Abstract
Positron emission tomography (PET) plays important roles in cancer diagnosis, neuroimaging, and molecular imaging research. However potential points remain for which big improvements could be made, including spatial resolution, sensitivity, and manufacturing costs. Depth-of-interaction (DOI) measurement in the radiation sensor will be a key technology to get any significant improvement in sensitivity while maintaining high spatial resolution. We have developed four-layered DOI detectors based on our original light-sharing method. DOI measurement also has a potential to expand PET application fields because it allows for more flexible detector arrangement. As an example, we are developing the world’s first, open-type PET geometry, “OpenPET,” which is expected to lead to PET imaging during treatment. The DOI detector itself continues to evolve with the help of recently developed semiconductor photodetectors, often referred to as silicon photomultipliers (SiPMs). We are developing a SiPM-based DOI detector “X’tal cube” to achieve sub-mm spatial resolution, which is reaching the theoretical limitation of PET imaging. Innovation of SiPMs encourages our development of PET/MRI, which is attracting great notice in terms of smaller radiation exposure and better contract in soft tissues compared with current PET/CT.
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1 Introduction
Positron emission tomography (PET) plays important roles in cancer diagnosis, neuroimaging, and molecular imaging research, but potential points remain for which big improvements could be made, including spatial resolution, sensitivity, and manufacturing costs. For example, the sensitivity of present PET scanners does not exceed 10 %. This means that more than 90 % of the gamma rays emitted from a subject are not utilized for imaging. Therefore, research on next generation PET technologies remains a hot topic worldwide.
The Imaging Physics Team at National Institute of Radiological Sciences (NIRS) has carried out basic studies on radiation detectors, data acquisition systems, image reconstruction algorithms, and data correction methods to improve image quality and quantity in nuclear medicine as well as to explore innovative systems.
A depth-of-interaction (DOI) detector, for which various methods have been studied [1–7], will be a key device to get any significant improvement in sensitivity while maintaining high spatial resolution (Fig. 3.1). In order to maintain enough detection efficiency, the scintillation crystals should be 2–3 cm long. In conventional detectors, the crystal thickness causes uncertainty in position identification, which results in degraded spatial resolution at the peripheral area of a field-of-view. On the other hand, DOI can reduce the parallax error while maintaining the efficiency.
We have developed four-layered DOI detectors based on a light-sharing method [8, 9]. One successful proof of concept was the “jPET” project, in which we developed brain prototype PET with our DOI detectors; almost uniform spatial resolution around 2 mm all over the field-of-view was obtained with iterative image reconstruction with geometrically defined system matrix [10]. We have also succeeded to upgrade the DOI detector to have better spatial resolution with cheaper production costs: successful identification of 32 × 32 × 4 array of LYSO crystals sized in 1.45 × 1.45 × 4.5 mm3 with a 64ch flat panel PMT (H8500, Hamamatsu Photonics K.K., Japan) [11], which has enabled Shimadzu’s new products of positron emission mammography.
DOI measurement also has a potential to expand PET application fields because it allows for more flexible detector arrangement. As an example, we are developing the world’s first, open-type PET geometry, “OpenPET,” which is expected to lead to PET imaging during treatment. In addition, flexible system design of OpenPET prototypes is enabling us to develop an innovative brain scanner “helmet-chin PET.” The DOI detector itself continues to evolve with the help of recently developed semiconductor photodetectors, often referred to as silicon photomultipliers (SiPMs). We are developing a SiPM-based DOI detector “X’tal cube” to achieve sub-mm spatial resolution, which is reaching the theoretical limitation of PET imaging. Innovation of SiPMs encourages our development of PET/MRI, which is attracting great notice in terms of smaller radiation exposure and better contract in soft tissues compared with current PET/CT. By using our SiPM-based DOI detectors, we are developing a novel, high-performance, and low-cost brain PET/MRI to meet demands for earlier diagnosis of Alzheimer’s disease. The key concept is a RF coil with DOI PET detectors, which has a potential to upgrade any existing MRI to PET/MRI. In this paper, an overview of above developments is shown.
2 The OpenPET: A Future PET for Therapy Imaging
OpenPET is our original idea to realize the world’s first open-type 3D PET scanner for PET-image guided particle therapy such as in situ dose verification and direct tumor tracking. The principal of dose verification for particle therapy is based on the measurement of positron emitters which are produced through fragmentation reactions caused by proton or 12C ion irradiation. Even with a full-ring geometry, the OpenPET has an open gap between its two detector rings through which the treatment beam passes, while conventional positron cameras applied to particle therapy imaging have been basically limited to planar imaging with lower detection efficiency [12–14]. Following our initial proposal of the dual-ring OpenPET (DROP) in 2008 (Fig. 3.2a) [15], we developed a small prototype in 2010 to show a proof of concept (Fig. 3.2b) [16]. In 2011, we also proposed the single-ring OpenPET (SROP), which is more efficient than DROP in terms of manufacturing cost and sensitivity [17]. We developed two small SROP prototypes in 2012 and 2013 (Fig. 3.2d, e) [18, 19], and we succeeded in visualizing a 3D distribution of beam stopping positions inside a phantom with the help of radioactive beams (11C beam and 10C beam) used as primary beams (Fig. 3.2f) [20]. Following these good results, in 2014, we have finally developed a whole-body prototype of DROP (Fig. 3.2g) [21].
The key technology which enabled OpenPET is our original, four-layered DOI detector. In order to measure radiations from the limited activity produced though fragmentation reactions, Zr-doped GSO (GSOZ), which contains less natural radioactivity, was chosen for the scintillators instead of Lu-based scintillators although timing performance was compromised. In order to compensate for the limited light yield, on the other hand, we used 64-channel, flat-panel PMTs with a super-bialkali photocathode (Hamamatsu R10552-100-M64), which had a 30 % higher quantum efficiency [22]. In order to enable stable in-beam PET measurement even under high background radiations, voltage divider circuits were designed so as to have five times higher linearity. In order to avoid severe radiation damage, in addition, gain control ASICs were not implemented in the front-end circuits, and position analyzer circuits were placed with a 15-m cable extension. A data acquisition system was developed based on the single events collection.
The prototype consisted of two detector rings, and each detector ring had two subrings of 40 detectors. Each detector consisted of 16 × 16 × 4 array of GSOZ (2.8 × 2.8 × 7.5 mm3). The portable gantry had a compact design; each detector ring had a 940 mm outer diameter and 171 mm thickness for the detector inner bore of 640 mm diameter and 113 mm thickness.
3 The Helmet-Chin PET for Super High-Sensitive Brain Imaging
For a potential demand for brain molecular imaging, prototypes of brain dedicated PET scanners have been developed. However all previous developments are based on a cylindrical geometry [3, 10, 23–25], which is not the most efficient for brain imaging. Making the detector ring as small as possible is essential in PET, because sensitivity can be increased with a limited number of detectors. With appropriate DOI detectors, which reduce the parallax error caused by the thickness of the scintillators, spatial resolution can be maintained, or even improved by reducing the angular deviation effect. Therefore, we developed the world’s first helmet-chin PET, in which DOI detectors are arranged to form a hemisphere, for compact, high-sensitivity, high-resolution, and low-cost PET imaging [26, 27].
Our basic idea relies on the evidence that the average sensitivity of a hemisphere PET is about 1.5-times higher than that of a cylinder PET of the same radius and height, while surface area is the same for both geometries (Fig. 3.3a, b). In addition, use of 12 % more detectors for “chin detectors,” which are placed like a chin strap, improves sensitivity especially at the central area (Fig. 3.3c). In the prototype, 47 block detectors were used to form a hemisphere of 25 cm inner diameter and 50 cm outer diameter, and seven block detectors were used for the chin strap (Fig. 3.3d). The total number of detectors was about only 1/5 of that to be used in whole body PET. Each detector block was a four-layered DOI detector, which consisted of 1024 Zr-doped GSO crystals (2.8 mm × 2.8 mm × 7.5 mm) and a high-sensitivity type of 64-channel flat-panel PMT. The data acquisition system was developed based on single event collection. An iterative reconstruction method with detector modeling was applied.
Measured sensitivity was 5 % at the cerebellum region and 10 % at the parietal region for a standard 400–600 keV energy window. Averaged FWHM of point sources was 3.0 mm (FBP) and 1.4 mm (iterative) (Fig. 3.3e).
4 The X’tal Cube: 0.8 mm Isotropic Resolution, a World Record
X’tal (crystal) cube is a future DOI detector we are developing. SiPMs, multi-pixel photon counters (MPPCs), are coupled on all sides of a scintillation crystal block, which is segmented into a 3D array of cubes [28] (Fig. 3.4a). Crystal segmentation is made by irradiating a laser to a monolithic crystal (Fig. 3.4b) [29]. No reflector is inserted into the crystal block so that scintillation light originating in one of the cubic segment spreads 3-dimensionally and distributes among all MPPCs on the crystal block. In 2012, we achieved 1-mm cubic resolution with 18 × 18 × 18 segments made by 3D laser processing (Fig. 3.4c, d) [30, 31]. In the last year, we succeeded in identifying (0.8 mm)3 crystal segments, which is a world record [32].
5 The Add-On PET: A PET Insert to Upgrade Existing MRI to PET/MRI
One of the major innovations made in recent years is combined PET/MRI (Fig. 3.5a) [33–46], but utilization of DOI measurement in PET detectors has not been studied well. DOI measurement, which allows for use of a smaller detector ring, is essential for PET in order to exploit the excellent potentials of PET imaging in terms of improved spatial resolution and sensitivity as well as reduced production costs of PET instrument. Therefore we proposed a new combined PET/MRI that makes full use of DOI measurement (Fig. 3.5b) [47, 48].
In order to make a PET detector ring as small as possible while placing electronic parts such as photodetectors and front-end circuits outside of a RF coil, PET detector modules were placed between spokes of the birdcage RF coil (Fig. 3.5c). For each detector module, electronic parts were covered with a Cu shielding box with a hole in front of the photodetectors, and scintillators were sticking out of the shielding box to allow their placement inside of the birdcage coil (Fig. 3.5e). In theory, the proposed birdcage coil integrated with PET detectors can be applied to any existing MRI as an additional choice of RF coils. For a proof of concept, we developed a full-ring prototype (four-layered arrays of 2.0 mm-LYSO with MPPCs) (Fig. 3.5d), which was applied to a 3T MRI (MAGNETOM Verio, Siemens) (Fig. 3.5f).
After evaluating interference between PET and MRI, no undesirable effect was seen in the PET imaging in terms of energy resolution and position identification. While a uniform static magnetic field was obtained, about a 20 % decrease in signal-to-noise ratio was observed in MR images; we suspected this was due to noise contamination from outside the MRI room. Although further optimization is required for shielding, we demonstrated a proof of concept of the proposed head coil with DOI PET detectors (Fig. 3.5g).
6 Conclusions
In PET, DOI measurement is a key technology to get significant improvement in sensitivity while maintaining high spatial resolution. DOI measurement also has a potential to expand PET application fields because it allows for more flexible detector arrangement. In this paper, two current developments, the OpenPET toward PET-image guided particle therapy and the helmet-chin PET for high-sensitive brain imaging, were shown. Current development status of the next-generation DOI detector X’tal cube, which uses SiPMs as a photosensor, was also described. SiPM-based DOI detector enabled the add-on PET, which is a PET insert having a potential to upgrade existing MRI to PET/MRI.
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Acknowledgments
The author would like to acknowledge the support of all research members engaged in the OpenPET project, the helmet-chin PET project, the X’tal cube project, and the add-on PET project. The OpenPET project was partially supported by the Grant-in-Aid for Scientists Research (A) of Kakenhi (22240065 and 25242052). The helmet-chin PET project was partially supported by ATOX Co., Ltd. (Tokyo, Japan). The X’tal cube project was partially supported by the Japan Science and Technology Agency (JST). The add-on PET project was partially supported by the JST and the Japan Agency for Medical Research and Development (AMED).
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Yamaya, T. (2016). PET Imaging Innovation by DOI Detectors. In: Kuge, Y., Shiga, T., Tamaki, N. (eds) Perspectives on Nuclear Medicine for Molecular Diagnosis and Integrated Therapy. Springer, Tokyo. https://doi.org/10.1007/978-4-431-55894-1_3
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