Combined PET/MRI: Global Warming—Summary Report of the 6th International Workshop on PET/MRI, March 27–29, 2017, Tübingen, Germany

Bailey, Dale L.; Pichler, Bernd J.; Gückel, Brigitte; Antoch, Gerald; Barthel, Henryk; Bhujwalla, Zaver M.; Biskup, Saskia; Biswal, Sandip; Bitzer, Michael; Boellaard, Ronald; Braren, Rickmer; Brendle, Cornelia; Brindle, Kevin M.; Chiti, Arturo; Fougère, Christian la; Gillies, Robert J.; Goh, Vicky; Goyen, Mathias; Hacker, Marcus; Heukamp, Lukas C.; Knudsen, Gitte M.; Krackhardt, Angela M.; Law, Ian; Morris, John C.; Nikolaou, Konstantin; Nuyts, Johan; Ordoñez, Alvaro A.; Pantel, Klaus; Quick, Harald H.; Riklund, Katrine; Sabri, Osama; Sattler, Bernhard; Troost, Esther G.C.; Zaiß, Moritz; Zender, Lars; Beyer, Thomas

doi:10.1007/s11307-017-1123-5

Cited by 49 publications

(42 citation statements)

References 78 publications

(60 reference statements)

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“…Thus, artifacts are mostly easily detectable in MR-AC, indicating regions of potentially inaccurate PET quantification [45,54]. ▪ While new features for the improvement of MR-AC are constantly developed and implemented into the commercial software of available PET/MRI systems, including high-resolution Dixon AC, ultrashort echo time (UTE), zero TE (ZTE) sequences and/or bone models for bone detection in PET/MRI attenuation correction [17,34,40,41], users need to remain attentive to MR-AC related limitations and artifacts in SUV quantification. ▪ Truncation artifacts along patient arms in MR-AC may affect PET quantification.…”

Section: Artifactsmentioning

confidence: 99%

Whole-Body [18F]-FDG-PET/MRI for Oncology: A Consensus Recommendation

Umutlu

Beyer

Grueneisen

et al. 2019

Fortschr Röntgenstr

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Combined PET/MR imaging (PET/MRI) was proposed for patient management in 2006 with first commercial versions of integrated whole-body systems becoming available as of 2010. PET/MRI followed the prior evolution of hybrid imaging as attested by the successful adoption of combined PET/CT and SPECT/CT since the early 2000 s. Today, around 150 whole-body PET/MRI systems have become operational worldwide. One of the main application fields of PET/MRI is oncologic imaging. Despite the increasing use of PET/MRI, little governance regarding standardized PET/MRI protocols has been provided to date. Standardization and harmonization of imaging protocols is, however, mandatory for efficient on-site patient management and multi-center studies. This document summarizes consensus recommendations on key aspects of patient referral and preparation, PET/MRI workflow and imaging protocols, as well as reporting strategies for whole-body [18F]-FDG-PET/MRI. These recommendations were created by early adopters and key experts in the field of PET, MRI and PET/MRI. This document is intended to provide guidance for the harmonization and standardization of PET/MRI today and to support wider clinical adoption of this imaging modality for the benefit of patients. Citation Format

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Section: Artifactsmentioning

confidence: 99%

Whole-Body [18F]-FDG-PET/MRI for Oncology: A Consensus Recommendation

Umutlu

Beyer

Grueneisen

et al. 2019

Fortschr Röntgenstr

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“…Despite the outlined complexity of the topic, I like to conclude with a statement from the 6 th Tübingen International Workshop on PET/MR: “There was general agreement between the participants and many clinical users that MRAC has been solved to the degree required for clinical use based on accepted image metrics.” This statement is supportive of my view: we have the tools and methods for accurate and robust clinical use of PET/MR already at hand. Given the mentioned broad variety of MRAC methods, there is, however, further need toward quality control and standardization efforts in PET/MR AC .…”

Section: Against the Proposition: Harald H Quick Phdmentioning

confidence: 99%

Current commercial techniques for MRI‐guided attenuation correction are insufficient and will limit the wider acceptance of PET/MRI technology in the clinic

Catana

Quick

Zaidi³

2018

Medical Physics

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OVERVIEWWhole-body hybrid PET/MR imaging has been used since its introduction in 2010 in clinical and research settings for diagnosis, staging and restaging, assessment of response to treatment, and radiation therapy planning. However, the quantitative potential of PET/MRI is challenged by the lack of reliable and accurate MRI-guided attenuation correction (MRAC) owing to the lack of direct relationship between MRI signal, reflecting proton density and relaxation time properties, and electron density, which is linked to photon attenuation properties of biological tissues. Despite the progress made during the last decade, MRAC is still in its infancy and remains problematic particularly in whole-body imaging. While some think that current techniques implemented on commercial systems for MRAC do not constitute a viable solution and are hampering the wider acceptance of PET/MRI technology in the clinic, others think that, despite their limitations, these techniques provide adequate correction fulfilling the requirements of the different clinical applications of this technology. This is the topic of this month's Point/Counterpoint debate.Arguing for the Proposition is Ciprian Catana, MD, PhD. Over the last decade, he has concentrated on further developing and validating this novel technology, identifying and implementing methods to best exploit the combined data, and developing quantitative PET/MRI for human use. Working closely with dozens of basic science researchers and physician-scientists, Dr. Catana is currently applying these advanced tools to the study of normal brain and neuropsychiatric diseases as well as exploring the clinical potential of this technology for wholebody oncological applications. Dr. Catana has authored more than 75 peer-reviewed manuscripts and book chapters and holds or has filed provisional patent applications for several technological and methodological innovations in the field of PET/MRI.

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“…variable amounts of mutational Kras (24) and the likelihood of ongoing transitional processes, entropy as a continuous variable can be imagined as a non-invasive "sensor" of such events that correlates with the extent of basal-like regions within a particular tumor. The testing of such hypotheses is challenging, requiring an integrated whole-tumor analysis, including high data-rich imaging, histopathology and molecular profiling(25).The rapid evolution of new therapeutic options in the treatment of PDAC requires the development of markers for a reliable pre-therapeutic patient stratification and -in light of the above-mentioned plasticity, therapy monitoring. Conroy et al demonstrated significantly improved survival rates of FOLFIRINOX over Gemcitabine monotherapy in the palliative setting…”

mentioning

confidence: 99%

A machine learning algorithm predicts molecular subtypes in pancreatic ductal adenocarcinoma with differential response to gemcitabine-based versus FOLFIRINOX chemotherapy

Kaissis

Ziegelmayer

Lohöfer

et al. 2019

Preprint

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Purpose: Development of a supervised machine-learning model capable of predicting clinically relevant molecular subtypes of pancreatic ductal adenocarcinoma (PDAC) from diffusion-weighted-imaging-derived radiomic features. Methods: The retrospective observational study assessed 55 surgical PDAC patients. Molecular subtypes were defined by immunohistochemical staining of KRT81. Tumors were manually segmented and 1606 radiomic features were extracted with PyRadiomics. A gradient-boosted-tree algorithm (XGBoost) was trained on 70% of the patients (N=28) and tested on 30% (N=17) to predict KRT81+ vs. KRT81-tumor subtypes. The average sensitivity, specificity and ROC-AUC value were calculated. Chemotherapy response was assessed stratified by subtype. Radiomic feature importance was ranked. Results: The mean±STDEV sensitivity, specificity and ROC-AUC were 0.90±0.07, 0.92±0.11, and 0.93±0.07, respectively. Patients with a KRT81+ subtype experienced significantly diminished median overall survival compared to KRT81-patients (7.0 vs. 22.6 months, HR 1.44, log-rank-test P=<0.001) and a significantly improved response to gemcitabine-based chemotherapy over FOLFIRINOX (10.14 vs. 3.8 months median overall survival, HR 0.85, P=0.037) compared to KRT81-patients, who responded significantly better to FOLFIRINOX over gemcitabine-based treatment (30.8 vs. 13.4 months median overall survival, HR 0.88, P=0.027). Conclusions:The machine-learning based analysis of radiomic features enables the prediction of subtypes of PDAC, which are highly relevant for overall patient survival and response to chemotherapy.

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Combined PET/MRI: Global Warming—Summary Report of the 6th International Workshop on PET/MRI, March 27–29, 2017, Tübingen, Germany

Cited by 49 publications

References 78 publications

Whole-Body [18F]-FDG-PET/MRI for Oncology: A Consensus Recommendation

Whole-Body [18F]-FDG-PET/MRI for Oncology: A Consensus Recommendation

Current commercial techniques for MRI‐guided attenuation correction are insufficient and will limit the wider acceptance of PET/MRI technology in the clinic

A machine learning algorithm predicts molecular subtypes in pancreatic ductal adenocarcinoma with differential response to gemcitabine-based versus FOLFIRINOX chemotherapy

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