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Department/Unit:Neuroscience Institute

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13562


A low-cost, 61-channel muECoG array for use in rodents

Woods, V.; Wang, C.; Bossi, S.; Insanally, M.; Trumpis, M.; Froemke, R.; Viventi, J.
Micro-Electrocorticography (muECoG) offers a minimally invasive, high resolution interface
INSPEC:15287114
ISSN: 1948-3546
CID: 1749632

Rapid free-breathing dynamic contrast-enhanced MRI using motion-resolved compressed

Li Feng; Sodickson, D.K.; Otazo, R.
Compressed sensing is a powerful rapid imaging approach for Magnetic Resonance Imaging
INSPEC:15309544
ISSN: 1945-7928
CID: 1749622

Massachusetts Alzheimer's Disease Research Center: Progress and challenges

Hyman, Bradley T; Growdon, John H; Albers, Mark W; Buckner, Randy L; Chhatwal, Jasmeer; Gomez-Isla, M Teresa; Haass, Christian; Hudry, Eloise; Jack, Clifford R Jr; Johnson, Keith A; Khachaturian, Zaven S; Kim, Doo Yeon; Martin, Joseph B; Nitsch, Roger M; Rosen, Bruce R; Selkoe, Dennis J; Sperling, Reisa A; St George-Hyslop, Peter; Tanzi, Rudolph E; Yap, Liang; Young, Anne B; Phelps, Creighton H; McCaffrey, Patricia M
PMCID:4654956
PMID: 26297855
ISSN: 1552-5279
CID: 1745392

Optimization of white matter fiber tractography with diffusional kurtosis imaging

Glenn, G Russell; Helpern, Joseph A; Tabesh, Ali; Jensen, Jens H
Diffusional kurtosis imaging (DKI) is a clinically feasible diffusion MRI technique for white matter (WM) fiber tractography (FT) with the ability to directly resolve intra-voxel crossing fibers by means of the kurtosis diffusion orientation distribution function (dODF). Here we expand on previous work by exploring properties of the kurtosis dODF and their subsequent effects on WM FT for in vivo human data. For comparison, the results are contrasted with fiber bundle orientation estimates provided by the diffusion tensor, which is the primary quantity obtained from diffusion tensor imaging. We also outline an efficient method for performing DKI-based WM FT that can substantially decrease the computational requirements. The recommended method for implementing the kurtosis ODF is demonstrated to optimize the reproducibility and sensitivity of DKI for detecting crossing fibers while reducing the occurrence of non-physically-meaningful, negative values in the kurtosis dODF approximation. In addition, DKI-based WM FT is illustrated for different protocols differing in image acquisition times from 48 to 5.3 min
PMID: 26275886
ISSN: 1099-1492
CID: 1745082

Automatic Adaptation to Fast Input Changes in a Time-Invariant Neural Circuit

Bharioke, Arjun; Chklovskii, Dmitri B
Neurons must faithfully encode signals that can vary over many orders of magnitude despite having only limited dynamic ranges. For a correlated signal, this dynamic range constraint can be relieved by subtracting away components of the signal that can be predicted from the past, a strategy known as predictive coding, that relies on learning the input statistics. However, the statistics of input natural signals can also vary over very short time scales e.g., following saccades across a visual scene. To maintain a reduced transmission cost to signals with rapidly varying statistics, neuronal circuits implementing predictive coding must also rapidly adapt their properties. Experimentally, in different sensory modalities, sensory neurons have shown such adaptations within 100 ms of an input change. Here, we show first that linear neurons connected in a feedback inhibitory circuit can implement predictive coding. We then show that adding a rectification nonlinearity to such a feedback inhibitory circuit allows it to automatically adapt and approximate the performance of an optimal linear predictive coding network, over a wide range of inputs, while keeping its underlying temporal and synaptic properties unchanged. We demonstrate that the resulting changes to the linearized temporal filters of this nonlinear network match the fast adaptations observed experimentally in different sensory modalities, in different vertebrate species. Therefore, the nonlinear feedback inhibitory network can provide automatic adaptation to fast varying signals, maintaining the dynamic range necessary for accurate neuronal transmission of natural inputs.
PMCID:4527762
PMID: 26247884
ISSN: 1553-7358
CID: 1744482

Local generation of multineuronal spike sequences in the hippocampal CA1 region

Stark, Eran; Roux, Lisa; Eichler, Ronny; Buzsaki, Gyorgy
Sequential activity of multineuronal spiking can be observed during theta and high-frequency ripple oscillations in the hippocampal CA1 region and is linked to experience, but the mechanisms underlying such sequences are unknown. We compared multineuronal spiking during theta oscillations, spontaneous ripples, and focal optically induced high-frequency oscillations ("synthetic" ripples) in freely moving mice. Firing rates and rate modulations of individual neurons, and multineuronal sequences of pyramidal cell and interneuron spiking, were correlated during theta oscillations, spontaneous ripples, and synthetic ripples. Interneuron spiking was crucial for sequence consistency. These results suggest that participation of single neurons and their sequential order in population events are not strictly determined by extrinsic inputs but also influenced by local-circuit properties, including synapses between local neurons and single-neuron biophysics.
PMCID:4547251
PMID: 26240336
ISSN: 1091-6490
CID: 1744312

Altered Neuronal and Circuit Excitability in Fragile X Syndrome

Contractor, Anis; Klyachko, Vitaly A; Portera-Cailliau, Carlos
Fragile X syndrome (FXS) results from a genetic mutation in a single gene yet produces a phenotypically complex disorder with a range of neurological and psychiatric problems. Efforts to decipher how perturbations in signaling pathways lead to the myriad alterations in synaptic and cellular functions have provided insights into the molecular underpinnings of this disorder. From this large body of data, the theme of circuit hyperexcitability has emerged as a potential explanation for many of the neurological and psychiatric symptoms in FXS. The mechanisms for hyperexcitability range from alterations in the expression or activity of ion channels to changes in neurotransmitters and receptors. Contributions of these processes are often brain region and cell type specific, resulting in complex effects on circuit function that manifest as altered excitability. Here, we review the current state of knowledge of the molecular, synaptic, and circuit-level mechanisms underlying hyperexcitability and their contributions to the FXS phenotypes.
PMCID:4545495
PMID: 26291156
ISSN: 1097-4199
CID: 1745292

GABA Receptor-mediated feed-forward circuit dysfunction in the mouse model of fragile X syndrome

Wahlstrom-Helgren, Sarah; Klyachko, Vitaly A
Circuit hyperexcitability has been implicated in neuropathology of Fragile X syndrome, the most common inheritable cause of intellectual disability. Yet, how canonical unitary circuits are affected in this disorder remains poorly understood. Here, we examined this question in the context of the canonical feed-forward inhibitory circuit formed by the Temporoammonic (TA) branch of the perforant path, the major cortical input to the hippocampus. TA feed-forward circuits exhibited a marked increase in excitation/excitation ratio and major functional defects in spike modulation tasks in Fmr1 KO mice, a Fragile X mouse model. Changes in feed-forward circuits were caused specifically by inhibitory, but not excitatory, synapse defects. TA-associated inhibitory synapses exhibited increase in paired-pulse ratio and in the coefficient of variation of IPSPs, consistent with decreased GABA release probability. TA-associated inhibitory synaptic transmission in Fmr1 KO mice was also more sensitive to inhibition of GABAB receptors, suggesting an increase in presynaptic GABAB receptor (GABAB R) signaling. Indeed, the differences in inhibitory synaptic transmission between Fmr1 KO and WT mice were eliminated by a GABAB R antagonist. Inhibition of GABAB Rs or selective activation of presynaptic GABAB Rs also abolished the differences in the TA feed-forward circuit properties between Fmr1 KO and WT mice. These GABAB R-mediated defects were circuit-specific and were not observed in the Schaffer collateral pathway-associated inhibitory synapses. Our results suggest that the inhibitory synapse dysfunction in the cortical-hippocampal pathway of Fmr1 KO mice causes hyperexcitability and feed-forward circuit defects, which are mediated in part by a presynaptic GABAB R-dependent reduction in GABA release
PMCID:4650406
PMID: 26282581
ISSN: 1469-7793
CID: 1745212

T-type calcium channels contribute to calcium disturbances in brain during hyponatremia

Odackal, John; Sherpa, Ang D; Patel, Nisha; Colbourn, Robert; Hrabetova, Sabina
Disturbance of calcium homeostasis is implicated in the normal process of aging and brain pathology prevalent in the elderly such as Alzheimer's, Parkinson's, and amyotrophic lateral sclerosis. Previous studies demonstrated that applying a hyponatremic iso-osmotic (low-NaCl) artificial cerebrospinal fluid (ACSF) to rodent hippocampus causes extracellular calcium to rapidly decrease. Restoring normonatremia after low-NaCl treatment causes a rapid increase in extracellular calcium that overshoots baseline. This study examined the amplitude, timing, and mechanism of these surprising calcium changes. We also tested whether hyponatremia increased calcium entry into brain cells or calcium binding to chondroitin sulfate (CS), a negatively charged constituent of the extracellular matrix (ECM) that may be occupied by sodium during normonatremia. We report three major findings. First we show that CS does not contribute to extracellular calcium changes during low-NaCl treatments. Second, we show that the time to minimum extracellular calcium during low-NaCl treatment is significantly shorter than the time to maximum extracellular calcium in recovery from low-NaCl treatment. Third, we show that the decrease in extracellular calcium observed during hyponatremia is attenuated by ML 218, a highly selective T-type calcium channel blocker. Together these data suggest that calcium rapidly enters cells at the onset of low-NaCl treatment and is extruded from cells when normonatremia is restored. Calcium binding to CS does not significantly contribute to calcium changes in brain during hyponatremia. Differences in timing suggest that extracellular calcium changes during and in recovery from hyponatremia occur by distinct mechanisms or by a multistep process. Finally, partial block of extracellular calcium influx by ML 218 suggests that T-type channels are involved in calcium entering cells during hyponatremia. Given the high prevalence of hyponatremia among elderly patients and the growing understanding of calcium's role in multiple neurologic pathologies, this study promotes a novel approach for studying and potentially preventing the effects of hyponatremia on calcium dysregulation in brain tissue.
PMCID:4644432
PMID: 26257025
ISSN: 1090-2430
CID: 1744662

Intrinsic brain indices of verbal working memory capacity in children and adolescents

Yang, Zhen; Jutagir, Devika R; Koyama, Maki S; Craddock, R Cameron; Yan, Chao-Gan; Shehzad, Zarrar; Castellanos, F Xavier; Di Martino, Adriana; Milham, Michael P
Working memory (WM) is central to the acquisition of knowledge and skills throughout childhood and adolescence. While numerous behavioral and task-based functional magnetic resonance imaging (fMRI) studies have examined WM development, few have used resting-state fMRI (R-fMRI). Here, we present a systematic R-fMRI examination of age-related differences in the neural indices of verbal WM performance in a cross-sectional pediatric sample (ages: 7-17; n=68), using data-driven approaches. Verbal WM capacity was measured with the digit span task, a commonly used educational and clinical assessment. We found distinct neural indices of digit span forward (DSF) and backward (DSB) performance, reflecting their unique neuropsychological demands. Regardless of age, DSB performance was related to intrinsic properties of brain areas previously implicated in attention and cognitive control, while DSF performance was related to areas less commonly implicated in verbal WM storage (precuneus, lateral visual areas). From a developmental perspective, DSF exhibited more robust age-related differences in brain-behavior relationships than DSB, and implicated a broader range of networks (ventral attention, default, somatomotor, limbic networks) - including a number of regions not commonly associated with verbal WM (angular gyrus, subcallosum). These results highlight the importance of examining the neurodevelopment of verbal WM and of considering regions beyond the "usual suspects".
PMCID:4696540
PMID: 26299314
ISSN: 1878-9307
CID: 1741982