Richard L. Doty

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Richard L. Doty is a professor of psychology and otorhinolaryngology at the University of Pennsylvania. He has also been the director of the University of Pennsylvania's Smell and Taste Center since 1980.

Contents

Doty is considered a world-renowned researcher in the field of olfactory functioning and dysfunction (anosmia). He is a pioneer in the development and validation of practical quantitative tests of olfaction, including the University of Pennsylvania Smell Identification Test (UPSIT). [1] [ non-primary source needed ]

Career

Doty received his Bachelor of Science degree from Colorado State University in 1966. He was awarded a Master of Arts in experimental psychology with an emphasis in psychophysics from California State University San Jose in conjunction with NASA’s Ames Research Center in 1968. Doty earned his Ph.D. in Comparative Psychology and Zoology from Michigan State University in 1971. [1] [ non-primary source needed ]

He was a postdoctoral research fellow at the University of California, Berkeley from 1971 to 1973 in the field of behavioral endocrinology and was advised by Dr. Frank Beach. At the Monell Chemical Senses Center in Philadelphia, Pennsylvania, he was a Postdoctoral Fellow from 1973-1974 and then Director of the Human Olfaction Section from 1974-1978. [1] [ non-primary source needed ]

Doty created the University of Pennsylvania Smell Identification Test (UPSIT). [2]

Doty has published over 400 papers in peer-reviewed journals related to olfactory and gustatory function,[ citation needed ] and is the editor or author of nine books, including Handbook of Olfaction and Gustation, [3] Neurology of Olfaction with Christopher Hawkes, [4] and The Great Pheromone Myth, [5] among others.

Awards

Doty has received multiple awards. In 1996, he received a James A. Shannon Award from the National Institutes of Health. Doty received the Olfactory Research Fund's Scientific Sense of Smell Award in 2000. In 2003 he received the William Osler Patient-Oriented Research Award from the University of Pennsylvania. 2004 saw Doty receive the Society of Cosmetic Chemists’ Service Award. A year later in 2005 he was recognized by the Association for Chemoreception Sciences with the Max Mozell Award for Outstanding Achievement in the Chemical Senses.

Books

Related Research Articles

<span class="mw-page-title-main">Anosmia</span> Inability to smell

Anosmia, also known as smell blindness, is the loss of the ability to detect one or more smells. Anosmia may be temporary or permanent. It differs from hyposmia, which is a decreased sensitivity to some or all smells.

<span class="mw-page-title-main">Olfactory system</span> Sensory system used for smelling

The olfactory system, or sense of smell, is the sensory system used for olfaction. Olfaction is one of the special senses directly associated with specific organs. Most mammals and reptiles have a main olfactory system and an accessory olfactory system. The main olfactory system detects airborne substances, while the accessory system senses fluid-phase stimuli.

In medicine and anatomy, the special senses are the senses that have specialized organs devoted to them:

<span class="mw-page-title-main">Olfactory tubercle</span> Area at the bottom of the forebrain

The olfactory tubercle (OT), also known as the tuberculum olfactorium, is a multi-sensory processing center that is contained within the olfactory cortex and ventral striatum and plays a role in reward cognition. The OT has also been shown to play a role in locomotor and attentional behaviors, particularly in relation to social and sensory responsiveness, and it may be necessary for behavioral flexibility. The OT is interconnected with numerous brain regions, especially the sensory, arousal, and reward centers, thus making it a potentially critical interface between processing of sensory information and the subsequent behavioral responses.

The primary olfactory cortex (POC) is a portion of the cerebral cortex. It is found in the inferior part of the temporal lobe of the brain. It receives input from the olfactory tract. It is involved in the sense of smell (olfaction).

Hyposmia, or microsmia, is a reduced ability to smell and to detect odors. A related condition is anosmia, in which no odors can be detected. Some of the causes of olfaction problems are allergies, nasal polyps, viral infections and head trauma. In 2012 an estimated 9.8 million people aged 40 and older in the United States had hyposmia and an additional 3.4 million had anosmia/severe hyposmia.

Dysosmia is a disorder described as any qualitative alteration or distortion of the perception of smell. Qualitative alterations differ from quantitative alterations, which include anosmia and hyposmia. Dysosmia can be classified as either parosmia or phantosmia. Parosmia is a distortion in the perception of an odorant. Odorants smell different from what one remembers. Phantosmia is the perception of an odor when no odorant is present. The cause of dysosmia still remains a theory. It is typically considered a neurological disorder and clinical associations with the disorder have been made. Most cases are described as idiopathic and the main antecedents related to parosmia are URTIs, head trauma, and nasal and paranasal sinus disease. Dysosmia tends to go away on its own but there are options for treatment for patients that want immediate relief.

Pamela Dalton is a cognitive psychologist. She has a Ph.D. in experimental psychology and a Masters in Public Health. Dalton is frequently quoted by the popular press as an authority on environmental odors. She has done extensive research in the fields of sick building syndrome and multiple chemical sensitivity. In the past she has worked with the United States Department of Defense on nonlethal weapons development, or the enhancement of bad odors as weapons. She currently works at the Monell Chemical Senses Center.

<span class="mw-page-title-main">Odor</span> Volatile chemical compounds perceived by the sense of smell

An odor or odour is a smell or a scent caused by one or more volatilized chemical compounds generally found in low concentrations that humans and many animals can perceive via their olfactory system. While smell can refer to pleasant and unpleasant odors, the terms scent, aroma, and fragrance are usually reserved for pleasant-smelling odors and are frequently used in the food and cosmetic industry to describe floral scents or to refer to perfumes.

<span class="mw-page-title-main">Sense of smell</span> Sense that detects smells

The sense of smell, or olfaction, is the special sense through which smells are perceived. The sense of smell has many functions, including detecting desirable foods, hazards, and pheromones, and plays a role in taste.

Olfactory memory refers to the recollection of odors. Studies have found various characteristics of common memories of odor memory including persistence and high resistance to interference. Explicit memory is typically the form focused on in the studies of olfactory memory, though implicit forms of memory certainly supply distinct contributions to the understanding of odors and memories of them. Research has demonstrated that the changes to the olfactory bulb and main olfactory system following birth are extremely important and influential for maternal behavior. Mammalian olfactory cues play an important role in the coordination of the mother infant bond, and the following normal development of the offspring. Maternal breast odors are individually distinctive, and provide a basis for recognition of the mother by her offspring.

<span class="mw-page-title-main">Sniffing (behavior)</span> Nasal inhalation to sample odors

Sniffing is a perceptually-relevant behavior, defined as the active sampling of odors through the nasal cavity for the purpose of information acquisition. This behavior, displayed by all terrestrial vertebrates, is typically identified based upon changes in respiratory frequency and/or amplitude, and is often studied in the context of odor guided behaviors and olfactory perceptual tasks. Sniffing is quantified by measuring intra-nasal pressure or flow or air or, while less accurate, through a strain gauge on the chest to measure total respiratory volume. Strategies for sniffing behavior vary depending upon the animal, with small animals displaying sniffing frequencies ranging from 4 to 12 Hz but larger animals (humans) sniffing at much lower frequencies, usually less than 2 Hz. Subserving sniffing behaviors, evidence for an "olfactomotor" circuit in the brain exists, wherein perception or expectation of an odor can trigger brain respiratory center to allow for the modulation of sniffing frequency and amplitude and thus acquisition of odor information. Sniffing is analogous to other stimulus sampling behaviors, including visual saccades, active touch, and whisker movements in small animals. Atypical sniffing has been reported in cases of neurological disorders, especially those disorders characterized by impaired motor function and olfactory perception.

Richard Eugene Frye is an American autism researcher and associate professor at Arizona Children's Hospital in Phoenix, and formerly of the University of Arkansas for Medical Sciences's department of pediatrics, as well as the Director of the Autism Multispecialty Clinic at Arkansas Children’s Hospital. Frye was formerly a faculty member at the University of Texas Health Science Center at Houston's division of child and adolescent neurology.

<span class="mw-page-title-main">University of Pennsylvania Smell Identification Test</span> Test of a persons olfactory system

The University of Pennsylvania Smell Identification Test (UPSIT) is a test that is commercially available for smell identification to test the function of an individual's olfactory system.

The peanut butter test is a diagnostic test which aims to detect Alzheimer's disease by measuring subjects' ability to smell peanut butter through each nostril. The original study, published in the Journal of the Neurological Sciences in October 2013, involves measuring the ability of people to smell peanut butter held close to their nose. The researchers believe that people with Alzheimer's were not able to smell the peanut butter as well through their left nostril as their right one.

The olfactory system is the system related to the sense of smell (olfaction). Many fish activities are dependent on olfaction, such as: mating, discriminating kin, avoiding predators, locating food, contaminant avoidance, imprinting and homing. These activities are referred to as “olfactory-mediated.” Impairment of the olfactory system threatens survival and has been used as an ecologically relevant sub-lethal toxicological endpoint for fish within studies. Olfactory information is received by sensory neurons, like the olfactory nerve, that are in a covered cavity separated from the aquatic environment by mucus. Since they are in almost direct contact with the surrounding environment, these neurons are vulnerable to environmental changes. Fish can detect natural chemical cues in aquatic environments at concentrations as low as parts per billion (ppb) or parts per trillion (ppt).

<span class="mw-page-title-main">Androstadienol</span> Chemical compound

Androstadienol, or androsta-5,16-dien-3β-ol, is a 16-androstene class endogenous steroid, pheromone, and chemical intermediate to several other pheromones that is found in the sweat of both men and women.

Odor molecules are detected by the olfactory receptors in the olfactory epithelium of the nasal cavity. Each receptor type is expressed within a subset of neurons, from which they directly connect to the olfactory bulb in the brain. Olfaction is essential for survival in most vertebrates; however, the degree to which an animal depends on smell is highly varied. Great variation exists in the number of OR genes among vertebrate species, as shown through bioinformatic analyses. This diversity exists by virtue of the wide-ranging environments that they inhabit. For instance, dolphins that are secondarily adapted to an aquatic niche possess a considerably smaller subset of genes than most mammals. OR gene repertoires have also evolved in relation to other senses, as higher primates with well-developed vision systems tend to have a smaller number of OR genes. As such, investigating the evolutionary changes of OR genes can provide useful information on how genomes respond to environmental changes. Differences in smell sensitivity are also dependent on the anatomy of the olfactory apparatus, such as the size of the olfactory bulb and epithelium.

Smell training or olfactory training is the act of regularly sniffing or exposing oneself to robust aromas with the intention of regaining a sense of smell. The stimulating smells used are often selected from major smell categories, such as aromatic, flowery, fruity, and resinous. Using strong scents, the patient is asked to sniff each different smell for a minimum of 20 seconds, no less than two times per day, for three to six months or more. It is used as a rehabilitative therapy to help people who have anosmia or post-viral olfactory dysfunction, a symptom of COVID-19. It was considered a promising experimental treatment in a 2017 meta-analysis.

<span class="mw-page-title-main">Olfactic communication</span> Social interaction through smell

Olfactic communication is a channel of nonverbal communication referring to the various ways people and animals communicate and engage in social interaction through their sense of smell. Our human olfactory sense is one of the most phylogenetically primitive and emotionally intimate of the five senses; the sensation of smell is thought to be the most matured and developed human sense.

References

  1. 1 2 3 "Richard L. Doty - Faculty Biosketch". University of Pennsylvania. Retrieved November 30, 2024.
  2. Doty, Richard; L Mackay-Sim, A, University of Pennsylvania smell identification test: Australian Journal of Oto-Laryngology, via ’’findarticles.com Oct 2001, Accessed 8 March 2010
  3. 1 2 Toller, Steve Van (1995). "Handbook of Olfaction and Gustation". Chemical Senses. 20 (4): 477–478. doi:10.1093/chemse/20.4.477. ISSN   0379-864X.
  4. 1 2 Jellinger, K. A. (July 2009). "The Neurology of Olfaction". European Journal of Neurology. 16 (7): e141. doi:10.1111/j.1468-1331.2009.02683.x.
  5. 1 2 Baker, Ann Eileen Miller (September 2011). "The Great Pheromone Myth . By Richard L. Doty. Baltimore (Maryland): Johns Hopkins University Press. $65.00. xiii + 278 p.; ill.; name and subject indexes. ISBN: 978-0-8018-9347-6. 2010". The Quarterly Review of Biology. 86 (3): 231. doi:10.1086/661121. ISSN   0033-5770.
  6. Delius, Juan D. (April 1, 1979). "Mammalian olfaction, reproductive processes and behavior: R.L. Doty (Editor). Academic Press, New York, N.Y., 1976, 343 pp., US $23.50, ISBN 0-12-221250-9". Behavioural Processes. 4 (1): 91–93. doi:10.1016/0376-6357(79)90056-1. ISSN   0376-6357.
  7. Toller, Steve Van (January 1992). "David G. Laing Richard L. Doty Winrich Breipohl The Human Sense of Smell 1991 Springer-Verlag DM198.00/£70.50 (xvi + 395 pages) ISBN 3 540 53355 9". Trends in Food Science & Technology. 3: 336–337. doi:10.1016/S0924-2244(10)80031-7.
  8. Hirsch, A. R. (December 24, 2003). "Handbook of Olfaction and Gustation". JAMA: The Journal of the American Medical Association. 290 (24): 3257–3258. doi:10.1001/jama.290.24.3257. ISSN   0098-7484.

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