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1 -gated channels are essential for vision and olfaction.
2 he latency of initial transduction events in olfaction.
3 elemental perceptual feature of odors in rat olfaction.
4 pid gains in our understanding of Drosophila olfaction.
5 ating the independence of this behavior from olfaction.
6 velopment of fins, tail, ear, eye, brain and olfaction.
7 humans, suggesting an indispensible role in olfaction.
8 owerful model system for studying vertebrate olfaction.
9 s, the most salient sensations are taste and olfaction.
10 urons are the primary sensory organelles for olfaction.
11 the nose, plays an important role in rodent olfaction.
12 to operate on principles inspired by canine olfaction.
13 rmine if these mice have similar deficits in olfaction.
14 mination and cortical pattern recognition in olfaction.
15 knowledge regarding why the disease impacts olfaction.
16 ey play roles in higher functions other than olfaction.
17 including autonomic dysfunction and impaired olfaction.
18 in the antennae and so could be involved in olfaction.
19 d molecular mechanisms that drive rhythms in olfaction.
20 , is one of the key factors in understanding olfaction.
21 role of UBR3 in sensory pathways, including olfaction.
22 but the principle of SAT is still debated in olfaction.
23 we present the direct observation of SAT in olfaction.
24 bulb (OB) of mice mediates daily changes in olfaction.
25 ng a central mechanism for sensory gating in olfaction.
26 ral to the mouth, associated with retronasal olfaction.
27 nderutilized, yet critical, animal model for olfaction.
28 diate diverse signaling processes, including olfaction.
29 on on the highly salient sensory modality of olfaction.
30 known, limiting mechanistic understanding of olfaction.
31 orco mutations should significantly impact olfaction.
32 cesses, including, as recently demonstrated, olfaction.
33 ng lipid metabolism, leukocyte migration and olfaction.
34 n differently affect appetite parameters and olfaction.
35 mechanism and functional logic for mammalian olfaction.
36 a and genes related to diet, metabolism, and olfaction.
37 larger integrated system of ortho-retronasal olfaction.
38 tum feeding, food reward (snack points), and olfaction.
39 nd changes that are consistent with enhanced olfaction.
40 shapes principal neuron activity to regulate olfaction.
41 ment newly offered up by vision, hearing and olfaction.
42 delayed or absent puberty and dysfunctional olfaction.
43 ng 2 questions: (1) What does AR do to human olfaction?
45 al cavity carried by the inhaled air, making olfaction a sense where animals can control the frequenc
46 e or dementia with Lewy bodies had decreased olfaction, a lesser chronotropic response to tilt, and a
47 have addressed these issues with C. elegans olfaction, a simple innate behavior mediated by sexually
53 re from existing methodologies in artificial olfaction, allows the recognition module to better mitig
65 s probably driven by increased resolution in olfaction and improvements in tactile sensitivity (from
67 siological function of Hedgehog signaling in olfaction and provide an important evolutionary link bet
68 strong evidence for temporal integration in olfaction and puts a constraint on models of olfactory p
69 le in regulating many behaviors that rely on olfaction and recently there has been great effort in de
70 dministration, followed by the assessment of olfaction and reward-driven snack intake in the absence
71 indicate that certain conditions that impact olfaction and sexual development, such as Kallmann syndr
75 lutionary novelties for beak development and olfaction and specifically for homeostasis-related genes
76 redefine the role of sorption properties in olfaction and suggest that the peripheral olfactory syst
79 ovide an important evolutionary link between olfaction and the requirement of a ciliary compartment f
80 odel to evaluate the specific role of MCs in olfaction and to test the restorative function of transp
82 lad over wild hosts, and whether the role of olfaction and vision in response to cues from host plant
84 s changes in some brain areas concerned with olfaction and voice perception consistent with sexual id
85 severe bladder/bowel dysfunction, preserved olfaction, and a cardiac chronotropic response upon tilt
86 he interactions between taste and retronasal olfaction, and a paradigm for enhancing liking of natura
87 antidepressant fluoxetine (FLX) on behavior, olfaction, and adult neurogenesis in the dentate gyrus (
88 evalent among genes associated with defense, olfaction, and among genes downstream of the Drosophila
89 mily, widely studied in insect gustation and olfaction, and are implicated in host-seeking by insect
91 an thus be used to better understand natural olfaction, and it also suggests ways to improve artifici
95 blebee chemoreception towards gustation from olfaction, and striking differences in microRNAs, potent
97 g sequences of genes critical for cognition, olfaction, and thermotolerance, consistent with the obse
98 physically and/or chemically interfere with olfaction, and thus maintains the olfactory acuity of th
102 nd suggest that impacts of neonicotinoids on olfaction are greater than their effects on rewarding me
104 rliest hypothesis of the role of sniffing in olfaction arises from the fact that odorants with differ
106 ence of correlated transformations affecting olfaction as well as mastication, head movement, and ven
107 We examine interactions between taste and olfaction as well as psychophysical measurement limitati
109 derives not from empirical studies of human olfaction but from a famous 19th-century anatomist's hyp
110 It locates its human hosts primarily through olfaction, but little is known about the molecular basis
111 R) superfamily is best known for its role in olfaction, but virtually nothing is known about a clade
112 the limits of temporal resolution in insect olfaction by delivering high frequency odor pulses and m
113 factory epithelium and are thought to affect olfaction by enzymatic conversion of odorant molecules.
116 interneurons, GH298 and krasavietz, leads to olfaction changes toward attraction or repulsion, while
118 s, autonomic and psychiatric manifestations, olfaction, color vision, sleep parameters, and neurocogn
119 ine minerality scores only in the orthonasal olfaction condition, samples from the left being more mi
120 Understanding the molecular basis of insect olfaction could facilitate the development of interventi
123 roxyurea (HU) treatment results in a loss of olfaction-dependent increase in yaw optomotor fidelity.
127 pecies that primarily use other senses (e.g. olfaction, echolocation), and suppression was strongest
130 nt odor molecules; gene families involved in olfaction exhibit high diversity in different animal phy
131 s, suggesting functionality of SiOBPs beyond olfaction Expression patterns of SiOBP subgroups also sh
140 n and metabolism, as well as those affecting olfaction, have reduced gene expression in Drosophila se
142 s and the endosseous labyrinth suggests that olfaction, hearing, and equilibrium were well-developed
144 hich include contributions to vision, taste, olfaction, hearing, touch, and thermo- and osmosensation
146 euronal stimulus selectivity in systems like olfaction, however, which lack a simple two-dimensional
147 neurons has facilitated our understanding of olfaction; however, many other AL neurons remain unident
148 lty, sweet, sour, bitter, umami), retronasal olfaction (i.e. smelling through the mouth), and somatos
149 under positive selection and are involved in olfaction, immune response, development, locomotion, and
151 faction in larvae to semiaquatic or airborne olfaction in adults requires anatomical, cellular, and m
152 gene family is absent from S. maritima, and olfaction in air is likely effected by expansion of othe
153 Behavioral analysis showed greatly impaired olfaction in AQP4-null mice, with latency times of 17 +/
165 ystem scaling in vertebrates, the primacy of olfaction in spatial navigation, even in visual speciali
166 lecular and cellular mechanisms underpinning olfaction in teleosts and mammals are similar despite 43
168 l variation and indicate the significance of olfaction in the regulation of reproductive decline duri
169 significance of this feedback mechanism for olfaction in vivo, we genetically mutated serine(1076) o
170 s thought to play several important roles in olfaction, including maintaining the sparseness of respo
172 d visceral/autonomic information, taste, and olfaction influence behavioral responses mediated by the
173 itional, action-based perspective focuses on olfaction instead of on vision and is descriptive (descr
174 Here, we test the hypothesis that taste and olfaction interact in the nucleus of the solitary tract
175 emotional disorders, as exaggerated emotion-olfaction interaction in negative mood states turns inno
179 ponents of odorant mixtures, suggesting that olfaction is a synthetic sense in which mixtures are per
183 Phylogenetically the most ancient sense, olfaction is characterized by a unique intimacy with the
187 s in Chd7 deficient mice, suggesting reduced olfaction is due to a dysfunctional olfactory epithelium
192 nformation inherent in the olfactory signal, olfaction is more involved in interpreting space and tim
198 completely overlooked, despite the fact that olfaction is one of the first sensory modalities to deve
203 the most fundamental tenets in the field of olfaction is that each olfactory receptor neuron (ORN) e
204 The current consensus model in mammalian olfaction is that the detection of millions of odorants
205 For many insects, including mosquitoes, olfaction is the dominant modality regulating their beha
206 considered a distance sense; hence, aquatic olfaction is thought to be mediated only by molecules di
209 g ability but it is unknown what the role of olfaction is when birds navigate freely without their se
214 espite the critical role of granule cells in olfaction, little is known about how sensory input recru
215 receptors (GPCRs), as well as the canonical olfaction machinery (Golf and AC3) in the smooth muscle
216 , spatial orientation, memory retrieval, and olfaction may explain some of the common disturbances in
217 s in defining the basic mechanisms of insect olfaction may lead to means of disrupting host-seeking a
219 nd suggest that the poor reputation of human olfaction may reflect, in part, behavioral demands rathe
225 ses were confirmed to result from retronasal olfaction: monitoring respiration revealed that exhalati
226 ur findings identify a role for the TAARs in olfaction, namely, in the high-sensitivity detection of
231 rstanding of olfactory impairment and of the olfaction-nutrition axis in patients with kidney disease
232 a) and non-motor symptoms (eg, cognition and olfaction) of LRRK2-associated PD were more benign than
233 We propose that, in addition to its role in olfaction, Olfr78 acts as a hypoxia sensor in the breath
235 the basis for the perceptual differences in olfaction or whether disease-specific or other entities,
237 ng in the Azores indicated a crucial role of olfaction over the open ocean, but left open the questio
239 s, communication at a distance by vision and olfaction, photosymbiosis, chemosymbiosis, suspension fe
240 important for transepithelial ion transport, olfaction, phototransduction, smooth muscle contraction,
241 nd physiology suggests that ortho-retronasal olfaction played a critical role at three stages of mamm
244 nted odors in at-sea trials, suggesting that olfaction plays a role in natural foraging behavior.
245 nhaling air through the nostrils, suggesting olfaction plays an important role in aquatic foraging.
248 iated genomic regions are highly enriched in olfaction-related genes, indicating a role of nuclear or
249 overall there is relaxed constraint on human olfaction relative to chimpanzee, species-specific senso
250 ate, their physiological functions in insect olfaction remain largely controversial in comparison to
257 iple measures of social interactions, social olfaction, repetitive behaviors, anxiety-related behavio
259 criminate odors in one breath, and mammalian olfaction research has thus focused on the first breath.
261 Comparison of rodent, insect and nematode olfaction reveals surprising differences and unexpected
262 ients had reduced CSF amyloid Ass1-42, lower olfaction scores, higher depression scores and increased
263 d 10 distinct communication behaviours, with olfaction, scraping, and cheek rubbing the most frequent
265 und in brain regions known to be involved in olfaction, somatic motor control, fluid homeostasis, ing
266 r of the five major sensory systems (vision, olfaction, somatosensation, and audition) are thought to
269 tionnaires, quantitative sensory testing and olfaction testing during the in-clinic phase of the stud
272 vor is produced by the integration of taste, olfaction, texture, and temperature, currently thought t
273 lts establish AQP4 as a novel determinant of olfaction, the deficiency of which probably impairs extr
275 bility of genomic and genetic tools to study olfaction-the sense of smell-has brought important new i
276 pment was driven in part by ortho-retronasal olfaction; the bauplan for neocortex had higher-level as
278 including locomotion, aversive learning and olfaction through at least four different 5-HT receptors
281 reat functional diversity including roles in olfaction, transportation, and prostaglandin synthesis i
282 e, it is widely held that mammals cannot use olfaction underwater because it is impossible for them t
284 re contains contradictory claims that insect olfaction uses cAMP, cGMP, or IP3 as second messengers;
285 ion/translation, metabolism, detoxification, olfaction, vision, cuticle regulation, and immunity, and
286 of inputs from different sensory modalities (olfaction, vision, thermosensation), we conclude that th
287 ulu-Asia Aging Study cohort members METHODS: Olfaction was assessed from 1991 to 1996 in 2,267 men in
290 ive biochemistry and molecular mechanisms of olfaction, we have developed a mammalian expression syst
291 the relationship between gene expression and olfaction, we have performed cohort comparisons of anten
293 ls to smell others' mouths and determine via olfaction what foods their conspecifics had chosen.
294 cilia, the essential signaling platform for olfaction, which alters the uniformity of responses in p
295 st to mammalian chemosensation or Drosophila olfaction, which are initiated by receptors composed of
296 ate disparate modalities, such as vision and olfaction, which are neither related by spatiotemporal s
298 ce and worms leads to profound impairment in olfaction, while similar mutations in the fly show more
299 ve seen significant advances in the study of olfaction, with particular emphasis on elucidating the m
300 trasonic vocalizations, but displayed normal olfaction, working and reference memory, motor abilities
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