Working Group 6

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Contents 1 Announcements 2 Working Group 6: Tissue Mechanics 2.1 Working Group Leads: Trent Guess, guesstr@umkc.edu, Ahmet Erdemir, erdemira@ccf.org 2.2 Goals and Objectives 2.3 Working Group 6 Participants 2.3.1 Active Participants 2.3.2 Observers 3 Presentations 4 Working Group Issues 4.1 Working Group Name 5 Multiscale Modeling in Tissue Mechanics 5.1 Multiscale Modeling Definition 5.2 Theoretical Background 5.3 Current Tools 5.4 Issues 5.4.1 Supporting Infrastructure 5.4.2 Modeling Related 5.4.3 Other 5.5 Repository 6 Journal Articles 7 Monthly Reports 8 Feedback

[edit] Announcements

ErdemirA 10:49, 25 November 2009 (EST) I am trying to conduct a mini survey based on some recent discussions in MSM and IMAG. The survey can be found in Survey on Modeling and Simulation. Please contribute by adding your comments below the questions. Add any other questions and items that you see relevant.

ErdemirA 16:24, 27 October 2009 (EDT) There has been a significant amount of e-mail traffic between myself, Trent, Joy Ku (Simbios), Grace Peng (NIH), Luis Ibanez (Kitware), and Philip Bourne (PLoS Computational Biology) on the need and mechanisms to start a journal to disseminate data, models, and software for simulation-based medicine. The discussion is becoming mature, therefore a wiki page is created at Journal for Dissemination.

ErdemirA 16:14, 8 September 2009 (EDT) Trent and I had a chance to meet during the Annual Meeting for the American Society of Biomechanics and discussed various issues relevant to multiscale modeling in tissue mechanics and the working group. Below is a summary, please provide feedback.

• Recruiting New Working Group Members: The more the merrier. Additional members with relevant research in multiscale musculoskeletal and tissue mechanics will likely stimulate our knowledge and establish new collaboration pathways by providing different perspectives. If anyone knows someone at this capacity and who is interested in discussions with our working group, please let me know. Someone that I am interested in inviting is Jess Snedeker from University of Zurich, http://www.biomechanics.ch/.
• Presentations by Software Developers: Open source development is continuing at a high pace and we have now access to many model development and simulations. Two relevant examples are FEBio and IA-FEMESH. We can invite the leading investigators in these projects (Jeff Weis, University of Utah and Nicole Grosland, University of Iowa) to provide MSM webinars.
• Advertising MSM webinars on Biomch-L: We can increase visibility of MSM webinars relavant to musculoskeletal biomechanics and tissue mechanics by advertising them at BIOMCH-L listserver. Is attendance to webinars from anyone in the community allowed? I notice that bandwidth maybe a problem.
• Article on Art of Modeling: Trent and I discussed about many tips and tricks that we employ in modeling but are not necessarily learned in a scientific manner. I.e., why tetrahedral elements work in some simulations and they do not in others? There are many such knowledge we gain through trial and error and or through word-of-mouth from the experience of previous generations. How can we document such knowledge that it can be more accessible?
• Journal Data, Model, and Software Dissemination: It appears that dissemination of data, model and software is rather slow and incomplete when compared to amount of work we conduct. A major reason for that is we all need to wait until we get our publications out and get credit for doing the work, which is only possible if a scientific question is addressed. In addition, bringing the data into a usable form more or less accessible by others can be a long and tedious process. While a scientific publication is focused on the research problem, it does not necessarily detail relevant data specifications nor provide a complete data set with full documentation. Can starting a journal designed for dissemination in simulation-based medicine expedite this process? It will definitely have different review criteria (more or less a certification process and a quick one) but it should definitely provide mechanisms to cite data, model or software, e.g. a doi number, and be incorporated into literature databases, e.g. PubMed. Any comments? Should we pass this idea to the MSM consortium?

[edit] Working Group 6: Tissue Mechanics

[edit] Working Group Leads: Trent Guess, guesstr@umkc.edu, Ahmet Erdemir, erdemira@ccf.org

[edit] Goals and Objectives

1. determine computational priorities and challenges related to multi-scale modeling (MSM), specifically MSM of tissue mechanics and biomechanics,
2. explore solutions for model sharing, and
3. provide a forum for discussion of issues related to MSM and biomechanics

[edit] Working Group 6 Participants

[edit] Active Participants

• Jeff Bischoff
• Daniel Einstein
• Ahmet Erdemir (co-lead), Media:erdemir-research_area.pdf
• Trent Guess (co-lead), Media:WG_6_Guess.pdf
• Jason Halloran
• James Moore Media:MooreLymphModelingBackground.pdf‎
• Peter Pivonka, Media:ECB-research-description.pdf‎
• Jeff Reinbolt
• Jess Snedeker, Media:snedeker-research_area.pdf
• Merryn Tawhai
• Srinivas Tadepalli

[edit] Observers

• Ching-Long Lin
• Anil Misra
• James Glazier

For participant details, see Working Group 6 Participants.

[edit] Presentations

Friday June 26, 2009 4-5pm EDT - Ahmet Erdemir, Merryn Tawhai, Trent Guess

Multiscale Modeling in Computational Biomechanics

Abstract Biomechanics is broadly defined as the scientific discipline that investigates the effects of forces acting on and within biological structures. The realm of biomechanics includes the circulatory and respiratory systems, tissue mechanics and mechanotransduction, and the musculoskeletal system and motor control. As in many other biological phenomena, many spatial scales are crossed by biomechanics research: intracellular, multicellular, and extracellular matrices; and tissue, organ, and multiorgan systems. It is well established that the effect of forces at higher scales influence behavior at lower scales and that lower-scale properties influence higher-scale response. However, computational methods that incorporate these interactions in biomechanics are relatively rare. In general, computational models that include representation of multiple spatial or temporal scales are loosely defined as multiscale. The fact that multiscale modeling is not well defined lends the term to a variety of scenarios within the computational physiology community. In biomechanics, multiscale modeling may mean establishing a hierarchical link between the spatial and temporal scales, while the output of a larger-scale system is passed through a finely detailed representation at a lower scale (e.g., body-level movement simulations that provide net joint loading for tissue-level stress analysis). In reality, multiscale modeling may require more intricate representation of interactions among scales. A concurrent simulation strategy is inevitable to adequately represent nonlinear associations that have been known for decades.

IEEE-EMB article, http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=4939188&isnumber=4939176

Slides Media:Imag June 2009.pdf

Tuesday March 3, 2009 3-4pm EST - Scott Delp, Stanford University

OpenSim - an Open-Source Application for Musculoskeletal Modeling and Movement Simulations

Abstract: OpenSim is an open-source software application with a graphical user interface that allows users to develop models of musculoskeletal structures and create dynamic simulations of movement. First released in August 2007, OpenSim has already been downloaded by over 2000 users from a wide range of fields. In this talk, I will provide an overview of OpenSim and discuss the built-in tools, such as for computing inverse kinematics and muscle excitations. I will give some examples of how OpenSim has been used for studying gait, show some of the related resources that have been developed by the OpenSim community, and touch on some of the new features that are currently being incorporated into OpenSim.

OpenSim can be downloaded from http://simtk.org/home/opensim.

Speaker: Scott Delp is a professor in bioengineering at Stanford University and co-PI for Simbios, the NIH National Center for Biomedical Computing on physics-based simulation on biological structures. His research focuses on understanding the mechanisms involved in the production of movement, and spans the gamut from developing new simulation tools and algorithms, to working on novel experimental and imaging techniques, to addressing specific clinical questions related to cerebral palsy, stroke, Parkinson's disease, and osteoarthritis.

Slides Media:Delp_OpenSim2.pdf

[edit] Working Group Issues

[edit] Working Group Name

Any thoughts on changing the working group name from Tissue Mechanics to Biomechanics? Based on our IEEE EMBS submission, this broader title might better align with our collective research areas.

Comments

Changing the name from Tissue Mechanics to Biomechanics may work better to cover all our research areas.

[edit] Multiscale Modeling in Tissue Mechanics

[edit] Multiscale Modeling Definition

Multi-scale typically means models that span multiple length and/or time scales. Is there a need to define computational multi-scale modeling specific to biomechanics? How would this be defined? Discussion on defining Multiscale Modeling in Biomechanics

Scope

1. Musculoskeletal biomechanics
2. Mechanotransduction/mechanobiology
3. Respiratory system
4. Cardiovascular system
5. Structure function/tissue mechanics

Biological Scales atomic, molecular, molecular complexes, sub-cellular, cellular, multi-cell systems, tissue, organ, multi-organ systems, organism, population, and behavior

[edit] Theoretical Background

• Grids

[edit] Current Tools

Computational Biomechanics Tools page is adapted from the working document on the computational tools used in biomechanics Media:Biomech_tools.doc (updated 8/31/07).

E-mail regarding the purpose and goals of the computational tools working document was sent on 7/31/07: Media:July 31 e-mail.txt.

[edit] Issues

[edit] Supporting Infrastructure

1. It is difficult to get funding to support infrastructural projects.
2. Devoting time to such projects can lead to an initial decrease in concrete research outputs.
3. Software development is costly; dissemination, maintenance and support even more so.
4. Developing, maintaining, and coordinating open source tools should be a priority

Discussion details can be found in the following document: Media: WG_discussion_Aug_07.txt‎

[edit] Modeling Related

Modeling Issues in Multiscale Biomechanics is adapted from the working document on modeling issues related to computational biomechanics (multiscale, tissue mechanics, musculoskeletal biomechanics): Media:Modeling Issues.doc

[edit] Other

WG discussion from the 2007 ASME SBC Media:ASME SBC 2007.txt

[edit] Repository

[edit] Journal Articles

• IEEE EMBS Article

[edit] Monthly Reports

• Media:Group 6 minutes April 1 2006.doc
• Media:Group 6 minutes May 1 2006.doc
• Media:Group 6 minutes June 1 2006.doc
• Media:Group 6 minutes July 1 2006.doc
• Media:Group 6 minutes August 1 2006.doc
• Media:Group 6 minutes September 1 2006.doc
• Media:Group 6 minutes October 2006.doc
• Media:Group 6 minutes November 2006.doc
• Media:Group 6 minutes December 2006.doc
• Media:Group 6 minutes January 2007.doc
• Media:Group 6 minutes February 2007.doc
• Media:Group 6 minutes March 2007.doc

[edit] Feedback