Abstract
Background: Visualization of the precise course of the visual pathways is relevant to prevent damage that may inflict visual field deficits during neurosurgical resections. In particular the optic radiations (OR) are susceptible to such damage during neurosurgery. Cortical pathways can be mapped in vivo, by using Diffusion Tensor Imaging (DTI). Visualization of these pathways would be potentially helpful to prevent neurosurgical visual morbidity. In this study an anatomical dissection of the visual pathways was compared to DTI fiber tractography (DTI-FT) data of four human brains. The feasibility of a definition of a Safety Zone is investigated.Methods: Four adult brains were dissected using Klingler's fiber dissection method, which allowed preparation of the OR. Measurements before and after dissection were used to establish distances from the cortex to the OR. DTI-scans were also obtained from these brains to determine the same distances.Results: Measurements from specific landmark points on the cortex to the lateral border of the OR were performed in four brains. Analysis through DTI tractography corresponded with the dissection results. Based on the combined results of both dissection and DTI-FT, we defined a quantitative surgical Safety Zone with respect to various anatomical landmarks (in particular the ventricle system).Conclusion: We conclude that there is a good correlation between the visualizations of the optic pathways based on dissection and DTI. Furthermore, we conclude that defining a neurosurgical Safety Zone which could preserve the integrity of the OR during surgery, based on the combination of DTI-FT images and dissection is feasible.
Highlights
The anatomical course of axons within the human brain has been initially studied using post-mortem dissections and histological investigations (Forel, 1877; Dejerine, 1901; Riley, 1953; Talairach, 1957; Lemaire et al, 2011)
This study focuses on visualization of the course and key points of the optic radiations (OR) through both anatomical dissection and DTIFT
These results correspond with previous anatomical studies (Ebeling and Reulen, 1988; Choi et al, 2006; Peltier et al, 2006; Sherbondy et al, 2008)
Summary
The anatomical course of axons within the human brain has been initially studied using post-mortem dissections and histological investigations (Forel, 1877; Dejerine, 1901; Riley, 1953; Talairach, 1957; Lemaire et al, 2011). The optic radiations (OR) cannot be identified using the standard view through a microscope (Hofer et al, 2010) This could lead to damage to the OR during neurosurgical resections (Ebeling and Reulen, 1988; Krolak-Salmon et al, 2000; Sincoff et al, 2004; Yasargil et al, 2004; Powell et al, 2005; Rubino et al, 2005; Taoka et al, 2005; Choi et al, 2006; Peltier et al, 2006; Sherbondy et al, 2008).
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