Mathematical Model for Pneumonia Dynamics among Children

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PNEUMONIA INTRODUCTION

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Mathematical Model for Pneumonia Dynamics among Children by Jacob Otieno Ong ala Strathmore University, Nairobi (Kenya) at SAMSA 2010, Lilongwe (Malawi)

Outline 1. Background information of pneumonia 2. Derivation of the model 3. Analysis and simulation of the model 4. Results and Discussion 12/4/2012 SAMSA 2012 2

Motivation 12/4/2012 SAMSA 2012 3

Background Information of Pneumonia Pneumonia is a high inflammatory disease characterized by inflammatory condition of the lungs. Cases of pneumonia can be as a result of inhaling droplets of coughs and sneezes of an infected person. Some of the risk factors associated to the spread of pneumonia are: malnutrition, lack of exclusive breastfeeding, indoor pollution, antecedent viral infection amongst others It is majorly caused by bacteria (Streptococcus Pneumoniae) amongst other microorganisms such us: virus, parasites and fungi. Once the bacteria gets into the lungs, they settle in the alveoli and passages of the lungs where they invades by multiplying in number and cause infection. 12/4/2012 SAMSA 2012 4

Background Information of Pneumonia (Cont ) As the body attempts fight the bacteria, the area infected get filled with fluids and pus which makes breathing difficult. Medical literature also indicates that a healthy person can carry the bacteria in his nasopharynx (These are referred to as Carriers) The carriers can developed infection if the bacteria find its way to the lungs. This is possible when immunity of an individual is lowered. There is a possibility of the carrier to clear the bacteria due to self immunity or with antibiotic treatment. Individuals showing symptoms (infected) can also recover due to self immunity or through antibiotic treatment. The recovered individuals can only acquire temporary immunity. 12/4/2012 Report for 2010 5

Background Information of Pneumonia (Cont ) The control strategies available for pneumonia are Vaccination, treatments and Isolation. Despite an increasing resistance of sp to antibiotics, it is still the major treatment procedure used for pneumonia. Today the vaccines used are a 7-valent, 13-valent and 23-valent polysaccharide. These can cover upto 23 strains of sp (30% of all strains available) This means that if vaccination is used, we are not be 100% sure that the disease would be contained. An understanding of the transmission dynamic is therefore required to determine the optimal control measures 12/4/2012 SAMSA 2012 6

Derivation of the model Population N Carrier, C Susceptible, S Recovered, R Infected, I 12/4/2012 SAMSA 2012 7

Derivation of the model μ C β ν μ S ρλ π (1-q)η qη R μ (1 ρ)λ μ I δ α 12/4/2012 Report for 2010 8

System of Equations λ = ψ I t + εc(t) N(t) ψ = κρ 12/4/2012 SAMSA 2012 9

Analysis of the model We checked the positivity and boundedness of the solutions Determination of the basic reproduction number Ro using the next generation operator method. Existence and Stability of the disease free equilibrium (DFE) Existence and Stability of the Endemic equilibrium (EE) Bifurcation Analysis. Numerical Analysis. 12/4/2012 SAMSA 2012 10

Results Ro is directly proportional to the contact rate κ and to the mean time spent in the diseased classes. Moreover, a partial derivative of Ro w.r.t β and κ is a decreasing function 12/4/2012 SAMSA 2012 11

Results 12/4/2012 Report for 2010 12

Results From the jacobian matrix of the model and DFE; Implying that DFE is stable: 12/4/2012 SAMSA 2012 13

Results The stability of EE is assessed using the graph below. 12/4/2012 Report for 2010 14

Results Bifurcation analysis. 12/4/2012 SAMSA 2012 15

Results Effect of Carrier proportion 12/4/2012 Report for 2010 16

Discussion The existence of forward bifurcation indicates that when R0 < 1 then the disease free equilibrium is stable and become unstable when R0 > 1. The Local stability of the endemic equilibrium point EE changes its nature to unstable when it crosses the critical value via a forward bifurcation. This is a clear indication that the effective control measure for pneumonia is achieved when Ro is reduced. The first sure way of reducing the progression of the disease is to isolate It is also possible to reduce the incidence by increasing recovery rates of the diseased class Increasing the carriers proportion in a closed population reduced the Infected proportions. 12/4/2012 SAMSA 2012 17

Further working Optimal control strategies (Using probabilistic approach) Effect on misdiagnosis and mistreatment of pneumonia in transmission dynamics 12/4/2012 Report for 2010 18

τλαηκ γθμ 12/4/2012 SAMSA 2012 19

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