… and I’m guessing that if you read this blog, you like at least one of these things.
Today sees the publication of a paper that I’m particularly pleased with, partly because it’s so far outside my usual area: The Concrete Diplodocus of Vernal — a Cultural Icon of Utah (Taylor et al. 2023). Let’s jump in by taking a look at the eponymous concrete Diplodocus:
Taylor et al. (2023:figure 5). The completed outdoor Diplodocus mount in a rare color photograph. Undated (but between 1957 and 1989). Scanned by Eileen Carr for the J. Willard Marriot Digital Library, image ID 415530. Used by permission, Uintah County Library Regional History Center.
(On of the things I love about this photo is that it has the same 1950s energy as the Carnegie Tyrannosaurus mount that I posted a while back.)
This paper tells the neglected story of how the Utah Field House museum in Vernal acquired the original Carnegie Diplodocus molds in 1957, after they had languished, unloved and overlooked, in their Pittsburgh basement for forty years; how they were used to cast a Diplodocus from actual concrete (one part cement to three parts aragonite, for those who care); how the molds then went on a series of adventures, never actually yielding another complete skeleton, before being lost or destroyed; how the concrete cast stood for 30 years before the harsh Utah weather degraded it past the point of safety; how it was then used to make a fresh set of molds, and replaced by a new lightweight cast taken from those molds; and how the molds were then used to create a new generation of Diplodocus casts.
It’s a long and fascinating story with lots of twists and turns that I necessarily omitted from that summary — which is why it runs to 27 pages in the lavishly illustrated PDF. I urge you to go and read it for yourself: we wrote it to be an engaging story, and I hope it’s a pretty easy read. (My wife found it interesting, and she once literally fell asleep while I was running a talk to solicit her feedback, so that’s really something.)
Taylor et al. (2023:figure 3). Field House Museum director G. Ernest Untermann (left), and his wife, Staff Scientist Billie Untermann (right), grouting the cast dorsal vertebrae of the Field House’s concrete Diplodocus. 24 January 1957. Scanned by Aric Hansen for the J. Willard Marriot Digital Library, image ID 1086940. Used by permission, Uintah County Library Regional History Center.
This paper was submitted on 2 November 2022, so it’s taken less than five months to go through peer review, editorial processes, typesetting with four(!) rounds of page proofs and online publication. This of course is how it should always be — it’s a bit stupid that I am drawing attention to this schedule like it’s something extraordinary, but the truth is that it is extraordinary. At any rate that makes it fifteen times faster than my long-delayed (mostly my fault) paper on neck incompleteness (Taylor 2022).
I got so deeply into this paper when I was lead-authoring it that the phrase “the Concrete Diplodocus of Vernal” really started to echo around in my head. That is why the paper ends by expressing this wish:
Our dearest hope for this paper is that it inspires someone to create a Dungeons and Dragons module in which the Concrete Diplodocus of Vernal is a quest artifact with magical powers.
But Mike, you ask — how did you, a scientist, find yourself writing a history paper? It’s a good question, and one with a complicated answer. Tune in next time to find out!
References
- Taylor, Michael P., Steven D. Sroka and Kenneth Carpenter. 2023. The Concrete Diplodocus of Vernal — a Cultural Icon of Utah. Geology of the Intermountain West 10:65-91. doi:10.31711/giw.v10.pp65-91
- Taylor, Michael P. 2022. Almost all known sauropod necks are incomplete and distorted. PeerJ 10:e12810. doi:10.7717/peerj.12810
No-one knows whether or not a neutral-tasting nutrient-sludge diet leads to enormous weight loss
February 15, 2023
I recently discovered the blog Slime Mold Time Mold, which is largely about the science of obesity — a matter of more than academic interest to me, and if I may say to, to Matt.
I discovered SMTM through its fascinating discussions of scurvy and citrus-fruit taxonomy. But what’s really been absorbing me recently is a series of twenty long, detailed posts under the banner “A Chemical Hunger“, in which the author contests that the principle cause of the modern obesity epidemic is chemically-induced changes to the “lipostat” that tells our bodies what level of mass to maintain.
I highly recommend that you read the first post in this series, “Mysteries“, and see what you think. If you want to read on after that, fine; but even if you stop there, you’ll still have read something fascinating, counter-intuitive, well referenced and (I think) pretty convincing.
Anyway. The post that fascinates me right now is one of the digressions: “Interlude B: The Nutrient Sludge Diet“. In this post, the author tells us about “a 1965 study in which volunteers received all their food from a ‘feeding machine’ that pumped a ‘liquid formula diet’ through a ‘dispensing syringe-type pump which delivers a predetermined volume of formula through the mouthpiece'”, but they were at liberty to choose how many hits of this neutral-tasting sludge they took.
This study had an absolutely sensational outcome: among the participants with healthy body-weight, the amount of nutrient sludge that they chose to feed themselves was almost exactly equal in caloric content to their diets before the experiment. But the grossly obese participants (weighing about 400 lb = 180 kg), chose to feed themselves a tiny proportion of their usual intake — about one tenth — and lost an astonishing amount of weight. All without feeling hunger.
Please do read the Slime Mold Time Mold write-up for the details. But I will let you in right now on the study’s very very significant flaw. The sample-size was two. That is, two obese participants, plus a control-group of two healthy-weight individuals. And clearly whatever conclusion we can draw from a study of that size is merely anecdotal, having no statistical power worth mentioning.
And now we come to the truly astonishing part of this. It seems no-one has tried to replicate this study with a decent-sized sample. The blog says:
If this works, why hasn’t someone replicated it by now? It would be pretty easy to run a RCT where you fed more than five obese people nutrient sludge ad libitum for a couple weeks, so this means either it doesn’t work as described, or it does work and for some reason no one has tried it. Given how huge the rewards for this finding would be, we’re going to go with the “it doesn’t work” explanation.
In a comment, I asked:
OK, I’ll bite. Why hasn’t anyone tried to replicate the astounding and potentially valuable findings of these studies? It beggars belief that it’s not been tried, and multiple times. Do you think it has been tried, but the results weren’t published because they were unimpressive? That would be an appalling waste.
The blog author replied:
Our guess is that it simple hasn’t been tried! Academia likes to pretend that research is one-and-done, and rarely checks things once they’re in the literature. We agree, someone should try to replicate!
I’m sort of at a loss for words here. How can it possibly be that, 58 years after a pilot study that potentially offers a silver bullet to the problem of obesity, no-one has bothered to check whether it works? I mean, the initial study is so old that Revolver hadn’t been released. Yet it seems to have just lain there, unloved, as the Beatles moved on through Sergeant Pepper, the White Album, Abbey Road et al., broke up, pursued their various solo projects, died (50% of the sample) and watched popular music devolve into whatever the heck it is now.
Why aren’t obesity researchers all over this?
The ludicrous sizes of world-record individuals
February 6, 2023
This recent news story tells of a cane toad found in Australia that weighs six pounds. Here’s the photo, because it’s too good not to include:
Kylee Gray, a ranger with the Queensland Department of Environment and Science, holds a giant cane toad, Thursday, Jan. 12, 2023, near Airlie Beach, Australia. “We believe it’s a female due to the size, and female cane toads do grow bigger than males. When we returned to base, she weighed in at 2.7kg, (5.95 lbs) which could be a new record”, said Gray. (Queensland Department of Environment and Science via AP)
I am no cane-toad expert, so I am only going on what this news report had to say, but apparently the average weight of a cane toad is about one pound. So this new world-record individual masses six times as much as a typical adult.
Mature male saltwater crocodiles Crocodylus porosus are typically about 4.5 m long, but the world-record verified skull length is 76 cm long indicating a total length of about 7 m. Having a length 1.56 times that of a typical individual, this beast would have massed 1.56^3 = 3.75 times as much.
There may be less variance in mammal sizes. The world-record elephant Satao massed about 11 tonnes. That’s about double the typical adult African elephant mass, which is various reported as 5 or 6 tonnes.
Now think about sauropod sizes. We have a bunch of big Diplodocus specimens all measuring on the order of 25 m in length, and massing perhaps 15 tonnes. If world-record individuals compared to these as world-record elephants do, there would have been Diplodocus individuals of twice that mass (30 tonnes); if they compared as crocs do, we should expect giant specimens massing 3.75 times as much (56 tonnes); and if they compared as cane toads do, then the factor of 6 would give us giant Diplodocus individuals massing 90 tonnes.
All of this is speculative of course — wildly so — because we have such tiny samples of Diplodocus compared with the three extant species discussed above. It’s not remotely surprising that the ten or so specimens we have don’t include a freak like this. But there’s a good chance they were out there.
Oh, and for Brachiosaurus, of which known individuals massed perhaps 30 tonnes, it’s not unreasonable to imagine giant individuals massing 60, 112 or gulp! 180 tonnes. Yes, the imagination balks at the idea of a 180-tonne land animal: but that alone is not reason enough to discount the possibility.
DIY dinosaurs: more dinosaur bone standees
January 25, 2023
Michelle Stocker with an apatosaur vertebra (left) and a titanosaur femur (right), both made from foam core board.
In the last post I showed the Brachiosaurus humerus standee I made last weekend, and I said that the idea had been “a gleam in my eye for a long time”. That’s true, but it got kicked into high gear late in 2021 when I got an email from a colleague, Dr. Michelle Stocker at Virginia Tech. She wanted to know if I had any images of big sauropod bones that she could print at life size and mount to foam core board, to demonstrate the size of big sauropods to the students in her Age of Dinosaurs course. We had a nice conversation, swapped some image files, and then I got busy with teaching and kinda lost the plot. I got back to Michelle a couple of days ago to tell her about my Brach standee, and she sent the above photo, which I’m posting here with her permission.
That’s OMNH 1670, a dorsal vertebra of the giant Oklahoma apatosaurine and a frequent guest here at SV-POW!, and MPEF-PV 3400/27, the right femur of the giant titanosaur Patogotitan, from Otero et al. (2020: fig. 8). (Incidentally, that femur is 236cm [7 feet, 9 inches] long, or 35cm longer than our brachiosaur humerus.) For this project Michelle vectorized the images so they wouldn’t look low-res, and she used 0.5-inch foam core board. She’s been using both standees in her Age of Dinosaurs class at VT (GEOS 1054) every fall semester, and she says they’re a lot of fun at outreach events. You can keep up with Michelle and the rest of the VT Paleobiology & Geobiology lab group at their research page, and follow them @VTechmeetsPaleo on Twitter.
Michelle’s standees are fully rad, and naturally I’m both jealous and desirous of making my own. I’ve been wanting a plywood version of OMNH 1670 forever. If I attempt a Patagotitan femur, I’ll probably follow Michelle’s lead and use foam core board instead of plywood — the plywood Brach humerus already gets heavy on a long trek from the house or the vehicle.
Speaking of, one thing to think about if you decide to go for a truly prodigious bone is how you’ll transport it. I can haul the Brach humerus standee in my Kia Sorento, but I have to fold down the middle seats and either angle it across the back standing on edge, or scoot the passenger seat all the way forward so I can lay it down flat. I could *maybe* get the Patagotitan femur in, but it would have to go across the tops of the passenger seats and it would probably rest against the windshield.
Thierra Nalley and me with tail vertebrae of Haplocanthosaurus (smol) and the giant Oklahoma apatosaur (ginormous), at the Tiny Titan exhibit opening.
As long as I’m talking about cool stuff other people have built, a formative forerunner of my project was the poster Alton Dooley made for the Western Science Center’s Tiny Titan exhibit, which features a Brontosaurus vertebra from Ostrom & McIntosh (1966) blown up to size of OMNH 1331, the largest centrum of the giant Oklahoma apatosaurine (or any known apatosaurine). I wouldn’t mind having one of those incarnated in plywood, either.
I’ll bet more things like this exist in the world. If you know of one — or better yet, if you’ve built one — I’d love to hear about it.
References
- Alejandro Otero , José L. Carballido & Agustín Pérez Moreno. 2020. The appendicular osteology of Patagotitan mayorum (Dinosauria, Sauropoda). Journal of Vertebrate Paleontology, DOI: 10.1080/02724634.2020.1793158
- Ostrom, John H., and John S. McIntosh. 1966. Marsh’s Dinosaurs. Yale University Press, New Haven and London. 388 pages including 65 absurdly beautiful plates.
DIY dinosaurs: building a life-size Brachiosaurus humerus standee
January 23, 2023
Building life-size standees of big dinosaur bones has been a gleam in my eye for a long time. What finally pushed me over the edge was an invitation from Oakmont Outdoor School here in Claremont, California, to come talk about dinosaurs. It was an outdoor assembly, with something like 280 kids in attendance, and most of my show and tell materials are hand-sized and would not show up well from a distance. Plus, I wanted to blow people away with the actual size of big dinosaur bones.
I started with a life-size poster print of FHPR 17108, the complete right humerus of Brachiosaurus from Brachiosaur Gulch in Utah (the story of the discovery and excavation of that specimen is here). I used the image shown above, scaled to print at 7 feet by 3 feet. You can see that print lying on my living room floor in the previous post.
It was simpler and cheaper to get two 2 foot x 4 foot pieces of plywood than one big piece, so that’s what I did. I laid them out on the living room floor, cut out the poster print of the humerus from its background, traced the outline of the humerus onto the plywood, and then took the pieces outside to cut out the humerus shapes with a jigsaw.
The big piece of darker plywood is the brace that holds the two front pieces together. The smaller piece down at the distal end is a sort of foot, level with the bottom of the humerus but wider and flatter to give more stability. I used wood glue and a bunch of screws to hold everything together. Probably more screws than were strictly necessary, but I wanted to build this thing once and then never worry about it again, and screws and glue are cheap.
Even just the plywood outline without the print glued on looked pretty good. Early in the project I dithered on whether to make the thing out of plywood or foam core board. Foam core board would have been cheaper, easier to work with, and a lot lighter, but I also had doubts about its survivability. I want to use this thing for outreach for a long time to come.
To make the thing free-standing I added a kickstand in the back, made from a six-foot board and a hinge.
I used some screw-eyes and steel wire from a picture-hanging kit to add restraints to the kickstand, so it can’t open up all the way and collapse.
I didn’t want the kickstand flopping around during transit, and I also did not want the whole weight of the kickstand hanging cantilevered from the hinge when this thing is being carried horizontally, so I added a couple of blocks on either side for support, and some peel-and-stick velcro to hold the kickstand in place when it’s not being used.
I took the thing to Oakmont Outdoor School this morning and everybody loved it. I think the teachers were just as impressed as the kids. That’s Jenny Adams, the principal at Oakmont, who invited me to come speak.
This was a deeply satisfying project and it didn’t require any complex or difficult techniques. The biggest expense was the big poster print, and the most specialized piece of equipment was the jigsaw. You could save money by going black-and-white or just blowing up an outline drawing on a plotter, by scavenging the plywood instead of buying new (all my old plywood has been turned into stuff already), or by using foam core board or some other lightweight material.
Many thanks to Jenny Adams and the whole Oakmont community for giving me a chance to come speak, and for asking so many excellent questions. However much fun it was for you all, I’m pretty sure it was even more fun for me. And now I have an inconveniently gigantic Brachiosaurus humerus to worship play with!
I am about a great work
January 21, 2023
I’m also teaching in two anatomy courses and in the process of moving residences (hence bins and boxes and whatnot), so the timing’s…not great. But needs must when the devil drives.
Further bulletins as events warrant.
I’m sure you’ve seen things like ChatGPT in the news: programs that can carry out pretty convincing conversations. They are known as Large Language Models (LLMs) and are frequently referred to as being Artificial Intelligence (AI) — but I really don’t like that designation as it implies some understanding.
To try this out, I asked OpenAI Chat this question: “What are the contenders for the title of Biggest Dinosaur, and what is the basis for their various claims?” I picked that because I know a bit about the answer, and in fact wrote an answer myself back in 2015.
Here’s what it came up with:
There are several contenders for the title of “biggest dinosaur,” and their claims are based on different pieces of evidence. The most commonly cited contenders are:
- Argentinosaurus: This is considered to be one of the largest known dinosaurs, with estimates of its length ranging from 110-130 feet (33-40 meters) and a weight of around 100-110 tons. Its size is based on a few fragmented bones, including vertebrae and limb bones, which were found in Argentina.
- Brachiosaurus: This dinosaur is estimated to have been around 85 feet (26 meters) long and weighed around 80-100 tons. Its size is based on several well-preserved specimens that have been found in North America, including a nearly complete skeleton.
- Puertasaurus: This dinosaur is estimated to have been around 85-100 feet (26-30 meters) long and weighed around 80-100 tons. Its size is based on a few bones, including a femur, that were found in Argentina.
- Supersaurus: This dinosaur is estimated to have been around 110-125 feet (33-38 meters) long and weighed around 80-100 tons. Its size is based on a single specimen, a set of vertebrae, that was found in the US.
- Diplodocus: This dinosaur is estimated to have been around 90-115 feet (27-35 meters) long and weighed around 20-40 tons. Its size is based on several well-preserved specimens that have been found in North America.
It’s worth noting that the size of these dinosaurs is approximate and there’s still debate among paleontologists. Also, the weight of these dinosaurs is based on estimations, not real measurements.
At first glance this is a decent answer. It’s certainly better than just saying “Argentinosaurus weighed 100 tons”. But if you know your sauropods, you’ll immediately recognise that this answer is riddled with inaccuracies:
- The Argentinosaurus entry is actually pretty good, although I’ve never seen a 110 ton mass estimate and modern estimates tend to be rather lower than the specified range.
- The Brachiosaurus mass estimate is way off, two or three times as high as it should be.
- More importantly, no remotely complete Brachiosaurus specimen has ever been described, and size estimates are based primarily on its Tanzanian relative Giraffatitan.
- There is no known femur of Puertasaurus. (When I corrected the AI on this, it told me instead that there is a pubis known.)
- Supersaurus is not based on a single specimen, and both of the main specimens that have been described contain plenty of appendicular material.
- The Diplodocus length estimate is a bit inflated, but otherwise not bad. But it’s not clear what it’s doing in a list of five biggest dinosaurs.
- The answer omits some very strong contenders, including Dreadnoughtus and Patagotitan.
- It doesn’t really address the second part of my question — e.g. Supersaurus has a good claim to be longer, but not heaviest; the converse is likely true for Argentinosaurus.
Now here is the real problem: the LLM does well enough to fool people. If it was nonsense from start to end, there would be nothing to fear here, but the plausibility of the answers and the authoritative tone in which they are given lends the many mistakes a credibility that they do not deserve.
Having seen this sort-of-convincing-but-very-wrong reply in a field that I know something about, I would be very very cautious about trusting an LLM to teach me about a field I don’t already know. I’m guessing its replies about space flight, quantum physics and Medieval French literature are going to be similarly flawed (but also, worryingly, similarly convincing to those such as myself who don’t know better.)
There is a very fundamental reason for all these mistakes: as I implied above, LLMs do not understand anything. They just know what phrases occur close to other phrases. They can do amazing things with that one trick, and I can see them being useful as discovery tools. But we’ll go badly wrong when we start trusting them as anything more than a bright but ignorant kid offering suggestions.
So for all the talk of AI having taken huge leaps forward in the last couple of years, I don’t think any such thing has happened. We’ve just got much better at generating plausible text. But there’s no advance in actual understanding.
Get yourselves over to Sauropoda Central!
January 3, 2023
For some bizarre reason, I have only today discovered Sauropoda Central — a sauropod blog written by someone who goes only by the name “Davidow”, but whose introductory post reveals that he is occasional SV-POW! commenter Vahe Demirjian.
It’s a solid blog full of meaty, sauropodolicious nourishment. There are 26 posts to catch up on, going back 2013, but the posting rate has recently picked up.
(I find the background image very distracting — for one thing, it makes it look like the blog’s title is Argentinosaurus huinculensis — but we can look past that.)
New paper out today: Aureliano et al. (2022) on vertebral internal structure in the earliest saurischians
December 9, 2022
Micro-computed tomography of the vertebrae of the basalmost sauropodomorph Buriolestes (CAPPA/UFSM 0035). (A) silhouette shows the position of the axial elements. Artist: Felipe Elias. (B), three-dimensional reconstruction of the articulated cervical vertebral series and the correspondent high-contrast density slices in (D–I). Diagenetic processes partially compromised the internal structures in these cervicals. (C), 3D reconstruction of the articulated anterior dorsal vertebrae and the correspondent high-contrast density slices in (J–M). Small circumferential chambers occur both ventrally in the dorsal centrum (J) and laterally in the neural arch pedicles (D). All images indicate apneumatic chaotic trabeculae architecture. Some of the latter develop into larger chambers in the centrum (E,J,K). Nutritional foramina are broader at the bottom of the neural canal in the posterior cervicals (F,G). All slices were taken from the approximate midshaft. Anterior views in (D–H,J,K). Lateral view in (L). Ventral view in (H,I,M). Anterior/posterior orientation was defined based on the axial position, not the anatomical plane. cc circumferential chamber, ccv chamber in the centrum, ctr chaotic trabecula, d diapophysis, ltr layered trabeculae, nc neural canal, nf nutritional foramen, s neural spine. Scale bar in (A) = 500 mm; in (B–M) = 10 mm. Computed tomography data processed with 3D Slicer version 4.10. Figures were generated with Adobe Photoshop CC version 22.5.1 X64. (Aureliano et al. 2022: fig. 4)
Here’s a nice early holiday present for me: 51 weeks after our first paper together, I’m on another one with Tito Aureliano and colleagues:
As before, I’m in the “just happy to be here” last author position, and quite happy to be so, too. I’ve had a productive couple of years, mostly because my colleagues keep inviting me to write a little bit, usually about pneumaticity, in exchange for a junior authorship, and that’s actually a perfect fit for my bandwidth right now. That dynamic has let me work on some cool and varied projects that have broadened my experience in satisfying ways. But enough navel-gazing!
Also as before, Tito made a really nice video that explains our findings from the paper and puts them in their broader scientific context:
For a long time now I’ve been interested in the origin of postcranial skeletal pneumaticity (PSP) in dinosaurs and pterosaurs (e.g., Wedel 2006, 2007, 2009, Yates et al. 2012, Wedel and Taylor 2013) — or is that origins, plural? Tito and crew decided to take a swing at the problem by CT scanning presacral vertebrae from the early sauropodomorphs Buriolestes and Pampadromaeus, and the herrerasaurid Gnathovorax. (Off-topic: Gnathovorax, “jaw inclined to devour”, is such a badass name that I adopted it for an ancient blue dragon in my D&D campaign.) All three taxa have shallow fossae on the lateral sides of at least some of their presacral centra, and some neural arch laminae, so they seemed like good candidates in which to hunt for internal pneumatization.
I’ll cut right to the chase: none of three have internal pneumatic chambers in their vertebrae, so if there were pneumatic diverticula present, they weren’t leaving diagnostic traces. That’s not surprising, but it’s nice to know rather than to wonder. The underlying system of respiratory air sacs could have been present in the ancestral ornithodiran, and I strongly suspect that was the case, but invasive vertebral pneumatization evolved independently in pterosaurs, sauropodomorphs, and theropods.
Detail of the vertebrae and foramina of the basalmost sauropodomorph Buriolestes (CAPPA/UFSM-0035). Cervical (A–C), anterior (D–F) and posterior (G–I) dorsal vertebrae in right lateral view. Note that nutritional foramina are present throughout the axial skeleton (dark arrows). Anterior/posterior orientation was defined based on the axial position, not the anatomical plane. Scale bar = 5 mm. Figures were generated with Adobe Photoshop CC version 22.5.1 X64. (Aureliano et al. 2022: fig. 4).
Just because we didn’t find pneumaticity, doesn’t mean we didn’t find cool stuff. Buriolestes, Pampadromaeus, and Gnathovorax all have neurovascular foramina — small holes that transmitted blood vessels and nerves — on the lateral and ventral aspects of the centra. That’s also expected, but again nice to see, especially since we think these blood vessels provided the template for invasive vertebral pneumatization in more derived taxa.
The findings I’m most excited about have to do with the internal structure of the vertebrae. Some of the vertebrae have what we’re calling a pseudo-polycamerate architecture. The polycamerate vertebrae of sauropods like Apatosaurus have large pneumatic chambers that branch into successively smaller ones. Similarly, some of the vertebrae in these Triassic saurischians have large marrow chambers that connect to smaller trabecular spaces — hence the term ‘pseudo-polycamerate’. This pseudo-polycamerate architecture is present in Pampadromaeus, but not in the slightly older Buriolestes, which has a more chaotic internal organization of trabecular spaces. So even in the apneumatic vertebrae of these early saurischians, there seems to have been an evolutionary trajectory toward more hierarchially-structured internal morphology.
Micro-computed tomography of the vertebrae of the herrerasaurid Gnathovorax (CAPPA/UFSM-0009). (A) silhouette shows the position of the axial elements. Artist: Felipe Elias. (B) 3D reconstruction of the anterior cervical vertebra and the correspondent high-contrast density slices in (D-I). Diagenetic artifacts greatly compromised the internal structures. (C) 3D reconstruction of the articulated posterior cervical vertebrae and the correspondent high-contrast density slices in (J–O). Minerals infilled between trabecular vacancies generate reddish anomalies. All images indicate irregular, chaotic, apneumatic architecture. Note the apneumatic large chambers in the centrum (ccv) and the smaller circumferential chambers at the bottom (cc). All slices were taken from the approximate midshaft. Anterior views in (D,H,I). Right lateral view in (E,L,M). Ventral view in (F,G,J,K). cc circumferential chambers, ccv chamber in the centrum, ce centrum, ctr chaotic trabeculae, d diapophysis, dia diagenetic artifact, nc neural canal, nf nutritional foramen, poz postzygapophysis, prz prezygapophysis. Scale bar in (A) = 1000 mm; in (B–O) = 10 mm. Computed tomography data processed with 3D Slicer version 4.10. Figures were generated with Adobe Photoshop CC version 22.5.1 X64.
But wait, there’s more! We also found small circumferential chambers around the margins of the centra, and what we’re calling ‘layered trabeculae’ inside the articular ends of the centra. These apneumatic trabecular structures look a heck of a lot like the circumferential pneumatic chambers and radial camellae that we described last year in a dorsal vertebra of what would later be named Ibirania (Navarro et al. 2022), and which other authors had previously described in other titanosaurs (Woodward and Lehman 2009, Bandeira et al. 2013) — see this post.
So to quickly recap, in these Triassic saurischians we find external neurovascular foramina from the nerves and vessels that probably “piloted” the pneumatic diverticula (in Mike’s lovely phrasing from Taylor and Wedel 2021) to the vertebrae in more derived taxa, and internal structures that are resemble the arrangement of pneumatic camerae and camellae in later sauropods and theropods. We already suspected that pneumatic diverticula were following blood vessels to reach the vertebrae and produce external pneumatic features like fossae and foramina (see Taylor and Wedel 2021 for a much fuller development of this idea). The results from our scans of these Triassic taxa suggests the tantalizing possibility that pneumatic diverticula in later taxa were following the vascular networks inside the vertebrae as well.
A morphological spectrum of vertebral structure, as I thought of it 15 years ago. The Triassic saurischians described in the new paper by Aureliano et al. 2022 would sit between Arizonasaurus and Barapasaurus. (Wedel 2007: text-fig. 8)
“Hold up”, I can hear you thinking. “You can’t just draw a straight line between the internal structure of the vertebrae in Pampadromaeus, on one hand, and Apatosaurus, or a friggin’ saltasaurine, on the other. They’re at the opposite ends of the sauropodomorph radiation, separated by a vast and stormy ocean of intermediate taxa with procamerate, camerate, and semicamellate vertebrae, things like Barapasaurus, Haplocanthosaurus, Camarasaurus, and Giraffatitan.” That’s true, and the vertebral internal structure in, say, Camarasaurus doesn’t look much like either Pampadromaeus or Ibirania — at least, in an adult Camarasaurus. What about a hatchling, which hasn’t had time to pneumatize yet? Heck, what about a baby Ibirania or Rapetosaurus or Alamosaurus? Nobody knows because nobody’s done that work. There aren’t a ton of pre-pneumatization baby neosauropod verts out there, but there are some. There’s an as-yet-unwritten dissertation, or three, to be written about the vascular internal structure of the vertebrae in baby neosauropods prior to pneumatization, and in adult vertebrae that don’t get pneumatized. If caudal 20 is the last pneumatic vertebra, what does the vascular internal structure look like in caudal 21?
Cervical vertebrae of Austroposeidon show multiple internal plates of bone separated by sheets of camellae. Bandeira et al. (2016) referred to those as ‘camellate rings’, Aureliano et al. (2021) called them ‘internal plates’, and in the new paper (Aureliano et al. 2022) we call similar structures in apneumatic vertebrae ‘layered trabeculae’. (Bandeira et al. 2016: fig. 12)
To me the key questions here are, first, why does the pneumatic internal structure of the vertebrae of titanosaurs like Ibirania — or Austroposeidon, shown just above in a figure from Bandeira et al. (2016) — look like the vascular internal structure of the vertebrae of basal sauropodomorphs like Pampadromaeus? Is that (1) a kind of parallelism or convergence; (2) a deep developmental program that builds vertebrae with sheets of bone separated by circumferential and radial spaces, whether those spaces are filled with marrow or air; (3) a fairly direct ‘recycling’ of those highly structured marrow spaces into pneumatic spaces during pneumatization; or (4) some other damn thing entirely? And second, why is the vertebral internal structure of intermediate critters like Haplocanthosaurus and Camarasaurus so different from that of both Ibirania and Pampadromaeus— do the pneumatic internal structures of those taxa reflect the pre-existing vascular pattern, or are they doing something completely different? That latter question in particular is unanswerable until we know what the apneumatic internal structure is like in Haplocanthosaurus and Camarasaurus, either pre-pneumatization (ontogenetically), or beyond pneumatization (serially), or ideally both.
A Camarasaurus caudal with major blood vessels mapped on, based on common patterns in extant tetrapods. A list of the places where blood vessels enter the bone is also a list of places where sauropod vertebrae can possibly be pneumatized. We don’t think that’s a coincidence. From Mike’s and my presentation last December at the 3rd Palaeo Virtual Congress, and this post. (Wedel and Taylor 2021)
I was on the cusp of writing that the future of pneumaticity is vascular. That’s true, but incomplete. A big part of figuring out why pneumatic structures have certain morphologies is going to be tracing their development, not just the early ontogenetic stages of pneumatization, but the apneumatic morphologies that existed prior to pneumatization. BUT we’re also nowhere near done just doing the alpha-level descriptive work of documenting what pneumaticity looks like in most sauropods. I’ll have more to say about that in an upcoming post. But the upshot is that now we’re fighting a war on two fronts — we still need to do a ton of basic descriptive work on pneumaticity in most taxa, and also need to do a ton of basic descriptive work on vertebral vascularization, and maybe a third ton on the ontogenetic development of pneumaticity, which is likely the missing link between those first two tons.
I’m proud of the new paper, not least because it raises many, many more questions than it answers. So if you’re interested in working on pneumaticity, good, because there’s a mountain of work to be done. Come join us!
References
- Tito Aureliano, Aline M. Ghilardi, Bruno A. Navarro, Marcelo A. Fernandes, Fresia Ricardi-Branco, & Mathew J. Wedel. 2021. Exquisite air sac histological traces in a hyperpneumatized nanoid sauropod dinosaur from South America. Scientific Reports 11: 24207.
- Aureliano, T., Ghilardi, A.M., Müller, R.T., Kerber, L., Pretto, F.A., Fernandes, M.A., Ricardi-Branco, F., and Wedel, M.J. 2022. The absence of an invasive air sac system in the earliest dinosaurs suggests multiple origins of vertebral pneumaticity. Scientific Reports 12:20844. https://doi.org/10.1038/s41598-022-25067-8
- Bandeira KLN, Medeiros Simbras F, Batista Machado E, de Almeida Campos D, Oliveira GR, Kellner AWA (2016) A New Giant Titanosauria (Dinosauria: Sauropoda) from the Late Cretaceous Bauru Group, Brazil. PLoS ONE 11(10): e0163373. https://doi.org/10.1371/journal.pone.0163373
- Navarro, Bruno A.; Ghilardi, Aline M.; Aureliano, Tito; Díaz, Verónica Díez; Bandeira, Kamila L. N.; Cattaruzzi, André G. S.; Iori, Fabiano V.; Martine, Ariel M.; Carvalho, Alberto B.; Anelli, Luiz E.; Fernandes, Marcelo A.; Zaher, Hussam. 2022. A new nanoid titanosaur (Dinosauria: Sauropoda) from the Upper Cretaceous of Brazil. Ameghiniana. 59 (5): 317–354.
- Taylor, Michael P., and Mathew J. Wedel. 2021. Why is vertebral pneumaticity in sauropod dinosaurs so variable? Qeios 1G6J3Q. doi:10.32388/1G6J3Q.5
- Wedel, M.J. 2006. Origin of postcranial skeletal pneumaticity in dinosaurs. Integrative Zoology 2:80-85.
- Wedel, M.J. 2007a. What pneumaticity tells us about ‘prosauropods’, and vice versa. Special Papers in Palaeontology 77:207-222.
- Wedel, M.J. 2009. Evidence for bird-like air sacs in saurischian dinosaurs. Journal of Experimental Zoology 311A:611-628.
- Wedel, Mathew J., and Taylor, Michael P. 2013. Caudal pneumaticity and pneumatic hiatuses in the sauropod dinosaurs Giraffatitan and Apatosaurus. PLOS ONE 8(10):e78213. doi:10.1371/journal.pone.0078213
- Wedel, M.J., and Taylor, M.P. 2021. Blood vessels provided the template for vertebral pneumatization in sauropod dinosaurs. 3rd Palaeontological Virtual Congress.
- Woodward, H.N., and Lehman, T.M. 2009. Bone histology and microanatomy of Alamosaurus sanjuanensis (Sauropoda: Titanosauria) from the Maastrichtian of Big Bend National Park, Texas. Journal of Vertebrate Paleontology 29(3):807-821.
- Yates, A.M., Wedel, M.J., and Bonnan, M.F. 2012. The early evolution of postcranial skeletal pneumaticity in sauropodomorph dinosaurs. Acta Palaeontologica Polonica 57(1):85-100. doi: http://dx.doi.org/10.4202/app.2010.0075
Sauropod Vertebra Picture of the Week 