Increased Prevalence of Developmental Venous Anomalies in Children with Intracranial Neoplasms

Discussion

DVAs are encountered with frequency in daily neuroradiology practice and are generally considered to be essentially benign variants of venous development. Several theories have been proposed to explain their etiology, the most broadly accepted of which is that they represent a response of the developing brain to a regional compromise of the normal venous drainage caused by stenosis, thrombosis, or maldevelopment.¹⁴ Others have suggested that abnormalities of fetal angiogenesis and regression may lead to their development.¹⁵ There is consensus that they arise in utero, though there have been reports documenting postnatal evolution.¹⁶

It has long been recognized that a substantial number of DVAs are associated with cavernous malformations, and it is theorized that both lesions represent differing responses to a compromise of regional venous drainage.^{17⇓⇓–20} However, DVAs are also seen with a high prevalence in patients with lymphatic or venolymphatic malformations of the head and neck,^21,22 and they have an increased incidence in a variety of genetically driven syndromes such as the blue rubber bleb nevus syndrome.²³ These associations suggest that DVA development is not solely a reaction to focal abnormalities of venous drainage but may also be a consequence of widespread perturbations of vascular development. Recent reports have identified associated parenchymal signal abnormalities in 11.6% of children and young adults⁹ and in 12.5% of older adults⁸ with DVAs, suggesting that the altered drainage they provide may have consequences on the surrounding brain. All of these associations lend credence to concerns that DVAs may have a deleterious impact on the surrounding brain or may be a harbinger of more widespread abnormalities. Our findings indicate that DVAs may be more prevalent in pediatric patients with intracranial neoplasms than in controls.

Because DVAs are lesions that primarily impact the brain parenchyma, we limited our study population to those patients with intra-axial tumors. The distribution of tumor types in our study population parallels the known relative prevalence of these lesions in the pediatric population, and the prevalence of DVAs within our study subjects generally follows the distribution of tumor types. We found no statistically significant association of DVA prevalence with tumor type, and the distribution of DVA location within the brain was consistent with that in prior reports.²⁴

The reason that DVAs may be more prevalent in children with primary intracranial neoplasms is not known. The fact that in none of our cases did the DVA drain the territory of the neoplasm essentially eliminates any direct causative link. However, if DVAs are exclusively the result of focal compromise of venous development, the same abnormality that led to the venous compromise may have caused a concomitant insult elsewhere in the brain that increases the risk of developing a neoplasm. Alternatively, if they are a consequence of a more widespread alteration of vascular development, as suggested by their association with venolymphatic malformations and neurocutaneous syndromes, it is conceivable that they may be associated with an increased vulnerability to neoplastic differentiation in the brain tissue.

It is reasonable to question whether the DVAs in this population could be a consequence of treatment for neoplasms, much as cavernous malformations are associated with prior radiation therapy.²⁵ However, in all except 2 of our cases, there was the clearly documented presence of the DVA before any chemotherapy or radiation treatment. There was no instance of a DVA becoming evident with time; they could be identified on the oldest available study for review in all cases. Furthermore, growth in response to therapy contradicts the generally accepted developmental nature of DVAs and would suggest that the DVAs identified in this analysis are substantially different from those recognized in the general population. The standard distribution and characteristic appearance of the DVAs in our study population would argue against this hypothesis. The possibility that the development of a DVA is somehow caused by the presence of a neoplasm elsewhere in the brain cannot be excluded, but the possible causal link is not apparent.

This study is weakened by its retrospective nature and dependence on reporting. It is not a study of lesion prevalence but rather one of lesion-identification prevalence, raising the question of bias in the interpretation of studies in controls compared with subjects. However, the prevalence of DVAs identified in our control population was similar to that demonstrated in the most recent imaging-based studies, suggesting a similar degree of sensitivity of detection. Furthermore, a 10% sampling of cases with negative findings from each group demonstrated no difference between detection rates. The same group of fellowship-trained neuroradiologists generated the reports in each group during their daily clinical practice; because they were working under the general assumption that DVAs are incidental variants with no relation to neoplasms, it is unlikely that they would have been sensitized to their presence in oncologic patients relative to controls. We found no significant differences in examination techniques that would favor the detection of DVA in one group or the other. The fact that most of the subjects had multiple examinations undoubtedly increased the chance of lesion detection, but nearly all DVAs were recognized on the initial studies performed, minimizing the impact of multiple studies.