A Preliminary Study of the Effect of Dousing and Foot Immersion on Cardiovascular and Thermal Responses to Extreme Heat

Morris, Nathan B.; Gruss, Fabian; Lempert, Sarah; English, Timothy; Hospers, Lily; Capon, Anthony; Jay, Ollie

doi:10.1001/jama.2019.13051

Cited by 44 publications

(37 citation statements)

References 7 publications

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“…A growing body of scientific evidence strongly supports the efficacy of several low-resource home-based cooling solutions. For example, skin-wetting has been shown to reduce physiological heat strain, dehydration, and thermal discomfort at temperatures up to 47 °C, irrespective of humidity ( Morris et al, 2019a ). Electric fans are another low-cost, low-energy demand (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…anticholinergics) ( Cheshire and Fealey, 2008 ), effectively reducing the range of conditions under which a fan is beneficial ( Gagnon et al, 2016 ). However, any potential decrements in sweating can be compensated by externally applying water directly to the skin with a spray bottle ( Morris et al, 2019a ). Therefore, our aim was assess the potential utility of electric fan-use with light water-spraying as a stay-at-home cooling solution across the United States this summer, by comparing the biophysically modelled humidity-dependent temperature limits for this strategy to peak historical summer weather conditions.…”

Section: Introductionmentioning

confidence: 99%

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Electric fans: A potential stay-at-home cooling strategy during the COVID-19 pandemic this summer?

Hospers

Smallcombe

Morris

et al. 2020

Science of The Total Environment

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Current public health guidance designed to protect individuals against extreme heat and the ongoing COVID-19 pandemic is seemingly discordant, yet during the northern hemisphere summer, we are faced with the imminent threat of their simultaneous existence. Here we examine the environmental limits of electric fan-use in the context of the United States summer as a potential stay-at-home cooling strategy that aligns with existing efforts to mitigate the spread of SARS-COV-2.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electric fans: A potential stay-at-home cooling strategy during the COVID-19 pandemic this summer?

Hospers

Smallcombe

Morris

et al. 2020

Science of The Total Environment

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“…Moreover, the colder the water used for submersion, the faster the rates of cooling will be, necessitating less break time to recover [131]; however cooling the water to greater extents, especially in hot environments, necessitates greater equipment and electrical consumption for cooling. To address these feasibility and cost issues, adequate rest stations can be established where multiple workers are able to cool concurrently, and based on the strength of the cooling effect and that meaningful cooling occurs at as little as 20-22°C water temperature [131,132], this may be the optimal method for delivering as much cooling as possible during short periods of time.…”

Section: Personal Cooling Optionsmentioning

confidence: 99%

“…In such scenarios, however, skin wetting has the added benefit of being able to use water that may not be of a sufficient quality to drink. This aspect of skin wetting may be particularly beneficial as skin wetting has been shown to reduce natural sweat rate without incurring elevated core temperatures or heart rate [132], thereby providing a method of slowing the dehydration process when drinking water is limited. One drawback to this method is that its use is not always feasible, especially indoors and/or when large amounts of personal protective equipment are worn.…”

Section: Personal Cooling Optionsmentioning

confidence: 99%

Sustainable solutions to mitigate occupational heat strain – an umbrella review of physiological effects and global health perspectives

et al. 2020

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Background: Climate change is set to exacerbate occupational heat strain, the combined effect of environmental and internal heat stress on the body, threatening human health and wellbeing. Therefore, identifying effective, affordable, feasible and sustainable solutions to mitigate the negative effects on worker health and productivity, is an increasingly urgent need. Objectives: To systematically identify and evaluate methods that mitigate occupational heat strain in order to provide scientific-based guidance for practitioners. Methods: An umbrella review was conducted in biomedical databases employing the following eligibility criteria: 1) ambient temperatures > 28°C or hypohydrated participants, 2) healthy adults, 3) reported psychophysiological (thermal comfort, heart rate or core temperature) and/or performance (physical or cognitive) outcomes, 4) written in English, and 5) published before November 6, 2019. A second search for original research articles was performed to identify interventions of relevance but lacking systematic reviews. All identified interventions were independently evaluated by all co-authors on four point scales for effectiveness, cost, feasibility and environmental impact. Results: Following screening, 36 systematic reviews fulfilled the inclusion criteria. The most effective solutions at mitigating occupational heat strain were wearing specialized cooling garments, (physiological) heat acclimation, improving aerobic fitness, cold water immersion, and applying ventilation. Although airconditioning and cooling garments in ideal settings provide best scores for effectiveness, the limited applicability in certain industrial settings, high economic cost and high environmental impact are drawbacks for these solutions. However, (physiological) acclimatization, planned breaks, shading and optimized clothing properties are attractive alternative solutions when economic and ecological sustainability aspects are included in the overall evaluation.

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“…Then, when a greater thermal challenge is identified by the net heat transfer capacity between human and environment, the patient would be contacted by their health service (Notley et al 2018 ), and upon the discretion of the telemedicine physicians, countermeasures could be proposed to immediately lower body temperature. For example, in the absence of air conditioning, electric fan use under defined conditions and self-application of water to the skin surface have been shown to effectively lower cardiovascular strain, thermal discomfort, and sweating in healthy individuals exposed to extreme heat stress (Morris et al 2019 ). Indeed, there are many viable cooling strategies available for individuals who present with altered thermoregulatory capacity.…”

Section: Heat Symptoms Prevention Protocol For Neurologically Impairementioning

confidence: 99%

Heat risk exacerbation potential for neurology patients during the COVID-19 pandemic and related isolation

et al. 2020

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COVID-19 may increase the risk of heat-related symptoms during hot weather since vulnerable populations, including the elderly and those with neurological disabilities, must continue to self-isolate, often indoors. Within the chronic neurological patient population, indoor conditions in summer months present a hazard because of impaired and/or altered thermoregulation, including poor hydration status due to both autonomic and behavioral dysfunction(s). To address this increased risk, telemedicine protocols should include an assessment of the patient’s environmental parameters, and when combined with physiological data from wearable devices, identify those with neurological diseases who are at higher risk of heat illness. Personalized medicine during times of self-isolation must be encouraged, and using smart technology in ambient assisted living solutions, including e-health to monitor physiological parameters are highly recommended, not only during extreme weather conditions but also during times of increased isolation and vulnerability.

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A Preliminary Study of the Effect of Dousing and Foot Immersion on Cardiovascular and Thermal Responses to Extreme Heat

Cited by 44 publications

References 7 publications

Electric fans: A potential stay-at-home cooling strategy during the COVID-19 pandemic this summer?

Electric fans: A potential stay-at-home cooling strategy during the COVID-19 pandemic this summer?

Sustainable solutions to mitigate occupational heat strain – an umbrella review of physiological effects and global health perspectives

Heat risk exacerbation potential for neurology patients during the COVID-19 pandemic and related isolation

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