International Center for workshops in the Sciences
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Drug development is an extremely expensive, long and relatively
inefficient process, often hampered by the lack of appropriate (human) disease model
systems. Assays based on primary tissues and cells in culture dishes are often
difficult to reproduce from cell batch to cell batch and in general do not
behave like cells in complex multicellular organs as in the human body. In
addition, ethnic and other genetic differences that influence disease
pathophysiology, drug sensitivity and toxicity (side effects) between individuals are not captured by inbred
animal models commonly used in laboratories. In addition, there is increasing
social, ethical and financial pressure to reduce, refine and replace animal use
for drug development and safety pharmacology. Clearly, there is a social and
scientific need for in vitro
alternatives for currently used model systems that more accurately model human
disease and pathophysiology. In particular models that reproduce complex,
integrated organ-level human physiological and pathological responses would be
of great value. The solution could be provided by the development of “Organs on
Chips”, multicellular mini-organs grown in a microfluidic chips that in vitro reproduce complex, integrated
organ-level physiological and pathological responses of humans. To grow, maintain, and analyze representative
human organ tissue in vitro, it is
necessary to create the appropriate microenvironment in which biochemical,
physical, and geometrical factors are controlled with high spatiotemporal
precision. Among the likely solutions to this is microfluidics technology that
can produce “chips” in which small volumes of liquids can be precisely controlled
and moved through microscopic (micrometer and millimeter-sized) channels and
chambers, much like blood flows through the body, creating a microenvironment
in which “mini-organs” can grow, function, and interact similar to the in vivo situation. If the cell types
required to create Organs- on- Chips are derived from human stem or progenitor
cells, expressing genes associated with specific diseases, in combination with
microfluidics technology this provides an innovative approach to generating
reproducible and scalable models for healthy and diseased human tissue, based
on defined genetic backgrounds. The
main objective of this workshop is to develop a common view on the required
combinations of methods and technologies for creating “Organs-on-Chips” for
different organs and diseases, on the basis of state of the art keynote
lectures and active multidisciplinary discussions. The workshop will be informal
and highly interdisciplinary with delegates from diverse fields, among which
physicists, chemists, engineers, biologists, medical specialists (oncologists,
pathologists), representatives from pharmaceutical research,
in-vitro-diagnostics (IVD) companies, and a representative from the US regulatory
authorities. The following major themes will be addressed in the workshop: (1)
Organs-on-Chips – definition and purpose; (2) Different human cell sources: opportunities;
(3) Microfluidics / microfabrication / tissue engineering
approaches; (4) Applications, regulatory aspects and related issues. The
results of the workshop will be summarized in a meeting report, to be published
in a high impact scientific journal. [Back] |