Towards Improved Outcomes for Cavernous Malformations of the Brainstem and Other "Critical" Function Brain Regions.

[BACKGROUND AND OBJECTIVES] To determine whether the size of the surgical pial-ependymal surface entry, relative to lesion size, predicts long-term functional outcome in the microsurgical treatment of cavernous malformations in brain regions with "critical function," including brainstem, thalamus, internal capsule, basal ganglia, and hypothalamus. We aimed to evaluate whether using the microtip flexible OmniGuide CO2 laser achieves more favorable entry geometries than conventional microsurgical techniques. The exemplar surgical pathology consisted of cavernous malformations, which are characteristically encountered in these regions.

[METHODS] We retrospectively analyzed 234 patients (140 laser, 94 conventional) with data on lesion (234 cavernous malformations) and entry size. A subgroup of 188 patients (101 laser, 87 conventional) had preoperative and long-term modified Rankin Scale scores available for outcome analysis. Entry-to-lesion size ratios were compared across groups. Functional improvement was defined as a reduction in modified Rankin Scale from baseline to the last follow-up. Logistic regression, spline modeling, and causal mediation analysis were evaluated for predictive value and the mechanistic role of entry geometry.

[RESULTS] Laser-assisted resection resulted in lower entry-to-lesion ratios than conventional surgery (mean 0.383 vs 0.539; P < .001), with lower average entry size compared with traditional microsurgery (4.9 mm vs 8 mm). In the outcome-assessable subgroup, lower entry-to-lesion ratios independently predicted functional improvement (slope = -1.71, P = .045; odds ratio [OR] = 0.981, 95% CI: 0.964-0.998, P = .029). Spline modeling delineated ratio thresholds corresponding to "ideal," "safe," and "risk" thresholds for recovery probability. Mediation analysis demonstrated approximately 51% of the benefit of laser surgery was mediated through a reduction in the entry-to-lesion ratio (P = .034).

[CONCLUSION] Entry-to-lesion ratio is a quantifiable predictor of neurological recovery after resection of deep lesions in critical brain regions. Laser microsurgery facilitates smaller, precision pial-ependymal access which may mediate their functional advantage. Entry burden should be considered a modifiable parameter in preoperative planning.