Giving particle detectors a boost

Argonne researchers have created a new device that acts like a superconductivity switch, helping boost the signal of tiny particles in particle colliders

DOE/ARGONNE NATIONAL LABORATORY

 

IMAGE: 

FALSE COLOR SCANNING ELECTRON MICROSCOPE IMAGE OF A PARALLEL-CHANNEL SUPERCONDUCTING NANOCRYOTRON. BLUE HIGHLIGHTS THE GROUND PLANE, GREY SHOWS THE TRENCH AND NANOWIRE GAPS, GREEN REPRESENTS THE EFFECTIVE NBN CHANNEL, AND RED SIGNIFIES THE NBN GATE TO CHOKE CONSTRICTION. SCALE BARS CORRESPOND TO 2 ΜM.

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CREDIT: (IMAGE BY ARGONNE NATIONAL LABORATORY.)

Device could help facilitate the operation of new particle colliders, such as the Electron-Ion Collider.

In particle colliders that reveal the hidden secrets of the tiniest constituents of our universe, minute particles leave behind extremely faint electrical traces when they are generated in enormous collisions. Some detectors in these facilities use superconductivity — a phenomenon in which electricity is carried with zero resistance at low temperatures — to function.

For scientists to more accurately observe the behavior of these particles, these weak electrical signals, or currents, need to be multiplied by an instrument capable of turning a faint electrical flicker into a real jolt.

Scientists at the U.S. Department of Energy’s (DOE) Argonne National Laboratory have developed a new device that acts as a ​“current multiplier.” This device, called a nanocryotron, is a prototype for a mechanism that could turn up a particle’s electrical signal high enough to a level where it temporarily turns off the superconductivity of the material, essentially creating a kind of on-off switch.

“This work is especially important for collider experiments, such as those that will be performed at the Electron-Ion Collider at Brookhaven National Laboratory.” — Argonne Distinguished Fellow and group leader Zein-Eddine Meziani

“We’re taking a small signal and using it to trigger an electric cascade,” said Tomas Polakovic, one of Argonne’s Maria Goeppert Mayer Fellows and an author of the study. ​“We’re going to funnel the very small current of these detectors into the switching device, which can be then used to switch a much bigger current.”

To prepare the nanocryotron for a collider experiment will take some more work because of the high magnetic fields involved. While today’s particle detectors can withstand magnetic fields of several tesla in strength, this switch’s performance degrades in high magnetic fields.

“Finding ways to make the device work in higher magnetic fields is key to incorporating it into a real experiment,” said Argonne graduate research assistant Timothy Draher, another author of the study.

To make this possible, the researchers plan to change the geometry of the material and introduce defects, or tiny holes. These defects will help researchers stabilize small superconducting vortices in the material, the movement of which can lead to an unanticipated disruption of superconductivity.

The nanocryotron was created by using electron beam lithography, a kind of stenciling technique that uses a beam of electrons to remove a polymer film to expose a particular region of interest. That region of interest is then etched using plasma ion etching.

“We basically just strip away the parts that are exposed, leaving behind the device that we want to use,” Draher said.

According to Argonne physicist Valentine Novosad, another author of the study, the new device also could serve as the basis for a kind of electronic logic circuitry.

“This work is especially important for collider experiments, such as those that will be performed at the Electron-Ion Collider at Brookhaven National Laboratory. There, superconducting nanowire detectors, positioned close to the beams, would require microelectronics immune to magnetic fields,” said Argonne Distinguished Fellow and group leader Zein-Eddine Meziani.

A paper based on the study, ​“Design and performance of parallel-channel nanocryotrons in magnetic fields,” appeared in the Dec. 18, 2023 edition of Applied Physics Letters. In addition to Draher, Zein-Eddine, Polakovic and Novosad, authors include Yi Li, John Pearson, Alan Dibos and Zhili Xiao.

The work was funded by DOE’s Office of Science, Office of Nuclear Physics. Work to perform reactive ion etching of the superconducting films in the experiment was carried out at the Center for Nanoscale Materials, a DOE User Facility.

About Argonne’s Center for Nanoscale Materials
The Center for Nanoscale Materials is one of the five DOE Nanoscale Science Research Centers, premier national user facilities for interdisciplinary research at the nanoscale supported by the DOE Office of Science. Together the NSRCs comprise a suite of complementary facilities that provide researchers with state-of-the-art capabilities to fabricate, process, characterize and model nanoscale materials, and constitute the largest infrastructure investment of the National Nanotechnology Initiative. The NSRCs are located at DOE’s Argonne, Brookhaven, Lawrence Berkeley, Oak Ridge, Sandia and Los Alamos National Laboratories. For more information about the DOE NSRCs, please visit https://​sci​ence​.osti​.gov/​U​s​e​r​-​F​a​c​i​l​i​t​i​e​s​/​U​s​e​r​-​F​a​c​i​l​i​t​i​e​s​-​a​t​-​a​-​G​lance.

Argonne National Laboratory seeks solutions to pressing national problems in science and technology. The nation’s first national laboratory, Argonne conducts leading-edge basic and applied scientific research in virtually every scientific discipline. Argonne researchers work closely with researchers from hundreds of companies, universities, and federal, state and municipal agencies to help them solve their specific problems, advance America’s scientific leadership and prepare the nation for a better future. With employees from more than 60 nations, Argonne is managed by UChicago Argonne, LLC for the U.S. Department of Energy’s Office of Science.

The U.S. Department of Energy’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit https://​ener​gy​.gov/​s​c​ience.

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JOURNAL

Applied Physics Letters

DOI

10.1063/5.0180709 

ARTICLE TITLE

Design and performance of parallel-channel nanocryotrons in magnetic fields

Robotic interface masters a soft touch

EPFL researchers have developed a haptic device capable of reproducing the softness of various materials, from a marshmallow to a beating heart, overcoming a deceptively complex challenge that has previously eluded roboticists

ECOLE POLYTECHNIQUE FÉDÉRALE DE LAUSANNE

 

IMAGE: 

SORI (SOFTNESS RENDERING INTERFACE)

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CREDIT: JAMANI CAILLET

The perception of softness can be taken for granted, but it plays a crucial role in many actions and interactions – from judging the ripeness of an avocado to conducting a medical exam, or holding the hand of a loved one. But understanding and reproducing softness perception is challenging, because it involves so many sensory and cognitive processes.

Robotics researchers have tried to address this challenge with haptic devices, but previous attempts have not distinguished between two primary elements of softness perception: cutaneous cues (sensory feedback from the skin of the fingertip), and kinesthetic cues (feedback about the amount of force on the finger joint).

“If you press on a marshmallow with your fingertip, it’s easy to tell that it’s soft. But if you place a hard biscuit on top of that marshmallow and press again, you can still tell that the soft marshmallow is underneath, even though your fingertip is touching a hard surface,” explains Mustafa Mete, a PhD student in the Reconfigurable Robotics Lab in the School of Engineering. “We wanted to see if we could create a robotic platform that can do the same.”

With SORI (Softness Rendering Interface), the RRL, led by Jamie Paik, has achieved just that. By decoupling cutaneous and kinesthetic cues, SORI faithfully recreate the softness of a range of real materials, filling a gap in the robotics field enabling many applications where softness sensation is critical – from deep-sea exploration to robot-assisted surgery.

The research appears in the Proceedings of the National Academy of Science (PNAS).

The Softness Rendering Interface (SORI) can recreate the softness of a range of materials

CREDIT

© Jamani Caillet

We all feel softness differently

Mete explains that neuroscientific and psychological studies show that cutaneous cues are largely based on how much skin is in contact with a surface, which is often related in part to the deformation of the object. In other words, a surface that envelopes a greater area of your fingertip will be perceived as softer. But because human fingertips vary widely in size and firmness, one finger may make greater contact with a given surface than another.

“We realized that the softness I feel may not be the same as the softness you feel, because of our different finger shapes. So, for our study, we first had to develop parameters for the geometries of a fingertip and its contact surface in order to estimate the softness cues for that fingertip,” Mete explains. Then, the researchers extracted the softness parameters from a range of different materials, and mapped both sets of parameters onto the SORI device.

Building on the RRL’s trademark origami robot research, which has fueled spinoffs for reconfigurable environments and a haptic joystick, SORI is equipped with motor-driven origami joints that can be modulated to become stiffer or more supple. Perched atop the joints is a dimpled silicone membrane. A flow of air inflates the membrane to varying degrees, to envelop a fingertip placed at its center.

With this novel decoupling of kinesthetic and cutaneous functionality, SORI succeeded in recreating the softness of a range of materials – including beef, salmon, and marshmallow – over the course of several experiments with two human volunteers. It also mimicked materials with both soft and firm attributes (such as a biscuit on top of a marshmallow, or a leather-bound book). In one virtual experiment, SORI even reproduced the sensation of a beating heart, to demonstrate its efficacy at rendering soft materials in motion.

Medicine is therefore a primary area of potential application for this technology; for example, to train medical students to detect cancerous tumors, or to provide crucial sensory feedback to surgeons using robots to perform operations.

Other applications include robot-assisted exploration of space or the deep ocean, where the device could enable scientists to feel the softness of a discovered object from a remote location. SORI is also a potential answer to one of the biggest challenges in robot-assisted agriculture: harvesting tender fruits and vegetables without crushing them.

“This is not intended to act as a softness sensor for robots, but to transfer the feeling of ‘touch’ digitally, just like sending photos or music,” Mete summarizes.

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JOURNAL

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2314901121 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

SORI: A Softness Rendering Interface to Unravel the Nature of Softness Perception

ARTICLE PUBLICATION DATE

11-Mar-2024

Propelling 3D printing into the future

Printing stronger materials five times faster

Business Announcement

DOE/SANDIA NATIONAL LABORATORIES

 MULTIMEDIA RELEASE 11-MAR-2024

 

IMAGE: 

SAMUEL LEGUIZAMON, LEFT, WATCHES AS ALEX COMMISSO STRETCHES 3D MATERIAL THAT THEY PRINTED AT SANDIA NATIONAL LABORATORIES, USING SELECTIVE DUAL-WAVELENGTH OLEFIN METATHESIS 3D-PRINTING, OR SWOMP.

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CREDIT: CRAIG FRITZ/SANDIA NATIONAL LABORATORIES

A NEW WAY OF PRINTING (IMAGE)

DOE/SANDIA NATIONAL LABORATORIES

CAPTION

SWOMP or Selective Dual-Wavelength Olefin Metathesis 3D-Printing uses two wavelengths of light simultaneously to change the way certain materials are 3D printed.

 

CREDIT

Graphic Courtesy: Samuel Leguizamon

Alex Commisso flexes a piece of 3D- printed material with varying softness achieved by Selective Dual-Wavelength Olefin Metathesis 3D-Printing, or SWOMP. 

CREDIT

Craig Fritz/Sandia National Laboratories

 

Deciphering the tip of migrating neurons: Discovery of growth cone in migrating neurons involved in promoting neuronal migration and regeneration in the brain after injury

Migrating neurons possess a growth cone that shares functions with axonal growth cones and regulates neuronal migration by interaction with the extracellular environment

NAGOYA CITY UNIVERSITY

 

IMAGE: 

COLLECTIVE TIME-LAPSE IMAGES OF A MIGRATING NEURON (LEFT) AND AN ELONGATING AXON (RIGHT) FROM SUPER-RESOLUTION MICROSCOPY. GROWTH CONES AT THE TIPS OF THE NEURONS ARE EXTENDED WHILE THE CELL BODY MIGRATES AND THE AXON ELONGATES.

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CREDIT: © NAGOYA CITY UNIVERSITY GRADUALTE SCHOOL OF MEDICAL SCIENCES

The structure and functions of the tip of migrating neurons remain elusive. Here, a research group led by Kazunobu Sawamoto, Professor at Nagoya City University and National Institute for Physiological Sciences, and by Chikako Nakajima and Masato Sawada, staff scientists in his laboratory, has found that the PTPσ-expressing growth cone senses the extracellular matrix and drives neuronal migration in the injured brain, leading to functional recovery.

Neural stem cells are present in the postnatal mammalian brain and produce new neurons. New neurons migrate toward injured sites, and promoting neuronal migration results in functional recovery after brain injury. Nevertheless, there is an inhibitory effect on neuronal migration in the injured sites, the mechanisms of which need to be elucidated in order to improve recruitment of new neurons in the injured sites and thus to enhance the recovery after brain injury. The migrating neurons possess an axonal growth cone-like structure at their tip, but the role of this structure in neuronal migration has not been fully understood.

Sawamoto’s group focused on elucidating the function of the growth cone-like structure of migrating neurons of the mouse brain. The researchers used super-resolution microscopy to study the cytoskeletal dynamics and molecular features of the neuronal tip. They showed that the tip structure shares important functions with axonal growth cones. In short, the growth cone of cultured migrating neurons is responsive to external signals through tyrosine phosphatase receptor type sigma (PTPσ) to guide the directionality of migration and initiate the movement of their cell body. The growth cone responds to chondroitin sulfate (CS) through PTPσ and collapses, resulting in inhibition of neuronal migration. In the presence of CS, the growth cones can revert to their extended morphology when they interact with heparan sulfate (HS), thus re-enabling neuronal migration. 

“To investigate whether the effect of HS in reversing the inhibitory effect of CS can promote neuronal migration in the injured brain, it was necessary to apply HS-containing biomaterial to the CS-rich injured brain,” Sawamoto said. 

Next, they employed HS-containing gelatin-fiber nonwoven fabric, a biomaterial that provides structural scaffolds for cells such as migrating neurons. They showed that the applied HS-containing fibers promoted extension of growth cones and neuronal migration in the injured brain. Furthermore, implantation of the HS-enriched gelatin fabric promoted the regeneration of mature neurons and restored neurological functions. These results suggest that elucidating the molecular mechanisms of growth cone-mediated interaction with the local extracellular environment may enable the development of new regeneration technologies based on the promotion of neuronal migration.

Recent studies by other groups have shown that aging alters the physical properties of brain extracellular matrix, including CSPG. 

“Given that the growth cone of migrating neurons serves as a primer for neuronal migration under inhibitory extracellular conditions, it is necessary to further investigate whether the growth cone-mediated treatment to recruit new neurons from the endogenous source to the damaged sites is also applicable to aged brains,” Nakajima commented.

The full findings of the study are published in Nature Communications.
Article title: Identification of the growth cone as a probe and driver of neuronal migration in the injured brain. DOI: 10.1038/s41467-024-45825-8

In addition to Kazunobu Sawamoto, Chikako Nakajima, and Masato Sawada, co-authors of this research article include researchers from Nagoya City University, National Institute for Physiological Sciences, Niigata University, Kyoto University, Doshisha University, Jichi Medical University, The Japan Wool Textile Co., Ltd., Nikke Medical Co., Ltd., Toray Research Center, Inc., New York University, Friedrich Schiller University Jena, University of Valencia, and University of Pennsylvania.

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JOURNAL

Nature Communications

DOI

10.1038/s41467-024-45825-8 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Animal tissue samples

ARTICLE TITLE

Identification of the growth cone as a driver and probe of neuronal migration in the injured brain

ARTICLE PUBLICATION DATE

9-Mar-2024

 

New research sets trap for potentially deadly sandfly

Peer-Reviewed Publication

UNIVERSITY OF NOTTINGHAM

 

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LUTZOMYIA LONGIPALPIS, A SPECIES OF SANDFLY NATIVE TO BRAZIL AND SOUTH AMERICA THAT CAN SPREAD A DISEASE CALLED LEISHMANIASIS. 

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CREDIT: UNIVERSITY OF NOTTINGHAM

Scientists have discovered the specific enzyme that a species of sandfly uses to produce a pheromone attractant, which could lead to the creation of targeted traps to control them and reduce the spread of the potentially fatal disease, Leishmaniasis.

The team from the University of Nottingham’s School of Chemistry analysed the genome of the Lutzomyia longipalpis, a species of sandfly native to Brazil and South America that can spread a disease called Leishmaniasis. 

The study identified the enzyme, called a Terpene Synthase that is responsible for making the terpene pheromone sobralene, that the insect uses to attract others for mating, a discovery that could lead to the development of commercial traps for targeting and controlling this type of sandfly. The research has been published today in PNAS. (link to be added)

Over 90 sandfly species are known to transmit Leishmania parasites that are spread to humans through being bitten, but Lutzomyia longipalpis is the major carrier of the disease in South America. The most common symptoms of the disease are skin ulcers and lesions which can leave life-long scars, in more serious cases people can become very unwell with fever, weight loss, enlargement of the spleen and liver, and anaemia. The most serious form of the disease, known as visceral leishmaniasis, is invariably fatal within 2-years if untreated. Most cases of visceral leishmaniasis occur in Brazil, but the disease can be found in large parts of the tropics and subtropics. 

Terpenes are widely used in nature for chemical communication, but understanding how these structurally diverse natural products are produced by insects is only now beginning to emerge. Males of the sandfly, Lutzomyia longipalpis, use terpene pheromones to lure females and other males to mating sites. 

Terpene synthases are responsible for the biosynthesis of many chemicals used by plants and microorganisms for defense and communication. This research identifies the first insect terpene synthase (TPS) from the insect Lutzomyia. It offers the potential for sustainable production of this compound through biocatalysis.    

Professor Neil Oldham from the University of Nottingham’s School of Chemistry led the study, he said: “Finding this enzyme has been very difficult and we have been hunting for it for over 2 years., The Lutzomyia genome contains an unusually high number of candidate terpene synthase genes, but thanks to the persistence of Dr Charlie Ducker, a talented researcher on the team, we were able to find the one that makes the pheromone.”

“The beauty of the pheromone approach is that it is very specific for this insect and so the next stage of the project will be to engineer microorganisms to make the enzyme in a way that would produce the pheromone. If we can then find a way to scale this up for commercial use this would be a way to control the populations of these insects and hopefully reduce the spread of Leishmaniasis.”

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JOURNAL

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2322453121 

METHOD OF RESEARCH

Experimental study

ARTICLE TITLE

A novel diterpene synthase from the sandfly Lutzomyia longipalpis produces the pheromone sobralene

ARTICLE PUBLICATION DATE

11-Mar-2024

 

Cicadas’ unique urination unlocks new understanding of fluid dynamics

While most small insects and mammals urinate in droplets, cicadas urinate in jets. Georgia Tech researchers say the finding could be used to create better robots and small nozzles

GEORGIA INSTITUTE OF TECHNOLOGY

 

VIDEO: 

SUMMARY OF FINDINGS

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CREDIT: GEORGIA TECH (SAAD BHAMLA/ELIO CHALLITA)

Cicadas are the soundtrack of summer, but their pee is more special than their music. Rather than sprinkling droplets, they emit jets of urine from their small frames. For years, Georgia Tech researchers have wanted to understand the cicada’s unique urination.

Saad Bhamla, an assistant professor in the School of Chemical and Biochemical Engineering, and his research group hoped for an opportunity to study a cicada’s fluid excretion. However, while cicadas are easily heard, they hide in trees, making them hard to observe. As such, seeing a cicada pee is an event. Bhamla’s team had only watched the process on YouTube.

Then, while doing field work in Peru, the team got lucky: They saw numerous cicadas in a tree, peeing.

This moment of observation was enough to disprove two main insect pee paradigms. First, cicadas eat xylem sap, and most xylem feeders only pee in droplets because it uses less energy to excrete the sap. Cicadas, however, are such voracious eaters that individually flicking away each drop of pee would be too taxing and would not extract enough nutrients from the sap.

“The assumption was that if an insect transitions from droplet formation into a jet, it will require more energy because the insect would have to inject more speed,” said Elio Challita, a former Ph.D. student in Bhamla’s lab and current postdoctoral researcher at Harvard University.

Second, smaller animals are expected to pee in droplets because their orifice is too tiny to emit anything thicker. Because of cicadas’ larger size — with wingspans that can rival a small hummingbird’s — they use less energy to expel pee in jets.

“Previously, it was understood that if a small animal wants to eject jets of water, then this becomes a bit challenging, because the animal expends more energy to force the fluid’s exit at a higher speed. This is due to surface tension and viscous forces. But a larger animal can rely on gravity and inertial forces to pee,” Challita said.

The cicadas’ ability to jet water offered the researchers a new understanding of how fluid dynamics impacts these tiny insects —and even large mammals. The researchers published this challenge to the paradigm as a brief, “Unifying Fluidic Excretion Across Life from Cicadas to Elephants,” in Proceedings of the National Academy of Sciences the week of March 11.

For years, the research group has been studying fluid ejection across species, culminating in a recent arXiv preprint that characterizes this phenomenon from microscopic fungi to colossal whales. Their framework reveals diverse functions — such as excretion, venom spraying, prey hunting, spore dispersal, and plant guttation — highlighting potential applications in soft robotics, additive manufacturing, and drug delivery.

Cicadas are the smallest animal to create high-speed jets, so they can potentially inform applications in making jets in tiny robots/nozzles. And because their population reaches trillions, the ecosystem impact of their fluid ejection is substantial but unknown. Beyond bio-inspired engineering, Bhamla believes the critters could also inform bio-monitoring applications. 

 Cicada peeing [VIDEO] |

"Our research has mapped the excretory patterns of animals, spanning eight orders of scale from tiny cicadas to massive elephants,” he said. “We've identified the fundamental constraints and forces that dictate these processes, offering a new lens through which to understand the principles of excretion, a critical function of all living systems. This work not only deepens our comprehension of biological functions but also paves the way for unifying the underlying principles that govern life’s essential processes."

Citation: Elio J. Challita & M. Saad Bhamla. “Unifying Fluidic Excretion Across Life from Cicadas to Elephants,” Proceedings of National Academy of Sciences, March 2024.

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JOURNAL

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2317878121 

METHOD OF RESEARCH

Observational study

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Unifying Fluidic Excretion Across Life from Cicadas to Elephants

ARTICLE PUBLICATION DATE

11-Mar-2024

 

Natural history specimens have never been so accessible

UTA part of project to make 3D images of 13,000 vertebrates available free online

Peer-Reviewed Publication

UNIVERSITY OF TEXAS AT ARLINGTON

 

IMAGE: 

GREGORY PANDELIS, COLLECTIONS MANAGER OF UT ARLINGTON’S Amphibian and Reptile Diversity Research Center

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CREDIT: PHOTO COURTESY UT ARLINGTON

With the help of 16 grants from the National Science Foundation, researchers have painstakingly taken computed topography (CT) scans of more than 13,000 individual specimens to create 3D images of more than half of all the world's animal groups, including mammals, fishes, amphibians and reptiles.

The research team, made of members from The University of Texas at Arlington and 25 other institutions, are now a quarter of the way through inputting nearly 30,000 media files to the open-source repository MorphoSource. This will allow researchers and scholars to share findings and improve access to material critical for scientific discovery.

“Thanks to this exciting openVertebrate project, also called oVert, anyone—scientists, researchers, students, teachers, artists—can now look online to research the anatomy of just about any animal imaginable without leaving home,” said Gregory Pandelis, collections manager of UT Arlington’s Amphibian and Reptile Diversity Research Center. “This will help reduce wear and tear on many rare specimens while increasing access to them at the same time.”

A summary of the project has just been published in the peer-reviewed journal BioScience reviewing the specimens that have been scanned to date and offering a glimpse of how the data might be used in the future.

For example, one research team has used the data to conclude that Spinosaurus, a massive dinosaur that was larger than Tyrannosaurus rex and thought to be aquatic, would have actually been a poor swimmer, and thus likely stayed on land. Another study revealed that frogs have evolved to gain and lose the ability to grow teeth more than any other animal.

The value of oVert extends beyond scientific inquiry. Artists are using the 3D models to create realistic animal replicas. Photographs of oVert specimens have been displayed as part of museum exhibits. In addition, specimens have been incorporated into virtual reality headsets that allow users to interact with the animals.

Educators also are able to use oVert models in their classrooms. From the outset of the project, the research team placed a strong emphasis on K-12 outreach, organizing workshops where teachers could learn how to use the data in their classrooms.

“As a kid who loved all things science- and nature-related and had a particular interest in skeletal anatomy, I would go through great pains to collect, preserve and study skulls and other specimens for my childhood natural history collection, the start of my scientific inspiration,” Pandelis said. “Realizing that you could study these things digitally with just a few clicks on a computer was eye-opening for me, and it opened up the path to my current research using CT scans of snake specimens to study their skull evolution. Now, this wealth of data has been opened and made publicly accessible to anyone who has a professional, recreational or educational interest in anatomy and morphology. Natural history specimens have never been so accessible and impactful.”

In the next phase of the research project, the team will be creating sophisticated tools to analyze the data collected. Since researchers have never had digital access to so many 3D natural history specimens before, it will take further developments in machine learning and supercomputing to use them to their full potential.

For a video snapshot of the project, watch this two-minute video.

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JOURNAL

BioScience

DOI

10.1093/biosci/biad120 

METHOD OF RESEARCH

Imaging analysis

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Increasing the impact of vertebrate scientific collections through 3D imaging: The openVertebrate (oVert) Thematic Collections Network

ARTICLE PUBLICATION DATE

6-Mar-2024

COI STATEMENT

We thank NSF—and, specifically, Reed Beaman—for believing in the mission of the oVert project. This work would not have been possible without the substantial funding from awards made across participating institutions (NSF grants no. DBI-1700908, no. 1701402, no. 1701516, no. 1701665, no. 1701713, no. 1701714, no. 1701737, no. 1701769, no. 1701797, no. 1701870, no. 1701932, no. 1701943, no. 1702143, no. 1702263, no. 1702421, no. 1702442, no. 1802491, no. 1902105, no. 1902242, no. 2001435, no. 2001443, no. 2001474, no. 2001652, no. 2101909, and no. RCN-2226185). The iDigBio project (NSF grant no. 1547229) supported a workshop in February 2020 hosted at Duke University titled “Integrating Institutional Archives with Disciplinary Web Repositories” that catalyzed changes in user agreements at institutions, especially through feedback from Kyle K. Courtney (Harvard University). Last, we thank all of the many users of oVert-generated data for sharing information about their work via MorphoSource, their publications, and personal communication. Without that information, demonstrating the impact of digital 3D objects would be remarkably difficult. The entire oVert Project Team would greatly appreciate users citing this article when publishing using data generated by our project.