Workshop on Cerebral Blood Flow (CBF) and Models of Neurovascular Coupling
July 14-18, 2014 at the Fields Institute
Organizer:
Tim David (Biomedical Engineering, Canterbury, NZ)

Registration on site July 14 Workshop fees: $100, Students and PDF: $50, Waived for invited speakers			Video of the talks of FieldsLive	Information for speakers
				Information for funded participants
Invited Speakers	Draft Program	Accommodation in Toronto		Toronto

Overview

The change in vessel diameter (vasoreactivity) controls the local cerebral blood flow and thereby the supply of oxygen and glucose. Although investigations of functional hyperaemia started over 200 years ago, the exact cellular and chemical pathways that are involved are still unknown. However, studies over the last decades indicate that neurons, astrocytes, smooth muscle cells and endothelial cells constitute a functional unit, which is collectively known as a neurovascular unit (NVU). When intercellular communication within the NVU functional hyperaemia is achieved, this process is called neurovascular coupling (NVC). A primary purpose is to maintain homeostasis in the cerebral micro-circulation and several mathematical models have been developed to mimic components of certain chemical pathways within the NVC.

Complex mathematical models can now be used to investigate the intricate relationship between neuronal activity and the regulation of the cerebral blood supply. Indeed they can also provide significant insight into the relationship between diabetes mellitus and the onset of dementia and Alzheimers disease. A physiologically relevant and experimentally validated mathematical model is critically needed to better understand the complexity of the underlying mechanisms, and to potentially identify strategies to prevent neuronal death, brain atrophy, and cognitive decline. These complex mathematical models produce extremely complex dynamical phenomena due to their nonlinear forms and the coupling that occurs between different types of cells. Mathematical analysis is required to investigate the crucial pathways in the model and, if possible, to simplify the system to a form whereby analytical tools can be used.

The above descriptions highlights the complexities involved in developing a viable mathematical model of blood perfusion in the cerebral tissue. However it is necessary if we are to advance our understanding of not only "normal" conditions but also pathological ones. Mathematical models can help in this advancement and it will be accelerated by the work of teams comprised of experts in a variety of areas.

This workshop will bring together international experts in the field of physiological modelling, mathematical analysis/modeling and young investigators. It will provide a framework for discussion, new insights and hopefully advancement in this new and exciting field of mathematical neuroscience.

Invited Speakers

Brian Carlson
Joshua Chang
Pierre Gremaud
James Kozloski
Fuyou Liang
Greg Mader
Adam Mahdi Yoichiro Mori
Johnny T Ottesen
Franck Plouraboue
Shu Tagaki
Marc Thiriet
Tim Secomb
Alix Withhoft
Yuan N. Young

Draft Program as of July 7
45 minutes each including questions ( speaker abstracts)

	Monday 14 July	Tuesday 15 July	Wednesday 16 July	Thursday 17 July	Friday 18 July
8:30 a.m.	On-site registration
8:45-9:00 a.m.	Welcoming remarks and introductions
9:00-9:45 a.m.	Tim David	Qiming Wang	Greg Mader	Brian Carlson	Fuyou Liang
10:00-10:45 a.m.	Joshua Chang	Shu Tagaki	Yoichiro Mori	Tim Secomb	Jingdong Tang
11:00-11:30 a.m.	Coffee Break
11:30-12:15	Marc Thiriet	Franck Plouraboue	Alix Witthoft	Yuan-nan Young	Closing
12:30-2:00 p.m.	Lunch
2:00-2:45 p.m.	Pierre Gremaud	James Kozloski	Bas-Jan Zandt	Brainstorm
3:00-3:30 p.m	Tea Break
	Brainstorm	Brainstorm	Brainstorm	Brainstorm