‘Virtual ward’ bed uses 4 times less carbon than traditional inpatient bed

These wards have the potential to reduce need to build more high-carbon impact hospitals

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A virtual ward bed uses 4 times less carbon than a traditional inpatient bed, so helping the NHS achieve its net zero target by 2045, finds the first study of its kind, published in the open access journal BMJ Innovations.

And they are a promising way to care for more patients effectively, with the potential to reduce the need to build more high-carbon impact hospitals, suggest the researchers.

A virtual ward, also known as "hospital at home," provides hospital-level care to patients in the comfort of their own homes, leveraging digital technology and remote monitoring. 

In recent years, particularly in the wake of the COVID-19 pandemic, virtual wards have been widely adopted throughout England to ease pressures on hospital bed capacity and streamline patient flow, say the researchers.

But while existing research has primarily focused on the care outcomes and cost effectiveness of virtual wards, few studies have looked at their environmental impact and carbon footprint.

To plug this knowledge gap, the researchers compared the carbon cost of virtual ward care with that of traditional inpatient care between May 2022 and May 2023 in a large acute hospital trust. 

They quantified the avoided carbon emissions for 1260 virtual ward patients, 728 of whom were frail and 532 of whom had an acute respiratory infection.

The researchers used the Greener Care at Home toolkit to calculate the carbon emissions of a care pathway, including carbon activity points, such as accident and emergency (A&E) attendance, travel to hospital in an ambulance/car, and diagnostics. 

All inpatient bed days, virtual ward bed days, home energy and community/general practice (GP) call-outs were calculated initially for a random sample of 30 patients, using a manual audit and then for the entire group of 1260 patients, using an internal data collection system. 

The researchers used a previously created method to calculate ‘predicted stay’ in hospital for the virtual ward and traditional inpatient care pathways.

 

The results show that there was a significant difference between the carbon costs of a virtual ward and an inpatient stay, with virtual wards emitting significantly less carbon when evaluated across the entire episode of care.

On average, an inpatient bed emits 4 times more carbon  at 37.9 kg CO2 than a virtual ward bed day at 8.8 kg CO2. And avoided carbon emissions added up to 285 tonnes of CO2 between May 2022 and May 2023.

This doesn’t represent a carbon reduction for the hospital, emphasise the researchers, as hospital beds were still in use by other patients, but it does represent increased capacity. 

And the reduced carbon footprint of virtual wards is particularly important as the NHS aims to deliver 40–50 virtual ward beds per 100,000 of the population, say the researchers. 

“Having a [virtual ward] in place will not decrease overall carbon emissions for the hospital but enable more patients to be cared for in the most efficient and lowest carbon way possible, enabling the hospital's capacity to increase and for teams to manage more patients with the same number of inpatient beds,” they write.

Carbon costs were higher, using the manual audit, largely due to the addition of external factors that internal hospital data systems don’t capture, note the researchers.

The researchers acknowledge that they didn’t have any data on carbon emissions from typical home use, and relied instead on government calculations, which estimate average home carbon emissions of 7.4 kg CO2/day. Nor do patients always fit into a neat box of a mapped pathway, which highlights the complexity of carbon mapping care pathways, they point out.

Nevertheless, they conclude: “[Virtual wards] look like a promising way for hospitals to increase capacity in a model of sustainable healthcare that aligns with the triple bottom line analysis of high-quality care, value for money, and low associated carbon emissions.”

They add: “We know that a traditional inpatient bed is a very high carbon/resource intensive method of treating patients. As our population increases, we will need to create more effective, less resource-intensive ways to treat our local population, without having to build more hospitals as this is extremely high cost, high carbon, and will require additional workforce.” 

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Journal

BMJ Innovations

DOI

10.1136/bmjinnov-2024-001347 

Method of Research

Observational study

Subject of Research

People

Article Title

Exploring the carbon impact of virtual wards in a large acute hospital

Article Publication Date

17-Jun-2025

 

Father-daughter bonding helps female baboons live longer

University of Notre Dame

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An adult male and infant baboon in the Amboseli ecosystem, Kenya.

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Credit: (Photo by Elizabeth Archie, professor at Notre Dame)

Besides humans, very few mammals receive care from their fathers. But when species do, it may benefit their children.

New research from the University of Notre Dame found that the strength of early-life father-daughter relationships predicts meaningful differences in the survival of female baboons.

Published in Proceedings of the Royal Society B, the study evaluated the impact father baboons may have when they choose to co-reside or interact with their daughters, even though baboon mothers provide all essential care. Until now, the consequences of early-life paternal relationships of offspring were mostly unknown.

“Male baboons tend to reach their peak reproductive success when they’re young adults,” said Elizabeth Archie, professor of biological sciences at Notre Dame and corresponding author of the study. “But once they’ve had a few kids and their condition declines, they sort of slide into ‘dad mode,’ where they don’t disperse as much and they don’t try as hard to mate. Then they have time to invest in and hang out with their kids.”

Looking at 216 female baboons and their fathers in the Amboseli ecosystem of East Africa, the researchers found about a third of the daughters lived in the same social group as their fathers for three years or more. The remaining two-thirds had fathers who either left the group or died within their daughter’s first three years of life.

Researchers also evaluated the grooming habits of juvenile females with their fathers and other adult males, which speaks to the potential strength of father-daughter and other relationships. Archie shared that grooming, which is used for hygiene and social bonding, could be considered the “human equivalent of sitting down, having a cup of coffee and a good chat.”

The study showed daughters who had a strong relationship with their fathers, who co-resided with their fathers for three years or more, or both, lived two to four years longer than females who had weak father-daughter relationships.

“Early life adversity has a powerful effect on lifespan, so this study suggests that having a dad allows females that have experienced other forms of adversity to recover some of those costs,” Archie said. “In a lot of mammals, dads have a reputation of not contributing very much to offering care, but we now know that even these seemingly minor contributions that males are making still have really important consequences, at least in baboons.”

Additionally, father-daughter pairs that lived together for longer had stronger grooming relationships. Meanwhile, strong relationships between juvenile females and other adult males did not predict adult survival. This could be because male baboons sometimes intervene on behalf of offspring in conflicts, protecting their daughters, and even the mothers, from other group members.

“Males seem to sort of expand a child’s social network, as they can be popular members of their social group. Lots of baboons are coming up and interacting with the male. So an infant who’s hanging out near a male has more diverse social interactions than if they’re only hanging out with mom,” Archie said. “And dads can create a sort of safety zone for their daughters.”

Although mammal fathers may not provide much, if at all, to their offspring, Archie believes this study may hold insight into the evolutionary roots of human parental care.

This study is part of the Amboseli Baboon Research Project, which began in 1971 and is among the longest-running primate studies in the world. Funded by the National Science Foundation (NSF) and the National Institutes of Health (NIH), the project is co-directed by Archie at Notre Dame, Susan Alberts from Duke University and Jenny Tung at the Max Planck Institute for Evolutionary Anthropology.

“We’re very grateful to the NSF and NIH for funding over the years that has allowed us to sustain this project. We could not have done over 50 years of this project without their support,” Archie said.

In addition to Archie, Alberts and Tung, study co-authors include David Jansen at the University of Wisconsin-Madison and J. Kinyua Warutere at the Amboseli National Park in Kenya. Archie is affiliated with Notre Dame’s Eck Institute for Global Health and Environmental Change Initiative.

Contact: Brandi Wampler, associate director of media relations, 574-631-2632, brandiwampler@nd.edu

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Subject of Research

Animals

Article Title

Early-life paternal relationships predict female survival in wild baboons

Article Publication Date

17-Jun-2025

 

New species of armored, monstersaur lizard that lived alongside dinosaurs identified by NHM paleontologists

Discovery of Bolg amondol, a name inspired by J.R.R. Tolkien’s Lord of the Rings universe, reveals, reveals the complex evolutionary history of giant Gila monster relatives that roamed Utah’s prehistoric tropical forests.

Natural History Museum of Los Angeles County

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image: 

Artistic reconstruction of Bolg amondol, depicted raiding an oviraptorosaur dinosaur nest amidst the lush Kaiparowits Formation habitat. 

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Credit: Art by Cullen Townsend.

A newly discovered raccoon-sized armored monstersaurian lizard from Grand Staircase-Escalante National Monument in southern Utah reveals a surprising diversity of these very big lizards at the pinnacle of the Age of Dinosaurs. Named for the goblin prince from J.R.R. Tolkien’s The Hobbit, the new species Bolg amondol also illuminates the sometimes murky path that life traveled between ancient continents. Published in the open-access journal Royal Society Open Science, the collaborative research led by the Natural History Museum of Los Angeles County’s Dinosaur Institute reveals hidden treasures awaiting future paleontologists in the bowels of museum fossil collections, and the vast potential of paleontological heritage preserved in Grand Staircase-Escalante National Monument and other public lands. 

“I opened this jar of bones labeled ‘lizard’ at the Natural History Museum of Utah, and was like, oh wow, there's a fragmentary skeleton here,” says lead author Dr. Hank Woolley from the Dinosaur Institute. “We know very little about large-bodied lizards from the Kaiparowits Formation in Grand Staircase-Escalante National Monument in Utah, so I knew this was significant right away.”

A Moniker from Middle-earth
Bolg represents an evolutionary lineage that sprouted within a group of large-bodied lizards called monstersaurs, the most familiar example being the Gila monsters, which still roam the deserts where Bolg was recovered from. Woolley knew that a new species of monstersaur called for an appropriate name from an iconic monster creator: J.R.R. Tolkien. “Bolg is a great sounding name. It's a goblin prince from The Hobbit, and I think of these lizards as goblin-like, especially looking at their skulls,” says Woolley.  He used the fictional language Sindarin—created by Tolkien for his elves—to craft the species epithet.  “Amon” means “mound”, and “dol” means “head” in the Elvish language, a reference to the mound-like osteoderms found on Bolg’s and other monstersaur skulls. “Mound-Headed Bolg” would fit right in with the goblins—and it’s revealing quite a bit about monstersaurs.”

Hidden Gems in Collection Drawers 
“Bolg is a great example of the importance of natural history museum collections,” says co-author Dr. Randy Irmis from the University of Utah. “Although we knew the specimen was significant when it was discovered back in 2005, it took a specialist in lizard evolution like Hank to truly recognize its scientific importance, and take on the task of researching and scientifically describing this new species.”

The new species was identified from an associated skeleton of fragmentary bones: tiny pieces of the skull, vertebrae, girdles, limbs, and the bony armor called osteoderms. 

“What's really interesting about this holotype specimen of Bolg is that it's fragmentary, yes, but we have a broad sample of the skeleton preserved,” Woolley says. “There's no overlapping bones—there's not two left hip bones or anything like that. So we can be confident that these remains likely belonged to a single individual.”

Most of the fossil lizards from the Age of Dinosaurs are even more fragmented—often just single isolated bones or teeth—so despite their fragmentary nature, the parts of Bolg’s skeleton that survived contain a stunning amount of information.

“That means more characteristics are available for us to assess and compare to similar-looking lizards. Importantly, we can use those characteristics to understand this animal's evolutionary relationships and test hypotheses about where it fits on the lizard tree of life,” says Woolley.

Other fossils described in the study, including remarkably armored skull bones, demonstrate that the ancient, seasonally tropical forests of what is now southern Utah, USA hosted at least three different types of large, predatory lizards. “Even though these lizards were large, their skeletons are quite rare, with most of their fossil record based on single bones and teeth,” says co-author Dr. Joe Sertich from the Smithsonian Tropical Research Institute and Colorado State University. “The exceptional record of big lizards from Grand Staircase-Escalante National Monument may prove to be a normal part of dinosaur-dominated ecosystems from North America, filling key roles as smaller predators hunting down eggs and small animals in the forests of Laramidia."

Stairway to Monstersaurs
The Monstersauria are characterized by their large size and distinctive features like pitted, polygonal armor attached to their skulls and sharp, spire-like teeth. They have a roughly 100 million-year history, but their fossil record is largely incomplete, making the discovery of Bolg a big deal for understanding these charismatic lizards, and Bolg would have been a bit of a monster to our eyes.

“Three feet tip to tail, maybe even bigger than that, depending on the length of the tail and torso,” says Woolley. “So by modern lizard standards, a very large animal, similar in size to a Savannah monitor lizard; something that you wouldn’t want to mess around with.”

The identification of a new species of monstersaur highlights the likelihood that there were many more kinds of big lizards in the Late Cretaceous. Additionally, this find shows that unexplored diversity is waiting to be dug up in the field and in paleontology collections.

Bolg’s closest known relative hails from the other side of the planet in the Gobi Desert of Asia. While dinosaurs have long been known to have traveled between the once connected continents during the Late Cretaceous Period, the discovery of Bolg reveals that smaller animals also made the trek, suggesting there were common patterns of biogeography across terrestrial vertebrates during this time.

Dr. Woolley began this research as a PhD student at the Dinosaur Institute and has continued it as a National Science Foundation Postdoctoral Fellow in the department, underscoring the value of funding scientific research and the unique role the Dinosaur Institute plays as a source of mentorship for young paleontologists. 

“The Natural History Museum and Dinosaur Institute has been proud to lead the way in empowering early career scientists,” says Dr. Nathan Smith, co-author and Gretchen Augustyn Director & Curator of the Dinosaur Institute. In addition to Dr. Woolley, co-author Dr. Keegan Melstrom (now an Assistant Professor at the University of Central Oklahoma), was also a Postdoctoral Fellow in the Dinosaur Institute. “The result of that investment and continued growth of programs like the Dinosaur Institute Fellowship Fund is groundbreaking paleontological research and new discoveries that highlight the value of museum collections and expand our knowledge of Earth history.”

Field collection of the specimens described in this study was conducted under paleontological permits issued by the Bureau of Land Management. This study was funded by the Bureau of Land Management, National Science Foundation award 2205564, the NHMLAC Dinosaur Institute, and the University of Utah. 

The rocks where Bolg was discovered, the Kaiparowits Formation of Grand Staircase-Escalante National Monument, have emerged as a paleontological hotspot over the past 25 years, producing one of the most astounding dinosaur-dominated records anywhere in North America with dozens of new species and critical insights into the past. Discoveries like this underscore the importance of protecting public lands in the western USA for science and research.
 

LEFT IMAGE: Publicly available rendered CT scan of Heloderma horridum (UF:Herp:153328) from morphosource.org used for comparison to Bolg amondol, with mound-like, polygonal osteoderms in green. RIGHT IMAGE: Skull of the modern monstersaur Heloderma horridum (LACM 159136), from the herpetology collection at NHMLAC, used for comparison with Bolg amondol.

Identified bones belonging to Bolg amondol (Specimen UMNH VP 16266, Natural History Museum of Utah / Bureau of Land Management). They are not much to look at, but they are jam-packed with valuable information on the anatomy and lifestyle of Bolg amondol.

Size comparison of the holotype specimen of Bolg amondol (UMNH VP 16266, left, Natural History Museum of Utah / Bureau of Land Management) and a modern Gila monster (Heloderma suspectum, right). Gold: preserved skeletal elements. Light gray: reconstructed elements based on preserved material. Dark gray: missing skeletal elements, based on publicly available rendered CT scans of Heloderma horridum available on morphosource.org (UF:Herp 153328). 

 

Credit

Dr. Hank Woolley

Journal

Royal Society Open Science

DOI

10.1098/rsos.250435 

Method of Research

Observational study

Subject of Research

Animals

Article Title

New monstersaur specimens from the Kaiparowits Formation of Utah reveal unexpected richness of large-bodied lizards in Late Cretaceous North America

Article Publication Date

17-Jun-2025

1959

New monstersaur species a ‘goblin prince’ among dinosaurs

University of Utah

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A newly discovered, raccoon-sized armored monstersaurian from the Grand Staircase-Escalante National Monument in Southern Utah, United States, reveals a surprising diversity of large lizards at the pinnacle of the age of dinosaurs. Named for the goblin prince from J.R.R. Tolkien’s “The Hobbit,” the new species Bolg amondol also illuminates the sometimes-murky path that life traveled between ancient continents.

“I opened this jar of bones labeled ‘lizard’ at the Natural History Museum of Utah, and was like, oh wow, there's a fragmentary skeleton here,” said lead author Hank Woolley from the Natural History Museum of Los Angeles County’s Dinosaur Institute. “We know very little about large-bodied lizards from the Kaiparowits Formation in Grand Staircase-Escalante National Monument in Utah, so I knew this was significant right away.”

Published on June 17, 2025 in the journal Royal Society Open Science, the collaborative research led by the Dinosaur Institute and the Natural History Museum of Utah (NHMU) reveals hidden treasures awaiting future paleontologists in the bowels of museum fossil collections, and the vast potential of paleontological heritage preserved in Grand Staircase-Escalante National Monument and other public lands.

“Discovering a new species of lizard that is an ancestor of modern Gila monsters is pretty cool in and of itself, but what's particularly exciting is what it tells us about the unique 76-million-year-old ecosystem it lived in,” said co-author Randy Irmis, associate professor at the University of Utah and curator of paleontology at NHMU. “The fact that Bolgco-existed with several other large lizard species indicates that this was a stable and productive ecosystem where these animals were taking advantage of a wide variety of prey and different micro-habitats.”

A Middle Earth-inspired moniker

Bolg represents an evolutionary lineage that sprouted within a group of large-bodied lizards called monstersaurs, that still roam the deserts from which Bolg was recovered. Woolley knew that a new species of monstersaur called for an appropriate name from an iconic monster creator, Tolkien.

“Bolg is a great sounding name. It's a goblin prince from ‘The Hobbit,’ and I think of these lizards as goblin-like, especially looking at their skulls,” said Woolley. He used the fictional Tolkien Elvish language Sindarin to craft the species epithet. “Amon” means “mound,” and “dol” means “head,” a reference to the mound-like osteoderms found on Bolg’s and other monstersaur’s skulls. “Mound-headed Bolg” would fit right in with the goblins—and it’s revealing quite a bit about monstersaurs.

Hidden gems in collection drawers 

The Bolg amondol discovery highlights the likelihood that more large-bodied lizards existed during the Late Cretaceous Period than previously thought. Bolg, along with other fossils from the Kaiparowits Formation, demonstrate at least three types of predatory lizards lived in the Late Cretaceous sub-tropical floodplains of what is now Southern Utah. Additionally, this find shows that unexplored diversity is waiting to be dug up both in the field and in paleontology collections.

“Bolg is a great example of the importance of natural history museum collections,” Irmis said. “Although we knew the specimen was significant when it was discovered back in 2005, it took a specialist in lizard evolution like Hank to truly recognize its scientific importance and take on the task of researching and scientifically describing this new species.”

The researchers identified the new species from tiny pieces of skull, limbs, girdles, vertebrae and bony armor called osteoderms. Most fossil lizards from the age of dinosaurs are even scrappier—often just single, isolated bones or teeth—so despite their fragmentary nature, the parts of Bolg’s skeleton that survived contain a stunning amount of information.

“That means more characteristics are available for us to assess and compare to similar-looking lizards. Importantly, we can use those characteristics to understand this animal's evolutionary relationships and test hypotheses about where it fits on the lizard tree of life,” Woolley said.

Stairway to monstersaurs

The monstersauria are characterized by their large size and distinctive features, such as sharp, spire-like teeth and pitted, polygonal armor attached to their skulls. They have a roughly 100-million-year history, but their fossil record is largely incomplete, making the discovery a big deal for understanding these charismatic lizards. Bolg would have been a bit of a monster to our eyes.

“Three feet tip to tail, maybe even bigger than that, depending on the length of the tail and torso,” said Woolley. “So, by modern lizard standards they’re a very large animal, similar in size to a Savannah monitor lizard; something that you wouldn’t want to mess around with.”

Bolg’s closest known relative hails from the other side of the planet in the Gobi Desert of Asia. Though dinosaurs have long been known to have traveled between the once-connected continents of the Late Cretaceous Period, Bolg reveals that smaller animals also made the trek, suggesting there were common patterns of biogeography across terrestrial vertebrates during this time.

The rocks where Bolg was discovered—the Kaiparowits Formation of Grand Staircase-Escalante National Monument—have emerged as a paleontological hotspot over the past 25 years, producing one of the most astounding dinosaur-dominated records in North America. Discoveries like this underscore the importance of preserving public lands in the Western U.S. for science and research.

“The exceptional record of big lizards from Grand Staircase-Escalante National Monument may prove to be a normal part of dinosaur-dominated ecosystems from North America, filling key roles as smaller predators hunting down eggs and small animals in the forests of Laramidia,” said co-author Joe Sertich from the Smithsonian Tropical Research Institute and Colorado State University.

****

This story is edited from the original by Tyler Hayden, science communication specialist, Natural History Museum of Los Angeles County.

Other authors include Keegan Melstrom, University of Central Oklahoma and Nathan Smith, Natural History Museum of Los Angeles County, Dinosaur Institute. Field collection of the specimens described in this study was conducted under paleontological permits issued by the Bureau of Land Management (BLM). This study was funded by the BLM, National Science Foundation award 2205564, the Natural History Museum of Los Angeles Dinosaur Institute and the University of Utah.

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Journal

Royal Society Open Science

DOI

10.1098/rsos.250435 

Method of Research

Observational study

Subject of Research

Not applicable

Article Title

New monstersaur specimens from the Kaiparowits Formation of Utah reveal unexpected richness of largebodied lizards in Late Cretaceous North America

Article Publication Date

17-Jun-2025