Several news outlets this week have justifiably made a big deal about the Greenland Shark. Recent research suggests these lumbering giants are now the record holder for the longest lived vertebrates we are aware of. This knocks the Bowhead whale from first place, whose age-determination story is fascinating in its own right, bolstered by the presence of an antique eskimo harpoon point.
Often sharks have been aged through examining growth bands present in vertebrae, however Greenland sharks have softer vertebrae that make this challenging. Additionally, due to challenges in reading these rings as sharks age, as well as possible disconnects between growth rate and age, radiocarbon dating has been joining the toolbox for determining fish longevity. This study used the method with the sharks’ eye lenses.
These sharks may take up to 150 years to reach sexual maturity, making their population vulnerable if too many individuals are culled before reproducing. They are also bizarrely prone to parasitism by a strangely-elongate copepod (most look more shrimp or lobster-like) that attaches to their eyeball and ultimately causes a march towards blindness. Only 1% of the 1500 sharks in a study concerning infection rates were parasite-free. 85% are afflicted in both eyes. However, due to their reliance on a keen sense of smell, rather than sight, for hunting, it has been suggested that the sharks may actually benefit from the copepod acting as small visible lures that interest nearby prey. However, Dr. George Benz of Middle Tennessee State University with expertise in shark and ray parasites, doubts this theory, instead favoring the idea that Greenland sharks may instead be ambush hunters, taking their targets instead through the element of surprise.
Lest you think National Geographic is losing their edge, the reason why ctenophores (the phylum to which comb jellies belong) defecating is a big deal is because it was thought this group of creatures had a single opening for both feeding and excreting. University of Miami researcher William Brown debuted videos at the March 2016 Ctenopolooza gathering at the Whitney Lab in St. Augustine (where I’ve done much of my own dissertation field and lab work) that prove otherwise. One of the peculiar videos is featured partway through Nat Geo’s article here. Science writes about the find as well.
One of the most interesting aspects of this find is questions regarding the evolutionary history of gut development. It was thought to be a pretty straight forward pathway from one opening to two. However, because comb jellies evolved before other organisms that still have a single opening, such as sponges, things are looking slightly more interesting. Perhaps ctenophores branched off, and smartly evolved a more complex gut tract independent of these organisms. Or, perhaps some of these single-orificed organisms started with two but lost one over time – similar to the story of some marine mammals that long ago left the sea to become land-dwellers, only to ultimately return again.
While running to meeting on the University of Florida campus, I looked down and spied this creature on the edge of a concrete walkway. While about the size of one of our local palmetto bugs (a deceivingly quaint name Floridians have bestowed upon one of the local cockroach species), this large docile beetle was far less menacing. I was entranced by its eye spots, and by the discovery of yet another new species (I am a transplant down here and very much dig the constant appearance of novel little beasties).
Due to its unique appearance, it was easy to later discover this insect’s identity – the speckled eastern eyed click beetle, Alaus oculatus. Among its other common names is the eyed elater. Their larval form is known as a wire worm, and due to its carnivorous diet, is often valued by gardeners for its ability to rid vegetation of other less desirable residents.
Click beetles are members of the family Elateridae and produce their trademark sound when their spine snaps into a groove located on their mesosternum (basically like a bug chest plate). They do this when righting themselves if flipped over, and this snapping action may allow many members of this family to propel themselves away from harm quickly. Additionally, the presence of eyespots in insects are often suggested to be a form of predator deterrence.
Never when I signed up for this whole PhD “thing”, did I think that further down along the line I would wander down the aisles of countless formless and faceless Home Depots and Lowes, familiarizing myself with PVC epoxies, pipe cutters, types of quick-pour concrete, and erratically color-coded lengths of rebar. While I am in the very last throes of the natural science component of my dissertation, for stretches within the last year, nary a week would pass without at least one, if not several, trips searching for the miscellanea one needs to make a bare-bones scientific project happen.
My method for estimating oyster filtration rates required the use of sediment traps (see my post about it here) constructed out of buckets and netting. However, the studies that used them prior and upon which I based my design, had employed them in very different settings. My traps had to withstand dynamic ocean conditions, tidal cycles, and the interest of the errant passerby. So thus began the nail-biting process of iterative design. What type of buckets to use to avoid re-suspending sediment? What kind of netting across the mouth? How to affix them to reef? How to weight them so they wouldn’t float away during the first high tide?
Practice run after practice run unfolded as I tried various proto-types. Scuba weights affixed to the mouth of buckets using hose clamps. Testing ways to keep everything in one place using ground anchors, thin lengths of PVC, rebar. Phone calls from nearby good Samaritans who had retrieved my runaway equipment (a PSA if there ever was one for labeling your gear!). A slick (if not utterly lo-fi) double-nested bucket design weighted down with rounds of concrete emerged out the mixture of mishaps and successes. I then did it all again and tapped into the same recurrent type of process when creating a seawater flow-through system for oyster filtration lab trials.
All the while, I was running to every hardware store in town, looking for materials of the right shape, weight, and construction for whatever small application I had in mind. Many questions directed towards employees started with “This is going to sound strange, but…”. Eyebrows were raised when I bought 30 of something generally purchased in increments of one or two – “…Doing a lot of yard work this weekend?” I recall poorly relaying the idea of my experimental sediment traps meant to measure the amount of oyster biodeposits produced during my experiment, and the amusing follow-up question: “Are you trying to keep the oysters from getting away?”
Many questions directed towards employees started with “This is going to sound strange, but…”.
Additionally I had the help of a marine lab machine shop to drill, cut, and sand. I learned how to estimate which equipment I needed for which job. I also had the opportunity to watch those inclined towards clever design and ask plenty of questions. Is there enough water pressure to do that? How do I get the flow to be more laminar? How do I keep this from leaking?
It’s a cultivated skill set, one which rewards those who tinkered with lego and kinex as a kid. Rarely are we told as marine biologists, fisheries scientists, or field ecologists, that we will draw so heavily upon what amounts to being back-of-the-envelope engineers.It’s also a continued argument for the inclusion of the “T” (technology) and the “E” (engineering) part of STEM training that is often desired on the job, but may make scant appearance in a scientist’s formal education.
Most of us instead gain experience through more informal avenues, as the best teacher is often necessity. Also there is no better practice than to constantly build, err, and deconstruct, all while slowly incorporating new fixes and experiencing the fog of confusion out of which comes little sparks of revelation. The act of literally building our science from the ground up is one of ultimate creativity, funneling in threads of right-brain function, and helping us shape solutions in response to whatever demands our research may make of us.
Each one of us is as old as the entire biological kingdom, and our bloodstreams are tributaries of the great sea of its total memory. – J.G. Ballard, The Drowned World
Earlier this year, (I am late in finally moving this post from draft to final form), University of Florida held a fascinating plenary session called “Imagining Climate Change: Science and Fiction in Dialogue” as part of their February 2016 Water Institute Symposium. I was lucky enough to attend this along with several other events meant to foster dialogue about water and water resources.Many of these events embraced the intersection between art and science, with an understanding that the former may have a lot to add to the communication of the latter.
The plenary focused on a panel consisting of scientists and science fiction writers, several who dabbled in the blurred lines between those professions. Terry Harpold, Associate Professor of English at UF, moderated the discussion. Scientists included Ellen E. Martin, a paleoclimatology fellow for the Florida Climate Institute and professor of paleoceanography at UF, and Jay Famiglietti, senior water scientist at the NASA Jet Propulsion Laboratory and an earth system sciences professor at UC Irvine. Rounding out the authors were Yann Quero, Jeff VanderMeer, and Tobias Buckell.
The session reminded me of variations of scenario-based planning exercises we practiced in our conflict management course. The participants can embark on a sort of imaginative course of suggesting possible futures or outcomes. As Kahane (2012) describes the method: “The scenario method asks people to talk not about what they predict will happen or what they believe should happen, but only about what they think could happen.” Different versions of the process have wavered on the importance of plausibility versus probability. But regardless, it lets those involved imagine the future and possibly envision solutions to keep negative possibilities from occurring, or identify steps to support positive scenarios.
Harpold directed the panel first to consider water and its influence on them – “the great solvent of our collective imagination” – and the members described often poignant moments where resource coincided with personal memory. One panel participant, Tobias Buckell, described his youth growing up in the Caribbean and living on boats, a unique perspective that colored his responses to later questions. Dr. Famiglietti was also able to re-iterate a point he has made in the documentary Last Call at the Oasis, concerning his findings of extreme water scarcity in the western coast of the US among other regions, and how his interests have continually moved towards how to relay this topic effectively to the public and outside of the constraints of technical writing.
The conversation turned to examining the role of writers in contrast to those of scientists, as it was noted that sometimes science writing is not enough, the effectiveness of the translation piece is becoming the defining thing. When asked why writers feel compelled to bring in the science, the French author Yann Quero noted that it used to be the job of the writer to make people dream. It appears however, for some writers, that the looming threat of climate change has made some of them feel a personal onus to translate the sometimes labored language of the science into humanized narratives, crafting stories with probable elements. “Let me grab you by the face and show you how tragic this will be on a human scale” added Tobias Buckell.
It was also suggested that this kind of science-driven fiction can make the lives of scientists more relatable by conveying their lives and the constraints they work under. Ideally, this would make the efforts of researchers like Dr. Famglietti and Dr. Martin easier. But it is also clear that scientists are operating under a different set of constraints with regards to communicating the science of climate change, as became very evident when the topic of uncertainty was posed to the panel.
Dr. Martin referred to the perception of there being gatekeepers of scientists and publishing, certain thresholds that needed to be met before scientists were let loose to communicate. Further discussion established that fiction had the luxury of being able to exist within a different convention of reliability. However, when the question was posed about how much uncertainty needed to be minimized before action was taken, Dr. Famiglietti recounted (I saw him in multiple contexts, so this comment may have been made at an earlier event) attending a meeting where Al Gore was speaking and proceeded to lay out a directive for the scientific community to embrace the responsibility of sharing their science, as no one else knew their data with the same intimacy, or perhaps understood with the same gravity, the messages their research was revealing. If there was a preponderance of supportive data, more harm than good could be done waiting to to reach a 98% confidence threshold.
Additionally, scientific jargon and word usage can be misconstrued. The public may hear the word “error” and understand it to mean “wrong”, when in a scientific context, it may in fact refer to the process of getting closer and closer to the correct answer. So there is the challenge of choosing how to effectively relay the larger messages. Alternatively, authors were asked how or if they maintain scientific rigor within their text, while still subscribing to the creative process of writing fiction. One of the more interesting responses came from weird fiction (an actual subgenre of speculative fiction, not my classification) author Jeff Vandermeer who suggested fiction doesn’t need to solve the questions it poses, as we often can’t in real life. He also referenced the writer J.G. Ballard, author of “The Drowned World”, who engages his reader in thought experiments. How is the human mind altered by climate change? Perhaps you don’t need to even characterize the change correctly, the power is more in the act of considering it.
The panel ended by gauging the level of hope panel participants had for the future, as moderator Harpold suggested “hope is a deeply irreducible human thing…” The tone of responses was one of adaptation rather than complete mitigation. There are no absolute solutions, but we would be remiss to do nothing. Dr. Famiglietti recognized the irreversible trend associated with some aspects of climate change but voiced his hope in future communities to develop sustainable ways to manage resources. Vandermeer suggested we not engage in magical thinking and shy away from the complexities of climate change, but may need to instead redefine our vision of utopia. Also acceptance that our current way of life is dead leaves us room to engage in new ways of living, that we we need to become less to become more. From his own experiences, Buckell has been led to believe we are far more likely to come together to rebuild and recover, in contrast to the “rugged individualism” Hollywood has led us to believe characterizes natural disaster.
All in all, the session an intriguing look into the minds of a group of men and women who have devoted a significant part of their lives to considering the implications of climate change. It is certainly a heavy task to engage it, but one they are clearly doing so with thoughtfulness and conviction.
Recently, I had the rare and exhilarating opportunity to spend part of an errant and lazy Wednesday afternoon at the beach.
Anastasia State Park is a striking coastal stretch in the St. Augustine area. You walk a long, angled boardwalk right into these beautiful dunes. Wispy sea grasses dot the sand, and every time the wind blows, the blades cut these little furrows around themselves.
I walked the length of the beach taking photos and was drawn to what seemed like a visually interesting tree. I took a couple angled shots and then noticed what I had originally mistook for some kind of buds on the tree were ornately woven adornments. Some unknown person or persons had up-righted what was a tree weathered and uprooted perhaps by some past storm, and decorated its branches with braids of sea grasses and shells. I watched as passersby casually searched for nearby elements to add.
The most beautiful aspect of this experience for me was both the enigmatic and unknowable origin of the act, and the momentum it took on afterwards. Each person has an intimate connection with this surprising find, but every experience is singular along a continuum of time. Not a shabby way to spend time at the beach.
Mass migrations fascinate me – massive swarms of creatures on robotic treks to satisfy deep-seated needs for resources – nature’s automatons reaching for food, for mates, for brighter skies. One of the earliest that captured my attention is expressed in this Animal Planet video documenting the movement of red crabs on Christmas Island:
(Note at 1:40, crustaceans seem to be playing “frogger” while obliviously scuttling across roads and railroad tracks. Not the unexpected result of the clash between crab and human.)
A gif of the oceanic equivalent has made a recent appearance online, showing an endless carpet of sandy colored scuttlers (they were in fact red, or “tuna,” crabs who appeared that way as they stirred up a the sediment on the sea floor). However, this article sheds more light on the unusual event captured by a manned submersible exploring Hannibal Bank off of Panama (fitting name for the location of a slightly unnerving and intriguing event to occur? ). The following video comes from Woods Hole Oceanographic Institut and features scientist Jesús Pineda explaining the details around recording the migration:
The buoy, which was deployed to gather data related to El Niño events, drifted off its mooring during a recent storm. Two fishermen chanced upon it, recovered it, and are now demanding $13,000 in exchange for its return. Their lawyer, a seemingly rather colorful character and self-described “old trial dog”, initially set the price a bit higher based on the following mathematics: ” On good days fishing they gross $2,700. Taking the big and gouging thing onto the boat and having it there kept the boat out of action for nine days for a multiply of $24,300. Twenty percent of value would be $80,000. We offer to SELL (you can use any other word you like in an agreement) it to you for $45,000.” One has to wonder why they took it upon themselves to keep the “big and gouging thing” on their boat for nine days in the first place.
The article notes from several sources that salvage laws likely do not apply here, especially as the buoy was never properly abandoned. However, the loss of and tampering with of expensive research equipment has always been a known and pervasive issue in oceanic research. I for one will be interested to follow the outcome of this eyebrow-raising case.
David Attenborough’s voice was the seminal soundtrack to my development as a biologist. It was his narration I heard in my head extolling the wonders of the living things I saw during my scuba dives, fieldwork, and time spent outdoors.
Here is a quick list re-visiting some of the more innovative and thought-provoking applications or ideas surrounding 3D printing in the sciences over the past few years:
Printing human tissue. Recent news shows we’re able to use 3D printing more effectively to create intricate models of organs for learning purposes. However, a smattering of experts across disciplines have made progress in printing processes that utilize the stuff of the human body to create swaths of tissue that can be used for grafts or testing. The purported next step is the more complex arrangement of tissue into whole organs that are custom designed for the patient, limiting the possibility of rejection and alleviating the long wait times on transplant lists.
Antimicrobial teeth. A boon to those of us with an arduous dental history, the development of bacteria-resistant tooth implants may be more than a distant fever dream. Dutch scientists have printed and initially tested tooth prototypes against human saliva, but are still a ways off from starting patient trials.
Smart textiles. When it comes to wearables, 3D printing is appearing in some surprising ways. Take this architectural swimsuit top meant to help clean the ocean by locking aquatic contaminants away in its fabric. Or this Anouk Wipprecht design of a “spider” dress that responds to the wearer’s emotional state. A great deal of industry seems to be focused on the concept of wearable electronics, which is sure to gain momentum from the recent production of a flexible graphene fabric.
The advent of 4D printing. Harvard researchers have revealed new research of 4D printing techniques that allows for the creation of materials that can interact with their environments and can experience temporal changes (thus adding a fourth dimension to 3D applications). They have developed mathematical models that can suggest exactly how the material is to be printed in order to produce the desired changes in shape. One of the primary suggested uses for 4D printing is the fabrication of self-building objects. But as presented in the photo above, the world of 4D printing and haute couture is also colliding.
Printing custom drug formulations. Lee Cronin at Glasglow University, as told to the Guardian in 2012, envisions a day where we would be able to print our prescriptions at home. The New York Times recently released this article about the continuing challenges of drug shortages that can arise from impacts to manufacturer facilities, or when drug production is limited due to concerns about bankability. The ability to more easily synthesize medical compounds could revolutionize the pharmaceutical industry.