DOCSLIB.ORG

The Nervous System: Sniffing out Cancer

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Nervous System: Sniffing out Cancer Biology The Nervous System: Sniffing out cancer This lesson introduces you to the nervous system. In this lesson you will investigate the following: • What is the nervous system? • How is the nervous system used to transfer messages to and from the brain? • How are our senses of smell, taste, touch, sight and sound related to the nervous system? • How can our nervous system protect us from danger? • How can dog’s noses help to develop devices to detect diseases? So let’s sniff out the information! This is a print version of an interactive online lesson. To sign up for the real thing or for curriculum details about the lesson go to www.cosmosforschools.com Introduction: Using our Senses (P1) We use dogs to help us in all sorts of ways, from rounding up sheep to helping blind people cross the road. But new research now makes these things seem rather simple, showing that dogs can use their amazing sense of smell to help detect diseases like cancer, just by sniffing a person’s breath. Some people have been using dogs like this for a while and they say they have a very good record in telling if people are sick or not, just through their sense of smell. Of course, dogs’ noses are much better at the job than ours. They have millions and millions more smell receptor cells – specialised cells that can pick up a scent for their brains to process. Other scientists are not using dogs, but are instead making new machines that work like a dog’s nose. In order to do so they must first work out what it is that cancer smells like and then build the incredible machines sensitive enough to detect it. But they are making progress and one day soon, they hope, they will be able to make the machines so small and reliable that you will be able to breathe into your smartphone and send the results to a lab to work out if you are sick. The technology could save many lives, as the earlier we can diagnose cancer, the better the chance of curing it. Read the full Cosmos Magazine article here or listen to it below. 00:00 -17:48 Left: Jobi, a "Medical Detection Dog", gets down to work. Middle and right: Prototype machines used for detecting smells. Image credits: Medical Detection Dogs, Hossam Haick and Menassa Research. Question 1 Think: What are some other ways that animals are used to detect smells and odours? Gather: Using our Senses (P1) Loading Video credit: Ted Ed / YouTube. Question 1 Question 2 ​Recall:​ A dogs olfactory epithelium is approximately 20 times ​Recall:​ The olfactory receptor cells are the most frequently larger than that of humans. replaced neurons in the body. True True False False Question 3 Describe: Cast your mind back to the last time that you had a cold. Describe how it affected your senses of smell and taste. Question 4 Infer: Why do you think that your cold affected your senses of smell and taste as you described above? Hint: You can sniff out some clues to help answer this question in the second half of the clip. Question 5 Calculate: The clip stated that adult humans can distinguish about 10,000 different smells. As part of a check-up with her doctor, Josephine was told that she had mild anosmia and that she can only distinguish about two thirds of the smells that most adults can. How many different smells can Josephine distinguish? The nervous system So far we have learned about the signal pathway from our nose to our brain that allows us to smell, but how do our other senses work? To answer this question we must first understand that our body relies on its nervous system to interact with the world around us. The nervous system is made up of the central nervous system and the peripheral nervous system. The central nervous system, sometimes referred to as "the coordinator", consists of the brain and the spinal cord. It is responsible for making sense of the messages it receives from the peripheral nervous system and sending "instructional messages" back to all parts of the body. The peripheral nervous system consists of the rest of the nerves in our body and is responsible for relaying messages between the central nervous system and the rest of the body. The central and peripheral nervous systems enable us to interact with the world around us. Receptors Receptors allow us to respond to specific stimuli. For example, olfactory receptor cells located in your nose respond to odour molecules. These receptors launch a chain of messages around the body via the nervous system. There are five primary types of receptors: Chemoreceptors are sensitive to chemicals, such as odour molecules in the air, and are located in your nose and tongue. Mechanoreceptors are sensitive to touch, pressure, sound and motion and are located in the skin, the inner ear and muscles. Pain receptors are sensitive to chemical changes in damaged cells and are located throughout your body, but most are located in your skin. Thermoreceptors are sensitive to temperature changes and are located in the skin. Photoreceptors are sensitive to light and are located in your eyes. Some of these receptors are neurons (described below), like the olfactory receptor cells, while others are not, such as the hair cells in your inner ear that enable you to hear. Question 6 Identify: Use the information above to complete the table below by matching the receptors and responses with each given stimuli. Include an example of your own in the bottom row. Stimulus Receptors responsible Typical response The bell rings at the end of class Pack up your books A very hot day down at the beach Body starts to sweat Your friend waves to you from across the Photoreceptors in the retina of the eye school yard You've put sour milk on your cereal and Spit milk out or pull a face only realise when you take a mouthful Mum has cooked your favourite meal and you smell it as you walk in the door Neurons Neurons are specialist cells that transmit messages, in the form of electrical signals, to and from the central nervous system. They are like the wires of an electric circuit. There are a number of different types of neurons: Interneurons transmit messages from sensory neurons to motor neurons. Motor neurons transmit messages from the central nervous system to "effectors" such as muscles and glands to initiate a response. Sensory neurons transmit messages from receptors to the central nervous system. Although they have different roles, neurons generally have the same structure. They are made up of dendrites (branches that receive messages), a cell body (where the nucleus is found), axons (that transmit a message away from the cell body) and myelin sheaths (a fatty layer that insulates the axon). There are different types of neurons in our body. Question 7 Label: Use the following terms and the information above, to label a typical neuron. The terms you have to choose from are: Axon Cell body Myelin sheath Dendrites Nucleus Also, use purple arrows to show the direction in which an electrical impulse would travel through the neuron. Process: Using our Senses (P1) Loading Video credit: Medical Detection Dogs / YouTube. Question 1 Debate: The Cosmos Magazine article states that after five years of training dogs can correctly sniff out bladder cancer samples 93% of the time. Is this statistic alone sufficient to be able to state that these dogs can "sniff out cancer"? What scientific evidence and tests are needed to be able to make claims such as these? Generate some points in the space provided and discuss them with a friend. When a dog sniffs, the odours in the air pass through the olfactory epithelium and trigger the olfactory epithelium cells which then send electrical impulses to the brain via the nervous system. This maps a path for that particular odour, like cutting a path through a jungle. If that path is mapped enough times, the brain starts to be able to easily recognise that odour. Question 2 Think: Complete the flow chart to show what happens once a dog recognises a particular odour. Hint: Receptors, coordinators and effectors are all described in "Gather". Question 3 Research: Use the internet to find out the similarities and differences between the way a dog's nose and an electronic nose detect an odour. Question 4 Discover: So far we have learned that messages, in the form of electrical impulses, are transmitted around the body via the nervous system by millions of specialised cells called neurons. But how is a signal transferred between neurons? Use the space below to write a report on synapses. Your information can presented in any number of ways, including written information, labelled sketches, flowcharts, YouTube clips and images. Apply: Using our Senses (P2) Experiment: Are we smelling it or tasting it? Background We eat a variety of foods and enjoy their delicious tastes, but are we really tasting them or are we in fact smelling them? This experiment will help you find out. You will eat a variety of foods first with your nostrils blocked, then with your nostrils open. To make sure that you don't cheat, you will be wearing a blindfold! So find a partner, apply your blindfold and get tasting. Materials Blindfold Variety of food Pen Paper Method Your teacher will provide plates of food for you to test, but you are not allowed to see them so move away from the table and apply your blindfold! 1.
Load more

Recommended publications
  • Taste and Smell Disorders in Clinical Neurology
    TASTE AND SMELL DISORDERS IN CLINICAL NEUROLOGY OUTLINE A. Anatomy and Physiology of the Taste and Smell System B. Quantifying Chemosensory Disturbances C. Common Neurological and Medical Disorders causing Primary Smell Impairment with Secondary Loss of Food Flavors a. Post Traumatic Anosmia b. Medications (prescribed & over the counter) c. Alcohol Abuse d. Neurodegenerative Disorders e. Multiple Sclerosis f. Migraine g. Chronic Medical Disorders (liver and kidney disease, thyroid deficiency, Diabetes). D. Common Neurological and Medical Disorders Causing a Primary Taste disorder with usually Normal Olfactory Function. a. Medications (prescribed and over the counter), b. Toxins (smoking and Radiation Treatments) c. Chronic medical Disorders ( Liver and Kidney Disease, Hypothyroidism, GERD, Diabetes,) d. Neurological Disorders( Bell’s Palsy, Stroke, MS,) e. Intubation during an emergency or for general anesthesia. E. Abnormal Smells and Tastes (Dysosmia and Dysgeusia): Diagnosis and Treatment F. Morbidity of Smell and Taste Impairment. G. Treatment of Smell and Taste Impairment (Education, Counseling ,Changes in Food Preparation) H. Role of Smell Testing in the Diagnosis of Neurodegenerative Disorders 1 BACKGROUND Disorders of taste and smell play a very important role in many neurological conditions such as; head trauma, facial and trigeminal nerve impairment, and many neurodegenerative disorders such as Alzheimer’s, Parkinson Disorders, Lewy Body Disease and Frontal Temporal Dementia. Impaired smell and taste impairs quality of life such as loss of food enjoyment, weight loss or weight gain, decreased appetite and safety concerns such as inability to smell smoke, gas, spoiled food and one’s body odor. Dysosmia and Dysgeusia are very unpleasant disorders that often accompany smell and taste impairments.
    [Show full text]
  • Review Article Olfactory Reference Syndrome
    British Journal of Pharmaceutical and Medical Research Vol.04, Issue 01, Pg.1617-1625, January-February 2019 Available Online at http://www.bjpmr.org BRITISH JOURNAL OF PHARMACEUTICAL AND MEDICAL RESEARCH Review ISSN:2456-9836 ICV: 60.37 Article Murat Eren Özen, Murat Aydin Olfactory Reference Syndrome: A Separate Disorder Or Part Of A Spectrum 1Psychiatrist, Department of Psychiatry, Private Adana Hospital, Adana Büyük şehir Belediyesi kar şısı, No:23, Seyhan-Adana- Türkiye. 2Private Dental Clinics, Gazipa şa bulv. Emre apt n:6 (kitapsan kar şısı) k:2 d:5 Adana- Türkiye. http://drmurataydin.com ARTICLE INFO ABSTRACT This article provides a narrative review of the literature on olfactory reference syndrome Article History: Received on (ORS) to address issues focusing on its clinical features. Similarities and/or differences with other psychiatric disorders such as obsessive-compulsive spectrum disorders, social anxiety 10 th Jan, 2019 Peer Reviewed disorder (including a cultural syndrome; taijin kyofusho), somatoform disorders and hypochondriasis, delusional disorder are discussed. ORS is related to a symptom of taijin on 24 th Jan, 2019 Revised kyofusho (e.g. jikoshu-kyofu variant of taijin kyofusho) Although recognition of this syndromes more than a century provide consistent descriptions of its clinical features, the on 17 th Feb, 2019 Published limited data on this topic make it difficult to form a specific diagnostic criteria. The core on 24 th Feb, symptom of the patients with ORS is preoccupation with the belief that one emits a foul or 2019 offensive body odor, which is not perceived by others. Studies on ORS reveal some limitations.
    [Show full text]
  • Respiration, Neural Oscillations, and the Free Energy Principle
    fnins-15-647579 June 23, 2021 Time: 17:40 # 1 REVIEW published: 29 June 2021 doi: 10.3389/fnins.2021.647579 Keeping the Breath in Mind: Respiration, Neural Oscillations, and the Free Energy Principle Asena Boyadzhieva1*† and Ezgi Kayhan2,3† 1 Department of Philosophy, University of Vienna, Vienna, Austria, 2 Department of Developmental Psychology, University of Potsdam, Potsdam, Germany, 3 Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany Scientific interest in the brain and body interactions has been surging in recent years. One fundamental yet underexplored aspect of brain and body interactions is the link between the respiratory and the nervous systems. In this article, we give an overview of the emerging literature on how respiration modulates neural, cognitive and emotional processes. Moreover, we present a perspective linking respiration to the free-energy principle. We frame volitional modulation of the breath as an active inference mechanism Edited by: in which sensory evidence is recontextualized to alter interoceptive models. We further Yoko Nagai, propose that respiration-entrained gamma oscillations may reflect the propagation of Brighton and Sussex Medical School, United Kingdom prediction errors from the sensory level up to cortical regions in order to alter higher level Reviewed by: predictions. Accordingly, controlled breathing emerges as an easily accessible tool for Rishi R. Dhingra, emotional, cognitive, and physiological regulation. University of Melbourne, Australia Georgios D. Mitsis, Keywords: interoception, respiration-entrained neural oscillations, controlled breathing, free-energy principle, McGill University, Canada self-regulation *Correspondence: Asena Boyadzhieva [email protected] INTRODUCTION † These authors have contributed “The “I think” which Kant said must be able to accompany all my objects, is the “I breathe” which equally to this work actually does accompany them.
    [Show full text]
  • Multi-Odor Discrimination by Rat Sniffing for Potential Monitoring Of
    sensors Article Multi-Odor Discrimination by Rat Sniffing for Potential Monitoring of Lung Cancer and Diabetes Yunkwang Oh 1,2, Ohseok Kwon 3, Sun-Seek Min 4, Yong-Beom Shin 1,5, Min-Kyu Oh 2,* and Moonil Kim 1,5,* 1 Bionanotechnology Research Center, Korea Research Institute of Bioscience and Biotechnology (KRIBB) 125 Gwahang-ro, Yuseong-gu, Daejeon 34141, Korea; [email protected] (Y.O.); [email protected] (Y.-B.S.) 2 Department of Chemical and Biological Engineering, Korea University, 145 Anam-ro, Sungbuk-gu, Seoul 02841, Korea 3 Infectious Disease Research Center, Korea Research Institute of Bioscience and Biotechnology (KRIBB) 125 Gwahang-ro, Yuseong-gu, Daejeon 34141, Korea; [email protected] 4 Department of Physiology and Biophysics, Eulji University School of Medicine, 77 Gyeryong-ro, Jung-gu, Daejeon 34824, Korea; [email protected] 5 KRIBB School, Korea University of Science and Technology (UST), 217 Gajeong-ro, Yuseong-gu, Daejeon 34113, Korea * Correspondence: [email protected] (M.-K.O.); [email protected] (M.K.); Tel.: +82-2-3290-3308 (M.-K.O.); +82-42-879-8447 (M.K.); Fax: +82-2-926-6102 (M.-K.O.); +82-42-879-8594 (M.K.) Abstract: The discrimination learning of multiple odors, in which multi-odor can be associated with different responses, is important for responding quickly and accurately to changes in the external environment. However, very few studies have been done on multi-odor discrimination by animal sniffing. Herein, we report a novel multi-odor discrimination system by detection rats based on the combination of 2-Choice and Go/No-Go (GNG) tasks into a single paradigm, in which the Go response of GNG was replaced by 2-Choice, for detection of toluene and acetone, which Citation: Oh, Y.; Kwon, O.; Min, S.-S.; are odor indicators of lung cancer and diabetes, respectively.
    [Show full text]
  • Characterization of the Sniff Magnitude Test
    ORIGINAL ARTICLE Characterization of the Sniff Magnitude Test Robert A. Frank, PhD; Robert C. Gesteland, PhD; Jason Bailie, BS; Konstantin Rybalsky, BS; Allen Seiden, MD; Mario F. Dulay, PhD Objective: To evaluate the potential utility of the Sniff Results: The SMT generally showed good agreement with Magnitude Test (SMT) as a clinical measure of olfactory UPSIT diagnostic categories, although SMT scores were function. only modestly elevated in the mild and modest hypo- smia range of the UPSIT. Age-related decline in olfac- Design: Between-subject designs were used to com- tory ability was evident on the UPSIT at younger ages than pare the SMT and University of Pennsylvania Smell Iden- that seen with the SMT. As predicted, otolaryngology pa- tification Test (UPSIT) in study participants from a broad tients with olfactory complaints were found to be im- range of ages. paired on both the UPSIT and SMT. Subjects: A total of 361 individuals from retirement com- Conclusions: The SMT provides a novel method for munities and an urban university and patients from an evaluating the sense of smell that shows good general otolaryngology clinic. agreement with the UPSIT. Its minimal dependence on language and cognitive abilities provides some advan- Intervention: Study participants completed the SMT and UPSIT using standard procedures. tages over odor identification tests. There is some indi- cation that the UPSIT may be more sensitive to olfac- Main Outcome Measures: The UPSIT was scored us- tory (and/or nonolfactory) deficits. We conclude that ing standard procedures to calculate the number of cor- sniffing behavior can be exploited for the clinical evalu- rectly identified odors; a score that can range from 0 to ation of olfaction.
    [Show full text]
  • Lecture 14 --Olfaction.Pdf
    14 Olfaction ClickChapter to edit 14 MasterOlfaction title style • Olfactory Physiology • Neurophysiology of Olfaction • From Chemicals to Smells • Olfactory Psychophysics, Identification, and Adaptation • Olfactory Hedonics • Associative Learning and Emotion: Neuroanatomical and Evolutionary Considerations ClickIntroduction to edit Master title style Olfaction: The sense of smell Gustation: The sense of taste ClickOlfactory to edit Physiology Master title style Odor: The translation of a chemical stimulus into a smell sensation. Odorant: A molecule that is defined by its physiochemical characteristics, which are capable of being translated by the nervous system into the perception of smell. To be smelled, odorants must be: • Volatile (able to float through the air) • Small • Hydrophobic (repellent to water) Figure 14.1 Odorants ClickOlfactory to edit Physiology Master title style The human olfactory apparatus • Unlike other senses, smell is tacked onto an organ with another purpose— the nose. Primary purpose—to filter, warm, and humidify air we breathe . Nose contains small ridges, olfactory cleft, and olfactory epithelium ClickOlfactory to edit Physiology Master title style The human olfactory apparatus (continued) • Olfactory cleft: A narrow space at the back of the nose into which air flows, where the main olfactory epithelium is located. • Olfactory epithelium: A secretory mucous membrane in the human nose whose primary function is to detect odorants in inhaled air. Figure 14.2 The nose ClickOlfactory to edit Physiology Master title style Olfactory epithelium: The “retina” of the nose • Three types of cells . Supporting cells: Provide metabolic and physical support for the olfactory sensory neurons. Basal cells: Precursor cells to olfactory sensory neurons. Olfactory sensory neurons (OSNs): The main cell type in the olfactory epithelium.
    [Show full text]
  • Nasal Secretion Insufficiency Syndrome (New Concept of Ozena)
    Journal of Lung, Pulmonary & Respiratory Research Online Report Open Access Nasal secretion insufficiency syndrome (new concept of ozena) Abstract Volume 7 Issue 2 - 2020 The patient complained of nasal odor and was referred to a psychiatrist by the Department Toshiro Takami of Otolaryngology as a case of olfactory reference syndrome. The patient had a strong nasal Akiyama hospital, Japan odor. The doctor denied the existence of atrophic rhinitis and rhinophobia. If you look around the internet, there are many who suffer from similar conditions. Almost Correspondence: Toshiro takami, Akiyama hospital, 47-8 Kuyamadai Isahaya-shi Nagasaki-prefecture, 854-0067, Japan, all of them complain of an unusually dry nose. It was thought that Pseudomonas aeruginosa Tel 080-5211-3990, Email or some fungus grew abnormally in the devastated nasal mucosa of the endogenous nasal cavity, and due to inadequate nasal secretion, the bacterial metabolites could not be forced Received: August 22, 2020 | Published: September 18, 2020 down the throat or other parts of the body, giving off a strong nasal odor. This disorder is often neglected or diagnosed by psychiatrists as olfactory reference syndrome. The term “nasal secretion insufficiency syndrome” is used to describe this condition. This is a new concept of nasal odor disease, which remains unnoticed, partly because there is no crusting or atrophy of the native nasal cavity, and partly because endoscopy reveals only the devastation of the nasal mucosa, and partly because it is hidden behind the veil of atrophic rhinitis and ozena. In all seven cases, the foul odor is weakened, albeit temporarily, by the use of saliva- enhancing drugs.
    [Show full text]
  • Sniffing Behavior Communicates Social Hierarchy
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Elsevier - Publisher Connector Current Biology 23, 575–580, April 8, 2013 ª2013 Elsevier Ltd All rights reserved http://dx.doi.org/10.1016/j.cub.2013.02.012 Report Sniffing Behavior Communicates Social Hierarchy Daniel W. Wesson1,* directed behaviors such as grooming each corresponded 1Department of Neurosciences, Case Western Reserve with unique modulations in sniffing frequency (Figures S1C– University, Cleveland, OH 44106, USA S1E), demonstrating the reliability of video-based measures in indexing time of respiratory modulation. In order to control the moment of the first physical interac- Summary tion between rats, I used a solid black plastic divider to parti- tion them and removed this divider after 5 min of acclimation. Sniffing is a specialized respiratory behavior that is essential Upon first social interactions, sniffing behavior was character- for the acquisition of odors [1–4]. Perhaps not independent ized by highly aberrant and rapid alterations in both frequency of this, sniffing is commonly displayed during motivated and amplitude (Figure S1F), corresponding with periods of [5–7] and social behaviors [8, 9]. No measures of sniffing vigorous, bidirectional investigations directed toward the among interacting animals are available, however, calling face, flank, and anogenital regions of the individual, as well into question the utility of this behavior in the social context. as with other general exploratory behaviors (e.g., rearing). From radiotelemetry recordings of nasal respiration, I found Over continued interaction, the number of social behavioral that investigation by one rat toward the facial region of events decreased, as did sniffing frequency (Figure S1G), a conspecific often elicits a decrease in sniffing frequency reflecting habituation toward the novel conspecific.
    [Show full text]
  • Deficits in Olfactory Sensitivity in a Mouse Model of Parkinson's
    www.nature.com/scientificreports OPEN Defcits in olfactory sensitivity in a mouse model of Parkinson’s disease revealed by plethysmography of odor-evoked snifng Michaela E. Johnson1,4, Liza Bergkvist1,4, Gabriela Mercado1, Lucas Stetzik1, Lindsay Meyerdirk1, Emily Wolfrum2, Zachary Madaj2, Patrik Brundin1 ✉ & Daniel W. Wesson3 ✉ Hyposmia is evident in over 90% of Parkinson’s disease (PD) patients. A characteristic of PD is intraneuronal deposits composed in part of α-synuclein fbrils. Based on the analysis of post-mortem PD patients, Braak and colleagues suggested that early in the disease α-synuclein pathology is present in the dorsal motor nucleus of the vagus, as well as the olfactory bulb and anterior olfactory nucleus, and then later afects other interconnected brain regions. Here, we bilaterally injected α-synuclein preformed fbrils into the olfactory bulbs of wild type male and female mice. Six months after injection, the anterior olfactory nucleus and piriform cortex displayed a high α-synuclein pathology load. We evaluated olfactory perceptual function by monitoring odor-evoked snifng behavior in a plethysmograph at one-, three- and six-months after injection. No overt impairments in the ability to engage in snifng were evident in any group, suggesting preservation of the ability to coordinate respiration. At all-time points, females injected with fbrils exhibited reduced odor detection sensitivity, which was observed with the semi-automated plethysmography apparatus, but not a buried pellet test. In future studies, this sensitive methodology for assessing olfactory detection defcits could be used to defne how α-synuclein pathology afects other aspects of olfactory perception and to clarify the neuropathological underpinnings of these defcits.
    [Show full text]
  • Sniffing Fast: Paradoxical Effects on Odor Concentration Discrimination at the Levels of Olfactory Bulb Output and Behavior
    New Research Sensory and Motor Systems Sniffing Fast: Paradoxical Effects on Odor Concentration Discrimination at the Levels of Olfactory Bulb Output and Behavior Rebecca Jordan,1,2 Mihaly Kollo,1,2 and Andreas T. Schaefer1,2 https://doi.org/10.1523/ENEURO.0148-18.2018 1Neurophysiology of Behaviour Laboratory, Francis Crick Institute, London, NW1 1AT, UK and 2Department of Neuroscience, Physiology & Pharmacology, University College London, London, UK Abstract In awake mice, sniffing behavior is subject to complex contextual modulation. It has been hypothesized that variance in inhalation dynamics alters odor concentration profiles in the naris despite a constant environmental concentration. Using whole-cell recordings in the olfactory bulb of awake mice, we directly demonstrate that rapid sniffing mimics the effect of odor concentration increase at the level of both mitral and tufted cell (MTC) firing rate responses and temporal responses. Paradoxically, we find that mice are capable of discriminating fine concen- tration differences within short timescales despite highly variable sniffing behavior. One way that the olfactory system could differentiate between a change in sniffing and a change in concentration would be to receive information about the inhalation parameters in parallel with information about the odor. We find that the sniff-driven activity of MTCs without odor input is informative of the kind of inhalation that just occurred, allowing rapid detection of a change in inhalation. Thus, a possible reason for sniff modulation of the early olfactory system may be to directly inform downstream centers of nasal flow dynamics, so that an inference can be made about environmental concentration independent of sniff variance.
    [Show full text]
  • Olfactory Adaptation
    1 In: Handbook of Olfaction and Gustation, 1st Edition (R.L. Doty, ed.). Marcel Dekker, New York, 1995, pp. 257-281. Olfactory Adaptation J. Enrique Cometto-Muñiz*1,2 and William S. Cain John B. Pierce Laboratory and Yale University, 290 Congress Avenue, New Haven, CT 06519, USA *Present affiliation: University of California, San Diego, California 1Correspondence to Dr. J. Enrique Cometto-Muñiz at: [email protected] 2Member of the Carrera del Investigador Científico, Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), República Argentina 2 Table of Contents Introduction I Effects on Thresholds. II Effects on Suprathreshold Odor Intensities. III Effects on Reaction Times. IV Effects on Odor Quality. V Self-adaptation vs. Cross-adaptation. VI Ipsi-lateral vs. Contra-lateral Adaptation: Implications for Locus of Adaptation VII Adaptation and Mixtures of Odorants. VIII Adaptation and Trigeminal Attributes of Odorants. IX Cellular and Molecular Mechanisms of Adaptation. X Clinical Implications. Summary 3 Introduction The phenomenon of olfactory adaptation reflects itself in a temporary decrease in olfactory sensitivity following stimulation of the sense of smell. Olfactory adaptation can be seen in increases in odor thresholds and decreases in odor intensities. Adaptation poses issues that require understanding in their own right, such as the magnitude of desensitization, the time-course of desensitization and recovery to normal sensitivity, and ultimately the mechanisms responsible for these phenomena. In principle, however, the study of adaptation could also provide important clues regarding receptor specificity. Behind this hope lies the expectation that stimuli impinging upon many receptors in common will induce substantial cross-adaptation (where the adapting stimuli differ from the test stimuli), whereas stimuli impinging on very few receptors in common will not.
    [Show full text]
  • Adaptations of Olfactometry and Odour Measurement with COVID-19 Crisis J.M
    A publication of CHEMICAL ENGINEERING TRANSACTIONS VOL. 85, 2021 The Italian Association of Chemical Engineering Online at www.cetjournal.it Guest Editors: Selena Sironi, Laura Capelli Copyright © 2021, AIDIC Servizi S.r.l. ISBN 978-88-95608-83-9; ISSN 2283-9216 Adaptations of olfactometry and odour measurement with COVID-19 crisis J.M. Guillot IMT Mines Ales, LSR, 30319 Alès cedex, France [email protected] The year 2020 was characterised by a worldwide pandemic crisis due to dissemination of a Coronavirus, the SARS-CoV-2 also named COVID-19. Many economic and social domains were impacted by adaptions or restrictions by the objective to limit local dispersion and more global flow of the virus. Without describing all human health effects of this virus, one characteristic is temporary anosmia. In this paper, firstly the physiological impact is synthetized to explain the anosmia. Secondly, because olfactometry need human smell, adaptations of sensorial methods are described. These adapted methods were proposed by laboratories/companies in charge of olfactometry or odour measurement and mainly concern how the distance guarantees between panellists were proposed. 1. Introduction The aim of this paper is to summarize two aspects of olfactory impact of COVID-19 crisis. The first part concerns the short description of the physiological impact taking into account that many studies are in progress to study mechanisms of action of this virus on sensorial receptors. Then it is just a synthesis of scientific results or hypothesis known at the beginning of year 2021. The second part, more developed, is dedicated to technical measurement of odours.
    [Show full text]