Infant with rare, incurable disease is first to successfully receive personalized gene therapy treatment
NIH-supported gene-editing platform lays groundwork to rapidly develop treatments for other rare genetic diseases
NIH/Office of the Director
Infant with rare, incurable disease is first to successfully receive personalized gene therapy treatment
NIH-supported gene-editing platform lays groundwork to rapidly develop treatments for other rare genetic diseases
A research team supported by the National Institutes of Health (NIH) has developed and safely delivered a personalized gene editing therapy to treat an infant with a life-threatening, incurable genetic disease. The infant, who was diagnosed with the rare condition carbamoyl phosphate synthetase 1 (CPS1) deficiency shortly after birth, has responded positively to the treatment. The process, from diagnosis to treatment, took only six months and marks the first time the technology has been successfully deployed to treat a human patient. The technology used in this study was developed using a platform that could be tweaked to treat a wide range of genetic disorders and opens the possibility of creating personalized treatments in other parts of the body.
A team of researchers at the Children’s Hospital of Philadelphia (CHOP) and the Perelman School of Medicine at the University of Pennsylvania (Penn) developed the customized therapy using the gene-editing platform CRISPR. They corrected a specific gene mutation in the baby’s liver cells that led to the disorder. CRISPR is an advanced gene editing technology that enables precise changes to DNA inside living cells. This is the first known case of a personalized CRISPR-based medicine administered to a single patient and was carefully designed to target non-reproductive cells so changes would only affect the patient.
“As a platform, gene editing -- built on reusable components and rapid customization -- promises a new era of precision medicine for hundreds of rare diseases, bringing life-changing therapies to patients when timing matters most: Early, fast, and tailored to the individual,” said Joni L. Rutter, Ph.D., director of NIH’s National Center for Advancing Translational Sciences (NCATS).
CPS1 deficiency is characterized by an inability to fully break down byproducts from protein metabolism in the liver, causing ammonia to build up to toxic levels in the body. It can cause severe damage to the brain and liver. Treatment includes a low protein diet until the child is old enough for a liver transplant. However, in this waiting period there is a risk of rapid organ failure due to stressors such as infection, trauma, or dehydration. High levels of ammonia can cause coma, brain swelling, and may be fatal or cause permanent brain damage.
The child initially received a very low dose of the therapy at six months of age, then a higher dose later. The research team saw signs that the therapy was effective almost from the start. The six-month old began taking in more protein in the diet, and the care team could reduce the medicine needed to keep ammonia levels low in the body. Another telling sign of the child’s improvement to date came after the child caught a cold, and later, had to deal with a gastrointestinal illness. Normally, such infections for a child in this condition could be extremely dangerous, especially with the possibility of ammonia reaching dangerous levels in the brain.
“We knew the method used to deliver the gene-editing machinery to the baby’s liver cells allowed us to give the treatment repeatedly. That meant we could start with a low dose that we were sure was safe,” said CHOP pediatrician Rebecca Ahrens-Nicklas, M.D., Ph.D.
“We were very concerned when the baby got sick, but they just shrugged the illness off,” said Penn geneticist and first author Kiran Musunuru, M.D., Ph.D. For now, much work remains, but the researchers are cautiously optimistic about the baby’s progress.
The scientists announced their work at the American Society of Gene & Cell Therapy Meeting on May 15th and described the study in The New England Journal of Medicine.
Funding for this project was provided by the NIH Common Fund Somatic Cell Genome Editing program grants, U01TR005355, U19NS132301, U19NS132303, DP2CA281401, and National Heart, Lung, and Blood Institute grants R35HL145203 and P01HL142494. In-kind contributions for the study were made by Acuitas Therapeutics, Integrated DNA Technologies, Aldevron, and Danaher Corporation. Additional funding was provided by the CHOP Research Institute’s Gene Therapy for Inherited Metabolic Disorders Frontier Program.
Reference: Musunuru et al, “Patient-Specific In Vivo Gene Editing to Treat a Rare Genetic Disease.” N Engl J Med. Online May 15, 2025. DOI: 10.1056/NEJMoa2504747
About the National Institutes of Health (NIH): NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.
Journal
New England Journal of Medicine
Method of Research
Randomized controlled/clinical trial
Subject of Research
People
Article Title
Patient-Specific In Vivo Gene Editing to Treat a Rare Genetic Disease
Article Publication Date
15-May-2025
World's first patient treated with personalized CRISPR gene editing therapy at Children’s Hospital of Philadelphia
Landmark study from CHOP and Penn Medicine showcases the power of customized gene editing therapy to treat patient with rare metabolic disease
Children's Hospital of Philadelphia
image:
Drs. Kiran Musunuru and Rebecca Ahrens-Nicklas with patient KJ.
view moreCredit: Children's Hospital of Philadelphia
Philadelphia and New Orleans, May 15, 2025 – In a historic medical breakthrough, a child diagnosed with a rare genetic disorder has been successfully treated with a customized CRISPR gene editing therapy by a team at Children’s Hospital of Philadelphia (CHOP) and Penn Medicine. The infant, KJ, was born with a rare metabolic disease known as severe carbamoyl phosphate synthetase 1 (CPS1) deficiency. After spending the first several months of his life in the hospital, on a very restrictive diet, KJ received the first dose of his bespoke therapy in February 2025 between six and seven months of age. The treatment was administered safely, and he is now growing well and thriving.
The case is detailed today in a study published by The New England Journal of Medicine and was presented at the American Society of Gene & Cell Therapy Annual Meeting in New Orleans. This landmark finding could provide a pathway for gene editing technology to be successfully adapted to treat individuals with rare diseases for whom no medical treatments are available.
“Years and years of progress in gene editing and collaboration between researchers and clinicians made this moment possible, and while KJ is just one patient, we hope he is the first of many to benefit from a methodology that can be scaled to fit an individual patient’s needs,” said Rebecca Ahrens-Nicklas, MD, PhD, director of the Gene Therapy for Inherited Metabolic Disorders Frontier Program (GTIMD) at Children’s Hospital of Philadelphia and an assistant professor of Pediatrics in the Perelman School of Medicine at the University of Pennsylvania.
CRISPR (clustered regularly interspaced short palindromic repeats)-based gene editing can precisely correct disease-causing variants in the human genome. Gene editing tools are incredibly complex and nuanced, and up to this point, researchers have built them to target more common diseases that affect tens or hundreds of thousands of patients, such as the two diseases for which there currently are U.S. Food and Drug Administration-approved therapies, sickle cell disease and beta thalassemia. However, relatively few diseases benefit from a “one-size-fits-all” gene editing approach since so many disease-causing variants exist. Even as the field advances, many patients with rare genetic diseases – collectively impacting millions of patients worldwide – have been left behind.
A Collaborative Effort
Ahrens-Nicklas and Kiran Musunuru, MD, PhD, the Barry J. Gertz Professor for Translational Research in Penn’s Perelman School of Medicine, who are co-corresponding authors on the published report, began collaborating to study the feasibility of creating customized gene editing therapies for individual patients in 2023, building upon many years of research into rare metabolic disorders, as well as the feasibility of gene editing to treat patients. Both are members of the NIH funded Somatic Cell Genome Editing Consortium, which supports collaborative genome editing research.
Ahrens-Nicklas and Musunuru decided to focus on urea cycle disorders. During the normal breakdown of proteins in the body, ammonia is naturally produced. Typically, our bodies know to convert the ammonia to urea and then excrete that urea through urination. However, a child with a urea cycle disorder lacks an enzyme in the liver needed to convert ammonia to urea. Ammonia then builds up to a toxic level, which can cause organ damage, particularly in the brain and the liver.
After years of preclinical research with similar disease-causing variants, Ahrens-Nicklas and Musunuru targeted KJ’s specific variant of CPS1, identified soon after his birth. Within six months, their team designed and manufactured a base editing therapy delivered via lipid nanoparticles to the liver in order to correct KJ’s faulty enzyme. In late February 2025, KJ received his first infusion of this experimental therapy, and since then, he has received follow-up doses in March and April 2025. In the newly published New England Journal of Medicine paper, the researchers, along with their academic and industry collaborators, describe the customized CRISPR gene editing therapy that was rigorously yet speedily developed for administration to KJ.
As of April 2025, KJ had received three doses of the therapy with no serious side effects. In the short time since treatment, he has tolerated increased dietary protein and needed less nitrogen scavenger medication. He also has been able to recover from certain typical childhood illnesses like rhinovirus without ammonia building up in his body. Longer follow-up is needed to fully evaluate the benefits of the therapy.
“While KJ will need to be monitored carefully for the rest of his life, our initial findings are quite promising,” Ahrens-Nicklas said.
“We want each and every patient to have the potential to experience the same results we saw in this first patient, and we hope that other academic investigators will replicate this method for many rare diseases and give many patients a fair shot at living a healthy life,” Musunuru said. “The promise of gene therapy that we’ve heard about for decades is coming to fruition, and it’s going to utterly transform the way we approach medicine.”
A Future for KJ
Typically, patients with CPS1 deficiency, like KJ, are treated with a liver transplant. However, for patients to receive a liver transplant, they need to be medically stable and old enough to handle such a major procedure. During that time, episodes of increased ammonia can put patients at risk for ongoing, lifelong neurologic damage or even prove fatal. Because of these threats to lifelong health, the researchers knew that finding new ways to treat patients who are too young and small to receive liver transplants would be lifechanging for families whose children faced this disorder.
“We would do anything for our kids, so with KJ, we wanted to figure out how we were going to support him and how we were going to get him to the point where he can do all the things a normal kid should be able to do,” his mother, Nicole Muldoon, said. “We thought it was our responsibility to help our child, so when the doctors came to us with their idea, we put our trust in them in the hopes that it could help not just KJ but other families in our position.”
“We’ve been in the thick of this since KJ was born, and our whole world’s been revolving around this little guy and his stay in the hospital,” his father, Kyle Muldoon, said. “We’re so excited to be able to finally be together at home so that KJ can be with his siblings, and we can finally take a deep breath.”
This study was supported by grants from the National Institutes of Health Somatic Cell Genome Editing Program (U01TR005355, U19NS132301), as well as additional National Institutes of Health grants (R35HL145203, U19NS132303, DP2CA281401, P01HL142494). In-kind contributions were made by Acuitas Therapeutics, Integrated DNA Technologies, Aldevron, and Danaher Corporation. Additional funding was provided by the CHOP Research Institute’s Gene Therapy for Inherited Metabolic Disorders Frontier Program.
Musunuru et al, “Patient-Specific In Vivo Gene Editing to Treat a Rare Genetic Disease.” N Engl J Med. Online May 15, 2025. DOI: 10.1056/NEJMoa2504747.
About Children’s Hospital of Philadelphia:
A non-profit, charitable organization, Children’s Hospital of Philadelphia was founded in 1855 as the nation’s first pediatric hospital. Through its long-standing commitment to providing exceptional patient care, training new generations of pediatric healthcare professionals, and pioneering major research initiatives, the hospital has fostered many discoveries that have benefited children worldwide. Its pediatric research program is among the largest in the country. The institution has a well-established history of providing advanced pediatric care close to home through its CHOP Care Network, which includes more than 50 primary care practices, specialty care and surgical centers, urgent care centers, and community hospital alliances throughout Pennsylvania and New Jersey, as well as the Middleman Family Pavilion and its dedicated pediatric emergency department in King of Prussia. In addition, its unique family-centered care and public service programs have brought Children’s Hospital of Philadelphia recognition as a leading advocate for children and adolescents. For more information, visit https://www.chop.edu.
About Penn Medicine
Penn Medicine is one of the world’s leading academic medical centers, dedicated to the related missions of medical education, biomedical research, excellence in patient care, and community service. The organization consists of the University of Pennsylvania Health System (UPHS) and Penn’s Raymond and Ruth Perelman School of Medicine, founded in 1765 as the nation’s first medical school.
The Perelman School of Medicine is consistently among the nation's top recipients of funding from the National Institutes of Health, with $580 million awarded in the 2023 fiscal year. Home to a proud history of “firsts,” Penn Medicine teams have pioneered discoveries that have shaped modern medicine, including CAR T cell therapy for cancer and the Nobel Prize-winning mRNA technology used in COVID-19 vaccines.
The University of Pennsylvania Health System cares for patients in facilities and their homes stretching from the Susquehanna River in Pennsylvania to the New Jersey shore. UPHS facilities include the Hospital of the University of Pennsylvania, Penn Presbyterian Medical Center, Chester County Hospital, Doylestown Health, Lancaster General Health, Princeton Health, and Pennsylvania Hospital—the nation’s first hospital, chartered in 1751. Additional facilities and enterprises include Penn Medicine at Home, GSPP Rehabilitation, Lancaster Behavioral Health Hospital, and Princeton House Behavioral Health, among others.
Penn Medicine is an $11.9 billion enterprise powered by nearly 49,000 talented faculty and staff.
Journal
New England Journal of Medicine
Method of Research
Case study
Subject of Research
People
Article Title
Patient-Specific In Vivo Gene Editing to Treat a Rare Genetic Disease
Article Publication Date
15-May-2025
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