Academic literature on the topic 'Thermal physiological responses'
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Journal articles on the topic "Thermal physiological responses":
Zhong, Xianzhun, Hang Yu, Yin Tang, Huice Mao, and Kege Zhang. "Local Thermal Comfort and Physiological Responses in Uniform Environments." Buildings 14, no. 1 (December 24, 2023): 59. http://dx.doi.org/10.3390/buildings14010059.
Zhu, Hui, Linsheng Huang, Chuck Wah Francis Yu, and Hua Su. "Thermal comfort under weightlessness: A physiological prediction." Indoor and Built Environment 29, no. 8 (July 12, 2020): 1169–80. http://dx.doi.org/10.1177/1420326x20935279.
Klous, L., A. Psikuta, K. Gijsbertse, D. Mol, M. van Schaik, H. A. M. Daanen, and B. R. M. Kingma. "Two isothermal challenges yield comparable physiological and subjective responses." European Journal of Applied Physiology 120, no. 12 (September 20, 2020): 2761–72. http://dx.doi.org/10.1007/s00421-020-04494-3.
Eglin, Clare M. "Physiological Responses to Fire-fighting: thermal and Metabolic Considerations." Journal of the Human-Environment System 10, no. 1 (2007): 7–18. http://dx.doi.org/10.1618/jhes.10.7.
Ying, B. A., Y. L. Kwok, Y. Li, C. Y. Yeung, F. Z. Li, and S. Li. "Mathematical modeling of thermal physiological responses of clothed infants." Journal of Thermal Biology 29, no. 7-8 (October 2004): 559–65. http://dx.doi.org/10.1016/j.jtherbio.2004.08.027.
Curio, Immo. "Physiological responses during magnitude estimation of thermal nociceptive stimuli." International Journal of Psychophysiology 7, no. 2-4 (August 1989): 168–69. http://dx.doi.org/10.1016/0167-8760(89)90115-3.
Salachan, Paul Vinu, Jesper Givskov Sørensen, and Heidi Joan Maclean. "What can physiological capacity and behavioural choice tell us about thermal adaptation?" Biological Journal of the Linnean Society 132, no. 1 (November 10, 2020): 44–52. http://dx.doi.org/10.1093/biolinnean/blaa155.
Tunnah, Louise, Suzanne Currie, and Tyson J. MacCormack. "Do prior diel thermal cycles influence the physiological response of Atlantic salmon (Salmo salar) to subsequent heat stress?" Canadian Journal of Fisheries and Aquatic Sciences 74, no. 1 (January 2017): 127–39. http://dx.doi.org/10.1139/cjfas-2016-0157.
Zlatar, Tomi, Denisse Bustos, José Torres Costa, João Santos Baptista, and Joana Guedes. "Physiological and Thermal Sensation Responses to Severe Cold Exposure (−20 °C)." Safety 10, no. 1 (February 12, 2024): 19. http://dx.doi.org/10.3390/safety10010019.
Gupta, Mahesh, Sachin Kumar, S. Dangi, and Babu Jangir. "Physiological, Biochemical and Molecular Responses to Thermal Stress in Goats." International Journal of Livestock Research 3, no. 2 (2013): 27. http://dx.doi.org/10.5455/ijlr.20130502081121.
Dissertations / Theses on the topic "Thermal physiological responses":
Lewis, Stella Anne. "Physiological and cellular level responses of Enteromorpha spp. to chemical and thermal stress." Thesis, University of Plymouth, 1998. http://hdl.handle.net/10026.1/2147.
Basson, Christine Helene. "Thermal adaptation in the lizard Cordylus oelofseni : physiological and behavioural responses to temperature variation." Thesis, Stellenbosch : Stellenbosch University, 2013. http://hdl.handle.net/10019.1/95471.
ENGLISH ABSTRACT: As ectotherms, lizards are particularly vulnerable to changes in the thermal landscape and face extinction risk if they lack the capacity to rapidly adapt or behaviourally mitigate increasingly altered thermal environments. Theoretical models that predict lizards‟ response to climate change often fail to take into account the thermal characteristics of the microenvironment, the ability of lizards to behaviourally buffer climate variation in the habitat and the plastic nature of both behaviour and physiology over ecologically relevant time-scales. Here, I address this major knowledge gap using two separate research chapters in an experimental physiology approach. In Chapter 1, I investigated the temperature-dependence and plasticity of resting metabolic rate, water-loss rate and preferred body temperature of Cordylus oelofseni at several temporal scales (within and between seasons) and incorporated field observations to acquire a better understanding of this species‟ adaptive potential to buffer thermal changes in the habitat. Cordylus oelofseni showed plasticity of both behaviour and physiology in response to thermal acclimation, but relied on distinct strategies depending on the time-scale investigated. These results highlighted the complexity of underlying mechanisms used by these organisms to buffer temperature variation. In Chapter 2, I used an experimental approach to examine the energetic costs of thermoregulation in C. oelofseni and test the cost-benefit model of thermoregulation. This model‟s primary prediction states that lizards should thermoregulate carefully only when the associated costs are low. Using four enclosures that simulated different thermal qualities (temporal and spatial distributions of operative temperatures) in the habitat, I found limited support for the cost-benefit model. Lizards in the low-quality heterogeneous enclosures invested the same energetic effort and thermoregulated with similar overall accuracy as lizards in the high-quality heterogeneous enclosure. The costs incurred were not necessarily energetic, but reflected missed opportunities (e.g. less time to forage), something that, along with important interaction effects with body mass, deserves further attention when testing this model. Together, these results illustrate the importance of incorporating ecological reality at various time and spatial scales in order to make relevant predictions regarding the fate of lizards with projected climate change.
AFRIKAANSE OPSOMMING: As ektotermiese diere, is akkedisse veral sensitief vir veranderinge in die termiese landskap en staar uitsterwingsrisiko in die gesig as hulle nie die vermoë het om vinnig aan te pas of gedragsveranderinge te maak in omgewings wat toenemend verwarm nie. Teoretiese modelle wat akkedisse se reaksie op klimaatsverandering voorspel, neem dikwels nie die termiese eienskappe van die mikro-omgewing, die vermoë van akkedisse om met gedragsveranderinge klimaat variasie in die habitat te buffer en die plastieke aard van beide gedrag en fisiologie oor ekologies relevante tydskale in ag nie. Hier bespreek ek hierdie groot kennisgaping met behulp van twee afsonderlike navorsingshoofstukke in 'n eksperimentele fisiologie benadering. In Hoofstuk 1 het ek ondersoek ingestel na die temperatuur-afhanklikheid en plastisiteit van rustende metaboliese tempo, waterverlies tempo en voorkeur liggaamstemperatuur van Cordylus oelofseni by verskeie tydskale (binne en tussen seisoene) en inkorporeer veld waarnemings om 'n beter begrip te verkry van hierdie spesie se aanpasbare potensiaal om termiese veranderinge in die habitat te buffer. Cordylus oelofseni het plastisiteit van beide gedrag en fisiologie in reaksie op hitte-akklimatisering getoon, maar staatgemaak op verskillende strategieë, afhangende van die tyd-skaal wat ondersoek is. Hierdie resultate beklemtoon die kompleksiteit van die onderliggende meganismes wat gebruik word deur hierdie organisme om temperatuur verandering te buffer. In Hoofstuk 2 het ek 'n eksperimentele benadering gebruik om die energiekoste van termoregulering in C. oelofseni te ondersoek en die kostevoordeel model van termoregulering te toets. Hierdie model se primêre voorspelling verklaar dat akkedisse slegs versigtig moet termoreguleer wanneer die gepaardgaande koste laag is. Deur gebruik te maak van vier afskortings wat verskillende termiese eienskappe gesimuleer het (tyd en ruimtelike verspreiding van operatiewe temperature) in die habitat, het ek beperkte ondersteuning gevind vir die koste-voordeel model. Akkedisse in die lae-gehalte heterogene afskortings het dieselfde energieke moeite belê en getermoreguleer met soortgelyke algehele akkuraatheid as akkedisse in die hoë-gehalte heterogene kamp. Die kostes wat aangegaan is, is nie noodwendig energiek nie, maar weerspieël geleenthede wat gemis is (bv. minder tyd om kos te soek), iets wat, saam met belangrike interaksie effekte met liggaamsmassa, verdere aandag verdien wanneer hierdie model getoets word. Tesame illustreer hierdie resultate die belangrikheid van die integrasie van ekologiese werklikheid op verskillende tyd en ruimtelike skale, om relevante voorspellings oor die lot van akkedisse met geprojekteerde klimaatsverandering te kan maak.
Barwood, Martin James. "Psychophysiology of survival : the impact of psychological strategies on the physiological responses to thermal environments." Thesis, University of Portsmouth, 2005. https://researchportal.port.ac.uk/portal/en/theses/psychophysiology-of-survival(5abcbf6a-c797-468f-bbf2-3a62e999d79d).html.
Yanagi, Junior Tadayuki. "Partial surface wetting to relieve acute thermal stress of laying hens." Universidade Federal de Viçosa, 2002. http://www.locus.ufv.br/handle/123456789/11515.
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Um sistema de medição e controle foi desenvolvido para o estudo de respostas fisiológicas de aves sujeitas a mudanças térmicas como meio de alívio de estresse térmico. O sistema faz o controle automático da temperatura (t a,SP ±0,2 oC) e da umidade relativa do ar (RH SP ±2 %); sendo que a velocidade do ar foi controlada manualmente (V SP ±0,1 m· s -1 ); e contínuo armazenamento das termografias (ex., temperatura superficial, t surf ) e da temperatura corporais (t b ) dos animais. As condições térmicas controladas na zona de ocupação animal (AZO) são atingidas pela operação de um pequeno túnel de vento (V = 0 to 1,5 m· s -1 ) colocado no interior de uma sala ambiental com t a e RH controlados (5,0 m comprimento × 3,5 m largura × 3,0 m altura). Os valores desejados de t a e RH foram alcançados por meio de aquecedores e umidificadores controlados em dois estágios via um módulo de controle e medição programável, e periféricos. Termografias (discernabilidade de 0.06°C) são adquiridas com uma camera infravermelho cuja operação é controlada remotamente por um PC. t b (±0.1°C) é armazenado em uma unidade de telemetria, sem a necessidade de intervenção cirurgica, que também é conectado a um PC. Em adição, um sistema de video tem sido usado para observar e arquivar os comportamentos do animal. A instrumentação desenvolvida foi usada em um experimento para ajustar equações empíricas para descrever as necessidades de molhamento parcial da superfície em galinhas poedeiras (Hy-Line W98, com 34 ± 1 semanas) sujeitas a condições de estresse térmico. A água necessária para limitar o aumento da temperatura superficial das galinhas foi expressada em termos de intervalo de aspersão (SI 10 , min) para uma dosagem constante (10 ml· aspersão -1 ) ou para uma taxa de evaporação (ER, ml.min -1 ) de água aspergida. As exposições térmicas consistiram de uma combinação fatorial de 3 temperaturas de bulbo seco (t db ) (35, 38 e 41 °C) x 2 temperaturas de ponto de orvalho (t dp ) (21,1 e 26,7 °C) x 3 velocidades do ar (V) (0,2, 0,7 e 1,2 m· s -1 ). As condições ambientais foram expressas como 18 combinações de déficit de vapor de pressão do ar (VPD air ) x V. ER foi diretamente proporcional ao produto VPD air · V . As relações podem servir como a base para a otimizar o sistema de resfriamento superficial intermitente para alívio de estresse térmico em galinhas criadas em gaiolas. Ademais, um índice de desconforto térmico (TDI) foi derivado com base nas respostas fisiológicas, temperatura superficial (t surf ) e temperatura corporal (t b ), de galinhas sujeitas a exposições térmicas. Com base no aumento da t b aos 50 min de exposição térmica (Δt b,50 ), um TDI foi relacionado ao VPD air e a V da seguinte forma: TDI = -15.17 + 18.62 (t db ) n – 0.92 · (VPD air · V ) n . Usando TDI, quatro zonas de desconforto térmico (segura, alerta, perigo e fatal) foram definidas para as várias combinações de condições térmicas. Um modelo teórico de transferência de calor e massa em regime transiente também foi proposto para predizer Δt b,50 em função das condições ambientais, das condições fisiológicas das aves e do nível de molhamento (β). O modelo proporciona uma ferramenta conveniente e interativa para determinar Δt b,50 nas galinhas submetidas ou não ao molhamento superficial para t db variando de 35 a 38 °C.
A control and measurement system was developed for studying physiological responses of poultry to thermal challenges and means of thermal stress relief. The system features automatic control of air temperature (t a,SP ±0.2 oC) and relative humidity (RH SP ± 2 %); manual setting of air velocity (V SP ± 0.1 m· s -1 ); and continuous recording of thermographs (i.e., core body temperature (t b ) of the animal. surface temperature, t surf ) and The controlled thermal conditions in the animal-occupied zone (AOZ) are achieved through operation of a small wind tunnel (V = 0 to 1.5 m· s -1 ) inside a t a - and RH-controlled environmental room (5 m L × 3.5 m W × 3.0 m H). Target t a and RH values are achieved by controlling auxiliary heaters and humidifiers in two stages via a programmable measurement and control module and peripherals. Thermographs (0.06°C discernability) are acquired with an infrared (IR) imager whose operation is remotely controlled by a PC. Core body temperature (t b , ±0.1°C) is recorded with a surgery-free telemetric sensing unit that is also interfaced with a PC. In addition, a video monitoring system is used to observe and archive animal behaviors. The instrumentation developed was used in an experiment to establish empirical equations to describe the need of partial surface wetting for cooling laying hens (Hy-Line W-98, 34 ±1 wk old) subjected to a range of thermal stress conditions. The thermal exposures consisted of a factorial combination of 3 dry bulb temperatures (t db ) (35, 38 and 41 °C) × 2 dew point temperatures (t dp ) (21.1 and 26.7 ° C) × 3 air velocities (V) (0.2, 0.7 and 1.2 m· s - ). The environmental conditions were expressed as 18 combinations of air vapor pressure deficit (VPD air ) × V. The water necessary to limit hen surface temperature from rising was expressed in terms of sprinkle interval (SI 10 , min) for a constant spray dosage (10 ml· spray -1 ) or evaporation rate (ER, ml· min -1 ) of the sprayed water. ER was directly proportional to VPD air · V . The relationships may serve as the basis for optimizing an intermittent partial surface cooling system for thermal stress relief of caged layers. Also from the study, a thermal discomfort index (TDI) was derived based on physiological responses, surface temperature (t surf ) and core body temperature (t b ) of the control (non-cooled) hens. Based on t b rise after 50 min of thermal exposure (Δt b,50 ), TDI related to VPD air and V as: TDI = -15.17 + 18.62 (t db ) n – 0.92· (VPD air · was V ) n . Using TDI, four zones of thermal discomfort (safe, alert, danger, and fatal) were defined for various combinations of thermal conditions. Furthermore, theoretical transient heat and mass transfer model was proposed to predict Δt b,50 as a function of environmental conditions, physiological responses of the hens and surface wetness level (β). The model provides a convenient, interactive tool for determining Δt b,50 on wetted and non-wetted hens for t db ranging from 35 to 38 °C.
Gerrett, Nicola. "Body mapping of perceptual responses to sweat and warm stimuli and their relation to physiological parameters." Thesis, Loughborough University, 2012. https://dspace.lboro.ac.uk/2134/11000.
Scucchia, Federica. "Transcriptional profiles inferring thermal stress responses of the coral Oculina patagonica from the Eastern Mediterranean Sea." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2019. http://amslaurea.unibo.it/17967/.
Rutledge, Charles Jerry 1941. "Physiological Ecology, Population Genetic Responses and Assemblage Stability of Fishes in Two Southwestern Intermittent Stream Systems." Thesis, University of North Texas, 1991. https://digital.library.unt.edu/ark:/67531/metadc277808/.
Bennett, Wayne A. (Wayne Arden). "Responses of Selected Texas Fishes to Abiotic Factors, and an Evaluation of the Mechanisms Controlling Thermal Tolerance of the Sheepshead Minnow." Thesis, University of North Texas, 1994. https://digital.library.unt.edu/ark:/67531/metadc277819/.
Hall, Laun William. "The Evaluation Of Dietary Betaine, Pre And Probiotics, Transitional Substrates, And B-Mercaptoacetate On Physiological, Metabolic, Hormonal And Production Responses In Lactating Holstein Cows Subjected To Thermal Stress." Diss., The University of Arizona, 2014. http://hdl.handle.net/10150/333473.
Morell, Alaia. "Dynamiques éco-évolutives des espèces exploitées en Mer du Nord en réponse à des variations biotiques et abiotiques de l'environnement." Electronic Thesis or Diss., Université de Lille (2022-....), 2022. http://www.theses.fr/2022ULILR079.
Global change scenarios are valuable for guiding management and governance strategies, stimulating decision making, and increasing collective awareness of future biodiversity trends. The degree of realism and integration of ecosystem models used for this purpose is constantly improving, but they still often neglect the evolution of marine populations in future projections. However, marine populations adapt to global changes, either through phenotypic plasticity or evolution, through modifications of their biological characteristics such as life history traits, physiological and bioenergetic traits. The challenge of this thesis is to develop an ecosystem model that allows the exploration of biodiversity scenarios at intra- and inter-specific scales by explicitly representing the phenotypic plasticity of life history traits, their genetic variability, selection and evolution under the combined influence of fisheries and climate change, and the resulting genetic drift and loss of genetic diversity. Applied to the North Sea, this new model is used to understand the processes responsible for changes in life history traits, whether they are of plastic or evolutionary origin. On the one hand, the bioenergetic processes underlying plastic changes are studied by an original approach comparing the differences between the fundamental and realized thermal response curves for different species and life history stages. On the other hand, changes in life history traits are explored through an evolutionary lens by taking into account multiple selection pressures such as fishing, prey-predator interactions and climate change.The integration of plastic and evolutionary processes in ecosystem models allows to describe the inter-individual variability of biological traits and to understand their temporal trends observed in the marine environment. In this way, it responds to the crucial issue of credibility of intra- and inter-specific biodiversity projections under scenarios combining climate and fisheries. The integration of these processes will also allow to quantify more precisely the synergistic and antagonistic effects of these two pressures and to take into account the capacity of populations to adapt to global changes in order to estimate more reliably their resilience
Books on the topic "Thermal physiological responses":
Thermal comfort and physiological responses during exercise in a warm-humid environment among young men who wore selected upper body garments. 1989.
Thermal comfort and physiological responses during exercise in a warm-humid environment among young men who wore selected upper body garments. 1986.
Thermal comfort and physiological responses during exercise in a warm-humid environment among young men who wore selected upper body garments. 1989.
Thermal comfort and physiological responses during exercise in a warm-humid environment among young men who wore selected upper body garments. 1989.
Falk, Bareket, and Raffy Dotan. Temperature regulation. Oxford University Press, 2013. http://dx.doi.org/10.1093/med/9780199232482.003.0023.
Optical-thermal response of laser-irradiated tissue. New York: Plenum Press, 1995.
Armstrong, Neil, and Willem van Mechelen, eds. Oxford Textbook of Children's Sport and Exercise Medicine. Oxford University Press, 2017. http://dx.doi.org/10.1093/med/9780198757672.001.0001.
Cheung, Stephen S., and Philip N. Ainslie. Advanced Environmental Exercise Physiology. Human Kinetics, 2022. http://dx.doi.org/10.5040/9781718220928.
Optical- Response of Laser-Irradiated Tissue (Lasers, Photonics, and Electro-Optics). Springer, 2007.
Near, Joseph C. Induction and accumulation of Hsp 70 mRNA in adult salamanders in response to different heat stresses: Including naturally occurring thermal stress conditions in the field. 1989.
Book chapters on the topic "Thermal physiological responses":
Zlatar, Tomi, J. Oliveira, J. Cardoso, D. Bustos, J. C. Guedes, and João S. Baptista. "Influence of Severe Cold Thermal Environment on Thermal Sensation and Physiological Responses." In Studies in Systems, Decision and Control, 363–72. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-14730-3_39.
Deaton, A. Shawn, Kyle Watson, Emiel A. DenHartog, and Roger L. Barker. "Effectiveness of Using a Thermal Sweating Manikin Coupled with a Thermoregulation Model to Predict Human Physiological Response to Different Firefighter Turnout Suits." In Performance of Protective Clothing and Equipment: Innovative Solutions to Evolving Challenges, 222–36. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959: ASTM International, 2020. http://dx.doi.org/10.1520/stp162420190077.
Whiteley, Nia M., and Clara L. Mackenzie. "Physiological responses of marine invertebrates to thermal stress." In Stressors in the Marine Environment, 56–72. Oxford University Press, 2016. http://dx.doi.org/10.1093/acprof:oso/9780198718826.003.0004.
S. Martin, Lisa, Emma Fraillon, Fabien P. Chevalier, and Bérengère Fromy. "Hot on the Trail of Skin Inflammation: Focus on TRPV1/TRPV3 Channels in Psoriasis." In Ion Channels - From Basic Properties to Medical Treatment [Working Title]. IntechOpen, 2022. http://dx.doi.org/10.5772/intechopen.103792.
González-Rete, Berenice, Jesús Guillermo Jiménez-Cortés, Margarita Cabrera-Bravo, Paz María Salazar-Schettino, Any Laura Flores-Villegas, José Antonio de Fuentes-Vicente, and Alex Córdoba-Aguilar. "Insect vectors of human pathogens in a warming world." In Effects of Climate Change on Insects, 287–302. Oxford University PressOxford, 2024. http://dx.doi.org/10.1093/oso/9780192864161.003.0014.
Maeda, Takafumi, Toshio Kobayashi, Kazuko Tanaka, Akihiko Sato, Shin-Ya Kaneko, and Masatoshi Tanaka. "Seasonal differences in physiological and psychological responses to hot and cold environments in the elderly and young males." In Environmental Ergonomics - The Ergonomics of Human Comfort, Health and Performance in the Thermal Environment, 35–41. Elsevier, 2005. http://dx.doi.org/10.1016/s1572-347x(05)80007-2.
Castillo-Pérez, Ulises, Michael L. May, and Alex Córdoba-Aguilar. "Thermoregulation in Odonata." In Dragonflies and Damselflies, 101–12. 2nd ed. Oxford University PressOxford, 2022. http://dx.doi.org/10.1093/oso/9780192898623.003.0008.
Tokura, Hiromi. "Physiological significance of bright vs. dim light intensities during the daytime for thermoregulatory responses, digestive functions and evening dressing behavior in the cold." In Environmental Ergonomics - The Ergonomics of Human Comfort, Health and Performance in the Thermal Environment, 25–30. Elsevier, 2005. http://dx.doi.org/10.1016/s1572-347x(05)80005-9.
Holman, J. Alan. "Herpetological Species as Paleoenvironmental Indicators." In Pleistocene Amphibians and Reptiles in Britain and Europe. Oxford University Press, 1998. http://dx.doi.org/10.1093/oso/9780195112320.003.0010.
O’Donnell, Colin F. J., and Jane A. Sedgeley. "Causes and Consequences of Tree-Cavity Roosting in a Temperate Bat, Chalinolobus tuberculatus, from New Zealand." In Functionaland Evolutionary Ecology of Bats, 308–28. Oxford University PressNew York, NY, 2006. http://dx.doi.org/10.1093/oso/9780195154726.003.0017.
Conference papers on the topic "Thermal physiological responses":
Ji, Lili, Abdelaziz Laouadi, Chang Shu, Abhishek Gaur, and Michael Lacasse. "Physiological modeling of thermal responses of the elderly under heat-stressful conditions." In 2021 Building Simulation Conference. KU Leuven, 2021. http://dx.doi.org/10.26868/25222708.2021.31075.
S. V. Matarazzo, I. J. O. Silva, M. Perissinotto, D. J. Moura, and S. A. A Fernandes. "THERMAL CONDITIONED IN RESTING AREA OF FREESTALL FACILITIES AND ITS CONSEQUENCES ON PRODUCTIVE AND PHYSIOLOGICAL RESPONSES IN DAIRY COWS." In 2005 Tampa, FL July 17-20, 2005. St. Joseph, MI: American Society of Agricultural and Biological Engineers, 2005. http://dx.doi.org/10.13031/2013.19474.
Bähr, Sabina, and Fabian Edel. "The effect of colored light in the vehicle interior on the thermal comfort and thermal responses of vehicle occupants." In 14th International Conference on Applied Human Factors and Ergonomics (AHFE 2023). AHFE International, 2023. http://dx.doi.org/10.54941/ahfe1003793.
Joshi, Prachi, Hirak Banerjee, Avdhoot V Muli, Aurobinda Routray, and Priyadarshi Patniak. "Study of Emotional contagion through Thermal Imaging: A pilot study using noninvasive measures in young adults." In 15th International Conference on Applied Human Factors and Ergonomics (AHFE 2024). AHFE International, 2024. http://dx.doi.org/10.54941/ahfe1004755.
Micoulet, Alexandre, and Joachim P. Spatz. "Single Cell Mechanics." In ASME 2003 International Mechanical Engineering Congress and Exposition. ASMEDC, 2003. http://dx.doi.org/10.1115/imece2003-43280.
Salloum, M., N. Ghaddar, and K. Ghali. "A New Transient Bio-Heat Model of the Human Body." In ASME 2005 Summer Heat Transfer Conference collocated with the ASME 2005 Pacific Rim Technical Conference and Exhibition on Integration and Packaging of MEMS, NEMS, and Electronic Systems. ASMEDC, 2005. http://dx.doi.org/10.1115/ht2005-72303.
Takano, Masahito, Kosuke Oiwa, and Akio Nozawa. "Construction of Facial Skin Temperature-Based Anomaly Detection Model for Daily Fluctuations in Health Conditions." In 9th International Conference on Kansei Engineering and Emotion Research (KEER2022). Kansei Engineering and Emotion Research (KEER), 2022. http://dx.doi.org/10.5821/conference-9788419184849.17.
Liu, Ping, Xiaomin Ren, and Lisa X. Xu. "Alternate Cooling and Heating Thermal Physical Treatment: An Effective Strategy Against MDSCs in 4T1 Mouse Mammary Carcinoma." In ASME 2012 Summer Bioengineering Conference. American Society of Mechanical Engineers, 2012. http://dx.doi.org/10.1115/sbc2012-80229.
Itani, Mariam, Nesreen Ghaddar, Kamel Ghali, Beatrice Khater, Djamel Ouahrani, and Walid Chakroun. "Experimental Study on Effective Placement of PCM Packets in Cooling Vest to Improve Performance in Warm Environment." In ASME 2017 Heat Transfer Summer Conference. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/ht2017-4756.
Song, Donghyun, Eunjee Kim, Yujin Kwon, Woojin Yoon, Baekhee Lee, Yoseob Lee, and Gwanseob Shin. "Driver Mental Stress in Response to Thermal Stress Change during Highway Driving." In WCX SAE World Congress Experience. 400 Commonwealth Drive, Warrendale, PA, United States: SAE International, 2023. http://dx.doi.org/10.4271/2023-01-0146.
Reports on the topic "Thermal physiological responses":
Yahav, Shlomo, John McMurtry, and Isaac Plavnik. Thermotolerance Acquisition in Broiler Chickens by Temperature Conditioning Early in Life. United States Department of Agriculture, 1998. http://dx.doi.org/10.32747/1998.7580676.bard.
Meiri, Noam, Michael D. Denbow, and Cynthia J. Denbow. Epigenetic Adaptation: The Regulatory Mechanisms of Hypothalamic Plasticity that Determine Stress-Response Set Point. United States Department of Agriculture, November 2013. http://dx.doi.org/10.32747/2013.7593396.bard.
Lamont, Susan J., Michael G. Kaiser, Max F. Rothschild, Michael E. Persia, Chris Ashwell, and Carl Schmidt. Breed Differences in Physiologic Response to Embryonic Thermal Conditioning and Post-hatch Heat Stress in Chickens. Ames (Iowa): Iowa State University, January 2015. http://dx.doi.org/10.31274/ans_air-180814-1316.
Yahav, Shlomo, John Brake, and Noam Meiri. Development of Strategic Pre-Natal Cycling Thermal Treatments to Improve Livability and Productivity of Heavy Broilers. United States Department of Agriculture, December 2013. http://dx.doi.org/10.32747/2013.7593395.bard.
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