Scintillating fiber dosimeter for radiology
SEDI-ATI designs scintillating fiber optic probes for dosimeter applications applied to radiology.
A societal issue: measuring the radiation dose rate received by the patient
X-rays are nowadays essential in the characterization and metrology of materials, objects and living species, as well as in certain therapies such as cancer therapy for example. One of today’s societal challenges is the quantification of the level of radioactive exposure of the patient during a radiological examination such as a CT or MRI scan.
The idea is to place an ultra-compact and flexible X-ray detector either under or inside the mattress, or even in the headrest, of the examination table where the patient stands.
Radiation sensors based on scintillating and plastic optical fibers
Two solutions are being studied. The first one consists in a fibered probe, of a 500 µm plastic optical fiber and a 500 µm scintillating X-ray sensitive fiber optic section .
The second one is a woven mesh of scintillating optical fibers, which could in addition make it possible to very finely locate the position where the radiation was received.
A unique know-how: splicing between different types of large core optical fibers
SEDI-ATI has a long experience on splicing scintillating optical fibers with plastic optical fibers on both ends to perform a radiation probe. SEDI-ATI has mastered the mechanical process to make a splice on this type of fiber. The junction between the two fibers (plastic and scintillating) is then protected by a stainless steel tube. The splicing between the two fiber types, having a similar 500 µm diameter, is not feasible by fusion but needs to be done by a mechanical process.
NANOPTiX: a pioneering program of the ANR
Thanks to its notoriety on scintillating fibers, SEDI-ATI is the industrial partner in the NANOPTiX project of the French National Research Agency [ANR]. The research project aims to develop the next generation of miniaturized X-ray sensors with faster response time, higher sensitivity and crosstalk free.
This project targets tiny X-ray probes integrated at the end of narrow fibers of the size of a human hair. To this end, NANOPTIX will exploit, for the first time, the concept of Nano-Optical Antenna (NOA) for controlling the X-ray excited luminescence (XEL) from scintillators.