Global ETD Search

131	Modeling incomplete penetrance in long QT syndrome type 3 (LQT3) through ion channel heterogeneity Miller, Jacob Andrew January 2022 (has links) No description available. Biomedical Engineering Biomedical Research Physiology Biology Biophysics LQT3 ion channel INaL gain-of-function arrhythmia sudden cardiac death SIDS
132	Effects of Isoproterenol on IhERG during K+ changes in HEK293 cells Zhang, J., Shang, Lijun, Wang, T., Ni, Y., Ma, A. January 2017 (has links) Yes / Introduction:The human ether-a-go-go related gene (hERG) encodes the pore forming protein which mediates the rapid delayed rectifier K+ current in the heart (IKr). Together with other ion channels hERG determines the cardiac action potential and regulates the heart beating. Dysfuction of the hERG ion channel will lead to acquired long QT syndrome (LQTS). Therefore, new drug candidates must pass the test for a potential inhibitory effect on the hERG current as a first step in a nonclinical testing strategy. Arrhythmias in patients with LQTS are typically triggered during physical or emotional stress, suggesting a link between sympathetic stimulation and arrhythmias. It is well known that potassium level can affect the QT interval through affecting IhERG both in vivo and in vitro.In this study, we try to find out whether the trigger effect still exist when K+ changes violently in a short time period. In other words, whether the risk of TdP aggravate when patients suffer from acute water electrolyte balance disorder, which is a common symptom in hot weather. Methods: HEK293 Cell line stably expressing hERG channel were cultured in DMEM supplemented with 10% of fetal bovine serum.Whole-cell patch-clamp method was applied for ionic current recordings. The compositions of pipette was (in mM) 125 KCl, 5 MgCl2, 5 EGTA-K, 10 HEPES-K and 5 Na-ATP adjusted to pH 7.2 with KOH. The bath solutions for recording the IhERG currents was 136 NaCl, 4 KCl, 1 MgCl2, 10 HEPES-Na, 1.8 CaCl2 and 10 glucose, pH 7.4 with NaOH. The low extracellular K+ solution was 115 KCl, 5 MgCl2, 5 EGTA-K, 10 HEPES-K and 10 Na-ATP adjusted to pH 7.2 with NaOH. Patch-clamp experiments were performed at room temperature (22 ± 1°C). The recording of low K+ current was carried out immediately after the original normal K+ solution has been totally replaced. Isoproterenol (ISO) 100nM was added into both kinds of K+ solution to apply the effect of β1-AR stimulation. Results: We found that low K+ solution increased IhERG from 907.39±18.68to 1620.08±249.44pA(n=30,P<0.05); Low K+also shifted the I-V curve to the left. IC50 in control is 10.31±5.52 mV, low K+ is -6.15±1.58 mV. When adding ISO 100nM to extracellular solution, same effects were shown for both groups.ISO decreased Imax for both group. In control group, Imax reduced from 907.39±18.68to493.16±54.41pA (n=30, P<0.01), while in low K+ group, I max decreased Imax from 1620.08±29.44to 488.48±81.87pA(n=30,P<0.05). At the same time, ISO shifts the I-V curve to the right for the control group and shift the curve to the left for low K+ group. IC50 in control when added ISO is 22.25±3.80 mV, while IC50 in low K+ group after adding 100nM ISO is -31.00±5.73 mV. Conclusion: The results from this study is contradict to those in our previous study where low K+ combined with ISO can lead to temporarily increase of QT interval in vivo.It is reported that an increase in net outward repolarizing current, due to a relatively large increase of IKs, is responsible for the changes of QT interval in response to beta-adrenergic stimulation in vivo(2). Therefore future studies need to co-transfect IKs channel to confirm this. References: 1. Guo J, Massaeli H, Xu J, Jia Z, Wigle JT, Mesaeli N, et al. Extracellular K+ concentration controls cell surface density of IKr in rabbit hearts and of the HERG channel in human cell lines. The Journal of clinical investigation. 2009;119(9):2745- 57. 2. Shimizu W, Antzelevitch C. Differential effects of beta-adrenergic agonists and antagonists in LQT1, LQT2 and LQT3 models of the long QT syndrome. Journal of the American College of Cardiology. 2000;35(3):778-86. hERG ion channel Potassium level K+ current Isoproterenol IhERG currents HEK293 cells Cardiac action potential Heart beating
133	Rôle de l’extrémité C-terminale dans l’expression du canal calcique Cav1.2 à la membrane plasmique Le Coz, Florian 07 1900 (has links) Le canal calcique de type L, Cav1.2, joue un rôle clé dans le couplage excitation-contraction des myocytes ventriculaires. Il a été montré que la sous-unité Cavα1 était sujette à l’épissage alternatif et que ce phénomène pouvait mener à une protéine tronquée en C-terminal au niveau de l’exon 45 (Liao, Yong et al. 2005). D’autres groupes ont étudié différentes délétions au niveau de l’extrémité C-terminale (De Jongh, Warner et al. 1991; Gao, Cuadra et al. 2001). Les courants mesurés dans la configuration cellule entière, était significativement plus grands que le canal « pleine longueur ». Nous avons décidé de tester certaines de ces délétions (ΔC2030, ΔC1935, ΔC1856, ΔC1733, ΔC1700) en présence ou en absence de la sous-unité auxiliaire Cavβ3, susceptible d’interagir avec l’extrémité C-terminale de la sous-unité Cavα1 par l’intermédiaire de son domaine SH3 (Lao, Kobrinsky et al. 2008). Les résultats obtenus dans les ovocytes de Xénope ont mis en évidence que les sous-unités Cavα1.2 tronquées montraient des courants globaux plus élevés que le canal « pleine longueur » en présence de la sous-unité auxiliaire Cavβ3 et que les sous-unités Cavα1.2 tronquées donnaient des courants en absence de la sous-unité Cavβ3 contrairement à la sous-unité Cavα1.2 « pleine longueur ». Afin de vérifier si l’augmentation des courants macroscopiques était le résultat d’une augmentation du nombre de sous-unités Cavα1.2 à la membrane, nous avons choisi de quantifier la fluorescence spécifiquement due à cette sous-unité en utilisant la méthode de cytométrie de flux (FACS : « Fluorescence Activated Cell Sorting »). L’épitope HA a été inséré dans une région extracellulaire de la sous-unité Cavα1 du canal calcique Cav1.2 et un anticorps anti-HA couplé au FITC (« Fluorescein IsoThioCyanate ») a été utilisé pour observer la fluorescence. Nos résultats confirment que la sous-unité Cavα1-HA du canal calcique Cav1.2, s’exprime à la membrane plasmique en présence de la sous-unité auxiliaire Cavβ3, et qu’en absence de celle-ci, ne s’exprime que peu ou pas à la membrane. Les mêmes résultats ont été obtenus pour les trois délétions testées dans les mêmes conditions soit Cavα1.2-HA ΔC1935, Cavα1.2-HA ΔC1856 et Cavα1.2-HA ΔC1733. Ensemble, ces résultats suggèrent que l’augmentation des courants macroscopiques observés après une délétion partielle du C-terminal n’est pas causée par une augmentation du nombre de protéines Cavα1.2 à la membrane. / The L-type calcium channel, Cav1.2, plays an important role in the excitation-contraction coupling of the ventricular myocytes. It has been shown that the alternative splicing of Cavα1.2 subunit could lead to a truncated protein in the C-terminus at exon 45 (Liao, Yong et al. 2005). Many groups have studied deletions in the C-terminus (De Jongh, Warner et al. 1991; Gao, Cuadra et al. 2001). The currents, measured in the whole cell configuration, were significantly higher with the full-length channel. We chose to test some of these deletions (ΔC2030, ΔC1935, ΔC1856, ΔC1733, ΔC1700) in the presence or absence of the Cavβ3 auxiliary subunit which is likely to interact with the C-terminus of the Cavα1.2 subunit through its SH3 domain (Lao, Kobrinsky et al. 2008). The truncated Cavα1.2 subunit, expressed in Xenopus Oocytes, showed macroscopic currents that were greater than those of the full length channel in presence of the Cavβ3 subunit. In addition, the truncated Cavα1.2 subunits displayed currents in the absence of the Cavβ3 subunit in contrast with the Cavα1.2 full length subunit. To investigate whether the larger macroscopic currents resulted in an increase in the number of Cavα1.2 subunits at the plasma membrane, we chose the FACS (« Fluorescence Activated Cell Sorting ») method. An HA-tag was inserted in an extracellular region of the Cavα1.2 subunit and a FITC (« Fluorescein IsoThioCyanate ») coupled anti-HA antibody was used to measure fluorescence. Our results showed that the Cavα1.2-HA subunit of L- type channel is expressed at the plasma membrane in the presence of the Cavβ3 subunit whereas the Cavα1.2-HA subunit is slightly or not expressed at the plasma membrane in its absence. The same results were obtained for the three C-terminal deletions tested under the same conditions (CaVα1.2-HA ΔC1935, CaVα1.2-HA ΔC1856 and CaVα1.2-HA ΔC1733). Taken together, these results suggest that the increased macroscopic currents observed after a partial deletion of the C-terminus is not caused by an increased number of Cavα1.2 proteins expressed at the plasma membrane. Keywords: Calcium Canal ionique Gating Mutagénèse dirigée FACS Electrophysiologie Immunobuvardage de type Western Calcium Ion channel Gating Directed Mutagenesis FACS Electrophysiology Western-blot
134	Influence des glycines du lien S4-S5 sur le couplage électromécanique des canaux ioniques dépendants du voltage Barreto, Sandra 03 1900 (has links) Les canaux potassiques dépendants du voltage sont formés de quatre sous-unités, chacune possédant six segments transmembranaires (S1-S6) et une boucle (p-loop) qui se trouve entre le cinquième et le sixième segment au niveau du pore. Il est connu que le segment senseur du voltage (S1-S4) subit un mouvement lorsque le potentiel membranaire change. Pour ouvrir le canal, il est nécessaire de transférer l'énergie du senseur du voltage (généré par le mouvement des charges positives de S4) au pore. Le mécanisme exact de ce couplage électromécanique est encore sous étude. Un des points de liaison entre le senseur de voltage et le pore est le lien physique fait par le segment S4-S5 (S45L). Le but de cette étude est de déterminer l'influence de la flexibilité du segment S45L sur le processus de couplage. Dans le S45L, trois glycines sont distribuées dans des positions différentes. Elles sont responsables de la flexibilité des hélices-alpha. Ces glycines (mais pas leurs positions exactes) sont conservées pour tous les canaux potassiques dépendants de potentiel. En utilisant la technique de mutagènes dirigé, la glycine a été remplacée dans chacune de ces différentes positions par une alanine et dans une deuxième étape, par une proline (pour introduire un angle dans l'hélice). Pour étudier le comportement des canaux dans cette nouvelle conformation, on a appliqué la technique de « patch clamp » pour déterminer les effets lors de l'ouverture du pore (courant ionique). Avec le « cut-open oocyte voltage-clamp », nous avons étudié les effets sur le mouvement du senseur de voltage (courant “gating”) et la coordination temporelle avec l'ouverture du pore (courant ionique). Les données ont montré qu’en réduisant la flexibilité dans le S45L, il faut avoir plus d'énergie pour faire ouvrir le canal. Le changement pour une proline suggère que le mouvement du senseur est indépendant du pore pendant l'ouverture du canal. / Voltage-gated potassium channels are formed of four subunits, each one with six transmembrane segments (S1-S6) and a loop (p-loop) between S5 and S6 at the level of the pore. It is known that the voltage sensitive segment (S1-S4) undergoes a movement upon membrane potential changes. To open the channel, it is necessary to transfer the energy of the voltage sensor (generated by the displacement of the positive charges of S4) to the pore. The exact mechanism of this “electromechanical coupling” is still under investigation. The voltage sensor and pore are physically linked by the S4-S5 linker (S45L). The aim of this study is to determine the influence of S45L flexibility on the coupling process. In the S45L, three glycines are distributed at different positions and are responsible for the flexibility of the alpha-helix. These glycines (but not their exact position) are conserved within the potassium voltage-gated ion channels. The glycines were each replaced by an alanine using point mutagenesis. In a second step, a proline was introduced at the position in order to introduce a break in the helix. To study the behaviour of channels in this new conformation, we used the patch clamp technique to determine the effects during the pore opening (ionic current). With the cut-open voltage-clamp we determined the effects on voltage sensor movement (gating current) as well as the temporal correlation with the pore opening (ionic current). The data showed that when the flexibility of the S45L is reduced, the channel needs more energy to open. Exchange with proline suggests that the movement of the sensor is independent of pore opening. biophysique canal ionique shaker senseur de voltage glycine gating patch clamp cut-open ooocyte biophysics ion channel voltage-sensor
135	Studium funkce a struktury teplotně aktivovaných TRP iontových kanálů: Role evolučně konzervovaných motivů v modulaci TRPA1 / Functional and structural study of thermally activated TRP ion channels: The role evolutionarily conserved motifs in the TRPA1 modulation Kádková, Anna January 2016 (has links) Ankyrin receptor TRPA1 is an ion channel widely expressed on primary afferent sensory neurons, where it acts as a polymodal sensor of nociceptive stimuli. Apart from pungent chemicals (e. g. isothiocyanates, cinnamaldehyde and its derivatives, acrolein, menthol), it could be activated by cold temperatures, depolarizing voltages or intracellular calcium ions. TRPA1 channel is a homotetramer in which each subunit consists of cytoplasmic N and C termini and a transmembrane region. The transmembrane part is organized into six alpha- helices connected by intra- and extracellular loops. The N terminus comprises a tandem set of 16 to 17 ankyrin repeats (AR), while the C terminus has a substantially shorter, dominantly helical structure. In 2015, a partial cryo-EM structure of TRPA1 was resolved; however, the functional roles of the individual regions of the receptor have not yet been fully understood. This doctoral thesis is concerned to elucidate the role of highly conserved sequence and structural motifs within the cytoplasmic termini and the S4-S5 region of TRPA1 in voltage- and chemical sensitivity of the receptor. The probable binding site for calcium ions that are the most important physiological modulators of TRPA1 was described by using homology modeling, molecular-dynamics simulations,...
136	Identification and characterization of the ion channel TRPM8 in prostate cancer Kaiser, Simone 13 September 2004 (has links) Das Prostatakarzinom ist die häufigste Krebserkrankung des Mannes. Bei den zu Tode führenden Tumoren wird es im Jahre 2003 nach dem Bronchialkarzinom an 2. Stelle stehen. Diese Inzidenz zeigt, dass dringend neue diagnostische Marker und therapeutische Zielgene zur Behandlung von Prostatakrebs benötigt werden. Ziel dieser Dissertation war es, mit Hilfe der DNA-Chiptechnologie neue tumorrelevante Gene für eine Small-Molecule- und Antikörper-Basierte Therapie des Prostatakarzinoms zu identifizieren. Auf einen proprietären Tumor-Chip der Firma metaGen Pharmaceuticals GmbH wurde mikrodissektiertes Normal- und korrespondierendes Tumorgewebe von 52 Prostatatumorpatienten hybridisiert. Mit Hilfe bioinformatischer Analysen der Chipergebnisse konnte das Gen TRPM8 identifiziert werden, das in Prostatatumoren in mehr als 56% der Patienten überexprimiert ist. Northern-Blot, Dot-Blot und Chipexperimente zeigten, dass TRPM8 ungewöhnlich gewebespezifisch exprimiert wird. In mehr als 400 getesteten Tumorpatienten und in 23 Normalgeweben wurde TRPM8 ausschließlich in der Prostata und neuroendokrinen Tumoren nachgewiesen. TRPM8 gehört zur Familie der Transient Receptor Potential Channel Proteins. Es konnte hier erstmals in Fluoreszenz-Resonanz-Energie-Transfer-Experimenten (FRET) gezeigt werden, dass TRPM8 Multi-Homomere bildet. Dies wurde bisher nur für Kanäle anderer TRP-Subfamilien (TRPV und TRPC) gezeigt. Weiterhin konnten erstmals mehrere Spleißvarianten von TRPM8 identifiziert werden. Quantitative RT-PCR Experimente zeigten, dass diese noch stärker in Prostatatumoren überexprimiert sind als TRPM8 selbst. Des Weiteren wurde ein neues Gen auf dem DNA-Gegenstrang von TRPM8 entdeckt, das mit Exon 11 von TRPM8 100% komplementär ist und an der Regulation von TRPM8 beteiligt sein könnte. Der Promotor von TRPM8 wurde durch eine in silico Analyse identifiziert und in vitro bestätigt. Obwohl eine starke androgenabhängige Expression von TRPM8 in LNCaP Zellen gezeigt werden konnte, wurden keine Bindungsstellen für androgenabhänginge Elemente gefunden. Allerdings ließen sich drei Bindungsstellen des androgenregulierten Homeoboxgens NKX3.1 identifizieren. Die Ergebnisse dieser Arbeit zeigen, dass TRPM8 und seine Isoformen aufgrund ihrer Gewebspezifität ausgezeichnete Angriffspunkte für eine zielgerichtete Prostatakrebstherapie sind. / Prostate cancer is the most commonly diagnosed malignancy in men in the Western World. In 2003 malignancies of the prostate will be the second most common fatal cancer in men after lung cancer as estimated by the American Cancer Society. Despite the tremendous efforts made in the past to improve the treatment of prostate cancer patients, there is still an urgent need for new markers and therapeutic targets for medication. The aim of this thesis was the identification of new genes relevant in prostate cancer, which could be used in a small-molecule or antibody based therapy of prostate cancers. Microdissected matched prostate cancer and normal tissues of 52 prostate cancer patients were hybridized to a proprietary high density Cancer-Chip based on Affymetrix GeneChip technology. Using a bioinformatic analysis, it was possible to identify TRPM8, which was highly overexpressed in 56% of prostate cancer patients. Northern blot, dot blot and gene chip experiments revealed that TRPM8 expression is extremely tissue specific. Of 400 patients and 23 tissues tested, TRPM8 expression could only be detected in the prostate and neuroendocrine tumors. Functionally, the protein belongs to the transient receptor potential channel family of non-voltage gated proteins. It could be shown for the fist time that TRPM8 subunits form homomers using FRET technology. Molecular characterization of TRPM8 transcription revealed multiple splice forms of TRPM8. Further, it was possible to identify a new mRNA present on the opposite strand of TRPM8, which was 100% complementary to exon 11 of TRPM8, thus it could possibly function as a regulatory RNA of TRP channel. All of these isoforms were found to be even higher overexpressed in prostate tumors than TRPM8 itself. The promoter region of TRPM8 was identified using in silico methods and confirmed in promoter reporter assays. Although a high androgen dependent transcriptional activation of TRPM8 could be found by RT-PCR in LNCaP cells, no androgen responsive elements was identifiable within the promoter region. On the other hand three binding sites for the androgen dependent homeobox gene NKX3.1 and several other homeobox genes were discovered. The results of the thesis show that TRPM8 and its isoforms are, due to their tissue specificity, ideal targets for the development of new therapeutic drugs for the treatment of prostate cancer. TRPM8 Prostata Krebs Chip Ionenkanal TRPM8 prostate cancer microarray ion channel 570 Biowissenschaften, Biologie 32 Biologie XH 8004 XH 8015 ddc:570
137	Electrophysiological characterization of the human two-pore channel 2 Lam, Andy Ka Ming January 2015 (has links) The Two-pore channel (TPC1-3) family represents a recently identified class of endolysosomal ion channels. TPCs were originally proposed to be promising candidate channels for NAADP-induced Ca<sup>2+</sup> release. However, subsequent studies have emerged to propose an alternative view where TPCs may be Na+-selective channels regulated by the lysosome-specific phosphoinositide PI(3,5)P2 or voltage in an isoform-dependent manner. This thesis asks the question of whether pharmacological and ion permeation properties of TPCs, in particular the human TPC2, may satisfy or may be consistent with the requirement of a potential NAADP-sensitive Ca<sup>2+</sup>-release channel. These fundamental properties of hTPC2 were approached using patch-clamp electrophysiology and confocal fluorescence microscopy, and were analysed quantitatively to extract relevant physical parameters important to our understanding of their physiological and functional significance. Chapter 2 presents the basic electrophysiological characterisation of hTPC2. It follows a logical way by first determining the ion permeation properties, followed by the investigation of its physical relation with fractional Ca<sup>2+</sup> current and Ca<sup>2+</sup> nanodomains to rigorously prove that this Na<sup>+</sup> selectivity is sufficient to ensure negligible Ca<sup>2+</sup> leakage both experimentally and theoretically. This follows the logic that matter must not be created nor destroyed so that a Na+-selective channel that poses a physiologically significant energy barrier to Ca<sup>2+</sup> permeation from one side would not lead to the creation of Ca<sup>2+</sup> on the other side. Chapter 3 represents a natural progression from Chapter 2 and is aimed at investigating the underlying mechanisms responsible for the electrophysiological ion selectivity observed. This chapter also follows a logical way by first identifying spermine as a high valence intracellular blocker, its mutual antagonism with different external ionic species that allows the determination of ion-binding affinity, followed by the determination of the concentration dependence of ion conduction to identify possible lower affinity binding. By considering all the above qualities, the outcome is a coherent description and connection of ion binding selectivity, kinetic selectivity and ion binding configuration with the observed electrophysiological selectivity. Chapter 4 discusses the missing puzzles and how these questions might be addressed. 615.1
138	Mechanistic Insight into Subunit Stoichiometry for KIR Channel Gating: Ligand Binding, Gating, Binding-Gating Coupling, Coordination, and Cooperativity Wang, Runping 12 January 2007 (has links) Ligand-gated ion channels couple intra- and extracellular chemical signals to cellular excitability. In response to a specific ligand, these channels change their permeability to certain ions by opening or closing their ion conductive pathway, a controlling mechanism known as channel gating. Although recent studies with X-ray crystallography and site-directed mutagenesis have revealed several structures potentially important for channel gating, the gating mechanism is still elusive. Ligand-dependent channel gating involves a series of transient events and asymmetric movements of individual subunits. Understanding of these events appears to be a challenge to current approaches in gating studies by using the homomeric wild-type or mutant channels. I therefore took an alternative approach by constructing heteromeric channels. Subunit stoichiometric studies of the Kir1.1 channel showed that a minimum of one functional subunit was required for the pH-dependent gating of the channel. Four subunits in this channel were coordinated as dynamic functional dimers. In Kir6.2 channel, stoichiometry for proton-binding was almost identical to that for channel gating in the M2 helix, suggesting a one-to-one direct coupling of proton binding in C-terminus to channel gating in M2 helix. Positive cooperativity was suggested among subunits in both the proton binding and channel gating. Ligand binding can be differentiated from channel gating by studying the ATP-dependent gating of Kir6.2 channel. Disruptions in ATP binding were found to change both the potency and efficacy of the concentration-dependent curves, while the baseline activity instead of maximum inhibition was affected by disruptions of channel gating. Four subunits in the Kir6.2 channel undergo negative cooperativity in ATP binding and positive cooperativity in channel gating. The ligand binding was coupled to the gating mechanism in the same subunit and neighboring subunits, although the intrasubunit coupling was more effective. These results are well described with the operational model which we have applied to ion channel studies for the first time. By manipulating the relative distance and the interaction of two transmembrane helices, the inner helix bundle of crossing was found to not only serve as a gate but also determine the consequence of ligand binding. ion channel subunit Stoichiometry ligand binding channel gating binding-gating coupling subunit coordination subunit cooperativity Kir1.1 Kir6.2 pH dependent gating ATP dependent gating. Biology, general
139	Microchannel enhanced neuron-computer interface: design, fabrication, biophysics of signal generation, signal strength optimization, and its applications to ion-channel screening and basic neuroscience research Wang, Ling 15 December 2011 (has links) En el presente trabajo, utilizamos técnicas de microfabricación, simulaciones numéricas, experimentos de electrofisiología para explorar la viabilidad en me- jorar la interface ordenador-neurona a través de microcanales, y la biofísica para la generación de señales en los dispositivos con microcanales. También demos- tramos que los microcanales pueden ser usados como una técnica prometedora con alto rendimiento en el muestreo automático de canales iónicos a nivel subce- lular. Finalmente, se ha diseñado, fabricado y probado el micropozo-microcanal como modificación adicional a los arreglos de multielectrodos, permitiendo una alta ganancia en la relación señal/ ruido (en inglés Signal to Noise Ratio SNR), y el registro de múltiples-lugares en poblaciones de baja densidad de redes neu- ronales del hipocampo in vitro. Primero, demostramos que son de alto rendimiento los microcanales de bajo costo con interface neurona-electrodo, para el registro extracelular de la activi- dad neuronal con baja complexidad, por periodos estables de larga duración y con alta ganancia SNR. En seguida, se realiza un estudio mediante experimentos y simulaciones nu- méricas de la biofísica para la generación de las señales obtenidas de los dispositi- vos con microcanales. Basados en los resultados, racionalizamos y demostramos como es que la longitud del canal (siendo 200 μm) y la sección transversal del microcanal (siendo 12 μm2) canaliza a los potenciales de acción para estar dentro del rango de milivolts. A pesar del bajo grado de complexidad envuelto en la fabricación y aplicación, los dispositivos con microcanales otorgan una sola media de valor SNR de 101 76, lo cual es favorablemente comparable con la SNR que se obtiene de desarrollos recientes que emplean electrodos curados con CNT y Si-NWFETs. Más aún, nosotros demostramos que el microcanal es una técnica promete- dora para el alto rendimiento del muestro automático de canales iónicos a nivel subcelular: (1) Información experimental y simulaciones numéricas sugieren que las señales registradas sólo afectan los parches membranales localizados dentro del microcanal o alrededor de 100 μm de las entradas del microcanal. (2) La transferencia de masa de los componentes químicos en los microcanales fue ana- lizada por experimentos y simulaciones FEM. Los resultados muestran que los microcanales que contienen glía y tejido neuronal pueden funcionar como barre- ra de fluido/química. Los componentes químicos pueden ser solamente aplicados a diferentes compartimentos a nivel subcelular. Finalmente, basado en simulaciones numéricas y resultados experimentales, se propone que del micropozo-microcanal, obtenido de la modificación de MEA (MWMC-MEA), la longitud óptima del canal debe ser 0,3 mm y la posición 1 óptima del electrodo intracanal, hacia la entrada más cercana del microcanal, debe ser 0,1 mm. Nosotros fabricamos un prototipo de MWMC-MEA, cuyo hoyo pasante sobre las películas de Polydimethylsiloxane (PDMS) fue microtrabajado a través de la técnica de grabados reactivos de plasma de iones. La baja densidad del cultivo (57 neuronas /mm2) en el MWMC-MEAs permitió que las neuronas vivieran al menos 14 días, con lo que la señal neuronal con la máxima SNR obtenida fue de 142. 2 / In this present work, we used microfabrication techniques, numerical simulations, electrophysiological experiments to explore the feasibility of enhancing neuron-computer interfaces with microchannels and the biophysics of the signal generation in microchannel devices. We also demonstrate the microchannel can be used as a promising technique for high-throughput automatic ion-channel screening at subcellular level. Finally, a microwell-microchannel enhanced multielectrode array allowing high signal-to-noise ratio (SNR), multi-site recording from the low-density hippocampal neural network in vitro was designed, fabricated and tested. First, we demonstrate using microchannels as a low-cost neuron-electrode interface to support low-complexity, long-term-stable, high SNR extracellular recording of neural activity, with high-throughput potential. Next, the biophysics of the signal generation of microchannel devices was studied by experiments and numerical simulations. Based on the results, we demonstrate and rationalize how channels with a length of 200 μm and channel cross section of 12 μm2 yielded spike sizes in the millivolt range. Despite the low degree of complexity involved in their fabrication and use, microchannel devices provided a single-unit mean SNR of 101 76, which compares favourably with the SNR obtained from recent developments employing CNT-coated electrodes and Si-NWFETs. Moreover, we further demonstrate that the microchannel is a promising technique for high-throughput automatic ion-channel screening at subcellular level: (1) Experimental data and numerical simulations suggest that the recorded signals are only affected by the membrane patches located inside the microchannel or within 100 μm to the microchannel entrances. (2) The mass transfer of chemical compounds in microchannels was analyzed by experiments and FEM simulations. The results show that the microchannel threaded by glial and neural tissue can function as fluid/chemical barrier. Thus chemical compounds can be applied to different subcellular compartments exclusively. Finally, a microwell-microchannel enhanced MEA (MWMC-MEA), with the optimal channel length of 0.3 mm and the optimal intrachannel electrode position of 0.1 mm to the nearest channel entrance, was proposed based on numerical simulation and experiment results. We fabricated a prototype of the MWMCMEA, whose through-hole feature of Polydimethylsiloxane film (PDMS) was micromachined by reactive-ion etching. The low-density culture (57 neurons/mm2) were survived on the MWMC-MEAs for at least 14 days, from which the neuronal signal with the maximum SNR of 142 was obtained. Microchannel Multi electrode array MEA Neuron-computer interface Biophysics Diffusion Pharmacology Numerical simulation Compartment model FEM Ion channel 4-AP 621.3
140	Neural dynamics in reconfigurable silicon Basu, Arindam 26 March 2010 (has links) This work is a first step towards a long-term goal of understanding computations occurring in the brain and using those principles to make more efficient machines. The traditional computing paradigm calls for using digital supercomputers to simulate large scale brain-like neural networks resulting in large power consumption which limits scalability or model detail. For example, IBM's digital simulation of a cat brain with simplistic neurons and synapses consumes power equivalent to that of a thousand houses! Instead of digital methods, this work uses analog processing concepts to develop scalable, low-power silicon models of neurons which have been shown to be around ten thousand times more power efficient. This has been achieved by modeling the dynamical behavior of Hodgkin-Huxley (H-H) or Morris-Lecar type equations instead of modeling the exact equations themselves. In particular, the two silicon neuron designs described exhibit a Hopf and a saddle-node bifurcation. Conditions for the bifurcations allow the identification of correct biasing regimes for the neurons. Also, since the hardware neurons compute in real time, they can be used for dynamic clamp protocols in addition to computational experiments. To empower this analog implementation with the flexibility of a digital simulation, a family of field programmable analog array (FPAA) architectures have been developed in 0.35 um CMOS that provide reconfigurability in the network of neurons as well as tunability of individual neuron parameters. This programmability is obtained using floating-gate (FG) transistors. The neurons are organized in blocks called computational analog blocks (CAB) which are embedded in a programmable switch matrix. An unique feature of the architecture is that the switches, being FG elements, can be used also for computation leading to more than 50,000 analog parameters in 9 sq. mm. Several neural systems including central pattern generators and coincidence detectors are demonstrated. Also, a separate chip that is capable of implementing signal processing algorithms has been designed by modifying the CAB elements to include transconductors, multipliers etc. Several systems including an AM demodulator and a speech processor are presented. An important contribution of this work is developing an architecture for programming the FG elements over a wide dynamic range of currents. An adaptive logarithmic transimpedance amplifier is used for this purpose. This design provides a general solution for wide dynamic range current measurement with a low power dissipation and has been used in imaging chips too. A new generation of integrated circuits have also been designed that are 25 sq. mm in area and contain several new features including adaptive synapses and support for smart sensors. These designs and the previous ones should allow prototyping and rapid development of several neurally inspired systems and pave the path for the design of larger and more complex brain like adaptive neural networks. Field programmable analog array Floating-gate Ion-channel dynamics Wide dynamic range sensing Bifurcation Programmable analog VLSI Signal processing Digital computer simulation Neural networks (Computer science)

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