Cerebral Abnormalities in Adults with Ataxia-Telangiectasia

Discussion

This case series identifies a spectrum of supratentorial white matter findings in adults with A-T. Combined with the experience of a few reported individual cases,^12,17 it is apparent that patients with A-T frequently manifest scattered small white matter hypointensities that most likely represent tiny hemosiderin deposits related to telangiectatic vessels. These lesions were most conspicuous on SWI. The presence of these asymptomatic lesions in 6 of 10 neurologically stable patients > 19 years old contrasts with their absence in a younger reported cohort¹⁸ of 8 patients with A-T (mean age, 13 years; age range, 9–19 years), as well as our general experience at the Johns Hopkins Ataxia Telangiectasia Clinical Center reviewing several hundred initial diagnostic MR imaging scans. Although age-related differences in sensitivity or other technical differences are possible confounders, the most plausible explanation is that these are acquired lesions, passing over a threshold of MR imaging detectability in early adult years.

Disabling mutation of the ATM gene responsible for A-T has pleotrophic cellular effects.^4,19,20 Among the most prominent of these is disruption of the cell-cycle arrest and other cellular responses to DNA damage. Identification of the specific impaired ATM-kinase pathway responsible for formation of deep white matter telangiectasia is unknowable, though this is an appropriate target for research. The ocular and cutaneous telangiectasias that are part of the defining feature of A-T appear in light-exposed superficial regions. A similar vascular pathologic pattern in ATM-deficient mice²¹ that arises in the retina with diminished retinal vasculature attenuation is associated with increased vascular endothelial growth factor expression (implicated in angiogenesis), decreased tight junction protein occludin expression, and perturbed astrocytic interaction with endothelial cells, as well as increased vascular permeability with deposits of hemosiderin; however, this model differs from the deep brain lesions demonstrated in this case series by its relationship to light exposure.²² Another plausible explanation is offered by growing evidence that ATM mediates vascular endothelial cell senescence.^23,24

The imaging findings reported here in A-T are reminiscent of those seen in radiation-induced vascular malformations and white matter injuries. Vascular telangiectasias are reported more frequently in patients after CNS irradiation.^25⇓–27 Parenchymal radiation-associated MR imaging changes typically manifest as progressive, mild to moderate T2 prolongation in the periventricular white matter,²⁵ which may be the result of vascular abnormalities leading to parenchymal ischemia and white matter degeneration. It is not clear, however, whether similar mechanisms cause the white matter changes seen in older patients with A-T.

An unusual finding, identified in our 2 oldest participants (ages 34 and 28 years), was that of white matter T2/FLAIR hyperintensities. Similar hyperintensities have been the topic of individual case reports,^11,14,15 although we believe that these differ from the single case report of a child with diffuse white matter signal simulating leukodystrophy,¹³ a pattern we have not otherwise seen. Although MR spectroscopy and MRSI have been previously reported in A-T,^17,18 abnormalities (eg, reduced NAA) were found only in the atrophic cerebellum, and MR spectroscopy abnormality has not previously been reported in the supratentorial compartment. In one of the reported cases,¹⁴ these white matter signal changes were thought to represent demyelination, but the associated low level of all metabolites found in our MRSI investigation of similar T2 appearance lesions suggests that these white matter signal abnormalities represent reduced cellularity rather than active demyelination or ischemia. The peculiar appearance of a discrete fluid-filled cavity surrounded by the hemosiderin lesions in participant 10 of our series can be best explained by a transudative or exudative process related to leaky capillary telangiectasia.

A spectrum of supratentorial MR imaging abnormalities seem to be common in adults with A-T. These are asymptomatic, or possibly their associated signs and symptoms are lost amid the many otherwise stable neurologic impairments that such patients endure. Six of 10 participants in our current study manifested deep cerebral telangiectatic vessels best visualized on the SWI sequence, whereas the 2 oldest participants also manifested parenchymal lesions and white matter signal abnormalities. The vascular lesions have many similarities to those seen in patients after therapeutic radiation. The pathogenesis of these lesions is unknown, but candidates include impaired DNA damage response, oxidative damage, enhanced senescence, or any combination of these 3 changes. The prognosis of these MR imaging changes is unclear and will require longitudinal studies.