Seven-Probe Fiber Detector for Time-Resolved Source Tracking in HDR-Brachytherapy: Experimental Evaluation

Abstract

Purpose: This study evaluates a compact biocompatible Seven-probe Scintillator Detector (7SD) for monitoring HDR-BT treatment sequences across a range of dwell times and source-probe spacings representative of most HDR-BT techniques. Methods: The SSD comprises seven detection cells made of Gd2O2S:Tb, each measuring 0.28 0.02 mm in diameter and 0.43 0.02 mm in length, coupled to the microstructured tips of silica optical fibers (110-micron diameter). The probes, spaced 15 mm apart along the fiber axis, are organized into a bundle with a total diameter of less than 0.45 mm. The SSD was tested using a MicroSelectron 9.1 Ci Ir-192 HDR afterloader connected to a BT stainless steel interstitial needle. Detection signals were acquired with an sCMOS camera equipped. Monitoring of dwell times and positions was performed by combining detection signals from all seven probes. Results: A total of 4,040 dwell positions were analyzed, covering source-probe spacings from 10 to 36 mm and a source travel range of 62 mm, with dwell times ranging from 0.1 to 19.5 s. The 7SD successfully identified 99.5\% of the dwell positions. In cylindrical coordinates, the measured dwell positions deviated from the planned values by 0.224 0.155 mm (radial) and 0.077 0.181 mm (axial, source travel axis). The average deviation from planned dwell times was 0.006 0.061 s. 99.4\% of the dwell positions were measured within the 1 mm reliability threshold. The remaining 0.6\% of deviations consistently occurred at the initial dwell position of treatment sequences and appear to stem from a systematic source positioning error by the afterloader. Additionally, the detector accurately identified intentional needle mispositioning scenarios with sub-millimeter accuracy.