Introduction to - PowerPoint PPT Presentation

1 / 15
About This Presentation
Title:

Introduction to

Description:

University of the Philippines Ludwig-Maximilians-University. Diliman Munich, Germany ... Good fit between model and data ... Physiological facts for model ... – PowerPoint PPT presentation

Number of Views:48
Avg rating:3.0/5.0
Slides: 16
Provided by: eduardo9
Category:

less

Transcript and Presenter's Notes

Title: Introduction to


1
  • Introduction to
  • Mathematical and
  • Computational
  • Biology
  • Lecture 7B
  • Dr. Eduardo Mendoza
  • Mathematics Department Physics
    Department
  • University of the Philippines
    Ludwig-Maximilians-University
  • Diliman Munich, Germany
  • eduardom_at_math.upd.edu.ph
    Eduardo.Mendoza_at_physik.uni-muenchen.de
  • Department of Computer Science
  • Munich University of Applied Science

2
Topics to be covered
  • Delay Models
  • Concepts
  • Applications
  • Australian sheep blow-fly
  • Lemming population in Canada
  • Delay Models in Physiology Periodic Dynamic
    Diseases

3
1.3 Delay models
  • Previous models birth rate considered to act
    instantaneously, no time delay for reaching
    maturity
  • Delay differential equation models
  • dN/dt f (N(t), N(t T))
  • Logistic delay differential equation
  • dN/dt rN(t)(1 N(t T)/K)

4
Solution heuristics (1)
  • Suppose for t t1, N(t1 ) K and that for some
    t lt t1 , N (t T) lt K. Then
  • dN/dt gt 0 (since 1 N (t T)/K gt 0)
  • For t t1 T, N(t T) N(t1 ) K, hence dN/dt
    0.
  • Analogously, for t with t1 T lt t lt t2, dN/dt lt
    0, and t t2, dN/dt 0.
  • ? Possibility of oscillatory behavior

5
Solution heuristics (2)
  • Example dN/dt p/2T (N (t T)) ?
  • N(t) A cos pt/2T
  • Period 2T

6
Applications (1)
  • Australian sheep-blowfly (May, 1975)
  • Pest of considerable importance in Australian
    sheep farming
  • Data from Nicholsons 1957 experiments (over two
    years) regular basic periodic oscillation of
    35-40 days
  • In LDDE K food level available
  • T delay time need for larva to mature
  • r unknown parameter

7
Applications (2)
  • Lack of change with K observed (explained)
  • Good fit between model and data
  • Encourages use of logistic delay differential
    equations for populations, but care is needed in
    doing this!
  • Further applications
  • lemming population in Churchill, Canada (May,
    1981) 4 year-period, gestation time T 0.75
    year
  • Vole population in Scottish highlands (Stirzaker,
    1975) similar values as with lemmings
  • Rodent populations (Myers and Krebs, 1974) 3-4
    year cycles

8
Linear Analysis of Delay Population Models
Periodic Solutions (Excerpts from 1.4)
  • N 0 unstable with exponential growth
  • Need to consider only N K
  • Non-dimensionalization
  • N ? N(t)/K, t ? rt, T ? tT
  • Strictly speaking.N,r,T
  • Equation is now
  • dN(t)/dt N(t)(1-N(t-T))
  • Discussion s. blackboard

9
1.5 Periodic dynamic diseases
  • Cheyne-Stokes Respiration
  • human respiratory ailment manifsted in altered
    breathing pattern
  • Amplitude (directly related to breath volume or
    ventilation V) regularly waxes and wanes,
    separated by periods of apnea (very low volume)
  • S. blackboard for illustration

10
Physiological facts for model
  • Level c(t) of arterial carbon dioxide (CO2) is
    monitored by receptors (believed to be in the
    brainstem) ? timelag of T in overall control of
    breathing levels
  • Empirical data show ventilation response to CO2
    is sigmodial (s-form) ? use Hill function for
    the model

11
Model equation (1)
  • V Vmax cm(t T) / (am cm(t T) )
  • with
  • Vmax maximum possible volume
  • a, m determined by experimental data
  • (m is called the Hill constant)
  • Note we also assume that CO2 removal from blood
    ventilation x level of CO2

12
Model equation (2)
  • Model equation
  • dc(t)/dt p bVc(t)
  • with
  • p constant CO2 production rate
    in the body
  • b empirically determined constant
  • For extensive steady-state analysis, cf. pp.22-26
  • of Murray
  • Experimental parameter values estimated
  • Co 40 mmHg, p0 6 mmHg/min, V0 7
    liter/min,
  • T 0.25 min

13
Regulation of Haematopoiesis
  • Haematopoiesis formation of blood cell elements
    in the body
  • Physiological background
  • White and red blood cells, placelets and so on
    are produced in the bone marrow from where they
    enter the blood stream
  • When the level of oxygen in the blood decreases,
    this leads to a release of a substance, which in
    turn leads to an increase of blood elements from
    the marrow
  • Abnormalities in this feedback system are among
    major causes of haematological diseases

14
Model equation (1)
  • Let c(t) concentration of cells (the population
    species) in the circulating blood (in units of
    cells/mm3)
  • Assume cells are lost at a rate proportional to
    their concentration, say gc, where g has
    dimension (day)-1
  • After cell reduction, there is a 6-day delay
    before the marrow releases further cells to
    replenish
  • Assume flux ? of cells intro the bloodstream
    depends on cell concentration at an earlier time,
    namely c(t T), where T is the dely

15
Model equation (2)
  • Model equation
  • dc(t)/dt ? (c(t T)) gc(t)
  • Possible form for ? (c(t T)) due to Mackey
    and Glass, 1977
  • dc/dt ? am c(t T)/ am cm (t-T)
  • where ? , a, m, g and T are positive constants

16
1.6 Harvesting a single natural population
Write a Comment
User Comments (0)
About PowerShow.com