A baby born with a rare and dangerous genetic disease is growing and thriving after getting an experimental gene editing treatment made just for him. Researchers described the case in a new study, saying he’s among the first to be successfully treated with a custom therapy that seeks to fix a tiny but critical error in his genetic code that kills half of affected infants. Though it may be a while before similar personalized treatments are available for others, doctors hope the technology can someday help the millions left behind even as genetic medicine has advanced because their conditions are so rare. “This is the first step towards the use of gene editing therapies to treat a wide variety of rare genetic disorders for which there are currently no definitive medical treatments,” said Dr. Kiran Musunuru, a University of Pennsylvania gene editing expert who co-authored the study published Thursday in the New England Journal of Medicine. The baby, KJ Muldoon of Clifton Heights, Pennsylvania, is one of 350 million people worldwide with rare diseases, most of which are genetic. He was diagnosed shortly after birth with severe CPS1 deficiency, estimated by some experts to affect around one in a million babies. Those infants lack an enzyme needed to help remove ammonia from the body, so it can build up in their blood and become toxic. A liver transplant is an option for some. Knowing KJ’s odds, parents Kyle and Nicole Muldoon, both 34, worried they could lose him. “We were, like, you know, weighing all the options, asking all the questions for either the liver transplant, which is invasive, or something that’s never been done before,” Nicole said. “We prayed, we talked to people, we gathered information, and we eventually decided that this was the way we were going to go,” her husband added. Within six months, the team at Children’s Hospital of Philadelphia and Penn Medicine, along with their partners, created a therapy designed to correct KJ’s faulty gene. They used CRISPR, the gene editing tool that won its inventors the Nobel Prize in 2020. Instead of cutting the DNA strand like the first CRISPR approaches, doctors employed a technique that flips the mutated DNA “letter” — also known as a base — to the correct type. Known as “base editing,” it reduces the risk of unintended genetic changes. It’s “very exciting” that the team created the therapy so quickly, said gene therapy researcher Senthil Bhoopalan at St. Jude Children’s Research Hospital in Memphis, who wasn’t involved in the study. “This really sets the pace and the benchmark for such approaches.” In February, KJ got his first IV infusion with the gene editing therapy, delivered through tiny fatty droplets called lipid nanoparticles that are taken up by liver cells. While the room was abuzz with excitement that day, “he slept through the entire thing,” recalled study author Dr. Rebecca Ahrens-Nicklas, a gene therapy expert at CHOP. After follow-up doses in March and April, KJ has been able to eat more normally and has recovered well from illnesses like colds, which can strain the body and exacerbate symptoms of CPS1. The 9 ½-month old also takes less medication. Considering his poor prognosis earlier, “any time we see even the smallest milestone that he’s meeting – like a little wave or rolling over – that’s a big moment for us,” his mother said. Still, researchers caution that it’s only been a few months. They’ll need to watch him for years. “We’re still very much in the early stages of understanding what this medication may have done for KJ,” Ahrens-Nicklas said. “But every day, he’s showing us signs that he’s growing and thriving.” Researchers hope what they learn from KJ will help other rare disease patients. Gene therapies, which can be extremely expensive to develop, generally target more common disorders in part for simple financial reasons: more patients mean potentially more sales, which can help pay the development costs and generate more profit. The first CRISPR therapy approved by the U.S. Food and Drug Administration, for example, treats sickle cell disease, a painful blood disorder affecting millions worldwide. Musunuru said his team’s work — funded in part by the National Institutes of Health — showed that creating a custom treatment doesn’t have to be prohibitively expensive. The cost was “not far off” from the $800,000-plus for an average liver transplant and related care, he said. “As we get better and better at making these therapies and shorten the time frame even more, economies of scale will kick in and I would expect the costs to come down,” Musunuru said. Scientists also won’t have to redo all the initial work every time they create a customized therapy, Bhoopalan said, so this research “sets the stage” for treating other rare conditions. Carlos Moraes, a neurology professor at the University of Miami who wasn’t involved with the study, said research like this opens the door to more advances. “Once someone comes with a breakthrough like this, it will take no time” for other teams to apply the lessons and move forward, he said. “There are barriers, but I predict that they are going to be crossed in the next five to 10 years. Then the whole field will move as a block because we’re pretty much ready.”
Gene editing helped a desperately ill baby thrive. Scientists say it could someday treat millions
TruthLens AI Suggested Headline:
"Experimental Gene Editing Therapy Shows Promise in Treating Rare Genetic Disorder in Infant"
CNN
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TruthLens AI Summary
A baby named KJ Muldoon, born with a rare genetic disorder known as severe CPS1 deficiency, has shown remarkable improvement following a pioneering gene editing treatment tailored specifically for him. This condition, which affects approximately one in a million infants, prevents the body from eliminating ammonia, leading to toxic buildup that can be fatal. Faced with limited treatment options, KJ's parents chose to pursue an experimental therapy developed by a team at the Children's Hospital of Philadelphia and Penn Medicine. Their approach utilized CRISPR technology, specifically a method called 'base editing,' which corrects the mutated DNA without the risks associated with traditional gene editing methods. After receiving his first infusion in February, KJ has demonstrated significant progress, including improved eating habits and a reduced need for medication, much to the relief of his family and medical team.
Despite the initial success, researchers emphasize that it is still early in the evaluation of KJ's long-term health outcomes. They plan to monitor his progress closely over the coming years to better understand the implications of this innovative treatment. The study's co-author, Dr. Kiran Musunuru, expressed hope that this breakthrough could pave the way for personalized gene therapies for other rare genetic disorders that currently lack effective treatments. Importantly, the cost of developing such custom therapies is not as prohibitive as previously thought, potentially allowing for broader application in treating rare diseases. Experts believe that advancements in this field could lead to more efficient and cost-effective solutions, ultimately benefiting millions of patients with rare genetic conditions. As the research progresses, the insights gained from KJ's treatment may set a precedent for future gene editing therapies, making it possible to address the needs of patients with similar rare disorders.
TruthLens AI Analysis
The article highlights a remarkable case of a baby who received an experimental gene editing treatment for a rare genetic disorder, showcasing the potential of personalized medicine. This narrative is compelling, as it not only illustrates a breakthrough in medical science but also stirs hope for families dealing with rare genetic diseases.
Intent Behind the Article
The primary goal seems to be to inform the public about advancements in gene editing technology, especially its implications for treating rare genetic disorders. By focusing on a real-life success story, the article aims to evoke an emotional response and raise awareness about the potential for personalized medicine.
Public Perception
This article seeks to create a positive perception of gene editing technologies by presenting them as a beacon of hope for families facing devastating genetic conditions. It aims to generate excitement and optimism regarding future applications of such therapies, potentially influencing public opinion in favor of gene editing research.
Information Gaps
While the article primarily focuses on the success of the treatment, it may downplay the challenges and ethical considerations surrounding gene editing. For instance, the risks associated with experimental therapies or the long-term effects on the child and future patients are not deeply explored. This omission could lead to an incomplete understanding of the broader implications of such medical advancements.
Manipulative Potential
The article contains elements that could be seen as manipulative, particularly in how it frames the narrative around the baby’s recovery. By emphasizing the emotional journey of the family, it could lead readers to overlook the complexities and ongoing debates regarding gene editing technologies. The use of personal stories tends to engage the reader's emotions, which can sometimes overshadow critical analysis of the topic.
Credibility Assessment
The article is based on a study published in a reputable journal, lending it a degree of credibility. However, the optimistic portrayal of the treatment’s success and the emphasis on future potential may lead some to question whether it presents an overly simplistic view of gene editing's current state and future possibilities.
Societal Impact
If the gene editing technology discussed becomes more widely adopted, it could transform healthcare, especially for those with rare genetic disorders. This may lead to significant changes in how such conditions are treated and viewed in society, influencing healthcare policies and funding for genetic research.
Target Audience
The article likely appeals to a broad audience, including families affected by rare diseases, medical professionals, and advocates for genetic research. It aims to resonate with those seeking hope and solutions in the face of daunting medical challenges.
Market Implications
The advancements in gene editing could have implications for biotech firms, particularly those involved in genetic therapies. Positive coverage of such breakthroughs may boost investor confidence and interest in related stocks, potentially impacting the biotech market favorably.
Global Context
In the context of current global health discussions, this article touches on the ongoing evolution of medical technologies and their socio-ethical considerations. As gene editing becomes more prominent, it may alter global health landscapes and ethical frameworks surrounding genetic interventions.
AI Influence
It is plausible that AI tools were employed in crafting this article, particularly for data analysis or synthesizing information from complex studies. AI could influence the narrative by emphasizing certain aspects of the story, such as the emotional journey of the family, while minimizing technical details that may confuse general readers.
In conclusion, the article presents a compelling narrative that raises awareness about the potential of gene editing. However, readers should approach the subject with an understanding of the complexities and ethical considerations involved.