Effect of Midbrain and Pontine Tegmental Lesions on Audiogenic Seizures in Genetically Epilepsy‐Prone Rats

Browning, Ronald A.; Nelson, Daniel K.; Mogharreban, Namdar; Jobe, Phillip C.; Laird, Hugh E.

doi:10.1111/j.1528-1157.1985.tb05402.x

Cited by 93 publications

(28 citation statements)

References 11 publications

(14 reference statements)

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“…Some IC cortical cells project to deep layers of the superior colliculus (Tokunaga et al, 1984;Coleman and Clerici, 1987) and may be involved in the circuit mediating the appropriate orientation of head, eyes, and pinna movements (see Aitkin, 1985). Lesion and stimulation studies of the deep superior colliculus indicate that IC output generating the major components of the seizure behavior probably does not use this route (Wada et al, 1970;McCown et al, 1984;Browning et al, 1985;Browning, 1986). Other cells in the IC cortex form a "descending" projection to the pons and medulla, and it is interesting to note that bilateral lesions of a region of the pons called nucleus reticularis pontis oralis (RPO) significantly attenuates audiogenic convulsions (Browning et al, 1985).…”

Section: Activation Of Nmda Receptors and The Pds Phenomenonmentioning

confidence: 99%

“…Lesion and stimulation studies of the deep superior colliculus indicate that IC output generating the major components of the seizure behavior probably does not use this route (Wada et al, 1970;McCown et al, 1984;Browning et al, 1985;Browning, 1986). Other cells in the IC cortex form a "descending" projection to the pons and medulla, and it is interesting to note that bilateral lesions of a region of the pons called nucleus reticularis pontis oralis (RPO) significantly attenuates audiogenic convulsions (Browning et al, 1985). This would seem to implicate this descending pathway in seizure initiation; however, RPO is not the pontine region where colliculopontine fibers terminate (Bume et al, 1981;Faye-Lund, 1986).…”

Section: Activation Of Nmda Receptors and The Pds Phenomenonmentioning

confidence: 99%

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Anatomy and physiology of multipolar cells in the rat inferior collicular cortex using the in vitro brain slice technique

1992

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Coronal brain slices from 21–50-d-old hooded rats were used to characterize intracellular responses of cells in both the external and dorsal cortices of the inferior colliculus (IC). These cells could generate both sodium and calcium spikes. Depending on current amplitude, depolarizing current pulses could elicit either phasic or tonic firing patterns, with spike frequency adaptation. Spiking also occurred at the offset of a hyperpolarizing pulse. These patterns were due primarily to the activation of calcium conductances. Stimulation of the commissural pathway connecting the left and right IC produced a short-latency monosynaptic IPSP followed by an EPSP(s) and a late polysynaptic IPSP(s). Non-NMDA glutamate antagonists eliminated or reduced the amplitude of the EPSP and the late portion of the inhibition, while both IPSPs were blocked by GABAA antagonists. As described previously in guinea pig (Smith, 1986) and rat (Pierson et al., 1989), a large NMDA-mediated depolarizing event (paroxysmal depolarizing shift, or PDS) could be elicited by shocking the commissure of the IC in the presence of picrotoxin or bicuculline, NMDA, 4-aminopyridine, or in 0 Mg2+ Ringer's. The picrotoxin-induced PDS was significantly reduced or abolished in Ringer's containing aminophosphonovalerate. Cells displaying the responses described were labeled with neurobiotin. Those labeled are medium-sized multipolar cells. Their dendrites are usually spiny and can extend superficially up to the cortical surface. Their thin axons give rise to collaterals that branch profusely within the cortex. The main axons project laterally along the circumference of the IC or medially into the commissure separating the collicular hemispheres.

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Section: Activation Of Nmda Receptors and The Pds Phenomenonmentioning

confidence: 99%

Section: Activation Of Nmda Receptors and The Pds Phenomenonmentioning

confidence: 99%

Anatomy and physiology of multipolar cells in the rat inferior collicular cortex using the in vitro brain slice technique

1992

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“…Similar phenomena consisting of increases in the proportion of fast-wave sleep, linked with activation of the inferior colliculi, have been seen in rats, cats, and humans after repeated sessions of rhythmic auditory stimulation [19,20]. All these points provide grounds for the conclusion that the inferior colliculi in rats, acting via the relevant projections [22,28,34], may have a modulatory effect on the functioning of the centers triggering fast-wave sleep located in the area of the pons [30,37]. As demonstrated in our studies, the nature of these infl uences is far from unambiguous.…”

Section: Discussionmentioning

confidence: 70%

Effects of Stimulation of the Inferior Colliculi in Krushinskii–Molodkina Rats

Vataev

Mal’gina

Oganesyan

2015

Neurosci Behav Physi

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The inferior colliculi in rats of the Genetically Epile psyprone Rats (GEPR) strain are known to be the site at which epileptiform audiogenic convulsive seizures are initiated [24][25][26][27][28]35]. The role of the inferior colliculi in the formation of audiogenic paroxysmal reactions has not been studied in Krushinskii-Molodkina rats, which were developed and have been used in physiological studies in Russia [12,16]. The only data obtained show that convulsive responses to sound stimuli in rats of this strain are followed by decreases in the numbers of cells in the central nucleus of the inferior colliculi [6], while targeted implantation of embryonic striatal or cerebellar tissue into this structure decreased the intensity of audiogenic convulsions [8]. Furthermore, because of the wide use of Krushinskii-Molo dkina rats for studies of the actions of anticonvulsant agents [1,9,11,[13][14][15]18], there is an urgent need for more concrete explanations of the functional role of the inferior colliculi in the mechanisms of the formation and development of epileptiform convulsive manifestations in animals of this strain, as the similarities in audiogenic seizures between Krushinskii-Molodkina and GEPR rats does not suggest identity in the structural-functional mechanisms of their realization. Attention should be focused on the fact that Krushinskii-Molodkina rats are signifi cantly different from GEPR rats in terms of a number of biochemical parameters. Thus, Krushinskii-Molodkina rats have thyroid hyperfunction [7], while GEPR rats are hypothyroid during the neonatal period [32]. Animals of both strains also differ in terms of baseline (outside of audiogenic seizures) levels of various neurotransmitters. KrushinskiiMolodkina rats show increased dopamine and noradrenaline The effects of chemical and electrical stimulation of the central nucleus of the inferior colliculus on the generation and formation of convulsive manifestations and on the organization of sleep were studied in Krushinskii-Molodkina rats with an inherited predisposition to audiogenic convulsions. Microinjection of quinolinic acid (10 μg in 1 μl of distilled water) or electrical stimulation at a frequency of 70 Hz generated paroxysmal manifestations in the form of intense rotatory movement acts, similar to "wild running" of animals in the initial convulsion-free stage of audiogenic seizures. This provides grounds for suggesting that in Krushinskii-Molodkina rats the inferior colliculi are part of the neural network responsible for the generation and execution of the running stage during the formation of convulsive responses to sound stimuli. Application of these stimuli was also followed by a decrease in the total duration of fast-wave sleep during the poststimulus period. Conversely, electrical stimulation of the inferior colliculi at a frequency of 7 Hz on the background of deep slow-wave sleep induced episodes of fast-wave sleep in the rats; after 3-4 sessions of this stimulation producing this effect, there was an almost two-fold increase in th...

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“…In nonkindled rodents, full-blown audiogenic seizures do not usually induce epileptiform activity in the cortex [7,8,30,59,60], confirming the subcortical origin of these seizures. Acutely induced audiogenic seizures of moderate severity (i.e., generalized clonic seizures) are not accompanied by distinct cortical epileptiform activity [30], though the amygdala has been shown to be involved in the network of the clonic form of AS even in nonkindled GEPR-3s [61].…”

Section: Epileptiform Discharge Is a Hallmark Of Secondary Cortical Ementioning

confidence: 92%

Audiogenic kindling and secondary subcortico-cortical epileptogenesis: Behavioral correlates and electrographic features

Vinogradova

2017

Epilepsy & Behavior

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Effect of Midbrain and Pontine Tegmental Lesions on Audiogenic Seizures in Genetically Epilepsy‐Prone Rats

Cited by 93 publications

References 11 publications

Anatomy and physiology of multipolar cells in the rat inferior collicular cortex using the in vitro brain slice technique

Anatomy and physiology of multipolar cells in the rat inferior collicular cortex using the in vitro brain slice technique

Effects of Stimulation of the Inferior Colliculi in Krushinskii–Molodkina Rats

Audiogenic kindling and secondary subcortico-cortical epileptogenesis: Behavioral correlates and electrographic features

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