Justin Gregg

We currently lack strong evidence for consciousness in dolphins suggests Professor Heidi Harley in her recently published review article appearing in the Journal of Comparative Physiology A. For some (perhaps most) cognitive scientists studying animals minds, this is not a particularly controversial conclusion – a borderline truism. For other scientists – and perhaps for nearly everyone involved in issues of animal rights and animal welfare – the suggestion that dolphins are “not conscious” is simply absurd. Lurking between the truism and the absurdity of non-animal-consciousness we find a centuries-old battle over the problem of what consciousness is, and how on earth we’re meant to determine the extent to which non-human animals are conscious. Harley’s review article provides a quick introduction to this minefield of a problem, as well as a review of the current scientific evidence of consciousness in dolphins. If you’d like a quick rundown of this topic but don’t have time to read this article or the 2,500 year’s worth of philosophical musings on the topic of consciousness, I will provide a handy overview of Harley’s main points in the form of a dialogue between Phil, who represents the “of course dolphins are conscious” point of view, and Emily, who represents the “I think you’ll find it’s a bit more complicated than that” point of view. Take it away Phil and Emily:

Phil: It wasn’t that long ago that you skeptical scientist folks refused to entertain the idea that animals could even be conscious. Remember B.F. Skinner or J.B. Watson? It seems to me that scientists have always been closed minded when it comes to animal consciousness – keen to uphold the idea that only humans could even be conscious.

Emily: That might well have been true a hundred years ago, but when scientists like Donald Griffin started writing about the value of studying animal minds, a whole new field of scientific inquiry popped up, and now there are thousands upon thousands of scientists studying aspects of consciousnesses in animals.

Phil: But why is this still even a question? Isn’t it obvious that every animal needs to create a representation of the world in its mind in order to navigate its environment, find food, mate, etc? Isn’t this what consciousness is?

Emily: Not really. That’s just the way brains process and perceive incoming sensory stimuli. It’s not much different to how a solar panel with a light-sensor is able to follow the direction of the sun. Just because solar trackers can perceive light  doesn’t mean that solar panels are conscious, does it? No, the kind of complex consciousness that we know humans experience is called phenomenological consciousness – it’s the subjective experience of those stimuli/perceptions. If a solar panel experienced the light in some way, then it might well be conscious. Of course even if it did, it wouldn’t be able to tell us about it, which is why it’s so hard to investigate consciousness in non-linguistic animals (or solar panels).

Phil: So you’re saying that it’s impossible to study consciousness empirically then? Isn’t that what Nagel said? Are you suggesting that because consciousness is completely private, it’s not possible to study at all? If that’s the case, then what grounds do you have for suggesting that dolphins aren’t conscious?

Emily: I think even Nagel suggested that it’s possible to study aspects of consciousness (even though it is private). It might be hard to study consciousness, but it’s not impossible. The field of cognitive science has in fact been quite busy studying the way brains perceive and process information in ways that result in subjective experience. Have you heard of people with phantom limb syndrome? They might be missing, for example, an arm – but their mind still creates the conscious experience of the arm. Weird cases like this allow scientists to determine exactly how different parts of the brain and the body must be interacting in order to create subjective (conscious) experience.

Phil: But you’re missing an important point. Animals do more than just process stimuli to determine if they have an arm or not, or to track the direction of the sun. Plants can follow the direction of a light source, and maybe even sense when they are missing a leaf or something, and I am not suggesting that this means plants are conscious. I am talking about consciousness in animals like dolphins, that produce complex behaviors, including solving problems, tool use, etc. Surely the ability to think about and thus subjectively experience all of these incoming stimuli is required by any animal in order to produce complex behavior?

Emily: It might seem so, but there is plenty of evidence to suggest that brains can produce rather complex behavior without consciousness. Studies in humans show that we perform so much of our complex behavior unconsciously – from driving a car to investing our savings. There’s every reason to believe that most – if not all – non-human animal behavior we see could be being produced by an otherwise intelligent mind that is not producing subjective experiences of its own decision making processes.

Phil: This seems ludicrous to me. Are you saying that if I see a chimpanzee and a human both solve the same experimental problem (e.g., how to build a tool to reach a banana in a tree), that the human accomplished this via consciousness and the chimpanzee did this without consciousness? Why posit two different explanations for the same behavior? Isn’t that an unscientific approach?

Emily: This gets into the problem of how and when it’s appropriate to apply the argument-by-analogy approach to interpreting animal behavior. Just because an animal behaves like a human, does this mean we should assume its mind functions in the same way? Depending on how one decides to apply Occam’s Razor or Morgan’s Canon, it is possible to suggest that the same behavioral outcome was produced by different underlying cognitive processes, and that we should always assume that the simplest explanation is the likeliest one. So in this case, banana-reaching via unconscious thought for the chimpanzee. Again, a computer might also be able to solve this problem, but we don’t suggest that computers are conscious. One of the main problems we’re dealing with here is that science does not really have a good definition of consciousness. Yes, it’s some form of subjective experience, but it might come in a variety of forms, and thus animals might be conscious in different ways to humans. It’s important to point out that human minds are not better than the minds of other animals – all minds are different, and there is no scale that suggests human minds are somehow the best minds due to our form of consciousness or some other cognitive trait. In any event, it’s really hard to know the extent to which the chimpanzee in this scenario solved the problem via conscious thought as opposed to complex but otherwise unconscious thought. The big question is, how can we test for the presence of subjective experience?

Phil: So we’re back to this problem again. So in what ways have scientists been testing for consciousness in dolphins, and why exactly have you reached the conclusion that “we currently lack strong evidence for consciousness in dolphins?”

Emily: Scientists have given dolphins the mirror self recognition (MSR) test. Having some kind of awareness of oneself – whether it’s awareness of one’s body or of one’s own mind – is certainly linked to the idea of consciousness. For these tests, dolphins were marked with a kind of dye on their bodies, and if they then swam over to inspect the mark in a mirror, we could conclude that the dolphins must know that it’s themselves they are seeing in the mirror. This then is some kind of self awareness.

Phil: So did dolphins pass the test?

Emily: For the most part, yes. Although not everyone is convinced that they did. Dolphins, unlike chimpanzees or other great apes (which also pass the test) don’t have hands, so it’s hard to know for sure that they were truly inspecting the marks on their bodies. Chimpanzees can reach up and touch the mark, which makes it obvious what they are doing.

Phil: So if they passed the MSR test, then dolphins are self-aware, no? And if they are self-aware, they must have some sort of subjective experience of themselves, which means they are conscious, right?

Emily: Well, the problem is that being able to recognize one’s body in the mirror (that is, recognizing an external representation of one’s body) might not be the same thing as having a representation of one’s own mind (i.e., a sense of self). So passing the MSR test might not even be a sure test of self-awareness, let alone subjective experience.

Phil: Well what about those studies of metacognition in dolphins and other animals. Isn’t metacognion the same thing as consciousness?

Emily: Dolphins have indeed been tested for metacognition. In these experiments dolphins were able to “report” that they were uncertain as to whether or not a tone they were hearing was a low or a high tone, which meant that they must have known something about their own knowledge. But depending on how one interprets these results, they don’t necessarily suggest full blown subjective experience of that knowledge.

Phil: So hold on a second – are you saying that this is down to a matter of interpretation? That there are scientists who suggest that these and other studies are evidence of consciousness in dolphins?

Emily: Yes, that is indeed the case. Some dolphin scientists, like Lou Herman, suggest that these studies, as well as his studies of dolphins’ abilities to imitate their past behavior, indicate that the most likely interpretation is that dolphins have some kind of higher-order thinking going on that might be similar to consciousness.

Phil: So why are you saying that the evidence is lacking?

Emily: I think that most cognitive scientists take this evidence to mean that it’s certainly possible that dolphins are conscious in a similar way to humans, but that the results of research at this stage have yet to provide us with the smoking gun suggesting dolphin consciousness. In the coming years, we’re likely to see new experiments that are better designed to ferret out the presence of consciousness in dolphins and other animals. But at this stage, there’s just not enough evidence to draw strong conclusions.

Phil: So it’s somewhat a matter of interpretation?

Emily: Yes, I’d say so. Scientist still have a poor understanding of how to define or test for consciousness in animals, so there’s a lot of wiggle room when it comes to interpreting these results. But it’s important to emphasize that the current scientific evidence is simply not strong enough at present to make final conclusions.

Phil: You’re leaving the door open for the possibility of consciousness in dolphins then?

Emily: Of course! Scientists always leave the door open, and I’d love to be the one to design an experiment that solves the problem of how to test for subjective experience in dolphins.

Harley HE (2013). Consciousness in dolphins? A review of recent evidence. Journal of comparative physiology. A, Neuroethology, sensory, neural, and behavioral physiology PMID: 23649907

Did dolphins evolve large brains because they ate seafood? This was a suggestion put forth by a proponent of the Aquatic Ape Hypothesis (AAH) in a recent article in the Guardian. The AAH attempts to explain the origins of unique human characteristics (e.g., hairlessness) by suggesting that we evolved in an aquatic environment. The recent Guardian article garnered a lot of negative attention from AAH detractors (i.e., nearly the entire scientific community) soon after it was published. For those of us interested in dolphin science, there is a fantastic – if bizarre – reference to dolphins in the closing paragraphs:

“Docosahexaenoic acid (DHA) is an omega-3 fatty acid that is found in large amounts in seafood,” said Dr Michael Crawford, of Imperial College London.

“It boosts brain growth in mammals. That is why a dolphin has a much bigger brain than a zebra, though they have roughly the same body sizes. The dolphin has a diet rich in DHA. The crucial point is that without a high DHA diet from seafood we could not have developed our big brains. We got smart from eating fish and living in water. (SOURCE)

The idea that omega-3 fatty acid is “why a dolphin has a much bigger brain than a zebra” is not supported by anything from the scientific literature on dolphin brains as it pertains to cognition and behavior. As it stands, the leading hypothesis as to why dolphins evolved large brains is that they required the complex cognition generated by a large cortex in order to navigate their complex social worlds (i.e., the social brain hypothesis). Past hypotheses have involved the need to process complex auditory information (from their echolocation), or that large brains helped dolphins to generate heat. But nowhere in the scientific literature on dolphin brain evolution (as it pertains to behavior/cognition) is there any mention of “fish oil” being a continuing factor.

Of course I am not all that familiar with brain evolution as it pertains to fatty acids. So just to be sure I wasn’t missing something from the literature, I did a quick Google Scholar search for Docosahexaenoic acid and dolphin brains. I found an article from 1987 co-authored by (as far as I can tell) the same Dr. Michael Crawford quoted above wherein he states THE EXACT OPPOSITE of what he said in the Guardian:

The data demonstrate that, despite the high proportion of n-3 fatty acids in the marine environment, the free-living dolphins have remarkably high concentrations of arachidonic and other n-6 fatty acids in their tissue or membrane phosphoglycerides. In this respect, they are similar to land mammals. (Page 679)

In other words, dolphins don’t seems to have a diet rich in omega-3 fatty acids (or at least they don’t store much of it in their tissues) but instead have the same kind of boring-old n-6 fatty acid concentrations we find in small-brained zebras. So it follows that omega-3 can’t then be a contributing factor in hypotheses involving dolphin brain evolution (one would think). Maybe recent literature has overturned this finding (and I am sure this line of research is more complex than I understand it to be at first glance), but even if there is a strong link between ingesting DHA and brain size, we’re left with a much more fundamental problem: eating fish oil doesn’t cause brains to evolve to be larger in some weird Lamarckian way. To explain the evolution of large brains, we need to determine what selective pressures made having a large brain (and the complex cognition that goes with it) an advantage to dolphins’ ancestors. You can’t just say “fish oil did it” until you have an adaptive explanation to go along with it.  Here is how the fish oil explanation (as portrayed in the Guardian) looks alongside the current leading hypotheses as to why dolphins evolved large brains:

–> Because of the need to navigate a complex social system, dolphins evolved lager brains

–> Because of the need to process echolocation signals, dolphins evolved larger brains

–> Because of the need to fish oil, dolphins evolved larger brains

One of these things is not like the other.

Is the suggestion really that eating seafood leads to the evolution of larger brains? This can’t be the whole argument. If so, how do we explain large brains not having evolved in sea lions, seals, or other fish-eating marine mammals? Or for sharks? Or for fish-eating birds? Or for fish that eat other fish? Obviously, simply ingesting fatty-acids is not enough. I suppose that one can make the case that a combination is required; selective pressure driving the evolution of large (intelligent) brains and the presence of fish oil in the diet. This explanation does exist to explain the evolution of the human brain. But this then does not explain the evolution of large brain size (relative to body size) in other intelligent non-fish-eating-primates like Rhesus monkeys or chimpanzees. Or vegetarian elephants. Or dolphin species that don’t eat fish (e.g., mammal-eating killer whales). Nor does it explain the fact that we see intelligent behavior in non-fish-eating-small-brained species like scrub jays. The whole idea sounds like a just-so story that just-ain’t-so, and isn’t really helping the Aquatic Ape Hypothesis gain much traction with skeptical scientists.

Pop Quiz: which of the two orange circles is larger?

If you think that the circle on the right (the one surrounded by the smaller blue circles) is larger, then you are either a human or a dolphin, but not a pigeon. As it turns out, both orange circles are exactly the same size – but your visual system is influenced by the presence of the surrounding blue circles, resulting in an optical illusion whereby you perceive the orange circle on the right as larger. Pigeons, on the other hand, are influenced by the blue circles in exactly the opposite way, perceiving the circle on the left as larger.

This illusion, called the Ebbinghaus illusion, was first created by the German psychologist Hermann Ebbinghaus in 1901. Recently,researchers tested dolphins for the first time to see if they might be sensitive to the Ebbinghaus illusion. After first teaching the dolphins to reliably choose between larger and smaller shapes (see image below), they were shown a a version of the Ebbinhaus illusion, and, just like humans, chose the circle surrounded by the smaller “inducer” circles as being larger in 84% of trials.

It is difficult to say what being susceptible to this optical illusion might mean in terms of how complex an animal’s understanding of objects might be. Studies with other animals have led scientists to reach polar opposite conclusions.  One study found that baboons did not perceive the illusion, which the authors suggested might mean that humans, as opposed to baboons, adopt a more “global mode” of object perception, resulting from cognitive skills that  evolved recently in humans but not other primates. Another study found that four day old chickens were sensitive to the illusion, which the authors suggest might point to the ancient origins of a visual perceptual system generating this illusion in a vast number of species. In any event, we can now add dolphins to the list of species that are sensitive to the Ebbinghaus illusion.

Citation below

Murayama, T., Usui, A., Takeda, E., Kato, K., & Maejima, K. (2012). Relative Size Discrimination and Perception of the Ebbinghaus Illusion in a Bottlenose Dolphin (Tursiops truncatus) Aquatic Mammals, 38 (4), 333-342 DOI: 10.1578/AM.38.4.2012.333

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As we all know from watching The Hunt for Red October, submarine sonar operators have an almost super-human ability to identify underwater sounds. They can tell the difference between different types of military ships based solely on the sound produced by the engine, and it would be almost impossible to transmit man-made communication signals that a sonar operator couldn’t identify. But Chinese scientists have found a way to deceive even the best sonar operators, and they seem to have taken their lead from this scene from Down Periscope where Kelsey Grammer’s crew fools an enemy submarine into thinking they are a whale by having ‘Sonar’ Lovacelli (played by Harland Williams) imitate whale sounds. In this scene, the enemy sonar operators dismissed the sounds they heard as a “biologic,” and the crew of the USS Stingray was saved (whale sounds start at 1:04):

It seems Mr. Williams was onto something. In a recently published scientific article, Chinese scientists described how they were able to hide information in artificial dolphin vocalizations with the goal to have sonar operators dismiss these covert communication signals as being natural dolphin sounds. The system works by first transmitting a series of dolphin whistles that synch up both the sending and receiving systems. This is followed by a series of dolphin click sounds – the same kinds of clicks used in dolphin echolocation. By varying the time delay between the clicks, the scientists were able to include up to 6 bits of binary data, allowing for a rate of 37 bits per second of digital information to be transmitted. The scientists field tested the system on Lianhua Lake in Heilongjiang, where two ships spaced 2 kilometers apart were able to reliably transmit information via these fake dolphin vocalizations. Hypothetically, even the most experienced sonar operator would, upon hearing these artificial dolphin sounds, dismiss them as naturally occurring animal noises, allowing for secret messages to be conveyed. So the next time you hear dolphin click sounds when swimming under water, this is what might be happening:

1) Dolphins echolocating

2) Navy submarines transmitting a secret coded message

3) Harland Williams filming Down Periscope 2

Here’s the article in question, which was recently published in the The Journal of the Acoustical Society of America:

Liu S, Qiao G, & Ismail A (2013). Covert underwater acoustic communication using dolphin sounds. The Journal of the Acoustical Society of America, 133 (4) PMID: 23556695

In this bizarre video footage, a female Indo-Pacific dolphin is seen exhaling or leaking air from her left eye socket.

In case you might not be familiar with dolphin anatomy, dolphins aren’t meant to breathe through their eyes. In your traditional dolphin body, there is only one connection from the lungs to the outside world, and that’s via the blowhole. Everything in the dolphin’s skull is designed to make the transfer of air, in those brief moments when a dolphin’s head breaks the surface of the water, as safe and efficient as possible. Evolution even designed anatomical structures to block the connection from a dolphin’s mouth to its lungs just to make it that much harder to either accidentally inhale water, or inadvertently leak air. With such an exquisitely designed closed system,  how can we explain this strange video footage?

A team of dolphin scientists, including dolphin cranial specialists (yes that’s a thing), analyzed the above video and concluded that there must be something quite abnormal – and rather sinister – happening in this poor dolphin’s head. Dolphins have a number of air sac and other air-filled structures in their skull, including a sinus-like structure adjacent to their eye sockets. In a normal dolphin, there is an air-tight barrier of blood vessels and fibrous muscle tissue that separates this sinus structure from the eye-socket, with just enough room to allow the ocular nerve to pass through en-route to the brain. This flexible tissue-wall expands and contracts as the dolphin’s nasal-sacs fill with air. But for the poor dolphin in this video, there is some sort of hole or leak in this tissue-wall, which causes the expanding air to rush into the eye-socket as the animal rises to the surface. How did this hole get there? Here are the scientists’ two best guesses:

1) A worm-like lung-parasite (i.e., a nematode) ate its way through the tissue-wall.

2) The barb from the tail of a stingray stabbed the dolphin in the eye and punctured the tissue-wall.

Either of those options are tragic and/or gross, not to mention uncomfortable. So will this dolphin die from this bizarre problem? Maybe not. The two biggest risks for this dolphin are that it can’t keep enough air in its lungs to stay under water long enough to find food, or that the hole might actually let water rush into its lungs if it dives too deep. I guess the main lesson here is that if you suspect you have lung nematodes and are planning a diving holiday this summer, please visit your physician to see if the nematodes have eaten a hole in your sinus tissues. Maybe that’s not really the main lesson. But it is a lesson.

You can read more about this situation in the original article:

Dudzinski, K. (2013). Short Note: Air Release from the Left Orbit of an Indo-Pacific Bottlenose Dolphin (Tursiops aduncus): Symptomatic and Anatomical Aspects Aquatic Mammals, 39 (1), 97-100 DOI: 10.1578/AM.39.1.2013.97
PDF at this link.

The video footage was filmed by John Anderson of Terramar Productions.

UPDATE:
I actually didn’t notice this until a reader pointed it out to me, but that guy in the video is reaching out to try to touch the dolphins. Not cool bro! It is strongly advised to not touch wild dolphins in these kinds of situations. No chasing, no feeding, no touching – just observe silently and try your hardest not to bother wild dolphins, kthanks!

Uh oh – it seems the Ukrainian Navy has a small problem on their hands.  After rebooting the Soviet Union’s marine mammal program just last year with the goal of teaching dolphins to find underwater mines and kill enemy divers, three of the Ukrainian military’s new recruits have gone AWOL. Apparently they swam away from their trainers this morning ostensibly in search of a “mate” out in open waters. It might not be such a big deal except that these dolphins have been trained to “attack enemy combat swimmers using special knives or pistols fixed to their heads.” So if you are planning a family holiday to the Black Sea this week, I think it’s best you avoid any “friendly” dolphins that might approach – especially if they have KNIVES or PISTOLS strapped to their heads.

Here’s a documentary all about the former Soviet military dolphins, some of which have been sold to Iran, and a some of which are currently roaming the Black Sea looking for a good time.

UPDATE:
Here’s a more in-depth radio report on this subject from The Voice of Russia UK Edition
You can download/listen to the news report as an mp3 at this link.
Apparently, “The Ukrainian Defence Ministry has denied the reports.” But the Voice of Russia and the RIA Novosti appear to have sources at Sebastopol confirming that the dolphins escaped.

MORE UPDATES:
This Russian news agency is claiming that the escaped animals really did have firearms attached to their heads at the time they went missing (as far as I can tell via Google Translate). Crazy!

YET MORE UPDATES:
This news story has blown up on the interwebs, with reports suggesting that the escaped dolphins “are highly trained, intelligent, and can strike anywhere,” which is probably a slight exaggeration, as well as suggestions that the incident (first reported by RIA Novosti, but now found on every website known to man)  in fact never happened at all. Now that journalists around the world are on the case (producing well-researched reports like this one from Wired), maybe we’ll soon get to the bottom of this story! Meanwhile, let’s not panic people!

UPDATE #4:
Now there is evidence that the news report of this incident, first reported by the Russian news agency RIA Novosti, was (maybe) based on false information, with  RIA Novosti having received fake documents detailing a dolphin escape that never happened. So what are we to do with all these hilarious photoshopped images of dolphins with weapons strapped to their heads?

FINAL UPDATE:
This entire news story is now confirmed as bogus. Bummer!

An article titled “Vocal copying of individually distinctive signature whistles in bottlenose dolphins” is in the news this week. This is the latest in a series of studies from researchers at the University of St Andrews looking at how dolphins use “signature” whistles. Signature whistles are unique vocalizations that each dolphin develops at a young age that (sometimes) remains stable throughout their lives. It’s easy for humans, and presumably dolphins too, to hear the difference between dolphins’ signature whistles, which makes them useful for recognizing individual animals.

This study found that dolphins occasionally copy the signature whistles of their close associates (e.g., mothers and calves, male alliance partners), which is evidence that dolphins are using these whistles for friendly purposes, as opposed to territorial defense or aggression (which is often how bird species use copied sounds). The dolphins also appear to purposefully introduce very subtle changes in the copied whistles, which suggests they are not trying to deceive each other by pretending to be someone else.

It’s rare that animal communication results in animals having labels for objects in their environment – in this case it’s possible that the signature whistle is a kind of label that refers to individual dolphins. The most common examples of referential communication in the animal kingdom are alarm and food calls, which are found in diverse species (e.g., monkeys, rodents, chickens). Signature whistles are unique insofar as they are not used to refer to threats or food, but appear to refer to themselves, and possibly other dolphins. While we know from experiments that dolphins are able to learn both visual and acoustic labels for objects and concepts (something birds, primates, dogs and other animals can do as well), this is one of those rare cases where an animal might have a label for something in its natural communication system.

Unfortunately, this study was not able to tell us if dolphins copy the signature whistles of other dolphins in order to specifically refer to and/or get the attention of that individual or not. They might simply be copying the whistles/sounds which they hear most often in their environment and reproduce them as a general contact or distress call in times of trouble, which would explain why they copy the whistles of their close associates. It’s worth noting that the dolphins in this study didn’t actually copy each others’ whistles all that much – only 12 of the 121 individual dolphins in the capture-release scenario copied whistles at all, and then at a rate of only 0.18 copies per minute, which suggests that whistle copying is a rare-ish event. Although the media is keen to suggest that dolphins call each other by name, this is a bit of an oversimplification or exaggeration insofar as we still don’t know how label-like or referential these whistles really are, of if the dolphins producing the whistles of their associates truly intend to refer to or label that animal or not. As the lead author of this study, Stephanie L. King, noted in an interview with Wired: “We still need to show that experimentally, but that’s why it’s quite exciting.” Indeed! Hopefully the St. Andrew’s group will get to the bottom of this in future studies.

King SL, Sayigh LS, Wells RS, Fellner W, & Janik VM (2013). Vocal copying of individually distinctive signature whistles in bottlenose dolphins. Proceedings. Biological sciences / The Royal Society, 280 (1757) PMID: 23427174

The ocean is choc-a-block full of random acts of kindness these days. Recently we’ve heard about sperm whales adopting a deformed bottlenose dolphin, a dolphin that sought aid from a friendly diver, and now the latest offering; “altruistic” dolphins that help a lost seal find its way back home (video below).

It’s hard to tell from this video exactly what transpired since it’s a mashup of clips. The narrator seems fairly confident that the dolphins were keen to coax the little seal to safety, since he remarks at 1:30 that  “with gentle nudges, the dolphins seem to be encouraging the young seal to swim.” On closer inspection, I do not see any “nudging” by the dolphins (they don’t touch the seal), but I do see at least one dolphin focusing his attention on the genital region of the seal – more than likely engaging in a behavior that scientists call “genital-buzzing.” It’s observed fairly frequently in dolphins, and its function is unknown. Here’s one description of genital-buzzing from this scientific article:

During courtship, discipline of conspecifics, or the pursuit/herding of sharks, the predominant vocalization produced is the “buzz” or “genital buzz.” This vocalization is a low frequency, high-repetition rate echolocation train that is directed towards the genital or mid-section of a conspecific, often by a male to a receptive female during courtship behavior.

So genital buzzing happens when dolphins are fighting with each other (perhaps buzzes directed at the genitals hurt), when chasing away predators (again, maybe the buzzing is uncomfortable), or when courting and getting ready to mate (perhaps the buzzing stimulates the potential mate, or is a way to ascertain if the female is ovulating). It’s hard to know what it might mean when a dolphin buzzes a seal’s genitals. In any event, it’s not entirely clear what was happening in this video. I suggest the following three possible explanations as to what was going through the dolphins’ heads in the above clip:

Scenario 1
“Doris, come quick! This poor seal needs our help.”

“You’re right Tim – let’s lead him to safety.”

“Poor little guy. I hope he makes it!”

Scenario 2
“Hey Doris, check out this floating meat-log. What do you think it is?”

“Wow Tim, that thing’s ugly! Well, I just buzzed its genitals and colorectal area, and whatever it is it’s not a dolphin.”

“Duh-doy – I knew that already! In any event, I wouldn’t mate with it.”

“Dude! Eew!”

Scenario 3
“This juvenile Mirounga angustirostris is an ideal candidate for our genetic-hybridization program. Let’s bring it back to the laboratory and harvest its organs.”

“Doris you fool, can’t you see we’re being filmed by a human?”

“Drat! And he’s using an SD camera no less! Couldn’t he afford a GoPro? Anyhow, we’ll have to come back for the specimen when the coast is clear.”

“Wait, let me buzz this seal’s genitals real quick – that really confuses these so called human ‘scientists.’”

*****

Tip: For more on altruistic behavior in dolphins and other animals, you’ll find a decent intro over at the Stanford Encyclopedia of Philosophy.  Altruistic behavior is fairly widespread in the animal kingdom, and has had scientists thinking about how and why it evolved since Darwin first discussed the issue in On the Origin of Species.

An amazing video showing a diver removing a fishing line that was wrapped around the pectoral fin of a wild bottlenose dolphin has been making the rounds this week.

This video was uploaded by Ocean Wings Hawaii, an ecotour company offering night dives to observe manta rays feeding off the coast of Kailua-Kona. In the video, shot on January 4th 2013 by Martina Wing, an adult male bottlenose dolphin can be seen approaching a group of divers. The whole area is illuminated by powerful dive lights, and the manta rays can be seen in the background. The dolphin does not display any signs of being nervous or agitated, and hangs quite calmly in the water column just inches away from the (presumably) astonished divers. Before too long, the divers notice the fishing line. According to Wing,the fishing line was wrapped so tightly that it could not be removed by hand, which is why the diver featured in the video (Keller Laros – AKA the Manta Man) whips out a pair of underwater safety shears and begins cutting the line. Although the video is not time stamped (which makes it difficult to say how long the encounter lasted), it’s obvious based on the length of the uploaded video that the dolphin spent many minutes being gently manhandled by the divers as they tried to free him. At one point, the dolphin returns to the surface for a breath before re-approaching the divers. Eventually the line was removed from around the fin, although the fishing hook remained in the dolphin’s flesh.

I found this video to be pretty darn amazing – and that’s coming from someone who has spent an awful lot of time watching underwater video footage of wild dolphins.To begin with, I am amazed at how boldly this animal approached the divers, how close he got, and how easily he tolerated being touched and prodded. This is especially baffling if, as I suspect, this dolphin had not had much exposure to human divers, snorkelers, or swimmers in the past (i.e., it had not yet been habituated to human presence). Although wild dolphins certainly do approach humans, with the infamous lone sociable dolphins (like Fungi or JoJo) spending a lot of their time in close contact with humans, this level of contact – which appears to be a once-off occurrence – is rather rare. I am also amazed at how tolerant the dolphin was of the bubbles being expelled by the regulator – some of which hit him full on in the face. We often tell tourists that we see on our own research expeditions in The Bahamas how nervous wild dolphins can be around diver-produced bubbles, which is one of the reasons we snorkel with them as opposed to dive.

Many of the folks commenting on the video are suggesting that the dolphin approached the divers to solicit help in removing the fishing line. This is the explanation many have for why the dolphin was so relaxed, and got so close. Of course it’s entirely possible that the dolphin was sick or weak (from the fishing line entanglement or otherwise) which might explain his lack of fear and generally calm demeanor. And I am not 100% sure that it’s accurate to suggest that the dolphin “knew” that the divers were trying to help him. The dolphin also rubs up against the mooring line (as can be seen in the video), so it’s possible that the dolphin just regarded the humans as another thing to rub up against – something that appeared to work even better than a mooring line at getting rid of that darn fishing line. Given how difficult it is to prove what dolphins might or might not know about the thoughts or intentions of humans (or other dolphins), it’s probably going a bit too far to conclude that the dolphin knew it could find help if it approached the divers. Consider also that if the dolphin had tried the same approach with humans in somewhere like Taiji, things would have ended very differently.

But there is no denying that this dolphin remained strangely calm as a relatively large, bubble blowing monster with odd grasping appendages grabbed hold of a (probably quite tender) part of its body and starting tearing away at the fishing line – an activity that was probably painful in and of itself. Whatever the dolphin might have been thinking, it must have put the divers in the category “friend” and not “foe” in order to let this happen, which was, in this case, a very smart decision. Kudos to the divers for intervening.

UPDATE: Someone suggested that it’s possible the dolphins in this area might be being fed/provisioned by humans, which might explain why this dolphin was so comfortable around the divers. I sure hope this is not the explanation for this dolphin’s behavior since feeding wild dolphins is illegal, and increases the risk that they get injured by boat propellers or, ironically, tangled in nets and fishing lines.

The academic journal Aquatic Mammals has conducted interviews with over 40 of the world’s leading marine mammal scientists and put together this series of short videos offering advice for students wishing to study dolphins and other marine mammals. The full list of videos can be found at this link. A few of my favorites are embedded below, including Bernd Würsig, Randall Wells, Daniel Odell, and William Perrin.

Bernd Würsig – Advice for Students from Aquatic Mammals on Vimeo.

Randall Wells – Advice to Students from Aquatic Mammals on Vimeo.

Daniel Odell – Advice to Students from Aquatic Mammals on Vimeo.

William Perrin – Advice to Students from Aquatic Mammals on Vimeo.