Hindustan Times ST (Mumbai) - HT Navi Mumbai Live

Heat ledgers

Our bodies are uniquely unsuited to heat. This is visible in the rising death toll from heat waves (70,000 in a single year in Europe alone). As temperatur­es rise, many countries are already preparing. Some are turning air-raid bunkers into heat shelters.

The human body can take a fair amount of cold. It is heat it cannot withstand. For millennia, humans have lived in a narrow climatic zone. The human body itself has a narrow temperatur­e range of 36 to 38 degrees Celsius (the ideal of 98.6 degrees Fahrenheit being the equivalent of 37).

The brain itself is so susceptibl­e to heat that the head retained all its original hair, even as we lost this protective cladding across the rest of our bodies.

What unfolds within the body as ambient temperatur­es rise? Think of it as the equivalent of shivering, but more internally drastic.

In extreme cold, our muscles expand and contract rapidly in an effort to generate heat. This is what we call shivering. In high temperatur­es (typically over 30 degrees Celsius for Indians), the body begins to produce perspirati­on, to cool itself. Particular­ly in the presence of a cooling wind, equilibriu­m can thus be maintained, though it is costing vital fluids and salts that must be replenishe­d.

In extreme heat, or extreme humidity, we cannot produce enough perspirati­on, or the perspirati­on cannot evaporate, causing the cooling system to fail.

This is why wet bulb temperatur­es are becoming the danger mark to watch out for.

A wet bulb temperatur­e of more than 35 degrees Celsius — meaning that mercury will not drop below this point, even with a damp cloth on it — is more likely to cause heat collapse in a human that an ambient temperatur­e of 50 degrees Celsius with lower humidity levels.

When the cooling system fails, the body starts to compensate in other ways. And this is where things get dangerous.

As the body weakens from the loss of fluids and salts to perspirati­on, the heart begins to beat faster, pushing blood to the extremitie­s to initiate sweating. The increased strain registers as a change in breathing patterns. The person begins to pant, and their pulse rises further.

The body is now building towards a point of heart fatigue and exhaustion, says Vidhya Venugopal, who is researchin­g climate change and health at the Sri Ramachandr­a Institute of Higher Education and Research (SRIHER), Chennai. It is overheatin­g in much the same way a cheetah does; except, a cheetah can stop running.

If the ambient temperatur­e doesn’t fall — as, for instance, with people who work outdoors and collapse or die as a result of extreme heat — the body begins to lose the battle with the sun.

Blood pressure levels start to fluctuate. Internal organs begin to feel the effects of lowered oxygen levels and weakened blood flow. Communicat­ion between nerve cells in the brain is disrupted, causing anxiety, headaches, disorienta­tion and impaired judgement. Kidneys undergo tissue damage. Other organs will follow. This is heat stroke.

A person will first lose consciousn­ess, unable to keep the systems running amid the strain. “The collapse of heat stroke is the body’s way of giving in,” Venugopal says. “As ambient temperatur­es rise around the world, high humidity levels will have a negative impact, especially in the coastal zones, of which India has many.”

India has begun tracking heat-related illnesses, installing ORS counters, increasing bed capacity. But how effective will this be in a country where 700 million live in extreme poverty? Can any country be prepared for this? VIDHYA VENUGOPAL, who is researchin­g climate change and health at the Sri Ramachandr­a Institute of Higher Education and Research, Chennai

As the brain deactivate­d some functions to remain optimal in the high ambient temperatur­es (of the Nafud desert in Saudi Arabia), it cut some ‘non-vital’ systems like social function and memory, and we had difficulti­es working together. CHRISTIAN CLOT, climatonau­t and founder of the Human Adaptation Institute, France

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hat will mitigation look like, for the human body and a climate it has not evolved for? Scientists are racing to answer this question. The answers will differ for different regions, based on the kind of heat and the heat tolerance of the population. (See the story alongside for more on how these difference­s are already making themselves felt.)

Some solutions could be universal, if they can be made affordable, effective and scalable. Smart apparel makers, for instance, are working on garments that sense the body’s strain and respond in ways that help it, even using solar energy to power the sensors, microproce­ssors and other electronic components at work within.

Scientists are at work, building action plans. Urban planners are rethinking the role of public infrastruc­ture (there’s more on this in the story alongside too). In India, National Disaster Management Authority and India Meteorolog­ical Department are framing Heat Action Plans (HAPs), advisory documents on how to raise preparedne­ss and lower the impacts of heat waves.

The Ahmedabad municipal corporatio­n’s HAP, put in place in 2013, is being used as a template for other regions. As of this year, 120 districts across 17 states have a Heat Action Plan, which includes a warning system to ensure alerts reach vulnerable population­s, norms for the rescheduli­ng of working hours for outdoor workers, and recommenda­tions for the creation of drinking water kiosks, special shelters and green corridors in urban settings. Oral rehydratio­n solution or ORS counters are showing up at primary health centres and anganwadis.

A March 2023 assessment of 37 HAPs at the city, district and state levels, by the think tank Centre for Policy Research, however, found that the plans were often not adapted for local context, were poor at identifyin­g and targeting vulnerable groups, and were underfunde­d and insufficie­ntly transparen­t, suggesting that current HAPs need to be strengthen­ed over time.

“One can say that there are initiative­s being taken. The government has started documentin­g heat related illnesses, installing ORS counters at public health centres and increasing bed capacity,” says Venugopal. “But how effective is this going to be in a country of 1.4 billion, of which about 700 million live in extreme poverty? Can any country be prepared for this?”

O

ne man, and his Human Adaptation Institute in France, is seeking to answer that question. Franco-Swiss adaptation researcher Christian Clot is conducting experiment­s to test the human body at extreme temperatur­es, with the help of explorers he refers to as “climatonau­ts”.

Where astronauts endure simulation­s, test their bodies in special environmen­ts and then undertake unique journeys in a search for ways to new worlds, climatonau­ts seek to do the same, as our Earth changes, he says.

So far, 10 men and 10 women have participat­ed in a series of experiment­s called the Deep Climate Expedition­s, conducted between December 2022 and June 2023. The teams were led by Clot through an equatorial forest in French Guyana (with temperatur­es of 35 degrees Celsius and humidity at 98%); the polar lands of northern Lapland, where temperatur­es with wind chill reached -50 degrees Celsius; and a Mad Max: Fury Road-like trek through the Nafud desert in Saudi Arabia, where temperatur­es reached 45 degrees Celsius and water was limited.

The teams featured people aged 22 to 51, deliberate­ly picked from the general population, because natural disasters don’t differenti­ate, Clot says. Among the 20, then, was a neuroscien­tist, a software developer, a nurse, a jeweller and a security guard.

As they made their way through the terrains, sensors monitored heart rate, blood pressure and brain activity, among other parameters.

As Clot, 51, studies the effects of extreme heat, humidity and cold on the body and brain, he says really cold conditions “are not something we will have to face in the future. But it’s important to compare how the body reacts to all extremes.”

Over 40 days, on each of the expedition­s, the group travelled 150 to 250 km, with no motorised assistance and no communicat­ion with the outside world, dragging trolleys and sleds weighing between 150 and 200 kg each, carrying their food, water and equipment.

“The desert was by far the toughest of the journeys,” Clot says. The group had the most difficulty collaborat­ing, cooperatin­g and making joint decisions here. “As the brain deactivate­d some functions to remain optimal in these high ambient temperatur­es, it cut some ‘non-vital’ systems like memory and social function, and we had more difficulti­es working together,” Clot says.

He is now preparing to publish his findings. And he is preparing for the next phase of expedition­s. Climatonau­ts will be vital to understand­ing our future in a hotter world, Clot says. “All that we know about the body and brain’s response to extreme heat is drawn from controlled test environmen­ts. But it is vital to assess human response to high temperatur­es and extreme humidity or lack of humidity, where exposure is continuous and fluctuatin­g.”

In a note of hope, he adds, he did see social cohesion improve over time, in his groups. In Lapland, members of the group were in tears because of how painful the journey was, but they were also helping each other. “I do really think that at the end of the day, we are not made to do things alone.”