Cholinergic modulation of epileptiform activity in the developing rat neocortex

The effects of carbachol on picrotoxin-induced epileptiform activity and membrane properties of neurons in the developing rat neocortex were examined in an in vitro slice preparation. Intracellular recordings were obtained in layer II–III neurons of slices prepared from rats 9–21 days of age. Epileptiform activity in 9- to 14-day-olds consisted of a sharply rising, sustained (10–30 s) membrane depolarization with superimposed action potentials. Bath application of carbachol (5–50 μM) raised the threshold for evoking epileptiform activity but, when such responses were evoked, their underlying depolarizations were increased in amplitude. Orthodromic stimulation in slices from 15- to 21-day-old animals evoked a prolonged epileptiform burst response that triggered an episode of spreading depression (SD). Carbachol reduced epileptiform responses and suppressed the occurrence of SD. It did not significantly affect the resting membrane potential or the height of the action potential but decreased the rheobase current needed to evoke an action potential and increased the input resistance. All effects of carbachol were antagonized by atropine (1 μM). These results indicate that carbachol has both pre- and postsynaptic effects in the developing neocortex and can significantly modulate neuronal excitability in the immature nervous system

Actions of Histrionicotoxin on Acetylcholine Receptors

The effects of histrionicotoxin have been evaluated at the rat neuromuscular junction, the eel electroplaque and on the central nervous system of the cat, and have been shown to reduce markedly the response to acetylcholine or carbamylcholine. This toxin does not inhibit the binding of acetylcholine to Torpedo membrane fragments rich in acetylcholine receptor .protein, but rather augments its affinity for the receptor site. These findings suggest an accentuation of a desensitization phenomenon or a block of ionic channels

Actions of Histrionicotoxin on Acetylcholine Receptors

The effects of histrionicotoxin have been evaluated at the rat neuromuscular junction, the eel electroplaque and on the central nervous system of the cat, and have been shown to reduce markedly the response to acetylcholine or carbamylcholine. This toxin does not inhibit the binding of acetylcholine to Torpedo membrane fragments rich in acetylcholine receptor .protein, but rather augments its affinity for the receptor site. These findings suggest an accentuation of a desensitization phenomenon or a block of ionic channels

Non-invasive detection of animal nerve impulses with an atomic magnetometer operating near quantum limited sensitivity

Magnetic fields generated by human and animal organs, such as the heart, brain and nervous system carry information useful for biological and medical purposes. These magnetic fields are most commonly detected using cryogenically-cooled superconducting magnetometers. Here we present the frst detection of action potentials from an animal nerve using an optical atomic magnetometer. Using an optimal design we are able to achieve the sensitivity dominated by the quantum shot noise of light and quantum projection noise of atomic spins. Such sensitivity allows us to measure the nerve impulse with a miniature room-temperature sensor which is a critical advantage for biomedical applications. Positioning the sensor at a distance of a few millimeters from the nerve, corresponding to the distance between the skin and nerves in biological studies, we detect the magnetic field generated by an action potential of a frog sciatic nerve. From the magnetic field measurements we determine the activity of the nerve and the temporal shape of the nerve impulse. This work opens new ways towards implementing optical magnetometers as practical devices for medical diagnostics.Comment: Main text with figures, and methods and supplementary informatio

Changes of intracellular sodium and potassium ion concentrations in frog spinal motoneurons induced by repetitive synaptic stimulation

A post-tetanic membrane hyperpolarization following repetitive neuronal activity is a commonly observed phenomenon in the isolated frog spinal cord as well as in neurons of other nervous tissues. We have now used double-barrelled Na+- and K+-ion-sensitive microelectrodes to measure the intracellular Na+- and K+-concentrations and also the extracellular K+-concentration of lumbar spinal motoneurons during and after repetitive stimulation of a dorsal root. The results show that the posttetanic membrane hyperpolarization occurred at a time when the intracellular [Na+] reached its maximal value, intracellular [K+] had its lowest level and extracellular [K+] was still elevated. The hyperpolarization was blocked by ouabain and reduced by Li+. These data support the previous suggestion that an electrogenic Na+/K+ pump mode may be the mechanism underlying the post-tetanic membrane hyperpolarization

Amygdaloid Kindling and the GABA System

The effect of increased brain GABA levels on fully kindled amygdala seizures was investigated in Long-Evans rats. The newly synthesized GABA-transaminase inhibitor, -Γ-acetylenic GABA (GAG) administered on four consecutive days (100 mg/kg, followed by 50 mg/kg, i.p.) was found to either significantly reduce, or eliminate entirely, the behavioral seizures normally produced by amygdala stimulation. The effect is seen after the first injection of GAG although its magnitude was greater on subsequent days. Behavioral seizures reappeared 2 to 3 days after termination of GAG treatment. The duration of electrographic seizures (self-sustained amygdala after-discharge) was either unchanged or greater on the first day of GAG treatment, but was briefer on subsequent days. The duration of afterdischarges returned to normal levels 1 to 2 days earlier than the behavioral seizures after the termination of GAG. Picrotoxin (1.5-2 mg/kg, i.p.) did not antagonize either electrographic or behavioral effects of inhibition produced with GAG. Electrical stimulation of amygdala delivered during the initial sedation stage induced by picrotoxin resulted in further regression of kindled seizures in the majority of animals. Although in doses employed, GAG alleviates amygdaloid-kindled seizures its use requires caution in view of its ability to reduce arousal level. RÉSUMÉ L'effet de l'ÉlÉvation des taux cÉrÉbraux de GABA sur les crises amygdaliennes par effet d'embrasement complet a ÉtÉÉtudiÉ chez des rats Long-Evans. l'injection pendant 4 jours consÉcutifs de 100 mg/kg suivis de 50 mg/kg i.p. d'un inhibiteur de la GABA. Transaminase nouvellement synthÉtisÉ (Γ-acetylenic GABA ou GAG) a significativement rÉduit ou mÊme supprimÉ les crises normalement provoquÉes par la stimulation amygdalienne. l'effet est observÉ aprÈs la premiere injection de GAG, mais son importance s'accroit les jours suivants. Les crises rÉapparaissent 2 ou 3 jours aprÈs la fin du traitement au GAG. Du point de vue Électrographique, la durÉe de la postdÉcharge amygdalienne autoentretenue est inchingÉe ou accrue le premier jour du traitement, mais elle diminue les jours suivants pour retourner À la normale un ou deux jours avant que les crises ne rÉapparaissent aprÈs la fin de ('administration du GAG. l'injection de picrotoxine (1.5-2 mg/kg i.p.) ne s'oppose pas aux effets inhibiteurs du GAG sur les crises ou leur accompagnement EEG. La stimulation Électrique de l'amygdala pendant l'Étape sÉdative initiate induite par la picrotoxine provoque une rÉgression supplÉmentaire des crises d'embrasement chez la majoritÉ des animaux. Bien que, aux doses utilisÉes, le GAG attÉnue les crises amyg-daliennes d'embrasement, son utilisation nÉcessite des prÉcautions compte tenu de sa tendance À rÉduire le niveau d'Éveil. RESUMEN En ratas Long-Evans se ha investigado el efecto del aumento de los niveles cerebrales de GABA, sobre los ataques originados en la amÍgdala totalmente condicionada, (Kindling). El recientemente sintetizado in-hibidor de la GABA transaminasa, Γ-acetilÉnico GABA (GAG), redujo significativamente o eliminÓ totalmente las crisis de comportamiento que habitualmente se producen con la estimulaciÓn de la amÍgdala. El efecto se observa despuÉs de la primera in-yecciÓn de GAG pero su magnitud aumentÓ en dias subsiguientes. Las crisis de comportamiento reaparecieron a los 2–3 dÍas de la interrupciÓn del tratamiento con GAG. La duraciÓn de los ataques electrogrÁficos (perservaciÓn de la post-descarga de la amigdala) no se modificÓ, o incluso aumentÓ, en el primer dia de la administraciÓn de GAG pero se redujo en los dias siguientes. La duraciÓn de las post-descargas volviÓ a sus niveles normales 1 o 2 dias antes que la reapariciÓn de las crisis de comportamiento una vez terminado el tratamiento con GAG. La picrotoxina (1.5-2 mg/kg, i.p.) no antagonizÓ los efectos inhibitorios producidos por el GAG sobre el electroencefalograma o las crisis de comportamiento. La estimulaciÓn elÉctrica sobre la amÍgdala, aplicada durante la fase de sedaciÓn inicial inducida por la picrotoxina, condujo a una regresiÓn aÚn mÁs intensa de las crisis condicionadas, en la mayorÍa de los animales. A pesar de que, con las dosis utilizadas, el GAG alivia las crisis de la amÍgdala previamente condicionada, se requiere gran precauciÓn en su utilizaciÓn en vista de su propiedad de reducir el nivel del despertar. ZUSAMMENFASSUNG Die Wirkung erhÖhter GABA-Spiegel des Gehirns auf AmygdalonkrÄmpfe nach Kindling wurden bei Long-Evans-Ratten untersucht. Der neuerdings synthetisierte GABA-TYansaminasen-Inhibitor, Gamma-Acetylen-GABA (GAG) wurde an 4 aufeinander-folgenden Tagen in einer Dosis von 100 mg/kg und anschlieliend 50 mg/kg i.p. verabfolgt. Er reduzierte entweder signifikant oder eliminierte vÖllig die anfalls-weisen VerhaltensÄnderungen, die normalerweise durch Stimulation des Amygdalon produziert wurden. Die Wirkung ist nach der Erstinjektion des GAG zu beobachten, obgleich ihr Ausmaß an folgenden Tagen grÖßer war. Die VerhaltensanfÄlle kamen 2 bis 3 Tagen nach Beendigung der GAG-Behandlung wieder. Die Dauer der elektrographischen AnfÄlle (sich selbst un-terhaltende Amydalonnachentladungen) blieben entweder gleich oder sie wurden grÖßer am 1. Tag der GAG-Behandlung, wurden aber kÜrzer an folgenden Tagen. Die Dauer der Nachentladungen nor-malisierte sich 1 bis 2 Tage frÜher als die VerhaltensanfÄlle nach Beendigung des GAG verschwanden. Picrotoxin (1.5 bis 2 mg/kg i.p.) wirken nicht als Antagonist gegenÜber der durch GAG produzierten Hemmung der elektrographischen-oder Verhalten-seffekte. Die elektrische Stimulierung des Amygdalon wÄhrend der initialen Sedierung nach Picrotoxin ver-ursachte bei der Mehrzahl der Tiere einen weiteren RÜckgang der durch Kindling entstandenen AnfÄlle. Obgleich das GAG in den verwandten Dosen, die durch Kindling des Amygdalon erzeugten KrÄmpfe leichter ablaufen lUßt, erfordert seine Anwendung Vorsicht hinsichtlich seiner FÄhigkeit, das Erreg-barkeitsniveau zu senken.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/66112/1/j.1528-1157.1980.tb04058.x.pd

Effects of lithium on electrical activity and potassium ion distribution in the vertebrate central nervous system

Three different regions of the vertebrate central nervous system maintained in vitro (frog spinal cord, guinea pig olfactory cortex and hippocampus) have been used to investigate how Li+ influences membrane potential, membrane resistance, action potentials, synaptic potentials and the transmembrane K+-distribution of neurons and glial cells. In view of the therapeutic action of Li+ in manicdepressive disease, a special effort was made to determine the threshold concentration for the actions of Li+ on the parameters described above. It was observed that Li+ induced a membrane depolarization of both neurons and glial cells, a decrease of action potential amplitudes, a facilitation of monosynaptic excitatory postsynaptic potentials and a depression of polysynaptic reflexes. The membrane resistance of neurons was not altered. Li+ also induced an elevation of the free extracellular potassium concentration and a decrease of the free intracellular potassium concentration. Furthermore, in the presence of Li+ a slowing of the recovery of the membrane potential of neurons and glial cells, and of the extracellular potassium concentration after repetitive synaptic stimulation was observed. The threshold concentrations for the effects of Li+ were below 5 mmol/l in the frog spinal cord and below 2 mmol/l in the guinea pig olfactory cortex and hippocampus. The basic mechanism underlying the action of Li+ may be an interaction with the transport-function of the Na+/K+ pump

Effects of Chronic Ethanol Treatment on Neocortex

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/66043/1/j.1530-0277.1986.tb05133.x.pd