Tag Archives: bites

New Research Reveals Larger Dinosaurs Don’t Have Stronger Bites Than Expected

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It’s not that the enormous, carnivorous dinosaurs weren’t the terrifying, bone-crushing predators we envision.

A new study published in the journal Current Biology reveals that a variety of bipedal carnivorous dinosaurs, including Tyrannosaurus Rex, Spinosaurus, and Allosaurus, have evolved to possess the necessary skull strength for powerful bites.

Utilizing 3D scanning and computer modeling, the researchers examined the skull biomechanics of 18 species of theropods.

The findings indicated that while T. Rex and other giants had skulls designed to deliver immense bite forces capable of breaking bones, they actually possessed relatively weak jaws and employed diverse hunting strategies.

“The skull of a T. Rex was specifically optimized for high bite force, which led to significant skull stress,” stated the lead author, Dr. Andrew Lowe from the University of Bristol, UK. “In contrast, stress patterns in other giants like Giganotosaurus suggested they had relatively mild bites. This implies a variety of evolutionary pathways for these carnivorous giants.”

Giganotosaurus is larger than T. rex, reaching 13m (43 feet) long and weighing almost 14 tons – Credit: Getty

Instead of adhering to a singular evolutionary path to apex status, large carnivorous dinosaurs evolved various skull shapes and feeding strategies. Some, like T. Rex, would bite down akin to a crocodile, while others, such as Allosaurus and Spinosaurus, employed thrashing or ripping techniques reminiscent of modern Komodo dragons and big cats.

“The Tyrannosaurus took a different approach,” remarked Steve Brusatte, a professor and paleontologist at the University of Edinburgh who was not part of the study, as reported by BBC Science Focus. “They developed immense bite strength, allowing them to crush the bones of their prey. This created a perilous lifestyle, subjecting the skull’s bones and muscles to significant stress.”

The results also challenge the belief that larger dinosaurs necessarily had stronger bites. Some smaller species may actually exert more stress on their skulls due to increased muscle mass, indicating that size alone isn’t the key factor in bite power.

The variability in bite strength and skull architecture hints at a more specialized ecological landscape in dinosaur ecosystems, offering multiple strategies for dominance in the prehistoric food chain.

“There wasn’t a singular ‘best’ skull design for being a predatory giant. Various designs proved effective,” noted Lowe. “This biomechanical diversity implies that dinosaur ecosystems supported a more extensive range of giant carnivorous ecological niches than we typically consider, with less competition and greater specialization.”

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About our experts

Steve Brusatte is a professor and paleontologist at the University of Edinburgh, and author of the book Mammal Ascending and Governing (20 pounds, Picador), focusing on 325 million years of mammalian evolution and fossils.

Source: www.sciencefocus.com

Studies Suggest Giant Megalosauroids and Allosauroids Had Weak Bites

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Similar to the tyrannosaurus dinosaur Tyrannosaurus Rex, a study conducted by paleontologists at the University of Bristol revealed that other massive carnivorous dinosaurs, while having skulls designed for formidable bite forces, exhibited much weaker bites and specialized instead in physical reduction and clefts.

Tyrannosaurus Rex Holotype specimens from the Carnegie Museum of Natural History in Pittsburgh, USA. Image credit: Scott Robert Anselmo/CC BY-SA 3.0.

Dr. Andrew Lowe, a paleontologist at the University of Bristol, noted:

“Tyrannosaurs developed skulls that were robust and capable of grinding, while other species exhibited relatively weaker but more specialized skull structures, indicating diverse feeding strategies despite their large size.”

“In essence, there wasn’t a singular ‘best’ skull design for being a predatory giant; a variety of designs functioned effectively.”

Dr. Lowe and his colleague, Dr. Emily Rayfield, sought to understand how bipedalism affected skull biomechanics and feeding methods.

Historically, it was known that predatory dinosaurs evolved in distinct regions of the world at varying times, showcasing a range of skull shapes, even as they reached similar sizes.

These observations prompted questions about whether the skulls were functionally similar underneath or if significant differences existed in predatory behaviors.

To explore the connection between body size and skull biomechanics, the researchers employed 3D techniques, including CT scans and surface scans, to analyze skull mechanics, assess feeding performance, and measure bite strength across 18 species of theropods, a category of carnivorous dinosaurs ranging from small to gigantic.

While they anticipated some variations among species, the analysis astounded them as it revealed distinct biomechanical differences.

“For instance, the Tyrannosaurus Rex skull, designed for high bite force, ultimately compromised on stress resistance,” Dr. Lowe explained.

“Conversely, other large species like Giganotosaurus exhibited a calculated stress pattern, indicating a relatively gentle bite.”

“This insight led us to consider how multiple evolutionary paths could exist for life as a massive, carnivorous organism.”

Surprisingly, skull stress did not exhibit a consistent increase with size; some smaller species experienced higher stress levels than certain larger counterparts due to greater muscle mass and bite force.

The findings demonstrate that being a predatory giant does not always equate to having a bone-crushing bite.

In contrast to the Tyrannosaurus Rex, other dinosaurs, such as Spinosaurus and Allosaurus, evolved into giants while maintaining weaker bites better suited for slashing and shredding flesh.

“I often liken Allosaurus to modern Komodo Dragons in terms of feeding behavior,” Dr. Lowe commented.

“On the other hand, the larger tyrannosaurs had skulls optimized for high bite force, akin to modern crocodiles that crush their prey.”

“This biomechanical variability suggests that dinosaur ecosystems could have supported a broader spectrum of ecology among giant carnivores than previously thought, indicating reduced competition and increased specialization.”

This study will be featured in the journal Current Biology this week.

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Andre J. Lowe & Emily J. Rayfield. 2025. The carnivorous dinosaur lineage employs a variety of skull performances in huge sizes.Current Biology 35 (15): 3664-3673; doi: 10.1016/j.cub.2025.06.051

Source: www.sci.news

Universal Antivenom Could Emerge from a Volunteer Who Endures 200 Snake Bites

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The video lasts under 2.5 minutes. A slender man with thick hair enters the room, pulling a long black mamba that can deliver a lethal bite within an hour. He bites his left arm and moments later, extends his right arm towards a Taipan from Papua New Guinea. “Thank you for watching,” he states, as he calms down to speak to the camera while his left arm bleeds before it is bandaged.

For nearly 18 years, 57-year-old Tim Friede has injected himself with over 650 precisely measured doses of venom from 16 deadly snake species to develop immunity. He has also allowed snakes—mostly one at a time, although occasionally two, as in the video—to bite him nearly 200 times.

This coincidence, also known as one of its names, could aid in addressing global health issues. With over 600 species of venomous snakes across the globe, they bite approximately 2.7 million people annually, causing around 120,000 fatalities and affecting 400,000 others.

Researchers report that in Friede’s blood, they have discovered antibodies capable of neutralizing toxins from multiple snake species. According to Journal Cell.

“I am genuinely proud to contribute something meaningful for humanity and make a difference for people 8,000 miles away.

Deforestation, urban expansion, and climate change have heightened the risk of snake bites in recent years, yet antivenom research has not kept pace with demand.

“This is a more significant issue than the first world might realize,” stated Jacob Glanville, founder and CEO of Centivax, which aims to create broad-spectrum vaccines and serves as the lead author of the study.

Dr. Glanville and his team discovered that two potent antibodies from Friede’s blood, when paired with drugs that inhibit neurotoxins, can protect mice from the venom of 19 deadly snake species from various families around the world.

Experts not involved in the research consider this an extraordinary achievement. Most antivenoms can only counteract venom from one or a few closely related snake species within a particular area.

Nicholas Casewell, a researcher at the Liverpool School of Tropical Medicine in the UK, indicates that antivenom cocktails could potentially prevent fatalities and injuries from all snake families.

“The principles from this study can be effectively applied to other snakes,” he remarked.

Friede’s journey with snakes began with a harmless bite from a five-year-old garter snake, which sparked his lifelong fascination. “If I had known what lay ahead, I would have laughed at the thought,” he reminisces with a chuckle.

However, it wasn’t until he married and started a family while working in construction that he seriously began to explore his interest in snakes. He started experimenting with scorpions around 2000 but soon transitioned to snakes. At one point, he kept 60 venomous snakes in his basement lab.

His experiments came to a sudden halt on September 12, 2001, when he was bitten by two cobras, his emotions heightened by the previous day’s terrorist attack and the recent loss of a friend. Those were his first encounters with snakes without adequate immunity built up. While he initially felt fine after the first bite, the second caused him to feel cold, his eyelids to droop, and he lost his ability to speak. He awoke four days later in a hospital after slipping into a coma.

His wife was furious, while he felt frustrated with himself. He resolved to adopt a more methodical approach, carefully measuring venom doses and timing the bites.

“I work during the day, spend time with my kids and family at home, then head downstairs to work late into the night, only to repeat it all over again the next day,” he explained.

He faced numerous accidents, including unintentional bites, anaphylactic shocks, and power outages. Friede describes himself as a self-taught scientist, asserting, “No university in the world provides training for this. I’ve done as much as I could.”

Two scientific teams studied Friede’s blood over the years, but those efforts led to little progress. By the time he met Dr. Glanville in 2017, he was ready to give up.

Dr. Glanville was investigating what scientists refer to as broadly neutralizing antibodies as a foundation for universal vaccines, inspired by his upbringing in Mayan villages in the Guatemalan Highlands. He was intrigued by the potential to apply the same strategy to develop a Universal Antivenom.

Initially, he said his “humble” goal was to find someone like a hapless snake researcher who had experienced multiple bites. His quest took a turn when he stumbled upon an article about Friede.

“I had been eagerly awaiting this opportunity,” shared Dr. Glanville, expressing gratitude towards Friede.

In partnership with Columbia University vaccine researcher Peter Kwon, Dr. Glanville isolated broadly acting antibodies from Friede’s blood and devised a combination treatment.

Tests on antibodies from Friede’s blood against the venom of 19 snake species showed that one broadly neutralizing antibody protected mice from six species. When combined with a small molecule known as Varespladib, the second antibody provided full protection against 13 snake species and partial defense against the remaining six.

Cobras and mambas produce toxins that paralyze nerve cells, while the venom from Viper family snakes damages tissue and induces bleeding in victims. Each snake species within its family produces a unique combination of dozens of toxins, which can vary by region, age, diet, and season. It can vary significantly.

Despite advances, antivenoms are still produced using methods from 130 years ago. A small amount of venom is injected into horses, camels, or sheep, and the antibodies produced in response are harvested. These antibodies are typically specific to the type of venom administered and offer minimal relief from other snake venom types.

In fact, many antivenoms can cause more severe reactions than the venom itself, as mammalian proteins can provoke fatal allergic reactions.

Researchers are seeking treatments that mitigate these side effects. Cocktail treatments involving small-molecule drugs and monoclonal antibodies targeting critical toxic families are being developed—crafted copies of human antibodies that neutralize toxins across numerous species, according to Dr. Casewell.

Future plans include testing the Australian treatment on dogs brought into veterinary clinics for snake bites. Researchers also aim to identify additional components from Friede’s blood that could expand protection across all 19 snake species under study.

However, Friede’s experimental days are over. His last bite came from a water cobra in November 2018. He has since divorced; his wife and children have moved away. “That felt like enough,” he recalled.

While he misses the thrill of interacting with snakes, he insists it was not driven by painful bites. “I might revisit this in the future,” he reflected, “but for now, I’m content with where I am.”

Source: www.nytimes.com

Bone with crocodile bites dating back 76 million years discovered in Canada

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Understanding food chains in ancient ecosystems is one of the goals of paleoecology. Direct evidence of these interactions is rare and includes fossils with stomach contents and bite/teeth marks. A rare occurrence of bite marks on the neck vertebrae of a giant azhdarchyd goat larval vertebral column specimen from the Greater Sublineage of Alberta, Canada. was recorded. Approximately 76 million years ago. Based on the size and shape of the tooth marks and comparisons with modern animals, the authors suggest that crocodiles bite pterosaurs, but it is unclear whether this is active predation or scavenging. I couldn’t do it. Signs of giant pterosaurs are rare, so this provides novel details about how they fit into this ancient ecosystem.

Fossilized neck bones of a young boy Cryodrakon Boreas It shows signs (right part of specimens 2 and 8) that do not indicate that it was bitten by a crocodile-like creature 76 million years ago. Image credit: Brown et al. , doi:10.1017/jpa.2024.12.

The 76-million-year-old neck vertebrae were excavated in July 2023 in the Dinosaur Park Formation in Alberta, Canada.

The preserved (i.e. incomplete) length of the specimen is 5.8 cm. The estimated total length of the vertebrae is 9.4 cm.

The specimen has a circular puncture mark 4 mm wide from a crocodile tooth.

“Peterosaurus bones are very delicate, so it's very unusual to find fossils that were clearly chewed by another animal,” said Dr Caleb Brown, a palaeontologist at the Royal Tyrrell Museum of Paleontology. states.

“This specimen is even rarer because it is a juvenile.”

The punctured vertebrae belong to a larva (estimated wingspan 2 m) Cryodrakon Boreasa species of giant azhdarchid pterosaur that lived during the Late Cretaceous in what is now Canada.

Adults of this species will be as tall as a giraffe with a wingspan in an area of 10 m.

“With an estimated wingspan comparable to some of the largest azhdarchids, creedracon And other large azhdarchids were probably significant terrestrial foragers,” said the paleontologist.

“Bite marks, implanted teeth, and stomach contents indicate that the azhdarchid pterosaurs were fed by velociraptrines and crocodiles.”

Cryodrakon Boreas. Image credit: David Maas.

In this study, they used micro-CT scans and comparisons with other pterygoid bones to confirm that they were the result of an actual crocodile bite, rather than fossilization or damage during excavation. I did.

“It helps document species interactions from this time,” said Dr. Brian Pickles, a paleontologist at Reading College.

“While we can't say whether the palace was alive or dead when it was bitten, the specimen is a juvenile that crocodiles sometimes preyed on in prehistoric Alberta more than 700 million years ago, or removed.” It shows that it shows a pterosaur.”

study Published online today Journal of Paleontology.

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Caleb M. Brown et al. Larval vertebral vertebrae with putative crocodile bites from a Campanian in Alberta, Canada. Journal of Paleontologypublished online on January 23, 2025. doi:10.1017/jpa.2024.12

Source: www.sci.news

Heparin found to be effective antidote for cobra bites, say scientists

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Snake bites affect approximately 1.8 million people annually. The current standard of care is antibody-based antivenom, but it can be difficult to obtain and is generally ineffective against local tissue damage. New research suggests that heparin, a commonly used blood-clotting inhibitor, could be repurposed as an inexpensive antidote for cobra venom.

Zebra snake (Naja Nigrichinta) in Namibia. Image credit: Wolfgang Wüster.

“Our findings have the potential to significantly reduce the horrific necrotic injury caused by cobra bites, and may also slow the release of venom and improve survival rates,” Professor Greg Neely, from the University of Sydney, said.

The authors identified a way to block cobra venom using CRISPR gene editing technology and showed that heparin and related drugs could be repurposed to prevent necrosis caused by cobra bites.

“Heparin is cheap, ubiquitous and listed as an essential medicine by the World Health Organisation,” says Tian Du, a PhD student at the University of Sydney.

“If the human trials are successful, it could be used relatively quickly as a cheap, safe and effective drug to treat cobra bites.”

Using CRISPR, researchers have discovered the human gene required for cobra venom to kill flesh at the bite site.

One of the desired venom targets is an enzyme needed to make heparan and heparin, related molecules produced by many human and animal cells.

Heparan is present on cell surfaces and heparin is released during immune responses, and because of their similar structure, toxins can bind to either.

Scientists have used this knowledge to create an antidote that can stop necrosis in human cells and mice.

Unlike current cobra bite antivenoms, which are 19th century technology, heparinoids act as a “decoy” antidote.

The antidote works by injecting large amounts of “decoy” heparin sulfate or related heparinoid molecules into the bite site, which are able to bind to and neutralize the toxins in the venom that cause tissue damage.

“Our findings are intriguing because current antivenoms are largely ineffective at treating severe, localised poisoning which causes painful, progressive swelling, blistering and tissue necrosis around the bite,” said Professor Nicholas Casewell, from the Liverpool School of Tropical Medicine.

of study Published in the journal Science Translational Medicine.

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Tian Y. Du others2024. Molecular dissection of cobra venom highlights heparinoids as potential antidotes to spitting cobra venom. Science Translational Medicine 16 (756); doi: 10.1126/scitranslmed.adk4802

Source: www.sci.news