Mathematical modelling and the consequent analysis of problems arising in the Biomedical Sciences is increasingly becoming a major research interest.
Indeed, the great scientific revolution of this century is going to be the mathematical formalisation of phenomena in the Life Sciences, much as the revolution of the past two centuries was the development of the above approach in the Physical Sciences. To quote J E Cohen [1]: Mathematics is Biology’s next microscope, only better; Biology is Mathematics’ next Physics, only better.
The Italian community of mathematicians has decided to join efforts in facing the enormous challenges posed by such problems, by founding, in 1997, CIMAB, a national centre aimed at coordinating all major scientific competences in the area of Mathematical Biology and their diverse applications. It now includes seven universities (Florence, Milan, Naples, Torino University and Torino Politecnico, Trento, Urbino) and two National Research Council (IAC and IASI) centres, as well as individual researchers from other institutions including the IEO. We are aware that only by breaking down the academic and disciplinary silos will science be able to grow in order to resolve the enormous challenging problems raised by the Biomedical Sciences.
It is now becoming common to be aware that the heuristic or evidence based experimental approach, which is the traditional investigative method in the Biological Sciences, should be complemented by a mathematical modelling approach. The latter can be used as a hypothesis-testing, and indeed, hypothesis-generating, tool which can help to direct experimental research, while the results of experiments help to refine the modelling. The ultimate goal of CIMAB is to use mathematical models together with their computer simulations to support biomedical research to design new therapeutic strategies.
The main contribution that Mathematics can offer includes, because of its specific peculiarities, the following:
a) a better semantic understanding of the phenomenon, in terms of entities and relationships among them, followed by its syntactic representation, in terms of mathematical structures, i.e. its mathematical model;
b) the finding of solutions, possibly quantitative, of the mathematical models which on one hand offer an interpretation of available data, and on the other hand offer predictions of possible behaviours by varying some parameters, or the state of the system at the beginning, and also its external conditions;
c) validation of models based on real data, which includes the identification of the main parameters, is part of the mathematical approach to the analysis.
In addition to the above we cannot ignore the impact of sophisticated mathematical and statistical methods in medical diagnostics; let us just think of the methods for reconstruction and analysis of biomedical images obtained by non invasive techniques, such as TAC, NMR. The area of acquisition, processing and analysis of biomedical images is in itself a ground for challenging problems for mathematics and computational sciences.
One of the major contributions of Mathematical and Computational Biology is the ability to provide simulations, and related visualization in a set of scenarios that would be impossible in wet laboratories, because of financial, temporal or even ethical constraints. We are then facing the emergence of new paradigms that allocate computational experiments, based on mathematical models (in silico experiments - dry experiments) side to side with in vitro or in vivo experiments (wet experiments).
Mathematicians have become very aware that existing mathematical methods are not sufficient for the special complexity of biological systems, since the variety and the evolution of biological systems and their intrinsic complexity and multiscale structure make them a lot more complex than non biological systems.
An open problem is thus the development of innovative mathematical theories and methods capable of bridging different scales, from genes to cells, organs to organisms. Methods to reduce complexity, both analytical and computational, should be able to capture information at the micro-level of individuals (genes, cells, vessels, etc.) which are responsible for the emergence of complex behaviour on a larger scale (organs, organisms, etc.).
With the aim of encouraging interaction between mathematicians and researchers in Biomedical Sciences, CIMAB has organized the Workshop MathCell2010, that will be held in Rome on the14-15 December 2010 (web site: http://ctpde.iac.rm.cnr.it/MathCell2010/). Participation is free, but online registration is kindly required. As far as the topic of cancer research goes, this workshop will focus on the modelling and simulation of the complexity of cancer phenomena covering the whole path from the molecular (genetic) scale to that of tissues, through the description, by mathematical actions, at the cellular scale. The final, and main, objective of the modelling is focused on the optimization of therapeutic actions.
It is worth stressing that the workshop cannot aim to cover the whole variety of issues in the field, but simply to capture, out of the selected topics and speakers, the main issues related to the modelling of cancer phenomena with special focus on multi-scale aspects. Specifically the talks will deal with issues such as neo-angiogenesis and biomechanics of tumours. The hope is to cover sufficient material to motivate, on one side more mathematicians to develop a research activity in the field which also includes highly challenging analytic problems, while on the other side the hope is to attract the attention of the biomedical community towards a proficient cooperation aiming to improve the quality of human life, being aware that the solution of such tremendous problems can be reached only by a close collaboration of mathematicians, physicists, engineers and computer scientists with biologists and clinicians. Indeed, experimentalists and clinicians alike are becoming increasingly aware of the possibilities afforded by mathematical modelling, recognising that current medical techniques and experimental approaches are often unable to distinguish between various possible mechanisms underlying important aspects of tumour development.
Interestingly, Alberts et al [2] observe that ‘the emphasis given to cancer research has profoundly benefited a much wider area of medical knowledge than that of cancer alone’, explaining that ‘the effort to combat cancer has driven many fundamental discoveries in cell biology’.
The workshop will also cover topics concerning the regenerating tissues and the biofilms. From the mathematical modelling point of view, these biological phenomena share some open problems with the tumour growth, and we believe in the interest of the mutual interaction of these investigation.
The main speeches will be delivered during the Opening session by Prof G McVie (IEO), Prof M Chaplain (University of Dundee), and Prof L Preziosi (CIMAB-Politecnico Torino).
Vincenzo Capasso, Professor
Probability and Mathematical Statistics
Director of CIMAB
President-elect of the European Academy of Sciences
Department of Mathematics
Universita’ degli Studi di Milano
Via Saldini 50
20133 MILANO, Italy
e-mail: vincenzo.capasso@unimi.it
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[1] Cohen JE (2004) PLoS Biol 2 (12) e439 doi:10.1371/journal.pbio.0020439
[2] Alberts B et al (2002) Molecular Biology of the Cell 4th edn (New York: Garland Science)