Your search keyword '"Thomas, Beyer"' showing total 368 results

1. Detection of cancer‐associated cachexia in lung cancer patients using whole‐body [18F]FDG‐PET/CT imaging: A multi‐centre study

Author

Daria Ferrara, Elisabetta M. Abenavoli, Thomas Beyer, Stefan Gruenert, Marcus Hacker, Swen Hesse, Lukas Hofmann, Smilla Pusitz, Michael Rullmann, Osama Sabri, Roberto Sciagrà, Lalith Kumar Shiyam Sundar, Anke Tönjes, Hubert Wirtz, Josef Yu, and Armin Frille

Subjects

[18F]Fluoro‐2‐deoxy‐D‐glucose, Cachexia, Lung cancer, Metabolism, PET/CT, Diseases of the musculoskeletal system, RC925-935, Human anatomy, QM1-695

Abstract

Abstract Background Cancer‐associated cachexia (CAC) is a metabolic syndrome contributing to therapy resistance and mortality in lung cancer patients (LCP). CAC is typically defined using clinical non‐imaging criteria. Given the metabolic underpinnings of CAC and the ability of [18F]fluoro‐2‐deoxy‐D‐glucose (FDG)‐positron emission tomography (PET)/computer tomography (CT) to provide quantitative information on glucose turnover, we evaluate the usefulness of whole‐body (WB) PET/CT imaging, as part of the standard diagnostic workup of LCP, to provide additional information on the onset or presence of CAC. Methods This multi‐centre study included 345 LCP who underwent WB [18F]FDG‐PET/CT imaging for initial clinical staging. A weight loss grading system (WLGS) adjusted to body mass index was used to classify LCP into ‘No CAC’ (WLGS‐0/1 at baseline prior treatment and at first follow‐up: N = 158, 51F/107M), ‘Dev CAC’ (WLGS‐0/1 at baseline and WLGS‐3/4 at follow‐up: N = 90, 34F/56M), and ‘CAC’ (WLGS‐3/4 at baseline: N = 97, 31F/66M). For each CAC category, mean standardized uptake values (SUV) normalized to aorta uptake () and CT‐defined volumes were extracted for abdominal and visceral organs, muscles, and adipose‐tissue using automated image segmentation of baseline [18F]FDG‐PET/CT images. Imaging and non‐imaging parameters from laboratory tests were compared statistically. A machine‐learning (ML) model was then trained to classify LCP as ‘No CAC’, ‘Dev CAC’, and ‘CAC’ based on their imaging parameters. SHapley Additive exPlanations (SHAP) analysis was employed to identify the key factors contributing to CAC development for each patient. Results The three CAC categories displayed multi‐organ differences in . In all target organs, was higher in the ‘CAC’ cohort compared with ‘No CAC’ (P in ‘CAC’ was reduced by 5%. The ‘Dev CAC’ cohort displayed a small but significant increase in of pancreas (+4%), skeletal‐muscle (+7%), subcutaneous adipose‐tissue (+11%), and visceral adipose‐tissue (+15%). In ‘CAC’ patients, a strong negative Spearman correlation (ρ = −0.8) was identified between and volumes of adipose‐tissue. The machine‐learning model identified ‘CAC’ at baseline with 81% of accuracy, highlighting of spleen, pancreas, liver, and adipose‐tissue as most relevant features. The model performance was suboptimal (54%) when classifying ‘Dev CAC’ versus ‘No CAC’. Conclusions WB [18F]FDG‐PET/CT imaging reveals groupwise differences in the multi‐organ metabolism of LCP with and without CAC, thus highlighting systemic metabolic aberrations symptomatic of cachectic patients. Based on a retrospective cohort, our ML model identified patients with CAC with good accuracy. However, its performance in patients developing CAC was suboptimal. A prospective, multi‐centre study has been initiated to address the limitations of the present retrospective analysis.

Published

2024

2. Extracting value from total-body PET/CT image data - the emerging role of artificial intelligence

Author

Lalith Kumar Shiyam Sundar, Sebastian Gutschmayer, Marcel Maenle, and Thomas Beyer

Subjects

Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract The evolution of Positron Emission Tomography (PET), culminating in the Total-Body PET (TB-PET) system, represents a paradigm shift in medical imaging. This paper explores the transformative role of Artificial Intelligence (AI) in enhancing clinical and research applications of TB-PET imaging. Clinically, TB-PET’s superior sensitivity facilitates rapid imaging, low-dose imaging protocols, improved diagnostic capabilities and higher patient comfort. In research, TB-PET shows promise in studying systemic interactions and enhancing our understanding of human physiology and pathophysiology. In parallel, AI’s integration into PET imaging workflows—spanning from image acquisition to data analysis—marks a significant development in nuclear medicine. This review delves into the current and potential roles of AI in augmenting TB-PET/CT’s functionality and utility. We explore how AI can streamline current PET imaging processes and pioneer new applications, thereby maximising the technology’s capabilities. The discussion also addresses necessary steps and considerations for effectively integrating AI into TB-PET/CT research and clinical practice. The paper highlights AI’s role in enhancing TB-PET’s efficiency and addresses the challenges posed by TB-PET’s increased complexity. In conclusion, this exploration emphasises the need for a collaborative approach in the field of medical imaging. We advocate for shared resources and open-source initiatives as crucial steps towards harnessing the full potential of the AI/TB-PET synergy. This collaborative effort is essential for revolutionising medical imaging, ultimately leading to significant advancements in patient care and medical research.

Published

2024

3. Low-dose and standard-dose whole-body [18F]FDG-PET/CT imaging: implications for healthy controls and lung cancer patients

Author

Daria Ferrara, Lalith Kumar Shiyam Sundar, Zacharias Chalampalakis, Barbara Katharina Geist, Daniela Gompelmann, Sebastian Gutschmayer, Marcus Hacker, Hunor Kertész, Kilian Kluge, Marco Idzko, Werner Langsteger, Josef Yu, Ivo Rausch, and Thomas Beyer

Subjects

PET/CT, low-activity imaging, radiation exposure, [18F]fluoro-2-deoxy-D-glucose, standardized uptake values, Physics, QC1-999

Abstract

Aim: High-sensitivity hybrid positron emission tomography (PET) imaging using advanced whole-body (WB) or total-body PET/computed tomography (CT) systems permits reducing injected tracer activity while preserving diagnostic quality. Such approaches are promising for healthy control studies or exploring inter-organ communication in systemic diseases. This study assessed test/retest variations in the fluoro-2-deoxy-D-glucose (FDG) uptake in key organs from low-dose (LD) and standard-dose (STD) [18F]FDG-PET/CT imaging protocols in healthy controls and lung cancer patients.Methods: A total of 19 healthy controls (19–62 years, 46–104 kg, 10 M/9 F) and 7 lung cancer patients (47–77 years, 50–88 kg, 4 M/3 F) underwent [18F]FDG-PET/CT imaging. All subjects were first injected (“test,” LD) with 28 ± 2 MBq FDG and underwent a dynamic (0–67 min post-injection) WB imaging protocol with LD-CT. Then, 90 min post-LD injection, the subjects were repositioned and injected with 275 ± 16 MBq FDG (“retest,” STD). Second LD-CT and STD-CT scans were acquired for healthy controls and patients, respectively. Static images (55–67 min post-injection) were considered for subsequent analysis. The CT images were used to automatically segment the target volumes of interest. Standardized uptake values normalized to the body weight (SUVBW) were extracted for each volume of interest. The mean SUVBW were compared for both LD/STD conditions with paired t-tests. In patients, FDG-avid lesions were manually delineated on LD and STD static images. Effective dose levels were estimated from both the CT and PET acquisitions.Results: Organ-based mean SUVBW were similar between the LD and STD (mean %difference ≤5%) in both healthy controls and cancer patients, except in the heart. Intra-control test/retest variability was significant in the brain, heart, and skeletal muscle (p < 0.05). While 17 lesions were delineated on the STD images of the patients, only 10/17 lesions were identified on the LD images due to increased image noise. Lesion-based mean SUVBW were similar between LD and STD acquisitions (p = 0.49, %difference = 10%). In patients, the effective doses were (1.9 ± 0.2) mSv (LD-CT), (16.6 ± 5.4) mSv (STD-CT), (0.5 ± 0.1) mSv (LD-PET), and (4.6 ± 0.3) mSv (STD-PET).Conclusion: LD and STD [18F]FDG injections in healthy controls and lung cancer patients yielded comparable mean SUVBW, except in the heart. Dose levels may be reduced for [18F]FDG-PET imaging without a loss in mean SUVBW accuracy, promoting LD-PET/CT protocols for studying multi-organ metabolic patterns. In oncology patients, this approach may be hindered by a lower diagnostic quality in the presence of significant noise.

Published

2024

4. Development of anthropomorphic mathematical phantoms for simulations of clinical cases in diagnostic nuclear medicine.

Author

Natalya Denisova, Marina Ondar, Hunor Kertesz, and Thomas Beyer

Published

2023

5. Additively manufactured, solid object structures for adjustable image contrast in Magnetic Resonance Imaging

Author

Alejandra Valladares, Gunpreet Oberoi, Andreas Berg, Thomas Beyer, Ewald Unger, and Ivo Rausch

Subjects

MRI, Physical phantoms, Tumour heterogeneity, Additive manufacturing, PolyJet, 3D printing, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

The choice of materials challenges the development of Magnetic Resonance Imaging (MRI) phantoms and, to date, is mainly limited to water-filled compartments or gel-based components. Recently, solid materials have been introduced through additive manufacturing (AM) to mimic complex geometrical structures. Nonetheless, no such manufactured solid materials are available with controllable MRI contrast to mimic organ substructures or lesion heterogeneities. Here, we present a novel AM design that allows MRI contrast manipulation by varying the partial volume contribution to a ROI/voxel of MRI-visible material within an imaging object. Two sets of 11 cubes and three replicates of a spherical tumour model were designed and printed using AM. Most samples presented varying MRI-contrast in standard MRI sequences, based mainly on spin density and partial volume signal variation. A smooth and continuous MRI-contrast gradient could be generated in a single-compartment tumour model. This concept supports the development of more complex MRI phantoms that mimic the appearance of heterogeneous tumour tissues.

Published

2022

6. Diagnostic Reference Levels for nuclear medicine imaging in Austria: A nationwide survey of used dose levels for adult patients

Author

David Wachabauer, Thomas Beyer, Manfred Ditto, Hans-Jürgen Gallowitsch, Michael Hinterreiter, Bettina Ibi, Phillipp Malle, Siroos Mirzaei, Florian Smetana, Anton Staudenherz, Boris Warwitz, Georg Zettinig, and Ivo Rausch

Subjects

Radiation Protection, Nuclear medicine, Diagnostic reference levels, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Purpose: To assess dose levels in routine nuclear medicine (NUC) procedures in Austria as a prior to a legislative update of the National Diagnostic Reference Levels (NDRL). Method: As part of a nationwide survey of common NUC-examinations between June 2019 and November 2019, data sets were collected from 33 Austrian hospitals with NUC equipment. All hospitals were asked to report the NUC imaging devices in use (model, type, year of manufacture, detector material, collimators), the standard protocol parameters for selected examinations (standard activity, collimator, average acquisition time, reconstruction type, use of time-of-flight) and to report data from 10 representative examinations (e.g. injected activity, weight), incl. the most common NUC-examinations for planar imaging/SPECT and PET. Median/mean values for injected activity were calculated and compared to current Austrian and international NDRL. A Pearson correlation coefficient was computed comparing different variables. Results: In total, all 33 hospitals (100% response rate) reported data for this study for 60 SPECT devices, 21 PET/CT devices and 23 scintigraphy devices. Fixed activity values for scintigraphy/SPECT and PET were employed by about 90% and 56% of the hospitals, respectively. The most widely performed examinations for scintigraphy/SPECT are bone imaging, thyroid imaging, renal imaging (with MAG3/EC) and lung perfusion imaging (in 88% of the hospitals) and F-18 FDG-PET studies for oncology indications (in 100% of the hospitals). Significant correlations were found for patient weight and injected activity (scintigraphy/SPECT), use of iterative reconstruction and injected activity (PET) as well as size of field-of-view and injected activity (PET). Conclusions: The reported injected activity levels were comparable to those in other countries. However, for procedures for which NDRL exist, deviations in injected activities of >20% compared to the NDRL were found. These deviations are assumed to result mainly from advances in technology but also from deviations between NDRL and prescribed activities as given in the information leaflets of the radiopharmaceuticals.

Published

2022

7. Positron range in combination with point-spread-function correction: an evaluation of different implementations for [124I]-PET imaging

Author

Hunor Kertész, Maurizio Conti, Vladimir Panin, Jorge Cabello, Deepak Bharkhada, Thomas Beyer, Laszlo Papp, Walter Jentzen, Jacobo Cal-Gonzalez, Joaquín L. Herraiz, Alejandro López-Montes, and Ivo Rausch

Subjects

PET, Positron range correction, PRC, Image reconstruction, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Abstract Aim To evaluate the effect of combining positron range correction (PRC) with point-spread-function (PSF) correction and to compare different methods of implementation into iterative image reconstruction for 124I-PET imaging. Materials and methods Uniform PR blurring kernels of 124I were generated using the GATE (GEANT4) framework in various material environments (lung, water, and bone) and matched to a 3D matrix. The kernels size was set to 11 × 11 × 11 based on the maximum PR in water and the voxel size of the PET system. PET image reconstruction was performed using the standard OSEM algorithm, OSEM with PRC implemented before the forward projection (OSEM+PRC simplified) and OSEM with PRC implemented in both forward- and back-projection steps (full implementation) (OSEM+PRC). Reconstructions were repeated with resolution recovery, point-spread function (PSF) included. The methods and kernel variation were validated using different phantoms filled with 124I acquired on a Siemens mCT PET/CT system. The data was evaluated for contrast recovery and image noise. Results Contrast recovery improved by 2–10% and 4–37% with OSEM+PRC simplified and OSEM+PRC, respectively, depending on the sphere size of the NEMA IQ phantom. Including PSF in the reconstructions further improved contrast by 4–19% and 3–16% with the PSF+PRC simplified and PSF+PRC, respectively. The benefit of PRC was more pronounced within low-density material. OSEM-PRC and OSEM-PSF as well as OSEM-PSF+PRC in its full- and simplified implementation showed comparable noise and convergence. OSEM-PRC simplified showed comparably faster convergence but at the cost of increased image noise. Conclusions The combination of the PSF and PRC leads to increased contrast recovery with reduced image noise compared to stand-alone PSF or PRC reconstruction. For OSEM-PRC reconstructions, a full implementation in the reconstruction is necessary to handle image noise. For the combination of PRC with PSF, a simplified PRC implementation can be used to reduce reconstruction times.

Published

2022

8. Comparison of cardiac image-derived input functions for quantitative whole body [18F]FDG imaging with arterial blood sampling

Author

Murray Bruce Reed, Godber Mathis Godbersen, Chrysoula Vraka, Ivo Rausch, Magdalena Ponce de León, Valentin Popper, Barbara Geist, Lukas Nics, Arkadiusz Komorowski, Georgios Karanikas, Thomas Beyer, Tatjana Traub-Weidinger, Andreas Hahn, Werner Langsteger, Marcus Hacker, and Rupert Lanzenberger

Subjects

arterial input function, positron emission tomography (PET), image-derived input function, kinetic modelling, [18F]2-fluoro-2-deoxy-D-glucose ([18F]FDG), Physiology, QP1-981

Abstract

Introduction: Dynamic positron emission tomography (PET) and the application of kinetic models can provide important quantitative information based on its temporal information. This however requires arterial blood sampling, which can be challenging to acquire. Nowadays, state-of-the-art PET/CT systems offer fully automated, whole-body (WB) kinetic modelling protocols using image-derived input functions (IDIF) to replace arterial blood sampling. Here, we compared the validity of an automatic WB kinetic model protocol to the reference standard arterial input function (AIF) for both clinical and research settings.Methods: Sixteen healthy participants underwent dynamic WB [18F]FDG scans using a continuous bed motion PET/CT system with simultaneous arterial blood sampling. Multiple processing pipelines that included automatic and manually generated IDIFs derived from the aorta and left ventricle, with and without motion correction were compared to the AIF. Subsequently generated quantitative images of glucose metabolism were compared to evaluate performance of the different input functions.Results: We observed moderate to high correlations between IDIFs and the AIF regarding area under the curve (r = 0.49–0.89) as well as for the cerebral metabolic rate of glucose (CMRGlu) (r = 0.68–0.95). Manual placing of IDIFs and motion correction further improved their similarity to the AIF.Discussion: In general, the automatic vendor protocol is a feasible approach for the quantification of CMRGlu for both, clinical and research settings where expertise or time is not available. However, we advise on a rigorous inspection of the placement of the volume of interest, the resulting IDIF, and the quantitative values to ensure valid interpretations. In protocols requiring longer scan times or where cohorts are prone to involuntary movement, manual IDIF definition with additional motion correction is recommended, as this has greater accuracy and reliability.

Published

2023

9. Sex-specific radiomic features of L-[S-methyl-11C] methionine PET in patients with newly-diagnosed gliomas in relation to IDH1 predictability

Author

Laszlo Papp, Sazan Rasul, Clemens P. Spielvogel, Denis Krajnc, Nina Poetsch, Adelheid Woehrer, Eva-Maria Patronas, Boglarka Ecsedi, Julia Furtner, Markus Mitterhauser, Ivo Rausch, Georg Widhalm, Thomas Beyer, Marcus Hacker, and Tatjana Traub-Weidinger

Subjects

MET-PET, glioma, sex, IDH1, radiomics, imaging biomarker, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

IntroductionAmino-acid positron emission tomography (PET) is a validated metabolic imaging approach for the diagnostic work-up of gliomas. This study aimed to evaluate sex-specific radiomic characteristics of L-[S-methyl-11Cmethionine (MET)-PET images of glioma patients in consideration of the prognostically relevant biomarker isocitrate dehydrogenase (IDH) mutation status.MethodsMET-PET of 35 astrocytic gliomas (13 females, mean age 41 ± 13 yrs. and 22 males, mean age 46 ± 17 yrs.) and known IDH mutation status were included. All patients underwent radiomic analysis following imaging biomarker standardization initiative (IBSI)-conform guidelines both from standardized uptake value (SUV) and tumor-to-background ratio (TBR) PET values. Aligned Monte Carlo (MC) 100-fold split was utilized for SUV and TBR dataset pairs for both sex and IDH-specific analysis. Borderline and outlier scores were calculated for both sex and IDH-specific MC folds. Feature ranking was performed by R-squared ranking and Mann-Whitney U-test together with Bonferroni correction. Correlation of SUV and TBR radiomics in relation to IDH mutational status in male and female patients were also investigated.ResultsThere were no significant features in either SUV or TBR radiomics to distinguish female and male patients. In contrast, intensity histogram coefficient of variation (ih.cov) and intensity skewness (stat.skew) were identified as significant to predict IDH +/-. In addition, IDH+ females had significant ih.cov deviation (0.031) and mean stat.skew (-0.327) differences compared to IDH+ male patients (0.068 and -0.123, respectively) with two-times higher standard deviations of the normal brain background MET uptake as well.DiscussionWe demonstrated that female and male glioma patients have significantly different radiomic profiles in MET PET imaging data. Future IDH prediction models shall not be built on mixed female-male cohorts, but shall rely on sex-specific cohorts and radiomic imaging biomarkers.

Published

2023

10. Soft Tissue Sarcoma Co-segmentation in Combined MRI and PET/CT Data.

Author

Theresa Neubauer, Maria Wimmer 0002, Astrid Berg, David Major, Dimitrios Lenis, Thomas Beyer, Jelena Saponjski, and Katja Bühler

Published

2020

11. Automated data preparation for in vivo tumor characterization with machine learning

Author

Denis Krajnc, Clemens P. Spielvogel, Marko Grahovac, Boglarka Ecsedi, Sazan Rasul, Nina Poetsch, Tatjana Traub-Weidinger, Alexander R. Haug, Zsombor Ritter, Hussain Alizadeh, Marcus Hacker, Thomas Beyer, and Laszlo Papp

Subjects

cancer, hybrid imaging, PET, data preprocessing, machine learning, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

BackgroundThis study proposes machine learning-driven data preparation (MLDP) for optimal data preparation (DP) prior to building prediction models for cancer cohorts.MethodsA collection of well-established DP methods were incorporated for building the DP pipelines for various clinical cohorts prior to machine learning. Evolutionary algorithm principles combined with hyperparameter optimization were employed to iteratively select the best fitting subset of data preparation algorithms for the given dataset. The proposed method was validated for glioma and prostate single center cohorts by 100-fold Monte Carlo (MC) cross-validation scheme with 80-20% training-validation split ratio. In addition, a dual-center diffuse large B-cell lymphoma (DLBCL) cohort was utilized with Center 1 as training and Center 2 as independent validation datasets to predict cohort-specific clinical endpoints. Five machine learning (ML) classifiers were employed for building prediction models across all analyzed cohorts. Predictive performance was estimated by confusion matrix analytics over the validation sets of each cohort. The performance of each model with and without MLDP, as well as with manually-defined DP were compared in each of the four cohorts.ResultsSixteen of twenty established predictive models demonstrated area under the receiver operator characteristics curve (AUC) performance increase utilizing the MLDP. The MLDP resulted in the highest performance increase for random forest (RF) (+0.16 AUC) and support vector machine (SVM) (+0.13 AUC) model schemes for predicting 36-months survival in the glioma cohort. Single center cohorts resulted in complex (6-7 DP steps) DP pipelines, with a high occurrence of outlier detection, feature selection and synthetic majority oversampling technique (SMOTE). In contrast, the optimal DP pipeline for the dual-center DLBCL cohort only included outlier detection and SMOTE DP steps.ConclusionsThis study demonstrates that data preparation prior to ML prediction model building in cancer cohorts shall be ML-driven itself, yielding optimal prediction models in both single and multi-centric settings.

Published

2022

12. A scale space theory based motion correction approach for dynamic PET brain imaging studies

Author

Sebastian Gutschmayer, Otto Muzik, Zacharias Chalampalakis, Daria Ferrara, Josef Yu, Kilian Kluge, Ivo Rausch, Ronald Boellaard, Sandeep S.V. Golla, Sven Zuehlsdorff, Hartwig Newiger, Thomas Beyer, and Lalith Kumar Shiyam Sundar

Subjects

brain motion correction, scale-space, dynamic PET imaging, frame-based algorithm, gaussian pyramid algorithms, Physics, QC1-999

Abstract

Aim/Introduction: Patient head motion poses a significant challenge when performing dynamic PET brain studies. In response, we developed a fast, robust, easily implementable and tracer-independent brain motion correction technique that facilitates accurate alignment of dynamic PET images.Materials and methods: Correction of head motion was performed using motion vectors derived by the application of Gaussian scale-space theory. A multiscale pyramid consisting of three different resolution levels (1/4x: coarse, 1/2x: medium, and 1x: fine) was applied to all image frames (37 frames, framing of 12 × 10s, 15 × 30s, 10 × 300s) of the dynamic PET sequence. Frame image alignment was initially performed at the coarse scale, which was subsequently used to initialise coregistration at the next finer scale, a process repeated until the finest possible scale, that is, the original resolution was reached. In addition, as tracer distribution changes during the dynamic frame sequence, a mutual information (MI) score was used to identify the starting frame for motion correction that is characterised by a sufficiently similar tracer distribution with the reference (last) frame. Validation of the approach was performed based on a simulated F18-fluoro-deoxy-glucose (FDG) dynamic sequence synthesised from the digital Zubal phantom. Inter-frame motion was added to each dynamic frame (except the reference frame). Total brain voxel displacement based on the added motion was constrained to 25 mm, which included both translation (0–15 mm in x, y and z) and rotation (0–0.3 rad for each Euler angle). Twenty repetitions were performed for each dataset with arbitrarily simulated motion, resulting in 20 synthetic datasets, each consisting of 36 dynamic frames (frame 37 was the reference frame). Assessment of motion correction accuracy across the dynamic sequence was performed based on the uncorrected/residual displacement remaining after the application of our algorithm. To investigate the clinical utility of the developed algorithm, three clinically cases that underwent list-mode PET imaging utilising different tracers ([18F]-fluoro-deoxy-glucose [18F]FDG [18F]-fluoroethyl-l-tyrosine [18F]FET [11C]-alpha-methyl-tryptophan [11C]AMT), each characterised by a different temporal tracer distribution were included in this study. Improvements in the Dice score coefficient (DSC) following frame alignment were evaluated as the correlation significance between the identified displacement for each frame of the clinical FDG, FET and AMT dynamic sequences.Results: Sub-millimetre accuracy (0.4 ± 0.2 mm) was achieved in the Zubal phantom for all frames after 5 min p. i., with early frames (30 s–180 s) displaying a higher residual displacement of ∼3 mm (3.2 ± 0.6 mm) due to differences in tracer distribution relative to the reference frame. The effect of these differences was also seen in MI scores; the MI plateau phase was reached at 35s p. i., 2.0 and 2.5 min p. i. At the coarse, medium and fine resolution levels, respectively. For the clinical images, a significant correlation between the identified (and corrected) displacement and the improvement in DSC score was seen in all dynamic studies (FET: R = 0.49, p < 0.001; FDG: R = 0.82, p < 0.001; AMT: R = 0.92, p < 0.001).Conclusion: The developed motion correction method is insensitive to any specific tracer distribution pattern, thus enabling improved correction of motion artefacts in a variety of clinical applications of extended PET imaging of the brain without the need for fiducial markers.

Published

2022

13. Elective transfemoral amputation and simultaneous implantation of a transcutaneous osseointegrated prosthesis stem as salvage treatment after knee joint arthrodesis with poor function: A case report

Author

Katharina Krause, Katherina Richter, Thomas Beyer, Horst Heinrich Aschoff, Dagmar-Christiane Fischer, and Thomas Mittlmeier

Subjects

ACL reconstruction, surgical complication, knee joint arthrodesis, transfemoral amputation, transcutaneous osseointegrated prosthesis system, gait analysis, Surgery, RD1-811

Abstract

BackgroundSurgical reconstruction of anterior cruciate ligament ruptures is a well-established procedure, and although it is for the vast majority of patients without severe complications, total knee joint arthroplasty, arthrodesis of the knee, and finally transfemoral amputation have to be considered in the worst-case scenario.The caseWe report a case of a patient with a 13-year history of recurrent failure after anterior cruciate ligament reconstruction. She claimed she had severely impaired mobility secondary to a knee joint arthrodesis via an Ilizarov circular frame 2 years ago and chronic immobilizing pain, making a permanent medication with opioids necessary. She was aware of the therapeutic options and asked for transfemoral amputation and concomitant supply with a transcutaneous osseointegrated prosthesis system (TOPS).ProceduresAfter careful evaluation and clinical work-up, the indication for transfemoral amputation and concomitant implantation of the prosthetic stem into the femoral cavity was secured. Six weeks after the creation of the stoma for coupling of the artificial limb and onset of physiotherapy, balance and gait training were scheduled. Full weight-bearing and walking without crutches were allowed 12 weeks after the index procedure. This sequence of events was paralleled by a series of pre-defined examinations, that is, questionnaires and mobility scores addressing the situation of transfemoral amputees, as well as standardized clinical gait analysis. The latter was performed before surgery and 6, 9, and 18 months after the index procedure.OutcomeAt the time of the index procedure, opioids could be tapered to zero, and the patient quickly regained her walking abilities during the rehabilitation period. Clinical gait analysis confirmed the restoration of bilateral symmetry by mutual approximation of kinematics and kinetics to a standard gait pattern.ConclusionThe outcome of our patient strengthens the therapeutic potential of a unilateral transfemoral amputation in combination with TOPS. Nevertheless, long-term follow-up is necessary to detect future complications of this approach.

Published

2022

14. Standard MRI-based attenuation correction for PET/MRI phantoms: a novel concept using MRI-visible polymer

Author

Ivo Rausch, Alejandra Valladares, Lalith Kumar Shiyam Sundar, Thomas Beyer, Marcus Hacker, Martin Meyerspeer, and Ewald Unger

Subjects

PET/MRI, Phantom attenuation correction, MR visible polymer, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Abstract Background PET/MRI phantom studies are challenged by the need of phantom-specific attenuation templates to account for attenuation properties of the phantom material. We present a PET/MRI phantom built from MRI-visible material for which attenuation correction (AC) can be performed using the standard MRI-based AC. Methods A water-fillable phantom was 3D-printed with a commercially available MRI-visible polymer. The phantom had a cylindrical shape and the fillable compartment consisted of a homogeneous region and a region containing solid rods of different diameters. The phantom was filled with a solution of water and [18F]FDG. A 30 min PET/MRI acquisition including the standard Dixon-based MR-AC method was performed. In addition, a CT scan of the phantom was acquired on a PET/CT system. From the Dixon in-phase, opposed-phase and fat images, a phantom-specific AC map (Phantom MR-AC) was produced by separating the phantom material from the water compartment using a thresholding-based method and assigning fixed attenuation coefficients to the individual compartments. The PET data was reconstructed using the Phantom MR-AC, the original Dixon MR-AC, and an MR-AC just containing the water compartment (NoWall-AC) to estimate the error of ignoring the phantom walls. CT-based AC was employed as the reference standard. Average %-differences in measured activity between the CT corrected PET and the PET corrected with the other AC methods were calculated. Results The phantom housing and the liquid compartment were both visible and distinguishable from each other in the Dixon images and allowed the segmentation of a phantom-specific MR-based AC. Compared to the CT-AC PET, average differences in measured activity in the whole water compartment in the phantom of −0.3%, 9.4%, and −24.1% were found for Dixon phantom MR-AC, MR-AC, and NoWall-AC based PET, respectively. Average differences near the phantom wall in the homogeneous region were −0.3%, 6.6%, and −34.3%, respectively. Around the rods, activity differed from the CT-AC PET by 0.7%, 8.9%, and −45.5%, respectively. Conclusion The presented phantom material is visible using standard MR sequences, and thus, supports the use of standard, phantom-independent MR measurements for MR-AC in PET/MRI phantom studies.

Published

2021

15. What scans we will read: imaging instrumentation trends in clinical oncology

Author

Thomas Beyer, Luc Bidaut, John Dickson, Marc Kachelriess, Fabian Kiessling, Rainer Leitgeb, Jingfei Ma, Lalith Kumar Shiyam Sundar, Benjamin Theek, and Osama Mawlawi

Subjects

Oncology imaging, Instrumentation, CT, MRI, Optical, SPECT, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Oncological diseases account for a significant portion of the burden on public healthcare systems with associated costs driven primarily by complex and long-lasting therapies. Through the visualization of patient-specific morphology and functional-molecular pathways, cancerous tissue can be detected and characterized non-invasively, so as to provide referring oncologists with essential information to support therapy management decisions. Following the onset of stand-alone anatomical and functional imaging, we witness a push towards integrating molecular image information through various methods, including anato-metabolic imaging (e.g., PET/CT), advanced MRI, optical or ultrasound imaging. This perspective paper highlights a number of key technological and methodological advances in imaging instrumentation related to anatomical, functional, molecular medicine and hybrid imaging, that is understood as the hardware-based combination of complementary anatomical and molecular imaging. These include novel detector technologies for ionizing radiation used in CT and nuclear medicine imaging, and novel system developments in MRI and optical as well as opto-acoustic imaging. We will also highlight new data processing methods for improved non-invasive tissue characterization. Following a general introduction to the role of imaging in oncology patient management we introduce imaging methods with well-defined clinical applications and potential for clinical translation. For each modality, we report first on the status quo and, then point to perceived technological and methodological advances in a subsequent status go section. Considering the breadth and dynamics of these developments, this perspective ends with a critical reflection on where the authors, with the majority of them being imaging experts with a background in physics and engineering, believe imaging methods will be in a few years from now. Overall, methodological and technological medical imaging advances are geared towards increased image contrast, the derivation of reproducible quantitative parameters, an increase in volume sensitivity and a reduction in overall examination time. To ensure full translation to the clinic, this progress in technologies and instrumentation is complemented by advances in relevant acquisition and image-processing protocols and improved data analysis. To this end, we should accept diagnostic images as “data”, and – through the wider adoption of advanced analysis, including machine learning approaches and a “big data” concept – move to the next stage of non-invasive tumour phenotyping. The scans we will be reading in 10 years from now will likely be composed of highly diverse multi-dimensional data from multiple sources, which mandate the use of advanced and interactive visualization and analysis platforms powered by Artificial Intelligence (AI) for real-time data handling by cross-specialty clinical experts with a domain knowledge that will need to go beyond that of plain imaging.

Published

2020

16. Implementation of a Spatially-Variant and Tissue-Dependent Positron Range Correction for PET/CT Imaging

Author

Hunor Kertész, Thomas Beyer, Vladimir Panin, Walter Jentzen, Jacobo Cal-Gonzalez, Alexander Berger, Laszlo Papp, Peter L. Kench, Deepak Bharkhada, Jorge Cabello, Maurizio Conti, and Ivo Rausch

Subjects

positron emission tomography, image reconstruction, positron range correction, PET quantification, PRC, Physiology, QP1-981

Abstract

AimTo develop and evaluate a new approach for spatially variant and tissue-dependent positron range (PR) correction (PRC) during the iterative PET image reconstruction.Materials and MethodsThe PR distributions of three radionuclides (18F, 68Ga, and 124I) were simulated using the GATE (GEANT4) framework in different material compositions (lung, water, and bone). For every radionuclide, the uniform PR kernel was created by mapping the simulated 3D PR point cloud to a 3D matrix with its size defined by the maximum PR in lung (18F) or water (68Ga and 124I) and the PET voxel size. The spatially variant kernels were composed from the uniform PR kernels by analyzing the material composition of the surrounding medium for each voxel before implementation as tissue-dependent, point-spread functions into the iterative image reconstruction. The proposed PRC method was evaluated using the NEMA image quality phantom (18F, 68Ga, and 124I); two unique PR phantoms were scanned and evaluated following OSEM reconstruction with and without PRC using different metrics, such as contrast recovery, contrast-to-noise ratio, image noise and the resolution evaluated in terms of full width at half maximum (FWHM).ResultsThe effect of PRC on 18F-imaging was negligible. In contrast, PRC improved image contrast for the 10-mm sphere of the NEMA image quality phantom filled with 68Ga and 124I by 33 and 24%, respectively. While the effect of PRC was less noticeable for the larger spheres, contrast recovery still improved by 5%. The spatial resolution was improved by 26% for 124I (FWHM of 4.9 vs. 3.7 mm).ConclusionFor high energy positron-emitting radionuclides, the proposed PRC method helped recover image contrast with reduced noise levels and with improved spatial resolution. As such, the PRC approach proposed here can help improve the quality of PET data in clinical practice and research.

Published

2022

17. State of affairs of hybrid imaging in Europe: two multi-national surveys from 2017

Author

Sergios Gatidis, Thomas Beyer, Minerva Becker, Katrine Riklund, Konstantin Nikolaou, Clemens Cyran, and Christina Pfannenberg

Subjects

Hybrid imaging, Survey, PET/CT, Training, Procedures, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Abstract Objectives To assess the current state of hybrid imaging in Europe with respect to operations, reading and reporting, as well as qualification and training. Methods The first survey (LOCAL) was sent to the heads of the departments of radiology and nuclear medicine in Europe in 2017, including 15 questions regarding the organisation of hybrid imaging operations, reporting strategies for PET/CT and the existence of relevant training programmes. The second survey (NATIONAL) consisted of 10 questions and was directed to the national ministries of health of 37 European countries addressing combined training options in radiology and nuclear medicine. Results In the LOCAL survey, 61 valid responses from 26 European countries were received. In almost half of the institutions, hybrid imaging was performed within a single department, mainly in nuclear medicine departments (31%). In half of the centres (51%), PET/CT reports were performed jointly, while in 20% of the centres, reporting was performed by nuclear medicine physicians. Radiologists were responsible for presenting hybrid imaging results in clinical boards in 34% of responding sites. Integrated hybrid imaging training was available in 41% sites. In the NATIONAL survey, responses from 34 countries were received and demonstrated a heterogeneous landscape of official training possibilities in radiology and nuclear medicine with limited opportunities for additional qualifications in hybrid imaging. Conclusions The results of these surveys demonstrate a notable heterogeneity in the current practice of hybrid imaging throughout Europe. This heterogeneity exists despite the general consensus that strong professional cooperation is required in order to ensure high clinical quality and to strengthen the clinical role of hybrid imaging.

Published

2019

18. Medical Physics and Imaging–A Timely Perspective

Author

Thomas Beyer, Dale L. Bailey, Udo J. Birk, Irene Buvat, Ciprian Catana, Zhen Cheng, Qiyin Fang, Federico Giove, Claudia Kuntner, Elmar Laistler, Francesco Moscato, Stephan G. Nekolla, Ivo Rausch, Itamar Ronen, Simo Saarakkala, Kris Thielemans, Wouter van Elmpt, and Ewald Moser

Subjects

medical physics and biomedical engineering, medical imaging, image data, artificial intelligence, imaging technology, Physics, QC1-999

Published

2021

19. PET/MRI in the Presurgical Evaluation of Patients with Epilepsy: A Concordance Analysis

Author

Katalin Borbély, Miklós Emri, István Kenessey, Márton Tóth, Júlia Singer, Péter Barsi, Zsolt Vajda, Endre Pál, Zoltán Tóth, Thomas Beyer, Tamás Dóczi, Gábor Bajzik, Dániel Fabó, József Janszky, Zsófia Jordán, Dániel Fajtai, Anna Kelemen, Vera Juhos, Max Wintermark, Ferenc Nagy, Mariann Moizs, Dávid Nagy, János Lückl, and Imre Repa

Subjects

epilepsy surgery, medically refractory focal epilepsy, presurgical evaluation, MRI-negative patients, discordant electroclinical and MRI data, metabolic PET, Biology (General), QH301-705.5

Abstract

The aim of our prospective study was to evaluate the clinical impact of hybrid [18F]-fluorodeoxyglucose positron emission tomography/magnetic resonance imaging ([18F]-FDG PET/MRI) on the decision workflow of epileptic patients with discordant electroclinical and MRI data. A novel mathematical model was introduced for a clinical concordance calculation supporting the classification of our patients by subgroups of clinical decisions. Fifty-nine epileptic patients with discordant clinical and diagnostic results or MRI negativity were included in this study. The diagnostic value of the PET/MRI was compared to other modalities of presurgical evaluation (e.g., electroclinical data, PET, and MRI). The results of the population-level statistical analysis of the introduced data fusion technique and concordance analysis demonstrated that this model could be the basis for the development of a more accurate clinical decision support parameter in the future. Therefore, making the establishment of “invasive” (operable and implantable) and “not eligible for any further invasive procedures” groups could be much more exact. Our results confirmed the relevance of PET/MRI with the diagnostic algorithm of presurgical evaluation. The introduction of a concordance analysis could be of high importance in clinical and surgical decision-making in the management of epileptic patients. Our study corroborated previous findings regarding the advantages of hybrid PET/MRI technology over MRI and electroclinical data.

Published

2022

20. Feasibility of dose reduction for [18F]FDG-PET/MR imaging of patients with non-lesional epilepsy

Author

Hunor Kertész, Tatjana Traub-Weidinger, Jacobo Cal-Gonzalez, Ivo Rausch, Otto Muzik, Lalith Kumar Shyiam Sundar, and Thomas Beyer

Subjects

Radiology, Nuclear Medicine and imaging, General Medicine

Abstract

The aim of the study was to evaluate the effect of reduced injected [18F]FDG activity levels on the quantitative and diagnostic accuracy of PET images of patients with non-lesional epilepsy (NLE).Nine healthy volunteers and nine patients with NLE underwent 60-min dynamic list-mode (LM) scans on a fully-integrated PET/MRI system. Injected FDG activity levels were reduced virtually by randomly removing counts from the last 10-min of the LM data, so as to simulate the following activity levels: 50 %, 35 %, 20 %, and 10 % of the original activity. Four image reconstructions were evaluated: standard OSEM, OSEM with resolution recovery (PSF), the A-MAP, and the Asymmetrical Bowsher (AsymBowsher) algorithms. For the A-MAP algorithms, two weights were selected (low and high). Image contrast and noise levels were evaluated for all subjects while the lesion-to-background ratio (L/B) was only evaluated for patients. Patient images were scored by a Nuclear Medicine physician on a 5-point scale to assess clinical impression associated with the various reconstruction algorithms.The image contrast and L/B ratio characterizing all four reconstruction algorithms were similar, except for reconstructions based on only 10 % of total counts. Based on clinical impression, images with diagnostic quality can be achieved with as low as 35 % of the standard injected activity. The selection of algorithms utilizing an anatomical prior did not provide a significant advantage for clinical readings, despite a small improvement in L/B (In patients with NLE who are undergoing [18F]FDG-PET/MR imaging, the injected [18F]FDG activity can be reduced to 35 % of the original dose levels without compromising.

Published

2023

21. Fully Integrated PET/MR Imaging for the Assessment of the Relationship Between Functional Connectivity and Glucose Metabolic Rate

Author

Lalith Kumar Shiyam Sundar, Shahira Baajour, Thomas Beyer, Rupert Lanzenberger, Tatjana Traub-Weidinger, Ivo Rausch, Ekaterina Pataraia, Andreas Hahn, Lucas Rischka, Marius Hienert, Eva-Maria Klebermass, and Otto Muzik

Subjects

resting-state fMRI, Cerebral metabolic rate of glucose, integrated PET/MRI, glucose metabolic rate variability, standardization of psychological state, real-time fMRI, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

In the past, determination of absolute values of cerebral metabolic rate of glucose (CMRGlc) in clinical routine was rarely carried out due to the invasive nature of arterial sampling. With the advent of combined PET/MR imaging technology, CMRGlc values can be obtained non-invasively, thereby providing the opportunity to take advantage of fully quantitative data in clinical routine. However, CMRGlc values display high physiological variability, presumably due to fluctuations in the intrinsic activity of the brain at rest. To reduce CMRGlc variability associated with these fluctuations, the objective of this study was to determine whether functional connectivity measures derived from resting-state fMRI (rs-fMRI) could be used to correct for these fluctuations in intrinsic brain activity. Methods: We studied 10 healthy volunteers who underwent a test-retest dynamic [18F]FDG-PET study using a fully integrated PET/MR system (Siemens Biograph mMR). To validate the non-invasive derivation of an image-derived input function based on combined analysis of PET and MR data, arterial blood samples were obtained. Using the arterial input function (AIF), parametric images representing CMRGlc were determined using the Patlak graphical approach. Both directed functional connectivity (dFC) and undirected functional connectivity (uFC) were determined between nodes in six major networks (Default mode network, Salience, L/R Executive, Attention, and Sensory-motor network) using either a bivariate-correlation (R coefficient) or a Multi-Variate AutoRegressive (MVAR) model. In addition, the performance of a regional connectivity measure, the fractional amplitude of low frequency fluctuations (fALFF), was also investigated. Results: The average intrasubject variability for CMRGlc values between test and retest was determined as (14 ±8%) with an average inter-subject variability of 25% at test and 15% at retest. The average CMRGlc value (umol/100 g/min) across all networks was 39 ±10 at test and increased slightly to 43 ±6 at retest. The R, MVAR and fALFF coefficients showed relatively large test-retest variability in comparison to the inter-subjects variability, resulting in poor reliability (intraclass correlation in the range of 0.11–0.65). More importantly, no significant relationship was found between the R coefficients (for uFC), MVAR coefficients (for dFC) or fALFF and corresponding CMRGlc values for any of the six major networks. Discussion: Measurement of functional connectivity within established brain networks did not provide a means to decrease the inter- or intrasubject variability of CMRGlc values. As such, our results indicate that connectivity measured derived from rs-fMRI acquired contemporaneously with PET imaging are not suited for correction of CMRGlc variability associated with intrinsic fluctuations of resting-state brain activity. Thus, given the observed substantial inter- and intrasubject variability of CMRGlc values, the relevance of absolute quantification for clinical routine is presently uncertain.

Published

2020

22. Utility of Absolute Quantification in Non-lesional Extratemporal Lobe Epilepsy Using FDG PET/MR Imaging

Author

Tatjana Traub-Weidinger, Otto Muzik, Lalith Kumar Shiyam Sundar, Susanne Aull-Watschinger, Thomas Beyer, Marcus Hacker, Andreas Hahn, Gregor Kasprian, Eva-Maria Klebermass, Rupert Lanzenberger, Markus Mitterhauser, Magdalena Pilz, Ivo Rausch, Lucas Rischka, Wolfgang Wadsak, and Ekaterina Pataraia

Subjects

PET/MRI, extratemporal lobe epilepsy, absolute quantification, metabolic rate of glucose, brain imaging, Neurology. Diseases of the nervous system, RC346-429

Abstract

The purpose of this study was to establish a non-invasive clinical PET/MR protocol using [18F]-labeled deoxyglucose (FDG) that provides physicians with regional metabolic rate of glucose (MRGlc) values and to clarify the contribution of absolute quantification to clinical management of patients with non-lesional extratemporal lobe epilepsy (ETLE). The study included a group of 15 patients with non-lesional ETLE who underwent a dynamic FDG PET study using a fully-integrated PET/MRI system (Siemens Biograph). FDG tracer uptake images were converted to MRGlc (μmol/100 g/min) maps using an image derived input function that was extracted based on the combined analysis of PET and MRI data. In addition, the same protocol was applied to a group of healthy controls, yielding a normative database. Abnormality maps for ETLE patients were created with respect to the normative database, defining significant hypo- or hyper-metabolic regions that exceeded ±2 SD of normal regional mean MRGlc values. Abnormality maps derived from MRGlc images of ETLE patients contributed to the localization of hypo-metabolic areas against visual readings in 53% and increased the confidence in the original clinical readings in 33% of all cases. Moreover, quantification allowed identification of hyper-metabolic areas that are associated with frequently spiking cortex, rarely acknowledged in clinical readings. Overall, besides providing some confirmatory information to visual readings, quantitative PET imaging demonstrated only a moderate impact on clinical management of patients with complex pathology that leads to epileptic seizures, failing to provide new decisive information that would have changed classification of patients from being rejected to being considered for surgical intervention.

Published

2020

23. De n Sozialstaat neu wagen

Author

Thomas Beyer

Published

2022

24. A 2022 International Survey on the Status of Prostate Cancer Theranostics

Author

Thomas, Beyer, Johannes, Czernin, Lutz, Freudenberg, Frederik, Giesel, Marcus, Hacker, Rodney J, Hicks, and Bernd J, Krause

Subjects

Radiology, Nuclear Medicine and imaging

Abstract

Growing interest in PSMA imaging using [

Published

2022

25. Attenuation Correction Approaches for Serotonin Transporter Quantification With PET/MRI

Author

Lucas Rischka, Gregor Gryglewski, Neydher Berroterán-Infante, Ivo Rausch, Gregory Miles James, Manfred Klöbl, Helen Sigurdardottir, Markus Hartenbach, Andreas Hahn, Wolfgang Wadsak, Markus Mitterhauser, Thomas Beyer, Siegfried Kasper, Daniela Prayer, Marcus Hacker, and Rupert Lanzenberger

Subjects

attenuation correction, PET/MRI, serotonin transporter, [11C]DASB, occupancy, absolute quantification, Physiology, QP1-981

Abstract

BackgroundSeveral MR-based attenuation correction (AC) approaches were developed to conquer the challenging AC in hybrid PET/MR imaging. These AC methods are commonly evaluated on standardized uptake values or tissue concentration. However, in neurotransmitter system studies absolute quantification is more favorable due to its accuracy. Therefore, our aim was to investigate the accuracy of segmentation- and atlas-based MR AC approaches on serotonin transporter (SERT) distribution volumes and occupancy after a drug challenge.Methods18 healthy subjects (7 male) underwent two [11C]DASB PET/MRI measurements in a double-blinded, placebo controlled, cross-over design. After 70 min the selective serotonin reuptake inhibitor (SSRI) citalopram or a placebo was infused. The parameters total and specific volume of distribution (VT, VS = BPP) and occupancy were quantified. All subjects underwent a low-dose CT scan as reference AC method. Besides the standard AC approaches DIXON and UTE, a T1-weighted structural image was recorded to estimate a pseudo-CT based on an MR/CT database (pseudoCT). Another evaluated AC approach superimposed a bone model on AC DIXON. Lastly, an approach optimizing the segmentation of UTE images was analyzed (RESOLUTE). PET emission data were reconstructed with all 6 AC methods. The accuracy of the AC approaches was evaluated on a region of interest-basis for the parameters VT, BPP, and occupancy with respect to the results of AC CT.ResultsVariations for VT and BPP were found with all AC methods with bias ranging from −15 to 17%. The smallest relative errors for all regions were found with AC pseudoCT (

Published

2019

26. Clinically Valuable Quality Control for PET/MRI Systems: Consensus Recommendation From the HYBRID Consortium

Author

Alejandra Valladares, Sahar Ahangari, Thomas Beyer, Ronald Boellaard, Zacharias Chalampalakis, Claude Comtat, Laura DalToso, Adam E. Hansen, Michel Koole, Jane Mackewn, Paul Marsden, Johan Nuyts, Francesco Padormo, Ronald Peeters, Sebastian Poth, Esteban Solari, and Ivo Rausch

Subjects

hybrid imaging, consensus, recommendations, quality control, PET/MRI, Physics, QC1-999

Abstract

Quality control (QC) of medical imaging devices is essential to ensure their proper function and to gain accurate and quantitative results. Therefore, several international bodies have published QC guidelines and recommendations for a wide range of imaging modalities to ensure adequate performance of the systems. Hybrid imaging systems such as positron emission tomography/computed tomography (PET/CT) or PET/magnetic resonance imaging (PET/MRI), in particular, present additional challenges caused by differences between the combined modalities. However, despite the increasing use of this hybrid imaging modality in recent years, there are no dedicated QC recommendations for PET/MRI. Therefore, this work aims at collecting information on QC procedures across a European PET/MRI network, presenting quality assurance procedures implemented by PET/MRI vendors and achieving a consensus on PET/MRI QC procedures across imaging centers. Users of PET/MRI systems at partner sites involved in the HYBRID consortium were surveyed about local frequencies of QC procedures for PET/MRI. Although all sites indicated that they perform vendor-specific daily QC procedures, significant variations across the centers were observed for other QC tests and testing frequencies. Likewise, variations in available recommendations and guidelines and the QC procedures implemented by vendors were found. Based on the available information and our clinical expertise within this consortium, we were able to propose a minimum set of PET/MRI QC recommendations including the daily QC, cross-calibration tests, and an image quality (IQ) assessment for PET and coil checks and MR image quality tests for MRI. Together with regular checks of the PET–MRI alignment, proper PET/MRI performance can be ensured.

Published

2019

27. Der lumbosakrale Übergangswirbel als mögliche Ursache für unspezifische Lumbalgien

Author

Hanna Wäscher, Thomas Beyer, and Marc-André Weber

Subjects

Radiology, Nuclear Medicine and imaging

Published

2023

28. Development of anthropomorphic mathematical phantoms for simulations of clinical cases in diagnostic nuclear medicine

Author

Natalya Denisova, Marina Ondar, Hunor Kertesz, and Thomas Beyer

Subjects

Biomedical Engineering, Computational Mechanics, Radiology, Nuclear Medicine and imaging, Computer Science Applications

Published

2022

29. Technical note: A PET/MR coil with an integrated, orbiting 511 keV transmission source for PET/MR imaging validated in an animal study

Author

Andreas Renner, Ivo Rausch, Jacobo Cal Gonzalez, Elmar Laistler, Ewald Moser, Thies Jochimsen, Tatjana Sattler, Osama Sabri, Thomas Beyer, Michael Figl, Wolfgang Birkfellner, and Bernhard Sattler

Subjects

Artificial Intelligence, Phantoms, Imaging, Swine, Positron-Emission Tomography, Image Processing, Computer-Assisted, Animals, General Medicine, Magnetic Resonance Imaging, Multimodal Imaging

Abstract

MR-based methods for attenuation correction (AC) in PET/MRI either neglect attenuation of bone, or use MR-signal derived information about bone, which leads to a bias in quantification of tracer uptake in PET. In a previous study, we presented a PET/MRI specific MR coil with an integrated transmission source (TX) system allowing for direct measurement of attenuation. In phantom measurements, this system successfully reproduced the linear attenuation coefficient of water.The purpose of this study is to validate the TX system in a clinical setting using animals and to show its applicability compared to standard clinical methods.As test subject, a 15-kg piglet was injected with 53 MBq of 18F-NaF. The μ-map obtained with the TX system and the reconstructed activity distribution were compared to four established AC methods: a Dixon sequence, an ultra-short echo time (UTE) sequence, a CT scan, and a 511 keV transmission scan using a Siemens ECAT EXACT HR+ as the reference. The PET/MRI measurements were performed on a Siemens Biograph mMR to obtain the μ-map using the TX system as well as the Dixon and UTE sequence directly followed by the CT and ECAT measurements.The reconstructed activity distribution using the TX system for AC showed similar results compared to the reference (5% difference in hot regions) and outperformed the MR-based methods as implemented in the PET/MRI system (10% difference in hot regions). However, the additional hardware of the TX system adds complexity to the acquisition process.Our porcine study demonstrates the feasibility of post-injection transmission scans using the developed TX system in a clinical setting. This makes it a useful tool for PET/MRI in cases where transmission information is needed for AC. Potential applications are studies using larger animals where state-of-the-art atlas-based or artificial intelligence AC methods are not available.

Published

2022

30. Data from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Therapeutic monoclonal antibodies against the epidermal growth factor receptor (EGFR) have advanced the treatment of colon and head and neck cancer, and show great promise for the development of treatments for other solid cancers. Antibodies against EGFR have been shown to act via inhibition of receptor signaling and induction of antibody-dependent cellular cytoxicity. However, complement-dependent cytotoxicity, which is considered one of the most powerful cell killing mechanisms of antibodies, seems inactive for such antibodies. Here, we show a remarkable synergy for EGFR antibodies. Combinations of antibodies against EGFR were identified, which resulted in potent complement activation via the classic pathway and effective lysis of tumor cells. Studies on a large panel of antibodies indicated that the observed synergy is a general mechanism, which can be activated by combining human IgG1 antibodies recognizing different, nonoverlapping epitopes. Our findings show an unexpected quality of therapeutic EGFR antibodies, which may be exploited to develop novel and more effective treatments for solid cancers. [Cancer Res 2008;68(13):4998–5003]

Published

2023

31. Supplementary Table 1 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Table 1 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

32. Supplementary Figure 4 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Figure 4 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

33. Supplementary Figure 1 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Figure 1 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

34. Supplementary Figure 5 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Figure 5 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

35. Supplementary Legends of Tables 1-2, Figures 1-5 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Legends of Tables 1-2, Figures 1-5 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

36. Supplementary Figure 3 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Figure 3 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

37. Supplementary Table 2 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Table 2 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

38. Supplementary Figure 2 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Author

Thomas Valerius, Jan G.J. van de Winkel, Paul W.H.I. Parren, Wim K. Bleeker, Jeroen J. Lammerts van Bueren, Tanja Schneider-Merck, Thomas Beyer, Matthias Peipp, Sven Berger, Wencke Weisner, and Michael Dechant

Abstract

Supplementary Figure 2 from Complement-Dependent Tumor Cell Lysis Triggered by Combinations of Epidermal Growth Factor Receptor Antibodies

Published

2023

39. Corrigendum: Hybrid Imaging: Instrumentation and Data Processing

Author

Jacobo Cal-Gonzalez, Ivo Rausch, Lalith K. Shiyam Sundar, Martin L. Lassen, Otto Muzik, Ewald Moser, Laszlo Papp, and Thomas Beyer

Subjects

hybrid imaging, combined imaging, instrumentation, nuclear medicine, data processing, data corrections, Physics, QC1-999

Published

2018

40. Personalizing Medicine Through Hybrid Imaging and Medical Big Data Analysis

Author

Laszlo Papp, Clemens P. Spielvogel, Ivo Rausch, Marcus Hacker, and Thomas Beyer

Subjects

hybrid imaging, medical big data, machine learning, radiomics, holomics, personalized medicine, Physics, QC1-999

Abstract

Medical imaging has evolved from a pure visualization tool to representing a primary source of analytic approaches toward in vivo disease characterization. Hybrid imaging is an integral part of this approach, as it provides complementary visual and quantitative information in the form of morphological and functional insights into the living body. As such, non-invasive imaging modalities no longer provide images only, but data, as stated recently by pioneers in the field. Today, such information, together with other, non-imaging medical data creates highly heterogeneous data sets that underpin the concept of medical big data. While the exponential growth of medical big data challenges their processing, they inherently contain information that benefits a patient-centric personalized healthcare. Novel machine learning approaches combined with high-performance distributed cloud computing technologies help explore medical big data. Such exploration and subsequent generation of knowledge require a profound understanding of the technical challenges. These challenges increase in complexity when employing hybrid, aka dual- or even multi-modality image data as input to big data repositories. This paper provides a general insight into medical big data analysis in light of the use of hybrid imaging information. First, hybrid imaging is introduced (see further contributions to this special Research Topic), also in the context of medical big data, then the technological background of machine learning as well as state-of-the-art distributed cloud computing technologies are presented, followed by the discussion of data preservation and data sharing trends. Joint data exploration endeavors in the context of in vivo radiomics and hybrid imaging will be presented. Standardization challenges of imaging protocol, delineation, feature engineering, and machine learning evaluation will be detailed. Last, the paper will provide an outlook into the future role of hybrid imaging in view of personalized medicine, whereby a focus will be given to the derivation of prediction models as part of clinical decision support systems, to which machine learning approaches and hybrid imaging can be anchored.

Published

2018

41. Hybrid Imaging: Instrumentation and Data Processing

Author

Jacobo Cal-Gonzalez, Ivo Rausch, Lalith K. Shiyam Sundar, Martin L. Lassen, Otto Muzik, Ewald Moser, Laszlo Papp, and Thomas Beyer

Subjects

hybrid imaging, combined imaging, instrumentation, nuclear medicine, data processing, data corrections, Physics, QC1-999

Abstract

State-of-the-art patient management frequently requires the use of non-invasive imaging methods to assess the anatomy, function or molecular-biological conditions of patients or study subjects. Such imaging methods can be singular, providing either anatomical or molecular information, or they can be combined, thus, providing “anato-metabolic” information. Hybrid imaging denotes image acquisitions on systems that physically combine complementary imaging modalities for an improved diagnostic accuracy and confidence as well as for increased patient comfort. The physical combination of formerly independent imaging modalities was driven by leading innovators in the field of clinical research and benefited from technological advances that permitted the operation of PET and MR in close physical proximity, for example. This review covers milestones of the development of various hybrid imaging systems for use in clinical practice and small-animal research. Special attention is given to technological advances that helped the adoption of hybrid imaging, as well as to introducing methodological concepts that benefit from the availability of complementary anatomical and biological information, such as new types of image reconstruction and data correction schemes. The ultimate goal of hybrid imaging is to provide useful, complementary and quantitative information during patient work-up. Hybrid imaging also opens the door to multi-parametric assessment of diseases, which will help us better understand the causes of various diseases that currently contribute to a large fraction of healthcare costs.

Published

2018

42. Fully Automated, Semantic Segmentation of Whole-Body (18)F-FDG PET/CT Images Based on Data-Centric Artificial Intelligence

Author

Lalith Kumar Shiyam Sundar, Josef Yu, Otto Muzik, Oana C. Kulterer, Barbara Fueger, Daria Kifjak, Thomas Nakuz, Hyung Min Shin, Annika Katharina Sima, Daniela Kitzmantl, Ramsey D. Badawi, Lorenzo Nardo, Simon R. Cherry, Benjamin A. Spencer, Marcus Hacker, and Thomas Beyer

Subjects

Male, Human Body, multiorgan segmentation, Image Processing, Clinical Sciences, Neurosciences, Bioengineering, Basic Science Investigation, Semantics, Nuclear Medicine & Medical Imaging, Computer-Assisted, Fluorodeoxyglucose F18, Artificial Intelligence, Positron Emission Tomography Computed Tomography, Image Processing, Computer-Assisted, Biomedical Imaging, Humans, Radiology, Nuclear Medicine and imaging, Female, automated segmentation, systems medicine, total-body PET, artificial neural networks

Abstract

We introduce multiple-organ objective segmentation (MOOSE) software that generates subject-specific, multiorgan segmentation using data-centric artificial intelligence principles to facilitate high-throughput systemic investigations of the human body via whole-body PET imaging. Methods: Image data from 2 PET/CT systems were used in training MOOSE. For noncerebral structures, 50 whole-body CT images were used, 30 of which were acquired from healthy controls (14 men and 16 women), and 20 datasets were acquired from oncology patients (14 men and 6 women). Noncerebral tissues consisted of 13 abdominal organs, 20 bone segments, subcutaneous fat, visceral fat, psoas muscle, and skeletal muscle. An expert panel manually segmented all noncerebral structures except for subcutaneous fat, visceral fat, and skeletal muscle, which were semiautomatically segmented using thresholding. A majority-voting algorithm was used to generate a reference-standard segmentation. From the 50 CT datasets, 40 were used for training and 10 for testing. For cerebral structures, 34 (18)F-FDG PET/MRI brain image volumes were used from 10 healthy controls (5 men and 5 women imaged twice) and 14 nonlesional epilepsy patients (7 men and 7 women). Only (18)F-FDG PET images were considered for training: 24 and 10 of 34 volumes were used for training and testing, respectively. The Dice score coefficient (DSC) was used as the primary metric, and the average symmetric surface distance as a secondary metric, to evaluate the automated segmentation performance. Results: An excellent overlap between the reference labels and MOOSE-derived organ segmentations was observed: 92% of noncerebral tissues showed DSCs of more than 0.90, whereas a few organs exhibited lower DSCs (e.g., adrenal glands [0.72], pancreas [0.85], and bladder [0.86]). The median DSCs of brain subregions derived from PET images were lower. Only 29% of the brain segments had a median DSC of more than 0.90, whereas segmentation of 60% of regions yielded a median DSC of 0.80–0.89. The results of the average symmetric surface distance analysis demonstrated that the average distance between the reference standard and the automatically segmented tissue surfaces (organs, bones, and brain regions) lies within the size of image voxels (2 mm). Conclusion: The proposed segmentation pipeline allows automatic segmentation of 120 unique tissues from whole-body (18)F-FDG PET/CT images with high accuracy.

Published

2022

43. Application of a Deep Learning Approach to Analyze Large-Scale MRI Data of the Spine

Author

Felix Streckenbach, Gundram Leifert, Thomas Beyer, Anita Mesanovic, Hanna Wäscher, Daniel Cantré, Sönke Langner, Marc-André Weber, and Tobias Lindner

Subjects

Health Information Management, Leadership and Management, Health Policy, German National Cohort, MRI, spine, artificial intelligence, large-scale data, convolutional neural network, normative data, Health Informatics

Abstract

With its standardized MRI datasets of the entire spine, the German National Cohort (GNC) has the potential to deliver standardized biometric reference values for intervertebral discs (VD), vertebral bodies (VB) and spinal canal (SC). To handle such large-scale big data, artificial intelligence (AI) tools are needed. In this manuscript, we will present an AI software tool to analyze spine MRI and generate normative standard values. 330 representative GNC MRI datasets were randomly selected in equal distribution regarding parameters of age, sex and height. By using a 3D U-Net, an AI algorithm was trained, validated and tested. Finally, the machine learning algorithm explored the full dataset (n = 10,215). VB, VD and SC were successfully segmented and analyzed by using an AI-based algorithm. A software tool was developed to analyze spine-MRI and provide age, sex, and height-matched comparative biometric data. Using an AI algorithm, the reliable segmentation of MRI datasets of the entire spine from the GNC was possible and achieved an excellent agreement with manually segmented datasets. With the analysis of the total GNC MRI dataset with almost 30,000 subjects, it will be possible to generate real normative standard values in the future.

Published

2022

44. Whole-body PET imaging: A catalyst for whole-person research?

Author

Lalith Kumar Shiyam Sundar, Marcus Hacker, and Thomas Beyer

Subjects

Radiology, Nuclear Medicine and imaging

Abstract

The introduction of total-body PET has encouraged the research community to investigate multi-organ interactions - the organ connectome for understanding human physiology and pathology. This article highlights the potential of using whole-body and total-body PET image information to conduct multi-organ connectome analysis for disease phenotyping. Novel data analytics schemes help realise such studies. Novel study protocols and paradigms, as well as translational research pipelines, will be required to support causal interpretations of inter-organ relationships. Ultimately, the widened adoption of multi-organ connectome studies via PET anticipates new, cross-speciality interactions among scientists, clinicians, and patients. It is our choice to engage in it now.

Published

2022

45. Combined PET/MR imaging in neurology: MR-based attenuation correction implies a strong spatial bias when ignoring bone.

Author

Flemming Littrup Andersen, Claes Nøhr Ladefoged, Thomas Beyer, Sune Høgild Keller, Adam Espe Hansen, Liselotte Højgaard, Andreas Kjær, Ian Law, and Søren Holm

Published

2014

46. Design, Implementation, and Evaluation of a Head and Neck MRI RF Array Integrated with a 511 keV Transmission Source for Attenuation Correction in PET/MR.

Author

Lucia I. Navarro de Lara, Roberta Frass-Kriegl, Andreas Renner, Jürgen Sieg, Michael Pichler, Thomas Bogner, Ewald Moser, Thomas Beyer, Wolfgang Birkfellner, Michael Figl, and Elmar Laistler

Published

2019

47. Versorgungsbedarf in einer psychosomatischen Spezialambulanz für Geflüchtete an einem Universitätsklinikum

Author

Yesim Erim, Eva Morawa, Katrin Graemer, and Thomas Beyer

Subjects

Gynecology, medicine.medical_specialty, Political science, medicine, Neurology (clinical), Family Practice

Abstract

ZUSAMMENFASSUNG Hintergrund Nach der Fluchtbewegung von 2015 wurde vielfach festgestellt, dass die psychotherapeutischen Angebote nicht für den anzunehmenden Bedarf ausreichen können. Fragestellung Ziel dieser Studie war es, anhand eines Fragebogens, die in einer Spezialambulanz an einer Regelversorgungseinrichtung durchgeführten Behandlungen zu untersuchen und deren spezifischen Aspekte festzustellen. Material und Methoden Ablauf und Inhalte der psychotherapeutischen Behandlungen mit Geflüchteten wurden im Forscherteam diskutiert. Auf dieser Grundlage wurden die zu erwartenden Rahmenbedingungen und Interventionen in einem Fragebogen zusammengefasst. Dieser diente der retrospektiven Untersuchung der Behandlungen. Die Auswertung der Daten erfolgte rein deskriptiv. Ergebnisse 60 Behandlungen von Geflüchteten konnten ausgewertet werden. Die Inhalte der untersuchten Behandlungen können in Interventionen, besondere Rahmenbedingungen, ärztlich-psychotherapeutische Maßnahmen und Beachtung kultureller sowie religiöser Aspekte gegliedert werden. Unsere Ergebnisse geben einen differenzierten Überblick über die Inhalte der Behandlungen bei einer psychisch hochbelasteten Patientengruppe. Das Festlegen der Sitzordnung in einem gedolmetschten Gespräch erfolgte bei 56, Psychoedukation bei 43, Affekt- und Stressregulation bei 32, die Thematisierung religiöser Aspekte bei 28 und die Behandlung mit Psychopharmaka bei 24 Geflüchteten. Diskussion Unsere Ergebnisse zeigen, dass in den untersuchten Behandlungen stabilisierende Interventionen erfolgten, aber auch interkulturelle und religiöse Aspekte thematisiert wurden. Das Herstellen einer stabilen Beziehung zu den Geflüchteten wird vor allem beeinflusst durch interkulturelle sowie religiöse Aspekte und die Besonderheiten der Anwesenheit eines Dolmetschers und des Übersetzungsprozesses.

Published

2021

48. Reproducibility of Quantitative Brain Imaging Using a PET-Only and a Combined PET/MR System

Author

Martin L. Lassen, Otto Muzik, Thomas Beyer, Marcus Hacker, Claes Nøhr Ladefoged, Jacobo Cal-González, Wolfgang Wadsak, Ivo Rausch, Oliver Langer, and Martin Bauer

Subjects

kinetic modeling, PET/MR, PET, attenuation correction, inter-scan variability, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The purpose of this study was to test the feasibility of migrating a quantitative brain imaging protocol from a positron emission tomography (PET)-only system to an integrated PET/MR system. Potential differences in both absolute radiotracer concentration as well as in the derived kinetic parameters as a function of PET system choice have been investigated. Five healthy volunteers underwent dynamic (R)-[11C]verapamil imaging on the same day using a GE-Advance (PET-only) and a Siemens Biograph mMR system (PET/MR). PET-emission data were reconstructed using a transmission-based attenuation correction (AC) map (PET-only), whereas a standard MR-DIXON as well as a low-dose CT AC map was applied to PET/MR emission data. Kinetic modeling based on arterial blood sampling was performed using a 1-tissue-2-rate constant compartment model, yielding kinetic parameters (K1 and k2) and distribution volume (VT). Differences for parametric values obtained in the PET-only and the PET/MR systems were analyzed using a 2-way Analysis of Variance (ANOVA). Comparison of DIXON-based AC (PET/MR) with emission data derived from the PET-only system revealed average inter-system differences of −33 ± 14% (p < 0.05) for the K1 parameter and −19 ± 9% (p < 0.05) for k2. Using a CT-based AC for PET/MR resulted in slightly lower systematic differences of −16 ± 18% for K1 and −9 ± 10% for k2. The average differences in VT were −18 ± 10% (p < 0.05) for DIXON- and −8 ± 13% for CT-based AC. Significant systematic differences were observed for kinetic parameters derived from emission data obtained from PET/MR and PET-only imaging due to different standard AC methods employed. Therefore, a transfer of imaging protocols from PET-only to PET/MR systems is not straightforward without application of proper correction methods.Clinical Trial Registration:www.clinicaltrialsregister.eu, identifier 2013-001724-19

Published

2017

49. Radiogenomic markers enable risk stratification and inference of mutational pathway states in head and neck cancer

Author

Clemens P. Spielvogel, Stefan Stoiber, Laszlo Papp, Denis Krajnc, Marko Grahovac, Elisabeth Gurnhofer, Karolina Trachtova, Vojtech Bystry, Asha Leisser, Bernhard Jank, Julia Schnoell, Lorenz Kadletz, Gregor Heiduschka, Thomas Beyer, Marcus Hacker, Lukas Kenner, and Alexander R. Haug

Subjects

Radiology, Nuclear Medicine and imaging, General Medicine

Abstract

Purpose Head and neck squamous cell carcinomas (HNSCCs) are a molecularly, histologically, and clinically heterogeneous set of tumors originating from the mucosal epithelium of the oral cavity, pharynx, and larynx. This heterogeneous nature of HNSCC is one of the main contributing factors to the lack of prognostic markers for personalized treatment. The aim of this study was to develop and identify multi-omics markers capable of improved risk stratification in this highly heterogeneous patient population. Methods In this retrospective study, we approached this issue by establishing radiogenomics markers to identify high-risk individuals in a cohort of 127 HNSCC patients. Hybrid in vivo imaging and whole-exome sequencing were employed to identify quantitative imaging markers as well as genetic markers on pathway-level prognostic in HNSCC. We investigated the deductibility of the prognostic genetic markers using anatomical and metabolic imaging using positron emission tomography combined with computed tomography. Moreover, we used statistical and machine learning modeling to investigate whether a multi-omics approach can be used to derive prognostic markers for HNSCC. Results Radiogenomic analysis revealed a significant influence of genetic pathway alterations on imaging markers. A highly prognostic radiogenomic marker based on cellular senescence was identified. Furthermore, the radiogenomic biomarkers designed in this study vastly outperformed the prognostic value of markers derived from genetics and imaging alone. Conclusion Using the identified markers, a clinically meaningful stratification of patients is possible, guiding the identification of high-risk patients and potentially aiding in the development of effective targeted therapies. Graphical abstract

Published

2022

50. Supervised machine learning enables non-invasive lesion characterization in primary prostate cancer with [68Ga]Ga-PSMA-11 PET/MRI

Author

Marko Grahovac, Bernhard Grubmüller, Laszlo Papp, Clemens P. Spielvogel, Wolfgang Wadsak, Boglarka Ecsedi, S.F. Shariat, Markus Hartenbach, Thomas H. Helbich, Alexander Haug, Martin Susani, Markus Mitterhauser, Martina Hamboeck, Sabrina Hartenbach, D Mohamad, Reza Agha Mohammadi Sareshgi, Peter R. Mazal, Gero Kramer, Lukas Kenner, Thomas Beyer, M Hacker, Pascal A. T. Baltzer, Ivo Rausch, and Denis Krajnc

Subjects

Biochemical recurrence, Male, medicine.medical_treatment, Standardized uptake value, Gallium Radioisotopes, Machine learning, computer.software_genre, Prostate cancer, Positron Emission Tomography Computed Tomography, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Prospective Studies, Stage (cooking), Edetic Acid, Radiomics, Receiver operating characteristic, medicine.diagnostic_test, business.industry, Prostatectomy, Biochemical recurrence prediction, Prostatic Neoplasms, Magnetic resonance imaging, General Medicine, medicine.disease, Magnetic Resonance Imaging, PET/MRI, Positron emission tomography, Positron-Emission Tomography, Original Article, Artificial intelligence, Supervised Machine Learning, Overall patient risk prediction, business, computer, Lesion risk prediction

Abstract

Purpose Risk classification of primary prostate cancer in clinical routine is mainly based on prostate-specific antigen (PSA) levels, Gleason scores from biopsy samples, and tumor-nodes-metastasis (TNM) staging. This study aimed to investigate the diagnostic performance of positron emission tomography/magnetic resonance imaging (PET/MRI) in vivo models for predicting low-vs-high lesion risk (LH) as well as biochemical recurrence (BCR) and overall patient risk (OPR) with machine learning. Methods Fifty-two patients who underwent multi-parametric dual-tracer [18F]FMC and [68Ga]Ga-PSMA-11 PET/MRI as well as radical prostatectomy between 2014 and 2015 were included as part of a single-center pilot to a randomized prospective trial (NCT02659527). Radiomics in combination with ensemble machine learning was applied including the [68Ga]Ga-PSMA-11 PET, the apparent diffusion coefficient, and the transverse relaxation time-weighted MRI scans of each patient to establish a low-vs-high risk lesion prediction model (MLH). Furthermore, MBCR and MOPR predictive model schemes were built by combining MLH, PSA, and clinical stage values of patients. Performance evaluation of the established models was performed with 1000-fold Monte Carlo (MC) cross-validation. Results were additionally compared to conventional [68Ga]Ga-PSMA-11 standardized uptake value (SUV) analyses. Results The area under the receiver operator characteristic curve (AUC) of the MLH model (0.86) was higher than the AUC of the [68Ga]Ga-PSMA-11 SUVmax analysis (0.80). MC cross-validation revealed 89% and 91% accuracies with 0.90 and 0.94 AUCs for the MBCR and MOPR models respectively, while standard routine analysis based on PSA, biopsy Gleason score, and TNM staging resulted in 69% and 70% accuracies to predict BCR and OPR respectively. Conclusion Our results demonstrate the potential to enhance risk classification in primary prostate cancer patients built on PET/MRI radiomics and machine learning without biopsy sampling.

Published

2020