Outcomes of multilobar resections for epilepsy in Sweden 1990-2013: a national population-based study.

BACKGROUND: Reports on outcome after multilobar resection (MLR) are scarce and most are retrospective single-centre studies or case studies with few patients. The aim of this study is to present seizure and complication outcomes 2 years after MLR in a prospective population-based series. METHOD: The Swedish National Epilepsy Surgery Registry (SNESUR) provides prospective population-based data on outcome and complications after epilepsy surgery. For this study, we have analysed data on seizure outcome and complications after MLR from the SNESUR between 1990 and 2013. RESULTS: Fifty-seven patients underwent MLR; 40/57 surgeries were performed between 1990 and 2000. Sixteen operations were classified as partial hemispherotomy. Resections were right-sided in 33 (58 %) patients. Mean age was 17.3 years (range, 0.3-63.4 years) and mean duration of epilepsy before surgery was 11.0 years (range, 0.2-37 years). Preoperative neurological deficits were seen in 19 patients (33.3 %). Learning disability (LD) was seen in 18 patients (31.6 %), six had severe LD (IQ <50). Seizure outcome after 2 years was available for 53 patients. Thirteen (24.5 %) were seizure-free and 12 (22.6 %) had >75 % seizure frequency reduction. Three (5.3 %) patients suffered major complications: infarction of the middle cerebral artery, epidural abscess and hemiparesis. Minor complications were seen in ten patients. There was no mortality. CONCLUSIONS: This prospective, population-based study provides data on seizure outcome and complications after MLR. In selected patients MLR can be considered, but expectations for seizure freedom should not be too high and patients and parents should be counselled appropriately.

Tractography of Meyer's loop for temporal lobe resection­validation by prediction of postoperative visual field outcome‬‬‬‬.

BACKGROUND: Postoperative visual field defects are common after temporal lobe resection because of injury to the most anterior part of the optic radiation, Meyer's loop. Diffusion tensor tractography is a promising technique for visualizing the optic radiation preoperatively. The aim of this study was to assess the anatomical accuracy of Meyer's loop, visualized by the two most common tractography methods­deterministic (DTG) and probabilistic tractography (PTG)­in patients who had undergone temporal lobe resection. METHODS: Eight patients with temporal lobe resection for temporal lobe pathology were included. Perimetry and diffusion tensor imaging were performed pre- and postoperatively. Two independent operators analyzed the distance between the temporal pole and Meyer's loop (TP-ML) using DTG and PTG. Results were compared to each other, to data from previously published dissection studies and to postoperative perimetry results. For the latter, Spearman's rank correlation coefficient (r(s)) was used. RESULTS: Median preoperative TP-ML distances for nonoperated sides were 42 and 35 mm, as determined by DTG and PTG, respectively. TP-ML assessed with PTG was a closer match to dissection studies. Intraclass correlation coefficients were 0.4 for DTG and 0.7 for PTG. Difference between preoperative TP-ML (by DTG and PTG, respectively) and resection length could predict the degree of postoperative visual field defects (DTG: r(s) = -0.86, p < 0.05; PTG: r(s) = -0.76, p < 0.05). CONCLUSION: Both DTG and PTG could predict the degree of visual field defects. However, PTG was superior to DTG in terms of reproducibility and anatomical accuracy. PTG is thus a strong candidate for presurgical planning of temporal lobe resection that aims to minimize injury to Meyer's loop.

Strengths and limitations of tractography methods to identify the optic radiation for epilepsy surgery.

Diffusion tensor imaging (DTI) tractography (TG) can visualize Meyer's loop (ML), providing important information for the epilepsy surgery team, both for preoperative counseling and to reduce the frequency of visual field defects after temporal lobe resection (TLR). This review highlights significant steps in the TG process, specifically the processing of raw data including choice of TG algorithm and the interpretation and validation of results. A lack of standardization of TG of the optic radiation makes study comparisons challenging. We discuss results showing differences between studies and uncertainties large enough to be of clinical relevance and present implications of this technique for temporal lobe epilepsy surgery. Recent studies in temporal lobe epilepsy patients, employing TG intraoperatively, show promising results in reduction of visual field defects, with maintained seizure reduction.

Visualizing Meyer's loop: A comparison of deterministic and probabilistic tractography.

BACKGROUND: Diffusion tensor tractography of the anterior extent of the optic radiation - Meyer's loop - prior to temporal lobe resection (TLR) may reduce the risk for postoperative visual field defect. Currently there is no standardized way to perform tractography. OBJECTIVE: To visualize Meyer's loop using deterministic (DTG) and probabilistic tractography (PTG) at different probability levels, with the primary aim to explore possible differences between methods, and the secondary aim to explore anatomical accuracy. METHODS: Twenty-three diffusion tensor imaging exams (11 controls and 7 TLR-patients, pre- and post-surgical) were analyzed using DTG and PTG thresholded at probability levels 0.2%, 0.5%, 1%, 5% and 10%. The distance from the tip of the temporal lobe to the anterior limit of Meyer's loop (TP-ML) was measured in 46 optic radiations. Differences in TP-ML between the methods were compared. Results of the control group were compared to dissection studies and to a histological atlas. RESULTS: For controls and patients together, there were statistically significant differences (p<0.01) for TP-ML between all methods thresholded at PTG ≤1% compared to all methods thresholded at PTG ≥5% and DTG. There were no statistically significant differences between PTG 0.2%, 0.5% and 1% or between PTG 5%, 10% and DTG. For the control group, PTG ≤1% showed a closer match to dissection studies and PTG 1% showed the best match to histological tracings of Meyer's loop. CONCLUSIONS: Choice of tractography method affected the visualized location of Meyer's loop significantly in a heterogeneous, clinically relevant study group. For the controls, PTG at probability levels ≤1% was a closer match to dissection studies. To determine the anterior extent of Meyer's loop, PTG is superior to DTG and the probability level of PTG matters.