Summary: The NeuroEXPLORER PET system, presented at the 2024 SNMMI Annual Meeting and awarded the 2024 SNMMI Henry N. Wagner, Jr., Image of the Year, offers unprecedented measurement of brain nuclei with high sensitivity and resolution, showing significant improvement over the HRRT scanner and potential for advancing brain disease treatments.

Key Takeaways:

  1. The NeuroEXPLORER PET system offers unprecedented measurement of brain nuclei with high sensitivity and resolution, showing significant improvement over the HRRT scanner.
  2. This research was presented at the 2024 SNMMI Annual Meeting, earning the 2024 SNMMI Henry N. Wagner, Jr., Image of the Year for its advanced brain PET images.
  3. Developed in collaboration with Yale, UC Davis, and United Imaging, the NeuroEXPLORER aims for future clinical use pending recognition of its image quality by physicians.

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A new ultra-high-performance brain PET system allows for the direct measurement of brain nuclei as never before seen or quantified. With its ultra-high sensitivity and resolution, the NeuroEXPLORER provides advanced brain PET images and has the potential to spur advances in the treatment of many brain diseases. This research was presented at the 2024 Society of Nuclear Medicine and Molecular Imaging (SNMMI) Annual Meeting, and the grouping of images highlighting targeted tracer uptake in specific brain nuclei has been selected as the 2024 SNMMI Henry N. Wagner, Jr., Image of the Year.

Each year, SNMMI chooses an image that best exemplifies the most promising advances in the field of nuclear medicine and molecular imaging. The state-of-the-art technologies captured in these images demonstrate the capacity to improve patient care by detecting disease, aiding diagnosis, improving clinical confidence, and providing a means of selecting appropriate treatments. This year, the SNMMI Image of the Year was chosen from more than 1,500 abstracts submitted for the meeting.

NeuroEXPLORER Vs. HRRT PET scanners

The image quality of PET systems has improved in recent years, mostly by increases in sensitivity, including enhanced time-of-flight capabilities. However, these systems have shown only minimal improvement in intrinsic resolution. To address these issues, researchers designed the NeuroEXPLORER PET scanner with a focus on ultra-high sensitivity and resolution, as well as continuous head motion correction.

In the study, researchers conducted human brain imaging with both the NeuroEXPLORER and the High Resolution Research Tomograph, or HRRT (the previous state-of-the-art imaging tool). Multiple targeted radiopharmaceuticals were administered to observe synaptic density, dopamine receptors and transporters, muscarinic cholinergic receptors, and glutamate receptors. Images from both scanners were then compared.

A striking improvement in image contrast and quality of the NeuroEXPLORER compared to the HRRT was evident. NeuroEXPLORER images demonstrated low noise and exquisite resolution, showing focal uptake in specific brain nuclei.

“The high resolution of NeuroEXPLORER images is due to the system’s unique detector design and exceptional sensitivity produced by its long axial field-of-view,” says Richard E. Carson, PhD, professor of Biomedical Engineering and of Radiology and Biomedical Imaging and Emeritus director of the PET Center at Yale University in New Haven, Conn. “This technology will provide the opportunity for advanced research on all types of neuronal molecular and functional activity.”

“The dramatic improvement in resolution and overall quality of the NeuroEXPLORER images compared to the HRRT images is clear,” says SNMMI Scientific Program Committee chair Heather Jacene, MD. “The NeuroEXPLORER has the potential to be a gamechanger in research for conditions such as Alzheimer’s disease, Parkinson’s disease, epilepsy, and mental illnesses.”

Aspirations for Clinical Use

The NeuroEXPLORER scanner was built as a collaboration with Yale University, University of California, Davis, and United Imaging Healthcare of America, and was funded by a National Institutes of Health Brain Initiative grant. While the NeuroEXPLORER is currently used for research purposes, Carson and colleagues hope that once the excellent image quality is recognized by physicians it will become available for clinical use.

Featured image: 18F-SynVesT-1 images at early (0-10) and late (90-120 minute) times postinjection. There is clear identification of high flow regions in the early images. The late images show the synaptic (SV2A) pattern which differs from the flow pattern, e.g., in the thalamus. B. 11C-PHNO binding potential (BPND) images shown in transverse, coronal, and sagittal orientations of PET alone and PET overlaid with MRI. Left: Region of substantia nigra (green arrow, max display: 4.0). Right: Thalamic region (max: 2.5) showing focal bilateral binding in a specific thalamic nucleus (blue arrow, likely anteroventral nucleus). C. Sagittal images of 11C-LSN3172176 M1 muscarinic cholinergic BPND (max display: 10). D. Rimages of the same tracer (max: 2). Cerebellum (blue arrow) shows no specific binding (C) and high tracer delivery (D). E. 18F-FE-PE2I dopamine transporter BPND images (zoomed, max display: 6) showing striatum and substantia nigra (green arrow). F. Rimages of the same tracer (max: 2) with inset showing zoomed region in E.