News — July 11, 2023 (BOSTON) – A new national study, led by researchers at Tufts Medical Center in Boston, has found whole genome sequencing (WGS) to be nearly twice as effective as a targeted gene sequencing test at identifying abnormalities responsible for genetic disorders in newborns and infants. The study, “A Comparative Analysis of Rapid Whole Genomic Sequencing and a Targeted Neonatal Gene Panel in Infants with a Suspected Genetic Disorder: The Genomic Medicine for Ill Neonates and Infants (GEMINI) Study,” was first published online on The Journal of the American Medical Association (JAMA) website on July 11, 2023.

Funded by the National Institutes of Health, the first-of-its-kind GEMINI Study enrolled 400 newborns and infants under the age of one year, with a wide variety of suspected, undiagnosed genetic disorders, at six centers across the United States. Each newbon/infant received both WGS, which can identify variants in all 20,000 genes in the human body, and NewbornDx, a targeted gene sequencing test which can identify variants in 1,722 genes known to be linked to genetic disorders in newborns/infants. The researchers found that WGS detected a genetic disorder in 49 percent of patients, while the targeted gene sequencing test identified a genetic disorder in 27 percent of study participants. The targeted panel missed 40 percent of diagnoses that WGS captured. In addition, the researchers also found 134 new genetic diagnoses that had never before been described. Overall, 51 percent of patients in the study were diagnosed with a genetic disorder with either test.

“More than half of the babies in our study had a genetic disorder that would have remained undetected at most hospitals across the country if not for genome sequencing technologies,” said Jonathan Davis, MD, Chief of Newborn Medicine at Tufts Medical Center and Co-Principal Investigator of the study. “Successfully diagnosing an infant’s genetic disorder as early as possible helps ensure they receive the best medical care. This study shows that WGS, while still imperfect, remains the gold standard for accurate diagnosis of genetic disorders in newborns and infants.”

But WGS is not without its disadvantages, the researchers noted. On average, it took nearly two full days longer (six days vs. four days) to receive routine results from WGS compared to the targeted gene sequencing test. The targeted test is also less expensive, and since it screens for specific genetic disorders that only appear in newborns and infants, its use eliminates the risk of unintentionally revealing potential health risks later in life, such as Alzheimer’s disease or cancer, that the child’s parents may not want to know.

The GEMINI Study also identified an additional concern: a lack of standardization in neonatal genetics interpretation. In 40 percent of cases, different laboratories disagreed on whether a mutually acknowledged gene abnormality was the cause of the suspected genetic disorder in the newborn/infant.

“Many neonatologists and geneticists use genome sequencing panels, but it’s clear there are a variety of different approaches and a lack of consensus among geneticists on the causes of a specific patient’s medical disorder,” said Jill Maron, MD, MPH, Chief of Pediatrics at Women & Infants Hospital of Rhode Island and Co-Principal Investigator of the study. “Genome sequencing can be costly, but in this targeted, at-risk population, it proves to be highly informative. We are supportive of ongoing efforts to see these tests covered by insurance.”

Additional study sites include Rady Children’s Hospital in San Diego, Mt. Sinai Hospital, University of North Carolina-Chapel Hill, Cincinnati Children’s Hospital and the University of Pittsburgh.

“This study provides further evidence that genetic disorders are common among newborns and infants,” said Stephen F. Kingsmore, MD, DSc, President and CEO of Rady Children’s Institute for Genomic Medicine and a co-investigator and a second co-author of the study. “The findings strengthen support for early diagnosis by rapid genomic sequencing, allowing for the use of precision medicine to better care for this vulnerable patient population.”

The GEMINI study is supported by a National Center For Advancing Translational Sciences (NCATS) of the National Institutes of Health (NIH) grant to Tufts Medical Center, under Award Number U01TR00271. The authors note several limitations and conflicts of interest, which are described in the study. 

Tufts Medicine is the parent organization of Tufts Medical Center, a world renowned 415-bed academic medical center in Boston that cares for the sickest patients in the region, includes a level one trauma center and one of the largest heart transplant centers in New England, and also serves as the principal teaching hospital for Tufts University School of Medicine. Tufts Medicine is also the parent organization of Lowell General Hospital, MelroseWakefield Healthcare, an expansive home care and hospice network, and a large clinically integrated physician network that cares for more than one million patients per year. The health system is dedicated to providing patients with the highest quality of care as close to home as possible.