Tag: congenital diseases

Zika Virus Infection Fast Facts | CNN

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CNN
 — 

Here’s a look at Zika virus, an illness spread through mosquito bites that can cause birth defects and other neurological defects.

Sources: Centers for Disease Control and Prevention (CDC), World Health Organization (WHO) and CNN

Zika virus is a flavivirus, part of the same family as yellow fever, West Nile, chikungunya and dengue fever.

Zika is primarily transmitted through the bite of an infected female Aedes aegypti mosquito. It becomes infected from biting an infected human and then transmits the virus to another person. The Aedes aegypti mosquito is an aggressive species, active day and night and usually bites when it is light out. The virus can be transmitted from a pregnant woman to her fetus, through sexual contact, blood transfusion or by needle.

The FDA approved the first human trial of a Zika vaccine in June 2016. As of May 2022, there is still no available vaccine or medication.

Cases including confirmed, probable or suspected cases of Zika in US states and territories updated by the CDC.

Most people infected with Zika virus won’t have symptoms. If there are symptoms, they will last for a few days to a week.

Fever, rash, joint pain and conjunctivitis (red eyes) are the most common symptoms. Some patients may also experience muscle pain or headaches.

Zika virus infection during pregnancy can cause microcephaly, a neurological disorder that results in babies being born with abnormally small heads. Microcephaly can cause severe developmental issues and sometimes death. A Zika infection may cause other birth defects, including eye problems, hearing loss and impaired growth. Miscarriage can also occur.

An August 2018 report published by the CDC estimates that nearly one in seven babies born to women infected with the Zika virus while pregnant had one or more health problems possibly caused by the virus, including microcephaly.

According to the CDC, there is no evidence that previous infection will affect future pregnancies.

(Sources: WHO, CDC and CNN)

1947 – The Zika virus is first discovered in a monkey by scientists studying yellow fever in Uganda’s Zika forest.

1948 – The virus is isolated from Aedes africanus mosquito samples in the Zika forest.

1964 – First active case of Zika virus found in humans. While researchers had found antibodies in the blood of people in both Uganda and in Tanzania as far back as 1952, this is the first known case of the active virus in humans. The infected man developed a pinkish rash over most of his body but reported the illness as “mild,” with none of the pain associated with dengue and chikungunya.

1960s-1980s – A small number of countries in West Africa and Asia find Zika in mosquitoes, and isolated, rare cases are reported in humans.

April-July 2007 – The first major outbreak in humans occurs on Yap Island, Federated States of Micronesia. Of the suspected 185 cases reported, 49 are confirmed, and 59 are considered probable. There are an additional 77 suspected cases. No deaths are reported.

2008 – Two American researchers studying in Senegal become ill with the Zika virus after returning to the United States. Subsequently, one of the researchers transmits the virus to his wife.

2013-2014 – A large outbreak of Zika occurs in French Polynesia, with about 32,000 suspected cases. There are also outbreaks in the Pacific Islands during this time. An uptick in cases of Guillain-Barré Syndrome during the same period suggests a possible link between the Zika virus and the rare neurological syndrome. However, it was not proven because the islands were also experiencing an outbreak of dengue fever at the time.

March 2015 – Brazil alerts the WHO to an illness with skin rash that is present in the northeastern region of the country. From February 2015 to April 29, 2015, nearly 7,000 cases of illness with a skin rash are reported. Later in the month, Brazil provides additional information to WHO on the illnesses.

April 29, 2015 – A state laboratory in Brazil informs the WHO that preliminary samples have tested positive for the Zika virus.

May 7, 2015 – The outbreak of the Zika virus in Brazil prompts the WHO and the Pan American Health Organization (PAHO) to issue an epidemiological alert.

October 30, 2015 – Brazil reports an increase in the cases of microcephaly, babies born with abnormally small heads: 54 cases between August and October 30.

November 11, 2015 – Brazil declares a national public health emergency as the number of newborns with microcephaly continues to rise.

November 27, 2015 – Brazil reports it is examining 739 cases of microcephaly.

November 28, 2015 – Brazil reports three deaths from Zika infection: two adults and one newborn.

January 15 and 22, 2016 – The CDC advises all pregnant women or those trying to become pregnant to postpone travel or consult their physicians prior to traveling to any of the countries where Zika is active.

February 2016 – The CDC reports Zika virus in brain tissue samples from two Brazilian babies who died within a day of birth, as well as in fetal tissue from two miscarriages providing the first proof of a potential connection between Zika and the rising number of birth defects, stillbirths and miscarriages in mothers infected with the virus.

February 1, 2016 – The WHO declares Zika a Public Health Emergency of International Concern due to the increase of neurological disorders, such as microcephaly, in areas of French Polynesia and Brazil.

February 8, 2016 – The CDC elevates its Emergency Operations Center for Zika to Level 1, the highest level of response at the CDC.

February 26, 2016 – Amid indications that the mosquito-borne Zika virus is causing microcephaly in newborns, the CDC advises pregnant women to “consider not going” to the Olympics in Rio de Janeiro. The CDC later strengthens the advisory, telling pregnant women, “Do not go to the Olympics.”

March 4, 2016 – The US Olympic Committee announces the formation of an infectious disease advisory group to help the USOC establish “best practices regarding the mitigation, assessment and management of infectious disease, paying particular attention to how issues may affect athletes and staff participating in the upcoming Olympic and Paralympic Games.”

April 13, 2016 – During a press briefing, CDC Director Thomas Frieden said, “It is now clear the CDC has concluded that Zika does cause microcephaly. This confirmation is based on a thorough review of the best scientific evidence conducted by CDC and other experts in maternal and fetal health and mosquito-borne diseases.”

May 27, 2016 – More than 100 prominent doctors and scientists sign an open letter to WHO Director General Margaret Chan, calling for the summer Olympic Games in Rio de Janeiro to be postponed or moved “in the name of public health” due to the widening Zika outbreak in Brazil.

July 8, 2016 – Health officials in Utah report the first Zika-related death in the continental United States.

August 1, 2016 – Pregnant women and their partners are advised by the CDC not to visit the Miami neighborhood of Wynwood as four cases of the disease have been reported in the small community and local mosquitoes are believed to be spreading the infection.

September 19, 2016 – The CDC announces that it has successfully reduced the population of Zika-carrying mosquitoes in Wynwood and lifts its advisory against travel to the community.

November 18, 2016 – The WHO declares that the Zika virus outbreak is no longer a public health emergency, shifting the focus to long-term plans to research the disease and birth defects linked to the virus.

November 28, 2016 – Health officials announce Texas has become the second state in the continental United States to confirm a locally transmitted case of Zika virus.

September 29, 2017 – The CDC deactivates its emergency response for Zika virus, which was activated in January 2016.

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FDA advisers narrowly vote in favor of experimental gene therapy for rare muscle disease | CNN

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CNN
 — 

Most parents wouldn’t be thrilled with the idea of their kids getting hooked up to an IV bag filled with trillions of viruses.

But for Melanie Hennick, whose son, Connor, has Duchenne muscular dystrophy, it was an opportunity she hoped would change his life.

“We knew this wasn’t a cure,” Hennick said. “But it was a chance.”

Connor is one of just dozens of kids to have received SRP-9001, an experimental gene therapy that aims to slow or stop the progression of Duchenne muscular dystrophy, or DMD. Current treatments for the disease – which primarily affects boys because of the way it’s inherited – include steroids and, later, heart drugs. But none stop it.

SRP-9001 uses viruses to ferry a copy of a gene to muscles to help make up for one that’s causing the disease. Hennick and many other parents like her advocated for the treatment’s accelerated approval Friday in a meeting of outside advisers to the US Food and Drug Administration.

The advisers voted 8-6 in favor of approving the treatment, and the FDA will now decide whether to follow their advice.

“The decision the FDA has to make doesn’t just affect the patients in study 301 [an ongoing confirmatory trial that Sarepta is running]; it affects the entire field of drug development for Duchenne,” said Dr. Caleb Alexander, a professor of epidemiology and medicine in the Bloomberg School of Public Health at Johns Hopkins University, who voted against recommending approval. “The totality of evidence … simply doesn’t rise to the threshold that’s required for accelerated approval.”

Dr. Raymond Roos, a neurology professor at the University of Chicago Medical Center, voted in favor. “The downside of the gene therapy here is relatively small compared to whether it really helps the patient, and for this reason, I voted yes,” he said.

Dr. Peter Marks, director of the FDA’s Center for Biologics Evaluation and Research, said his agency will take the recommendation and “do something that we have to do every day at FDA. … We have to manage through the uncertainty here.”

The FDA’s decision, expected by the end of the month, will have implications not just for families like Connor’s but for how the agency regulateths treatments like this one more broadly: It would be the first of its kind of medicine – one-time treatments delivering a gene to try to fix a disease – to get accelerated approval, a faster track through the regulatory process. Its approval would set a precedent for other drugs like this based on so-called surrogate endpoints, a measure of what the drug does in the body, before further clinical evidence is available.

“Approval of a gene therapy for Duchenne muscular dystrophy will be huge,” said Jeffrey Chamberlain, a professor at the University of Washington School of Medicine who helped pioneer gene therapy approaches for the disease. “This, I think, will spur further research and further development of gene therapies for other diseases.”

DMD patients don’t have a lot of time to wait. Kids with Duchenne typically lose the ability to walk before they’re teenagers and often don’t live well into their 30s, Chamberlain said. He’s not directly involved with SRP-9001, which is being developed by Sarepta Therapeutics, and is on the scientific advisory board for another company working on DMD gene therapies, Solid Biosciences.

“Gene therapy appears to be a really good approach to try to treat this disease, because it’s a genetic disease,” Chamberlain said. “The cause of the disease is a mutation in a single gene.”

That gene is responsible for the production of dystrophin, a protein key to the structure of muscle cells.

“It’s kind of like the two-by-fours that make up your house,” Chamberlain said. “It’s really important for just holding everything together.”

SRP-9001, invented at Nationwide Children’s Hospital in Columbus, Ohio, before being licensed for development by Sarepta, delivers a miniaturized version of the dystrophin gene to cells, aiming to help them make a version of the muscle-preserving protein.

In a key clinical trial, the therapy appeared to do that. But it didn’t meet another main goal: showing a benefit on a measure of muscle function, complicating SRP-9001’s path through the FDA.

Sarepta blamed the outcome on an imbalance in how the trial separated patients into the placebo and treatment groups. But key FDA reviewers appear unconvinced.

“The clinical studies conducted to date do not provide unambiguous evidence that SRP-9001 is likely beneficial for ambulatory patients with DMD,” agency reviewers wrote in briefing documents released ahead of Friday’s meeting, referring to patients who can still walk – the group who will initially be eligible for the treatment if it gets approved.

Family after family who participated in Sarepta’s trials, like the Hennicks, disagree with the reviewers. They say they believe that the treatment has helped keep their kids walking and running in ways they never would have without it.

“It’s really miraculous,” said Nate Plasman, whose son Andrew got SRP-9001 as part of the trial in January 2019, at age 4.

Sara, left, Andrew and Nate Plasman on the day he was dosed in the trial in January 2019.

Andrew was away from school for more than two months when he got the experimental therapy, Plasman said, and when he returned, “his teachers at the preschool were blown away,” he recalled. “They’re like, ‘Who is this kid?’ He’s running. He’s jumping. He’s pedaling the tricycle. He’s getting up and down off the ground” – all things he couldn’t do as well before the therapy.

Marit Sivertson, mom to 9-year-old Brecken, agrees.

“We’ve seen the incredible changes with our son,” she said. “He’s not just walking around. He’s running; he’s swimming; he’s diving. He’s truly living the life that every 9-year-old boy ought to be living.”

Dr. Jerry Mendell of Nationwide Children's Hospital in Ohio, who developed the gene therapy, left, with Brecken Kinney.

Sivertson and Plasman also spoke at Friday’s meeting. Their goal isn’t to secure the therapy for their own kids; because it’s designed as a one-time treatment, they wouldn’t take it again. They say they’re speaking up on behalf of children who are still waiting.

That wait is especially painful for Daniel and Lindsey Flessner, who have two sons with DMD. Their 5-year-old son, Mason, is in the SRP-9001 clinical trial. Their 2-year-old, Dawson, is still too young.

“With every trip, every fall, every time he stands up by walking up his legs using his hands to help stabilize him, it just keeps chipping away at us,” Flessner said. “It’s very painful as the parents watching your children struggling knowing all you can do is wait, when waiting is what you don’t have time for.”

Lindsey and Daniel Flessner's sons, Mason and Dawson, both have DMD.

In addition to questions about how well the treatment works, the FDA reviewers raised concerns about safety, particularly “related to the possibility of administering an ineffective gene therapy.”

The reviewers focused on opportunity cost: Because of the viruses used to deliver the gene, patients can develop an immune response that could render future doses ineffective.

Chamberlain said work is underway to find ways to be able to administer more doses, if needed, but it’s currently a one-and-done treatment.

For now, he thinks this approach is the best hope for DMD patients.

“It’s not perfect,” he acknowledged. “It’s not a complete cure, but from what I can gauge from the clinical results that have been released by Sarepta and some of the other companies, I think the micro-dystrophin gene therapy is working better than any other drug that’s been tried for Duchenne muscular dystrophy.”

It’s unclear how long the effects will last; Sarepta is continuing trials, and a confirmatory study would be required as part of accelerated approval. Sarepta has proposed a trial that it’s already running to satisfy that requirement, with results expected later this year.

For families facing DMD, there’s an opportunity cost to waiting, too. In its briefing documents for the FDA meeting, Sarepta estimated that accelerated approval would speed up broad access to SRP-9001 by at least a year, a time in which about 400 boys could lose the ability to walk and another 400, whose disease is more advanced, would die.

Melanie Hennick said Connor was admitted to the trial just weeks before he’d have aged out, at 8 years old. She said she believes the therapy is the reason Connor’s doing so well.

“We had the opportunity to see Connor grow as an 8-, 9-, 10-, 11- and 12-year-old with more capacity than we ever dreamed,” she said. “He climbs stairs unaided; he runs around; he plays football; he plays hockey; he plays on a baseball team. … Those are things that we never thought we would be able to see him do, especially at 12.”

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More people with Down syndrome are living longer, but medical systems aren’t keeping up | CNN

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Montrose, Missouri
KFF
 — 

It took Samantha Lesmeister’s family four months to find a medical professional who could see that she was struggling with something more than her Down syndrome.

The young woman, known as Sammee, had become unusually sad and lethargic after falling in the shower and hitting her head. She lost her limited ability to speak, stopped laughing, and no longer wanted to leave the house.

General-practice doctors and a neurologist said such mental deterioration was typical for a person with Down syndrome entering adulthood, recalled her mother, Marilyn Lesmeister. They said nothing could be done.

The family didn’t buy it.

Marilyn researched online and learned the University of Kansas Health System has a special medical clinic for adults with Down syndrome. Most other Down syndrome programs nationwide focus on children, even though many people with the condition now live into middle age and often develop health problems typically associated with seniors. And most of the clinics that focus on adults are in urban areas, making access difficult for many rural patients.

The clinic Marilyn found is in Kansas City, Kansas, 80 miles northwest of the family’s cattle farm in central Missouri. She made an appointment for her daughter and drove up.

The program’s leader, nurse practitioner Moya Peterson, carefully examined Sammee Lesmeister and ordered more tests.

“She reassured me that, ‘Mom, you’re right. Something’s wrong with your daughter,’” Marilyn Lesmeister said.

With the help of a second neurologist, Peterson determined Sammee Lesmeister had suffered a traumatic brain injury when she hit her head. Since that diagnosis about nine years ago, she has regained much of her strength and spirit with the help of therapy and steady support.

Sammee, now 27, can again speak a few words, including “hi,” “bye,” and “love you.” She smiles and laughs. She likes to go out into her rural community, where she helps choose meals at restaurants, attends horse-riding sessions at a stable, and folds linens at a nursing home.

Without Peterson’s insight and encouragement, the family likely would have given up on Sammee’s recovery. “She probably would have continued to wither within herself,” her mother said. “I think she would have been a stay-at-home person and a recluse.”

The Lesmeisters wish Peterson’s program wasn’t such a rarity. A directory published by the Global Down Syndrome Foundation lists just 15 medical programs nationwide that are housed outside of children’s hospitals and that accept Down syndrome patients who are 30 or older.

The United States had about three times as many adults with the condition by 2016 as it did in 1970. That’s mainly because children born with it are no longer denied lifesaving care, including surgeries to correct birth defects.

Adults with Down syndrome often develop chronic health problems, such as severe sleep apnea, digestive disorders, thyroid conditions, and obesity. Many develop Alzheimer’s disease in middle age. Researchers suspect this is related to extra copies of genes that cause overproduction of proteins, which build up in the brain.

“Taking care of kids is a whole different ballgame from taking care of adults,” said Peterson, the University of Kansas nurse practitioner.

Sammee Lesmeister is an example of the trend toward longer life spans. If she’d been born two generations ago, she probably would have died in childhood.

She had a hole in a wall of her heart, as do about half of babies with Down syndrome. Surgeons can repair those dangerous defects, but in the past, doctors advised most families to forgo the operations, or said the children didn’t qualify. Many people with Down syndrome also were denied care for serious breathing issues, digestive problems, or other chronic conditions. People with disabilities were often institutionalized. Many were sterilized without their consent.

Such mistreatment eased from the 1960s into the 1980s, as people with disabilities stood up for their rights, medical ethics progressed, and courts declared it illegal to withhold care. “Those landmark rulings sealed the deal: Children with Down syndrome have the right to the same lifesaving treatment that any other child would deserve,” said Brian Skotko, a Harvard University medical geneticist who leads Massachusetts General Hospital’s Down Syndrome Program.

The median life expectancy for a baby born in the U.S. with Down syndrome jumped from about four years in 1950 to 58 years in the 2010s, according to a recent report from Skotko and other researchers. In 1950, fewer than 50,000 Americans were living with Down syndrome. By 2017, that number topped 217,000, including tens of thousands of people in middle age or beyond.

The population is expected to continue growing, the report says. A few thousand pregnant women a year now choose abortions after learning they’re carrying fetuses with Down syndrome. But those reductions are offset by the increasing number of women becoming pregnant in their late 30s or 40s, when they are more likely to give birth to a baby with Down syndrome.

Skotko said the medical system has not kept up with the extraordinary increase in the number of adults with Down syndrome. Many medical students learn about the condition only while training to treat pediatric patients, he said.

Few patients can travel to specialized clinics like Skotko’s program in Boston. To help those who can’t, he founded an online service, Down Syndrome Clinic to You, which helps families and medical practitioners understand the complications and possible treatments.

Charlotte Woodward, who has Down syndrome, is a prominent advocate for improved care. She counts herself among the tens of thousands of adults with the condition who likely would have died years ago without proper treatment. Woodward, 33, of Fairfax, Virginia, had four heart surgeries as a child and then a heart transplant in her 20s.

Woodward, who is an education program associate for the National Down Syndrome Society, has campaigned to end discrimination against people with disabilities who need organ transplants.

She said her primary care doctor is excellent. But she has felt treated like a child by other health care providers, who have spoken to her parents instead of to her during appointments.

She said many general-practice doctors seem to have little knowledge about adults with Down syndrome. “That’s something that should change,” she said. “It shouldn’t just be pediatricians that are aware of these things.”

Woodward said adults with the condition should not be expected to seek care at programs housed in children’s hospitals. She said the country should set up more specialized clinics and finance more research into health problems that affect people with disabilities as they age. “This is really an issue of civil rights,” she said.

Advocates and clinicians say it’s crucial for health care providers to communicate as much as possible with patients who have disabilities. That can lead to long appointments, said Brian Chicoine, a family practice physician who leads the Adult Down Syndrome Center of Advocate Aurora Health in Park Ridge, Illinois, near Chicago.

“It’s very important to us that we include the individuals with Down syndrome in their care,” he said. “If you’re doing that, you have to take your time. You have to explain things. You have to let them process. You have to let them answer. All of that takes more time.”

Time costs money, which Peterson believes is why many hospital systems don’t set up specialized clinics like the ones she and Chicoine run.

Peterson’s methodical approach was evident as she saw new patients on a recent afternoon at her Kansas City clinic. She often spends an hour on each initial appointment, speaking directly to patients and giving them a chance to share their thoughts, even if their vocabularies are limited.

Her patients that day included Christopher Yeo, 44, who lives 100 miles away in the small town of Hartford, Kansas. Yeo had become unable to swallow solid food, and he’d lost 45 pounds over about 1½ years. He complained to his mother, Mandi Nance, that something “tickled” in his chest.

During his exam, he lifted his shirt for Peterson, revealing the scar where he’d had heart surgery as a baby. He grimaced, pointed to his chest, and repeatedly said the word “gas.”

Peterson looked Yeo in the eye as she asked him and his mother about his discomfort.

The nurse practitioner takes seriously any such complaints from her patients. “If they say it hurts, I listen,” she said. “They’re not going to tell you about it until it hurts bad.”

Nurse practitioner Moya Peterson speaks to Christopher Yeo of Hartford, Kansas. Peterson leads an rare clinic for adults with Down syndrome.

Yeo’s mother had taken him to a cardiologist and other specialists, but none had determined what was wrong.

Peterson asked numerous questions. When does Yeo’s discomfort seem to crop up? Could it be related to what he eats? How is his sleep? What are his stools like?

After his appointment, Peterson referred Yeo to a cardiologist who specializes in adults with congenital heart problems. She ordered a swallowing test, in which Yeo would drink a special liquid that appears on scans as it goes down. And she recommended a test for Celiac disease, an autoimmune disorder that interferes with digestion and is common in people with Down syndrome. No one had previously told Nance about the risk.

Nance, who is a registered nurse, said afterward that she has no idea what the future holds for their family. But she was struck by the patience and attention Peterson and other clinic staff members gave to her son. Such treatment is rare, she said. “I feel like it’s a godsend. I do,” she said. “I feel like it’s an answered prayer.”

Peterson serves as the primary care provider for some of her patients with Down syndrome. But for many others, especially those who live far away, she is someone to consult when complications arise. That’s how the Lesmeisters use her clinic.

Mom Marilyn is optimistic Sammee can live a fulfilling life in their community for years to come. “Some people have said I need to put her in a home. And I’m like, ‘What do you mean?’ And they say, ‘You know ― a home,’” she said. “I’m like, ‘She’s in a home. Our home.’”

Sammee’s sister, who lives in Texas, has agreed to take her in when their parents become too old to care for her.

Marilyn’s voice cracked with emotion as she expressed her gratitude for the help they have received and her hopes for Sammee’s future.

“I just want her to be taken care of and loved like I love her,” she said. “I want her to be taken care of like a person, and not a condition.”

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How human gene editing is moving on after the CRISPR baby scandal | CNN

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London
CNN
 — 

For most of her life, Victoria Gray, a 37-year-old mother of four from Mississippi, had experienced excruciating bouts of pain.

Born with the blood disorder sickle cell disease, lengthy hospital stays and debilitating fatigue disrupted her childhood, forcing her to quit pursuing a college nursing degree and take potent and addictive painkillers.

“The pain I would feel in my body was like being struck by lightning and hit by a freight train all at once,” she said this week at the Third International Summit on Human Genome Editing in London.

In 2019, she received an experimental treatment for the inherited disease that used the gene-editing technique CRISPR-Cas9, which allowed doctors to make very precise changes to her DNA. While the procedure itself was grueling and took seven to eight months to fully recover from, she said it has transformed her life.

“The feeling is amazing. I really feel that I’m cured now,” Gray said. “Because I no longer have to face the battles that I faced on a day-to-day (basis). I came from having to have an in-home caregiver to help me take baths, clean my house and care for my children. Now I do all those things on my own.”

She’s now able to enjoy a life she once felt was passing her by. She holds down a full-time job as a Walmart cashier, and she’s able to attend her children’s football games and cheerleading events and enjoy family outings. “The life I felt I was just existing in I’m now thriving in,” she said.

Gray shared her experience with doctors, scientists, patient advocates and bioethicists who gathered in London for the human genome editing summit, at which participants reported on advances made in the field and debated the thorny ethical issues posed by the cutting-edge technology.

“I’m here really to be a light because there’s mixed feelings about gene editing. And I think people can see the positive result of it. You know that a person who was once suffering in life, was miserable, now is able to be a part of life and enjoy it,” Gray told CNN.

Gray’s uplifting story, which received a standing ovation from the audience, stood in contrast to a presentation made the last time the conference was held, in Hong Kong in 2018, when Chinese doctor He Jiankui stunned his peers and the world with the revelation that he had created the world’s first gene-edited babies.

The two girls grew from embryos He had modified using CRISPR-Cas9, which he said would make them resistant to HIV. His work was widely condemned by the scientific community, which decried the experiment as medically unnecessary and ethically irresponsible. He received a three-year jail sentence in 2019.

Questions about the baby scandal still linger more than four years later, and after being recently released from prison, He is reportedly seeking to continue his work. China has tightened its regulation of experimental biomedical research since 2018, but it hasn’t gone far enough, said Joy Zhang, a medical sociologist at the University of Kent in the United Kingdom.

“Ethical governance in practice is still confined to traditional medical, scientific, as well as educational, establishments. The new measures fail to directly address how privately funded research and other … ventures will be monitored,” Zhang said at the conference.

Ethically questionable experimental research isn’t an issue confined to China, said Robin Lovell-Badge, head of the Laboratory of Stem Cell Biology and Developmental Genetics at the Francis Crick Institute in London, who chaired the 2018 Hong Kong conference session in which He attempted to defend his work.

“(He Jiankui) is not the only concern in this area. One of our big concerns I always have is the possibility that there will be rogue companies, rogue scientists setting up to do genome editing in an inappropriate way,” Lovell-Badge said on Monday at the conference.

Gray shared her story at Monday's conference.

While the CRISPR baby scandal tarnished the technology’s reputation, CRISPR-Cas9 and related techniques have made a major impact on biomedical research, and two scientists behind the tool — Emmanuelle Charpentier and Jennifer A. Doudna — won a Nobel prize for their work in 2020.

“Clinical trial results demonstrate that CRISPR is safe, and it’s effective for treating and curing human disease — an extraordinary advance given the technology is only 10 years old,” Doudna said at the conference in a video address. “It’s important with a powerful technology like this to grapple with the challenges of responsible use.”

In addition to the sickle cell trial that includes Gray, clinical trials are also underway to test the safety of gene editing in treating several other conditions, including a related blood disorder called beta thalassemia; leber congenital amaurosis, which is a form of inherited childhood blindness; blood cancers such as leukemia and lymphoma; type 1 diabetes; and HIV/AIDS.

DNA acts as a instruction manual for life on our planet, and CRISPR-Cas9 can target sites in plant and animal cells using guide RNA to get the Cas-9 enzyme to a more precise spot on a strand of DNA. This allows scientists to change DNA by knocking out a particular gene or inserting new genetic material at a predetermined site in the strand.

People with sickle cell disease have abnormal hemoglobin in red blood cells that can cause them to get hard and sticky, clogging blood flow in small vessels.

In the trial that Gray was part of, doctors increased the production of a different kind of hemoglobin, known as fetal hemoglobin, which makes it harder for cells to sickle and stick together. The process is invasive and involves removing premature cells from the bone marrow and modifying them — by using CRISPR-Cas9 in the lab — to eventually produce fetal hemoglobin. The patient has to undergo a round of chemotherapy before receiving the gene-edited cells to ensure the body doesn’t reject them.

The conference also shed light on new, more sophisticated gene-editing techniques, such as prime editing and base editing, which recently was used to modify immune cells and successfully treat a teen with treatment-resistant leukemia.

These next generation techniques will allow humans “to have some say in the sequence of our genomes so we are no longer so beholden to the misspellings in our DNA,” said David Liu, the Richard Merkin professor and director of the Merkin Institute of Transformative Technologies in Healthcare at the Broad Institute of MIT and Harvard University.

The gene therapy trials currently underway involve treating people who were born with a certain disease or condition by altering non-reproductive cells in what’s known as somatic gene editing.

The next frontier — many would say red line — is heritable gene editing: altering the genetic material in human sperm, eggs or embryos so that it can be safely passed onto the next generation. The goal would be to prevent babies from inheriting genetic diseases.

A researcher handles a petri dish while observing a CRISPR/Cas9 process through a stereomicroscope at the Max-Delbrueck-Centre for Molecular Medicine in 2018.

“It’s a very different set of ethical trade-offs when you’re not a treating disease in an existing individual but you’re in fact preventing an individual yet to be born from suffering from a disease. That’s a very different set of considerations,” said George Daley, Caroline Shields Walker Professor of Medicine and dean of the faculty of medicine at Harvard Medical School.

In a statement released at the end of the conference, the organizers said “heritable human genome editing remains unacceptable at this time.”

They added that public discussion and policy debates should continue and were important for resolving whether this technology should be used.

The hope offered by gene therapy is creating fresh ethical storms — primarily over who gets access to such treatments. The therapy Gray received, which is expected to soon receive regulatory approval, is likely to cost more than $2 million per person, putting it out of reach for many who need it in the United States and in low-income countries.

“If we want to be serious about equitable access to these kinds of therapies, we have to start talking early on about ways to develop them and make them available and make them cost effective and sustainable,” said Alta Charo, the Warren P. Knowles Professor Emerita of Law and Bioethics at the University of Wisconsin at Madison.

Researchers want to develop CRISPR therapies that can be delivered though an injection rather than the chemotherapy and invasive bone marrow transplant Gray went through.

Worldwide, more than 300,000 children are born with sickle cell disease every year, over 75% of whom live in sub-Saharan Africa, where screening programs and treatment options are limited.

Even relatively affordable drugs to treat sickle cell disease, such as hydroxyurea, don’t reach everyone who needs them in India, said Gautam Dongre, the secretary of the National Alliance of Sickle Cell Organizations in India and father of two children with sickle cell disease.

“After 40 years if these drugs aren’t reachable for the common people, then what about gene therapy?” Dongre asked at the conference.

Julie Makani, an associate professor in the department of haematology and blood transfusion at Muhimbili University of Health and Allied Sciences in Tanzania, said more genomic research should take place in Africa.

“The ultimate thing for me, particularly as a physician scientist, is not just discovery, but also seeing the application of knowledge…into (an) improvement in health,” Makani said.

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Elite athletes with genetic heart disease can safely return to play with diagnosis and treatment, early study suggests | CNN

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CNN
 — 

In a new study, most elite athletes with a diagnosed genetic heart disease did not experience serious or fatal symptoms of their condition, such as sudden cardiac death. The research suggests it can be “feasible” and “safe” for athletes to continue to participate in their sport.

Among a sample of 76 elite athletes with a genetic heart disease who had competed or are still competing in either Division I university or professional sports, 73 out of the 76 did not experience a cardiac event triggered by their disease during the study period, according to researchers behind a late-breaking clinical trial presented Monday at the American College of Cardiology’s Annual Scientific Session Together With the World Congress of Cardiology.

Among those elite athletes with a genetic heart disease, 40 of them – 52% – were asymptomatic, the study abstract finds.

Over the years, researchers have become more aware of alarming reports about elite athletes experiencing heart problems, or even suddenly collapsing during games.

“For athletes with genetic heart conditions, and I would add non-athletes, the tragedies occur when we don’t know of their condition,” said Dr. Michael Ackerman, a genetic cardiologist at Mayo Clinic in Rochester, Minnesota, who was a senior author of the new research. “When we know of their condition, and we assess the risk carefully and we treat it well, these athletes and non-athletes, they can expect to live and thrive despite their condition.”

The new research has not yet been published in a peer-reviewed journal, but the findings suggest that many athletes with a genetic heart disease can decide with their health care professionals on whether to continue competing in their sport and how to do so safely, instead of being automatically disqualified due to their health conditions.

“In sports, historically, we’ve been paternalistic and de-emphasize patient preference and risk tolerance, but we know that athletes come from all walks of life. They are intelligent and when there’s scientific uncertainty, their values should be incorporated in medical decision-making,” Dr. J. Sawalla Guseh, cardiologist at Massachusetts General Hospital, who was not involved in the new study, said during Monday’s scientific session.

“Shared decision-making when done well can have very favorable outcomes,” he said.

Elite basketball, hockey, soccer and football players, were among the 76 athletes included in the new study, conducted by researchers at Mayo Clinic and other institutions in the United States. They wrote in their study abstract that this is the first study to their knowledge describing the experience of athletes competing at the NCAA Division I level or in professional sports with a known genetic heart disease that puts them at risk of sudden cardiac death.

The athletes in the study were cleared for return-to-play at either a NCAA Division I school or at the professional level. They were studied over an average of seven years, and all had been diagnosed with a genetic heart disease in the past 20 years, being treated at either Mayo Clinic, Morristown Medical Center, Massachusetts General Hospital or Atrium Health Sports Cardiology Center.

“Only three of them had a breakthrough cardiac event, which means after they were diagnosed and treated, they were still having an event,” said Katherine Martinez, an undergraduate student at Loyola University in Baltimore, who helped conduct the research as an intern in the Mayo Clinic’s Windland Smith Rice Sudden Death Genomics Laboratory.

Fainting was the most common event, and one athlete received a shock with an implantable cardioverter defibrillator, or ICD. None of the athletes died.

“The majority of these athletes went on to continue their career with no events at all,” Martinez said. But most of the athletes in the study – 55 of them, or 72% – were initially disqualified from competing by their primary provider or institution after their diagnosis. Most ultimately opted to return to play with no restrictions after undergoing comprehensive clinical evaluations and talking with their doctors.

While each sports league has its own set of rules, historically, some people diagnosed with a genetic heart disease that puts them at an increased risk for sudden cardiac death have been restricted from competitive sports, the researchers wrote in their study abstract.

“Just because you were given this diagnosis, doesn’t mean that your life, your career, the future that you see for yourself is over, but taking a second opinion from an expert who knows what they’re doing and is comfortable with shared decision-making is the next step,” said Martinez, who worked on the new research alongside her father, Dr. Matthew Martinez, director of Atlantic Health System Sports Cardiology at Morristown Medical Center and an author of the new research.

Regarding the new study, “the take-home message is, if you have one of these findings, seek out an expert who’s going to help you identify a safe exercise plan for you and determine what level you can continue to safely participate in,” he said. “This is the next best step – the next evolution – of how we manage athletes with genetic heart disease.”

Leaving their sport due to a genetic heart disease can be “very destructive” for athletes who have devoted their lives to excelling in competitions, said Dr. Lior Jankelson, director of the Inherited Arrhythmia Program at NYU Langone Heart in New York, who was not involved in the new research.

Yet he added that these athletes still need to consult with their doctors and be watched closely because some genetic diseases could be more likely to cause a serious cardiac event than others.

The new study highlights that “the majority of athletes with genetic heart disease could probably – after careful, meticulous expert risk-stratification and care strategy – participate in sports,” Jankelson said. “But at the same time, this is exactly the reason why these patients should be cared only in high-expertise genetic cardiology clinics, because there are other conditions that are genetic, that could respond very adversely to sports, and have a much higher risk profile of developing an arrhythmia during intense activity.”

Separately, the NCAA Sports Science Institute notes on its website, “Though many student-athletes with heart conditions can live active lives and not experience health-related problems, sudden fatality from a heart condition remains the leading medical cause of death in college athletes.”

For athletes with a genetic heart disease, their symptoms and their family history of cardiac events should be considered when determining their risks, said Dr. Jayne Morgan, a cardiologist with Piedmont Healthcare in Atlanta, who was not involved in the new research.

“Certainly, there is concern with elite athletes competing and whether or not they are being screened appropriately,” Morgan said. But she added that the new research offers “some understanding” to the mental health implications for athletes with a genetic heart disease who may be required to step away from a competitive sport that they love.

“This study, I think, begins to go a long way in identifying that we may not need to pull the trigger so quickly and have athletes step away from something that they love,” Morgan said.

The new study is “timely” given the recent national attention on athletes and their risk of sudden cardiac death, Dr. Deepak Bhatt, director of Mount Sinai Heart in New York City, who was not involved in the research, said in an email.

“These are some of the best data showing that the risk of return to play may not be as high as we fear,” Bhatt said about the new research.

“Some caveats include that the majority of these athletes were not symptomatic and about a third had an implantable defibrillator,” he added. “Any decision to return to the athletic field should be made after a careful discussion of the potential risks, including ones that are hard to quantify. Input from experts in genetic cardiology and sports cardiology can be very helpful in these cases.”

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Millions have the same ‘bendy body’ disease as my daughter. Why isn’t the medical profession paying more attention? | CNN

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CNN
 — 

One day in July 2021, my then 15-year-old daughter Poppy stumbled and fell while walking down some stairs, grazing her knee. It wasn’t a serious wound, but over the weeks it didn’t heal.

Around the same time, her wrists and knees became sore; her ankles started rolling when she walked; her hands began shaking; her headaches and stomach aches became more frequent and intensely painful. She was always exhausted.

Before her health declined, Poppy had enjoyed horse riding and gymnastics, she’d competed in cross country races and been a fearless goalkeeper for the school hockey team.

But within a couple of months, as walking became increasingly difficult, she asked me for a walking stick. We found one that folds up and fits neatly in her school bag.

I took Poppy to doctors who conducted tests, but they couldn’t find out what was wrong with her. Then, in October, a breakthrough.

A podiatrist who was measuring Poppy for insoles to support her aching feet asked if Poppy could bend her thumb to reach her forearm. She could. Could she pull her little finger back to form a 90-degree angle with the back of her hand? She could do that, too.

“Have you heard of Ehlers-Danlos syndrome?” the podiatrist asked me. I hadn’t – so as soon as I got home, I went looking on the internet.

There are 13 types of Ehlers-Danlos syndrome (EDS), according to research and advocacy organization The Ehlers-Danlos Society. Most types are very rare, and can be diagnosed using genetic tests. However, the genes that cause hypermobile EDS (hEDS) – the most common form, accounting for about 90% of cases – are unknown, so diagnosis is based on a checklist of symptoms. The list includes a hypermobility rating, known as the Beighton Score.

Poppy had enough symptoms to qualify for hEDS, and the diagnosis was confirmed by a doctor one year ago, on Christmas Eve. He told us that although we can do our best to alleviate some symptoms, there is no cure.

Poppy reacted to the news better than I did. She had known for some time that something was fundamentally wrong. The diagnosis was upsetting but identifying her illness also gave her a sense of relief. I felt shocked and overwhelmed, and I cried for weeks.

Reading about EDS was like a dreadful slow reveal.

I learned that it’s a genetic disorder that causes the body to make faulty connective tissue, and connective tissue is everywhere – in the tendons, ligaments, skin, heart, digestive system, eyes and gums.

Weak connective tissue leads to hypermobility, which may sound like a good thing, but some people with bendy bodies suffer a mind-boggling array of symptoms, including joint dislocations and subluxations (like a mini dislocation, when the joint partially slips out of place), soft stretchy skin, abnormal scarring, poor wound healing, gastrointestinal disorders, chronic pain and fatigue.

The severity of symptoms varies wildly. Patients with milder cases can lead relatively normal lives, while others become housebound, and some can’t digest food and must be fed through tubes.

What’s more, people with hEDS are prone to other conditions, including POTS (postural orthostatic tachycardia syndrome, which makes you dizzy when you stand up) and MCAS (mast cell activation syndrome, which gives you allergy-type symptoms).

I learned a lot of new acronyms and they all spelled bad news.

I initially thought hEDS was rare, because all forms of EDS are commonly referred to as rare. But within a few weeks, I felt like I was seeing references to hEDS everywhere. Actor, writer and director Lena Dunham; actor and presenter Jameela Jamil; and drag queen Yvie Oddly live with it. I deep dived into EDS Twitter and EDS Instagram, while Poppy found it comforting to watch TikTok videos made by teenagers with the condition.

I discovered multiple patient groups on Facebook, each with tens of thousands of members, which turned out to be great sources of support. I asked questions (what kind of shoes are best for weak ankles? Which knee braces are easiest to pull on and off?) and kind strangers sent helpful advice. At the same time, scrolling through countless personal stories of pain, despair and shattered dreams made me feel terrified about what might lie ahead.

I noticed common themes. Many EDS patients had spent years seeking the correct diagnosis; others felt they’d been neglected and gaslit by doctors.

There was also a lot of talk of zebras.

Linda Bluestein, a Colorado-based physician who specializes in EDS and other hypermobility conditions, and has hEDS herself, explains why.

“I was told in medical school, ‘when you hear hoofbeats think horses, not zebras,’” she says. Many trainee doctors receive the same advice – when a patient presents with symptoms, “look for the common thing.” That’s why EDS patients commonly refer to themselves as zebras – and also use the fabulous collective noun “dazzle.” The name represents rarity and evokes the stripy stretch marks that are a common feature on EDS skin.

But if people with hEDS are medical zebras, why am I encountering so many of them?

Bluestein says that for many years it was thought that one in 5,000 people had Ehlers-Danlos syndrome. But she says the limited research that’s been carried out into the prevalence of hEDS suggests the true number of cases is “much, much higher” than that.

Dr. Linda Bluestein has treated hEDS patients who have been searching for a diagnosis for decades.

Bluestein points me to a 2019 study carried out in Wales – a country of 3.1 million people. An examination of primary care and hospital records from 1990 to 2017 found that one in 500 people there has either hEDS or joint hypermobility syndrome (a similar condition with a slightly different set of symptoms). She says it’s “a good study” but believes it’s still an underestimate. The Ehlers-Danlos Society says more population studies need to be done to give a more accurate view of its incidence elsewhere.

But despite this possible prevalence, and how debilitating hypermobility disorders can be, the average time to diagnosis from the onset of symptoms is 10 to 12 years, according to The Ehlers-Danlos Society.

Bluestein has firsthand experience of this. Growing up, she wanted to become a ballet dancer and trained six days a week. When puberty hit, she started experiencing joint pain and migraines, and at 16 had her first orthopedic surgery. She realized she wouldn’t succeed in the ballet world and instead pursued her “back-up plan,” to become a doctor. But despite her career choice, Bluestein only received her hEDS diagnosis when she was 47 – more than 30 years later.

“I told my doctor on numerous occasions, ‘there is something wrong with me, I don’t heal well, I get injured more easily than other people’,” she says. “And he just never, never listened.”

Why, for so many patients, does it take so long to get diagnosed?

In 2014 a leading EDS expert, Professor Rodney Grahame, remarked at a conference that “no other disease in the history of modern medicine has been neglected in such a way as Ehlers-Danlos syndrome.”

Far more women than men are diagnosed with EDS, which could help to explain the neglect, because the medical profession has a long history of overlooking health complaints made by women.

A 2009 study, conducted by the European Organisation for Rare Diseases, surveyed 414 families of EDS patients from five countries and found that the average delay to an EDS diagnosis was four years for men – but 16 years for women.

The report states that women with EDS tend to be “diagnosed later because their pain and hypotonia (poor muscle tone) aren’t considered as physical symptoms but rather as psychological symptoms or common complaints.”

“We tend to get dismissed a lot more easily,” says Bluestein. “People jump to the conclusion that we’re histrionic females.”

Anxiety is very common in patients with hypermobility issues, says Bluestein, which can cloud the picture. “When people with anxiety present to a physician, it can suck all the air out of the room, so that the physician almost can’t see anything else.”

This can ramp up the patient’s anxiety further “because people aren’t validating our symptoms, and then we start to doubt ourselves,” she says.

What’s more, medicine is divided into silos which creates the “worst possible model” for EDS patients, says Bluestein.

VIDEO THUMBNAIL Ehlers-Danlos Syndrome 1

‘We’re born with this and will never be free:’ Hear stories from people with Ehlers-Danlos syndrome

She explains that undiagnosed patients might consult a neurologist for their migraines, a rheumatologist for joint pain, a cardiologist for palpitations, a gastroenterologist for digestive issues and a urologist for bladder symptoms. Each doctor focuses on the symptoms that fall within their specialty but doesn’t consider the other ailments. “Nowhere along the way does somebody realize that there are certain conditions that could tie all of these things together and explain everything,” says Bluestein.

The 2009 rare diseases study found that during the quest for a diagnosis, 58% of EDS patients consulted more than five doctors, and 20% consulted more than 20.

The consequences of not getting diagnosed for years can be devastating.

Melissa Dickinson, a psychotherapist in Atlanta, Georgia, says she experienced symptoms of a “mystery illness” since childhood. Then in 2013, she “went on honeymoon to Mexico, relatively healthy, and came back disabled and with a dislocated neck.”

While on vacation, Dickinson says she got food poisoning and was prescribed ciprofloxacin, an antibiotic that can pose a serious risk of aortic aneurysm to people with EDS. Instead, she says it triggered significant nerve damage, digestive issues that almost made her go blind because her body wasn’t absorbing nutrients, and put her in a wheelchair.

Dickinson, who finally received her hEDS diagnosis in 2014, says taking the wrong medication “wrecked me from head to toe.” Now that she’s receiving treatment, “I can walk with mobility aids, but most of my body has to have constant support to function.”

Lara Bloom, president and CEO of The Ehlers-Danlos Society, who herself has hEDS, says many patients have “medicalized PTSD.”

“They have had to stop their careers, they’ve had to drop out of school, their relationships have broken down.” The delay inevitably results in worsening symptoms and a declining quality of life, she says. In worst-case scenarios, patients “are dying by suicide, they’re self-harming.”

Sometimes, the failure to diagnose EDS has led to children being taken away from their parents.

In 2010, Americans Rana Tyson and her husband Chad were falsely accused of harming their 4-week-old twin daughters, who had unexplained fractures in their legs.

Along with their older sister, the baby girls were taken by state authorities in Texas and sent to live with relatives. “It was the worst day of my life,” Tyson tells me in a phone call.

Five months later, a geneticist identified the twins as having a connective tissue disorder, and they were subsequently diagnosed with EDS and a vitamin D deficiency. The family was reunited but “12 years later, it still hurts,” says Tyson.

Bloom says some other parents of children with EDS have been wrongly accused of “fabricated or induced illness (FII)” – a rare form of abuse, formerly known as Munchausen’s syndrome by proxy, in which a parent or care giver deliberately causes symptoms or tries to convince doctors that a healthy child is ill.

Ellie Pattison, who has hEDS, has been repeatedly misdiagnosed as having an eating disorder.

Ellie Pattison, a 19-year-old student who lives in County Durham, England, suffers from severe digestive issues linked to hEDS.

Throughout her childhood, Ellie was repeatedly misdiagnosed as having an eating disorder, she says, while her mother Caroline was accused of FII on three separate occasions. Caroline successfully fought to keep her daughter at home, says Ellie, but the ordeal has left the whole family with “an unimaginable amount of trauma.” Ellie says she suffered from PTSD and endured years of horrific nightmares, triggered by living with the fear from a young age that she could be forcibly separated from her family.

This underlines why prompt diagnosis is so important, says Bloom. “Our hope and dream is for people to get diagnosed when their symptoms begin.”

In the case of hEDS, a crucial first step is to find out what causes it.

Cortney Gensemer, a biomedical scientist in the Norris Lab at the Medical University of South Carolina’s department of Regenerative Medicine and Cell Biology, is trying to solve this mystery. She and research mentor Russell Norris, head of the lab, have been studying a gene mutation they believe causes hEDS (the results of the study are currently under peer review).

Like Poppy, Gensemer was diagnosed with hEDS as a teenager. She says the disease affects every aspect of her work. Looking down a microscope is particularly painful at times – her neck is unstable because of her hEDS, and she’s had metal screws put into some of her neck vertebrae to fuse them.

Cortney Gensemer working in the Norris Lab and recovering from neck surgery earlier this year.

Norris kitted the lab out with special equipment, including motion sensor doors (standard lab doors are very heavy), adjustable chairs and ergonomic pipettes that are gentle on the hands. “If I didn’t have all that stuff, I don’t think I’d be able to do it,” says Gensemer.

To find a hEDS-causing gene, Gensemer says she and Norris sampled DNA from a large family with cases spanning four generations and looked for a mutation that appears only in relatives who have the disease. They identified a “strong candidate gene” and inserted it into mice using gene editing tools.

Gensemer and Norris found that the hEDS mice had significantly more lax tissues, and floppier tails than regular rodents. “You can tie a loose knot into the mutant mouse tail. With a normal mouse tail, you can (only) bend it into a circle,” Gensemer says.

The gene that Gensemer and Norris found won’t account for all hEDS cases, she says. They believe that eventually multiple genes will be identified, and hEDS may be split into different subtypes. This would help to explain why different patients have different symptoms. Crucially, if genetic information sheds light on how the connective tissue is “messed up,” it could lead to effective treatments, says Gensemer.

The Ehlers-Danlos Society is also looking for genes as well as blood markers, working with a team of experts to sequence and analyze the DNA of 1,000 hEDS patients from around the world. And at the UK’s University of Warwick, Ph.D. candidate Sabeeha Malek, another scientist with hEDS, has proposed that EDS might be caused by a fault in the way that collagen binds to cell membranes in connective tissue. If she’s right, she hopes her work will lead to a skin biopsy test that could identify all forms of the disease.

Sabeeha Malek is working to identify biomarkers that could make EDS diagnosis easier.

Progress is being made but on a very small scale. “If you look at any major academic institution, there are multiple labs studying cancer, multiple labs studying heart disease. When you look at a disease that affects one in 500 people, and probably more than that, there should be a lab studying it at every single academic institution,” says Gensemer.

Gensemer hopes that as more discoveries are made and data is accumulated it will “change the way the medical community looks at the disease” – and that it will be taken more seriously.

A year has passed since Poppy’s diagnosis. The initial shock has subsided, and while I’m still grieving the loss of her health, we’ve both learned to accept our new reality and have adjusted to living with EDS.

I’ve assembled a team of supportive doctors and therapists and acquired an arsenal of paraphernalia to fight pain and manage symptoms, including braces and kinesiology tape to hold her joints in place; ice packs, heat pads, tiger balm and arnica gel for sore muscles; and a cupboard full of medications and supplements.

With Poppy often stuck at home, I also got her a giant kitten that she calls Bagel, and he provides the best therapy.

Poppy with Bagel.

Writing this article has taught me a lot more about EDS: It’s been upsetting to report on the terrible experiences some have suffered, but I’ve been awestruck by the dedication of people, many with the condition themselves, who are working to find solutions.

I don’t know what the future holds for Poppy. Some patients’ symptoms improve with age; others experience an increase in pain and a loss of mobility. I’ve learned there’s a limit to what we can control but there’s a lot we can do, to tackle symptoms and make life easier. And I believe that change is coming.

With a better understanding of the condition and diagnostic tools on the horizon, my biggest hope is that there will be a cure one day – and that it will come in time for Poppy.

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