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Intrinsic Membrane Properties (intrinsic + membrane_property)

Distribution by Scientific Domains
Medical Sciences50%
Life Sciences50%

Selected Abstracts

Neurons with distinctive firing patterns, morphology and distribution in laminae V,VII of the neonatal rat lumbar spinal cord

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 3 2003
Péter Szûcs
Abstract It is generally accepted that neurons in the ventral spinal grey matter, a substantial proportion of which can be regarded as constituents of the spinal motor apparatus, receive and integrate synaptic inputs arising from various peripheral, spinal and supraspinal sources. Thus, a profound knowledge concerning the integrative properties of interneurons in the spinal ventral grey matter appears to be essential for a fair understanding of operational principles of spinal motor neural assemblies. Using the whole cell patch clamp configuration in a correlative physiological and morphological experimental approach, here we demonstrate that the intrinsic membrane properties of neurons vary widely in laminae V,VII of the ventral grey matter of the neonatal rat lumbar spinal cord. Based on their firing patterns in response to depolarizing current steps, we have classified the recorded neurons into four categories: ,phasic', ,repetitive', ,single' and ,slow'. Neurons with firing properties characteristic of the ,phasic', ,repetitive' and ,single' cells have previously been reported also in the superficial and deep spinal dorsal horn, but this is the first account in the literature in which ,slow' neurons have been recovered and described in the spinal cord. The physiological heterogeneity in conjunction with the morphological correlation and distribution of neurons argues that different components of motor neural assemblies in the spinal ventral grey matter possess different signal processing characteristics. [source]

Rhythmogenesis in Vasopressin Cells

JOURNAL OF NEUROENDOCRINOLOGY, Issue 9 2004
C. H. Brown
Abstract Many neurones in the central nervous system possess intrinsic pattern-generating properties, including vasopressin magnocellular neurosecretory cells. Synaptic input to vasopressin cells is not rhythmically patterned and yet these neurones fire action potentials in a ,phasic' activity pattern comprised of alternating periods of activity and silence that each last tens of seconds. This review describes the intrinsic and extrinsic mechanisms that generate phasic activity in vasopressin cells, highlighting recent work that has shown phasic activity to result from feedback modulation of synaptic inputs, and of intrinsic membrane properties, by peptides released from the dendrites of vasopressin cells. [source]

Regulation of Kv channel expression and neuronal excitability in rat medial nucleus of the trapezoid body maintained in organotypic culture

THE JOURNAL OF PHYSIOLOGY, Issue 9 2010
Huaxia Tong
Principal neurons of the medial nucleus of the trapezoid body (MNTB) express a spectrum of voltage-dependent K+ conductances mediated by Kv1,Kv4 channels, which shape action potential (AP) firing and regulate intrinsic excitability. Postsynaptic factors influencing expression of Kv channels were explored using organotypic cultures of brainstem prepared from P9,P12 rats and maintained in either low (5 mm, low-K) or high (25 mm, high-K) [K+]o medium. Whole cell patch-clamp recordings were made after 7,28 days in vitro. MNTB neurons cultured in high-K medium maintained a single AP firing phenotype, while low-K cultures had smaller K+ currents, enhanced excitability and fired multiple APs. The calyx of Held inputs degenerated within 3 days in culture, having lost their major afferent input; this preparation of calyx-free MNTB neurons allowed the effects of postsynaptic depolarisation to be studied with minimal synaptic activity. The depolarization caused by the high-K aCSF only transiently increased spontaneous AP firing (<2 min) and did not measurably increase synaptic activity. Chronic depolarization in high-K cultures raised basal levels of [Ca2+]i, increased Kv3 currents and shortened AP half-widths. These events relied on raised [Ca2+]i, mediated by influx through voltage-gated calcium channels (VGCCs) and release from intracellular stores, causing an increase in cAMP-response element binding protein (CREB) phosphorylation. Block of VGCCs or of CREB function suppressed Kv3 currents, increased AP duration, and reduced Kv3.3 and c- fos expression. Real-time PCR revealed higher Kv3.3 and Kv1.1 mRNA in high-K compared to low-K cultures, although the increased Kv1.1 mRNA was mediated by a CREB-independent mechanism. We conclude that Kv channel expression and hence the intrinsic membrane properties of MNTB neurons are homeostatically regulated by [Ca2+]i -dependent mechanisms and influenced by sustained depolarization of the resting membrane potential. [source]

Synaptic Control Of Motoneuron Excitability In Rodents: From Months To Milliseconds

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 1-2 2000
Gd Funk
SUMMARY 1. Motoneurons (MN) shape motor patterns by transforming inputs into action potential output. This transformation, excitability, is determined by an interaction between synaptic inputs and intrinsic membrane properties. Excitability is not static, but changes over multiple time scales. The purpose of the present paper is to review our recent data on synaptic factors important in the dynamic control of MN excitability over time scales ranging from weeks to milliseconds. 2. Developmental changes in modulation of MN excitability are well established. Noradrenergic potentiation of hypoglossal (XII) MN inspiratory activity in rhythmically active medullary slice preparations from rodents increases during the first two postnatal weeks. This is due to increasing ,1 - and ,-adrenoceptor excitatory mechanisms and to a decreasing inhibitory mechanism mediated by ,2 -adrenoceptors. Over a similar period, ATP potentiation of XII inspiratory activity does not change. 3. Motoneuron excitability may also change on a faster time scale, such as between different behaviours or different phases of a behaviour. Examination of this has been confounded by the fact that excitatory synaptic drives underlying behaviour can obscure smaller concurrent changes in excitability. Using the rhythmically active neonatal rat brain-stem,spinal cord preparation, we blocked excitatory inspiratory drive to phrenic MN (PMN) to reveal a reduction in PMN excitability specific to the inspiratory phase that: (i) arises from an inhibitory GABAergic input; (ii) is not mediated by recurrent pathways; and (iii) is proportional to and synchronous with the excitatory inspiratory input. We propose that the proportionality of the concurrent inhibitory and excitatory drives provides a means for phase- specific modulation of PMN gain. 4. Modulation across such diverse time scales emphasizes the active role that synaptic factors play in controlling MN excitability and shaping behaviour. [source]