Nirmal

From childhood, we are taught that the human body has five senses. I’m sure we can all recite them: sight, hearing, touch, taste, and smell. This list has remained unchanged since the time of Aristotle. To most people, a “sixth sense” refers either to one outside the realm of the scientific, or one that simply does not exist in most humans.

However, ask a neurologist how many senses the human body has, and you might get a surprising answer. Many identify nine or more senses- some listing as many as twenty-one. The first category of senses is the “special” senses, including the familiar sight, hearing, taste, and smell. The second category is made up of the somatic senses, which we usually lump under “touch”- including our perception of pressure, heat, and pain. The third category, however, is not nearly as well-known. These are the interoceptive senses- those that deal with data originating in the body itself.

It is fairly obvious what happens to a person when a sense fails. Many members of society are missing one or more senses. It is common knowledge that blindness is the absence of sight. Deafness, of hearing. Everyone knows what it’s like to lose taste and smell as well; this loss accompanies every head cold. But what happens when the body loses knowledge of itself is a far stranger occurrence.

The interoceptive senses are lumped together in various configurations, but there are basically three. The first– balance– is the sense of the body’s alignment. This is the sense that keeps an animal upright; the famous ability of cats to always land on its feet, for example, is due to this sense. The organic sense is what alerts the body to its internal condition; this is how you know that you are hungry or thirsty. The third sense is known as proprioception. This, put simply, is the brain’s knowledge of the relative positions of the body’s parts.

To visualize this sense, close your eyes and extend your hand in a random direction. Now identify in your mind its exact position and open your eyes. Note that your brain was well aware of your hand’s position, even though none of the “classic” five senses were currently detecting it. This is proprioception. If you want another example of this sense, try driving erratically enough to attract official attention. The familiar walk-the-line and finger-to-nose sobriety tests that you will be subjected to are yet more examples of what your body can do- or at least should be able to do- thanks to proprioception.

The loss of this ability is known by several names. Proprioception Deficit Disorder, Sacks’ Syndrome, and Descartes’ Disease are all titles for the same illness, which is a complete and total failure of the body’s knowledge of itself. Since it is a rare disorder, it is difficult to say what the premonitory symptoms are. However, there have been reports that the first symptoms are extremely vivid dreams of lost motor function or physical control. These are followed by an increasing lack of coordination, culminating in full-blown proprioceptive failure. At this point, the human mind is completely unaware of its own body. Sufferers report a “disembodied” feeling, as if the mind and body have completely separated.

Oliver Sacks, one of the disease’s namesakes, reported perhaps the first recognized case of the disorder. In The Disembodied Woman, he describes the process by which a patient- whom he calls “Christina”- succumbed to PDD. In a matter of days, she transitioned from a healthy and active mother of two to a helpless physical wreck, with no sensation of her own body. The preliminary testing showed that her nerves were in perfect working order; she could feel physical sensations nearly as well as she always had. However, somewhere between mind and body a roadblock had developed, preventing her brain from forming an accurate body image- or indeed a body image at all.

The results of this disorder are logical once one understands the concept of proprioception. Think of all the activities in a typical day that require the body’s knowledge of its own position. If you carry your briefcase to the car while fumbling for the keys, your legs do not buckle because they are currently unsupervised. Your hand does not drop its load because you neglected for a moment to think, hold on to the briefcase. Your jaw does not hang slack because you weren’t specifically concentrating on keeping your mouth closed. But for someone with PDD, these are exactly the type of things that happen.

Currently there is no known cure for PDD. Sometimes the body self-corrects, but in Christina’s case it never did. Like any other sensory-deprived person, victims of PDD begin to naturally replace the missing sense with those that remain. Christina replaced it with sight. Since she no longer possessed an intuitive knowledge of where her respective body parts were located, she built up that knowledge herself using her eyes. If she wanted to pick up a cup of coffee, she watched her hand carefully until she had successfully put it down again. If she wanted to walk across the room, she had to supervise her feet until she was safely sitting on the other side. Sitting itself is difficult for a sufferer of PDD; if the hands are not watched carefully they will either grip the chair with white-knuckle intensity or release their hold, allowing the startled individual to slide to the floor.

In many respects, the body of a PDD victim becomes their puppet. Each movement must be carefully analyzed and put into motion; no longer can one trust the body to “just walk” or “just sit.” Thus, the movement does not look at all natural; opening a door becomes a laborious process of extend hand, tighten each finger, rotate knob, extend arm, raise foot, lower foot, and so on. Meanwhile one must not become distracted from the other foot, and who knows what is happening with the body parts not directly involved in the current process.

Fortunately, PDD is an extremely rare disorder. It is neither contagious nor genetic, and no one knows what causes the permanent variety. There is a type that is brought on by massive overdoses of vitamin B6 (pyridoxine), but it is for the most part temporary with few lingering effects. A rather eerie set of statistics suggests that, unlike most disorders, the more education one has the more likely one is to develop the affliction. This factor, as well as the initial dream symptoms, suggests that the disease could have psychophysiologic roots. However, until we know for sure, this disorder represents one of the parts of the human mind that remains a mystery. It also proves with tragic clarity the old axiom: you never know what you have until you lose it.

Comment by Nirmal: Text credit – Zack Jordan.

For centuries sailors have been telling stories of encountering monstrous ocean waves which tower over one hundred feet in the air and toss ships about like corks. Historically oceanographers have discounted these reports as tall tales– the embellished stories of mariners with too much time at sea. But in the last eleven years scientists have discovered strong evidence indicating that such massive rogue waves do exist. The phenomenon has become the subject of recent scientific study, but their origin remains a mystery of the deep.

About one ship is lost every week in the world’s oceans, mostly due to poor seamanship or severe weather. But it now seems likely that at least a small percentage of sea disappearances are due to encounters with these destructive waves. Over the years experienced captains have made very credible reports of meeting behemoth waves which appear spontaneously, cause extensive damage to their ships, and shrug back into the sea just as mysteriously as they had appeared. One account describes the appearance of a giant wave trough which onlookers likened to a “hole in the sea”, followed by a twelve-story-tall “wall of water.” To further compound the mystery, some such waves have been said to appear mid-ocean, and often in calm weather.

This rare photo of a rogue wave was taken by first mate Philippe Lijour aboard the supertanker Esso Languedoc, during a storm off Durban in South Africa in 1980. The mast seen starboard in the photo stands 25 metres above mean sea level. The wave approached the ship from behind before breaking over the deck, but in this case caused only minor damage. The mean wave height at the time was between 5-10 metres. Credits: Philippe Lijour

On the open sea, waves can commonly reach seven meters in height; or even up to fifteen in extreme weather. In contrast, some reported rogue waves have exceeded thirty meters in height. Curiously, rogue waves are often seen traveling against the prevailing current and wave directions; and unlike a tsunami, rogue waves are localized and very short-lived. Most modern merchant vessels are designed to withstand about fifteen tons of pressure per square meter, but these unusual waves exert a pressure of about one hundred tons per square meter. Needless to say, a rogue wave means big trouble for any ship it meets.

Encounters with rogue waves have been rare but memorable. In 1933 in the North Pacific, the US Navy transport USS Ramapo triangulated a rogue wave at thirty-four meters in height. In 1942, the RMS Queen Mary was transporting 15,000 US troops to Europe when it was hit by a twenty-three meter wave and nearly capsized. The giant vessel listed by about 52 degrees due to the impact, after which it slowly righted itself.

In 1978, the 37,000-ton MS Munchen radioed a garbled distress call from the mid-Atlantic. When rescuers arrived, they found only “a few bits of wreckage,” including an unlaunched lifeboat with one of its attachment pins “twisted as though hit by an extreme force.” It is now believed that a rogue wave hit the ship, causing it to capsize and sink. No survivors were ever found.

In 1996, the Queen Elizabeth 2 encountered a rogue wave of twenty-nine meters, which the Captain said “came out of the darkness” and “looked like the White Cliffs of Dover.” London newspapers said that the captain situated the vessel to “surf” the wave to avoid being sunk.

Rogue waves are most common in the Agulhas current off the east coast of South Africa, with numerous well documented cases of extreme individual waves, including some striking photographs of damaged ships. Here is shown bow damage received by Norwegian tanker Wilstar in 1974: the combination of pitch motion and a steep incoming wave can cause excessive local structural damage. One of the aims of rogue wave research is to recommend changes in ship design to make them less vulnerable in future. Credits: DLR

Despite these and other encounters with rogue waves, scientists long rejected such claims as unlikely. Anecdotal evidence is often unreliable, so researchers used computer modelling to predict the likelihood of such massive waves. Oceanographers’ findings indicated that waves higher than fifteen meters were probably very rare events, occurring perhaps once in 10,000 years. That all changed in 1995 when a freak wave hit the Draupner North Sea oil platform. The oil rig swayed a little, suffering minor damage, but its onboard measuring equipment successfully recorded the wave height at nineteen meters.

More recently, satellite photos and radar imagery have documented the existence of numerous rogue waves, and it turns out that they are far more common than previously thought. During a three-week study in 2001, radar scanning detected ten monster waves in a 1.5 million square kilometer area. Satellites and direct observations have also established that rogue waves can happen anywhere, but they are most numerous in the North Atlantic and off the western shore of South Africa. In spite of their frequency, monster waves rarely meet with sea vessels because they are so short-lived.

Giant wave detected during a global census using three weeks of raw ERS-2 SAR imagette data, carried out by the German Aerospace Centre (DLR). This SAR data set was inverted to individual wave heights and investigated for individual wave height and steepness. The wave shown here has a height of 29.8 m. Credits: DLR

Giant wave produced with a hydaulically-powered wave generator in the Giant Wave Tank in Hannover in 2002. As part of the MaxWave project, a team at the Technical University of Berlin worked on simulating their production. Their work guided by computer modelling, the team found rogue waves appear to be formed when slow-moving waves are caught up by a succession of faster waves moving at more than twice their speed, then merge together. Credits: Technical University of Berlin

The cause of rogue waves is still an area of active research. One theory under investigation cites “constructive interference,” which is a result of several smaller waves overlapping in phase, combining to produce one massive wave. Another working hypothesis is based on the “non-linear Schrödinger effect,” in which energy is “soaked up” from neighboring waves to create a monster wave. Still other researchers are looking into the possibility that wave energy is being focused by the surrounding environments, or that wind action on the surface is amplifying existing effects.

Science is necessarily skeptical of things which are beyond our observation, but now that rogue waves are a measurable phenomenon they have been officially upgraded from legend to reality. This recent finding is very telling about how little we really know about our world’s oceans, and how many secrets the sea must still hold.

Comment by Nirmal: Article Credit – Greg Bjerg