Amplitude-based optimal respiratory gating (ORG) effectively removes respiratory-induced motion blurring from clinical 18F-fluorodeoxyglucose (FDG) positron emission tomography (PET) images. Correction of FDG-PET images for these respiratory motion artefacts improves image quality, diagnostic and quantitative accuracy. Removal of respiratory motion artefacts is important for adequate clinical management of patients using PET.
Positron emission tomography (PET) combined with X-ray computed tomography (CT) is an important molecular imaging platform that is required for accurate diagnosis and clinical staging of a variety of diseases. The advantage of PET imaging is the ability to visualize and quantify a myriad of biological processes in vivo with high sensitivity and accuracy. However, there are multiple factors that determine image quality and quantitative accuracy of PET images. One of the foremost factors influencing image quality in PET imaging of the thorax and upper abdomen is respiratory motion, resulting in respiration-induced motion blurring of anatomical structures. Correction of these artefacts is required for providing optimal image quality and quantitative accuracy of PET images.
Several respiratory gating techniques have been developed, typically relying on acquisition of a respiratory signal simultaneously with PET data. Based on the respiratory signal acquired, PET data is selected for reconstruction of a motion-free image. Although these methods have been shown to effectively remove respiratory motion artefacts from PET images, the performance is dependent on the quality of the respiratory signal being acquired. In this study, the use of an amplitude-based optimal respiratory gating (ORG) algorithm is discussed. In contrast to many other respiratory gating algorithms, ORG permits the user to have control over image quality versus the amount of rejected motion in the reconstructed PET images. This is achieved by calculating an optimal amplitude range based on the acquired surrogate signal and a user-specified duty cycle (the percentage of PET data used for image reconstruction). The optimal amplitude range is defined as the smallest amplitude range still containing the amount of PET data required for image reconstruction. It was shown that ORG results in effective removal of respiration-induced image blurring in PET imaging of the thorax and upper abdomen, resulting in improved image quality and quantitative accuracy.
Positron Emission Tomography (PET) in combination with X-ray computed tomography (CT) is a widely accepted imaging tool in clinical practice for accurate diagnosis and clinical staging of a variety of diseases1. The advantage of PET imaging is the ability to visualize and quantify a myriad of biological processes in vivo with high sensitivity and accuracy2. This is achieved through intravenously administering a radioactively labelled compound, also known as a radiotracer, to the patient. Depending on the radiotracer being used, tissue characteristics such as glucose metabolism, cellular proliferation, degree of hypoxia, amino acid transport, and expression of proteins and receptors, can be visualized and quantified2.
Although several radiotracers have been developed, validated, and used in clinical practice, the radioactive glucose analogue 18F-fluorodeoxyglucose (FDG) is the most widely used radiotracer in clinical practice. Given that FDG predominantly accumulates in cells with an elevated glycolytic rate (i.e., cells with elevated glucose uptake and conversion to pyruvate for energy production), it is possible to discriminate tissues with different metabolic states. Similar to glucose, the first step of FDG uptake is transport from the extra-cellular space over the plasma membrane to the intra-cellular space, which is facilitated by glucose transporters (GLUT)3. Once the FDG is in the intra-cellular space, phosphorylation by hexokinases will result in the generation of FDG-6-phosphate. However, in contrast to glucose-6-phosphate, FDG-6-phosphate cannot enter the Krebs cycle for further aerobic dissimilation due to the absence of a hydroxyl (OH) group at the second (2’) carbon position. Given that the reverse reaction, the dephosphorylation of FDG-6-phosphate back to FDG, hardly occurs in most tissues, the FDG-6-phosphate is trapped intracellularly3. Therefore, the degree of FDG uptake is dependent on the expression of the GLUT (in particular GLUT1 and GLUT3) on the plasma membrane, and the intracellular enzymatic activity of hexokinases. The concept of this continuous uptake and trapping of FDG is referred to as metabolic trapping. The fact that FDG preferentially accumulates in tissues with an elevated metabolic activity is shown in Figure 1a, demonstrating the physiological distribution of FDG in a patient. This FDG-PET image shows higher uptake in heart, brain, and liver tissues, which are known to be metabolically active organs under normal conditions.
The high sensitivity for detecting differences in the metabolic state of tissues makes FDG an excellent radiotracer for discriminating normal from diseased tissues, given that an altered metabolism is an important hallmark for many diseases. This is readily depicted in Figure 1b, showing an FDG-PET image of a patient with stage IV non-small cell lung cancer (NSCLC). There is increased uptake in the primary tumor as well as in metastatic lesions. In addition to visualization, quantification of radiotracer uptake plays an important role in clinical management of patients. Quantitative indices derived from PET images reflecting the degree of radiotracer uptake, such as the standardized uptake value (SUV), metabolic volumes, and total lesion glycolysis (TLG), can be used to provide important prognostic information and measure treatment response for different patient groups4,5,6. In this regard, FDG-PET imaging is increasingly being used to personalize radiotherapy and systemic treatment in oncology patients7. Furthermore, the use of FDG-PET for monitoring acute treatment induced toxicity, such as radiation induced esophagitis8, pneumonitis9 and systemic inflammatory responses10, has been described and provides important information for making image-guided treatment decisions.
Given the important role of PET for clinical management of patients, image quality and quantitative accuracy is important for appropriately guiding treatment decisions based on PET images. However, there are numerous technical factors that can compromise quantitative accuracy of PET images11. An important factor that can significantly influence image quantification in PET is related to the longer acquisition times of PET compared to other radiological imaging modalities, typically several minutes per bed position. As a consequence, patients are usually instructed to breath freely during PET imaging. The result is that PET images suffer from respiratory induced motion, which can lead to significant blurring of organs located within the thorax and upper abdomen. This respiratory-induced motion blurring can significantly impair adequate visualization and quantitative accuracy of radiotracer uptake, which can affect clinical management of patients when using PET images for diagnosis and staging, target volume definition for radiation treatment planning applications, and monitoring of therapy response12.
Several respiratory gating methods have been developed in an attempt to correct PET images for respiratory motion artefacts13. These methods can be categorized into prospective, retrospective, and data-driven gating strategies. Prospective and retrospective respiratory gating techniques typically rely on the acquisition of a respiratory surrogate signal during PET imaging14. These respiratory surrogate signals are used to track and monitor the patient’s respiratory cycle. Examples of respiratory tracking devices are detection of chest wall excursion using pressure sensors12 or optical tracking systems (e.g., video cameras)15, thermocouples to measure the temperature of breathed air16, and spirometers to measure airflow and thereby indirectly estimating volume changes in the patient’s lungs17.
Respiratory gating is then typically accomplished by continuously and simultaneously recording a surrogate signal (designated S(t)), with the PET data during image acquisition. Using the surrogate signal acquired, PET data corresponding to a particular respiratory phase or amplitude range (amplitude-based gating) can be selected12,13,18. Phase-based gating is performed by dividing each respiratory cycle into a fixed number of gates, as depicted in Figure 2a. Respiratory gating is then performed by selecting data acquired at a particular phase during the patient’s respiratory cycle to be used for image reconstruction. Similarly, amplitude-based gating relies on defining an amplitude range of the respiratory signal, as shown in Figure 2b. When the value of the respiratory signal falls within the set amplitude range, the corresponding PET listmode data will be used for image reconstruction. For retrospective gating approaches, all data is collected and re-binning of the PET data is performed after image acquisition. Although prospective respiratory gating methods use the same concepts as retrospective gating approaches for re-binning of PET data, these methods rely on collecting data prospectively during image acquisition. When a sufficient amount of PET data is collected, image acquisition will be finalized. The difficulty of such prospective and retrospective gating approaches is maintaining acceptable image quality without significantly prolonging image acquisition times when irregular breathing occurs13. In this regard, phase-based respiratory gating methods are particularly sensitive to irregular breathing patterns13,19, where significant amounts of PET data can be discarded due to rejection of inappropriate triggers, resulting in considerable reduction of image quality or unacceptable lengthening of image acquisition time. Additionally, when inappropriate triggers are accepted, the performance of the respiratory gating algorithm and thereby the effectiveness of motion rejection from the PET images can be reduced due to the fact that respiratory gates are defined at different phases of the respiratory cycle, as depicted in Figure 2a. Indeed, it has been reported that amplitude-based respiratory gating is more stable than phase-based approaches in case of irregularities in the respiratory signal13. Though amplitude-based respiratory gating algorithms are more robust in the presence of irregular breathing frequencies, these algorithms are more sensitive to baseline drifting of the respiratory signal. Drifting of the baseline signal can occur due to numerous reasons when the patient’s muscle tension (i.e., transition of a patient into a more relaxed state during image acquisition) or breathing pattern changes. In order to prevent such baseline drifting of the signal, care should be taken to securely attach tracking sensors to the patient and perform regular monitoring of the respiratory signal.
Although these problems are known, traditional respiratory gating algorithms only allow limited control over image quality and usually require significant lengthening of image acquisition time or increased amounts of radiotracer to be administered to the patient. These factors resulted in limited adoption of such protocols in clinical routine. In order to circumvent these problems related to the variable quality of the respiratory gated images , a specific type of amplitude-based gating algorithm, also known as optimal respiratory gating (ORG), has been proposed18. Respiratory gating with ORG permits the user to specify image quality of the respiratory gated images by providing a duty cycle as input to the algorithm. The duty cycle is defined as a percentage of the acquired PET list-mode data that is used for image reconstruction. In contrast to many other respiratory gating algorithms, this concept permits the user to directly determine image quality of the reconstructed PET images. Based on the duty cycle specified, an optimal amplitude range is calculated, which takes the specific characteristics of the entire respiratory surrogate signal into account18. The optimal amplitude range for a specific duty cycle will be calculated by starting with a selection of different values for the lower amplitude limit, designated (L), of the respiratory signal. For each selected lower limit, the upper amplitude limit, designated (U), is adjusted in such a way that the sum of the selected PET data, defined as data acquired when the respiratory signal falls within the amplitude range (L<S(t)<U), is equal to the specified duty cycle. For example, for a duty cycle of 50% and six minutes of acquired PET listmode data, the amplitude range is adapted to include three minutes (50%) of PET data. The optimal amplitude range (W) is defined as the smallest amplitude range used for respiratory gating that still contains the required amount of PET data (i.e., ArgMax([U–L])), as depicted in Figure 2c12. Thus, by specifying the duty cycle, the user makes a trade-off between the amount of noise and the degree of residual motion residing in the ORG PET images. Lowering the duty cycle will increase the amount of noise, though this will also reduce the amount of residual motion in the PET images (and vice versa). Although the concepts and effects of ORG have been described in previous reports, the purpose of this manuscript is to provide clinicians with details on the specific protocols when using ORG in clinical practice. Therefore, the use of ORG in a clinical imaging protocol is described. Several practical aspects, including patient preparation, image acquisition and reconstruction protocols will be provided. Furthermore, the manuscript will cover the user interface of the ORG software and specific choices that can be made when performing respiratory gating during PET imaging. Lastly, the effect of ORG on lesion detectability and image quantification, as shown in previous studies, are discussed.
All procedures performed involving human participants were in accordance with the ethical standards of the internal review board (IRB) of the Radboud university medical center and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. The ORG algorithm is a vendor specific product and is available on the Siemens Biograph mCT PET/CT scanner family and newer PET/CT models.
1. Patient preparation
2. Image acquisition and reconstruction
The use of ORG in PET results in an overall reduction of respiratory-induced blurring of the images. For example, in a clinical evaluation of patients with non-small cell lung cancer (NSCLC), ORG resulted in detection of more pulmonary lesions and hilar/mediastinal lymph nodes20. This is readily demonstrated in Figure 8 and Figure 9, showing non-gated and ORG PET images of patients with NSCLC.
In particular, ORG resulted in management changes in patients with early disease stages (I-IIB) where detection of additional lesions of lymph nodes can significantly affect the prescribed treatment and additional diagnostic procedures required. These results are confirmed by a study conducted by van der Gucht et al. for lesions located in the upper abdomen21. The use of ORG resulted in detection of more lesions in FDG-PET of patients with hepatic and perihepatically located lesions. Although these results support that the use of ORG may lead to improved diagnosis and staging of patients, the exact clinical impact of ORG remains unclear.
Image quantification is significantly impacted when ORG was used to correct PET images for respiratory motion, particularly for pulmonary lesions located near the diaphragm and hilar regions of the lungs. In a study investigating the effects of ORG in 66 lung cancer patients, there was a statistically significant increase in mean SUV (SUVmean) uptake in the ORG images with respect to the non-gated PET images. Compared to the non-gated PET images, the ORG PET images showed an increase in SUVmean of 6.2±12.2% (p<0.0001), 7.4±13.3% (p<0.0001), and 9.2±14.0% (p<0.0001), for duty cycles of 50%, 35% and 20% respectively12.
Furthermore, a statistically significant decrease in metabolic volumes of the lesions was observed when ORG was performed. These volumes were segmented using a region growing fixed threshold (40% of the maximum uptake (SUVmax)) segmentation algorithm. There was a decrease of 6.9±19.6% (p=0.02), 8.5±19.3% (p<0.0001), and 11.3±20.2% (p<0.0001) for duty cycles of 50%, 35%, and 20% respectively12. The significant increase in uptake and decrease in metabolic volume indicate effective removal of respiration-induced image blurring from the PET images when ORG is performed. Additionally, it was shown that the influence of respiratory motion artefacts on quantification of lesion uptake and volume was dependent on anatomical location. There was only a significant increase in SUVmean and decrease in volume for lesions located in the lower lung lobes and centrally (particularly hilar) located lesions. The effect of anatomical location is readily demonstrated in Figure 10, showing two different NSCLC lesions in a single patient. Furthermore, comparing the ORG PET images reconstructed images with a duty cycle of 35% to their non-gated equivalent images showed that the levels of image noise are comparable, demonstrating that image quality is kept constant when using ORG12.
The relation between duty cycle and image noise was demonstrated by calculating the coefficient of variation (COV) of FDG uptake in unaffected lung parenchyma. The COV in non-gated images using all data available was on average 26.1±6.4%, whereas the COV in ORG PET images reconstructed with a duty cycle of 20% was 39.4±7.5%. There was a non-significant difference in COV between ORG PET images reconstructed with a duty cycle of 35% (32.8±6.4%) and their non-gated equivalent images (31.8±5.6%). Figure 11 shows two different ORG PET and non-gated PET images with different statistical quality. This figure demonstrates that lowering the duty cycle increases the amount of noise, while the quality of the ORG PET image reconstructed with a duty cycle of 35% and the non-gated equivalent image is kept constant. Although ORG results in significant reduction of lesion volume as quantified on PET images, the absolute reduction in volume yielded no significant sparing of the radiation dose delivered to the organs at risk (OARs) during radiotherapy planning, as demonstrated in another study22.
The blurring effect of respiratory motion is also affecting quantification of intra-tumor heterogeneity. In a cohort of 60 NSCLC patients, ORG resulted in statistically significant differences in texture feature quantification of lesions in the middle and lower lung lobes23. For the textural features; high-intensity emphasis (HIE), entropy, zone percentage (ZP), and dissimilarity, the relative increase was 16.8% ± 17.2% (p = 0.006), 1.3% ± 1.5% (p = 0.02), 2.3% ± 2.2% (p = 0.002), 11.6% ± 11.8% (p = 0.006) between the ORG PET images and their non-gated equivalent PET images. Quantification of intra-tumor heterogeneity was not significantly affected for lesions in the upper lung lobes. The mean decrease of these textural features was of 1.0% ± 7.7% (p = 0.3), 0.35% ± 1.8% (p = 0.3), 1.7% ± 13.2% (p = 0.4), and 0.4% ± 2.7% (p = 0.5), for dissimilarity, entropy, HIE, and ZP respectively. Furthermore, there was no significant difference in between ORG and non-gated PET images for centrally located lesions, with a mean increase of 0.58% ± 3.7% (P = 0.6), 5.0% ± 19.0% (P = 0.4), 0.59% ± 4.0% (P = 0.9), and 4.4% ± 27.8% (P = 0.4), for entropy, dissimilarity, ZP, and HIE respectively. Although quantification of textural features was significantly affected for lesions located in the middle and lower lung lobes, the multivariate Cox regression models for survival were not significantly affected23. In addition to quantification of intra-tumor heterogeneity of pulmonary lesions, respiratory motion can result in significant changes in quantification of intra-tumor heterogeneity of lesions located in the upper abdominal region. This is readily demonstrated in a study investigating the effect of ORG on the quantification of patients with a pancreatic ductal adenocarcinoma (PDAC)24. Removal of respiratory motion artifacts from PET images using ORG considerably affects quantification of textural features in PDAC lesions. It was observed that the correlation of the calculated texture features with overall survival was significantly affected.
Figure 1: a) Physiological distribution of 18F-fluorodeoxyglycose (FDG) in a patient who underwent positron emission tomography (PET) imaging. There is significant uptake of FDG in the heart, brain, and liver of the patient. b) Increased FDG-uptake in multiple lung, lymph node and distant metastases in a patient with stage IV non-small cell lung cancer (NSCLC), demonstrating the preferential uptake of FDG in cancer lesions when compared to most other non-affected tissues. Please click here to view a larger version of this figure.
Figure 2: Phase- and amplitude-based gating in positron emission tomography (PET). a) Phase-based gating, b) amplitude-based gating, and c) optimal respiratory gating (ORG). During phase-based gating, each respiratory cycle is subdivided into a fixed number of gates (in this case 4). Data collected in a specific gate will be used to reconstruct an image from which the main respiratory motion components will be removed. Amplitude-based gating relies on definition of an upper and lower amplitude limit. Amplitude-based respiratory gating approaches typically rely on specification of an amplitude-range by the user. Data collected when the respiratory signals falls within the defined amplitude range will be used for image reconstruction. The optimal respiratory gating (ORG) algorithm uses such an amplitude-based approach and will calculate an optimal amplitude range based on the duty cycle (percentage of the PET data that is required for image reconstruction) provided. The smallest amplitude range that still contains the specified amount of data that is required for image reconstruction (total sum of the areas shaded in blue) is selected as the optimal amplitude range (W). In order to achieve this, the ORG algorithm adjusts the upper limit (U) for different values of the lower limit (L). Generally, increasing the number of gates or reduction of the amplitude range will result in a more effective rejection of respiratory motion at the cost of increased image noise. Please click here to view a larger version of this figure.
Figure 3: Selection of appropriate imaging protocol. A predefined imaging protocol can be selected by selecting a protocol from a specific category (by hoovering the mouse over the protocol categories (indicated by the red box) and select a protocol from the drop-down menu). Please click here to view a larger version of this figure.
Figure 4: Different keys on the control box of the Siemens mCT and Horizon PET/CT scanners. 1) Move Key, used to move the patient table to the next measuring position, 2) Unload patient key: used to move the patient table to the unload position after image acquisition, 3) Start key: Used to trigger a scan, the radiation warning sign (4) will light up during image acquisition, 4) Radiation warning lamp: Indicates and provides a warning signal when X-ray tube is on, 5) Suspend key: Used to hold the scan procedure. This is the preferred method for interrupting a scan before completion. The suspend option permits restart of the image protocol at the point is was halted, 6) Hear patient key: Press this key to hear the patient, the light diode indicated that the listening connection is active, press this key again to release the listening connection, 7) Loudspeaker, 8) Call patient key: Hold down this key while speaking to the microphone (10) to provide instructions to the patient, 9) Stop key: Used to immediately stop the scanning procedure, used in case of an emergency, 10) Microphone. Please click here to view a larger version of this figure.
Figure 5: After acquisition of the topogram, the acquisition time of different bed positions have to be specified (in the ‘Routine’ tab). In this example, the gated bed positions are recorded for 6 minutes (bed 2), while the non-gated bed positions are acquired in 2 minutes (bed 1 and3). Gated bed positions (highlighted in orange in the topogram) can be set by setting the option ‘Physio’ to ‘On’ in the second column. Please click here to view a larger version of this figure.
Figure 6: Respiratory waveform of the patient is displayed in the upper part of the dashboard together with a histogram of the breathing frequency (lower part) in the ‘Trigger’ tab. The duty cycle can be selected from the drop-down menu on the right (in this case 35%). This protocol has a standard image acquisition time of 6 minutes per bed position for gated bed positions and 2 minutes for non-gated bed positions. Please click here to view a larger version of this figure.
Figure 7: Selection of image reconstruction protocol (‘Recon’ tab), details of image reconstruction can be specified for each protocol by filling in the relevant fields. For viewing, a high resolution image reconstruction protocol is advised to provide detail in the reconstructed PET images. For quantification of radiotracer uptake on PET images, the use of an EARL compliant reconstruction protocol is advised. Please click here to view a larger version of this figure.
Figure 8: Non-gated and optimal gated (ORG) FDG-PET–CT images of a patient with non-small cell lung cancer (NSCLC). This figure shows non-gated (a) and ORG PET (b) images of a hilar lymph node in station X in a patient with a solitary NSCLC lesion in the left lower lobe. The ORG PET image is reconstructed with a 35% duty cycle. Reduction of the blurring effects of respiratory motion would have resulted in upstaging of this patient from cT1N0M0 to cT1N1M0 and the requirement for histological evaluation of the hilar lymph node using endobronchial ultrasound (EBUS). This figure has been modified from Grootjans et al. (Lung Cancer 2015). Please click here to view a larger version of this figure.
Figure 9: Non-gated (a) and optimal respiratory gated (ORG) (b) FDG-PET–CT image of a primary NSCLC lesion and satellite lesion in the right lung hilum. The primary lesion is indicated by a ‘p’ while the satellite lesion is indicated by a ‘s’ in this figure. Respiratory gating in this patient resulted in improved contrast recovery of satellite lesions adjacent to the primary lesion. The presence of the lesion was confirmed on follow-up CT imaging, although these findings would not have significantly impacted clinical management for this patient, ORG resulted in detection of additionally pulmonary lesions. This figure has been modified from Grootjans et al. (Lung Cancer 2015). Please click here to view a larger version of this figure.
Figure 10: Non-gated and optimal respiratory gated (ORG) FDG-PET–CT images of a patient with NSCLC lesions in the left lower lobe and lung hilum. This example shows the effect of respiration-induced motion blurring on visualization and quantification of NSCLC lesions. a) Non-gated PET image depicting a lesion in the left lower lobe, b) ORG PET image, reconstructed with a duty cycle of 35% of a lesion in the left lower lobe, c) Non-gated PET image depicting a lesion in the left lung hilum, d) ORG PET image, reconstructed with a duty cycle of 35% of a lesion in the left lung hilum. In this patient, the lesion located in the lung hilum is subjected to considerable respiration-induced motion, showing a large effect on quantification of lesion uptake and metabolic volume when ORG is performed. For this lesion, an increase in mean standardized uptake value (SUVmean) of 31.9% and decrease in metabolic volume of 23.0% was observed. The effect of respiratory motion on quantification of lesion uptake and volume was 5.3% and 1.9% respectively for the lesion in the upper lung lobe. This figure has been modified from Grootjans et al. (Eur Radiol 2014). Please click here to view a larger version of this figure.
Figure 11: Comparison of optimally respiratory gated (ORG) and non-gated PET images with different counts statistics in a patient with stage IV non-small cell lung cancer (NSCLC). The left column (a and c) display the non-gated PET images reconstructed with all (a) and 35% (c) of the recorded data. Comparing images a and c reveals that noise levels are increased when less data is used for image reconstruction, particularly noticeable in the areas of relatively homogeneous uptake, such as the liver (indicated with an asterisk ‘*’). The column on the right (b and d) displays the ORG PET images reconstructed with 50% and 35% duty cycle. These images show that the amount of noise is increased when the duty cycle is lowered. Comparing the non-gated PET image (c) with its ORG PET equivalent (d) shows that the respiratory-induced blurring effect is reduced in the ORG image, which is reflected by the apparent size of the metastatic lesion in the adrenal gland (indicated with a plus sign ‘+’) and renal calices of the left kidney (indicated with an ‘x’). Please click here to view a larger version of this figure.
In the nuclear medicine community, the deteriorating effects of respiratory motion artefacts in PET imaging have been well-recognized for a long time. It has been shown in many studies that the blurring effect of respiratory motion artefacts can significantly influence image quantification and lesion detectability. Although several respiratory gating methods have been developed, respiratory gating is currently not widely being used in clinical practice. This is particularly due to a resulting variable image quality, unacceptable prolongation of image acquisition times, and non-ideal integration of respiratory gating in a clinical full body imaging protocol. The advantage of ORG is that it permits convenient integration in a standard whole-body PET imaging protocol, making it possible to seamlessly integrate multiple gated and non-gated bed positions in a single image. Furthermore, the ORG algorithm takes specific characteristics of the entire respiratory signal, such as plateau phases, into account when calculating the optimal amplitude range, while the user has the ability to directly specify the image quality of the reconstructed PET images by specifying the duty cycle. However, similar to many other respiratory gating methods, ORG requires the use of external sensors which is used to perform respiratory gating. Furthermore, depending on the duty cycle used, a considerable amount of PET data is discarded and not used for reconstruction of the final image. Therefore, successful respiratory gating with ORG relies on appropriate tracking of respiratory motion using external sensors and lengthening image acquisition times or the amount of administered activity to the patients. The difficulty related to the use of sensors inspired the development of data-driven, or sensor-less respiratory gating approaches25,26,27. These data-driven techniques omit the requirement for an external surrogate signal by extracting information on respiratory motion from the PET list-mode data itself. Such data-driven techniques have been developed by multiple PET vendors and have been proposed as clinically applicable alternatives to sensor-based methods, facilitating routine PET respiratory gating in clinical practice.
In addition to solely extracting information regarding respiratory motion from PET data, newer methods permit the use of all PET data being recorded for image reconstruction28. These motion-compensated image reconstructions are performed by elastically transforming PET data from different respiratory phases to a single image from which motion artefacts are removed. Compared to traditional sensor-based respiratory gating, motion-compensated reconstruction does not require lengthening of image acquisition time and prevent the use of additional hardware during gating. These methods effectively remove respiratory motion from PET images whilst maintaining image quality29. Furthermore, with the emergence of hybrid PET and magnetic resonance (MR) imaging, several methods have been developed that use motion information derived from MR to correct PET images30,31,32,33.Though these methods have existed for some time in a research setting, the first data-driven respiratory gating methods have entered the market. However, most of these methods are still under active development and continuous improvement and larger clinical studies are required to evaluate the performance and robustness of such algorithms.
Although respiratory gating methods are mainly focused on correcting PET images for respiratory motion artefacts, these algorithms usually do not take the acquired CT data into consideration. In clinical practice, low-dose (LD) CT is usually performed without providing breathing instructions. Registration of a LDCT acquired when the patient is breathing freely can result in a significant spatial mismatch between respiratory gated PET and LDCT, particularly for anatomical structures that move during respiration34. In addition to accurately localize radiotracer uptake, the LDCT is used for attenuation correction of the PET images. Therefore, the effect of a spatial mismatching between PET and CT can introduce profound quantitative inaccuracies in PET, particularly when radiotracer uptake is located near structures with large differences in density, such as lung and bone tissue. Several authors have investigated different methods to synchronize image acquisition to reduce spatial mismatching between PET and CT images. One proposed method involves providing breathing instructions to the patient during CT acquisition. Although standard CT breathing instructions in combination with ORG did not yield an improvement in spatial matching between CT and PET35, patient-specific instructions based on the same respiratory signal and amplitude range used for ORG did result in an overall improvement of the spatial match between PET and CT36. However, these methods are sensitive to variations in operator instructions and patient interpretation. Improved results have been obtained by performing training sessions with the patient before PET-CT imaging. However, given that some patients have difficulty complying to these breathing instructions due an impaired physical condition, success might remain variable in a clinical setting. Other approaches include the use of respiratory triggered CT, where the respiratory signal is used to trigger the CT acquisition34. This approach in combination with ORG resulted in a significant reduction in spatial mismatch between PET and CT images. In a study evaluating a triggered to a standard CT protocol showed an increase in SUVmax and SUVmean of 5.7% ± 11.2% (P < 0.001) and 6.1% ± 10.2% (P = 0.001), respectively. Although full 4D CT gating has been proposed to match PET and CT images, such strategies are not applicable in routine clinical practice given an unacceptably high radiation exposure to the patient. Different methods for reducing the spatial mismatch between PET and CT images are still under evaluation for their effectiveness and clinical usefulness.
Although respiratory motion significantly influences image quantification of PET images, there remain many other technical factors that have to be taken into account in order to maintain reproducibility and quantitative accuracy of PET images11. These factors are related to patient preparation, imaging acquisition settings and reconstruction protocols. It is important to adhere to strict acquisition protocols, including the use of similar patient-preparation procedures, assessment of radiotracer uptake at specific time points, and scanning and reconstruction parameters11,37. In this regard, the European Association of Nuclear Medicine (EANM) provides guidelines on quantitative FDGPET–CT for multicenter comparisons. It has been shown that harmonization of imaging protocols using standardized guidelines results in overall improved comparability of PET images from different institutions38.
The authors have nothing to disclose.
The authors would like to thank Richard Raghoo for providing the PET images shown in Figure 1.
Sensor Port, sensor, black box, wave deck, elastic band, load cell sensor (complete set) | anzai medical co. | respiratory gating system AZ-733V | http://www.anzai-med.co.jp/en/product/item/az733v |