#شناسایی #سازوکارهای بالقوه ایجاد #الکلیزم
#Dopamine #Neurons #Change the #Type of #Excitability in #Response to #Stimuli
#پژوهشگران مدرسه عالی اقتصاد روسیه با همکاری موسسه ملی سلامت و وزارت آموزش روسیه 🇷🇺، دانشکده نرمال سوپریر فرانسه 🇫🇷، و دانشگاه ایندیانای ایالات متحده 🇺🇸، در پژوهش بر ریشه های #عصبی، #ژنتیک و #متابولیک #الکلیزم در افراد دریافتند که مکانیزم های #تغییریافته عمل در پاسخ #نورون های #دوپامینرژیک در پویایی های #کرتکس #پیش_پیشانی منجر به تغییر سطح #دوپامین مغز شده و فرد را به سمت الکلیزم سوق دهند.
Abstract
#The #dynamics of #neuronal #excitability #determine the #neuron’s response to stimuli, its #synchronization and #resonance properties and, ultimately, the computations it performs in the #brain. We investigated the dynamical #mechanisms underlying the excitability type of dopamine (#DA) neurons, using a #conductance-based #biophysical model, and its #regulation by intrinsic and #synaptic currents. #Calibrating the model to reproduce low frequency #tonic firing results in #N-methyl-D-aspartate (#NMDA) #excitation balanced by γ-Aminobutyric acid (#GABA)-mediated #inhibition and leads to type I excitable behavior characterized by a continuous decrease in firing frequency in response to #hyperpolarizing currents. Furthermore, we analyzed how excitability type of the DA neuron model is influenced by changes in the intrinsic current composition. A #subthreshold #sodium current is necessary for a continuous frequency decrease during application of a negative current, and the low-frequency “balanced” state during simultaneous activation of NMDA and GABA #receptors. Blocking this current switches the neuron to type II characterized by the abrupt onset of repetitive firing. Enhancing the #anomalous rectifier #Ih current also switches the excitability to type II. Key characteristics of synaptic conductances that may be observed in vivo also change the type of excitability: a #depolarized γ-Aminobutyric acid receptor (#GABAR) reversal potential or co-activation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (#AMPARs) leads to an abrupt frequency drop to zero, which is typical for type II excitability. Coactivation of N-methyl-D-aspartate receptors (#NMDARs) together with AMPARs and GABARs shifts the type I/II boundary toward more hyperpolarized GABAR reversal potentials. To better understand how altering each of the aforementioned currents leads to changes in excitability profile of DA neuron, we provide a thorough dynamical analysis. Collectively, these results imply that type I excitability in dopamine neurons might be important for low firing rates and fine-tuning basal dopamine levels, while switching excitability to type II during NMDAR and AMPAR activation may facilitate a transient increase in dopamine concentration, as type II neurons are more amenable to synchronization by mutual excitation.
لینک منبع 👇🏻(further reading)👇🏻
journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1005233
✅(در صورت جذابیت و علاقمندی به موضوع، مطلب را برای دیگران نیز بازنشر فرمایید).
📢کانال #دکترامیرمحمدشهسوارانی
🍃🌹🌸💐🌸🌹🍃
@DrAmirMohammadShahsavarani
#Dopamine #Neurons #Change the #Type of #Excitability in #Response to #Stimuli
#پژوهشگران مدرسه عالی اقتصاد روسیه با همکاری موسسه ملی سلامت و وزارت آموزش روسیه 🇷🇺، دانشکده نرمال سوپریر فرانسه 🇫🇷، و دانشگاه ایندیانای ایالات متحده 🇺🇸، در پژوهش بر ریشه های #عصبی، #ژنتیک و #متابولیک #الکلیزم در افراد دریافتند که مکانیزم های #تغییریافته عمل در پاسخ #نورون های #دوپامینرژیک در پویایی های #کرتکس #پیش_پیشانی منجر به تغییر سطح #دوپامین مغز شده و فرد را به سمت الکلیزم سوق دهند.
Abstract
#The #dynamics of #neuronal #excitability #determine the #neuron’s response to stimuli, its #synchronization and #resonance properties and, ultimately, the computations it performs in the #brain. We investigated the dynamical #mechanisms underlying the excitability type of dopamine (#DA) neurons, using a #conductance-based #biophysical model, and its #regulation by intrinsic and #synaptic currents. #Calibrating the model to reproduce low frequency #tonic firing results in #N-methyl-D-aspartate (#NMDA) #excitation balanced by γ-Aminobutyric acid (#GABA)-mediated #inhibition and leads to type I excitable behavior characterized by a continuous decrease in firing frequency in response to #hyperpolarizing currents. Furthermore, we analyzed how excitability type of the DA neuron model is influenced by changes in the intrinsic current composition. A #subthreshold #sodium current is necessary for a continuous frequency decrease during application of a negative current, and the low-frequency “balanced” state during simultaneous activation of NMDA and GABA #receptors. Blocking this current switches the neuron to type II characterized by the abrupt onset of repetitive firing. Enhancing the #anomalous rectifier #Ih current also switches the excitability to type II. Key characteristics of synaptic conductances that may be observed in vivo also change the type of excitability: a #depolarized γ-Aminobutyric acid receptor (#GABAR) reversal potential or co-activation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (#AMPARs) leads to an abrupt frequency drop to zero, which is typical for type II excitability. Coactivation of N-methyl-D-aspartate receptors (#NMDARs) together with AMPARs and GABARs shifts the type I/II boundary toward more hyperpolarized GABAR reversal potentials. To better understand how altering each of the aforementioned currents leads to changes in excitability profile of DA neuron, we provide a thorough dynamical analysis. Collectively, these results imply that type I excitability in dopamine neurons might be important for low firing rates and fine-tuning basal dopamine levels, while switching excitability to type II during NMDAR and AMPAR activation may facilitate a transient increase in dopamine concentration, as type II neurons are more amenable to synchronization by mutual excitation.
لینک منبع 👇🏻(further reading)👇🏻
journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1005233
✅(در صورت جذابیت و علاقمندی به موضوع، مطلب را برای دیگران نیز بازنشر فرمایید).
📢کانال #دکترامیرمحمدشهسوارانی
🍃🌹🌸💐🌸🌹🍃
@DrAmirMohammadShahsavarani
journals.plos.org
Dopamine Neurons Change the Type of Excitability in Response to Stimuli
Author Summary Dopamine neurons play a central role in guiding motivated behaviors. However, complete understanding of computations these neurons perform to encode rewarding and salient stimuli is still forthcoming. Network connectivity influences neural…
♻️علت احتمالی #بیماری #پارکینسن، اتصالات جدید #عصبی در #مغز است.
Loss of #Hyperdirect #Pathway #Cortico-#Subthalamic #Inputs Following #Degeneration of #Midbrain #Dopamine Neurons
پژوهشگران نوروساینس دانشگاه نورث وسترن شیکاگو 🇺🇸 در پژوهشی که گزارش آن به تازگی منتشر شده است دریافتند فعالیت غیر عادی در #گلوبوس_پالیدوس (بخش مهمی از #گره های #پایه مغز) مسئول مشکلات #حرکتی در بیماری پارکینسن است.
🔬در این پژوهش که بر #مدل #موش صورت گرفته است، مشخص شده است کاهش #دوپامین در ساختارهای #قاعده #جمجمه منجر به ایجاد مجدد و #تحریک بیش از حد اتصالات بین #نورون ها می شود که در نتیجه مشکلات حرکتیِ مشخصۀ بیماری پارکینسن در مبتلایان مشاهده خواهد شد.
🔆همچنین یافته های این پژوهش مدل فعلی بیماری پارکینسن را به چالش کشیده و رد می کند
Summary
The #motor #symptoms of #Parkinson’s disease (#PD) are linked to abnormally correlated and coherent activity in the #cortex and #subthalamic #nucleus (#STN). However, in #parkinsonian #mice we found that cortico-STN #transmission strength had diminished by #50%–75% through loss of #axo-dendritic and #axo-spinous #synapses, was incapable of long-term potentiation, and less effectively patterned STN activity. #Optogenetic, #chemogenetic, #genetic, and #pharmacological interrogation suggested that #downregulation of #cortico-STN transmission in PD mice was triggered by increased #striato-pallidal transmission, leading to #disinhibition of the STN and increased activation of #STN #NMDA #receptors. Knockdown of STN NMDA receptors, which also suppresses proliferation of #GABAergic #pallido-STN inputs in PD mice, reduced loss of cortico-STN transmission and patterning and improved motor function. Together, the data suggest that loss of dopamine triggers a maladaptive shift in the balance of #synaptic #excitation and #inhibition in the STN, which contributes to parkinsonian activity and motor dysfunction.
لینک منبع 👇🏻(further reading)👇🏻
http://www.cell.com/neuron/fulltext/S0896-6273(17)30781-X
✅(در صورت جذابیت و علاقمندی به موضوع، مطلب را برای دیگران نیز بازنشر فرمایید).
📢کانال #دکترامیرمحمدشهسوارانی
🍃🌹🌸💐🌸🌹🍃
@DrAmirMohammadShahsavarani
Loss of #Hyperdirect #Pathway #Cortico-#Subthalamic #Inputs Following #Degeneration of #Midbrain #Dopamine Neurons
پژوهشگران نوروساینس دانشگاه نورث وسترن شیکاگو 🇺🇸 در پژوهشی که گزارش آن به تازگی منتشر شده است دریافتند فعالیت غیر عادی در #گلوبوس_پالیدوس (بخش مهمی از #گره های #پایه مغز) مسئول مشکلات #حرکتی در بیماری پارکینسن است.
🔬در این پژوهش که بر #مدل #موش صورت گرفته است، مشخص شده است کاهش #دوپامین در ساختارهای #قاعده #جمجمه منجر به ایجاد مجدد و #تحریک بیش از حد اتصالات بین #نورون ها می شود که در نتیجه مشکلات حرکتیِ مشخصۀ بیماری پارکینسن در مبتلایان مشاهده خواهد شد.
🔆همچنین یافته های این پژوهش مدل فعلی بیماری پارکینسن را به چالش کشیده و رد می کند
Summary
The #motor #symptoms of #Parkinson’s disease (#PD) are linked to abnormally correlated and coherent activity in the #cortex and #subthalamic #nucleus (#STN). However, in #parkinsonian #mice we found that cortico-STN #transmission strength had diminished by #50%–75% through loss of #axo-dendritic and #axo-spinous #synapses, was incapable of long-term potentiation, and less effectively patterned STN activity. #Optogenetic, #chemogenetic, #genetic, and #pharmacological interrogation suggested that #downregulation of #cortico-STN transmission in PD mice was triggered by increased #striato-pallidal transmission, leading to #disinhibition of the STN and increased activation of #STN #NMDA #receptors. Knockdown of STN NMDA receptors, which also suppresses proliferation of #GABAergic #pallido-STN inputs in PD mice, reduced loss of cortico-STN transmission and patterning and improved motor function. Together, the data suggest that loss of dopamine triggers a maladaptive shift in the balance of #synaptic #excitation and #inhibition in the STN, which contributes to parkinsonian activity and motor dysfunction.
لینک منبع 👇🏻(further reading)👇🏻
http://www.cell.com/neuron/fulltext/S0896-6273(17)30781-X
✅(در صورت جذابیت و علاقمندی به موضوع، مطلب را برای دیگران نیز بازنشر فرمایید).
📢کانال #دکترامیرمحمدشهسوارانی
🍃🌹🌸💐🌸🌹🍃
@DrAmirMohammadShahsavarani