shows that although [11C]ethanol may moderately contribute to the brain radioactivity distribution pattern of [11C]vinpocetine, the rapid degradation of [11C]ethanol makes it unlikely that the contribution of this metabolite is of importance. The distinct distribution patterns and kinetics of [11C]vinpocetine and [11C]ethanol also support the view, obtained from our previous observations, that vinpocetine may bind to specific sites in the monkey and human brain, especially in the thalamus.

[Cerebral uptake and regional distribution of [11C]-vinpocetin after intravenous administration to healthy men: a PET study]. / [11C]-vinpocetin agyi felvétele és regionális eloszlása egyszeri intravénás adás után emberben: PET vizsgálatok.

INTRODUCTION: Vinpocetine is a compound widely used in the prevention and treatment of cerebrovascular diseases. The exact mechanism of action of the drug is still not known. The objective of the present investigation was to determine the global uptake and regional distribution of radiolabelled vinpocetine in the human brain. Three healthy persons were examined with positron emission tomography (PET) and [11C]-vinpocetine. RESULTS: The uptake of [11C]-vinpocetine in brain was rapid and on average as a maximum 3.7% of the total radioactivity injected was in the brain 2 minutes after radioligand administration. The uptake was heterogeneously distributed among brain regions. When compared with the cerebellum, an a priori reference region, the highest regional uptake was in the thalamus, the upper brain stem, the striatum and the cortex. CONCLUSIONS: The brain regions showing increased uptake in the human brain correspond to those in which vinpocetine has previously been shown to induce elevated metabolism and blood flow by PET clinical studies in patients with chronic ischaemic post-stroke condition.