From Inverse Problems in Mathematical Physiology to Quantitative Differential Diagnoses

The improved capacity to acquire quantitative data in a clinical setting has generally failed to improve outcomes in acutely ill patients, suggesting a need for advances in computer-supported data interpretation and decision making. In particular, the application of mathematical models of experimentally elucidated physiological mechanisms could augment the interpretation of quantitative, patient-specific information and help to better target therapy. Yet, such models are typically complex and nonlinear, a reality that often precludes the identification of unique parameters and states of the model that best represent available data. Hypothesizing that this non-uniqueness can convey useful information, we implemented a simplified simulation of a common differential diagnostic process (hypotension in an acute care setting), using a combination of a mathematical model of the cardiovascular system, a stochastic measurement model, and Bayesian inference techniques to quantify parameter and state uncertainty. The output of this procedure is a probability density function on the space of model parameters and initial conditions for a particular patient, based on prior population information together with patient-specific clinical observations. We show that multimodal posterior probability density functions arise naturally, even when unimodal and uninformative priors are used. The peaks of these densities correspond to clinically relevant differential diagnoses and can, in the simplified simulation setting, be constrained to a single diagnosis by assimilating additional observations from dynamical interventions (e.g., fluid challenge). We conclude that the ill-posedness of the inverse problem in quantitative physiology is not merely a technical obstacle, but rather reflects clinical reality and, when addressed adequately in the solution process, provides a novel link between mathematically described physiological knowledge and the clinical concept of differential diagnoses. We outline possible steps toward translating this computational approach to the bedside, to supplement today's evidence-based medicine with a quantitatively founded model-based medicine that integrates mechanistic knowledge with patient-specific information.

[1]  E. Jaynes Information Theory and Statistical Mechanics , 1957 .

[2]  M. Ursino,et al.  Role of active changes in venous capacity by the carotid baroreflex: analysis with a mathematical model. , 1994, The American journal of physiology.

[3]  David R. Anderson,et al.  Model selection and multimodel inference : a practical information-theoretic approach , 2003 .

[4]  Yuval Shahar,et al.  Knowledge-based temporal abstraction in clinical domains , 1996, Artif. Intell. Medicine.

[5]  Roque Marín,et al.  Fuzzy theory approach for temporal model-based diagnosis: An application to medical domains , 2006, Artif. Intell. Medicine.

[6]  S. Malpas,et al.  Slow oscillations in blood pressure via a nonlinear feedback model. , 2001, American journal of physiology. Regulatory, integrative and comparative physiology.

[7]  N. Silverman,et al.  Cardiac ventricular diastolic and systolic duration in children with heart failure secondary to idiopathic dilated cardiomyopathy. , 2006, The American journal of cardiology.

[8]  Malene Højbjerre,et al.  A population-based Bayesian approach to the minimal model of glucose and insulin homeostasis. , 2005, Statistics in medicine.

[9]  D C Angus,et al.  Severity scoring systems in the modern intensive care unit. , 1998, Annals of the Academy of Medicine, Singapore.

[10]  Koji Kashihara,et al.  A derivative-sigmoidal model reproduces operating point-dependent baroreflex neural arc transfer characteristics. , 2004, American journal of physiology. Heart and circulatory physiology.

[11]  N. McIntosh Intensive care monitoring: past, present and future. , 2002, Clinical medicine.

[12]  Donald E Stanley,et al.  BMC Health Services Research BioMed Central Debate A philosophical analysis of the evidence-based medicine debate , 2003 .

[13]  Gilles Clermont,et al.  Using Mathematical Models to Improve the Utility of Quantitative ICU Data , 2007 .

[14]  Didier Payen,et al.  Noninvasive techniques for measurements of cardiac output , 2005, Current opinion in critical care.

[15]  C. Hanson,et al.  Artificial intelligence applications in the intensive care unit , 2001, Critical care medicine.

[16]  O. Frank,et al.  Die grundform des arteriellen pulses , 1899 .

[17]  S. Doherty,et al.  Evidence‐based medicine: Arguments for and against , 2005, Emergency medicine Australasia : EMA.

[18]  M. Bonten,et al.  treatment of , 2004 .

[19]  T. G. Coleman,et al.  Circulation: overall regulation. , 1972, Annual review of physiology.

[20]  W. Young,et al.  Infinite number of solutions to the hemodynamic inverse problem. , 2001, American journal of physiology. Heart and circulatory physiology.

[21]  M. Ursino,et al.  Role of short-term cardiovascular regulation in heart period variability: a modeling study. , 2003, American journal of physiology. Heart and circulatory physiology.

[22]  D. Glower,et al.  Linearity of the Frank-Starling relationship in the intact heart: the concept of preload recruitable stroke work. , 1985, Circulation.

[23]  Roger G. Mark,et al.  Continuous cardiac output monitoring by peripheral blood pressure waveform analysis , 2006, IEEE Transactions on Biomedical Engineering.

[24]  Timothy J. Robinson,et al.  Sequential Monte Carlo Methods in Practice , 2003 .

[25]  A. Kulkarni,et al.  The challenges of evidence-based medicine: A philosophical perspective , 2005, Medicine, health care, and philosophy.

[26]  Craig J. Hartley,et al.  Resolving the hemodynamic inverse problem , 2006, IEEE Transactions on Biomedical Engineering.

[27]  Albert Tarantola,et al.  Inverse problem theory - and methods for model parameter estimation , 2004 .

[28]  B J TenVoorde,et al.  A baroreflex model of short term blood pressure and heart rate variability. , 2000, Studies in health technology and informatics.

[29]  L M Irwig,et al.  Evidence‐based medicine: useful tools for decision making , 2001, The Medical journal of Australia.

[30]  Max Harry Weil,et al.  Fluid challenge revisited , 2006, Critical care medicine.

[31]  M. Singer,et al.  Assessment of the clinical effectiveness of pulmonary artery catheters in management of patients in intensive care ( PAC-Man ) : a randomised controlled trial , 2022 .

[32]  Richard H Clayton,et al.  Mathematical modelling for the new millenium: medicine by numbers. , 2002, Medical engineering & physics.

[33]  E. Marder,et al.  Similar network activity from disparate circuit parameters , 2004, Nature Neuroscience.

[34]  Wolfgang Nejdl,et al.  Abstract temporal diagnosis in medical domains , 1997, Artif. Intell. Medicine.

[35]  James P. Keener,et al.  Mathematical physiology , 1998 .

[36]  B. Reglin,et al.  Structural response of microcirculatory networks to changes in demand: information transfer by shear stress. , 2003, American journal of physiology. Heart and circulatory physiology.

[37]  Y. Z. Ider,et al.  Quantitative estimation of insulin sensitivity. , 1979, The American journal of physiology.

[38]  K Sagawa,et al.  Translation of Otto Frank's paper "Die Grundform des Arteriellen Pulses" Zeitschrift für Biologie 37: 483-526 (1899). , 1990, Journal of molecular and cellular cardiology.

[39]  Vic Hasselblad,et al.  Impact of the pulmonary artery catheter in critically ill patients: meta-analysis of randomized clinical trials. , 2005, JAMA.

[40]  Peter Green,et al.  Markov chain Monte Carlo in Practice , 1996 .

[41]  Mauro Ursino,et al.  Interaction between carotid baroregulation and the pulsating heart: a mathematical model. , 1998, American journal of physiology. Heart and circulatory physiology.

[42]  J. Hadamard Sur les problemes aux derive espartielles et leur signification physique , 1902 .