A drug used to treat children with epilepsy prevents brain tumour formation and growth in two mouse models of neurofibromatosis type 1 (NF1), according to a study by researchers at Washington University School of Medicine in St. Louis. NF1 is a genetic condition that causes tumours to grow on nerves throughout the body.
The findings lay the groundwork for a clinical trial to assess whether the drug, lamotrigine, can prevent or delay brain tumours in children with NF1. The study is published online in the journal Neuro-Oncology.
“Based on these data, the Neurofibromatosis Clinical Trials Consortium is considering launching a first-of-its-kind prevention trial,” said senior author David H. Gutmann, MD, PhD, professor of neurology. “The plan is to enrol kids without symptoms, treat them for a limited time, and then see whether the number of children who develop tumours that require treatment goes down.
“This is a novel idea, so we took it to an NF1 patient focus group,” Gutmann continued. “They said, ‘This is exactly what we’re looking for.’ A short-term treatment with a drug that has been used safely for 30 years was acceptable to them if it reduced the chance their children would develop tumours and need chemotherapy that might have all kinds of side effects.”
Optic gliomas, tumours on the optic nerve are the most serious type that those with NF1 get. Such tumours typically appear between ages 3 to 7. Though rarely fatal, they cause vision loss in up to a third of patients as well as other symptoms, including early puberty. Standard chemotherapy for optic gliomas is only moderately effective at preventing further vision loss and can affect children’s developing brains, resulting in cognitive and behavioural problems.
In a previous study, Gutmann and Corina Anastasaki, PhD, an assistant professor of neurology and the first author on the new paper, showed that lamotrigine stopped optic glioma growth in NF1 mice by suppressing neuronal hyperactivity. Intrigued, the Neurofibromatosis Clinical Trial Consortium asked Gutmann and Anastasaki to clarify the connection between NF1 mutation, neuronal excitability and optic gliomas; assess whether lamotrigine was effective at the doses already proven safe in children with epilepsy; and conduct these studies in more than one strain of NF1 mice.
In humans, NF1 could be caused by any one of thousands of different mutations in the NF1 gene, with different mutations causing different medical problems. Repeating experiments in multiple strains of mice was a way of gauging whether lamotrigine was likely to work in people regardless of the underlying mutation.
Anastasaki and Gutmann not only showed that lamotrigine worked in two strains of NF1 mice, they also showed that the drug worked at lower doses than those used for epilepsy, meaning that it was probably safe. Even better, they found that a short course of the drug had lasting effects, both as a preventive and a treatment. Mice with tumours and that were treated for four weeks starting at 12 weeks of age saw their tumours stop growing and even showed no further damage to the retinas. Mice that received a four-week course of the drug starting at 4 weeks of age, before tumours typically emerge, showed no tumour growth even four months after treatment had ended.
These findings have led Gutmann to suggest that a one-year course of treatment for young children with NF1, maybe between the ages of 2 to 4, might be enough to reduce their risk of brain tumours.
“The idea that we might be able to change the prognosis for these kids by intervening within a short time window is so exciting,” Gutmann said. “If we could just get them past the age when these tumours typically form, past age 7, they may never need treatment. I’d love it if I never again had to discuss chemotherapy for kids who aren’t even in first grade yet.”