A Moonlit Earth as Seen From Artemis II

April 2, 2026

One of the first images transmitted back to Earth from the Artemis II mission was a stunner. In a single image, Earth’s full disk appears amid celestial phenomena that illustrate its place in the solar system. And although the visible hemisphere appears to be awash in sunlight, it is actually lit by moonlight. The astronauts’ vantage point provided a rare opportunity to capture nighttime features—most notably lights from human habitation—from a new perspective.

An Artemis crew member captured the photo from the Orion spacecraft after it completed the translunar injection burn, which sent the spacecraft out of Earth orbit and on a trajectory toward the Moon. In the photo, Earth eclipses the Sun from Orion’s perspective, leaving only a small sliver of its bright light visible around the bottom right edge. Green auroras, caused by charged particles from the Sun interacting with Earth’s upper atmosphere, glow around the north and south poles (lower left and upper right, respectively).

The Sun’s light also produces the fuzzy glow, known as zodiacal light, that appears to the lower right of Earth. This phenomenon comes from sunlight reflecting off interplanetary dust. Skywatchers on Earth may see it at certain times of year around dawn or dusk as a faint column of light extending up from the horizon. Data collected by NASA’s Juno spacecraft on its journey to Jupiter suggest that Mars may be a significant source of the dust particles that produce zodiacal light. Earth’s other planetary neighbor, Venus, appears as the bright object in the bottom right of the image.

April 2, 2026

On Earth itself, city lights are evidence of human activity. Bright areas appear in Spain, Portugal, and northern Africa (lower left), sub-Saharan Africa (center left), and Brazil (center right). Digital camera technology—with help from the illumination of a full Moon—made it possible to see these and other details of Earth’s surface and atmosphere in low light. The crew set the camera’s ISO to 51,200 to make it highly sensitive to light. For comparison, an ISO setting of 100 or 200 is common for daytime photography.

Previous nighttime views of Earth taken from spacecraft may look very different from this photo but have also inspired and enlightened. For instance, the Apollo 12 crew photographed Earth eclipsing the Sun in 1969; astronaut Alan Bean would go on to depict his impressions of the event in paintings.

More recently, astronauts aboard the International Space Station have photographed the planet at night from low Earth orbit, while NASA’s Black Marble nighttime lights product suite uses satellite observations to produce science-quality records of nighttime lights at daily, monthly, and yearly time scales. Those programs provide sustained data records, while the Artemis II photo is distinctive as a single human-captured full-disk view showing many low-light features at once.

Cindy Evans, senior exploration scientist in the Astromaterials Research and Exploration Science Division at NASA’s Johnson Space Center, was working in the Science Evaluation Room during the Artemis II mission and was one of the first people on Earth to see the image. Evans was struck both by its beauty and the perspective revealed by all the visible solar system features. “I love the image so much because it was taken with Earth in moonshine, and shows Earth as a solar system body, a dynamic planet interacting with the solar wind, and a place harboring life,” she said.

The image is scientifically valuable, as well, said Miguel Román, Deputy Director for Atmospheres and Data Systems at NASA’s Goddard Space Flight Center. “It speaks powerfully to the breadth of what NASA does across science and human exploration,” he said. Román studies artificial light at night, as viewed from space, as a measurable signal of human activity.

“[This photo] reminds us that Earth at night is visually compelling, physically complex, and scientifically underexplored,” Román said. “I see this image as a glimpse of what Earth science can become in the future.”

NASA images prepared for Earth Observatory by Lauren Dauphin. Story by Lindsey Doermann.

References & Resources

• NASA (2026, April 22) Advancing Earth Observation at NASA Since Release of Earthrise Photo. Accessed June 2, 2026.
• NASA (2026, April 3) Hello, World. Accessed June 2, 2026.
• NASA (2006, October 9) Astronaut Still Photography During Apollo. Accessed June 2, 2026.
• NASA Earth Observatory (2026, May 15) Picturing Earth in a New Light. Accessed June 2, 2026.
• NASA Image and Video Library (2026, April 3) Earth From the Perspective of Artemis II. Accessed June 2, 2026. 

Source: A Moonlit Earth as Seen From Artemis II - NASA Science   

The Forgotten Organ: How Your Thymus Could Hold the Key to Longevity and Cancer Treatment

Tucked behind your sternum, just in front of your heart, sits a small organ called the thymus. You were probably never taught much about it after biology class, and neither, it turns out, were most doctors. The thymus was long believed to serve its purpose early in life, training the immune system’s T cells during childhood, then quietly fading into irrelevance after puberty.

That story is now being rewritten.

Two new studies from researchers at Harvard-affiliated Mass General Brigham, published simultaneously in the same issue of Nature in March 2026, present compelling evidence that thymic health in adults has profound consequences for how long we live, our risk of cardiovascular disease, whether we develop cancer, and critically, how well we respond to one of oncology’s most powerful modern tools: cancer immunotherapy.

 

“The thymus has been overlooked for decades and may be a missing piece in explaining why people age differently, and why cancer treatments fail in some patients.”

Hugo Aerts, PhD — HMS Professor & Director, AI in Medicine Program, Mass General Brigham

What the thymus actually does

The thymus is where T cells, the immune system’s front-line fighters, are trained and certified to distinguish the body’s own cells from foreign threats. During childhood and adolescence, it is highly active. But it shrinks as we age, producing fewer new T cells, and researchers largely assumed this meant its job was done.

What the new research reveals is that this involution is not uniform. Thymic health varies widely between individuals of the same age, and that variation turns out to matter enormously, far more than anyone had measured before.

Using AI to see what the eye misses

The breakthrough that made these studies possible was methodological. Researchers led by Simon Bernatz, MD, and corresponding author Hugo Aerts, PhD, developed a deep-learning AI model capable of estimating thymic health directly from routine chest CT scans, the kind patients already receive during standard cancer screening or cardiac workups. The thymus appears in the field of view of these scans, but physicians have historically ignored it.

The team trained their model on 5,674 independent CT scans, then applied it to two large prospective cohorts: over 25,000 participants in the National Lung Screening Trial and 2,581 adults from the long-running Framingham Heart Study. Crucially, these were generally healthy, asymptomatic adults, not patients already being treated for disease.

The findings: thymic health and longevity

The results from the first study were striking. After generating a “thymic health” score for each participant, the researchers found dramatic differences in outcomes between those with high and low scores:

·         50% lower risk of death (all causes) for those with high thymic health

·         63% lower risk of cardiovascular death

·         36% lower risk of developing lung cancer

These associations held up after adjusting for age and other established health factors, meaning thymic health carries independent predictive value beyond what doctors already track. The researchers theorize that when thymic health and T cell diversity decline, the immune system becomes less capable of responding to new threats, whether that’s a forming tumor or an inflamed vessel wall.

A new predictor of immunotherapy response

The second study tackled a problem that has frustrated oncologists for years: why do some cancer patients respond dramatically to immunotherapy while others see little benefit? Immune checkpoint inhibitors, drugs that take the brakes off T cells so they can attack tumors, have transformed cancer treatment. But predicting who will respond has remained elusive.

The researchers applied their AI thymic health model to CT scans from 3,476 real-world cancer patients receiving checkpoint inhibitor therapy across multiple tumor types. Among patients with non-small cell lung cancer, those with high thymic health scores had a 37% lower risk of cancer progression and a 44% lower risk of death compared to those with low scores. Importantly, this effect was seen across different tumor types, suggesting thymic health may act as a tumor-agnostic predictor of immunotherapy success.

Caveat: The researchers note these findings require confirmation in further studies, and the AI imaging method is not yet ready for routine clinical use.

What harms thymic health?

The studies also identified lifestyle and systemic factors associated with poorer thymic health. Chronic inflammation, smoking, and high body weight were all linked to lower thymic health scores, the same behaviors known to harm cardiovascular and metabolic health may also be quietly degrading the immune organ that helps keep us alive longer.

What this means for medicine

The implications, if confirmed, are considerable. Thymic health measured from a CT scan a patient is already receiving could become a new tool for stratifying cancer patients before immunotherapy, helping predict who will benefit, and potentially guiding decisions about treatment intensity or combination strategies.

More broadly, the research repositions the thymus as what the authors call “a central regulator of immune-mediated aging and disease susceptibility in adulthood.” A companion piece in Nature Biotechnology notes that a cluster of biotechnology companies is already investigating thymus regeneration and ways to recapitulate thymic function pharmacologically.

Related journal research

·         Bernatz et al., “Thymic health consequences in adults” — Nature 652, 986–994 (2026)

·         Bernatz et al., “Thymic health and immunotherapy outcomes in patients with cancer” — Nature 652, 995–1003 (2026)

·         “Thymic health is a predictor of lifelong well-being and immunotherapy effectiveness” — Nature News & Views (2026)

·         Sheridan C., “Thymus renaissance poised to boost health and longevity” — Nature Biotechnology 44, 675–678 (2026)

·         “Could thymic health predict immunotherapy outcomes?” — Medscape, October 2025 (ESMO Congress)

Looking ahead

The team at Mass General Brigham is already pursuing follow-up research, including a study examining whether incidental radiation exposure to the thymus during lung cancer treatment affects patient outcomes, a question with immediate implications for radiotherapy planning.

For now, the thymus remains in the research phase rather than the clinic. But these two papers mark a clear inflection point. An organ that medicine largely forgot about may turn out to be one of the most important variables in how long we live and how well we fight cancer.

Original source: Harvard Medical School News · Research published in Nature, March 18, 2026. 

Source: The Forgotten Organ: How Your Thymus Could Hold the Key to Longevity and Cancer Treatment – Scents of Science