Abstract
PurposeDuring resections of brain tumors, neurosurgeons have to weigh the risk between residual tumor and damage to brain functions. Different perspectives on these risks result in practice variation. We present statistical methods to localize differences in extent of resection between institutions which should enable to reveal brain regions affected by such practice variation.MethodsSynthetic data were generated by simulating spheres for brain, tumors, resection cavities, and an effect region in which a likelihood of surgical avoidance could be varied between institutions. Three statistical methods were investigated: a non-parametric permutation based approach, Fisher’s exact test, and a full Bayesian Markov chain Monte Carlo (MCMC) model. For all three methods the false discovery rate (FDR) was determined as a function of the cut-off value for the q-value or the highest density interval, and receiver operating characteristic and precision recall curves were created. Sensitivity to variations in the parameters of the synthetic model were investigated. Finally, all these methods were applied to retrospectively collected data of 77 brain tumor resections in two academic hospitals.ResultsFisher’s method provided an accurate estimation of observed FDR in the synthetic data, whereas the permutation approach was too liberal and underestimated FDR. AUC values were similar for Fisher and Bayes methods, and superior to the permutation approach. Fisher’s method deteriorated and became too liberal for reduced tumor size, a smaller size of the effect region, a lower overall extent of resection, fewer patients per cohort, and a smaller discrepancy in surgical avoidance probabilities between the different surgical practices. In the retrospective patient data, all three methods identified a similar effect region, with lower estimated FDR in Fisher’s method than using the permutation method.ConclusionsDifferences in surgical practice may be detected using voxel statistics. Fisher’s test provides a fast method to localize differences but could underestimate true FDR. Bayesian MCMC is more flexible and easily extendable, and leads to similar results, but at increased computational cost.
Highlights
Despite intensive chemotherapy, radiotherapy, and surgery regimens, prognosis for glioblastoma patients remains poor
For a single patient it is not possible to say which plan would be superior, but using larger cohorts of patients it should be possible to compare the surgical practices of two teams and learn how to strike a better compromise between tumor control and toxicity
Risk-minus values over all elements and all (1000) permutations were collected in a cumulative histogram, representing the null distribution. p-values per element were derived by looking up the cumulative count at the observed risk-minus
Summary
Radiotherapy, and surgery regimens, prognosis for glioblastoma patients remains poor. Stopping early may incur earlier tumor recurrence, while stopping late may compromise tumor-infiltrated functional brain tissues. Such decisions are generally discussed within a surgical team, based on the available MR imaging and clinical status. The result of such a discussion is a surgical plan, aiming for the maximum extent of resection attainable for that patient. Another team presented with the same patient might well make other decisions, and come to a different surgical plan. For a single patient it is not possible to say which plan would be superior, but using larger cohorts of patients it should be possible to compare the surgical practices of two teams and learn how to strike a better compromise between tumor control and toxicity
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
