Abstract
Neurofibromatosis (NF1) represents the most common single gene cause of learning disabilities. NF1 patients have impairments in frontal lobe based cognitive functions such as attention, working memory, and inhibition. Due to its well–characterized genetic etiology, investigations of NF1 may shed light on neural mechanisms underlying such difficulties in the general population or other patient groups. Prior neuroimaging findings indicate global brain volume increases, consistent with neural over-proliferation. However, little is known about alterations in white matter microstructure in NF1. We performed diffusion tensor imaging (DTI) analyses using tract-based spatial statistics (TBSS) in 14 young adult NF1 patients and 12 healthy controls. We also examined brain volumetric measures in the same subjects. Consistent with prior studies, we found significantly increased overall gray and white matter volume in NF1 patients. Relative to healthy controls, NF1 patients showed widespread reductions in white matter integrity across the entire brain as reflected by decreased fractional anisotropy (FA) and significantly increased absolute diffusion (ADC). When radial and axial diffusion were examined we found pronounced differences in radial diffusion in NF1 patients, indicative of either decreased myelination or increased space between axons. Secondary analyses revealed that FA and radial diffusion effects were of greatest magnitude in the frontal lobe. Such alterations of white matter tracts connecting frontal regions could contribute to the observed cognitive deficits. Furthermore, although the cellular basis of these white matter microstructural alterations remains to be determined, our findings of disproportionately increased radial diffusion against a background of increased white matter volume suggest the novel hypothesis that one potential alteration contributing to increased cortical white matter in NF1 may be looser packing of axons, with or without myelination changes. Further, this indicates that axial and radial diffusivity can uniquely contribute as markers of NF1-associated brain pathology in conjunction with the typically investigated measures.
Highlights
Neurofibromatosis Type 1 (NF1) is caused by a mutation in the neurofibromin gene at locus 17q11.2, and is one of the most common single-gene genetic disorders affecting cognitive function in humans [1]
Structural magnetic resonance imaging (MRI) Results The structural volume analysis revealed significantly larger total grey matter volume [t(24) = 2.84, p = .009; effect size = .987] and white matter volume [t(24) = 3.38, p = .003; effect size = 1.12] in NF1 patients relative to controls. This finding remained significant when restricted to an region of interest (ROI) of the frontal lobe white matter [t(24) = 3.62, p = .0014; effect size (Cohen’s d) = 1.17], frontal lobe grey matter was significantly larger in controls [t(24) = 3.64,p = .0013; effect size = 1.174; see Figure 2]
Radial diffusion showed a similar pattern of global changes (Figure 4)
Summary
Neurofibromatosis Type 1 (NF1) is caused by a mutation in the neurofibromin gene at locus 17q11.2, and is one of the most common single-gene genetic disorders (prevalence 1:3000) affecting cognitive function in humans [1]. The NF1 cognitive profile is characterized by severe impairments in ‘cognitive control’, or the ability to maintain attentional focus and resist distraction, which is generally considered to be a key function of the frontal lobe These cognitive control deficits are notable in the areas of working memory, cognitive flexibility, and inhibitory control [1,4,5,6]. Due to its well-characterized genetic etiology, investigation of the neural mechanisms underlying these deficits in NF1 could shed light on the pathogenesis of attentional dysfunction and social deficits in the broader population
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