Global ETD Search

1	Physical, chemical and sensory studies of sapid molecules Shamil, S. H. January 1987 (has links) No description available. 612 Taste chemoreception
2	Immunohistochemistry of the Gills of the Channel Catfish Ictalurus Punctatus: Cells and Neurochemicals That May Be Involved in the Control of Cardioventilatory Reflexes Oden, David S. 12 1900 (has links) In teleost fishes the neurochemicals involved in sensing and responding to hypoxia are unresolved. Serotonergic branchial neuroepithelial cells (NECs) are putative O2 chemoreceptors believed to be homologous to the neural crest (NC) derived APUD (amine-precursor uptake and decarboxylation) pulmonary NECs and carotid body type-1 glomus cells. Branchial NECs contain serotonin (5-HT), thought to be central to the induction of the hypoxic cardioventilatory reflexes. However, application of 5-HT in vivo does not elicit cardioventilatory reflexes similar to those elicited by hypoxia. But previous in vitro neural recordings from glossopharyngeal (IX) afferents innervating O2 chemoreceptors in the trout gill show the same discharge response to hypoxic conditions as does that of acetylcholine (ACh) application. This evidence strongly supports the cholinergic hypothesis of chemoreceptor impulse origin rather than a serotonergic-induced impulse origin model. We therefore hypothesized that NECs contain ACh among other neurochemicals in cells belonging to the APUD series. Although serotonergic branchial NECs did not colocalize with ACh using immunohistochemical methods, several populations of ACh and/or tyrosine hydroxylase (TH) (catecholaminergic) positive, dopamine (DA) negative, cells were found throughout the second gill arch of the channel catfish Ictalurus punctatus. In addition, the NC derivation marker zn-12 labelled the HNK-1-like epitope (Human natural killer) expressed by lamellar pillar cells’ collagen column-associated pillar cell adhesion molecules (CC-PCAMs), evidence confirming their hypothesized NC origin. Immunohistochemistry oxygen-chemoreception acetylcholine (ACh)
3	The Role of Serotonin (5-HT) in Regulating the Hypoxic Hyperventilatory Response of Larval Zebrafish Jensen, Gregory January 2016 (has links) Serotonin (5-HT) containing neuroepithelial cells (NECs) are O2 sensitive chemoreceptors found throughout the skin of larval zebrafish (Danio rerio). Zebrafish larvae are sensitive to changes in ambient PO2 as early as 2 days post fertilisation (dpf) and hyperventilate in response to hypoxia beginning at 3 dpf. Tryptophan hydroxylase (tph) is the rate-limiting enzyme in 5-HT synthesis; three tph paralogs are present in zebrafish (tph1a, tph1b and tph2). Although 5-HT has been implicated as a key neurotransmitter mediating hypoxic hyperventilation, it has not been possible to discern the role of 5-HT specifically contained within the NECs in promoting hypoxic hyperventilation. The purpose of this study was to determine the role of NEC 5-HT in regulating the hypoxic ventilatory response in larval zebrafish. It was hypothesised that 5-HT is a key neurotransmitter released from NECs which contributes to hypoxic hyperventilation. Immunohistochemistry was used to determine the distribution of tph paralogs and their role in 5-HT production in NECs. Tph1a was present in NECs and nerves innervating NECs. Exposure to the non-selective tph inhibitor, para-chlorophenylalanine (pCPA), or translational gene knockdown of tph1a, diminished 5-HT expression within NECs. Exposure to acute hypoxia (PO2 = 30 mmHg) revealed a blunted hypoxic ventilatory response (reduced breathing frequency) in fish exhibiting depleted 5-HT in NECs. The hypoxic hyperventilatory response was rescued with application of 5-HT. The results of these experiments demonstrate that tph1a is responsible for 5-HT production in NECs of larval zebrafish, and that 5-HT released from NECs is involved in establishing their hypoxic hyperventilatory response. hypoxia chemoreception neuroepithelial cell tryptophan hydroxylase
4	BEHAVIORAL STUDIES OF CHEMORECEPTION BY THE PACIFIC WHITE SHRIMP LITOPENAEUS VANNAMEI: TESTING ATTRACTABILITY AND PALATABILITY OF PROPRIETARY CHEMICAL MIXTURES THAT AUGMENT FEED PELLETS USED IN SHRIMP AQUACULTURE Elsayed, Farida 07 May 2016 (has links) Litopenaeus vannamei or Pacific white shrimp is the most widely farmed crustacean in the world. Shrimp are commonly fed feed containing 30-40% soybean meal or other plant-based feeds that are more economically and environmentally sustainable than animal-based feed. However, plant-based pellets are less palatable and less chemically attractive compared to animal material. Based on that, current research and practice includes the addition of specific marine animal meals in order to enhance palatability and attractability of plant-based shrimp feed. Yet, it is not sustainable or economically achievable to continue relying on marine animal meal. In the herein study, the effect of proprietary chemical mixtures designed by our research group as feed additives was examined based on their attractability and palatability in comparison to krill meal, a highly attractive and palatable supplement for shrimp feed. In palatability assays, total amount of pellets was measured before and after one-hour and three-hour periods of feeding in group-housed animals. In attractability assays, responses of shrimp were measured based on the number of probes and grabs on the source (airstone) of the stimulus being released. Each diet-set used contained different concentrations of krill meal and synthetic chemical mixtures. Results demonstrated these chemical mixtures enhance attractability and palatability of soybean based feed in L. vannamei when compared to krill meal. Furthermore, the addition of a proprietary mixture (= “premix”) improved responses in the attractability assays when compared to stimuli that did not contain the premix. Overall, results support the hypothesis that synthetic chemical mixtures can improve palatability and attractability of soybean meal based shrimp feed. This work could provide a reference for the development of synthetic chemoattractants and chemopallatants for the aquaculture of shrimp. Pacific white shrimp attractability mixtures palatability chemoreception aquaculture.
5	Chemical Defenses of Aplysia Californica and Sensory Processing by Predatory Fishes Nusnbaum, Matthew 18 April 2011 (has links) In predator-prey interactions, prey species have complex defensive behaviors to protect themselves from predators. Chemical defenses are one tool that is employed to protect against predators, especially for slow-moving or otherwise susceptible prey. Many of these chemical defenses have been studied and the effective compounds identified, but few studies were performed on their mechanisms of detection. In my research, I used the sea hare, Aplysia californica, as chemically defended prey. This slow moving mollusk is soft-bodied with no external shell, but it has adapted a number of defenses including chemical defenses. Ink is a sticky mixture of the products of the ink gland and the opaline gland which are mixed in the mantle cavity and released toward an attacker. I show that this ink secretion protects the sea hare from predation by a fish predator. Because many deterrent compounds taste bitter, bitter taste receptors are thought to protect predators from ingesting harmful compounds in prey. Studies of deterrent taste detection have commonly utilized bitter compounds from human hedonics to study the responses in animals, such as fruit flies, fishes, rats, and monkeys. In my dissertation, I argue that the study of chemical defenses allows us to ask more questions about detection of relevant deterrents and interactions between predators and prey at the individual and population levels. My results show that diet-derived pigments in Aplysia ink, aplysioviolin and phycoerythrobilin, are strongly deterrent to fish predators. Electrophysiological analyses of the gustatory system show that these compounds are equipotent and cross-adapt each others’ responses completely. Aplysioviolin and phycoerythrobilin produced incomplete reciprocal cross-adaptation with amino acids and adapted bile salt responses but were not significantly adapted by these latter stimuli. These results showed multiple pathways that are sensitive to aplysioviolin and phycoerythrobilin, which may have different effects on the physiology and behavior of the predatory fish. My findings demonstrate the value to the fields of chemical ecology and chemosensory biology of studying sensory processing of relevant deterrent compounds. This work lays the foundation for how a diet-derived photopigment is adapted by a species to protect itself from predators by stimulating their chemosensory systems. Aplysia californica Aplysioviolin Ariopsis felis Chemoreception Deterrence Fish Neuroscience and Neurobiology
6	A specialized serotonergic neuron subtype transduces chemosensory signals and regulates breathing Brust, Rachael Danielle January 2014 (has links) Serotonergic neurons modulate a wide range of behaviors and functions, from mood and aggression to vital autonomic processes like heart rate, respiratory dynamics, and body temperature. We hypothesize that this broad scope reflects the collective actions of many functionally and molecularly distinct subtypes of serotonergic neurons, each with specialized roles in different neural processes. Supporting this idea are examples of heterogeneity among serotonergic neurons with respect to developmental origin, biophysical properties, and molecular expression; yet deciphering the functional and behavioral relevance of these differences has been challenging. In order to better understand serotonergic system organization, we have developed and applied a set of mouse genetic tools to subdivide serotonergic neurons into groups based on molecular criteria, and then to query these subtypes for differences with respect to biophysical properties, hodology, gene expression, and whole animal function. We applied these tools in a stage-wise fashion, from neural system en masse, as reference, and then to specific serotonergic neuron subtypes. From this, we have established that serotonergic neurons play key roles in at least two life-sustaining reflexes - the respiratory chemoreflex (breathing modulation to keep tissue PCO2/pH within physiological limits) and body temperature regulation. We found that chemoreflex modulation, but not body temperature regulation, maps to a specific serotonergic neuron subtype - that subtype with a developmental history of Egr2 gene expression. Further, in brain slice preparations, we found that this subtype is chemosensitive, increasing firing rate in response to conditions of hypercapnic acidosis. Thus, in vivo, Egr2-serotonergic neurons likely transduce chemosensory information into action potential firing to increase respiratory drive and ultimately breathing. Further, we found that Egr2-serotonergic neurons project selectively to respiratory nuclei involved in PCO2/pH sensory signal transduction, but not primary respiratory motor nuclei. This indicates that the serotonergic system has distinct sensory and motor divisions - another unexpected finding. In summary, these results establish a previously unappreciated functional modularity and organization to the serotonergic system, and open up potential for tailored function-specific therapeutic strategies, for example here as relates to disorders of respiratory homeostasis or thermoregulation. Genetics Neurosciences Chemoreception Mouse Genetics Neuron Subtypes Respiratory Physiology Serotonin
7	Tracking response of the freshwater copepod Hesperodiaptomus shoshone: Importance of hydrodynamic features Pender-Healy, Larisa Alexandra 27 August 2014 (has links) Using three-dimensional Schlieren-based videography, males of the freshwater alpine species Hesperodiaptomus shoshone (Wyoming) were found to follow both conspecific females and conspecific males, remaining 0.45 ± 0.13 cm (male) and 0.56 ± 0.13 cm (female) from the lead copepod for 0.91 ± 0.35 seconds (male) and 0.84 ± 0.46 seconds (female). Trail following is initiated when the male makes a rapid reorientation. Chemical pheromones either were not produced by the female or were not detected by the male because males would follow trail mimics composed of female-conditioned water. Using unconditioned water, males were found capable not only of following trail mimics but they showed a preference, quantified as a higher follow frequency, of trails running at speeds matching that of their female mate. Remarkably, the male copepods always followed upstream, micro-casting between the edges of the trail to remain on track. Trails flowing at speeds matching their mate’s swimming speed were followed for a longer period of time and at greater gross distance. As the flow speed of the trail mimic increased, the distance the copepod would advance would decrease until the threshold speed of 2.30 cm/sec at which it would not follow a trail and only station hold. Station holding has never been observed before for copepods and may represent an adaptive behavior to avoid being washed out of their resident alpine pond. At speeds greater than that evoking station holding, the stream seemed to push the copepod out of the flow even though the copepod would make repeated efforts to swim up the stream. This research revealed a behavior not documented before: instead of relying on discrete pulses of flow left by hopping copepods, this high alpine lake copepod followed smoothly swimming mates or continuously flowing thin streams, relying only on sensing hydrodynamic cues. Mate tracking Calanoid copepods Mechanoreception Chemoreception Hesperodiaptomus shoshone
8	Oxygen Chemoreception in Larval Zebrafish: From Signal Initiation to the Hypoxic Ventilatory Response Pan, Yihang 28 October 2021 (has links) Multicellular organisms typically depend on O₂ for energy production to maintain normal cellular function, and even brief periods of O₂ deprivation may have fatal consequences. The aqueous environment is prone to changes in ambient water O₂ tension (PO₂) and thus the ability of fish to sense changes in water PO₂ and to elicit appropriate physiological responses is essential for their survival. Studies on fish O₂ chemoreception have identified neuroepithelial cells (NECs), which are characterized as having dense-cored vesicles containing serotonin (5-HT), as peripheral O₂ chemoreceptors. Upon exposure to hypoxia, isolated and cultured NECs in vitro depolarize, likely resulting in neurotransmitter release. However, to date there is no evidence that NECs are activated by hypoxia in vivo to initiate physiological responses such as the hypoxic ventilatory response (HVR), which is the focus of this thesis. Initial findings demonstrated that larval zebrafish fine-tune the HVR as early as 4 days post fertilization (dpf) and by 7 dpf, the HVR aids in O₂ uptake under hypoxic conditions. In addition, the HVR is multiphasic, with an initiation phase followed by a decline phase that gradually stabilizes above normoxic baseline values (Chapter 2). In the absence of tools to probe the hypoxia sensitivity of NECs in vivo, research focused on Merkel-like cells (MLCs), a newly proposed O₂ chemoreceptor in larval zebrafish. Using in vivo calcium imaging it was shown that MLCs are stimulated by hypoxia. Data suggest that MLCs are responsible for the initiation phase of the HVR, while peripheral sensory neurons (PSNs)/peripheral sensory ganglia (PSG) that innervate MLCs play a more important role in reducing ventilation during the decline phase of the HVR (Chapter 4). Attempts at identifying the putative neurotransmitter(s) involved in the O₂ signal transduction pathway revealed that adrenaline (AD), serotonin (5-HT), and dopamine (DA) are probable candidates (Chapter 4), though the presence of AD and DA within MLCs is yet to be confirmed. In addition, 5-HT likely plays a role in the central nervous system (CNS), integrating peripheral signals resulting in the final HVR (Chapter 3). Taken together, this thesis provides the first evidence of putative O₂ chemoreceptors responding to hypoxia in vivo and thus significantly advances models for O₂ signal transduction in larval zebrafish. Oxygen chemoreception Hypoxic ventilatory response Serotonin Merkel-like cells
9	Structure-activity relationship studies in chemoreception, toxicology and medicinal chemistry Ptchelintsev, Dmitri Stanislav January 1993 (has links) No description available. Chemistry, General Structure-activity relationships
10	Mecanismos purinérgicos no bulbo ventrolateral rostral modulam respostas cardiovasculares e respiratórias promovidas pela ativação dos quimiorreceptores centrais e periféricos. / Purinergic mechanism in rostroventrolateral medulla modulate cardiovascular and respiratory responses promoted by central and peripheral chemoreceptors activation. Roberto Sobrinho, Cleyton 03 December 2015 (has links) Quimioreceptores centrais (QC) e periféricos (QP) são células especializadas em detectar alterações de CO2, O2 e H+, e promover ajustes na ventilação e pressão arterial via sistema nervoso central. Avaliamos aqui a ação da sinalização purinérgica em áreas que apresentam essa propriedade (RTN, C1, NTScom e RPa) durante as respostas cardiorrespiratórias promovidas pela ativação dos quimiorreceptores, e a possível participação de astrócitos. Encontramos evidências que receptores P2 modulam a resposta de QC no RTN, enquanto que receptores P2Y1 e receptores glutamatérgicos, modulam a resposta de QP no C1, e que a sinalização purinérgica na região do NTScom ou na região RPa não contribui para resposta de QC. A manipulação farmacológica de astrócitos do RTN com fluorocitrato, mas não da região do NTScom e RPa, produz alterações respiratórias via receptores P2. Nossos achados evidenciam a importância e contribuem para descriminação dos mecanismos de ação da sinalização purinérgica na região bulbo ventrolateral rostral durante a ativação QC e QP. / Central (CC) and peripherals (PC) chemoreceptors are specialized cells to detect changes in CO2, O2 and H+, and produce adjustments in ventilation and blood pressure via the central nervous system. Here we evaluate the action of purinergic signaling in areas with this property (RTN, C1, commNTS, RPA) during the cardiorespiratory responses elicited by activation of chemoreceptors, and a possible role of astrocytes. We found evidence that P2 receptors modulate CC responses in RTN, while P2Y1 and glutamate receptors modulate PC responses in C1, and that the purinergic signaling in the RPa and commNTS region does not contribute to CC responses. The pharmacological manipulation of the RTN astrocytes, but not commNTS or RPa, with fluorocitrate produces respiratory changes via P2 receptors. Our findings show the importance and contribute to discrimination of the mechanisms of purinergic signaling in the rostral ventrolateral medulla during CC and PC activation. C1 group Central chemoreception Grupamento C1 Núcleo retrotrapezóide P2 Purinergic receptors Peripheral chemoreception Purinergic signaling Quimiorrecepção central Quimiorrecepção periférica Receptores purinérgicos P2 Retrotrapezoid nucleus Sinalização purinérgica

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