Time-of-Flight PET/CT Imaging of Ga-68-Dotatate: Normal Pattern, SUV Quantification, and Differences from Non-Time-of-Flight Imaging

• Introduction
• Conventional Non-TOF PET/CT Cameras versus TOF PET/CT Cameras
• Materials and Methods
• Study Population
• Radiopharmaceutical
• Ga-68-Dotatate PET/CT Imaging Protocol
• Image Analysis
• Statistical Analysis
• Results
• Physiologic Biodistribution of Ga-68-Dotatate in Normal Structures with TOF/Non-TOF Algorithm
• Spectrum of Uptake in Lesions TOF versus Non-TOF
• TOF versus Non-TOF SUVmax Comparison and Statistical Significance
• Discussion
• Study Limitations
• Validity of Non-TOF Uptake Data
• Ga-68-Dotatate Distribution in TOF versus Non-TOF
• Conclusion
• References

Abstract

Purpose The biodistribution of gallium-68-dotatate (Ga-68-dotatate) and standardized uptake values (SUVs) using non-time-of-flight (TOF) positron emission tomography/computed tomography (PET/CT) cameras is well established. However, with the eventual retirement of older PET cameras and their replacement with newer, highly sensitive TOF PET/CT cameras, where SUV_max measurements are reportedly higher, updated knowledge of normal SUV_max range is needed and, to our knowledge, not previously reported. Our objectives are as follows:

1. To establish normal Ga-68-dotatate TOF SUV_max database for common structures and to aid the visual detection of abnormalities objectively.

2. To compare SUV_max values using the TOF and non-TOF algorithms.

Methods Fifty consecutive patients referred routinely to our nuclear medicine service (20 men, 30 women; median age 55 years) with presumed neuroendocrine tumors underwent Ga-68-dotatate scans on a PET-CT camera having capability of reconstructing both TOF/non-TOF images. Region of interests (ROIs) were drawn around 24 normal structures as well as the primary lesion with abnormal radiotracer uptake and SUV_max was measured. The same ROI was analyzed using both algorithms simultaneously and both TOF and non-TOF SUV_max values were compared.

Results Twelve hundred ROIs were evaluated. Non-TOF Ga-68-dotatate uptake in normal structures was in alignment with previously published studies. As compared to non-TOF, TOF images had better target to background ratios visually. TOF SUV_max was higher for all structures except for lung and brain. TOF SUV_max was more than double in adrenals/uncinate process of the pancreas; approximately 1.8 times in abnormal lesions, lymph nodes, pineal gland; and greater than 1.5 times in thyroid, breast, and pancreatic head.

Conclusion Normal database of Ga-68-dotatate TOF SUV_max is provided for common structures to aid visual detection of abnormalities objectively. Overall, TOF SUV_max measures higher in identical ROIs, with abnormal lesions measuring approximately 1.8 times higher versus non-TOF technology. These findings need to be taken in consideration when comparing patient scans imaged on different PET/CT technologies.

Introduction

Surveillance, epidemiology, and end results data from 1973 to 2012 shows that even though neuroendocrine tumors (NET) are rare tumors, their incidence is gradually rising over the years.[1] Accordingly, there has been an increased need for improved methods of imaging these tumors. Somatostatin receptors (SSTR) are high-affinity G protein membrane receptors that are preferentially expressed in neuroendocrine cells. These SSTRs have five subtypes with subtype 2/SSTR2 representing higher density in most NETs as well as lung, breast, and prostate cancer.[2] [3] [4] These SSTR2 receptors proved to be a viable target for SST analogues. In the early 1990s, diethylene triamine penta-acetic acid-octreotide (pentetreotide or DTPA-octreotide) was developed and radiolabeled with Indium-111 (In-111). Its binding to SSTR was imaged via gamma camera and had a proven sensitivity of greater than 75%.[5] In-111 octreotide's main detractors were its extended time from injection to imaging (up to 48 hours), high radiation dose, and lower image resolution. In 2016, gallium-68 dotatate (Ga-68-dotatate) was approved by the Food and Drug Administration for use with positron emission tomography (PET)/computerized tomography (CT) cameras. Ga-68-dotatate was proven to be highly sensitive, specific, and accurate (94%), and versus In-111 octreotide, Ga-68-dotatate PET/CT had 100 times the affinity for SST2 receptors, a lower overall radiation dose (0.08 vs. 0.02 millisieverts/megabecquerel) (mSv/MBq) and required less than two hours to complete the entire study.[6] [7] Ga-68-dotatate uptake is determined by visual analysis and assisted by semiquantitative measures such as maximum standardized uptake value (SUV_max). SUV is a surrogate for concentration of radiotracer activity in a lesion and is calculated using voxel values of activity concentration per unit volume (kilobecqueral [kBq]/milliliters [mL]) normalized to the available concentration of radiotracer injected in the patient's body (injected radiotracer activity in Mbq divided by patient weight in kilograms [kg]). It is calculated using the following formula.

SUV_max represents the maximum voxel value within a region of interest (ROI) and is most commonly used clinically as it is not prone to observer variation. It helps in objectively differentiating abnormal activity from physiological distribution, and comparing it to reference organs such as liver and spleen for interpretation.[8] [9] [10] Due to these advancements, Ga-68-dotatate PET/CT has rapidly become the preferred imaging modality for evaluating NETs.[6] [11] [12] Just as SST analogues and new radiopharmaceuticals continue to emerge, new imaging technology and more sensitive and specific cameras continue to unfold such as the newer time-of-flight (TOF) cameras.

Conventional Non-TOF PET/CT Cameras versus TOF PET/CT Cameras

In conventional PET imaging, a positron released from the radiotracer annihilates with an electron and releases two photons in opposite directions along a 180-degree line of response (LOR). During the PET scan, the released photons from the annihilation striking the opposing detectors at nearly the same time are included for image construction, and the slight time difference of their detection allows computers to determine their approximate location along the LOR. Multiple intersecting LORs are then used to determine a more precise location of the annihilation event, thereby the site of radiotracer accumulation. Ultimately, using CT attenuation correction and the anatomical images obtained from the CT, the exact location in the body where the annihilation event occurred is determined.[13] Conventional PET/CT cameras (a.k.a. the non-TOF cameras) detect the slight time difference of annihilation photons striking the detectors within nanoseconds. They utilize all the coincident photons striking their detectors within a coincidence time window of about 10 nanoseconds for scintillation detection and image generation.

In 2006, a more advanced technology that could detect even shorter time differences of photon detection was introduced, which has progressively improved over the years. These advancements in technology have introduced newer scanners, such as those employing lutetium-based crystal scintillators or digital systems utilizing silicon photomultipliers. These innovations allow for a more precise recording of the difference in coincident photon arrival times, decreasing the coincidence time window to approximately 0.6 nanoseconds. Consequently, this enhancement facilitates superior localization of the annihilation event, resulting in improved signal-to-noise ratio and temporal resolution, and more sensitive imaging. This technique is used by various manufacturers who give it different names and is referred to as TOF imaging by GE (Boston, Massachusetts, United States) PET/CT camera system. This TOF PET/CT technology allowing for more precise measurement of the time difference between photon detection down to the pico-second is becoming increasingly sought after.[13] This additional ultra-short time difference data shortened the spread of activity allowing the detection algorithms to decrease the spread of activity along the LOR, provide even more precise. This additional ultra short time difference data allows the detection algorithms to shorten the spread of activity along the LOR, providing even more precise localization, better target to background ratio, improved image quality, and more accurate detection of abnormal lesions. This decrease in spread of activity is one of the reasons for higher SUV_max noted with TOF imaging, especially for smaller lesions. With the eventual retirement of older non-TOF PET cameras and their replacement with newer, highly sensitive TOF PET/CT cameras, where SUV_max measurements are reportedly higher, updated knowledge and database of normal ranges of SUV_max are needed.

To our knowledge, TOF SUV_max in normal structures on Ga-68-dotatate scans has not been previously reported. Additionally, awareness of how much the TOF SUV_max differs from the non-TOF value is required for adequate scan comparisons, while the different technologies coexist, and for follow-up examinations over a period when camera technology may change between scans. Our study objectives were as follows:

1. To establish normal average TOF SUV_max values for common structures on Ga-68-dotatate PET/CT

2. To compare SUV_max values obtained using the TOF and non-TOF algorithms.

Materials and Methods

Retrospective analysis of 77 consecutive clinically referred Ga-68-Dotatate scans was performed. Only the scans performed on the new PET-CT camera that had the capability of creating images using both TOF and non-TOF image reconstruction capability were included in the study. Only 50 patients underwent imaging on the camera with both reconstruction capabilities and were included in the analysis. The remaining 27 patients did not undergo scanning using both reconstruction capability due to camera availability and thus did not have comparison TOF versus non-TOF imaging and were excluded. Since there were no specific characteristics of the excluded 27 patients, the generalizability of the results is not affected.

Upon submission of this study's objectives and design, the parent institution's Department of Research Programs determined that this project did not require Institutional Review Board approval as per 32 Code of Federal Regulation 219.102 and Department of Defense Instruction 3216.02 and approved the conduction of the study as a quality improvement project.

Study Population

Inclusion criteria for the retrospective analysis were as follows: (1) Any patient with known/presumed NET clinically imaged on the PET-CT camera having both the TOF and non-TOF reconstruction capability, (2) age older than 18 years, (3) not pregnant. Retrospective analysis of 77 consecutive Ga-68-dotatate patient scans from 2016 to 2019 was performed out of which 50 patients (20 men and 30 women; median age 55 years; range 18–88; median weight 88.5 kg, see [Table 1]) were selected. Twenty patients were excluded as they underwent imaging with only TOF reconstruction without having comparison non-TOF analysis. Their exclusion should thus not affect the generalizability of this study as the lack of dual analysis was the only known variable. All patients were imaged using identical PET imaging protocol.

Radiopharmaceutical

Unit doses of Ga-68-dotatate for each clinical patient were manufactured as per standard manufacturing protocol in commercial pharmacies following strict nuclear pharmacy regulations.[14] These clinical doses were received by a nuclear pharmacist and inspected for colorless and particulate free appearance. The doses were injected, and patients were imaged using identical PET imaging protocols.

Ga-68-Dotatate PET/CT Imaging Protocol

Patients were asked to fast 2 hours prior to injection. A minimum of 24 hours after short-acting SST analogues or just prior to the next dose of long-acting SST analogues was required. Patients were then injected with a prescribed dose of 185 MBq / 5 millicurie (mCi) of Ga-68-dotatate. Average dose was 4.6 mCi, and median was 4.9 mCi. The average interval between injection to scan time was 61 minutes. Whole body imaging was performed from vertex to mid-thigh without contrast. Imaging was performed on a Siemens Biograph mCT (Munich, Germany) (see [Table 2]).

A CT scout image was acquired with 120kVp, 35mA, over 10.5 seconds. Whole-body CT images were acquired at 120kVp, weight-based mA, 1.0 pitch, and 3 mm slices. Maintaining patient position, a PET emission scan was performed in three-dimensional mode and a 5-slice overlap between consecutive bed acquisitions at 4 minutes/bed. PET images were reconstructed using an ordered subsets expectation maximization algorithm using 2 iterations and 21 subsets per manufacturer recommendations and CT-based attenuation correction.[15] Transaxial PET slice thickness was 3mm on the Siemens mCT (Munich, Germany). PET slice thickness was matched to CT slice thickness.

Image Analysis

Ga-68-dotatate uptake was measured via SUVs calculated using the following equation as described previously:

where r is the radioactivity activity concentration [kBq/ml] measured by the PET scanner within a ROI, a′ is the decay-corrected amount of injected radiolabeled FDG [kBq], and w is the weight of the patient, which is used a surrogate for a distribution volume of tracer.[16] Maximum SUV (SUV_max) within a ROI is the most commonly utilized clinically. It represents the maximum voxel value within that ROI and remains unaffected by observer variation.

Images were reviewed by a board-certified nuclear medicine physician and 5th year radiology resident using a Hermes workstation (Hermes Medical Solutions, Stockholm). SUV_max was measured on axial images. Each image was processed using TOF and non-TOF reconstruction algorithms ([Fig. 1]). A semiautomated 1-centimeter square (cm²) ROI was drawn on 24 anatomically normal appearing structures ([Table 3]) to measure SUV_max while avoiding any confounding adjacent activity or areas concerning for any possible disease or abnormality on CT and when unavoidable, a manually contoured region was drawn ([Fig. 2]). The 1 cm² ROI was placed on the area with the highest appearing uptake visually while avoiding adjacent organs. The same ROI was analyzed using both algorithms and the SUV_max was compared. Bone marrow uptake was measured at the 5th lumbar vertebral body, blood uptake was measured at the left atrium, and lung uptake was measured at the right upper lobe. Manual ROIs were also drawn for the suspected tumor lesion.

Statistical Analysis

Average values were calculated for all data such as age, radiopharmaceutical dose, and imaging time. Data was shown as an average of SUV_max with a 95% confidence interval (CI) for both TOF and non-TOF. A paired t-test was performed with a threshold of p-value less than 0.05 to determine significance.

Results

Physiologic Biodistribution of Ga-68-Dotatate in Normal Structures with TOF/Non-TOF Algorithm

A total of 1200 ROIs were evaluated. [Fig. 3] visually depicts the distribution of Ga-68-dotatate in a typical study patient with both TOF and non-TOF cameras. [Fig. 4] depicts the mean and 95% CI for the 24 selected ROIs for both TOF and non-TOF. [Table 4] provides the numerical data for [Fig. 4]. [Fig. 5] details the average ratio of the TOF and non-TOF SUVmax for each organ.

The urinary system had the highest observed activity for both TOF/non-TOF algorithms with a TOF SUV_max of 79.22 (95% CI ± 15.91, p <0.0001). Non-TOF urinary system SUV_max measured 70.83 (p < 0.0001). The high SUV_max values were due to the excretion of the radiotracer into the renal collection system and bladder. The highest normal physiologic uptake for TOF and non-TOF was the spleen with a TOF SUV_max of 24.49 (95% CI ± 2.41, p < 0.0001). Non-TOF spleen SUVmax measured 22.54 (p <0.0001).

Ga-68-dotatate uptake in normal structures on non-TOF images was observed in the following decreasing order: spleen, renal cortex, pituitary, adrenals, liver, pancreas tail, uncinate pancreas, salivary gland, pancreas body, pancreas head, thyroid, bone marrow, blood, myocardium, lymph node, muscle, breast, lung, fat, brain, pineal.

Ga-68-dotatate uptake in normal structures on TOF images was observed in the following decreasing order: spleen, pituitary, renal cortex, adrenals, uncinate pancreas, liver, pancreas except uncinate, salivary gland, thyroid, bone marrow, myocardium, lymph node, blood, breast, muscle, lung, fat, pineal gland, and brain ([Fig. 4])

Spectrum of Uptake in Lesions TOF versus Non-TOF

All 50 patients included in this study had suspected NET lesions and each ROI was assessed using TOF/non-TOF algorithms. TOF images had better tumor to background ratios visually. Non-TOF SUV_max average lesion uptake was 34.7 as compared to TOF SUV_max at 49.2 (p <0.0001).

TOF versus Non-TOF SUV_max Comparison and Statistical Significance

As compared to non-TOF SUV_max, TOF SUV_max was higher for all structures except for lung and brain. All TOF versus non-TOF SUV_max values were significantly different (p <0.0001) with the exception of the lung (p < 0.5). The lack of statistical significance in this one organ system is unclear and requires further scientific exploration.

As compared to non-TOF SUV_max, TOF SUV_max measured more than double in adrenals, and uncinated pancreas; approximately 1.8 times in concerning lesions, lymph nodes, pineal gland; and greater than 1.5 times in thyroid, breast, and pancreatic head. The spleen to liver ratio was approximately 3.36 with TOF versus 3.44 with non-TOF.

Discussion

Ga-68-dotatate uptake via non-TOF was in relative alignment with previous studies.[17] [18] [19] We expand upon the previous knowledge of Ga-68-dotatate distribution using a TOF capable camera system.

Study Limitations

Given the retrospective nature of this study, it is inherently prone to certain limitations. The study population were all military members or their dependents, which may not be representative of the general population. The writers of this study have no known reasons why they would not be generalizable versus a civilian cohort. Our study included the full extent of available Ga-68-dotatate studies from 2016 to 2019 (n = 77) with minimal exclusion criteria (final n = 50). Thus, the results of this study should have a high level of generalizability. All imaging protocols are in alignment with community standards and are clearly provided, further increasing generalizability. The study could have been improved, however, through the inclusion of a National Electrical Manufacturers Association (NEMA) phantom as a standardized reference value. NEMA phantoms provide a standardized and reproducible test environment. They have well-defined geometries and material compositions, ensuring consistency across different imaging systems and study settings. This standardization allows for more reliable comparisons between different imaging modalities, protocols, or facilities. This and all referenced previous Ga-68-dotatate studies have not utilized a NEMA phantom to our knowledge. Avenues for future research should include a standardized NEMA phantom as it would add further credibility and validity to their findings.

Validity of Non-TOF Uptake Data

Overall biodistribution and overlap are good between this study and previous studies.[17] [18] [19] As compared to Shastry et al's non-TOF study[18] whose patient population included NET patients with negative scans and no evidence of disease in a 2-year follow-up period, we have similar number of patients (50 vs. 42) and median age (55 vs. 50). The male/female ratio was 30:20 (vs. 15:27). Overall biodistribution and overlap are good between our studies. Our study yielded the same top 5 SUV_max organs as Shastry et al with the exception of ordering. The pituitary was the third highest uptake (SUV_max 12.87) and was fifth in Shastry et al (SUV_max 7.6). Our study's top five organ systems were the spleen (22.54), renal cortex (16.02), pituitary (12.87) adrenals (7.6), and liver (6.54). Shastry et al's top five organ systems were the spleen (27.9), renal cortex (13.6), adrenals (12.5), liver (8.2), and then the pituitary (7.6). The potential difference in uptake between the pituitary SUV_max in these studies needs further investigation. It could potentially be due to numerous reasons to include scanner differences or ROI size/location.

Ga-68-Dotatate Distribution in TOF versus Non-TOF

Utilizing newer TOF PET technology yielded mean TOF SUV_max values ([Fig. 5]) that were consistently higher for all structures except for lung and brain. As compared to non-TOF SUV_max, TOF SUV_max measured more than double in adrenals, and uncinate process of the pancreas; approximately 1.8 times in concerning lesions, lymph nodes, pineal gland; and greater than 1.5 times in thyroid, breast, and pancreatic head ([Fig. 5]). TOF suspected lesions measured approximately 1.8 times higher versus non-TOF lesions (p <0.0001).

Patients may obtain PET/CT scans using different facilities and cameras that may show different radiotracer uptake values. Awareness of these differences is useful in scan interpretation. Additionally, readers may now have a potential database of SUV_max ranges for the TOF cameras, especially for the PET/CT cameras used in this study.

This study also compared TOF/non-TOF values for abnormal lesions in our population of 50 patients. SUV_max non-TOF values aligned with previous studies that characterized typical lesional uptake of Ga-68-dotatate via non-TOF systems, most recently being Moradi et al in 2016. The average SUV_max abnormal lesion uptake for non-TOF suspected tumors was 34.7 compared to Moradi et al that found mean SUV_max values of 29.3 ± 17.6 for 157 hepatic lesions deemed malignant. Moradi et al's data validated the use of SUV analysis in the interpretation of malignant versus benign lesions primarily that SUV_max evaluation alone approaches the accuracy of clinical assessment based on multimodal imaging interpretation and follow-up.[17] Furthermore, Moradi et al highlighted that malignant lesions have a statistically significant increase in uptake versus benign lesions in most cases.

The exact cause of these differences is not well documented. It is theorized that for small lesions less than a centimeter in diameter, partial volume effects come into play and TOF provides better partial volume reconstruction thus making the SUV_max higher.[8] [19] Additionally, if the TOF reconstruction has more iterations than the non-TOF reconstruction, that tends to cause higher SUV_max values.

The large increase in SUV_max when using TOF technology could lead to clinical misinterpretation of therapy response and subsequent mismanagement. Practitioners should be aware and understand the differences between TOF and non-TOF Ga-68-dotatate SUV_max values.

Conclusion

Overall, TOF SUV_max measures approximately 2X higher in identical ROIs versus non-TOF. This is also true of abnormal NET lesions (1.8X). These findings need to be taken in consideration when comparing patient scans imaged on different PET/CT technologies. This is of particular significance in transient populations (such as the US Military, government, and civilian populations) where they are more likely to receive follow-up or surveillance scanning on potentially different technologies. Additionally, as hospital systems continue to maximize their investment in PET scanners, existing scanners that lack TOF-reconstruction will persist for many years into the future. It is of clinical importance that these findings be taken into consideration or there is the potential for misdiagnosis if incorrect assumptions are made regarding the equivalency of SUV_max values across technologies.

Our study furthers the clinical knowledge base of Ga-68-dotatate uptake in newer TOF systems by providing a Ga-68-dotatate TOF physiologic distribution pattern, providing a side-by-side comparison to non-TOF data on identical ROIs and lesions. This novel data should improve interpretation accuracy as well as allow relative SUV comparison when a patient's prior scan was from a non-TOF camera, avoiding potential misdiagnoses or medical mismanagement.

These study findings could be further advanced through the development of standardized protocols or software tools that account for differences in reconstruction algorithms and imaging characteristics to ensure reliable comparison of SUV_max values across technologies. Furthermore, future research could investigate the impact of differences in SUV_max measurements between TOF and non-TOF PET/CT systems on clinical outcomes, such as diagnostic accuracy, treatment response assessment, and patient management decisions. Large-scale prospective studies could be conducted to evaluate whether discrepancies in SUV_max values lead to differences in patient outcomes or influence clinical decision-making.

Conflict of Interest

None declared.

Contributorship/Institutional Acknowledgements

The views expressed in this manuscript are those of the author(s) and do not reflect the official policy of the Department of Army/Navy/Air Force, Department of Defense, or U.S. Government.

• References

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Publication History

Article published online:
07 May 2024

© 2024. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/)

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• References

• 1 Dasari A, Shen C, Halperin D. et al. Trends in the incidence, prevalence, and survival outcomes in patients with neuroendocrine tumors in the United States. JAMA Oncol 2017; 3 (10) 1335-1342
  CrossrefPubMedGoogle Scholar
• 2 Körner M, Eltschinger V, Waser B, Schonbrunn A, Reubi JC. Value of immunohistochemistry for somatostatin receptor subtype sst2A in cancer tissues: lessons from the comparison of anti-sst2A antibodies with somatostatin receptor autoradiography. Am J Surg Pathol 2005; 29 (12) 1642-1651
  CrossrefPubMedGoogle Scholar
• 3 Evangelou I, Petraki C, Msaouel P. et al. Immunohistochemical expression of somatostatin receptor subtypes 2 and 5 in colorectal cancer. Eur J Clin Invest 2012; 42 (07) 777-783
  CrossrefPubMedGoogle Scholar
• 4 Reubi JC, Laissue J, Krenning E, Lamberts SW. Somatostatin receptors in human cancer: incidence, characteristics, functional correlates and clinical implications. J Steroid Biochem Mol Biol 1992; 43 (1-3): 27-35
  CrossrefPubMedGoogle Scholar
• 5 Kwekkeboom DJ, Krenning EP. Somatostatin receptor imaging. Semin Nucl Med 2002; 32 (02) 84-91
  CrossrefPubMedGoogle Scholar
• 6 Deppen SA, Liu E, Blume JD. et al. Safety and efficacy of 68Ga-DOTATATE PET/CT for diagnosis, staging, and treatment management of neuroendocrine tumors. J Nucl Med 2016; 57 (05) 708-714
  CrossrefPubMedGoogle Scholar
• 7 Deppen SA, Blume J, Bobbey AJ. et al. 68Ga-dotatate compared with 111In-DTPA-octreotide and conventional imaging for pulmonary and gastroenteropancreatic neuroendocrine tumors: a systematic review and meta-analysis. J Nucl Med 2016; 57 (06) 872-878
  CrossrefPubMedGoogle Scholar
• 8 Kuyumcu S, Özkan ZG, Sanli Y. et al. Physiological and tumoral uptake of (68)Ga-DOTATATE: standardized uptake values and challenges in interpretation. Ann Nucl Med 2013; 27 (06) 538-545
  CrossrefPubMedGoogle Scholar
• 9 Kunikowska J, Królicki L, Pawlak D, Zerizer I, Mikołajczak R. Semiquantitative analysis and characterization of physiological biodistribution of (68)Ga-DOTA-TATE PET/CT. Clin Nucl Med 2012; 37 (11) 1052-1057
  CrossrefPubMedGoogle Scholar
• 10 Velikyan I, Sundin A, Sörensen J. et al. Quantitative and qualitative intrapatient comparison of 68Ga-DOTATOC and 68Ga-DOTATATE: net uptake rate for accurate quantification. J Nucl Med 2014; 55 (02) 204-210
  CrossrefPubMedGoogle Scholar
• 11 Geijer H, Breimer LH. Somatostatin receptor PET/CT in neuroendocrine tumours: update on systematic review and meta-analysis. Eur J Nucl Med Mol Imaging 2013; 40 (11) 1770-1780
  CrossrefPubMedGoogle Scholar
• 12 Łapińska G, Bryszewska M, Fijołek-Warszewska A, Kozłowicz-Gudzińska I, Ochman P, Sackiewicz-Słaby A. The diagnostic role of 68Ga-DOTATATE PET/CT in the detection of neuroendocrine tumours. Nucl Med Rev Cent East Eur 2011; 14 (01) 16-20
  CrossrefPubMedGoogle Scholar
• 13 Pryma DA. Nuclear Medicine: Practical Physics, Artifacts, and Pitfalls,. Oxford University Press, Incorporated; 2014. . ProQuest Ebook Central
  Google Scholar
• 14 NETSPOT. (kit for the preparation of gallium Ga 68 dotatate injection) [package insert]. New York, NY: Gipharma S.r.1; 2016
  Google Scholar
• 15 Visvikis D, Costa DC, Croasdale I. et al. CT-based attenuation correction in the calculation of semi-quantitative indices of [18F]FDG uptake in PET. Eur J Nucl Med Mol Imaging 2003; 30 (03) 344-353
  CrossrefPubMedGoogle Scholar
• 16 Kinahan PE, Fletcher JW. Positron emission tomography-computed tomography standardized uptake values in clinical practice and assessing response to therapy. Semin Ultrasound CT MR 2010; 31 (06) 496-505
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