Saturday, September 10, 2022

Why go back to the Moon?

by Lucie AUBOURG

The United States is returning to the Moon 60 years after JFK's famous speech.

On September 12, 1962, then US president John F Kennedy informed the public of his plan to put a man on the Moon by the end of the decade.

It was the height of the Cold War and America needed a big victory to demonstrate its space superiority after the Soviet Union had launched the first satellite and put the first man in orbit.

"We choose to go to the Moon," Kennedy told 40,000 people at Rice University, "because that challenge is one that we are willing to accept, one we are unwilling to postpone, and one which we intend to win."

Sixty years on, the United States is about to launch the first mission of its return program to the Moon, Artemis. But why repeat what has already been done?

Criticism has risen in recent years, for example from Apollo 11 astronaut Michael Collins, and the Mars Society founder Robert Zubrin, who have long advocated for America to go directly to Mars.

But NASA argues re-conquering the Moon is a must before a trip to the Red Planet. Here's why.

Long space missions

NASA wants to develop a sustainable human presence on the Moon, with missions lasting several weeks –- compared to just a few days for Apollo.

The goal: to better understand how to prepare for a multi-year round trip to Mars.

In deep space, radiation is much more intense and poses a real threat to health.

Low Earth Orbit, where the International Space Station (ISS) operates, is partly shielded from radiation by the Earth's magnetic field, which isn't the case on the Moon.

"We choose to go to the Moon," Kennedy told 40,000 people at Rice University, "because that challenge is one that — "We choose to go to the Moon," Kennedy told 40,000 people at Rice University, "because

From the first Artemis mission, many experiments are planned to study the impact of this radiation on living organisms, and to assess the effectiveness of an anti-radiation vest.

What's more, while the ISS can often be resupplied, trips to the Moon—a thousand times further—are much more complex.

To avoid having to take everything with them, and to save costs, NASA wants to learn how to use the resources present on the surface.

In particular, water in the form of ice, which has been confirmed to exist on the lunar south pole, could be transformed into rocket fuel by cracking it into its separate hydrogen and oxygen atoms.

Testing new gear

NASA also wants to pilot on the Moon the technologies that will continue to evolve on Mars. First, new spacesuits for spacewalks.

Their design was entrusted to the company Axiom Space for the first mission which will land on the Moon, in 2025 at the earliest.

Other needs: vehicles —both pressurized and unpressurized—so that the astronauts can move around, as well as habitats.

Finally, for sustainable access to an energy source, NASA is working on the development of portable nuclear fission systems.

Solving any problems that arise will be much easier on the Moon, only a few days away, than on Mars, which can only be reached in at least several months.

ASA also wants to test on the Moon the technologies that will continue to evolve on Mars.

Establishing a waypoint

A major pillar of the Artemis program is the construction of a space station in orbit around the Moon, called Gateway, which will serve as a relay before the trip to Mars.

All the necessary equipment can be sent there in "multiple launches," before finally being joined by the crew to set off on the long voyage, Sean Fuller, responsible for the Gateway program, told AFP.

"Kind of like you're stopping at your gas station to make sure you get all the stuff, and then you're off on your way."

Maintaining leadership over China

Apart from Mars, another reason put forward by the Americans for settling on the Moon is to do so before the Chinese, who plan to send taikonauts by the year 2030.

China is the United States' main competition today as the once proud Russian space program has withered.

"We don't want China suddenly getting there and saying, "This is our exclusive territory,'" NASA boss Bill Nelson said in a recent interview.

For the sake of science

While the Apollo missions brought back to Earth nearly 400 kilograms of lunar rock, new samples will make it possible to further deepen our knowledge of this celestial object and its formation.

"The samples that we collected during the Apollo missions changed the way we view our solar system," astronaut Jessica Meir told AFP. "I think we can expect that from the Artemis program as well."

She expects further scientific and technological breakthroughs too, just like during the Apollo era.

To the Moon and beyond: NASA's Artemis program

Growth of psychiatric mental health nurse practitioners helped offset drop in psychiatrists treating Medicare patients

Peer-Reviewed Publication

HARVARD T.H. CHAN SCHOOL OF PUBLIC HEALTH

Boston, MA—The mental health system is increasingly reliant on psychiatric mental health nurse practitioners (PMHNPs) to meet the psychiatric needs of Medicare patients, according to a new study led by researchers at Harvard T.H. Chan School of Public Health.

“We were surprised by the degree to which PMHNPs are the de facto mental health prescribers in parts of the country,” said corresponding author Michael Barnett, associate professor of health policy and management at Harvard Chan School. “In the states where PMHNPs have no restrictions on prescribing medications, these providers account for 50% of all mental health prescriber visits in rural areas, which was much greater than we had anticipated.”

The study will be published in the September 2022 issue of Health Affairs.

Mental health access is a public health crisis that the COVID-19 pandemic has exacerbated. While demand for mental health treatment is soaring, the supply of psychiatrists accepting insurance is dropping, particularly in rural areas.

To assess how the mental health workforce and patient population have changed over time, Barnett and his colleagues analyzed fee-for-service Medicare claims during 2011-2019. The team focused on the number of PMHNPs and psychiatrists billing Medicare, the volume of outpatient and psychiatric services by provider group, and how these numbers varied by rurality and scope-of-practice regulations, which can restrict whether a PMHNP is able to prescribe medications.

The findings showed that PMHNPs provided nearly 1 in 3 mental health prescriber visits to Medicare patients nationally by 2019. The number of PMHNPs also increased 162% during 2011-2019, while psychiatrists billing Medicare dropped by 6%. During this period, without growth in the PMHNP workforce, there would have been a decline of nearly 30% in mental health specialist visits in Medicare. Instead, the drop was 12%.

“This work puts the spotlight on PMHNPs as a critical part of the mental health workforce,” said Barnett. “This is so important because we desperately need new solutions to address the current mental health crisis in this country. Policy that targets the PMHNP workforce could be a key part of the national effort to expand mental health access.”

Co-author Arno Cai is also from Harvard Chan School.

This research was supported by the National Institute on Aging (K23 AG058806-01) and the National Institute of Mental Health (R01 MH112829-01) in the National Institutes of Health.

“Trends In Mental Health Care Delivery By Psychiatrists And Nurse Practitioners In Medicare, 2011–19,” Arno Cai, Ateev Mehrotra, Hayley D. Germack, Alisa B. Busch, Haiden A. Huskamp, and Michael L. Barnett, Health Affairs, September 2022, doi: 10.1377/ hlthaff.2022.00289.

Visit the Harvard Chan School website for the latest news, press releases, and multimedia offerings.

###

Harvard T.H. Chan School of Public Health brings together dedicated experts from many disciplines to educate new generations of global health leaders and produce powerful ideas that improve the lives and health of people everywhere. As a community of leading scientists, educators, and students, we work together to take innovative ideas from the laboratory to people’s lives—not only making scientific breakthroughs, but also working to change individual behaviors, public policies, and health care practices. Each year, more than 400 faculty members at Harvard Chan School teach 1,000-plus full-time students from around the world and train thousands more through online and executive education courses. Founded in 1913 as the Harvard-MIT School of Health Officers, the School is recognized as America’s oldest professional training program in public health.

JOURNAL

Health Affairs

DOI

10.1377/hlthaff.2022.00289

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

People

ARTICLE TITLE

Trends In Mental Health Care Delivery By Psychiatrists And Nurse Practitioners In Medicare, 2011–19

ARTICLE PUBLICATION DATE

6-Sep-2022

OUR FRIENDLY FUNGUY

Can fungi help Texas’ grasses cope with climate change?

From humid east to arid west, Texas is a living lab for Rice study of range limits

Grant and Award Announcement

RICE UNIVERSITY

Collecting grass and symbionts near Huntsville, Texas — IMAGE: SKIDMORE COLLEGE STUDENT SAR LINDNER (LEFT) OBSERVES AS RICE UNIVERSITY GRADUATE STUDENT ALI CAMPBELL EXAMINES A GRASS STEM FOR SIGNS OF SYMBIOTIC FUNGI DURING A FIELD SAMPLING EXPEDITION NEAR HUNTSVILLE, TEXAS. view more
CREDIT: JEFF FITLOW/RICE UNIVERSITY

HOUSTON – (Sept. 6, 2022) – As anyone who’s crossed Texas on Interstate 10 can tell you, the Lone Star State is where east meets west. For Rice University biologist Tom Miller, the sharp divide between East Texas’ humid piney woods and West Texas’ parched desert is also a living laboratory where he and his students can learn about boundaries that aren’t found on maps.

“That's one of the sharpest aridity gradients on the planet,” Miller said of the climatic shift from east to west Texas. “And it’s an important boundary for species. A lot of species that occur in eastern North America hit their westernmost limits in Texas.”

Miller, an associate professor of biosciences at Rice, and his research group study range limits, invisible biological dividing lines between where a species can survive and where it can’t. In a world of changing climate, those lines are moving, and Miller and his students want to study and understand how they are moving and why.

Miller’s team studies grasses and other species at eight field sites along a 580-mile stretch of I-10 from lush Lafayette, Louisiana, to sandy Sonora, Texas, about 170 miles west of San Antonio. Thanks to a grant from the National Science Foundation, they’ve begun a first-of-its-kind study to find out whether a strange, ancient marriage between native Texas grasses and their hidden fungal partners could position the plants to better withstand droughts that are expected to be more frequent and severe due to climate change.

“Range limits arise from stress,” Miller said. “As plants go from very wet to very dry places, their drought stress increases. We expect drought stress to be an important limit on how far west a lot of species can make it, particularly eastern species. Because the further west you go, the greater the drought stress.

“The unique thing about this study is that we're trying to understand the role that microbes and microbial symbionts play in determining the range limits of plants,” he said.

The grass species in the study are varieties that thrive in cooler months. Each hosts Epichloë endophytes, symbiotic fungi that live inside the plant. In exchange for living a protected life inside their hosts, the fungi supplies the plants with alkaloid chemicals that previous studies have shown both improve drought tolerance and discourage predation by sickening grass-eating animals.

In their experiments, Miller and his students remove the fungal partner from some grasses and leave it in others. At each field site, partnered and unpartnered plants are grown in plots near one another, and the difference between them reveals the effects of the fungus.

“We’ll plant at all of these places from Louisiana to West Texas, and we’ll compare how important that microbial effect is as the grasses go from east to west and their drought stress increases,” he said. “That's going to allow us to build models that will tell us what role the microbes play in generating range limits and possibly extending range limits.

“That is new,” Miller said. “To my knowledge, this will be the first study to do that.”

Global warming is already raising temperatures in Texas and a 2021 report from the Texas State Climatologist’s office predicts that the number of 100-degree days each summer will nearly double by 2036 compared to the average number of such days from 2001-2020.

Ranges of plants and animals will shift in response, and the wet-dry gradient that has defined Central Texas for centuries may shift as droughts become more frequent and more intense. One might easily imagine drought-tolerant and drought-intolerant plants marching right along with such a shift, followed by all the insects and animals that depend on them. But the real world is far more complex, Miller said. Even slight variations in average rainfall, soil moisture and many other factors can push the balance one way or the other.

“For plants, there’s also the question of whether they can shift to a new range,” he said. “Most rely on either the wind or animals to carry their seeds to new places, and climate change could impact both, making range shifts impossible for some plants.”

Better understanding the beneficial relationship between native Texas grasses and their microbial partners will unlock pieces of the range-shifting puzzle that today are hidden from ecologists, conservation biologists and others who track species ranges, Miller said.

“The ways that climate maps onto geography are already changing and will continue to change,” Miller said. “What do these microbial associations mean for how species will shift in response to climate change? Are microbes going to facilitate expansion into new habitats? Could they potentially inhibit expansion into other habitats?

“Microbial associations are a hidden layer in this large-scale biogeographic problem, and we want to unlock that layer and inform this bigger discussion about how plants and animals in Texas are going to respond to climate change,” Miller said.

-30-

CAPTION

From left to right, Rice University graduate student Ali Campbell opens a grass stem and collects a thin layer of tissue, which will be examined later under a microscope for the presence of symbiotic fungi.

CREDIT

Jeff Fitlow/Rice University

CAPTION
Rice University biosciences graduate student Joshua Fowler collects samples of grass species and their symbiotic microbial partners at a field site near Huntsville, Texas.
CREDIT
Jeff Fitlow/Rice University

Grant information:

“The geographic footprint of host-symbiont mutualism” | National Science Foundation | Division of Environmental Biology

https://www.nsf.gov/awardsearch/showAward?AWD_ID=2208857

VIDEO is available at:

https://youtu.be/dYuayCB6scE
DESCRIPTION: Rice University biologist Tom Miller’s research group studies range limits, invisible biological dividing lines between where species can survive and where they can’t. In a world of changing climate, those lines are moving, and Miller and his students are using Texas as a “living laboratory” to better understand those changes. Thanks to a grant from the National Science Foundation, they’re conducting a first-of-its-kind study at eight sites along a 580-mile stretch of I-10 from Lafayette, Louisiana, to Sonora, Texas. The goal is to find out whether a strange, ancient marriage between native Texas grasses and their hidden fungal partners could position the plants to better withstand droughts that are expected to be more frequent and severe due to climate change.

High-resolution IMAGES are available for download at:

https://news-network.rice.edu/news/files/2022/09/0906_GRASSES-268-lg.jpg
CAPTION: From left, students Joshua Fowler, Ali Campbell and Sar Lindner carry gear they will use at a field site near Huntsville, Texas, to collect samples of native grass species as well as symbiotic fungi that live inside the grass. (Photo by Jeff Fitlow/Rice University)

https://news-network.rice.edu/news/files/2022/09/0906_GRASSES-388-lg.jpg
CAPTION: Skidmore College student Sar Lindner (left) observes as Rice University graduate student Ali Campbell examines a grass stem for signs of symbiotic fungi during a field sampling expedition near Huntsville, Texas. (Photo by Jeff Fitlow/Rice University)

https://news-network.rice.edu/news/files/2022/09/0906_GRASSES-4p-lg.jpg
CAPTION: From left to right, Rice University graduate student Ali Campbell opens a grass stem and collects a thin layer of tissue, which will be examined later under a microscope for the presence of symbiotic fungi. (Photo by Jeff Fitlow/Rice University)

https://news-network.rice.edu/news/files/2022/09/0906_GRASSES-503-lg.jpg
CAPTION: Rice University biosciences graduate student Joshua Fowler collects samples of grass species and their symbiotic microbial partners at a field site near Huntsville, Texas. (Photo by Jeff Fitlow/Rice University)

This release can be found online at news.rice.edu.

Follow Rice News and Media Relations via Twitter @RiceUNews.

Located on a 300-acre forested campus in Houston, Rice University is consistently ranked among the nation’s top 20 universities by U.S. News & World Report. Rice has highly respected schools of Architecture, Business, Continuing Studies, Engineering, Humanities, Music, Natural Sciences and Social Sciences and is home to the Baker Institute for Public Policy. With 4,240 undergraduates and 3,972 graduate students, Rice’s undergraduate student-to-faculty ratio is just under 6-to-1. Its residential college system builds close-knit communities and lifelong friendships, just one reason why Rice is ranked No. 1 for lots of race/class interaction and No. 1 for quality of life by the Princeton Review. Rice is also rated as a best value among private universities by Kiplinger’s Personal Finance.

How changes in length of day change the brain and subsequent behavior

UC San Diego researchers illuminate the role of key neurons, which alter function in response to seasonal changes in light exposure

Peer-Reviewed Publication

UNIVERSITY OF CALIFORNIA - SAN DIEGO

SNG Graphic, National Institute of General Medical Sciences — IMAGE: IN THIS SCHEMATIC, SUNLIGHT CUES NEURONAL SIGNALS IN THE SUPRACHIASMATIC NUCLEUS, THE BRAIN’S MASTER CLOCK, WHICH IN TURN COORDINATES BIOLOGICAL CLOCKS REGULATING FUNCTIONS THROUGHOUT THE BODY, AND CONSEQUENTIAL BEHAVIORS. view more
CREDIT: NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES

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, publishing 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, PhD, 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 Porcu, PhD, 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.

Co-authors include: Anna Nilsson, Sathwik Booreddy, Samuel A. Barnes and David K. Welsh, all at UC San Diego.

# # #