Limited-angle TOF-PET for intraoperative surgical applications: proof of concept and first experimental data

TL;DR

This study demonstrates the feasibility of limited-angle TOF PET technology for intraoperative cancer detection, showing promising results in identifying small lesions quickly and accurately, potentially surpassing current gamma probe methods.

Contribution

The paper introduces a novel limited-angle TOF PET system for intraoperative use, providing proof of concept and experimental data that show improved lesion detection over traditional gamma probes.

Findings

6 mm lesions identified within 60 seconds

Sub-minute detection of small lymph node analogs

Simulation aligns with experimental lesion detectability results

Abstract

Intraoperative Gamma Probe (IPG) remains the current gold standard modality for sentinel lymph node identification and tumor removal in cancer patients. However, even alongside the optical dyes they do not meet with <5% false negative rates (FNR) requirement, a key metric suggested by the American Society of Clinical Oncology (ASCO). We are aiming to reduce FNR by using time of flight (TOF) PET detector technology in the limited angle geometry system by using only two detector buckets in coincidence, where one small-area detector is placed above the patient and the other with larger detection-area, placed just under the patient bed. For proof of concept, we used two Hamamatsu TOF PET detector modules (C13500-4075YC-12) featuring 12x12 array of 4.2x4.2x20 mm3 LFS crystal pixels, one-one coupled to silicon photomultiplier (SiPM) pixels. Detector coincidence timing resolution (CTR) measured 271 ps FWHM for the whole detector. We 3D printed lesion phantom containing spheres with 2-10 mm in diameter, representing lymph nodes, and placed it inside a 10-liter warm background water phantom. Experimental results show that with sub-minute data acquisition, 6 mm diameter spheres can be identified in the image when a lesion phantom with 10:1 activity ratio to background is used. Simulation results are in good agreement with the experimental data, by resolving 6 mm diameters lesions with 60 seconds acquisition time, in 25 cm deep background water phantom with 10:1 activity ratio. The image quality improves as the CTR improves in the simulation, and with decreasing background water phantom depth or lesion to background activity ratio, in the experiment. With the results presented here we conclude that limited angle TOF PET detector is a major step forward for intraoperative applications in that, improved lesion detectability is beyond what the conventional Gamma- and NIR-based probes could achieve.