Donald D. Samulack scite author profile

1. The membrane properties and synaptic inputs of interneurons, located at the stratum (s.) lacunosum-moleculare and radiatum border (L-M) of the CA1 region, were examined with the use of current-clamp whole-cell recordings in rat hippocampal slices. 2. Biocytin-labeled L-M interneurons had nonpyramidal somata and aspinous, often beaded, dendrites that arborized in s. lacunosum-moleculare and radiatum, sometimes as far as s. moleculare of the dentate gyrus. Their axon coursed and branched in s. lacunosum-moleculare and radiatum. Axon collaterals were also observed traversing the hippocampal fissure and arborizing in s. moleculare of the dentate gyrus and s. radiatum of the CA3 region. 3. Several membrane properties of interneurons were typically nonpyramidal: they had large input resistances, short-duration action potentials followed by prominent fast afterhyperpolarizations, and responded to hyperpolarizing current pulses with little membrane rectification. L-M interneurons showed significant anodal break responses, and their mean membrane time constant was 33 ms. After-depolarizations elicited by subthreshold depolarizing current pulses were larger in amplitude and decayed more slowly at depolarized than hyperpolarized membrane potentials. 4. The majority of L-M interneurons (35 of 49 cells) were silent at resting membrane potentials, whereas other displayed either spontaneous single action potentials (n = 12) or rhythmic bursts (n = 2). The rhythmic bursts were insensitive to the N-methyl-D-aspartate (NMDA) and non-NMDA excitatory amino acid receptor antagonists, 2-amino-5-phosphonopentanoic acid (AP-5; 50 microM) and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 20 microM), respectively. Both spontaneous single action potentials and burst firing were blocked by membrane hyperpolarization, suggesting that they were intrinsically rather than synaptically generated. 5. L-M interneurons responded with regular sustained firing to depolarizing current pulses at resting membrane potential. However, at more hyperpolarized membrane potentials (near -75 mV), depolarizing current pulses elicited action-potential firing with a delayed onset. This suggests that voltage-sensitive, transient outward currents may be activated in L-M interneurons from hyperpolarized membrane potentials. 6. Electrical stimulation of s. radiatum or lacunosum-moleculare elicited predominantly long-duration excitatory postsynaptic potentials (EPSPs; n = 20 cells), or both EPSPs and inhibitory postsynaptic potentials (IPSPs; n = 17 cells). In most L-M interneurons (35/37), with increasing intensities, up to two action potentials were elicited. Occasionally, larger bursts (3-5 action potentials) were observed (n = 2). 7. The multiphasic components of the synaptic responses became more evident when stimulations were repeated at different membrane potentials.(ABSTRACT TRUNCATED AT 400 WORDS)

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Tissue transplants in primates for upper extremity reconstruction: A preliminary report

Daniel

Egerszegi

Samulack

et al. 1986

The Journal of Hand Surgery

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Topographic Organization of Baboon Primary Motor Cortex: Face, Hand, Forelimb, and Shoulder Representation

Waters

Samulack

Dykes

et al. 1990

Somatosensory & Motor Research

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(1) The fine details of the motor organization of the forelimb, face, and tongue representation of the baboon (Papio h. anubis) primary motor cortex were studied in four adult animals, using intracortical microstimulation (ICMS). (2) A total of 293 electrode penetrations were made. ICMS was delivered to 10,052 sites, and of these, 6,186 sites were verified to have been located within the grey matter. Motor effects were evoked from 30% of these sites. (3) The baboon motor cortex is confined, in large part, to the cortical tissue lying along the anterior bank of the central sulcus. When the electrode penetrations were confined to the precentral gyrus, few sites were capable of evoking movement when stimulated by currents of 40 microA or less. (4) The details of the motor maps varied among the four animals; nonetheless, a general topographic organization existed, with the tongue musculature being represented most laterally, followed by a medial progression of the face, digits, wrist, forearm, and shoulder. Within the representation of a given body part, the muscles were organized as a mosaic, wherein the same muscle was multiply represented. (5) A zone of unresponsive cortex was observed to lie consistently between the face and forelimb representation in all four animals. Repeated electrode penetrations within the unresponsive zone failed to elicit muscle contractions even with stimulating currents as high as 80 microA. (6) Our results suggest that the baboon motor cortex is topographically organized; however, embedded within this overall pattern lies a fine-grained mosaic incorporating multiple representations of the same muscle.

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Hyperpolarizing synaptic potentials evoked in CA1 pyramidal cells by glutamate stimulation of interneurons from the oriens/alveus border of rat hippocampal slices. II. sensitivity to GABA antagonists

Samulack

Lacaille

1993

Hippocampus

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The receptor type mediating the inhibitory postsynaptic potentials (glut-IPSPs), recorded in CA1 pyramidal cells, as a result of glutamate stimulation of interneurons in stratum oriens near the alveus (O/A) was assessed and compared to the type mediating recurrent IPSPs evoked by recurrent activation of interneurons through glutamate stimulation of pyramidal cells in stratum pyramidale (PYR). In response to repetitive electrical stimulation, the peak amplitude of both the O/A glut-IPSP and the PYR glut-IPSP was attenuated (n = 5) in parallel to the reduction in amplitude of the early and late components of the electrically evoked response (stimulus-evoked disinhibition). This suggested the involvement of GABAergic receptors and attested that the interneurons activated during glut-IPSPs were also involved in the circuitry of the electrically evoked IPSPs. The local application of the selective GABAA antagonist bicuculline (100-200 microM) to the slice resulted in a significant reduction in the amplitude of both the O/A (by 76.5%; n = 9) and PYR (by 86.2%; n = 5) glut-IPSPs, in parallel to a decrease of the electrically evoked early IPSP, but not of the late IPSP. The presence of the GABAB antagonist 2-hydroxy-saclofen (1 mM) was able to significantly reduce the amplitude of the O/A glut-IPSPs (by 27.5%; n = 7) and of the electrically evoked late IPSP, but not the PYR glut-IPSP (n = 3). Although the application of phaclofen (20 mM) to the slice reduced the amplitude of the O/A glut-IPSPs (n = 3), the reduction was not statistically significant. These results suggest that recurrent IPSPs elicited from activation of interneurons by stimulation of pyramidal cells are mediated solely via GABAA receptors. Inhibitory postsynaptic potentials elicited from stimulation of interneurons in O/A were also mediated mostly by GABAA receptors, but in addition, displayed a minor component mediated by GABAB receptors. Therefore, since a large proportion of interneurons in O/A are recurrently excited by pyramidal cells (Lacaille J-C et al., 1987, J Neurosci 7: 1979-1993), and since recurrent IPSPs appeared mediated by GABAA receptors, a subpopulation of interneurons activated from O/A might exist that do not receive recurrent excitation but can inhibit pyramidal cells via GABAB receptors.

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