Publications

Semiautomatic segmentation and follow‐up of multicomponent low‐grade tumors in longitudinal brain MRI studies

PURPOSE:

Tracking the progression of low grade tumors (LGTs) is a challenging task, due to their slow growth rate and associated complex internal tumor components, such as heterogeneous enhancement, hemorrhage, and cysts. In this paper, the authors show a semiautomatic method to reliably track the volume of LGTs and the evolution of their internal components in longitudinal MRI scans.

METHODS:

The authorsˈ method utilizes a spatiotemporal evolution modeling of the tumor and its internal components. Tumor components gray level parameters are estimated from the follow‐up scan itself, obviating temporal normalization of gray levels. The tumor delineation procedure effectively incorporates internal classification of the baseline scan in the time‐series as prior data to segment and classify a series of follow‐up scans. The authors applied their method to 40 MRI scans of ten patients, acquired at two different institutions. Two types of LGTs were included: Optic pathway gliomas and thalamic astrocytomas. For each scan, a “gold standard” was obtained manually by experienced radiologists. The method is evaluated versus the gold standard with three measures: gross total volume error, total surface distance, and reliability of tracking tumor components evolution.

RESULTS:

Compared to the gold standard the authorsˈ method exhibits a mean Dice similarity volumetric measure of 86.58% and a mean surface distance error of 0.25 mm. In terms of its reliability in tracking the evolution of the internal components, the method exhibits strong positive correlation with the gold standard.

CONCLUSIONS:

The authorsˈ method provides accurate and repeatable delineation of the tumor and its internal components, which is essential for therapy assessment of LGTs. Reliable tracking of internal tumor components over time is novel and potentially will be useful to streamline and improve follow‐up of brain tumors, with indolent growth and behavior.

Authors: Lior Weizman, Liat Ben Sira, Leo Joskowicz, Daniel L. Rubin, Kristen W. Yeom, Shlomi Constantini, Ben Shofty, Dafna Ben Bashat
Year of publication: 2014
Journal: Medical Physics, Volume 41, Issue 5, 052303

Link to publication:

Labs:

“Working memory”