scholarly journals Assessing the utility of MAGNETO to control neuronal excitability in the somatosensory cortex

2019 ◽  
Author(s):  
Koen Kole ◽  
Yiping Zhang ◽  
Eric J. R. Jansen ◽  
Terence Brouns ◽  
Ate Bijlsma ◽  
...  
Keyword(s):  
Somatosensory Cortex ◽  
Action Potentials ◽  
Magnetic Stimulation ◽  
Neuronal Excitability ◽  
Neural Interfaces ◽  
Intracellular Recordings ◽  
Membrane Excitability ◽  
Freely Moving ◽  
The Brain

Magnetic neuromodulation has outstanding promise for the development of novel neural interfaces without direct physical intervention with the brain. Here we tested the utility of Magneto in the adult somatosensory cortex by performing whole-cell intracellular recordings in vitro and extracellular recordings in freely moving mice. Results show that magnetic stimulation does not alter subthreshold membrane excitability or contribute to the generation of action potentials in virally transduced neurons expressing Magneto.

scholarly journals Development of Optically-Controlled “Living Electrodes” with Long-Projecting Axon Tracts for a Synaptic Brain-Machine Interface

2018 ◽  
Author(s):  
Dayo O. Adewole ◽  
Laura A. Struzyna ◽  
James P. Harris ◽  
Ashley D. Nemes ◽  
Justin C. Burrell ◽  
...  
Keyword(s):  
Brain Activity ◽  
Optical Recording ◽  
Neural Interfaces ◽  
New Class ◽  
Brain Surface ◽  
Long Term Performance ◽  
Term Performance ◽  
The Brain

AbstractAchievements in intracortical neural interfaces are compromised by limitations in specificity and long-term performance. A biological intermediary between devices and the brain may offer improved specificity and longevity through natural synaptic integration with deep neural circuitry, while being accessible on the brain surface for optical read-out/control. Accordingly, we have developed the first “living electrodes” comprised of implantable axonal tracts protected within soft hydrogel cylinders for the biologically-mediated monitoring/modulation of brain activity. Here we demonstrate the controlled fabrication, rapid axonal outgrowth, reproducible cytoarchitecture, and simultaneous optical stimulation and recording of neuronal activity within these engineered constructs in vitro. We also present their transplantation, survival, integration, and optical recording in rat cortex in vivo as a proof-of-concept for this neural interface paradigm. The creation and functional validation of these preformed, axon-based “living electrodes” is a critical step towards developing a new class of biohybrid neural interfaces to probe and modulate native circuitry.

scholarly journals Repetitive low intensity magnetic field stimulation in a neuronal cell line: A metabolomics study

2018 ◽  
Author(s):  
Ivan Hong ◽  
Andrew Garrett ◽  
Garth Maker ◽  
Ian Mullaney ◽  
Jennifer Rodger ◽  
...  
Keyword(s):  
Cell Line ◽  
Magnetic Stimulation ◽  
Neuronal Excitability ◽  
Therapeutic Potential ◽  
Neuronal Cell ◽  
Neural Tissue ◽  
Gaba Release ◽  
Low Intensity ◽  
Repetitive Magnetic Stimulation

Low intensity repetitive magnetic stimulation of neural tissue modulates neuronal excitability and has promising therapeutic potential in the treatment of neurological disorders. However, the underpinning cellular and biochemical mechanisms remain poorly understood. This study investigates the behavioural effects of low intensity repetitive magnetic stimulation (LI-rMS) at a cellular and biochemical level. We delivered LI-rMS (10 mT) at 1 Hz and 10 Hz (n=5 wells per group) to B50 rat neuroblastoma cells in vitro for 10 minutes and measured levels of selected metabolites immediately after stimulation. LI-rMS at both frequencies depleted selected tricarboxylic acid (TCA) cycle metabolites without affecting the main energy supplies. Furthermore, LI-rMS effects were frequency-specific with 1 Hz stimulation having stronger effects than 10 Hz. The observed depletion of metabolites was consistent with an increase in GABA release as a result of higher spontaneous activity. Although the absence of organised neural circuits and other cellular contributors (e.g. excitatory neurons and glia) in the B50 cell line limits the degree to which our results can be extrapolated to the human brain, the changes we describe provide novel insights into how LI-rMS modulates neural tissue.

scholarly journals Repetitive low intensity magnetic field stimulation in a neuronal cell line: a metabolomics study

PeerJ ◽  
2018 ◽  
Vol 6 ◽  
pp. e4501 ◽  
Author(s):  
Ivan Hong ◽  
Andrew Garrett ◽  
Garth Maker ◽  
Ian Mullaney ◽  
Jennifer Rodger ◽  
...  
Keyword(s):  
Cell Line ◽  
Magnetic Stimulation ◽  
Neuronal Excitability ◽  
Therapeutic Potential ◽  
Neuronal Cell ◽  
Neural Tissue ◽  
Gaba Release ◽  
Low Intensity ◽  
Repetitive Magnetic Stimulation

Low intensity repetitive magnetic stimulation of neural tissue modulates neuronal excitability and has promising therapeutic potential in the treatment of neurological disorders. However, the underpinning cellular and biochemical mechanisms remain poorly understood. This study investigates the behavioural effects of low intensity repetitive magnetic stimulation (LI-rMS) at a cellular and biochemical level. We delivered LI-rMS (10 mT) at 1 Hz and 10 Hz to B50 rat neuroblastoma cellsin vitrofor 10 minutes and measured levels of selected metabolites immediately after stimulation. LI-rMS at both frequencies depleted selected tricarboxylic acid (TCA) cycle metabolites without affecting the main energy supplies. Furthermore, LI-rMS effects were frequency-specific with 1 Hz stimulation having stronger effects than 10 Hz. The observed depletion of metabolites suggested that higher spontaneous activity may have led to an increase in GABA release. Although the absence of organised neural circuits and other cellular contributors (e.g., excitatory neurons and glia) in the B50 cell line limits the degree to which our results can be extrapolated to the human brain, the changes we describe provide novel insights into how LI-rMS modulates neural tissue.

scholarly journals Orexin A suppresses in vivo GH secretion

2004 ◽  
pp. 731-736 ◽  
Author(s):  
LM Seoane ◽  
SA Tovar ◽  
D Perez ◽  
F Mallo ◽  
M Lopez ◽  
...  
Keyword(s):  
Nutritional Status ◽  
Area Under The Curve ◽  
Sleep Regulation ◽  
Gh Secretion ◽  
Neuroendocrine Function ◽  
Freely Moving Rats ◽  
Freely Moving ◽  
The Brain

BACKGROUND/AIMS: Orexins (OXs) are a newly described family of hypothalamic neuropeptides. Based on the distribution of OX neurons and their receptors in the brain, it has been postulated that they could play a role in the regulation of neuroendocrine function. GH secretion is markedly influenced by nutritional status and body weight. To investigate the role OX-A plays in the neuroregulation of GH secretion we have studied its effect on spontaneous GH secretion as well as GH responses to GHRH and ghrelin in freely moving rats. Finally, we also assessed the effect of OX-A on in vitro GH secretion. METHODS: We administered OX-A (10 microg, i.c.v.) or vehicle (10 microl, i.c.v.) to freely moving rats. Spontaneous GH secretion was assessed over 6 h with blood samples taken every 15 min. RESULTS: Administration of OX-A led to a decrease in spontaneous GH secretion in comparison with vehicle-treated rats, as assessed by mean GH levels (means+/-s.e.m. 4.2+/-1.7 ng/ml vs 9.4+/-2.2 ng/ml; P<0.05), mean GH amplitude (3.6+/-0.5 ng/ml vs 20.8+/-5.6 ng/ml; P<0.01) and area under the curve (848+/-379 ng/ml per 4 h vs 1957+/-458 ng/ml per 4 h; P<0.05). In contrast, OX-A failed to modify in vivo GH responses to GHRH (10 microg/kg, i.v.) although it markedly blunted GH responses to ghrelin (40 microg/kg, i.v.) (mean peak GH levels: 331+/-71 ng/ml, vehicle, vs 43+/-11 ng/ml in OX-A-treated rats; P<0.01). Finally, OX-A infusion (10(-7), 10(-8) or 10(-9) M) failed to modify in vitro basal GH secretion or GH responses to GHRH, ghrelin and KCl. CONCLUSIONS: These data indicate that OX-A plays an inhibitory role in GH secretion and may act as a bridge among the regulatory signals that are involved in the control of growth, nutritional status and sleep regulation.

scholarly journals Neuroplasticity induction using transcranial magnetic stimulation

2019 ◽  
Keyword(s):  
Synaptic Plasticity ◽  
Transcranial Magnetic Stimulation ◽  
Magnetic Stimulation ◽  
Neuronal Excitability ◽  
Scientific Data ◽  
Dependent Manner ◽  
Global Dynamic ◽  
Endogenous Dopamine ◽  
Ipsilateral Striatum ◽  
The Brain

In this article, we have displayed the results of an analysis of modern scientific data on the induction of neuroplasticity using transcranial magnetic stimulation. We presented the multilevel neuroplastic effects of electromagnetic fields caused by transcranial magnetic stimulation (TMS). The authors of the article determined that transcranial magnetic stimulation uses variable magnetic fields to non-invasively stimulate neurons in the brain. The basis of this method is the modulation of neuroplasticity mechanisms with the subsequent reorganization of neural networks. Repeated TMS (rTMS), which is widely used in neurology, affects neurotransmitters and synaptic plasticity, glial cells and the prevention of neuronal death. The neurotrophic effects of rTMS on dendritic growth, as well as growth and neurotrophic factors, are described. An important aspect of the action of TMS is its effect on neuroprotective mechanisms. A neuroimaging study of patients with Parkinson's disease showed that rTMS increased the concentration of endogenous dopamine in the ipsilateral striatum. After rTMS exposure, the number of β-adrenergic receptors in the frontal and cingulate cortex decreases, but the number of NMDA receptors in the ventromedial thalamus, amygdala, and parietal cortex increases. These processes ultimately lead to the induction of prolonged potentiation. In response to rTMS, neuronal excitability changes due to a shift in ion balance around a population of stimulated neurons; this shift manifests itself as altered synaptic plasticity. Combinations of rTMS treatment and pharmacotherapy (e.g., small doses of memantine) may block the alleviating effect during prolonged potentiation. Studies using models of transient ischemic attack and prolonged ischemia have shown that rTMS protects neurons from death and alters the blood flow and metabolism in the brain. It has been demonstrated that TMS has a proven ability to modulate the internal activity of the brain in a frequency-dependent manner, generate contralateral responses, provide, along with the neuromodulating and neurostimulating effect, affect the brain as a global dynamic system.

scholarly journals Injectable Nanoelectrodes Enable Wireless Deep Brain Stimulation of Native Tissue in Freely Moving Mice

2020 ◽  
Author(s):  
Kristen L. Kozielski ◽  
Ali Jahanshahi ◽  
Hunter B. Gilbert ◽  
Yan Yu ◽  
Önder Erin ◽  
...  
Keyword(s):  
Behavioral Changes ◽  
Less Invasive ◽  
Magnetoelectric Materials ◽  
The Central Nervous System ◽  
Freely Moving ◽  
The Brain ◽  
Deep Brain ◽  
Stimulation Of

AbstractDevices that electrically modulate the central nervous system have enabled important breakthroughs in the management of neurological and psychiatric disorders. Such devices typically have centimeter-scale dimensions, requiring surgical implantation and wired-in powering. Using smaller, remotely powered materials could lead to less invasive neuromodulation. Herein, we present injectable magnetoelectric nanoelectrodes that wirelessly transmit electrical signals to the brain in response to an external magnetic field. Importantly, this mechanism of modulation requires no genetic modification of the brain, and allows animals to freely move during stimulation. Using these nanoelectrodes, we demonstrate neuronal modulation in vitro and in deep brain targets in vivo. We also show that local thalamic modulation promotes modulation in other regions connected via basal ganglia circuitry, leading to behavioral changes in mice. Magnetoelectric materials present a versatile platform technology for less invasive, deep brain neuromodulation.

Depression by magnesium ion of neuronal excitability in tissue cultures of central nervous system

1977 ◽  
Vol 55 (3) ◽  
pp. 367-372 ◽  
Author(s):  
J. M. Wojtowicz ◽  
K. C. Marshall ◽  
W. J. Hendelman
Keyword(s):  
Central Nervous System ◽  
Nervous System ◽  
Neuronal Excitability ◽  
Neuronal Membrane ◽  
Magnesium Ion ◽  
Tissue Cultures ◽  
Central Nervous System Tissue ◽  
Membrane Excitability ◽  
Antidromic Activation

Magesium ion (Mg2+) in concentrations of 5–10 mM has been used to block synaptic transmission in in vitro preparations of central nervous system tissue. We have used explants of mouse cerebellum grown in culture to test whether significant levels of direct depression of neuronal membrane excitability could occur in such experiments. Using thresholds for antidromic activation and iontophoretically applied glutamate as tests of excitability, potent depressions of membrane excitability were found using 5–10 mM Mg2+. The additive depressant effects of increased Ca2+ concentrations provided further evidence that the effects were largely on membrane excitability and not on transmitter release mechanisms.

scholarly journals Repetitive low intensity magnetic field stimulation in a neuronal cell line: A metabolomics study

2018 ◽  
Author(s):  
Ivan Hong ◽  
Andrew Garrett ◽  
Garth Maker ◽  
Ian Mullaney ◽  
Jennifer Rodger ◽  
...  
Keyword(s):  
Cell Line ◽  
Magnetic Stimulation ◽  
Neuronal Excitability ◽  
Therapeutic Potential ◽  
Neuronal Cell ◽  
Neural Tissue ◽  
Gaba Release ◽  
Low Intensity ◽  
Repetitive Magnetic Stimulation

Low intensity repetitive magnetic stimulation of neural tissue modulates neuronal excitability and has promising therapeutic potential in the treatment of neurological disorders. However, the underpinning cellular and biochemical mechanisms remain poorly understood. This study investigates the behavioural effects of low intensity repetitive magnetic stimulation (LI-rMS) at a cellular and biochemical level. We delivered LI-rMS (10 mT) at 1 Hz and 10 Hz (n=5 wells per group) to B50 rat neuroblastoma cells in vitro for 10 minutes and measured levels of selected metabolites immediately after stimulation. LI-rMS at both frequencies depleted selected tricarboxylic acid (TCA) cycle metabolites without affecting the main energy supplies. Furthermore, LI-rMS effects were frequency-specific with 1 Hz stimulation having stronger effects than 10 Hz. The observed depletion of metabolites was consistent with an increase in GABA release as a result of higher spontaneous activity. Although the absence of organised neural circuits and other cellular contributors (e.g. excitatory neurons and glia) in the B50 cell line limits the degree to which our results can be extrapolated to the human brain, the changes we describe provide novel insights into how LI-rMS modulates neural tissue.

scholarly journals CCL2 has similar excitatory effects to TNF-α in a subgroup of inflamed C-fiber axons

2011 ◽  
Vol 106 (6) ◽  
pp. 2838-2848 ◽  
Author(s):  
Natalie Richards ◽  
Thomas Batty ◽  
Andrew Dilley
Keyword(s):  
Action Potentials ◽  
Neuronal Excitability ◽  
Ongoing Activity ◽  
Additional Group ◽  
Tnf Α ◽  
C Fiber ◽  
Noxious Mechanical Stimulation ◽  
Underlying Mechanisms

Peripheral nerve inflammation can cause neuronal excitability changes that have been implicated in the pathogenesis of chronic pain. Although the neuroimmune interactions that lead to such physiological changes are unclear, in vitro studies suggest that the chemokine CCL2 may be involved. This in vivo study examines the effects of CCL2 on untreated and inflamed neurons and compares its effects with those of TNF-α. Extracellular recordings were performed in the anesthetized rat on isolated neurons with C-fiber axons. On untreated neurons, CCL2, as well as TNF-α, had negligible effects. Following neuritis, both cytokines transiently caused the firing of action potentials in 27–30% of neurons, which were either silent or had background (ongoing) activity. The neurons with ongoing activity, which responded to either cytokine, had significantly slower baseline firing rates {median = 3.0 spikes/min [interquartile range (IQR) 3.0]} compared with the nonresponders [median = 24.4 spikes/min (IQR 24.6); P < 0.001]. In an additional group, 26–27% of neurons, which were sensitized due to repeated noxious mechanical stimulation of the periphery, also responded to the effects of both cytokines. Neither cytokine caused axons to become mechanically sensitive. Immunohistochemistry confirmed that the cognate CCL2 receptor, CCR2, is mainly expressed on glia and is therefore not likely to be an axonal target for CCL2 following inflammation. In contrast, the cognate TNF-α receptor (TNFR), TNFR1, was present on untreated and inflamed neurons. In summary, CCL2 can excite inflamed C-fiber neurons with similar effects to TNF-α, although the underlying mechanisms may be different. The modulatory effects of both cytokines are limited to a subgroup of neurons, which may be subtly inflamed.

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