Heat exhaustion

resource Common Sources: • Elevated heart rate • Lowered blood pressure • Elevated core body temperature (not exceeding 40 °C or 104 °F) • Elevated respiratory rate • Profuse sweating • Dehydration • Serum electrolyte depletion • Weakness and fatigue • Persistent muscle cramps • Skin tingling • Nausea and vomiting • Dizziness and light-headedness • Irritability • Headache Less common Sources: == Physiology ==

The human body maintains a core body temperature at around 37 °C or 98.6 °F through mechanisms controlled by the thermoregulatory center within the hypothalamus. When the body is exposed to high ambient temperatures, intense physical exertion, or both, the thermoregulatory center will initiate several processes to dissipate more heat: • Blood vessels near the skin surface dilate, increasing blood flow to the skin to facilitate heat loss through radiation and convection • Heart rate increases to support elevated blood flow to the skin • Eccrine sweat glands in the skin produce sweat, which evaporates from the skin surface Heat cramps and heat syncope Heat-related illnesses lie on a spectrum of severity. Conditions on the lower end of this spectrum include heat cramps and heat syncope. The electrolyte depletion theory proposes that increased sweating during intense physical exertion in high ambient temperatures results in a depletion of serum electrolytes (e.g., sodium, potassium, etc.) that causes sustained involuntary muscle contractions, or heat cramps. However, the contribution of intense physical exertion and high ambient temperatures to serum electrolyte depletion in the absence of significant dehydration has been contested by more recent research, which proposes an alternative theory. The neuromuscular theory proposes that muscle fatigue increases the excitability of α1 muscle spindles and decreases the inhibitory input from Golgi tendon organs, leading to sustained involuntary muscle contractions. In heat syncope, or exercise-associated collapse, there is an increased dilation of blood vessels near the skin's surface and a pooling of blood in the lower extremities due to a decrease in vasomotor tone, which is the extent of control over the constriction and dilation of blood vessels. This results in a drop in blood pressure when not lying down and a temporary reduction in blood flow to the brain, leading to fainting. • Alterations in enzyme function • Protein denaturation • Disruption of cellular membranes. Hyperthermia causes direct cellular damage, triggering a systemic inflammatory response. This inflammatory cascade can result in multi-organ dysfunction, potentially leading to: • Acute kidney injury • Liver failure • Disseminated intravascular coagulation ==Causes==

There is increasing evidence linking higher temperatures to a variety of diseases and disorders as well as elevated mortality and morbidity rates. The Intergovernmental Panel on Climate Change (IPCC) projects that temperatures will rise by up to 1.5 °C in the future due to ongoing greenhouse gas emissions. Climate change exacerbates extreme temperatures, resulting in more intense and frequent heat waves. As this trend continues, populations with greater susceptibility to heat exhaustion, such as children, older adults, and individuals with chronic diseases, are at an increased risk. • Prolonged exposure to hot, sunny, or humid weather conditions • Extended time spent in high-temperature environments without adequate cooling • Engaging in strenuous activities through work, exercise, or sports, particularly in hot conditions • Insufficient fluid intake leading to dehydration • Overconsumption of fluids without adequate electrolyte replacement, leading to serum electrolyte depletion • Wearing tight or non-breathable clothing that does not allow heat to escape, trapping heat close to the body • Use of certain medications that impair thermoregulation, such as diuretics, antihypertensives, anticholinergics, and antidepressants • Sudden exposure to high temperatures without gradual acclimatization ==Risk factors==

Risk factors for heat exhaustion include: • Wearing dark, padded, or insulated clothing, hats, and helmets (e.g., football pads, turnout gear, etc.) that trap heat and impede cooling • Higher body fat percentage, which can hinder heat dissipation • Presence of fever, which elevates body temperature and lowers heat tolerance • Children younger than 5 years old and adults older than 65 are at a higher risk of serious heat illness due to impaired thermoregulation, even at rest, especially in hot and humid conditions without adequate cooling • People with long term medical conditions such as diabetes • Insufficient access to water, air conditioning, or other cooling methods • Use of medications that increase the risk of heat exhaustion, including diuretics, first-generation antihistamines, beta-blockers, antipsychotics, MDMA ('Ecstasy', 'Molly'), and other amphetamines ==Medication impact ==

Medications such as diuretics, antihypertensives, anticholinergics, and antidepressants can cause electrolyte imbalances, drug-induced hypohidrosis (reduced sweating), or drug-induced hyperhydrosis (excessive sweating). This disrupts the body's ability to regulate core temperature and increases the risk of heat exhaustion. Anticholinergic medications inhibit the parasympathetic arm of the autonomic nervous system involving the muscarinic M3 acetylcholine receptors, which often results in symptoms of dry mouth, increased thirst, as well as an increased risk of dehydration. Other medications containing anticholinergic properties, such as certain antidepressants and first-generation antihistamines, have comparable side effects. For patients at risk of or experiencing heat exacerbation, taking these medications can further increase their risk. Certain antidepressants, such as tricyclic antidepressants and selective serotonin reuptake inhibitors (SSRIs), as well as opioids that stimulate histamine release, can cause hyperhidrosis, leading to significant fluid and serum electrolyte depletion Beta-blockers limit the body's ability to redirect hyperthermic blood away from the body's core and towards the skin for cooling. If dehydration and electrolyte imbalances are left untreated, they can lead to severe complications, progress to a more severe heat-related illness such as a heatstroke, and can potentially be fatal. The management of drug-induced hypohidrosis and hyperhidrosis should be thoroughly evaluated and discussed with a healthcare professional. Treatment options may include discontinuation of the medication, a dose adjustment, a drug substitution to a different drug-class, adaptation to new behavioral and environmental changes, or the addition of another agent that can counteract the side effects. == Special populations ==

Pediatrics Children (under the age of 18 years old) have a lower heat tolerance compared to adults due to decreased homeostatic regulatory systems, increased metabolic rates, and decreased cardiac output. Strenuous exercise in high-temperature conditions is the leading cause of heat-related illness in children. The dehydration stemming from heat-related illness is what puts children at risk for thermoregulatory dysfunction. Thermoregulatory dysfunction only worsens the ability for children to fight heat exhaustion because it leads to decreased sweat capabilities and increased core temperature response. Similar to that of adults, the best way to combat and prevent heat exhaustion in children is to properly condition prior to exercise exertion, hydrate, allow for temperature adjustment, and clothe accordingly. The reason for these more serious adverse effects is that pregnancy causes higher metabolic and cardiovascular demands, and the presence of heat exhaustion only amplifies these demands further. The dehydration symptom of heat exhaustion is vital to overcome because proper hydration is deeply necessary for proper development of the fetus and metabolic activity. To combat the dehydration aspect, the amount of water intake must be increased from the intake amount prior to pregnancy and hot environments should be avoided to prevent sweating. ==Prevention==

Ways to prevent and lower risk of heat exhaustion include: • Public widespread announcements of heat waves or rapid increases in temperature • Staying up to date on daily weather reports • Heat shelters throughout communities • Wearing loose fitting and lighter fabric clothing • Try to stay well hydrated unless fluid intake is limited • For those who are doing lots of outdoor activities or work, find shady cool areas to rest • Avoid prolonged exposure to hot environments, such as tropical sunshine in the middle of the day, Mediterranean forests • If possible, avoid exposure to the sun during daytime , or a boiler room • Drink adequate fluids • Avoid exertion and exercise in hot weather • Avoid medications that can be detrimental to the regulation of body heat ==Diagnosis==

A diagnosis of heat exhaustion most commonly is diagnosed by medical professionals with various physical examinations. Through examination a person would have their temperature checked and questioned about their recent activity. • Urinalysis, an urinalysis or urine test is a test to measure color, clarity, pH levels, glucose concentration, and protein levels. The test additionally can check a person's kidney function, which is common to be affected by classic heat stroke. ==Treatment==

First aid First aid for heat exhaustion or heat stroke includes: • Moving the person to a shaded, fanned, or air-conditioned place • Removing any excess or tight clothing to facilitate cooling • Applying wet towels or ice packs wrapped in cloth to the forehead, neck, armpits, and groin, and using a fan to cool the person down • Lying the person down on their back and elevating their feet above head level to improve blood circulation • Having the person drink cool water or sports drinks, also referred to as electrolyte drinks, provided they are conscious, alert, and not vomiting (Only applies to heat exhaustion) • Turning the person on their side if they are vomiting to prevent choking • Monitoring the person's vital signs, which includes their heart rate, blood pressure, breathing rate, and body temperature • Monitoring the person's mental status (i.e., confusion, delirium, reduced alertness etc.) • Contacting emergency medical services if their situation does not improve rapidly or worsens Emergency medical treatment If an individual with heat exhaustion receives medical treatment, Emergency Medical Technicians (EMTs), doctors, and/or nurses may also: • Provide supplemental oxygen • Administer intravenous fluids and electrolytes if they are too confused to drink and/or are vomiting Do Not If an individual is experiencing heat exhaustion or any other heat related illness DO NOT: • Administer fever medications such as aspirin or Tylenol as they can be harmful for the individual • Administer salt tablets as they can worsen dehydration • Use alcohol or caffeine containing products as they can make it harder for the individual to control their body temperature • Give anything by mouth if the person is vomiting or unconscious ==Heat warning resources==

With high temperatures becoming more frequent, there are resources available to stay up to date on sudden changes in the weather. In the United States, OSHA in collaboration with the NIOSH have a Heat Safety Tool app that notifies their users with real time data on weather forecasts in a certain location, common side effects of heat related illnesses, and how the temperature feels like outside allowing individuals to safely plan out their day based on the weather. Additional resources include monitoring weather in your area of the United States based on zip code using weather.gov, being aware of cooling centers in your area, knowing how to save and use less energy within your household, and being well informed of certain populations who are more vulnerable to heat related illnesses than others. Apart from these resources, there are radio stations and news weather forecasts that continue to provide information on changes in the weather and temperature both globally and within your area. ==Prognosis==

After adequate rest and rehydration, most individuals typically recover from their heat exhaustion. However, when heat exhaustion is left untreated, the most common disease progression is heat stroke. According to the CDC, a typical trait indicating a person is having a heat stroke is when their body temperature reaches 40 °C/104 °F or higher in a span of 10 to 15 minutes. In addition to a high body temperature, they will also experience central nervous system dysfunction such as alteration in their mental status and slurred speech. Another possible illness that heat stroke can lead to is rhabdomyolysis or rapid injury to skeletal muscle especially when heat stroke is caused by physical exertion. When an individual experiences rhabdomyolysis, that damaged skeletal tissue releases toxic muscle components such as myoglobin into the bloodstream and can cause issues such as coca cola colored urine, myalgia, and kidney damage due to the blocked tubules to name a few. If a person is experiencing a heat stroke and is not properly treated, that can further progress to metabolic abnormalities, irreversible damage to multiple organs in the body, and death as a result. ==See also==