Your search keyword '"Respiratory-gated PET"' showing total 8 results

1. Impact of respiratory gating and ECG gating on 18F-FDG PET/CT for cardiac sarcoidosis.

Author

Hanaoka, Kohei, Watanabe, Shota, Morimoto-Ishikawa, Daisuke, Kaida, Hayato, MD, Yamada, Takahiro, Yasuda, Masakazu, Iwanaga, Yoshitaka, Nakazawa, Gaku, and Ishii, Kazunari

Abstract

Background: The aim of this study was to estimate the impact of respiratory and electrocardiogram (ECG)-gated FDG positron emission tomography (PET)/computed tomography (CT) on the diagnosis of cardiac sarcoidosis (CS). Methods and Results: Imaging from thirty-one patients was acquired on a PET/CT scanner equipped with a respiratory- and ECG-gating system. Non-gated PET images and three kinds of gated PET/CT images were created from identical list-mode clinical PET data: respiratory-gated PET during expiration (EX), ECG-gated PET at end diastole (ED), and ECG-gated PET at end systole (ES). The maximum standardized uptake value (SUVmax) and cardiac metabolic volume (CMV) were measured, and the locations of FDG accumulation were analyzed using a polar map. The mean SUVmax of the subjects was significantly higher after application of either respiratory-gated or ECG-gated reconstruction. Conversely, the mean CMV was significantly lower following the application of respiratory-gated or ECG-gated reconstruction. The segment showing maximum accumulation was shifted to the adjacent segment in 25.8%, 38.7%, and 41.9% of cases in EX, ED, and ES images, respectively. Conclusion: In FDG PET/CT scanning for the diagnosis of CS, gated scanning is likely to increase quantitative accuracy, but the effect depends on the location and synchronization method. [ABSTRACT FROM AUTHOR]

Published

2023

2. Respiratory-gated 18F Fluorodeoxyglucose Positron Emission Tomography/Magnetic Resonance Imaging in Evaluation of Primary Gastric Lesions and Gastric Lymph Nodes in Patients with Gastric Cancer.

Author

Gülbahar Ateş, S., Aydos, U., Akdemir, Ü.Ö., Yüksel, O., Üner, A., Dursun, A., and Atay, L.Ö.

Subjects

*STOMACH tumors, *PREDICTIVE tests, *MAGNETIC resonance imaging, *LYMPH nodes, *CANCER patients, *POSITRON emission tomography, *RADIOPHARMACEUTICALS, *DEOXY sugars, *SENSITIVITY & specificity (Statistics), *HISTOLOGY, *BODY mass index, *RESPIRATION, *ABDOMINAL radiography

Abstract

To evaluate the added value of respiratory-gated positron emission tomography (PET) in 18F fluorodeoxyglucose (FDG) PET/magnetic resonance imaging (MRI) in the visual and semi-quantitative assessment of primary gastric lesions and gastric lymph nodes for patients with gastric cancer. In total, 102 upper abdominal respiratory-gated and whole-body 18F FDG PET/MRI of 88 patients with gastric cancer were evaluated visually and semi-quantitatively. For 41 patients who underwent surgery, histopathological and PET findings were compared. Three PET images were obtained from upper abdominal PET data: non-Q static (non-QS) PET from all counts, respiratory-gated Q static (QS) PET from counts in the end-expiration phase of breathing, shortened 4 min (S4min) PET that was reconstructed to obtain similar counts to QS PET. The semi-quantitative parameters (standardised uptake values, metabolic tumour volume, total lesion glycolysis) of primary lesions for each PET image, the sizes of primary lesions and the patient's body mass index were recorded. According to lymph node stations, the presence and numbers of positive lymph nodes and visual scores of lymph nodes for each PET image were recorded. The patients with smaller gastric lesions (≤30 mm) or higher body mass index (>30) had significantly higher standardised uptake value percentage changes in QS PET compared with non-QS PET (all P < 0.05). The third (lesser curvature), fourth (greater curvature) and sixth (infra-pyloric) lymph node stations had significantly higher visual scores in the QS PET than in the others. The fourth lymph node station had a significantly higher number of FDG-positive lymph node in the QS PET than in the non-QS and the whole-body PET images. In the fourth station, sensitivity, positive predictive value, negative predictive value and accuracy increased in the QS PET compared with the others. Respiratory-gated PET/MRI was found to be significantly superior in the evaluation of especially the fourth lymph node station, smaller gastric lesions and in the patients with a higher BMI compared with the non-respiratory-gated PET images. • Respiratory-gated PET is beneficial during abdominal PET/MRI in gastric cancer patients. • It was superior in the evaluation of perigastric gastric lymph nodes. • It may be more valuable in smaller gastric lesions and patients with higher BMI. [ABSTRACT FROM AUTHOR]

Published

2022

3. Impact of respiratory gating and ECG gating on 18F-FDG PET/CT for cardiac sarcoidosis

Author

Hanaoka, Kohei, Watanabe, Shota, Morimoto-Ishikawa, Daisuke, Kaida, Hayato, MD, Yamada, Takahiro, Yasuda, Masakazu, MD, Iwanaga, Yoshitaka, MD, Nakazawa, Gaku, MD, and Ishii, Kazunari

Published

2023

4. Evaluation of a direct motion estimation/correction method in respiratory-gated PET/MRI with motion-adjusted attenuation.

Author

Bousse, Alexandre, Manber, Richard, Holman, Beverley F., Atkinson, David, Arridge, Simon, Ourselin, Sébastien, Hutton, Brian F., and Thielemans, Kris

Subjects

*RESPIRATORY disease diagnosis, *DIAGNOSTIC imaging, *ATTENUATION of electromagnetic waves, *MAGNETIC resonance imaging, *MEDICAL imaging systems

Abstract

Purpose Respiratory motion compensation in PET/ CT and PET/ MRI is essential as motion is a source of image degradation (motion blur, attenuation artifacts). In previous work, we developed a direct method for joint image reconstruction/motion estimation ( JRM) for attenuation-corrected ( AC) respiratory-gated PET, which uses a single attenuation-map ( μ-map). This approach was successfully implemented for respiratory-gated PET/ CT, but since it relied on an accurate μ-map for motion estimation, the question of its applicability in PET/ MRI is open. The purpose of this work is to investigate the feasibility of JRM in PET/ MRI and to assess the robustness of the motion estimation when a degraded μ-map is used. Methods We performed a series of JRM reconstructions from simulated PET data using a range of simulated Dixon MRI sequence derived μ-maps with wrong attenuation values in the lungs, from −100% (no attenuation) to +100% (double attenuation), as well as truncated arms. We compared the estimated motions with the one obtained from JRM in ideal conditions (no noise, true μ-map as an input). We also applied JRM on 4 patient datasets of the chest, 3 of them containing hot lesions. Patient list-mode data were gated using a principal component analysis method. We compared SUVmax values of the JRM reconstructed activity images and non motion-corrected images. We also assessed the estimated motion fields by comparing the deformed JRM-reconstructed activity with individually non- AC reconstructed gates. Results Experiments on simulated data showed that JRM-motion estimation is robust to μ-map degradation in the sense that it produces motion fields similar to the ones obtained when using the true μ-map, regardless of the attenuation errors in the lungs (< 0.5% mean absolute difference with the reference motion field). When using a μ-map with truncated arms, JRM estimates a motion field that stretches the μ-map in order to match the projection data. Results on patient datasets showed that using JRM improves the SUVmax values of hot lesions significantly and suppresses motion blur. When the estimated motion fields are applied to the reconstructed activity, the deformed images are geometrically similar to the non- AC individually reconstructed gates. Conclusion Motion estimation by JRM is robust to variation of the attenuation values in the lungs. JRM successfully compensates for motion when applied to PET/ MRI clinical datasets. It provides a potential alternative to existing methods where the motion fields are pre-estimated from separate MRI measurements. [ABSTRACT FROM AUTHOR]

Published

2017

5. Integrating respiratory-gated PET-based target volume delineation in liver SBRT planning, a pilot study.

Author

Riou, Olivier, Serrano, Benjamin, Azria, David, Paulmier, Benoit, Villeneuve, Remy, Fenoglietto, Pascal, Artenie, Antonella, Ortholan, Cécile, Faraggi, Marc, and Thariat, Juliette

Subjects

*LIVER cancer, *LIVER metastasis, *POSITRON emission tomography, *COMPUTED tomography, *STEREOTACTIC radiotherapy, *RADIOTHERAPY treatment planning, *THERAPEUTICS

Abstract

Background To assess the feasibility and benefit of integrating four-dimensional (4D) Positron Emission Tomography (PET) - computed tomography (CT) for liver stereotactic body radiation therapy (SBRT) planning. Methods 8 patients with 14 metastases were accrued in the study. They all underwent a non-gated PET and a 4D PET centered on the liver. The same CT scan was used for attenuation correction, registration, and considered the planning CT for SBRT planning. Six PET phases were reconstructed for each 4D PET. By applying an individualized threshold to the 4D PET, a Biological Internal Target Volume (BITV) was generated for each lesion. A gated Planning Target Volume (PTVg) was created by adding 3 mm to account for set-up margins. This volume was compared to a manual Planning Target Volume (PTV) delineated with the help of a semi-automatic Biological Target Volume (BTV) obtained from the non-gated exam. A 5 mm radial and a 10 mm craniocaudal margins were applied to account for tumor motion and set-up margins to create the PTV. Results One undiagnosed liver metastasis was discovered thanks to the 4D PET. The semi-automatic BTV were significantly smaller than the BITV (p = 0.0031). However, after applying adapted margins, 4D PET allowed a statistically significant decrease in the PTVg as compared to the PTV (p = 0.0052). Conclusions In comparison to non-gated PET, 4D PET may better define the respiratory movements of liver targets and improve SBRT planning for liver metastases. Furthermore, non respiratorygated PET exams can both misdiagnose liver metastases and underestimate the real internal target volumes. [ABSTRACT FROM AUTHOR]

Published

2014

6. Integrating respiratory-gated PET-based target volume delineation in liver SBRT planning, a pilot study

Author

Benoit Paulmier, Pascal Fenoglietto, Cécile Ortholan, Olivier Riou, Antonella Artenie, Rémy Villeneuve, Marc Faraggi, Benjamin Serrano, David Azria, and Juliette Thariat

Subjects

Male, medicine.medical_specialty, Respiratory-Gated Imaging Techniques, Radiotherapy planning, Stereotactic body radiation therapy, medicine.medical_treatment, Planning target volume, Computed tomography, Pilot Projects, Radiosurgery, Liver metastases, Imaging, Three-Dimensional, Neoplasms, medicine, Humans, Radiology, Nuclear Medicine and imaging, 4D PET, Prospective Studies, Aged, Neoplasm Staging, SBRT, medicine.diagnostic_test, business.industry, Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted, Research, Liver Neoplasms, Radiotherapy Dosage, Middle Aged, Prognosis, Tumor Burden, Respiratory-gated PET, Radiation therapy, Oncology, Radiology Nuclear Medicine and imaging, Positron emission tomography, Positron-Emission Tomography, Female, Radiology, Tomography, Radiotherapy, Intensity-Modulated, business, Nuclear medicine, Tomography, X-Ray Computed, Emission computed tomography, Follow-Up Studies

Abstract

Background To assess the feasibility and benefit of integrating four-dimensional (4D) Positron Emission Tomography (PET) – computed tomography (CT) for liver stereotactic body radiation therapy (SBRT) planning. Methods 8 patients with 14 metastases were accrued in the study. They all underwent a non-gated PET and a 4D PET centered on the liver. The same CT scan was used for attenuation correction, registration, and considered the planning CT for SBRT planning. Six PET phases were reconstructed for each 4D PET. By applying an individualized threshold to the 4D PET, a Biological Internal Target Volume (BITV) was generated for each lesion. A gated Planning Target Volume (PTVg) was created by adding 3 mm to account for set-up margins. This volume was compared to a manual Planning Target Volume (PTV) delineated with the help of a semi-automatic Biological Target Volume (BTV) obtained from the non-gated exam. A 5 mm radial and a 10 mm craniocaudal margins were applied to account for tumor motion and set-up margins to create the PTV. Results One undiagnosed liver metastasis was discovered thanks to the 4D PET. The semi-automatic BTV were significantly smaller than the BITV (p = 0.0031). However, after applying adapted margins, 4D PET allowed a statistically significant decrease in the PTVg as compared to the PTV (p = 0.0052). Conclusions In comparison to non-gated PET, 4D PET may better define the respiratory movements of liver targets and improve SBRT planning for liver metastases. Furthermore, non respiratory-gated PET exams can both misdiagnose liver metastases and underestimate the real internal target volumes.

Published

2014

7. The clinical significance and management of lesion motion due to respiration during PET/CT scanning

Author

Jason, Callahan, Tomas, Kron, Michal, Schneider-Kolsky, and Rodney J, Hicks

Subjects

4D PET/CT, lesion motion, Lung Neoplasms, Movement, Respiration, clinical significance, Review, Multimodal Imaging, Respiratory-gated PET, Positron-Emission Tomography, Therapy, Computer-Assisted, Humans, Artifacts, Tomography, X-Ray Computed

Abstract

Lesion movement during positron emission tomography (PET) scan acquisition due to normal respiration is a common source of artefact. A PET scan is acquired in multiple couch positions of between 2 and 5 min duration with the patient breathing freely. A PET-avid lesion will become blurred if affected by respiratory motion, an effect similar to that created when a person moves in a photograph. This motion also frequently causes misregistration between the PET and computed tomography (CT) scan acquired for attenuation correction and anatomical correlation on hybrid scanners. The compounding effects of blurring and misregistration in whole-body PET/CT imaging make accurate characterization of PET-avid disease in areas of high respiratory motion challenging. There is also increasing interest in using PET quantitatively to assess disease response in both clinical reporting and trials. However, at this stage, no response criteria take the effect of respiratory motion into account when calculating the standardized uptake value on a PET scan. A number of different approaches have been described in the literature to address the issue of respiratory motion in PET/CT scanning. This review details the clinical significance of lesion movement due to respiration and discusses various imaging techniques that have been investigated to manage the effects of respiratory motion in PET/CT scanning.

Published

2011

8. An implementation of time-efficient respiratory-gated PET acquisition by repeated breath-holds.

Author

Skretting A, Revheim ME, Knudtsen IS, Johnsrud K, and Bogsrud TV

Subjects

Artifacts, Fluorodeoxyglucose F18, Humans, Patient Positioning, Radiopharmaceuticals, Whole Body Imaging, Liver Diseases diagnostic imaging, Lung Diseases diagnostic imaging, Multimodal Imaging methods, Positron-Emission Tomography, Respiration, Tomography, X-Ray Computed

Abstract

Background: Respiratory gating in positron emission tomography (PET) is used to improve detection of small tumors in the lower lung regions and in the liver, and to obtain a better estimate of the standardized uptake value (SUV)., Purpose: To develop a time-efficient method for acquisition of respiratory-gated PET/CT that would produce one single high quality image volume corresponding to a breath-hold state., Material and Methods: An instrument was developed that displayed to the patient either red or green numbers, counting down from a chosen maximum to one at a rate of one dial per second. The patient was instructed to repeatedly hold the breath in moderate inspiration when red numbers were displayed and to breathe freely during display of green numbers. PET data were acquired in list mode and trigger signals were sent to the scanner and inserted into the list file each time the color of the countdown numbers switched from green to red. Data acquired during breath-holds were used to create one single image volume., Results: High quality breath-hold images were obtained from 10 min data acquisition at one bed position. Improved image quality compared to standard whole-body PET was demonstrated by a significant reduction of noise (standard deviation) in regions of normal liver tissues., Conclusion: The instruction to perform repeated breath-holds was well understood by patients and they cooperated satisfactorily. When the new procedure is used the duration of the data acquisition may typically be reduced by a factor of 4 compared to conventional respiratory-gated protocols where the patient breathes freely.

Published

2013