Tmax Determined Using a Bayesian Estimation Deconvolution Algorithm Applied to Bolus Tracking Perfusion Imaging: A Digital Phantom Validation Study. Uwano I, Sasaki M, Kudo K, Boutelier T, Kameda H, Mori F, Yamashita F. Tmax Determined Using a Bayesian Estimation Deconvolution Algorithm Applied to Bolus Tracking Perfusion Imaging: A Digital Phantom Validation Study. Magn Reson Med Sci. 2017 Jan 10;16(1):32-37 | Voir |
Etude de la perfusion myocardique et évaluation de nouvelles approches de quantification bayésiennes et spatio-temporelles. Daviller C, Giacalone M, Frindel C, Boutelier T, Croisille P, Viallon M. Etude de la perfusion myocardique et évaluation de nouvelles approches de quantification bayésiennes et spatio-temporelles. 3ème Congrès de la SFRMBM, 2017. Bordeaux (France) . | Voir |
Perfusion Deconvolution in DSC-MRI with Dispersion-Compliant Base. Pizzolato M, Boutelier T, Deriche R. Perfusion Deconvolution in DSC-MRI with Dispersion-Compliant Base. Medical Image Analysis. 2017 Feb;36:197-215 | Voir |
Evaluation de Méthodes de Quantification de la Perfusion Cardiaque : Approches Bayésiennes et Spatio-temporelle. Recherche en Imagerie et Technologies pour la Santé (RITS). Daviller C, Giacalone M, Frindel C, Boutelier T, Croisille P, Viallon M. Evaluation de Méthodes de Quantification de la Perfusion Cardiaque : Approches Bayésiennes et Spatio-temporelle. Recherche en Imagerie et Technologies pour la Santé (RITS). Mar 2017. Lyon (France) | Voir |
Effect of Phase Correction on DTI and q-space Metrics. Pizzolato M, Boutelier T, Deriche R. Effect of Phase Correction on DTI and q-space Metrics. ISMRM workshop. 2016. Lisbon (Portugal). | Voir |
Improved Vascular Transport Function Characterization in DSC-MRI via Deconvolution with Dispersion-Compliant Bases. Pizzolato M, Fick R, Boutelier T, Deriche R. Improved Vascular Transport Function Characterization in DSC-MRI via Deconvolution with Dispersion-Compliant Bases. ISMRM. 2016. Singapore (Singapore). | Voir |
Noise Floor Removal via Phase Correction of Complex Diffusion-Weighted Images: Influence on and q-space Metrics. Marco Pizzolato, Rutger Fick, Timothé Boutelier, Rachid Deriche. Noise Floor Removal via Phase Correction of Complex Diffusion-Weighted Images: Influence on and q-space Metrics. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01358770 | Voir |
Elucidating dispersion effects in perfusion MRI by means of dispersion-compliant bases. Marco Pizzolato, Timothé Boutelier, Rutger Fick, Rachid Deriche. ELUCIDATING DISPERSION EFFECTS IN PERFUSION MRI BY MEANS OF DISPERSION-COMPLIANT BASES. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01309243 | Voir |
Stratégies et résultats de la segmentation volumique lésionnelle de l’AVC en IRM. Chaptal T, Le Bars E, Menjot de Champfleur N, Costalat V, Bonafé A. Stratégies et résultats de la segmentation volumique lésionnelle de l’AVC en IRM. SFNR. 2016. Paris (France).
Journal of Neuroradiology. March 2016. 43(2): 115–116. | Voir |
Perfusione in risonanza magnetica nello studio di gliomi cerebrali: riproducibilita? e confronto di dati ottenuti utilizzando due software di analisi. Conte GM, Iadanza A, Cadioli M, Castellano A, Falini A, Terreni MR, Franzin A, Calori G, Anzalone N. Perfusione in risonanza magnetica nello studio di gliomi cerebrali: riproducibilita? e confronto di dati ottenuti utilizzando due software di analisi. OSR. 2016. Milan (Italy). | Voir |
Exploiting the Phase in Diffusion MRI for Microstructure Recovery: Towards Axonal Tortuosity via Asymmetric Diffusion Processes. Pizzolato M, Wassermann D, Boutelier T, Deriche R. Exploiting the Phase in Diffusion MRI for Microstructure Recovery: Towards Axonal Tortuosity via Asymmetric Diffusion Processes. MICCAI. 2015. Munich (Germany). | Voir |
Exploiting the Phase in Diffusion MRI for Microstructure Recovery: Towards Axonal Tortuosity via Asymmetric Diffusion Processes. Marco Pizzolato, Demian Wassermann, Timothe Boutelier, Rachid Deriche. Exploiting the Phase in Diffusion MRI for Microstructure Recovery: Towards Axonal Tortuosity via Asymmetric Diffusion Processes. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01152672 | Voir |
A Temperature Phantom to Probe the Ensemble Average Propagator Asymmetry: an In-Silico Study. Marco Pizzolato, Demian Wassermann, Tanguy Duval, Jennifer S. W. Campbell, Timoth´e Boutelier, Julien Cohen-Adad, Rachid Deriche. A Temperature Phantom to Probe the Ensemble Average Propagator Asymmetry: an In-Silico Study. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01218143 | Voir |
Perfusion MRI Deconvolution with Delay Estimation and Non-Negativity Constraints. Hal Inria / Archives ouvertes. Marco Pizzolato, Aurobrata Ghosh, Timothé Boutelier, Rachid Deriche. Perfusion MRI Deconvolution with Delay Estimation and Non-Negativity Constraints. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01143213 | Voir |
Bias and Precision of Three Different DCE-MRI Analysis Software Packages: A Comparison Using Simulated Data. Cron GO, Sourbron S, Barboriak DP, Abdeen R, Hogan M, Nguyen TB. Bias and Precision of Three Different DCE-MRI Analysis Software Packages: A Comparison Using Simulated Data. ISMRM. 2014. Milan (Italy). | Voir |
Bayesian analysis of perfusion-weighted imaging to predict infarct volume: comparison with singular value decomposition. Kudo K, Boutelier T, Pautot F, Honjo K, Hu JQ, Wang HB, Shintaku K, Uwano I, Sasaki M. Bayesian analysis of perfusion-weighted imaging to predict infarct volume: comparison with singular value decomposition. Magn Reson Med Sci. 2014;13(1):45-50 | Voir |
Magnitude and complex based diffusion signal reconstruction. Marco Pizzolato, Aurobrata Ghosh, Timothe Boutelier, Rachid Deriche. Magnitude and complex based diffusion signal reconstruction. Hal Inria / Archives ouvertes. https://hal.inria.fr/hal-01095127 | Voir |
Assessment of the accuracy of a Bayesian estimation algorithm for perfusion CT by using a digital phantom. Sasaki M, Kudo K, Boutelier T, Pautot F, Christensen S, Uwano I, Goodwin J, Higuchi S, Ito K, Yamashita F. Assessment of the accuracy of a Bayesian estimation algorithm for perfusion CT by using a digital phantom. Neuroradiology. 2013 Oct;55(10):1197-203. | Voir |
Magnetic Resonance PWI-Derived Collateral Flow Index Is a Predictor of MCA-M1 Recanalization After IV Thrombolysis: New Insight Using The Bayesian Method. Nicoli F, Boutelier T, Pautot F, Girard N. Magnetic Resonance PWI-Derived Collateral Flow Index Is a Predictor of MCA-M1 Recanalization After IV Thrombolysis: New Insight Using The Bayesian Method. ISMRM. 2013. Salt Lake City (USA). | Voir |
Signal-To-Noise Ratio and Acquisition Duration Explain Erroneous Mean Transit Times in Acute Stroke Computed Tomography Perfusion Imaging. Pautot F, Kudo K, Boutelier T, Sasaki M. Signal-To-Noise Ratio and Acquisition Duration Explain Erroneous Mean Transit Times in Acute Stroke Computed Tomography Perfusion Imaging. ISC. 2012. New Orleans (USA). | Voir |
Bayesian hemodynamic parameter estimation by bolus tracking perfusion weighted imaging. Boutelier T, Kudo K, Pautot F, Sasaki M. Bayesian hemodynamic parameter estimation by bolus tracking perfusion weighted imaging. IEEE Trans Med Imaging. 2012 Jul;31(7):1381-95 | Voir |
Inter-observer and Intra-observer agreement of rCBV values in glial tumours using different proprietary analysis software. Fallatah S, Krishnan A, Brisson M, Adams M, Golay X, Jäger HF. Inter-observer and Intra-observer agreement of rCBV values in glial tumours using different proprietary analysis software. ESNR. 2012. Edinburgh (Scotland). | Voir |