Do you ever spend any moment worrying about aging and the shortness of life? A week it seems is sometimes over as quickly as it had begun in the first place. Weeks turn into months, years and decades. Neither science, nor L’Oreal can change the fact that someday we’re all going to die.
Sure, if you devoted yourself to any kind of religion you’re likely to believe in some form of “god” and an afterlife and worry less about leaving your body behind. But someone who doesn’t build his faith and beliefs on the assumption that somewhere a higher being actually exists and when whatever here is done, we’ll go to a better or worse place. Worse is sometimes hard to imagine when you turn on the news.
All you atheists, non-believers and skeptics out there: don’t you sometimes envy people who live their lives believing in a higher entity and life after death? Maybe just a little bit? I know I do. Even though I share Dawkins theory that we are what we are and once we’re done living, we’re dead and decay, but, the thought of nothingness can leave you seriously worried. I’d imagine dying it somewhat like falling asleep… without the dreams and the waking up in the morning bit. The hardest part about the whole death thing is certainly the minutes or seconds before death occurs… first and foremost, physically.
A while ago, Science Daily published a fascinating, yet morbid and kinda horrifying article on what it feels like to die in certain ways like drowning for instance. It gives you a clear(er) image of death itself and how the body reacts. Definitely an interesting read:
The “surface struggle” for breath
Just how fast people drown depends on several factors, including swimming ability and water temperature. In the UK, where the water is generally cold, 55 per cent of open-water drownings occur within 3 metres of safety. Two-thirds of victims are good swimmers, suggesting that people can get into difficulties within seconds, says Mike Tipton, a physiologist and expert in marine survival at the University of Portsmouth in the UK.
Typically, when a victim realises that they cannot keep their head above water they tend to panic, leading to the classic “surface struggle”. They gasp for air at the surface and hold their breath as they bob beneath, says Tipton. Struggling to breathe, they can’t call for help. Their bodies are upright, arms weakly grasping, as if trying to climb a non-existent ladder from the sea. Studies with New York lifeguards in the 1950s and 1960s found that this stage lasts just 20 to 60 seconds.
When victims eventually submerge, they hold their breath for as long as possible, typically 30 to 90 seconds. After that, they inhale some water, splutter, cough and inhale more. Water in the lungs blocks gas exchange in delicate tissues, while inhaling water also triggers the airway to seal shut – a reflex called a laryngospasm. “There is a feeling of tearing and a burning sensation in the chest as water goes down into the airway. Then that sort of slips into a feeling of calmness and tranquility,” says Tipton, describing reports from survivors.
That calmness represents the beginnings of the loss of consciousness from oxygen deprivation, which eventually results in the heart stopping and brain death.
One of the most common forms of exit
The most common symptom is, of course, chest pain: a tightness, pressure or squeezing, often described as an “elephant on my chest”, which may be lasting or come and go. This is the heart muscle struggling and dying from oxygen deprivation. Pain can radiate to the jaw, throat, back, belly and arms. Other signs and symptoms include shortness of breath, nausea and cold sweats.
Most victims delay before seeking assistance, waiting an average of 2 to 6 hours. Women are the worst, probably because they are more likely to experience less well-known symptoms, such as breathlessness, back or jaw pain, or nausea, says JoAnn Manson, an epidemiologist at Harvard Medical School. Survivors say they just didn’t want to make a fuss; that it felt more like indigestion, tiredness or muscle cramps than a heart attack. Then again, some victims are just in denial.
Delay costs lives. Most people who die from heart attacks do so before reaching hospital. The actual cause of death is often heart arrhythmia – disruption of the normal heart rhythm, in other words.
Even small heart attacks can play havoc with the electrical impulses that control heart muscle contraction, effectively stopping it. In about 10 seconds the person loses consciousness, and minutes later they are dead.
Patients who make it to hospital quickly fare much better; in the UK and US more than 85 per cent of heart attack patients admitted to hospital survive to 30 days. Hospitals can deploy defibrillators to shock the heart back into rhythm, and clot-busting drugs and artery-clearing surgery.
Bleeding to death
Several stages of haemorrhagic shock
The speed of exsanguination, as bleeding to death is known, depends on the source of the bleed, says John Kortbeek at the University of Calgary in Alberta, Canada, and chair of Advanced Trauma Life Support for the American College of Surgeons. People can bleed to death in seconds if the aorta, the major blood vessel leading from the heart, is completely severed, for example, after a severe fall or car accident.
Death could creep up much more slowly if a smaller vein or artery is nicked – even taking hours. Such victims would experience several stages of haemorrhagic shock. The average adult has 5 litres of blood. Losses of around 750 millilitres generally cause few symptoms. Anyone losing 1.5 litres – either through an external wound or internal bleeding – feels weak, thirsty and anxious, and would be breathing fast. By 2 litres, people experience dizziness, confusion and then eventual unconsciousness.
“Survivors of haemorrhagic shock describe many different experiences, ranging from fear to relative calm,” Kortbeek says. “In large part this would depend on what and how extensive the associated injuries were. A single penetrating wound to the femoral artery in the leg might be less painful than multiple fractures sustained in a motor vehicle crash.”
It’s usually the toxic gases that prove lethal
Long the fate of witches and heretics, burning to death is torture. Hot smoke and flames singe eyebrows and hair and burn the throat and airways, making it hard to breathe. Burns inflict immediate and intense pain through stimulation of the nociceptors – the pain nerves in the skin. To make matters worse, burns also trigger a rapid inflammatory response, which boosts sensitivity to pain in the injured tissues and surrounding areas.
As burn intensities progress, some feeling is lost but not much, says David Herndon, a burns-care specialist at University of Texas Medical Branch in Galveston. “Third-degree burns do not hurt as much as second-degree wounds, as superficial nerves are destroyed. But the difference is semantic; large burns are horrifically painful in any instance.”
Some victims of severe burns report not feeling their injuries while they are still in danger or intent on saving others. Once the adrenalin and shock wear off, however, the pain quickly sets in. Pain management remains one of the most challenging medical problems in the care of burns victims.
Most people who die in fires do not in fact die from burns. The most common cause of death is inhaling toxic gases – carbon monoxide, carbon dioxide and even hydrogen cyanide – together with the suffocating lack of oxygen. One study of fire deaths in Norway from 1996 found that almost 75 per cent of the 286 people autopsied had died from carbon monoxide poisoning.
Depending on the size of the fire and how close you are to it, concentrations of carbon monoxide could start to cause headache and drowsiness in minutes, eventually leading to unconsciousness. According to the US National Fire Protection Association, 40 per cent of the victims of fatal home fires are knocked out by fumes before they can even wake up.
Beheading, if somewhat gruesome, can be one of the quickest and least painful ways to die – so long as the executioner is skilled, his blade sharp, and the condemned sits still.
The height of decapitation technology is, of course, the guillotine. Officially adopted by the French government in 1792, it was seen as more humane than other methods of execution. When the guillotine was first used in public, onlookers were reportedly aghast at the speed of death.
Quick it may be, but consciousness is nevertheless believed to continue after the spinal chord is severed. A study in rats in 1991 found that it takes 2.7 seconds for the brain to consume the oxygen from the blood in the head; the equivalent figure for humans has been calculated at 7 seconds. Some macabre historical reports from post-revolutionary France cited movements of the eyes and mouth for 15 to 30 seconds after the blade struck, although these may have been post-mortem twitches and reflexes.
If you end up losing your head, but aren’t lucky enough to fall under the guillotine, or even a very sharp, well-wielded blade, the time of conscious awareness of pain may be much longer. It took the axeman three attempts to sever the head of Mary Queen of Scots in 1587. He had to finish the job with a knife.
Decades earlier in 1541, Margaret Pole, the Countess of Salisbury, was executed at the Tower of London. She was dragged to the block, but refused to lay her head down. The inexperienced axe man made a gash in her shoulder rather than her neck. According to some reports, she leapt from the block and was chased by the executioner, who struck 11 times before she died.
The heart and the brain are most vulnerable
In accidental electrocutions, usually involving low, household current, the most common cause of death is arrhythmia, stopping the heart dead. Unconsciousness ensues after the standard 10 seconds, says Richard Trohman, a cardiologist at Rush University in Chicago. One study of electrocution deaths in Montreal, Canada found that 92 per cent had probably died from arrhythmia.
Higher currents can produce nearly immediate unconsciousness. The electric chair was designed to produce instant loss of consciousness and painless death – a step up from traditional hangings – by conducting the current through the brain and the heart.
Whether it achieves this end is debatable. Studies on dogs in 1950 found that electrodes had to be placed on either side of the head to ensure sufficient current passed through the brain to knock the creature out. There have been many botched executions – those that required several jolts to kill, or where flames leapt from the prisoner’s head, in one case due to a damp synthetic sponge being attached to the electrodes on the prisoner’s head, which was such a poor conductor it was heated up by the current and caught fire.
An analysis in 2005 of post-mortem remains from 43 prisoners sentenced to death by electrocution found the most common visible injuries to be head and leg burns where the electrodes were attached. The study’s senior author, William Hamilton, a medical examiner in Florida, concluded that these burns occurred post-mortem and that death was indeed instantaneous.
However, John Wikswo, a biophysicist at Vanderbilt University in Nashville, Tennessee, maintains that the thick, insulating bones of the skull would prevent sufficient current from reaching the brain, and prisoners could instead be dying from heating of the brain, or perhaps from suffocation due to paralysis of the breathing muscles – either way, an unpleasant way to go.
Fall from a height
If possible aim to land feet first
A high fall is certainly among the speediest ways to die: terminal velocity (no pun intended) is about 200 kilometres per hour, achieved from a height of about 145 metres or more. A study of deadly falls in Hamburg, Germany, found that 75 per cent of victims died in the first few seconds or minutes after landing.
The exact cause of death varies, depending on the landing surface and the person’s posture. People are especially unlikely to arrive at the hospital alive if they land on their head – more common for shorter (under 10 metres) and higher (over 25 metres) falls. A 1981 analysis of 100 suicidal jumps from the Golden Gate Bridge in San Francisco – height: 75 metres, velocity on impact with the water: 120 kilometres per hour – found numerous causes of instantaneous death including massive lung bruising, collapsed lungs, exploded hearts or damage to major blood vessels and lungs through broken ribs.
Survivors of great falls often report the sensation of time slowing down. The natural reaction is to struggle to maintain a feet-first landing, resulting in fractures to the leg bones, lower spinal column and life-threatening broken pelvises. The impact travelling up through the body can also burst the aorta and heart chambers. Yet this is probably still the safest way to land, despite the force being concentrated in a small area: the feet and legs form a “crumple zone” which provides some protection to the major internal organs.
Some experienced climbers or skydivers who have survived a fall report feeling focused, alert and driven to ensure they landed in the best way possible: relaxed, legs bent and, where possible, ready to roll. Certainly every little helps, but the top tip for fallers must be to aim for a soft landing. A paper from 1942 reports a woman falling 28 metres from her apartment building into freshly tilled soil. She walked away with just a fractured rib and broken wrist.
Speed of death depends on the hangman’s skill
Suicides and old-fashioned “short drop” executions cause death by strangulation; the rope puts pressure on the windpipe and the arteries to the brain. This can cause unconsciousness in 10 seconds, but it takes longer if the noose is incorrectly sited. Witnesses of public hangings often reported victims “dancing” in pain at the end of the rope, struggling violently as they asphyxiated. Death only ensues after many minutes, as shown by the numerous people being resuscitated after being cut down – even after 15 minutes.
When public executions were outlawed in Britain in 1868, hangmen looked for a less performance-oriented approach. They eventually adopted the “long-drop” method, using a lengthier rope so the victim reached a speed that broke their necks. It had to be tailored to the victim’s weight, however, as too great a force could rip the head clean off, a professionally embarrassing outcome for the hangman.
Despite the public boasting of several prominent executioners in late 19th-century Britain, a 1992 analysis of the remains of 34 prisoners found that in only about half of cases was the cause of death wholly or partly due to spinal trauma. Just one-fifth showed the classic “hangman’s fracture” between the second and third cervical vertebrae. The others died in part from asphyxiation.
Michael Spence, an anthropologist at the University of Western Ontario in London, Canada, has found similar results in US victims. He concluded, however, that even if asphyxiation played a role, the trauma of the drop would have rapidly rendered all of them unconscious. “What the hangmen were looking for was quick cessation of activity,” he says. “And they knew enough about their craft to ensure that happened. The thing they feared most was decapitation.”
US-government approved, but is it really painless?
Lethal injection was designed in Oklahoma in 1977 as a humane alternative to the electric chair. The state medical examiner and chair of anaesthesiology settled on a series of three drug injections. First comes the anaesthetic thiopental to speed away any feelings of pain, followed by a paralytic agent called pancuronium to stop breathing. Finally potassium chloride is injected, which stops the heart almost instantly.
Each drug is supposed to be administered in a lethal dose, a redundancy to ensure speedy and humane death. However, eyewitnesses have reported inmates convulsing, heaving and attempting to sit up during the procedure, suggesting the cocktail is not always completely effective.
The reason, say Leonidas Koniaris at the University of Miami Miller School of Medicine, is insufficient thiopental. He and his colleagues analysed 41 executions by lethal injection in North Carolina and California, and compared anaesthetic doses to known effects in animal models, such as pigs. As the same dose of thiopental is used regardless of body weight, the anaesthesia produced in some heavier inmates might be inadequate, they concluded.
“I think that awareness is a real possibility in a large fraction of executions,” says Koniaris. That awareness might include feelings of suffocation from paralysed lungs and the searing, burning pain of a potassium chloride injection. The effect of the paralytic, however, might mean that witnesses never see any outward signs of pain.
The Supreme Court is now going to review whether this mode of execution is legal.
It takes your breath away
Death due to exposure to vacuum is a staple of science fiction plots, whether the unfortunate gets thrown from an airlock or ruptures their spacesuit.
In real life there has been just one fatal space depressurisation accident. This occurred on the Russian Soyuz-11 mission in 1971, when a seal leaked upon re-entry into the Earth’s atmosphere; upon landing all three flight crew were found dead from asphyxiation.
Most of our knowledge of depressurisation comes from animal experiments and the experiences of pilots in accidents at very high altitudes. When the external air pressure suddenly drops, the air in the lungs expands, tearing the fragile gas exchange tissues. This is especially damaging if the victim neglects to exhale prior to decompression or tries to hold their breath. Oxygen begins to escape from the blood and lungs.
Experiments on dogs in the 1950s showed that 30 to 40 seconds after the pressure drops, their bodies began to swell as the water in tissues vaporised, though the tight seal of their skin prevented them from “bursting”. The heart rate rises initially, then plummets. Bubbles of water vapour form in the blood and travel through the circulatory system, obstructing blood flow. After about a minute, blood effectively stops circulating.
Human survivors of rapid decompression accidents include pilots whose planes lost pressure, or in one case a NASA technician who accidentally depressurised his flight suit inside a vacuum chamber. They often report an initial pain, like being hit in the chest, and may remember feeling air escape from their lungs and the inability to inhale. Time to the loss of consciousness was generally less than 15 seconds.
One mid-1960s experiment by the US Army Aeromedical Research Laboratory in New Mexico found that a chimpanzee had a period of useful consciousness of just 11 seconds before lack of oxygen caused them to pass out.
Surprisingly, in view of these apparently traumatic effects, animals that have been repressurised within 90 seconds have generally survived with no lasting damage.