Your search keyword '"MARMOSET CALLITHRIX-JACCHUS"' showing total 4 results

1. High-resolution frequency tuning but not temporal coding in the human cochlea

Author

Christian Desloovere, Eric Verschooten, and Philip X. Joris

Subjects

Life Sciences & Biomedicine - Other Topics, PITCH PERCEPTION, Male, High resolution, Monkeys, SPEECH-PERCEPTION, 01 natural sciences, Macaque, 0302 clinical medicine, Nerve Fibers, Short Reports, Hearing, Animal Cells, Medicine and Health Sciences, Biology (General), 010301 acoustics, Mammals, Neurons, Coding Mechanisms, biology, General Neuroscience, Resolution (electron density), Eukaryota, Limiting, Animal Models, Healthy Volunteers, Cochlea, Sound, Experimental Organism Systems, Vertebrates, Inner Ear, Female, Anatomy, Cellular Types, General Agricultural and Biological Sciences, Life Sciences & Biomedicine, Primates, Adult, Biochemistry & Molecular Biology, AUDITORY-NERVE, QH301-705.5, MARMOSET CALLITHRIX-JACCHUS, Research and Analysis Methods, Rodents, General Biochemistry, Genetics and Molecular Biology, NEURAL PHASE-LOCKING, GUINEA-PIG, 03 medical and health sciences, Young Adult, biology.animal, 0103 physical sciences, OTOACOUSTIC EMISSIONS, Old World monkeys, otorhinolaryngologic diseases, Animals, Humans, Biology, Cochlear Nerve, Computational Neuroscience, Science & Technology, General Immunology and Microbiology, PATHOLOGICAL HUMAN, business.industry, Organisms, Biology and Life Sciences, Computational Biology, Pattern recognition, Cell Biology, Macaca mulatta, Acoustic Stimulation, Ears, Cellular Neuroscience, COMPLEX TONES, Amniotes, Chinchillas, Animal Studies, Artificial intelligence, business, Head, 030217 neurology & neurosurgery, Coding (social sciences), FINE-STRUCTURE, Neuroscience

Abstract

Frequency tuning and phase-locking are two fundamental properties generated in the cochlea, enabling but also limiting the coding of sounds by the auditory nerve (AN). In humans, these limits are unknown, but high resolution has been postulated for both properties. Electrophysiological recordings from the AN of normal-hearing volunteers indicate that human frequency tuning, but not phase-locking, exceeds the resolution observed in animal models., Author summary The coding of sounds by the cochlea depends on two primary properties: frequency selectivity, which refers to the ability to separate sounds into their different frequency components, and phase-locking, which refers to the neural coding of the temporal waveform of these components. These properties have been well characterized in animals using neurophysiological recordings from single neurons of the auditory nerve (AN), but this approach is not feasible in humans. As a result, there is considerable controversy as to how these two properties may differ between humans and the small animals typically used in neurophysiological studies. It has been proposed that humans excel both in frequency selectivity and in the range of frequencies over which they have phase-locking. We developed a technique to quantify these properties using mass potentials from the AN, recorded via the middle ear in human volunteers with normal hearing. We find that humans have unusually sharp frequency tuning but that the upper frequency limit of phase-locking is at best similar to—and more likely lower than—that of the nonhuman animals conventionally used in experiments.

Published

2018

2. Rabbit forebrain cholinergic system

Subjects

confocal laser scanning microscopy, CORTICAL PROJECTION PATTERNS, PRECURSOR PROTEIN EXPRESSION, MARMOSET CALLITHRIX-JACCHUS, IMMUNOHISTOCHEMICAL LOCALIZATION, choline acetyltransferase, NADPH-DIAPHORASE, HUMAN BASAL FOREBRAIN, DIAGONAL BAND, nervous system, calcium-binding protein, P75 NEUROTROPHIN RECEPTOR, p75 low-affinity neurotrophin receptor, mapping, MONOCLONAL-ANTIBODIES, GROWTH-FACTOR RECEPTOR

Abstract

Although the rabbit brain, in particular the basal forebrain cholinergic system, has become a common model for neuropathological changes associated with Alzheimer's disease, detailed neuroanatomical studies on the morphological organization of basal forebrain cholinergic nuclei and on their output pathways are still awaited. Therefore, we performed quantitative choline acetyltransferase (ChAT) immunocytochemistry to localize major cholinergic nuclei and to determine the number of respective cholinergic neurons in the rabbit forebrain. The density of ChAT-immunoreactive terminals in layer V of distinct neocortical territories and in hippocampal subfields was also measured. Another cholinergic marker, the low-affinity neurotrophin receptor (p75(NTR)), was also employed to identify subsets of cholinergic neurons. Double-immunofluorescence labeling of ChAT and p75(NTR), calbindin D-28k (CB), parvalbumin, calretinin, neuronal nitric oxide synthase (nNOS), tyrosine hydroxylase, or substance P was used to elucidate the neuroanatomical borders of cholinergic nuclei and to analyze the neurochemical complexity of cholinergic cell populations. Cholinergic projection neurons with heterogeneous densities were found in the medial septum, vertical and horizontal diagonal bands of Broca, ventral pallidum, and magnocellular nucleus basalis (MBN)/substantia innominata (SI) complex; cholinergic interneurons were observed in the caudate nucleus, putamen, accumbens nucleus, and olfactory tubercule, whereas the globus pallidus was devoid of cholinergic nerve cells. Cholinergic interneurons were frequently present in the hippocampus and to a lesser extent in cerebral cortex. Cholinergic projection neurons, except those localized in SI, abundantly expressed p75(NTR), and a subset of cholinergic neurons in posterior MBN was immunoreactive for CB and nNOS. A strict laminar distribution pattern of cholinergic terminals was recorded both in the cerebral cortex and in CA1-CA3 and dentate gyrus of the hippocampus. In summary, the structural organization and chemoarchitecture of rabbit basal forebrain may be considered as a transition between that of rodents and that of primates. (C) 2003 Wiley-Liss, Inc.

Published

2003

3. Rabbit forebrain cholinergic system

Subjects

confocal laser scanning microscopy, CORTICAL PROJECTION PATTERNS, PRECURSOR PROTEIN EXPRESSION, MARMOSET CALLITHRIX-JACCHUS, IMMUNOHISTOCHEMICAL LOCALIZATION, choline acetyltransferase, NADPH-DIAPHORASE, HUMAN BASAL FOREBRAIN, DIAGONAL BAND, calcium-binding protein, P75 NEUROTROPHIN RECEPTOR, p75 low-affinity neurotrophin receptor, mapping, MONOCLONAL-ANTIBODIES, GROWTH-FACTOR RECEPTOR

Abstract

Although the rabbit brain, in particular the basal forebrain cholinergic system, has become a common model for neuropathological changes associated with Alzheimer's disease, detailed neuroanatomical studies on the morphological organization of basal forebrain cholinergic nuclei and on their output pathways are still awaited. Therefore, we performed quantitative choline acetyltransferase (ChAT) immunocytochemistry to localize major cholinergic nuclei and to determine the number of respective cholinergic neurons in the rabbit forebrain. The density of ChAT-immunoreactive terminals in layer V of distinct neocortical territories and in hippocampal subfields was also measured. Another cholinergic marker, the low-affinity neurotrophin receptor (p75(NTR)), was also employed to identify subsets of cholinergic neurons. Double-immunofluorescence labeling of ChAT and p75(NTR), calbindin D-28k (CB), parvalbumin, calretinin, neuronal nitric oxide synthase (nNOS), tyrosine hydroxylase, or substance P was used to elucidate the neuroanatomical borders of cholinergic nuclei and to analyze the neurochemical complexity of cholinergic cell populations. Cholinergic projection neurons with heterogeneous densities were found in the medial septum, vertical and horizontal diagonal bands of Broca, ventral pallidum, and magnocellular nucleus basalis (MBN)/substantia innominata (SI) complex; cholinergic interneurons were observed in the caudate nucleus, putamen, accumbens nucleus, and olfactory tubercule, whereas the globus pallidus was devoid of cholinergic nerve cells. Cholinergic interneurons were frequently present in the hippocampus and to a lesser extent in cerebral cortex. Cholinergic projection neurons, except those localized in SI, abundantly expressed p75(NTR), and a subset of cholinergic neurons in posterior MBN was immunoreactive for CB and nNOS. A strict laminar distribution pattern of cholinergic terminals was recorded both in the cerebral cortex and in CA1-CA3 and dentate gyrus of the hippocampus. In summary, the structural organization and chemoarchitecture of rabbit basal forebrain may be considered as a transition between that of rodents and that of primates. (C) 2003 Wiley-Liss, Inc.

Published

2003

4. Rabbit forebrain cholinergic system: Morphological characterization of nuclei and distribution of cholinergic terminals in the cerebral cortex and hippocampus

Author

Varga, C, Hartig, W., Grosche, J., Keijser, Jan N., Luiten, P.G.M., Seeger, J, Brauer, K, Harkany, T., and Neurobiology

Subjects

confocal laser scanning microscopy, CORTICAL PROJECTION PATTERNS, PRECURSOR PROTEIN EXPRESSION, MARMOSET CALLITHRIX-JACCHUS, IMMUNOHISTOCHEMICAL LOCALIZATION, choline acetyltransferase, NADPH-DIAPHORASE, HUMAN BASAL FOREBRAIN, DIAGONAL BAND, nervous system, calcium-binding protein, P75 NEUROTROPHIN RECEPTOR, p75 low-affinity neurotrophin receptor, mapping, MONOCLONAL-ANTIBODIES, GROWTH-FACTOR RECEPTOR

Abstract

Although the rabbit brain, in particular the basal forebrain cholinergic system, has become a common model for neuropathological changes associated with Alzheimer's disease, detailed neuroanatomical studies on the morphological organization of basal forebrain cholinergic nuclei and on their output pathways are still awaited. Therefore, we performed quantitative choline acetyltransferase (ChAT) immunocytochemistry to localize major cholinergic nuclei and to determine the number of respective cholinergic neurons in the rabbit forebrain. The density of ChAT-immunoreactive terminals in layer V of distinct neocortical territories and in hippocampal subfields was also measured. Another cholinergic marker, the low-affinity neurotrophin receptor (p75(NTR)), was also employed to identify subsets of cholinergic neurons. Double-immunofluorescence labeling of ChAT and p75(NTR), calbindin D-28k (CB), parvalbumin, calretinin, neuronal nitric oxide synthase (nNOS), tyrosine hydroxylase, or substance P was used to elucidate the neuroanatomical borders of cholinergic nuclei and to analyze the neurochemical complexity of cholinergic cell populations. Cholinergic projection neurons with heterogeneous densities were found in the medial septum, vertical and horizontal diagonal bands of Broca, ventral pallidum, and magnocellular nucleus basalis (MBN)/substantia innominata (SI) complex; cholinergic interneurons were observed in the caudate nucleus, putamen, accumbens nucleus, and olfactory tubercule, whereas the globus pallidus was devoid of cholinergic nerve cells. Cholinergic interneurons were frequently present in the hippocampus and to a lesser extent in cerebral cortex. Cholinergic projection neurons, except those localized in SI, abundantly expressed p75(NTR), and a subset of cholinergic neurons in posterior MBN was immunoreactive for CB and nNOS. A strict laminar distribution pattern of cholinergic terminals was recorded both in the cerebral cortex and in CA1-CA3 and dentate gyrus of the hippocampus. In summary, the structural organization and chemoarchitecture of rabbit basal forebrain may be considered as a transition between that of rodents and that of primates. (C) 2003 Wiley-Liss, Inc.

Published

2003