Your search keyword '"Restrepo, Diego"' showing total 10 results

1. γ Spike-Field Coherence in a Population of Olfactory Bulb Neurons Differentiates between Odors Irrespective of Associated Outcome.

Author

Anan Li, Gire, David H., and Restrepo, Diego

Subjects

OLFACTORY bulb, LABORATORY mice, ODORS, ANALYSIS of variance

Abstract

Studies in different sensory systems indicate that short spike patterns within a spike train that carry items of sensory information can be extracted from the overall train by using field potential oscillations as a reference (Kayser et al., 2012; Panzeri et al., 2014). Here we test the hypothesis that the local field potential (LFP) provides the temporal reference frame needed to differentiate between odors regardless of associated outcome. Experiments were performed in the olfactory system of the mouse (Mus musculus) where the mitral/tufted (M/T) cell spike rate develops differential responses to rewarded and unrewarded odors as the animal learns to associate one of the odors with a reward in a go-no go behavioral task. We found that coherence of spiking in M/T cells with the Y LFP (65 to 95 Hz) differentiates between odors regardless of the associated behavioral outcome of odor presentation. [ABSTRACT FROM AUTHOR]

Published

2015

2. Potential Role of Transient Receptor Potential Channel M5 in Sensing Putative Pheromones in Mouse Olfactory Sensory Neurons.

Author

Oshimoto, Arisa, Wakabayashi, Yoshihiro, Garske, Anna, Lopez, Roberto, Rolen, Shane, Flowers, Michael, Arevalo, Nicole, and Restrepo, Diego

Subjects

TRP channels, PHEROMONES, PHARMACOLOGY, CHEMORECEPTORS, OLFACTORY receptors, NEUROANATOMY, NEUROPHYSIOLOGY, SENSE organs, LABORATORY mice

Abstract

Based on pharmacological studies of chemosensory transduction in transient receptor potential channel M5 (TRPM5) knockout mice it was hypothesized that this channel is involved in transduction for a subset of putative pheromones in mouse olfactory sensory neurons (OSNs). Yet, in the same study an electroolfactogram (EOG) in the mouse olfactory epithelium showed no significant difference in the responses to pheromones (and odors) between wild type and TRPM5 knockout mice. Here we show that the number of OSNs expressing TRPM5 is increased by unilateral naris occlusion. Importantly, EOG experiments show that mice lacking TRPM5 show a decreased response in the occluded epithelia to putative pheromones as opposed to wild type mice that show no change upon unilateral naris occlusion. This evidence indicates that under decreased olfactory sensory input TRPM5 plays a role in mediating putative pheromone transduction. Furthermore, we demonstrate that cyclic nucleotide gated channel A2 knockout (CNGA2-KO) mice that show substantially decreased or absent responses to odors and pheromones also have elevated levels of TRPM5 compared to wild type mice. Taken together, our evidence suggests that TRPM5 plays a role in mediating transduction for putative pheromones under conditions of reduced chemosensory input. [ABSTRACT FROM AUTHOR]

Published

2013

3. Microvillous cells expressing IP3 receptor type 3 in the olfactory epithelium of mice C. C. Hegg et al. IP3R3 MV cells in the olfactory epithelium.

Author

Hegg, Colleen C., Jia, Cuihong, Chick, Wallace S., Restrepo, Diego, and Hansen, Anne

Subjects

INOSITOL phosphates, CELL receptors, OLFACTORY nerve, GREEN fluorescent protein, IMMUNOHISTOCHEMISTRY, EPITHELIUM, PURINERGIC receptors, LABORATORY mice

Abstract

Microvillous cells of the main olfactory epithelium have been described variously as primary olfactory neurons, secondary chemosensory cells or non-sensory cells. Here we generated an IP3R3 mouse in which the coding region for a fusion protein of tau and green fluorescent protein replaces the first exon of the Itpr3 gene. We provide immunohistochemical and functional characterization of the cells expressing IP3 receptor type 3 in the olfactory epithelium. These cells bear microvilli at their apex, and we therefore termed them IP3R3 MV cells. The cell body of these IP3R3 MV cells lies in the upper third of the main olfactory epithelium; a long thick basal process projects towards the base of the epithelium without penetrating the basal lamina. Retrograde labeling and unilateral bulbectomy corroborated that these IP3R3 MV cells do not extend axons to the olfactory bulb and therefore are not olfactory sensory neurons. The immunohistochemical features of IP3R3 MV cells varied, suggesting either developmental stages or the existence of subsets of these cells. Thus, for example, subsets of the IP3R3 MV cells make contact with substance P fibers or express the purinergic receptor P2X3. In addition, in recordings of intracellular calcium, these cells respond to ATP and substance P as well as to a variety of odors. The characterization of IP3R3 MV cells as non-neuronal chemoresponsive cells helps to explain the differing descriptions of microvillous cells in the literature. [ABSTRACT FROM AUTHOR]

Published

2010

4. Toward a Mouse Neuroethology in the Laboratory Environment.

Author

Oliva, Anthony M., Salcedo, Ernesto, Hellier, Jennifer L., Xuan Ly, Koka, Kanthaiah, Tollin, Daniel J., and Restrepo, Diego

Subjects

NEUROANATOMY, SMELL disorders, LABORATORY mice, PHENOTYPES, NEURONS, ANIMAL behavior, LABORATORIES

Abstract

In this report we demonstrate that differences in cage type brought unexpected effects on aggressive behavior and neuroanatomical features of the mouse olfactory bulb. A careful characterization of two cage types, including a comparison of the auditory and temperature environments, coupled with a demonstration that naris occlusion abolishes the neuroanatomical changes, lead us to conclude that a likely important factor mediating the phenotypic changes we find is the olfactory environment of the two cages. We infer that seemingly innocuous changes in cage environment can affect sensory input relevant to mice and elicit profound effects on neural output. Study of the neural mechanisms underlying animal behavior in the laboratory environment should be broadened to include neuroethological approaches to examine how the laboratory environment (beyond animal well-being and enrichment) influences neural systems and behavior. [ABSTRACT FROM AUTHOR]

Published

2010

5. From the top down: flexible reading of a fragmented odor map

Author

Restrepo, Diego, Doucette, Wilder, Whitesell, Jennifer D., McTavish, Thomas S., and Salcedo, Ernesto

Subjects

*ANIMAL communication, *OLFACTORY receptors, *LABORATORY mice, *ANIMAL behavior, *URINALYSIS, *OLFACTORY cortex

Abstract

Animals that depend on smell for communication and survival extract multiple pieces of information from a single complex odor. Mice can collect information on sex, genotype, health and dietary status from urine scent marks, a stimulus made up of hundreds of molecules. This ability is all the more remarkable considering that natural odors are encountered against varying olfactory backgrounds; the olfactory system must therefore provide some mechanism for extracting the most relevant information. Here we discuss recent data indicating that the readout of olfactory input by mitral cells in the olfactory bulb can be modified by behavioral context. We speculate that the olfactory cortex plays a key role in tuning the readout of olfactory information from the olfactory bulb. [Copyright &y& Elsevier]

Published

2009

6. In Vivo Penetration Mechanics and Mechanical Properties of Mouse Brain Tissue at Micrometer Scales.

Author

Sharp, Andrew A., Ortega, Alicia M., Restrepo, Diego, Curran-Everett, Douglas, and Gall, Ken

Subjects

PENETRATION mechanics, BRAIN diseases, TISSUE mechanics, TISSUE analysis, CEREBRAL cortex, OLFACTORY cortex, LABORATORY mice, ARTIFICIAL implants, NERVE tissue, EQUIPMENT & supplies

Abstract

Abstract-Substantial advancement in the understanding of the neuronal basis of behavior and the treatment of neurological disorders has been achieved via the implantation of various devices into the brain. To design and optimize the next generation of neuronal implants while striving to minimize tissue damage, it is necessary to understand the mechanics of probe insertion at relevant length scales. Unfortunately, a broad-based understanding of brain-implant interactions at the necessary micrometer scales is largely missing. This paper presents a generalizable description of the micrometer-scale penetration mechanics and material properties of mouse brain tissue in vivo. Cylindrical stainless steel probes were inserted into the cerebral cortex and olfactory bulb of mice. The effects of probe size, probe geometry, insertion rate, insertion location, animal age, and the presence of the dura and pia on the resulting forces were measured continuously throughout probe insertion and removal. Material properties (modulus, cutting force, and frictional force) were extracted using mechanical analysis. The use of rigid, incompressible, cylindrical probes allows for a general understanding of how probe design and insertion methods influence the penetration mechanics of brain tissue in vivo that can be applied to the quantitative design of most future implantable devices. [ABSTRACT FROM AUTHOR]

Published

2009

7. Evaluation of the Validity of a Maximum Likelihood Adaptive Staircase Procedure for Measurement of Olfactory Detection Threshold in Mice.

Author

Clevenger, Amy C. and Restrepo, Diego

Subjects

*OLFACTORY nerve, *LABORATORY mice, *STIMULUS intensity, *MAXIMUM likelihood statistics, *OLFACTOMETRY, *MONTE Carlo method

Abstract

Threshold is defined as the stimulus intensity necessary for a subject to reach a specified percent correct on a detection test. MLPEST (maximum likelihood parameter estimation by sequential testing) is a method that is able to determine threshold accurately and more rapidly than many other methods. Originally developed for human auditory and visual tasks, it has been adapted for human olfactory and gustatory tests. In order to utilize this technique for olfactory testing in mice, we have adapted MLPEST methodology for use with computerized olfactometry as a tool to estimate odor detection thresholds. Here we present Monte Carlo simulations and operant conditioning data that demonstrate the potential utility of this technique in mice, we explore the ramifications of altering MLPEST test parameters on performance, and we discuss the advantages and disadvantages of using MLPEST compared to other methods for the estimation of thresholds in rodents. Using MLPEST, we find that olfactory detection thresholds in mice deficient for the cyclic nucleotide–gated channel subunit A2 are similar to those of wild-type animals for odorants the knockout animals are able to detect. [ABSTRACT FROM AUTHOR]

Published

2006

8. Associative Cortex Features in the First Olfactory Brain Relay Station

Author

Doucette, Wilder, Gire, David H., Whitesell, Jennifer, Carmean, Vanessa, Lucero, Mary T., and Restrepo, Diego

Subjects

*OLFACTORY cortex, *SENSORY neurons, *SYNAPSES, *DECISION making, *ODORS, *LABORATORY mice

Abstract

Summary: Synchronized firing of mitral cells (MCs) in the olfactory bulb (OB) has been hypothesized to help bind information together in olfactory cortex (OC). In this survey of synchronized firing by suspected MCs in awake, behaving vertebrates, we find the surprising result that synchronized firing conveys information on odor value (“Is it rewarded?”) rather than odor identity (“What is the odor?”). We observed that as mice learned to discriminate between odors, synchronous firing responses to the rewarded and unrewarded odors became divergent. Furthermore, adrenergic blockage decreases the magnitude of odor divergence of synchronous trains, suggesting that MCs contribute to decision-making through adrenergic-modulated synchronized firing. Thus, in the olfactory system information on stimulus reward is found in MCs one synapse away from the sensory neuron. [ABSTRACT FROM AUTHOR]

Published

2011

9. Olfactory discrimination varies in mice with different levels of α7-nicotinic acetylcholine receptor expression

Author

Hellier, Jennifer L., Arevalo, Nicole L., Blatner, Megan J., Dang, An K., Clevenger, Amy C., Adams, Catherine E., and Restrepo, Diego

Subjects

*SMELL, *LABORATORY mice, *CHOLINERGIC receptors, *NICOTINIC receptors, *GENE expression, *OLFACTORY nerve, *SENSORY neurons, *MINERAL oils

Abstract

Abstract: Previous studies have shown that schizophrenics have decreased expression of α7-nicotinic acetylcholine (α7) receptors in the hippocampus and other brain regions, paranoid delusions, disorganized speech, deficits in auditory gating (i.e., inability to inhibit neuronal responses to repetitive auditory stimuli), and difficulties in odor discrimination and detection. Here we use mice with decreased α7 expression that also show a deficit in auditory gating to determine if these mice have similar deficits in olfaction. In the adult mouse olfactory bulb (OB), α7 expression localizes in the glomerular layer; however, the functional role of α7 is unknown. We show that inbred mouse strains (i.e., C3H and C57) with varying α7 expressions (e.g., α7 wild-type [α7+/+], α7 heterozygous knock-out [α7+/−] and α7 homozygous knock-out mice [α7−/−]) significantly differ in odor discrimination and detection of chemically-related odorant pairs. Using [125I] α-bungarotoxin (α-BGT) autoradiography, α7 expression was measured in the OB. As previously demonstrated, α-BGT binding was localized to the glomerular layer. Significantly more expression of α7 was observed in C57 α7+/+ mice compared to C3H α7+/+ mice. Furthermore, C57 α7+/+ mice were able to detect a significantly lower concentration of an odor in a mixture compared to C3H α7+/+ mice. Both C57 and C3H α7+/+ mice discriminated between chemically-related odorants sooner than α7+/− or α7−/− mice. These data suggest that α7-nicotinic-receptors contribute strongly to olfactory discrimination and detection in mice and may be one of the mechanisms producing olfactory dysfunction in schizophrenics. [Copyright &y& Elsevier]

Published

2010

10. Disorganized olfactory bulb lamination in mice deficient for transcription factor AP-2ɛ

Author

Feng, Weiguo, Simoes-de-Souza, Fabio, Finger, Thomas E., Restrepo, Diego, and Williams, Trevor

Subjects

*OLFACTORY cortex, *NEURONS, *NEOCORTEX, *TRANSCRIPTION factors, *EMBRYOLOGY, *GENE expression, *LABORATORY mice

Abstract

Abstract: Within the olfactory bulb, neurons and their axonal connections are organized into distinct layers corresponding to different functionalities. Here we demonstrate that transcription factor AP-2ɛ is required for olfactory bulb development, specifically the establishment of appropriate neuronal lamination. During normal mouse embryogenesis, AP-2ɛ transcripts are one of the earliest markers of olfactory bulb formation, and expression eventually becomes refined to the projection neurons, the mitral and tufted cells. To assess the function of AP-2ɛ in olfaction, we generated a null allele (the “AK” allele) by inserting a Cre recombinase transgene into the endogenous AP-2ɛ genomic locus. AP-2ɛ-null mice exhibited defective olfactory bulb architecture. The mitral cell layer was disorganized, typified by misoriented and aberrantly positioned projection neurons, and the adjacent internal plexiform layer was absent. Despite the significant disruption of olfactory bulb organization, AP-2ɛ null mice were viable and could discriminate a variety of odors. AP-2ɛ-null mice thus provide compelling evidence for the robust nature of the mouse olfactory system, and serve as a model system to probe both the regulation of neuronal lamination and the functional circuitry of the olfactory bulb. We also show that Cre recombinase expression directed by the AP-2ɛ locus can specifically target floxed genes within the olfactory bulb, extending the utility of this AK allele. [Copyright &y& Elsevier]

Published

2009