- You thought Hidetaka Miyazaki lied about the length of Elden Ring, so he won’t tell you how long the DLC is Gamesradar
- Elden Ring will only get one DLC in Shadow of the Erdtree, but FromSoftware isn’t ruling out a full sequel for the RPG Gamesradar
- FromSoftware Has Bad News for Elden Ring Fans GameRant
- One and done: Elden Ring’s first DLC expansion will also be its last Ars Technica
- Elden Ring lead Hidetaka Miyazaki won’t say how long the DLC is since everyone thinks he lowballed the main game: ‘Everyone told me I was lying and that’s not remotely enough time!’ PC Gamer
Tag Archives: Length
PS5 Exclusive Phantom Blade Zero Length Revealed, Will Have Multiplayer & Open World Elements – PlayStation LifeStyle
- PS5 Exclusive Phantom Blade Zero Length Revealed, Will Have Multiplayer & Open World Elements PlayStation LifeStyle
- The incredible-looking Phantom Blade 0 is a semi-open-world “rebirth” of a $7 indie JRPG Gamesradar
- Phantom Blade Zero Game Length Is 30-40 Hours, Multiplayer Confirmed, Combat Scenes Captured In-Engine MP1st
- My highlight of Sony’s PlayStation showcase is, you guessed it, coming to PC PC Gamer
- PlayStation Showcase’s ‘game of the show’ is drawing a lot of attention from the Sekiro fandom Gamesradar
- View Full Coverage on Google News
‘John Wick: Chapter 4’ Review: Keanu Reeves Takes Franchise To New Levels Of Action, And Length – SXSW – Deadline
- ‘John Wick: Chapter 4’ Review: Keanu Reeves Takes Franchise To New Levels Of Action, And Length – SXSW Deadline
- John Wick: Chapter 4 Review IGN
- ‘John Wick: Chapter 4’ Review: Latest Entry in Keanu Reeves Franchise Is Pure, Over-the-Top Action Spectacle Hollywood Reporter
- ‘John Wick: Chapter 4’ Review: Keanu Reeves in a Three-Hour Action Epic That’s Like a Spaghetti Western Meets John Woo as Seen in Times Square Yahoo Entertainment
- John Wick: Chapter 4 review – overlong and overstuffed action sequel The Guardian
- View Full Coverage on Google News
Average pregnancy length in the US is shorter than in European countries
Maternal health outcomes continue to worsen in the United States, where maternal and infant mortality rates far exceed rates in European countries and other wealthy nations. Now, a new study led by researchers at Boston University School of Public Health (BUSPH) and Harvard Medical School-affiliated Beth Israel Deaconess Medical Center (BIDMC) is shedding insight on how hospital organizational structures and staffing within US maternity care may affect the birthing process and possibly contribute to adverse birth outcomes.
Published in the journal PLOS ONE, the study analyzed gestational age patterns and timing of home and hospital births in three high-income countries: the US, which embraces a maternity care model that relies heavily on obstetricians and clinical interventions, and England and the Netherlands, which primarily rely on midwives who provide low-intervention maternity care.
The findings show that the average length of US pregnancies steadily declined by more than half a week between 1990 and 2020, from 39.1 weeks to 38.5 weeks, and that US pregnancies, on average, are shorter than pregnancies in England and the Netherlands. In 2020, only 23 percent of US births occurred at 40 or more weeks, compared with 44 percent of births in the Netherlands and 40 percent of births in England. The gestational age pattern for home births was the same in all three countries.
In all three countries, the researchers also examined birth timing by hour of the day for home and vaginal births at the hospital, and then repeated this analysis, limiting the comparison to hospital-based vaginal births without interventions such as induction or labor augmentation that could possibly alter the timing.
In England and the Netherlands, births at home and at the hospital occurred at similar times in the day, peaking in the early morning hours between 1 a.m.-6 a.m.
But in the US, there was a noticeable difference in birth timing between the two settings: births at home peaked in the same early morning hours as home births in other countries. By contrast, hospital-based births—even those with no interventions that could affect the natural pattern of timing—largely occurred during standard working hours for clinical staff, from 8 a.m. to 5 p.m.
The paper is the first international study using large datasets to compare gestational age and birth timing in three high-income countries; most prior research has focused on data from individual hospitals or countries. Given England’s and the Netherlands’s superior birthing outcomes, the authors say their findings suggest the US maternity care models could benefit from an organizational shift that places less emphasis on active, clinical management of labor and allows the birthing process to take a natural course.
“Our multi-country analysis shows that the US is an outlier in gestational age distribution and timing of low-intervention hospital births,” says study lead and corresponding author Dr. Eugene Declercq, professor of community health sciences at BUSPH. “There’s a lesson to be learned from countries with more positive maternity outcomes than the US in having hospital staffing and operational plans conform more closely to the natural patterns of birth timing and gestational age rather than try to have birth timing fit organizational needs.”
The study included nationally representative and publicly available population-based birth data from all three countries, including data on more than 3.8 million births in the US and 156,000 births in the Netherlands in 2014, and more than 56,000 births in England from 2008-2010. The researchers examined home and hospital birth timing for births that occurred between 37 and 42 weeks.
“Every system is perfectly designed to get the results that it gets,” says study senior author Dr. Neel Shah, chief medical officer of Maven Clinic and a visiting scientist at BIDMC. “The alarmingly poor results of the US maternal health system demand greater attention to its design. Our study shows that in comparison with other high-income countries, American hospitals may be designed to center the convenience of clinicians more than the needs of people giving birth.”
More information:
Eugene Declercq et al, The natural pattern of birth timing and gestational age in the U.S. compared to England, and the Netherlands, PLOS ONE (2023). DOI: 10.1371/journal.pone.0278856
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Scientists crack aging mystery: Gene length is the deciding factor
Scientists believe they’ve cracked the secret of aging.
A major genetic analysis of people, rodents and fish found the length of their DNA was directly linked to their biological age.
Shorter genes were associated with shorter lifespans, while longer genes were linked to better health and longevity.
Scientists believe if they can hijack this mechanism, it could pave the way for a fountain of youth drugs that could slow — or even reverse — aging.
Dr Thomas Stoeger, lead author of the study from Northwestern University in Illinois, said: ‘I find it very elegant that a single, relatively concise principle seems to account for nearly all of the changes in the activity of genes that happen in animals as they age.’
Scientists said having longer genes can lead someone to live longer (stock photo)
The length of a gene is based on the number of nucleotides within it. Each string of nucleotides translates to an amino acid, forming a protein.
Therefore a very long gene yields a large protein, and a short gene yields a small protein. A cell needs to have a balanced number of small and large proteins to achieve homeostasis, and problems occur when that balance gets out of whack.
In the study, researchers looked at genetic data from several large datasets, including the Genotype-Tissue Expression Project, a National Institutes of Health-funded tissue bank that archives samples from human donors for research purposes.
The research team first analyzed tissue samples from mice, rats and killifish of various ages.
In all animals, the researchers noticed subtle changes to thousands of different genes across samples.
This means that not just a small subset of genes that contributes to aging. Aging, instead, is characterized by systems-level changes.
This view differs from prevailing biological approaches that study the effects of single genes.
Since the onset of modern genetics in the early 20th century, many researchers expected to be able to attribute many complex biological phenomena to single genes.
And while some diseases, such as hemophilia, do result from single gene mutations, the narrow approach to studying single genes has yet to lead to explanations for the myriad changes that occur in neurodegenerative diseases and aging.
After completing their animal research, the researchers turned their attention to humans. They looked at changes in human genes from ages 30 to 49, 50 to 69 and then 70 and older.
Measurable changes in gene activity according to gene length already occurred by the time humans reached middle age.
‘There already seems to be something happening early in life, but it becomes more pronounced with age,’ Dr Stoeger said.
‘It seems that, at a young age, our cells are able to counter perturbations that would lead to an imbalance in gene activity. Then, suddenly, our cells can no longer counter it.’
Northwestern’s Luis Amaral, a senior author of the study, said: ‘The result for humans is very strong because we have more samples for humans than for other animals.
‘It was also interesting because all the mice we studied are genetically identical, the same gender and raised in the same laboratory conditions, but the humans are all different.
‘They all died from different causes and at different ages. We analyzed samples from men and women separately and found the same pattern.’
But the scientists found that with aging activity within cells shifts towards shorter genes, upsetting the balance.
This is counterbalanced in people with very long genes, because they have longer proteins available in cells.
Dr Stoeger said: ‘The changes in the activity of genes are very, very small, and these small changes involve thousands of genes.
‘We found this change was consistent across different tissues and in different animals.’
Scientists hope the study — published in Nature Aging — will spur the development of therapies to slow or reverse aging.
Currently, medications target symptoms rather than the causes of getting older which the Northwestern experts said was like using painkillers to reduce a fever.
Dr Amaral said: ‘Fevers can occur for many, many reasons. It could be caused by an infection, which requires antibiotics to cure, or caused by appendicitis, which requires surgery.
‘Here, it is the same thing. The issue is the gene activity imbalance. If you can help correct the imbalance, then you can address the downstream consequences.’
Length of REM Sleep Linked to Body Temperature
According to new research from UCLA, the length of REM sleep is linked to animals’ body temperature, with higher body temperatures associated with lower amounts of REM sleep.
Warm-blooded animal groups with lower body temperatures have more rapid eye movement (REM) sleep, while those with higher body temperatures have lower amounts of REM sleep. This is according to new research from Jerome Siegel, a University of California, Los Angeles (UCLA) professor who said his study suggests that REM sleep acts like a “thermostatically controlled brain heater.”
REM sleep first occurs about 90 minutes after falling asleep. Behind closed eyelids, your eyes dart rapidly from side to side. Mixed frequency brain wave activity becomes closer to that seen in wakefulness. Your breathing becomes faster and irregular, and your heart rate and blood pressure increase to near waking levels. Most of your dreaming occurs during REM sleep, although some can also occur in non-REM sleep. Your arm and leg muscles become temporarily paralyzed, which prevents you from acting out your dreams. As you age, less of your time sleeping is spent in REM sleep.
Siegel says the findings suggest a previously unobserved relationship between body temperature and REM sleep, a period of sleep when the brain is highly active. Published recently in Lancet Neurology, the study was authored by Prof. Siegel, who directs the Center for Sleep Research at the Jane and Terry Semel Institute for Neuroscience and Human Behavior at UCLA.
Birds have the highest body temperature of any warm-blooded, or homeotherm, animal group at 41°C (106°F) while getting the least REM sleep at 0.7 hours per day. That’s followed by humans and other placental mammals (37°C/99°F), 2 hours of REM sleep), marsupials (35°C/95°F, 4.4 hours of REM sleep), and monotremes (31°C/88°F, 7.5 hours of REM sleep).
Brain temperature falls in non-REM sleep and then rises in REM sleep that typically follows. This pattern “allows homeotherm mammals to save energy in non-REM sleep without the brain getting so cold that it is unresponsive to threat,” Siegel said.
The amount of humans’ REM sleep is neither high nor low compared to other homeotherm animals, “undermining some popular views suggesting a role for REM sleep in learning or emotional regulation,” he said.
Reference: “Sleep function: an evolutionary perspective” by Jerome M Siegel, PhD, 1 October 2022,
How Changes in Length of Day Change the Brain and Subsequent Behavior
Summary: Neurons in the suprachiasmatic nucleus coordinate to adapt to different lengths of daylight, changing at cellular and network levels. The neurons changed in mix and expression of dopamine, altering brain activity and subsequently daily routine behaviors.
Source: UCSD
Seasonal changes in light—longer days in summer, shorter in winter—have long been associated with human behaviors, affecting everything from sleep and eating patterns to brain and hormonal activity.
Seasonal affective disorder (SAD) is a prime example: A type of depression related to diminished exposure to natural sunlight, typically occurring during winter months and more often at higher latitudes when daylight hours are shortest.
Bright light therapy has proven an effective remedy for treating SAD, plus maladies such as non-seasonal major depression, postpartum depression and bipolar disorder, but how seasonal changes in day length and light exposure affect and alter the brain at the cellular and circuit levels has kept scientists largely in the dark.
In a new study, published September 2, 2022, in Science Advances, researchers at University of California San Diego School of Medicine used a mouse model to illuminate a process in which affected neurons switch expression of neurotransmitters in response to day length stimuli, triggering related behavioral changes.
The work was led by senior study author Davide Dulcis, Ph.D., associate professor in the Department of Psychiatry at UC San Diego School of Medicine and a member of the Center for Circadian Biology at UC San Diego.
Tucked within the hypothalamus of the human brain is a small structure called the suprachiasmatic nucleus (SCN), each consisting of approximately 20,000 neurons. (The average human brain contains roughly 86 billion neurons and another 85 billion non-neuronal cells.)
The SCN is the body’s timekeeper, regulating most circadian rhythms—physical, mental and behavioral changes that follow a 24-hour cycle and affect everything from metabolism and body temperature to when hormones are released.
The SCN operates based on input from specialized photosensitive cells in retina, which communicate changes in light and day length to our body.
In the new study, Dulcis and colleagues describe how SCN neurons coordinate with each other to adapt to different lengths of daylight, changing at cellular and network levels. Specifically, they found that in mice, whose brains function similarly to humans, the neurons changed in mix and in expression of key neurotransmitters that, in turn, altered brain activity and subsequent daily behaviors.
Seasonal changes in light exposure have also been shown to alter the number of neurotransmitter-expressing neurons in the paraventricular nucleus (PVN), a region of the brain that plays essential roles in controlling stress, metabolism, growth, reproduction, immune and other autonomic functions.
“The most impressive new finding in this study is that we discovered how to artificially manipulate the activity of specific SCN neurons and successfully induce dopamine expression within the hypothalamic PVN network,” said Dulcis.
“We revealed novel molecular adaptations of the SCN-PVN network in response to day length in adjusting hypothalamic function and daily behavior,” added first author Alexandra Porca, Ph.D., a member of Dulcis’ lab.
“The multi-synaptic neurotransmitter switching we showed in this study might provide the anatomical/functional link mediating the seasonal changes in mood and the effects of light therapy.”
The authors suggest their findings provide a novel mechanism explaining how the brain adapts to seasonal changes in light exposure. And because the adaptation occurs within neurons exclusively located in the SCN, the latter represents a promising target for new treatments for disorders associated with seasonal changes in light exposure.
About this neuroscience research news
Author: Scott La Fee
Source: UCSD
Contact: Scott La Fee – UCSD
Image: The image is credited to National Institute of General Medical Sciences
See also
Original Research: Open access.
“Seasonal changes in day length induce multisynaptic neurotransmitter switching to regulate hypothalamic network activity and behavior” by Alessandra Porcu et al. Science Advances
Abstract
Seasonal changes in day length induce multisynaptic neurotransmitter switching to regulate hypothalamic network activity and behavior
Seasonal changes in day length (photoperiod) affect numerous physiological functions. The suprachiasmatic nucleus (SCN)–paraventricular nucleus (PVN) axis plays a key role in processing photoperiod-related information.
Seasonal variations in SCN and PVN neurotransmitter expression have been observed in humans and animal models. However, the molecular mechanisms by which the SCN-PVN network responds to altered photoperiod is unknown.
Here, we show in mice that neuromedin S (NMS) and vasoactive intestinal polypeptide (VIP) neurons in the SCN display photoperiod-induced neurotransmitter plasticity.
In vivo recording of calcium dynamics revealed that NMS neurons alter PVN network activity in response to winter-like photoperiod. Chronic manipulation of NMS neurons is sufficient to induce neurotransmitter switching in PVN neurons and affects locomotor activity.
Our findings reveal previously unidentified molecular adaptations of the SCN-PVN network in response to seasonality and the role for NMS neurons in adjusting hypothalamic function to day length via a coordinated multisynaptic neurotransmitter switching affecting behavior.
Earth’s Days Are Mysteriously Getting Longer, Scientists Say
Atomic clocks, combined with precise astronomical measurements, have revealed that the length of a day is suddenly getting longer, and scientists don’t know why.
This has critical impacts not just on our timekeeping, but also things like GPS and other technologies that govern our modern life.
Over the past few decades, Earth’s rotation around its axis – which determines how long a day is – has been speeding up. This trend has been making our days shorter; in fact, in June 2022 we set a record for the shortest day over the past half a century or so.
But despite this record, since 2020 that steady speedup has curiously switched to a slowdown – days are getting longer again, and the reason is so far a mystery.
While the clocks in our phones indicate there are exactly 24 hours in a day, the actual time it takes for Earth to complete a single rotation varies ever so slightly. These changes occur over periods of millions of years to almost instantly – even earthquakes and storm events can play a role.
It turns out a day is very rarely exactly the magic number of 86,400 seconds.
The ever-changing planet
Over millions of years, Earth’s rotation has been slowing down due to friction effects associated with the tides driven by the Moon. That process adds about about 2.3 milliseconds to the length of each day every century. A few billion years ago an Earth day was only about 19 hours.
For the past 20,000 years, another process has been working in the opposite direction, speeding up Earth’s rotation. When the last ice age ended, melting polar ice sheets reduced surface pressure, and Earth’s mantle started steadily moving toward the poles.
Just as a ballet dancer spins faster as they bring their arms toward their body – the axis around which they spin – so our planet’s spin rate increases when this mass of mantle moves closer to Earth’s axis. And this process shortens each day by about 0.6 milliseconds each century.
Over decades and longer, the connection between Earth’s interior and surface comes into play too. Major earthquakes can change the length of day, although normally by small amounts.
For example, the Great Tōhoku Earthquake of 2011 in Japan, with a magnitude of 8.9, is believed to have sped up Earth’s rotation by a relatively tiny 1.8 microseconds.
Apart from these large-scale changes, over shorter periods weather and climate also have important impacts on Earth’s rotation, causing variations in both directions.
The fortnightly and monthly tidal cycles move mass around the planet, causing changes in the length of day by up to a millisecond in either direction. We can see tidal variations in length-of-day records over periods as long as 18.6 years.
The movement of our atmosphere has a particularly strong effect, and ocean currents also play a role. Seasonal snow cover and rainfall, or groundwater extraction, alter things further.
Why is Earth suddenly slowing down?
Since the 1960s, when operators of radio telescopes around the planet started to devise techniques to simultaneously observe cosmic objects like quasars, we have had very precise estimates of Earth’s rate of rotation.
A comparison between these estimates and an atomic clock has revealed a seemingly ever-shortening length of day over the past few years.
But there’s a surprising reveal once we take away the rotation speed fluctuations we know happen due to the tides and seasonal effects. Despite Earth reaching its shortest day on 29 June 2022, the long-term trajectory seems to have shifted from shortening to lengthening since 2020. This change is unprecedented over the past 50 years.
The reason for this change is not clear. It could be due to changes in weather systems, with back-to-back La Niña events, although these have occurred before. It could be increased melting of the ice sheets, although those have not deviated hugely from their steady rate of melt in recent years.
Could it be related to the huge volcano explosion in Tonga injecting huge amounts of water into the atmosphere? Probably not, given that occurred in January 2022.
Scientists have speculated this recent, mysterious change in the planet’s rotational speed is related to a phenomenon called the “Chandler wobble” – a small deviation in Earth’s rotation axis with a period of about 430 days.
Observations from radio telescopes also show that the wobble has diminished in recent years; the two may be linked.
One final possibility, which we think is plausible, is that nothing specific has changed inside or around Earth. It could just be long-term tidal effects working in parallel with other periodic processes to produce a temporary change in Earth’s rotation rate.
Do we need a ‘negative leap second’?
Precisely understanding Earth’s rotation rate is crucial for a host of applications – navigation systems such as GPS wouldn’t work without it. Also, every few years timekeepers insert leap seconds into our official timescales to make sure they don’t drift out of sync with our planet.
If Earth were to shift to even longer days, we may need to incorporate a “negative leap second” – this would be unprecedented, and may break the internet.
The need for negative leap seconds is regarded as unlikely right now. For now, we can welcome the news that – at least for a while – we all have a few extra milliseconds each day.
Matt King, Director of the ARC Australian Centre for Excellence in Antarctic Science, University of Tasmania and Christopher Watson, Senior Lecturer, School of Geography, Planning, and Spatial Sciences, University of Tasmania.
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Earth’s Days Have Been Mysteriously Increasing in Length – Scientists Don’t Know Why
Precise measurements show that Earth’s rotation has been mysteriously slowing down since 2020, making the day longer.
Precise astronomical observations, combined with atomic clocks, have revealed that the length of a day is suddenly getting longer. Scientists don’t know why.
This has critical impacts not just on our timekeeping, but also on things like GPS and other precision technologies that govern our modern life.
Earth’s rotation around its axis has been speeding up over the past few decades. Since this determines how long a day is, this trend has been making our days shorter. In fact, in June 2022 we set a record for the shortest day over the past half a century or so.
However, despite this record, since 2020 that steady speedup has curiously switched to a slowdown. Now, days are getting longer again, and the reason so far remains a mystery.
While the clocks in our phones indicate there are exactly 24 hours in a day, the actual time it takes for Earth to complete a single rotation can vary ever so slightly. These changes sometimes occur over periods of millions of years, and other times almost instantly. For example, even earthquakes and storm events can play a role.
It turns out that a day is very rarely exactly the magic number of 86,400 seconds.
The ever-changing planet
Earth’s rotation has been slowing down over millions of years due to friction effects associated with the tides driven by the Moon. That process adds about 2.3 milliseconds to the length of each day every 100 years. A few billion years ago, an Earth day was only about 19 hours.
For the past 20,000 years, another process has been working in the opposite direction, speeding up Earth’s rotation. When the last ice age ended, melting polar ice sheets reduced surface pressure, and Earth’s mantle started steadily moving toward the poles.
Just as a ballet dancer spins faster as they bring their arms toward their body – the axis around which they spin – our planet’s spin rate increases when this mass of mantle moves closer to Earth’s axis. This process has been shortening each day by about 0.6 milliseconds each century.
Over decades and longer, the connection between Earth’s interior and surface comes into play too. Major earthquakes can change the length of day, although normally by small amounts. For example, the Great Tōhoku Earthquake of 2011 in Japan, with a magnitude of 8.9, is believed to have sped up Earth’s rotation by a relatively tiny 1.8 microseconds.
Apart from these large-scale changes, over shorter periods weather and climate also have important impacts on Earth’s rotation, causing variations in both directions.
The fortnightly and monthly tidal cycles move mass around the planet, causing changes in the length of day by up to a millisecond in either direction. We can see tidal variations in length-of-day records over periods as long as 18.6 years. The movement of our atmosphere has a particularly strong effect, and ocean currents also play a role. Seasonal snow cover and rainfall, or groundwater extraction, alter things further.
Why is Earth suddenly slowing down?
Since the 1960s, when operators of radio telescopes around the planet started to devise techniques to simultaneously observe cosmic objects like quasars, we have had very precise estimates of Earth’s rate of rotation.
Using radio telescopes to measure Earth’s rotation involves observations of radio sources like quasars. Credit:
Scientists have speculated this recent, mysterious change in the planet’s rotational speed is related to a phenomenon called the “Chandler wobble” – a small deviation in Earth’s rotation axis with a period of about 430 days. Observations from radio telescopes also show that the wobble has diminished in recent years. Perhaps the two are linked.
One final possibility, which we think is plausible, is that nothing specific has changed inside or around Earth. It could just be long-term tidal effects working in parallel with other periodic processes to produce a temporary change in Earth’s rotation rate.
Do we need a ‘negative leap second’?
Precisely understanding Earth’s rotation rate is crucial for a host of applications – navigation systems such as GPS wouldn’t work without it. Also, every few years timekeepers insert leap seconds into our official timescales to make sure they don’t drift out of sync with our planet.
If Earth were to shift to even longer days, we may need to incorporate a “negative leap second” – this would be unprecedented, and may break the internet.
The need for negative leap seconds is regarded as unlikely right now. For now, we can welcome the news that – at least for a while – we all have a few extra milliseconds each day.
Written by:
- Matt King – Director of the ARC Australian Centre for Excellence in Antarctic Science, University of Tasmania
- Christopher Watson – Senior Lecturer, School of Geography, Planning, and Spatial Sciences, University of Tasmania
This article was first published in The Conversation.
Full length trailer of ‘Game of Thrones’ prequel ‘House of the Dragon’ drops before Comic-Con panel Saturday
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The highly anticipated full-length trailer for the “Game of Thrones” prequel “House of the Dragon” dropped on Wednesday, ahead of the show’s Comic-Con panel on Saturday.
The nearly three-minute trailer is the first-time fans have seen the actors actually act as their character, as up until now, they have only been able to reference the on-set pictures which were released to the public as the show was filming.
In the trailer, fans are introduced to the Targaryen family in their darkest hour up to that point, and it features plenty of dragons.
The new show will tell the story of Daenerys Targaryen’s ancestors, the Targaryen family, when they ruled Westeros.
(AP)
The prequel series was first announced in October 2019, on the same day HBO Max announced the cancellation of another prequel they were planning, which was supposed to dig deeper into the story of The Long Night which is often referred to throughout “Game of Thrones.”
HBO CONFIRMS ‘GAME OF THRONES’ PREQUEL TO START FILMING IN APRIL
“House of the Dragon” is based on a book written by George R.R. Martin, the author of “A Song of Ice and Fire” the book “Game of Thrones” is based off, called “Fire and Blood.”
The book takes place 200 years before the events of “Game of Thrones,” and tells the story of the Targaryen family when they still ruled Westeros. King Viserys I, played by Paddy Considine, is searching for an heir, because although he has a daughter, Westerosi law at the time did not allow for women to sit on the Iron Throne.
Aegon II goes to war with his niece Rhaenyra Targaryen for the Iron Throne after his brother King Viserys dies.
(HBO)
The show will then detail the civil war which took place between King Viserys’ brother Aegon II and his daughter Rhaenyra Targaryen after his death. The feud between niece and uncle came to be known as the Dance of Dragons and split the citizens of Westeros into teams.
Showrunners of “Game of Thrones,” D.B. Weiss and David Benioff are not involved in the making of this prequel series, and handed the baton off to Miguel Sapochnik and Ryan Condal.
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“Ryan and Miguel have done an amazing job, and the cast… just as with Game of Thrones, most viewers will only have heard of a few of the actors, but I think you are going to fall in love with a lot of them. (Only to have your heart broken later when… but no, that would be telling),” Martin wrote on his website last December. “I think the Targaryens are in very good hands.”
The show is based off a book written by George R.R. Martin called “Fire and Blood.” Martin approves of Miguel Sapochnik and Ryan Condal’s take on his book.
(Amy Sussman/Getty Images)
Both Condal and Sapochnik are excited to take on this project, but admitted it was difficult coming up in the shadow of “Game of Thrones,” which was such a big success.
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“We can’t say, ‘Well, when we did Thrones, we did it this way…,'” Sapochnik told The Hollywood Reporter. “This is something else, and should be something else… Hopefully it will be seen as something else. But it will have to earn that. We’ll be lucky if we ever come close to what the original show was, so we’re just putting our heads down and getting on with it and hoping what we come up with is worthy of having a Game of Thrones title.”