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Pregnancy With Lupus Is Risky. Would She Be Able to Carry Her Baby to Term?

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Pregnancy With Lupus Is Risky. Would She Be Able to Carry Her Baby to Term?

Fatimah Shepherd knew she was not supposed to get pregnant — not now, while her illness was acting up, and maybe never.

Lupus, an autoimmune disease, was gnawing away at her kidneys, and doctors had warned her that pregnancy could tip her into full-blown kidney failure.

But in December 2023, there it was, a positive pregnancy test: two bold lines on the test strip, bright pink and indisputable.

“I almost passed out,” said Ms. Shepherd, 41, a New York City Fire Department dispatcher who lives in Brooklyn and had always wanted a child. “All I was thinking was, ‘What am I going to do?’”

For much of the 20th century, doctors instructed patients with lupus — a disease that strikes women during their prime childbearing years and that disproportionately affects Black, Hispanic and Asian women — to avoid pregnancy at any cost. The miscarriage rate was high, and pregnancy appeared to aggravate the disease.

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That advice has changed in recent decades, as treatments have improved. But pregnancy can still be a precarious enterprise, and women with lupus that attacks the kidneys are advised to become pregnant during periods when their disease is stable and has been in remission for six months.

Ms. Shepherd’s disease was far from stable. Her kidney function was so compromised that she had started the process of getting on a waiting list for a donor kidney. A nervous Ms. Shepherd called her nephrologist, Dr. Mala Sachdeva, a professor of medicine with Northwell Health in Great Neck, N.Y.

But Ms. Shepherd recalled: “When I told her my news, she said, ‘Wow! Congratulations!’ And the way she said it, I could finally breathe.”

The doctor told her that pregnancy posed serious health risks, but that she had cared for other women who had done well and given birth to healthy babies. She told Ms. Shepherd, “We’re going to get through this.”

“It was a thing she said over and over again, throughout my pregnancy, every time I saw her: ‘We’re going to get through this,’” Ms. Shepherd recalled.

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The team of doctors managing Ms. Shepherd’s care at Northwell Health — all women, most of them mothers themselves — met with Ms. Shepherd early in the pregnancy. They described in detail the risks that pregnancy entailed for both her and the fetus, and urged her to think carefully about whether to proceed.

The stress of pregnancy would almost certainly push her into kidney failure, and it could be permanent. Her high blood pressure could escalate out of control, which could restrict the baby’s growth. And she was at high risk for developing pre-eclampsia, a life-threatening condition that might force her doctors to deliver the baby prematurely.

“If her blood had clotting issues, if she had a seizure, then we would be delivering her to save her life,” said Dr. Hima Tam Tam, director of obstetrical medicine at North Shore University Hospital and Long Island Jewish Medical Center

A premature baby also would face risks. “There’s a risk of cerebral palsy; there’s a risk of blindness; there’s a risk the baby might have difficulty with ambulation,” said Dr. Dawnette Lewis, the director of the Northwell Center for Maternal Health.

There was also a risk the baby would not make it at all.

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The doctors had several conversations with Ms. Shepherd because they wanted to give her time to process the information. “It’s a lot to wrap your head around,” Dr. Tam Tam said.

But they told her they would support any decision she made.

“And she definitely knew what she wanted,” Dr. Tam Tam said. “I knew that from the minute I saw her. I just wanted to make sure that she knew how long this journey was going to be.”

In January, Ms. Shepherd went on a planned vacation to the Bahamas. But a month later, when she came in for a checkup, the doctors were alarmed. Her potassium levels had spiked, which could cause cardiac arrest. Her blood acid levels were also high, putting the fetus at risk. She needed to start dialysis immediately.

Most kidney failure patients undergo dialysis three times a week. But pregnant women are recommended to have four-hour sessions, six days a week, in order to minimize fluid fluctuations that can restrict blood flow to the fetus. The fetal heart rate is monitored before, during and after dialysis.

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Dialysis is exhausting, and Ms. Shepherd would be commuting from Brooklyn to Long Island for her care. All the doctors agreed: The safest thing at that point was to admit her to the hospital.

“We all kind of felt we wanted to just pack her up and take her home with us,” Dr. Tam Tam said.

But Ms. Shepherd had just come for a doctor’s visit; she didn’t even have a change of clothes with her. Still, she trusted the team. “It was their suggestion, but it was my choice,” she said. “And I said, OK, I’m going to do it. If you’re saying this is going to better for my child, I’ll stay here.”

She would remain at Katz Women’s Hospital at North Shore University Hospital in Manhasset for the next five months.

Ms. Shepherd was given a room with a view: on a corner, with large windows looking out over the parking lot on one side, where she could see the hospital staff’s comings and goings, and a small waterfall nestled in a grove of trees on the other.

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She decided to make the best of it. She did her hair every morning and got dressed — no hospital gowns for her — and she took up painting. She had dialysis in the afternoons, and spent the mornings walking the halls of the hospital to maintain good circulation in her legs. Darnell Wilson, the baby’s father, came every Friday and spent the weekend with her; family members visited, and her colleagues from the Fire Department set up a rotating schedule of visits, so she was never alone.

When Ms. Shepherd was in her sixth month of pregnancy, she had a gender reveal party in her hospital room. She was having a boy, and she painted her nails blue in celebration. In May, she hired a professional photographer to do a pregnancy photo shoot of her.

“I kept myself busy,” she said. “I would take nice walks around the hospital and socialize with everybody. And I prayed every night and throughout the day. I had to keep a positive mind-set.”

Her doctors were checking her labs daily, constantly making adjustments in her medications and monitoring for any signs of pre-eclampsia. It was tricky, because lupus flare-ups during pregnancy can look like the condition, and when blood pressure spikes, it is not always clear whether it is from hypertension or pre-eclampsia. “You don’t want to deliver someone early because of a wrong diagnosis,” Dr. Lewis said.

“We were scared,” Dr. Tam Tam said, then corrected herself: “We were terrified.”

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Ms. Shepherd’s official due date was Aug. 3, but her medical team planned to induce her on July 8, if she made it that far. But at 3:30 a.m. on July 5, Ms. Shepherd went into spontaneous labor, and Baby Oakari was delivered a couple of hours later via cesarean section.

Oakari was a healthy little boy who weighed five pounds at birth. Ms. Shepherd had carried him just short of 36 weeks. It was an incredible outcome: Most women with lupus whose disease inflames the kidneys develop complications and are forced to deliver much earlier, by about 33 weeks.

“She really beat the odds,” Dr. Lewis said.

But she wasn’t quite out of the woods yet.

As soon as Ms. Shepherd and her partner, Mr. Wilson, got their hands on an infant car seat, they took Oakari home. Mr. Wilson was on a few weeks of paternity leave, and Ms. Shepherd continued her dialysis treatments, now three times a week instead of six.

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But in late August, Ms. Shepherd started having chest pain and shortness of breath. She went to the nearest emergency room, where she was diagnosed with cardiomyopathy, a disease of the heart muscle that develops in rare cases after childbirth, during the period known as the fourth trimester, which is fraught with risk for new mothers.

Ms. Shepherd was hospitalized for a few days, and then referred to Dr. Evelina Grayver, director of women’s heart health at Katz Women’s Hospital for a follow-up. But when she arrived on Long Island for her appointment in early October, Oakari in tow, she was breathing rapidly and gasping for air.

“My nurse, Paula, ran into my office and said, ‘There’s a new patient, and she doesn’t look good — she’s huffing and puffing,’” Dr. Grayver said.

Oakari had started crying, so Dr. Grayver scooped him up and held him while she examined Ms. Shepherd, who was struggling to breathe, and gave her oxygen.

“She told me she thought she just needed to go to dialysis, but I told her, ‘I think you’re going into heart failure,’” Dr. Grayver said.

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Dr. Grayver called the transport services to take Ms. Shepherd to the emergency department, while Ms. Shepherd tried to reach her partner. But Mr. Wilson was on a job several hours away, and Ms. Shepherd’s sister could not get to the hospital right away.

“I was worried she would have to go on a ventilator, but the only thing she was worried about was the baby,” Dr. Grayver said.

Dr. Grayver went down to the emergency department, still holding Oakari. He was fussy, so the emergency nurses warmed a bottle for him, and Dr. Grayver sat herself in a corner and fed the infant.

“Fatimah was in such distress, and she saw the baby took to me, and said, ‘You’re so good with him,’” Dr. Grayver recalled. “So I said, ‘Do you want him to stay with me?’”

And that’s what they did. Ms. Shepherd got started on a nitroglycerin drip, and while a bed was prepared for her in the cardiac intensive care unit, she gave permission for Dr. Grayver to watch the baby until a family member could pick him up.

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Dr. Grayver kept Oakari with her all afternoon, and her nurse practitioner took him whenever a patient came in. Dr. Grayver was preparing to take him home with her when Ms. Shepherd’s sister came to pick him up. “Just between us, I was secretly quite disappointed,” Dr. Grayver said. “He is such a cutie.”

Ms. Shepherd was fortunate. About one-third of patients with postpartum cardiomyopathy get worse, about one-third stay the same and about one-third improve. Ms. Shepherd improved. “I am beyond happy,” Dr. Grayver said.

Oakari is almost 2 now. He is walking — well, when he’s not running — and loves soccer and picture books and other children.

But Ms. Shepherd’s kidney function did not recover after the delivery. For a while, she hoped that a live donor would come forth to give her a kidney. Organs from living donors last longer, and the waiting time for a kidney can be up to five years.

But on Sunday, at 6:40 a.m., Ms. Shepherd got a call from North Shore University Hospital: A kidney from a deceased donor was available, and it was a good match for her. Could she get to the hospital in an hour?

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She did, and by Sunday afternoon, she had a new healthy kidney. It was the ultimate happy ending.

Now she is looking forward to a taking Oakari to swim lessons, and to the many other things she could not do while on dialysis. Most of all, she said, “I want to get my energy back. and play with my son like a normal mom.”

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Boyle Heights blaze choked L.A. with astronomical soot pollution

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Boyle Heights blaze choked L.A. with astronomical soot pollution

The air near the Lineage refrigerated warehouse fire in Boyle Heights carried astronomically high levels of smoke and soot, surpassing some of the worst air pollution during the Los Angeles County fires in January 2025, according to preliminary data from air officials.

The fire spewed thick black smoke for days. From downtown Los Angeles to the San Gabriel Valley, tens of thousands were enveloped in unhealthful levels of smoke, even as some local officials told residents that the air posed no danger.

As the days wore on, worst off were communities nearest the blaze. On June 19, three days after the facility ignited, a temporary air quality monitoring station at Eastman Elementary in unincorporated East Los Angeles measured an extremely hazardous 755 micrograms per cubic meter of fine particles for more than an hour, according to the South Coast Air Quality Management District.

For comparison, a Caltech air monitor in Pasadena recorded about 650 micrograms per cubic meter during the Eaton fire.

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These high levels of fine particles, known as PM 2.5, probably resulted in the surge of residents into local emergency rooms during the fire, according to local health officials. But even now with the smoke gone, people still have not been told what chemicals they were breathing in during the weeklong ordeal.

Michael Jerrett, an environmental health professor at the UCLA Fielding School of Public Health, said his concern is the composition of materials emitted when the building burned.

“These contain many particularly toxic components,” Jerrett said, “and we know little about how these mixtures affect health.”

There is no completely safe level of fine particulate pollution, he noted, meaning higher concentrations are always worse.

During the 2025 L.A. County fires, local air officials announced that several monitors downwind had detected elevated levels of brain-damaging lead and cancer-causing arsenic from toxic paint and construction materials used in older homes.

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The Lineage warehouse, built in 2018, is likely to contain different materials of concern. Thick insulation foam required for a massive refrigeration operation, solar panels and refrigerants were burned, leaving many residents on edge.

Even though three public agencies conducted air monitoring, the picture is still murky.

“[Public officials] are speaking with a lot of confidence but not a lot of information,” said mark! Lopez, a community organizer with East Yard Communities for Environmental Justice. “We’ve gotten in the room with folks to discuss where the gaps lie and where assumptions are being made. And I think they are realizing these agencies supposed to protect our air and our health aren’t as reliable as they thought they were.”

In response to the Boyle Heights fire, the South Coast air district deployed a mobile monitoring vehicle to screen for toxic substances in the community near the fire, according to Nahal Mogharabi, a spokesperson for the air district. It found increased levels of bromine, a chemical commonly found in fire retardant, and chlorine, often released from burning plastic. Both were below short-term health-based exposure thresholds.

Toxic metals, including lead and arsenic, were not elevated, according to air district data.

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“That was the reassuring piece, that they were not picking up any of the metals,” said Dr. Nichole Quick, chief medical advisor for the Los Angeles County Department of Public Health. “But … that smoke is unhealthy. “You don’t want to be breathing it, regardless.”

The U.S. Environmental Protection Agency set up air monitors around the perimeter of the facility to test for toxic air contaminants, has the results and has not made them public. Julia Giarmoleo, an EPA spokesperson, said the monitors did not detect elevated metals, but would not provide a copy of the data without a federal records request.

The Los Angeles Fire Department’s hazardous material team also tested for ammonia, which is used in refrigeration, and hydrogen fluoride, a toxic chemical that could be released by burning lithium-ion batteries and solar panels.

Fire officials previously said they measured low levels of hydrogen fluoride on the second day of the fire. But the department would not answer questions about its air monitoring. It also told a reporter to submit a public records request.

It remains unclear whether any agency has tested for hydrogen cyanide or isocyanates, highly toxic gases that could be released from burning chemical-laden insulating foam inside the building.

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“The real issue is what monitoring has not been done to protect the fence-line community from the air toxics,” said Jane Williams, executive director of California Communities Against Toxics.

Without the EPA or LAFD data, what is known of the smoke’s toxicity rests on the air district’s mobile monitoring.

Jerrett, the UCLA researcher, said that is not ideal for understanding the kind of plume released by the Boyle Heights fire, which rapidly changed direction with the wind.

“This can in some instances lead to levels that look low, but they are resulting from a mismatch between the location of the vehicle and the plume,” he said.

The Boyle Heights blaze, similar to the Eaton and Palisades fires, has revealed the region’s air monitoring can’t always tell people what they’ve been exposed to in a disaster.

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“We do need a better monitoring system in place,” he said.

Local officials are now shifting their focus to the rancid odors from millions of pounds of rotting food in the ruined wing of the warehouse. Decomposing food can release hydrogen sulfide, a toxic gas synonymous with landfills and garbage. Lineage hired contractors who are measuring this noxious gas and other pollution. Their data indicate they have not detected hydrogen sulfide.

As Lineage workers haul the rotting food to local landfills, they are using deodorizing mist and have discussed using shrink wrapping to suppress the stench and minimize issues for nearby homes.

At this point, the odors are believed to be an inconvenience rather than a public health threat, according to Quick, the county medical advisor. She said running air purifiers may help to reduce odors indoors.

“It’s very important for folks to understand that the odors themselves do not indicate any dangerous levels of toxins, mold, bacteria, and so forth,” Quick said. “But the odors are a public nuisance.”

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The air district is still encouraging residents to report odors to its online complaint system or by calling (800) 288-7664.

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After Trump axed federal employees running climate site, thousands crowdfund its comeback

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After Trump axed federal employees running climate site, thousands crowdfund its comeback

Federal employees who were axed during waves of cuts by the Trump administration have fought back against the dismantling of a key climate science website, Climate.gov, and put up a new site, Climate.us, that can now do everything the original did.

The site, with millions of users each year, was known for colorful charts that anyone could freely download and that simplified giant sets of data, such as temperature readings. Now it refers to another page and is no longer being updated.

Daniel Swain, a UC Agriculture & Natural Resources climate scientist, called the resources available at Climate.gov “the most efficacious dollars spent by NOAA on public-facing science, possibly ever.” He has used graphics from the former website on his popular weather blog.

“I am a terrible artist or illustrator. It would be very bad if I had to create those on my own.” Swain said. The website didn’t just make graphics that were beautiful, he said, they were accurate and reliable because of the network of researchers who fact-checked them.

Rebecca Lindsey was the editorial lead and program manager for Climate.gov until February 2025, when her position at the National Oceanic and Atmospheric Administration was eliminated by the Elon Musk-led Department of Government Efficiency, or DOGE. She explained that the online resource was “a bridge between scientists, data and the public.”

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Lindsey and her team have now rebuilt the bridge piece by piece, if just a bit further downstream.

The team is made of the same editorial and technical staff that ran Climate.gov. It’s paid for through a crowdfunding campaign and one large, anonymous donation.

The group has raised some $380,000, about $100,000 of which came in the last week. They also have recruited 80 scientists who are willing to volunteer as subject matter experts and fact checkers. It’s enough to keep the work going through February while they seek more long-term funding.

The first iteration of Climate.us went online in 2025 to keep the last 15 years of work from the government website available. The newest version restores the full function of the previous website.

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For Californians, the timing could be important.

“We’re headed for a very strong El Niño event that will have significant implications for Southern California,” Swain said. “Climate.gov and the scientists behind it did a great job walking people through the last one, and I would expect that’s the case this time as well.”

Climate.gov excelled at tapping into a pool of academic experts to explain what was happening in nearly real time. This allowed the public to see how events such as wildfire, drought or large weather patterns such as El Niño were shaping their lives when they needed the information most. Research from academic institutions, by contrast, can take years to publish results from major natural disasters.

Swain emphasized that cuts to resources that give context to hard-to-interpret data is not just a loss for the research community.

“It’s getting more and more difficult for the American public to access the science and the scientists that their tax dollars have supported for over half a century,” he said.

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With the revival of Climate.us, Swain said he plans to directly use the site and its graphics to keep Californians connected to the world of climate science.

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This Cell Feeds, Grows and Reproduces. And It’s Manmade.

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This Cell Feeds, Grows and Reproduces. And It’s Manmade.

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A SpudCell on a microscope slide

Scientists have long dreamed of discovering the alchemy by which chemicals can be turned into life. On Wednesday, a team at the University of Minnesota announced that it had taken a major step toward that vision.

Blending together dozens of ingredients, the researchers have synthesized simple cells that feed, grow, reproduce and compete with one another for food. If these cells are not yet fully alive, they have most of the hallmarks of life.

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“Life is not binary,” said Kate Adamala, a synthetic biologist who led the research. “That’s why I’m hesitant to call this ‘alive.’ There’s no clear line, as much as we would love it to be.”

Until now, scientists had never mastered the recipe for a cell that can perform so many functions, said John Glass, a synthetic biologist at the J. Craig Venter Institute in La Jolla, Calif., who was not involved in the study.

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“It is dazzling that she has put these things all together,” he said.

Drew Endy, a synthetic biologist at Stanford University, said, “It’s a cell that was built, not born. It’s constructed, but it does what cells do.”

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Dr. Adamala named her creation SpudCell, after its potato-like appearance. Rather than patent it, she and Dr. Endy are organizing a community of scientists to focus on making SpudCells more fully alive and adapting them to new kinds of experiments.

They and their colleagues have founded a nonprofit research organization that Dr. Endy estimates will spend hundreds of millions of dollars on the effort in the next decade. Hundreds of scientists are expected to join.

“We’re going to remember this moment,” said Roseanna Zia, a computational biologist at the University of Missouri who was not involved in the project.

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Dr. Adamala and her colleagues posted a 190-page account of their work online. The research is under review for publication in a scientific journal.

Scientists hope synthetic cells can tell them things about life that natural cells cannot, including such basic questions as how many genes are necessary for a minimal form of life.

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But synthetic cells also might someday be engineered to do things that natural cells can’t, like making new kinds of medicine or drawing large amounts of carbon dioxide from the atmosphere. In theory, engineered SpudCells might produce a vast range of proteins that natural cells cannot be coaxed to make, or even toxic chemicals like rocket fuel.

Now, “we can think about doing chemistry that we’re barely getting our heads around,” Dr. Glass said.

The trouble with life as we know it: mysterious, messy complexity. Our own DNA contains tens of thousands of genes, as well as millions of molecular switches turning those genes on and off. Scientists barely have a clue as to what many of those pieces of DNA are doing. Often a gene that they think they understand turns out to be performing other jobs than scientists expected.

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One way to sidestep this intricacy is to simplify.

In the 1990s, a team led by the late biologist Craig Venter began studying a microbe that had fewer than 1,000 genes. The team, now led by Dr. Glass, went on to strip the microbe’s genome down to 525 essential genes.

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In a 2016 paper, the team reported it didn’t know what a third of those genes were doing. Dr. Glass and his colleagues have spent the last decade trying to solve the puzzle, and they still can’t say what 56 of them do.

“There are still significant tasks that every cell has to do that we don’t know,” Dr. Glass said.

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Other researchers tackled the problem from the opposite direction. Instead of working from the top down, they moved from the bottom up, seeking to combine lifeless molecules to produce a living cell.

Since the 1990s, several labs have bitten off small pieces of this problem. Some of them have perfected recipes to make hollow bubbles from oily molecules. Others have found ways to encapsulate simple genetic molecules inside those bubbles.

But scientists struggled to put these pieces together into more complex systems, let alone something that could be called a cell.

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In recent years, Dr. Adamala took on one of the fundamental challenges: cell division. A natural cell divides with the help of proteins that lock together into a ring anchored to its inner wall. The ring winds itself tighter, pinching the cell in two.

Other proteins act like winches, moving DNA and other molecules into the forming cells, so that they have the ingredients necessary to keep living.

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At first, Dr. Adamala tried building a simpler version of the natural system. But then she decided not to mimic real cells at all.

Biophysicists had found that if they stuck proteins on a membrane, they created pressure that made the membrane bend. Dr. Adamala and her team created bubbles that could snag proteins floating around them. When a bubble collected enough proteins, its surface began bending inward until it popped in two.

While the idea was simple, getting it to work in the lab required a year of experiments. “But once it works, it works,” Dr. Adamala said.

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That success prompted the team to try to build a synthetic cell in its entirety.

The first step was to create a broth of the molecules necessary for a cell to operate. The recipe ultimately included about a hundred kinds of proteins and simple molecules required for crucial chemical reactions, such as making new proteins from genes.

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The researchers also provided their synthetic cell with genes borrowed from a virus and the ubiquitous microbe Escherichia coli. They picked 36 genes for basic jobs like copying DNA.

After mixing these ingredients together into a soup, the scientists added the building blocks of membranes. They spontaneously joined together into bubbles, each engulfing some of the soup.

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Many of these bubbles ended up encasing the right mix of genes, proteins and other molecules, and they started carrying out the chemical reactions seen in real cells.

As the new cells floated in flasks, Dr. Adamala and her colleagues added food. The cells slurped up small molecules through channels on their surfaces.

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The scientists also put in small bubbles loaded with proteins and other molecules that were too big to fit through the channels. By bumping and fusing into one of these bubbles, the cell could feed on the treats inside.

As the cells fed, they grew. And in just a few hours, they were big enough to divide.

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The scientists added a special protein to the flasks, which latched onto the surface of the cells and forced them to bend inward. Once the cells split in two, the pair of new cells kept growing.

Now the SpudCells grew, fed and reproduced. As it turned out, the cells even had a rudimentary ability to evolve.

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Dr. Adamala and her colleagues created a mutant version that bound more tightly to the snack-filled bubbles floating around it. To test it, they created a 50-50 mixture of original and mutant SpudCells.

The cells competed for five generations for food. Eventually the mutants outnumbered the originals, suggesting that they were outcompeting the originals for food.

“That’s the shake-the-ground accomplishment here,” said Dr. Zia. Scientists will be able to put various synthetic cells in competition with one another and rapidly develop more sophisticated ones.

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For all this evidence of life, SpudCell still has some major shortcomings. For starters, it can’t make the molecular factory that produces new proteins, called a ribosome. The cells can carry all the genes they need to build ribosomes, but for some reason the parts don’t come together.

For now, Dr. Adamala and her colleagues have to feed ready-made ribosomes to SpudCells. This solution has an expiration date, though: SpudCells can keep making proteins through five to 10 generations before they fail as their ribosomes become defective.

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“I don’t want to say it dies, but it stops working,” Dr. Adamala said.

When Dr. Adamala showed SpudCell to Dr. Endy last year, he was so awestruck that he decided to help her found Biotic, the nonprofit organization intended to create a community of SpudCell researchers.

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“I’m pouring my life’s work into this,” Dr. Endy said. One of the first tasks for Biotic will be to make it easier for other scientists to create SpudCells.

Dr. Adamala can create a fresh batch of them in her own lab in about a day. But that’s only because she has freezers full of purified proteins and an intimate understanding of each step of her recipe. Biotic expects to offer scientists easier recipes and provide the required ingredients.

Dr. Endy hopes that the open-source tools will encourage scientists to collaborate on building new kinds of SpudCells with more of the defining features of life, such as the ability to make their own ribosomes and to divide indefinitely.

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“It’s completely doable,” said Dr. Glass.

Biotic researchers are already planning their first meeting, in September in Philadelphia. High on their list of priorities will be formalizing plans to safeguard this area of research.

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For now, the synthetic cell can only survive a few generations on a special lab diet. But future versions may be more robust, raising the possibility that someone might someday use SpudCells unethically, perhaps even to make a weapon.

Dr. Endy argues that an open-source research community will be better prepared to prevent that from happening. “We can have these conversations now, as opposed to waiting for somebody else to do it, and then we’re just all reacting,” he said.

Dr. Endy likens SpudCells to a biological version of the Wright flyer, the crude plane that the Wright Brothers used to make the first sustained controlled flight in 1903, ushering in the age of airplanes.

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“The Wright flyer flying for 12 seconds doesn’t get you a 737,” Dr. Endy said. “This is just the beginning.”

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