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The Physiome: Genes to Organism. Modeling toward Human Health. ( Model Reproducibility, Databasing, and Covenient Dissem

The Physiome: Genes to Organism. Modeling toward Human Health. ( Model Reproducibility, Databasing, and Covenient Dissemination). James Bassingthwaighte, James H. Caldwell, 1 Bioengineering, 1,2 Radiology, 2 Medicine University of Washington, Seattle. Supported by ORNL NIH Program Office.

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The Physiome: Genes to Organism. Modeling toward Human Health. ( Model Reproducibility, Databasing, and Covenient Dissem

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  1. The Physiome: Genes to Organism.Modeling toward Human Health.( Model Reproducibility, Databasing, and Covenient Dissemination) James Bassingthwaighte, James H. Caldwell, 1Bioengineering, 1,2Radiology, 2Medicine University of Washington, Seattle Supported by ORNL NIH Program Office

  2. From Genome to Function:(Integrating Knowledge of Biological Systems) Health Organism The Physiome Project Organ Tissue • Gene, Structure & Function: • Experiments, Databases • System description • Quantitative system modeling • Archiving & dissemination Cell Molecule Genes

  3. The Physiome and the Physiome Project • The “Physiome” is the quantitative description of the functional behavior of the physiological state of an individual of a species. In its fullest form it should define relationships from organism to genome. • The “Physiome Project” is a concerted effort to define the Physiome through databasing and through the development of a sequence of model types: schema of interactions, descriptions of structure and functional relationships, and integrative quantitative modeling for logical prediction and critical projections.

  4. Physiome and Physiome Projects • Integrative models of genomic, metabolic, and intact in vivo systems should, via iteration with carefully designed experiments, resolve contradictions among prior observations and interpretations. • Comprehensive, accurate and realistic models will demonstrate emergent properties not inherent to the individual components, but apparent in the intact organism. • The “reverse engineering” of biology will aid clinical diagnosis and the design and the evaluation of therapy. • Gene regulatory networks, though difficult to construct, and almost impossible to validate, have their effects through higher level networks of cellular metabolism, tissue and organ function. These well identified systems serve as boundary conditions for proposed genetic networks, and serve also as the basis on which to explore the governance of transcription. • Databases, concepts, descriptions, and models should be in the public domain, in an open system fostering rapid progress in science.

  5. Modeling Approach: Use modular construction and use module reduction to gain speed (compromising robustness)

  6. Health Organism Structure of heart defines spread of excitation (Mcculloch, UCSD) Organ Tissue Cell Molecule The Human Physiome Gene Ion channel activation requires metabolism: Muscle contraction follows ion channel activation: Beard, Jafri, Kemp et al The Cardiome: multiscale modeling is required to cover the range of levels of function Contracting heart driven by spread of excitation (Hunter & Smith in Auckland, with D.Beard’s coronaries)

  7. Modeling and Hypothesis testing • Formulating an hypothesis integrates the ideas. • Testing and disproving hypotheses is a secure route to the advancement of scientific knowledge. Use Platt’s approach1. • The testing requires analysis of real data, and for complex hypotheses, the simultaneous accounting for multiple and diverse data sets. • Because biological systems are so deeply interconnected, meaningful cause-and-effect modeling necessitates a multiscale modular approach. • Here we tackle the application of modeling analysis to the estimation of regional myocardial blood flow, seeking diagnostic information via comparisons of maps of flows at rest and during vasodilatory stress. 1. Platt JR. Strong inference. Science 146: 347-353, 1964.

  8. The hypothesis to be tested: • Quantitative modeling analysis improves the diagnostic accuracy of regional myocardial blood flows and of regional flow reserve in patients with regional ischemic episodes with or without compromised cardiac ejection. • Background: • In the normal heart there is an 8 to 10-fold range of regional blood flows at any particular instant. The relative local flows are quite stable over time. This means that a low flow region is not necessarily ischemic. • Flows must be estimated indirectly, as flow per gram of tissue, and non-invasively, using PET, MRI, SPECT, or other technique. • Analysis of transients in marker concentrations is common to all of these technical approaches.

  9. Myocardial Flow Heterogeneity in Awake Baboons The distribution of regional flows, in voxels of about 0.5% of LV mass, shows a relative dispersion (SD/mean) of 25 to 30% in the LV, and more in the heart as a whole. RV flows are 70% of LV flows. (Data from 13 awake baboons at rest.) (King, Bassingthwaighte, Hales, and Rowell. Circ Res.57: 285-295, 1985. Fig 4)

  10. Myocardial capillaries within sheets of cardiac muscle Capillaries parallel muscle fibers within myocardial sheets (one capillary per cell) from Bassingthwaighte, Yipintsoi and Harvey, Microvasc. Res. 1964

  11. PS Flow Regional Fatty Acid Uptake and Flow are in Constant Proportion To fit these data, there must be increased density of fatty acid transporters in higher flow regions. This implies that transporter transcription is higher in higher flow regions. J. Caldwell et al. Am J. Cardiol. 1994

  12. Regional Cardiac Oxygen Metabolism using 15O-oxygen and PET Results show that MRO2 versus flow parallels palmitate uptake versus flow

  13. Estimating Regional Oxygen Consumption in vivo • Single breath inhalation of 15O-oxygen using PET • Image reconstruction at 2-second intervals provides time course of 15O in many regions of interest (ROI) • 15O -oxygen is reduced to form 15O -water • The fraction of the tracer oxygen transformed, times the total oxygen entering the tissue per unit time = oxygen consumption rate Li Z, Yipintsoi T, and Bassingthwaighte JB. Nonlinear model for capillary-tissue oxygen transport and metabolism. Ann Biomed Eng 25: 604-619, 1997.

  14. 100 m Capillaries are parallel (5 mm diam., 800 mm long) and radial intercapillary distances for diffusion are < 20 microns. The Supply Side (Bassingthwaighte, Yipintsoi & Harvey, 1974)

  15. Hexagonal arrangement of capillaries and muscle fibers allows simplified computation

  16. General blood-tissue exchange model

  17. Dual Oxygen/Water Modelfor analyzing PET images by Residue detection H2O H2O

  18. + Mb MbO The Process of Transport and Exchange of Oxygen

  19. 4-region Krogh cylinder axially-distributed model convection diffusion permeation reaction consumption production facilitated transport 4 regions * 4 species = 16 nonlinear PDEs Schematic Diagram of the Model:Capillary-Tissue Exchange Unit

  20. invertible Hill-type equations: [O2] and [CO2] can be obtained from SHbO2 and SHbCO2analytically… Equations for O2 and CO2 Saturations of Hemoglobin: SHbO2 and SHbCO2 Plasma CHbO2 and CHbCO2 can be expressed in terms of PO2 and PCO2 by Henry’s law: [O2]=O2PO2, [CO2]= CO2PCO2. Modified Hill coefficients KHbO2 and KHbCO2 account for the influences of pH and nonlinear O2-CO2interactions. KHbO2 and KHbCO2 also depend on an equilibrium constant K4’ for O2 binding Hb which varies with PO2, PCO2, pH, [DPG], T.

  21. K4”, n0, n1, n2, n3, n4 are estimated so as to get proper forms and shifts in HbO2 & HbCO2dissociation curves w.r.t. PO2, PCO2, pH, [DPG], T. Subscript “S” refers to the standard physiological levels in RBCs Equations for Modified Hill Coefficients: KHbO2 and KHbCO2 ( Dash and Bassingthwaighte, Ann. Biomed. Eng 2004 )

  22. Bohr effect pH  PCO2 [DPG]  T  Nonstandard Oxyhemoglobin (HbO2) Dissociation Curves

  23. Exchange Systems Pathways of Oxygen and Carbon Dioxide Transport and Exchange – A Big Picture

  24. Clinical Need • PET Myocardial Perfusion Studies • Offer diagnostic improvement in all patient categories • Can provide quantification, gives absolute rather than relative flow • Important in diabetes, microvessel disease and assessing significance of coronary stenosis • No commercially available software for flow quantification • Cardiac PET estimated to grow • In US, # of studies grew 45%/yr over last 10 yrs, anticipate 10%/yr  • In China: 6 sites 2007. Anticipate minimum of 30 sites in 2010 • No PET in Beijing in 2000. In 2005, 3,400 procedures* • 2005, one site doing cardiac PET • ~100 studies but 10% more studies than oncology in the 40 to 60 age group  courtesy of Bracco® * Nuc Med Comm., 28:661, 2007

  25. Quantitative PET Myocardial Perfusion Imaging: Integrated Image Manipulation, Modeling and Display for the Clinician Overall Goal: Provide a user-friendly analysis tool to the PET community for estimating regional myocardial blood flow quantitatively, using PET imaging of [13N]-ammonia and [82Rb]-rubidium Team: James B. Bassingthwaighte, MD, PhD, James H. Caldwell, MD Adam M. Alessio, PhD, Erik Butterworth, Support: Coulter Foundation

  26. Rationale for Quantitative Myocardial Perfusion Imaging • Non-invasive measure of absolute coronary flow reserve • Anatomic stenosis does not equal physiology and is not prognostic • Balanced ischemia • 3 vessel disease w/out a normal region • Abnormal Coronary Flow Reserve: • Occurs in aging, hypertrophy, post- transplant vasculopathies, endothelial dysfunction. • The problem is that when regional differences are reduced a qualitative scan does not distinguish ischemic from normal regions, or distinguish one of low reserve from one with adequate reserve since the data are on the flat part of the curves (right). Stress flow coronary flow reserve Rest flow Gould, Am J Cardiol, 1974

  27. Goal 2: Quantification of Myocardial Blood Flow NH3 Blood-Tissue Exchange Model Capillary Vp Dp 13NH4 Flow PSMig 13NOUT PSg 13NIN Disf Visf PSMipc PSpc Myocyte G 13N-glutamine (Mi) 13NH4 13N-glutamate (Ma) Vpc Dpc 13N-urea

  28. Quantification of Myocardial Blood Flow MBF Methods: 13N-NH3 injection into antecubital vein, obtain concentration time curves from LA(input function) and from myocardium (Residue functions). Same ROI during Stress ROI at Rest

  29. Goal 2: Quantification of Myocardial Blood Flow Coronary Short-axis Equivalent Circumflex Stress Polar MBF All Slices Stress PET Mid-ventricle slice > 95% > 70% LAD Bull’s eye plot: Apex at center, Septum at left. Anterior down.

  30. Physician’s Summary The qualitative maps, left column, suggest modest flow compromise in posterior wall near base but not elsewhere. The quantitative maps, center column, show low flow everywhere at rest, but severe compromise in flows everywhere but especially in the LV free wall and posteriorly. The flow reserve map shows only one region (#9, white) with near normal reserve. Diagnosis: nearly global ischemia.

  31. 15O-oxygen studies show that: • Regional flows and oxygen consumption are • Almost proportional (linear with positive intercept) • Demonstrate near neighbor positive correlation • Follow fractal statistical relationship • Results extend the observations of Caldwell et al (Am J Physiol 1994) that fatty acid uptake and flow are linearly related. • Reinforces concept that flow is determined by tissue’s metabolic needs.

  32. Conclusions re the distribution of energy utilization • Parts of the heart use more flow, fat, sugar, and oxygen (and presumably ATP) than other parts. Regionally there is up- or down-regulation of transporters and enzymes. • Cardiac geometry is variegated, local conduction velocities vary widely, fibre bundles slide across one another, sarcomere shortening is regionally varied. • Some parts work harder than others. ATP use by myosin ATPase, i.e. the cross-bridge and force generation, dominates the variation in local demand for substrates for energy production. • This result infers that the normal heterogeneity of regional flows is based on local mechanical functional differences?

  33. Thanks Colleagues and Collaborators at UW Postdoctoral Fellows and Students at UW Visiting Professors Keith Kroll* Dan Beard Jim Caldwell Eric Feigl Martin Kushmerick Ken Krohn Jeanne Link Zheng Li Tom Lewellen Maxwell Neal * deceased Lisa Schwartz Lori Gustafson Jim Revenaugh Dwight Stapleton Michael Kellen Kalyan Vinnakota Coert Zuurbier Jans Rijken Brian Carlson Tada Yipintsoi Andreas Deussen Santibrata Ghosh Andras Eke Ulrich Decking Ger van der Vusse Rob Reneman Frits Prinzen

  34. Appreciation

  35. Strain LV Free Wall 0 Septum 3-D heart model, a single slice:Finite Element modeling of LBBB 3 mm slice thickness at mid-LV (from Alex Veress, U. Washington)

  36. Conclusions • Realistic clinically useful models are often complicated, even complex. • Spatially distributed models are commonly required, but these are not more complicated than compartmental models, just more realistic. • Models are in day-to-day use in medical practice using imaging. • First principle models provide insight into the biology and can be built upon • Model archiving is essential

  37. Conclusions re the distribution of regional flows in the normal heart • Regional flows correlate with substrate and oxygen consumption (and presumably ATP). There is regional up- or down-regulation of transporters (fatty acid). • Normal cardiac geometry is variegated, conduction velocities vary, fibre bundle directions vary from endo- to epicardium, sarcomere shortening is regionally varied. • Some parts work harder than others. ATP use by myosin ATPase, i.e. the cross-bridge and force generation, dominates the local demand for substrates for energy production. • This can account for the heterogeneity in flow distribution when there is a vasodilatory response to increased local work and a diminution in vasodilatory influence when regional work decreases. • Myocardial flow heterogeneity, normal, is a result of uneven workloads and metabolism, presumable due to a combination of the geometric arrangements and of the timing of activation.

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