Information Processing in Medical Imaging

Information Processing in Medical Imaging, or IPMI, is a conference held every two years^[1] focused on the fields of applied mathematics, computer science, image processing and image analysis (particularly of medical images); applied results in neuroscience, cardiology, and microscopy are also frequently considered. IPMI is the longest standing conference focused on medical images having first met, organized by Dr. Francois Erbsmann, in Brussels in 1969. IPMI 2021 is scheduled to be held in Bornholm, Denmark in June 2021.

History

The Information Processing in Medical Imaging conference – IPMI - was first organized by Francois Erbsmann and collaborators in Brussels in 1969. That first conference was held under the title, “Information Processing in Scintigraphy” as at the time the meeting was focused on restoration of those images derived by nuclear medicine. Since that first instance, the conference has successfully met every two years. The third instance of the meeting, organized by Stephen Pizer and Charles Metz, was its first appearance in the United States and since that occasion IPMI has alternated its venue between the U.S. and Europe. It was the 1977 meeting organized by Randy Brill in Nashville that first used the name IPMI to reflect the broadening community of physicists, mathematicians, computer scientists, and biologists interested in medical image computing in its many manifestations and applications who now contributed to the meeting. Commemorating his contribution as the conference founder, beginning with IPMI 1987 the Francois Erbsmann prize is awarded by the IPMI board each conference to one young investigator for outstanding contribution to the field. This investigator must have given their first oral presentation at the current IPMI.

Standing with tradition, IPMI includes a single track of presentations on novel methodology wherein speakers are allotted sufficient time to describe their contributions in thorough detail. Discussions following each presentation have no time-limit permitting stimulating debate and resolution of any questions or comments regarding the work, alternatives to it, additional possible applications, etc. Further, the paper associated with each presentation is assigned a study-group of attendees in advance rendering a portion of the community prepared to provide real time peer discussion in high technical detail. Study groups often pair younger researchers with field experts encouraging an exchange of experience and new ideas. Often, discussions and debates are continued through meals and social activities uniting the community through vigorous evaluation of avant-garde developments in medical imaging. To permit such depth the conference is limited to a maximum of 120 participants.

Reflecting its focus on depth and community, IPMI is often held in a relatively small and sometimes remote location. Attendees are accommodated together in collective housing in campus or university dorms, meals are typically enjoyed together by the entire community, and by a string of luck IPMI conferences have thus far been held in close proximity to a bar open sufficiently late to host continued scholarly debate. Further, IPMI fosters collaboration through its several social functions including the traditional soccer match and activities that take advantage of the typically remote setting.

For its tradition, intellectual value, and community building IPMI is a conference that many attendees very much look forward to.

Past IPMI Proceedings

The proceedings of the conference including all papers accepted for presentation are published by Springer in the series titles, "Lecture Notes on Computer Science" and "Image Processing, Computer Vision, Pattern Recognition, and Graphics." Some proceedings available online include those from the following years:

1983^[2] 1987^[3] 1989^[4]

1991^[5] 1993^[6] 1995^[7] 1999^[8]

2001^[9] 2003^[10] 2005^[11] 2007^[12] 2009^[13] 2011^[14] 2013^[15] 2015^[16] 2017^[17] 2019^[18] 2021^[19]

Past Francois Erbsmann Prize Winners

1987 (Utrecht, The Netherlands): John M. Gauch, University of North Carolina, Chapel Hill, NC, USA.

J.M. Gauch, W.R. Oliver, S.M. Pizer: Multiresolution shape descriptions and their applications in medical imaging.

1989 (Berkeley, CA, USA): Arthur F. Gmitro, University of Arizona, Tucson, AZ, USA.

A.F. Gmitro, V. Tresp, V. Chen, Y. Snell, G.R. Gindi: Video-rate reconstruction of CT and MR images.

1991 (Wye, Kent, UK): H. Isil Bozma, Yale University, New Haven, CT, USA.

H.I. Bozma, J.S. Duncan: Model-based recognition of multiple deformable objects using a game-theoretic framework.

1993 (Flagstaff, AZ, USA): Jeffrey A. Fessler, University of Michigan, Ann Arbor, MI, USA.

J.A. Fessler: Tomographic reconstruction using information-weighted spline smoothing.

1995 (Brest, France): Maurits K. Konings, University Hospital, Utrecht, The Netherlands.

M.K. Konings, W.P.T.M. Mali, M.A. Viergever: Design of a robust strategy to measure intravascular electrical impedance.

1997 (Poultney, VT, USA): David Atkinson, Guy's Hospital, London, UK.

D. Atkinson, D.L.G. Hill, P.N.R. Stoyle, P.E. Summers, S.F. Keevil: An autofocus algorithm for the automatic correction of motion artifacts in MR images.

1999 (Visegrad, Hungary): Liana M. Lorigo, Massachusetts Institute of Technology, Cambridge, MA, USA.

L.M. Lorigo, O. Faugeras, W.E.L. Grimson, R. Keriven, R. Kikinis, C.-F. Westin: Co-dimension 2 geodesic active contours for MRA segmentation.

2001 (Davis, CA, USA): Viktor K. Jirsa, Florida Atlantic University, FL, USA.

V.K. Jirsa, K.J. Jantzen, A. Fuchs, J.A. Scott Kelso: Neural field dynamics on the folded three-dimensional cortical sheet and its forward EEG and MEG.

2003 (Ambleside, UK): Guillaume Marrelec, INSERM, France.

G. Marrelec, P. Ciuciu, M. Pélégrini-Issac, H. Benali: Estimation of the hemodynamic response function in event-related functional MRI: directed acyclic graphs for a general Bayesian inference framework.

2005 (Glenwood Springs, Colorado, USA): Duygu Tosun, Johns Hopkins University, Baltimore, USA.

D. Tosun, J.L. Prince: Cortical surface alignment using geometry driven multispectral optical flow.

2007 (Kerkrade, The Netherlands): Ben Glocker, Technische Universität München, Garching, Germany.

B. Glocker, N. Komodakis, N. Paragios, G. Tziritas, and N. Navab: Inter- and intra-modal deformable registration: continuous deformations meet efficient optimal linear programming.

2009 (Williamsburg, VA, USA): Maxime Descoteaux, NeuroSpin, Saclay, France

M. Descoteaux, R. Deriche, D. Le Bihan, J.F. Mangin, C. Poupon: Diffusion Propagator Imaging: Using Laplace's Equation and Multiple Shell Acquisitions to Reconstruct the Diffusion Propagator

2011 (Kloster Irsee, Germany): Hubert Fonteijn, University College London, London, UK.

H. M. Fonteijn, M. J. Clarkson, M. Modat, J. Barnes, M. Lehmann, S. Ourselin, N. C. Fox, D. C. Alexander: An Event-Based Disease Progression Model and Its Application to Familial Alzheimer's Disease

2013 (Asilomar, California, USA): Hervé Lombaert, McGill University, Montreal

H. Lombaert, J. Sporring, K. Siddiqi: Towards Diffeomorphic Spectral Matching of Cortical Surfaces

2015 (Isle of Skye, Scotland, UK): Joseph Dagher, University of Arizona

J. Dagher: A Joint Acquisition-Estimation Framework for MR Phase Imaging

2017 (Boone, North Carolina, USA): Thomas Schlegl, Medical University of Vienna

Thomas Schlegl, Philipp Seeböck, Sebastian Waldstein, Georg Langs: Unsupervised Anomaly Detection with Generative Adversarial Networks to Guide Marker Discovery

2019 (Hong Kong): Sara Garbarino, Université Côte d’Azur

Sara Garbarino and Marco Lorenzi: Modeling and Inference of Spatio-Temporal Protein Dynamics Across Brain Networks

2021 (Virtual, Bornholm, Denmark): Kristen Campbell, University of Utah

Kristen Campbell, Haocheng Dai, Zhe Su, Martin Bauer, Tom Fletcher, Sarang Joshi: Structural Connectome Atlas Construction in the Space of Riemannian Metrics

2023 (Bariloche, Argentina): John Orlando Kalkhof, TU Darmstadt

John Orlando Kalkhof, Camila Gonzalez, Anirban Mukhopadhyay: Med-NCA: Robust and Lightweight Segmentation with Neural Cellular Automata

References

1. "dblp: IPMI". dblp.uni-trier.de. Retrieved 2017-04-26.
2. Information Processing in Medical Imaging - Proceedings of | Frank Deconinck | Springer. Springer. 1984. ISBN 9789400960473.
3. Graaff, C. N. De; Viergever, M. A. (2013-11-22). Information Processing in Medical Imaging. Springer Science & Business Media. ISBN 9781461572633.
4. Information processing in medical imaging : proceedings of the 11th International Conference on Information Processing in Medical Imaging held June 19-23, 1989 at Berkeley, California. Ortendahl, Douglas A., Llacer, Jorge. New York: Wiley-Liss. 1991. ISBN 978-0471560647. OCLC 22705804.
5. Information Processing in Medical Imaging - 12th | Alan C.F. Colchester | Springer. Lecture Notes in Computer Science. Springer. 1991. ISBN 9783540542469.
6. Barrett, Harrison H. (1993). Information Processing in Medical Imaging | SpringerLink. Lecture Notes in Computer Science. Vol. 687. doi:10.1007/bfb0013776. ISBN 978-3-540-56800-1. S2CID 36215114.
7. Information processing in medical imaging : 14th international conference, Ile de Berder, France, June 1995. Bizais, Y. (Yves), Barillot, Christian., Di Paola, Robert., International Conference on Information Processing in Medical Imaging (14th : 1995 : Ile Berder, France). Dordrecht: Kluwer Academic. 1995. ISBN 9780792335931. OCLC 46963076.
8. Information Processing in Medical Imaging - 16th International | Attila Kuba | Springer. Lecture Notes in Computer Science. Springer. 1999. ISBN 9783540661672.
9. Information Processing in Medical Imaging - 17th | Michael F. Insana | Springer. Lecture Notes in Computer Science. Springer. 2001. ISBN 9783540422457.
10. Information Processing in Medical Imaging - 18th International | Chris Taylor | Springer. Lecture Notes in Computer Science. Springer. 2003. ISBN 9783540405603.
11. Information Processing in Medical Imaging - 19th | Gary E. Christensen | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2005. ISBN 9783540265450.
12. Information Processing in Medical Imaging - 20th | nico karssemeijer | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2007. ISBN 9783540732723.
13. Information Processing in Medical Imaging - 21st | Jerry L. Prince | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2009. ISBN 9783642024979.
14. Information Processing in Medical Imaging - 22nd International | Gabor Szekely | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2011. ISBN 9783642220913.
15. Information Processing in Medical Imaging - 23rd International | James C. Gee | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2013. ISBN 9783642388675.
16. Information Processing in Medical Imaging - 24th | Sebastien Ourselin | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2015. ISBN 9783319199917.
17. Information Processing in Medical Imaging - 25th | Marc Niethammer, Martin Styner | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2017. ISBN 9783319590493.
18. Information Processing in Medical Imaging - 26th | Albert Chung | Springer. Image Processing, Computer Vision, Pattern Recognition, and Graphics. Springer. 2019. ISBN 9783030203504.
19. "Information Processing in Medical Imaging 2021 – IPMI 2021". Retrieved 2021-10-01.

External links

• Website for IPMI 2017
• Website for IPMI 2019
• Website for IPMI 2021
• Website for IPMI 2023