This paper develops an SIBR cholera transmission model with general incidence rate. Necessary and sufficient conditions for local and global asymptotic stability of the equilibria are established by Routh Hurwitz criterium, Lyapunov function, and the second additive composite matrix theorem. What is more, exploiting the DED is cover simulation tool, the parameter values of the model are estimated with the 1998-2021 cholera case data in China. Finally, we perform sensitivity analysis for the basic reproduction number to seek for effective interventions for cholera control.
Cholera, a grave waterborne ailment caused by Vibrio cholerae, exhibits a remarkable ability to persist in certain aquatic environments for durations spanning three months to two years. Its clinical manifestations are characterized by intense diarrhea and vomiting, with severe cases leading to potentially fatal dehydration due to significant loss of bodily fluids and electrolytes. Categorized as a class A infectious disease in China, cholera is distinguished by its sudden onset and rapid transmission dynamics. The primary mode of transmission involves the interaction between humans and their environment, particularly through the ingestion of food or water contaminated by the Vibrio cholerae bacteria [
Significantly, Wang et al. [
{ S ′ = μ N − β 1 ( I ) S I − β 2 ( I ) S B B + K − μ S + σ R , I ′ = β 1 ( I ) S I + β 2 ( I ) S B B + K − ( γ + μ ) I , B ′ = β 3 ( I ) S I − δ B , R ′ = γ I − ( μ + σ ) R . (1.1)
In this framework, the entire human population, denoted by the constant size N, is categorized into distinct compartments: the susceptible (S), the infectious (I) and the recovered (R) [
Furthermore, this model accounts for the influence of human behavior arising from health education, improved hygiene, and sanitation practices [
{ S ′ = μ N − S g ( I ) − S f ( I , B ) − μ S + σ R , I ′ = S g ( I ) + S f ( I , B ) − ( γ + μ ) I , B ′ = η ( I ) − δ B , R ′ = γ I − ( μ + σ ) R . (1.2)
Assume that the total population is constant N = S + I + R . The model is based on the standard SIR (susceptibility-infection-recovery) compartment structure and has an additional compartment B indicating the concentration of Vibrio cholera in contaminated water. Based on the above assumptions, model (1.2) can be established [
The structure of this article unfolds as follows: Section 1 is the proof of the positivity and boundedness of solutions for the model (1.2). Section 2 is dedicated to establishing the existence and stability of equilibria, encompassing both the disease-free equilibrium and the positive equilibrium points. Some numerical simulations and sensitivity analyses are performed in Section 3 for the parameter R 0 , corroborating the theoretical analysis mentioned earlier. Finally, the article concludes in Section 4 with a concise discussion summarizing our findings.
Theorem 2.1. Under nonnegative initial conditions, for t > 0 , the solution ( S ( t ) , I ( t ) , B ( t ) , R ( t ) ) of model (1.2) is nonnegative.
Proof. Let t = S u p { t > 0 | S > 0 , I > 0 , B > 0 , R > 0 } . Now, from the first equation of model (1.2), we obtain
d S ( t ) d t ≥ μ N − ( g ( I ) + f ( I , B ) + μ ) S .
From the above equation, we can reduce that
d d t [ S ( t ) exp { ∫ 0 t g ( I ) d ς + ∫ 0 t f ( I , B ) d ς + μ t } ] ≥ μ N exp { ∫ 0 t g ( I ) d ς + ∫ 0 t f ( I , B ) d ς + μ t } .
Further,
S ( t 1 ) exp { ∫ 0 t 1 g ( I ) d ς + ∫ 0 t 1 f ( I , B ) d ς + μ t 1 } − S ( 0 ) ≥ ∫ 0 t 1 μ N exp { ∫ 0 ϕ g ( I ) d ϕ + ∫ 0 ϕ f ( I , B ) d ϕ + μ ϕ } d ϕ .
Therefore,
S ( t 1 ) ≥ S ( 0 ) exp { − ∫ 0 t 1 g ( I ) d ς − ∫ 0 t 1 f ( I , B ) d ς − μ t 1 } + exp { − ∫ 0 t 1 g ( I ) d ς − ∫ 0 t 1 f ( I , B ) d ς + μ t 1 } × ∫ 0 t 1 μ N exp { ∫ 0 ϕ g ( I ) d ϕ + ∫ 0 ϕ f ( I , B ) d ϕ + μ ϕ } d ϕ > 0.
Similarly, we can obtain the bounds for the other components of the solution.
Theorem 2.2. All solutions of model (1.2) are bounded.
Proof. The model (1.2) consists of two populations, namely human and pathogen. Therefore, we will break the model (1.2) into two parts, of which one involves the human population ( S , I , R ) and the other the pathogen population B. According to model (1.2) we obtain
d ( S + I + R ) d t d ( S + I + R ) / d t = μ ( N − S − I − R ) .
Further, from the first equation of the model (1.2), we have
S ′ ≤ N ( μ + σ ) − S ( μ + σ ) .
Hence, we conclude that S < N . Now, from the last equation of the model, we deduce that R ′ ≤ r N − ( r + μ + σ ) R . We can obtain R ≤ r N / ( r + μ + σ ) . According to the third equation of the model (1.2) and assumptions in reference [
B ′ = α 3 − b 3 m 3 ( I ) − δ B ≤ α 3 − δ B .
Therefore, B ≤ α 3 / δ . From the above discussion, it is clear from the above discussion that all solutions are bounded. Next, we obtain the feasible region for the human population as
Ω H = { ( S , I , R ) | S + I + R = N , 0 ≤ S ≤ N , 0 ≤ R ≤ r N / ( r + μ + σ ) } .
And the feasible region for pathogen population is
Ω B = { B | 0 ≤ B ≤ α 3 / δ } .
Define Ω = Ω H × Ω B . Now, Ω is a positively invariant region for the model (1.2). Moreover, the model (1.2) is mathematically and epidemiologically well-posed with the method utilized in [
The existence of equilibria is discussed below, we define
g ( 0 ) = 0 , f ( 0 , B ) ≥ 0 , f ( I , 0 ) = 0 , η ( 0 ) = 0 , f ′ I ( 0 , 0 ) = 0 , f ′ I ( I , B ) < f ( I , B ) / I , f ′ I ( I , B ) < 0 , 0 ≤ f ′ B ( I , B ) ≤ f ( I , B ) / B , 0 ≤ η ′ ( I ) ≤ η ( I ) / I , 0 ≤ g ′ ( I ) ≤ g ( I ) / I .
Theorem 3.1 When R 0 > 1 , then model (1.2) has two equilibria E 0 and E * , when R 0 ≤ 1 , model (1.2) has a unique equilibrium E 0 .
Proof. Due to N = S + I + R , R = γ I / ( μ + σ ) S = N − I − R = N − ( μ + σ + γ ) I / ( μ + σ ) = ϕ ( I ) , and
S = ( μ + γ ) I g ( I ) + f ( I , η ( I ) / δ ) = ( μ + γ ) h ( I ) ≜ ψ ( I ) , h ( I ) = ( g ( I ) + f ( I , η ( I ) / δ ) ) / I .
Because of S = ϕ ( I ) > 0 , then 0 < I < ( μ + σ ) N / ( μ + σ + γ ) = I max . Thus, considering S = ϕ ( I ) and S = ψ ( I ) at the intersection where [ 0 , I max ) Thus, we can obtain
h ′ ( I ) = 1 I 2 [ g ′ ( I ) I − g ( I ) + f ′ I ( I , B ) I + ( f ′ B ( I , B ) η ′ ( I ) ) I / δ − f ( I , B ) ] ≤ 1 I 2 [ g ′ ( I ) I − g ( I ) + f ′ B ( I , B ) η ( I ) / δ − f ( I , B ) ] = 1 I 2 [ g ′ ( I ) I − g ( I ) + f ′ B ( I , B ) B − f ( I , B ) ] ≤ 0.
This indicates that ψ ′ ( I ) ≥ 0 , On the other hand ϕ ′ ( I ) ≤ 0 , ϕ ( 0 ) = N , ϕ ( I max ) = 0 and ψ ( I max ) > 0 , then
ψ ( 0 + ) = lim I → 0 + μ + γ h ( I ) = μ + γ g ′ ( 0 ) + f ′ I ( 0 , 0 ) + f ′ B ( 0 , 0 ) η ′ ( 0 ) / δ = N T 1 .
Therefore, when T 1 > 1 , ϕ ( 0 ) > ψ ( 0 + ) is the only one node, denoted as I ∗ . When T 1 ≤ 1 , ϕ ( 0 ) ≤ ψ ( 0 + ) , there is no node. With the utilization of next generation matrix method mentioned in [
F = [ N g ′ ( 0 ) N f ′ B ( 0 , 0 ) η ′ ( 0 ) 0 ] , V = [ μ + γ 0 0 δ ] .
Therefore, the basic reproduction number R 0 of the model can be obtained as follows
R 0 = ρ ( M ) = 1 2 [ N g ′ ( 0 ) μ + γ + ( N g ′ ( 0 ) μ + γ ) 2 + 4 N f ′ B ( 0 , 0 ) δ η ′ ( 0 ) μ + γ ] .
At the same time, if disease control targets at a particular host type, a useful threshold is called the reproduction number T. The reproduction number defines the expected number of secondary infections due to a typical primary case in a fully susceptible population [
Theorem 3.2.1. When R 0 < 1 , the disease-free equilibrium point of model (1.2) is locally asymptotically stable. When R 0 > 1 , the disease-free equilibrium point of model (1.2) is unstable.
Proof. According to the model (1.2), we take R = N − S − I . Thus, it can be seen that
{ S ′ = ( μ + σ ) N − S g ( I ) − S f ( I , B ) − S ( μ + σ ) − σ I , I ′ = S g ( I ) + S f ( I , B ) − ( γ + μ ) I , B ′ = η ( I ) − δ B . (3.1)
Then, its Jacobi matrix of (3.1) at E 0 is
J = [ − g ( I ) − f ( I , B ) − ( μ + σ ) − S g ′ ( I ) − S f ′ I ( I , B ) − σ − S f ′ B ( I , B ) g ( I ) + f ( I , B ) S g ′ ( I ) + S f ′ I ( I , B ) − ( γ + μ ) S f ′ B ( I , B ) 0 η ′ ( I ) − δ ] .
The characteristic equation is ( λ + μ + σ ) ( λ 2 + a 1 λ + a 2 ) = 0 .
As for a 1 = γ + μ + δ − N g ′ ( 0 ) , a 2 = δ ( γ + μ − N g ′ ( 0 ) ) − N f ′ B ( 0 , 0 ) η ′ ( 0 ) . It is easy to know that one of the eigenvalues is λ = − ( μ + σ ) , rest up to ( λ 2 + a 1 λ + a 2 ) = 0 , take advantage of T 1 = N g ′ ( 0 ) / ( μ + γ ) + N f ′ B ( 0 , 0 ) η ′ ( 0 ) / ( μ + γ ) δ , T 1 < 1 , a 1 > 0 , and a 2 > 0 .
By the Hurwitz criterion, when T 1 < 1 , all the eigenvalues are negative, the disease-free equilibrium is locally asymptotically stable. When T 1 > 1 , the characteristic equation consists of one positive root and two negative roots, so the disease-free equilibrium is unstable, completing the proof.
Theorem 3.2.2. When R 0 ≤ 1 , model (1.2) has a globally asymptotically stable disease-free equilibrium point.
Proof. Now we use the next generation matrix method to prove this theorem. Establish
F 1 = [ N g ′ ( 0 ) N f ′ B ( 0 , 0 ) 0 0 ] , V 1 = [ μ + γ 0 − η ′ ( 0 ) δ ] .
Because of I ≥ 0 , g ( I ) ≥ 0 . If and only if I = 0 , g ″ ( I ) ≤ 0 . So g ′ ( I ) I ≤ g ( I ) ≤ g ′ ( 0 ) I . When y = ( I , B ) T , model (3.1) satisfies
d y d t ≤ d y ( F 1 − V 1 ) y .
Le w = ( N g ′ ( 0 ) , N f ′ B ( 0 , 0 ) ) , due to T 1 = ρ ( F 1 V 1 − 1 ) = ρ ( V 1 − 1 F 1 ) we can prove w V 1 − 1 F 1 = T 1 w . From [
L ′ = w V 1 − 1 d y d t ≤ w V 1 − 1 ( F 1 − V 1 ) y = ( T 1 − 1 ) w y .
When T 1 ≤ 1 , the disease-free equilibrium is globally asymptotically stable.
Consider the differential equation x ˙ = f ( x ) , x ∈ D . Let x ( t , x 0 ) be the solution to this equation with the initial value x ( 0 , x 0 ) = x 0 satisfying two hypotheses listed as follows [
(H1) There exists a compact attractive subset K ⊂ D ,
(H2) Model (3.1) has a unique equilibrium x ∈ D .
Lemma 3.3.1. [
Theorem 3.3.1 When R 0 > 1 , the positive equilibrium point E * is locally asymptotically stable.
Proof. The Jacobi matrix of model (3.1) at E * is
M ( E * ) = [ − g ( I * ) − f ( I * , B * ) − ( μ + σ ) − S g ′ ( I * ) − S f ′ I ( I * , B * ) − σ − S f ′ B ( I * , B * ) g ( I * ) + f ( I * , B * ) S g ′ ( I * ) + S f ′ I ( I * , B * ) − ( γ + μ ) S f ′ B ( I * , B * ) 0 η ′ ( I * ) − δ ] .
Therefore t r ( M ( E * ) ) = S g ′ ( I * ) + S f ′ I ( I * , B * ) − g ( I * ) − f ( I * , B * ) − ( γ + μ + δ ) − ( γ + μ ) , take advantage of ( μ + γ ) = ( S g ( I ) + S f ( I , B ) ) / I , it is easy to derive
t r ( M ( E * ) ) = S g ′ ( I * ) − S g ( I * ) / I * + S f ′ I ( I * , B * ) − S f ( I * , B * ) / I * − g ( I * ) − f ( I * , B * ) − ( μ + σ + δ ) < 0.
The determinant of M ( E * ) is
d e t ( M ( E * ) ) = δ S / I * ( μ + σ ) ( B f ′ B ( I * , B * ) − f ( I * , B * ) ) + δ ( μ + σ ) ( S g ′ ( I * ) − S g ( I * ) / I * + S f ′ I ( I * , B * ) ) − δ ( g ( I * ) + f ( I * , B * ) ) ( S g ′ ( I * ) + S f ′ I ( I * , B * ) + σ ) < 0.
We can write
M [ 2 ] ( E * ) = [ M 11 ( E * ) S f ′ B ( I * , B * ) S f ′ B ( I * , B * ) η ′ ( I * ) − g ( I * ) − f ( I * , B * ) − ( μ + σ + δ ) − S g ′ ( I * ) − S f ′ I ( I * , B * ) − σ 0 g ( I * ) + f ( I * , B * ) S g ′ ( I * ) + S f ′ I ( I * , B * ) − ( γ + μ + δ ) ] .
Among M 11 ( E * ) = S g ′ ( I * ) + S f ′ I ( I * , B * ) − g ( I * ) − f ( I * , B * ) − ( σ + γ + 2 μ ) . Calculate its determinant as
det ( M [ 2 ] ( E * ) ) < ( S g ′ ( I * ) + S f ′ I ( I * , B * ) − ( γ + μ + δ ) − g ( I * ) − f ( I * , B * ) ) ( δ S f ( I * , B * ) / I * − η ′ ( I * ) S f ′ B ( I * , B * ) ) < 0.
It’s made use of η ′ ( I ) S f ′ B ( I , B ) ≤ η ( I ) S f ′ B ( I , B ) / I ≤ δ B S f ′ B ( I , B ) / I ≤ δ S f ( I , B ) / I . In conclusion, when R 0 > 1 , E * is locally asymptotic stability, the theorem is proven.
Lemma 3.3.2. [
Since (H1) is equivalent to the consistent persistence of model (3.1) [
Lemma 3.3.3. When R 0 > 1 , model (3.1) is consistent and persistent.
Theorem 3.3.2. When R 0 > 0 , the positive equilibrium point E * is globally asymptotically stable.
Proof. First, based on the M ( E * ) obtained above, the Lyapunov function is established as follows.
V 2 ( x , u ) = { max | X | , I ( | Y | + | Z | ) / B } .
According to model (3.1), it can be concluded that
{ X ′ = M 11 X + S f ′ B ( I , B ) ( Y + Z ) , Y ′ = η ′ ( I ) X − ( g ( I ) + f ( I , B ) + ( μ + σ + δ ) ) Y − ( S g ′ ( I ) + S f ′ I ( I , B ) + σ ) Z , Z ′ = ( g ( I ) + f ( I , B ) ) Y − ( − S g ′ ( I ) − S f ′ I ( I , B ) + ( γ + μ + δ ) ) Z . (3.2)
Then
D + | X | ≤ M 11 | X | + B I S f ′ B ( I , B ) ( I B ( | Y | + | Z | ) ) , D + | Y | ≤ η ′ ( I ) | X | − ( g ( I ) + f ( I , B ) + ( μ + σ + δ ) ) | Y | − ( S g ′ ( I ) + S f ′ I ( I , B ) + σ ) | Z | , D + | Z | ≤ ( g ( I ) + f ( I , B ) ) | Y | − ( − S g ′ ( I ) − S f ′ I ( I , B ) + ( γ + μ + δ ) ) | Z | .
The derivative of V 2 along the positive solution of model (3.2) can be simplified as the following differential inequality
D + [ I B ( | Y | + | Z | ) ] = I B ( I ′ I − B ′ B ) [ | Y | + | Z | ] + I B D + [ | Y | + | Z | ] ≤ I B { η ′ ( I ) | X | − ( μ + σ + δ ) | Y | − ( γ + μ + σ + δ ) | Z | } + I B ( I ′ I − B ′ B ) [ | Y | + | Z | ] ≤ η ( I ) B | X | + I B ( I ′ I − B ′ B − γ − μ − σ − δ ) [ | Y | + | Z | ] .
Obtained from model (3.1) that I ′ I = S g ( I ) I + S f ( I , B ) I − ( γ + μ ) and B ′ B = η ( I ) B − δ , then
g 1 ( t ) = S g ′ ( I ) + S f ′ I ( I , B ) − g ( I ) − f ( I , B ) − ( σ + γ + 2 μ ) + B I S f ′ B ( I , B ) = I ′ I + ( μ + σ ) − g ( I ) − f ( I , B ) + S g ′ ( I ) − S g ( I ) I + B I S f ′ B ( I , B ) − S f ( I , B ) I + S f ′ I ( I , B ) < I ′ I − ( μ + σ ) (3.3)
g 2 ( t ) = η ( I ) B + ( I ′ I − B ′ B − γ − μ − σ − δ ) = B ′ B + δ + I ′ I − B ′ B − μ − σ − δ = I ′ I − ( μ + σ ) (3.4)
By using inequalities (3.3) and (3.4) we have
D + V ( t ) < sup { g 1 ( t ) , g 2 ( t ) } ≤ I ′ I − ( μ + σ ) = λ ′ ( t ) − ( μ + σ ) .
For satisfying that ( S ( 0 ) , I ( 0 ) , B ( 0 ) ) ∈ K (K is the inner compact attractive set Γ ° ) is the solution of the model (3.1) X ( t ) = ( S ( t ) , I ( t ) , B ( t ) ) , there must be
1 t ∫ 0 t D + V ( t ) d s ≤ 1 t ∫ 0 t I ′ I − ( μ + σ ) d s = 1 t ln I ′ ( t ) I ( 0 ) − ( μ + σ ) .
Thereby q ≤ − ( μ + σ ) < − ( μ + σ ) / 2 < 0 . Therefore, when R 0 > 1 , E * is globally asymptotically stable. The proof is now complete.
In this section, the DED is cover simulation tool [
R 0 = 1 2 [ α 1 N μ + γ + ( α 1 N μ + γ ) 2 + 4 α 2 α 3 N δ ( μ + γ ) K ] .
where α 1 , α 2 , and α 3 are the direct propagation rate, indirect propagation rate, and dropout rate, respectively. The biological meaning and the standard deviation of each parameters in model (1.2) are listed in
In
| Parameter | Meaning | Standard deviation | Source |
|---|---|---|---|
| μ | Natural mortality rate | 0.013 | [ |
| σ | Host immune loss rate | 13 | [ |
| γ | Recovery rate | 19.75 | [ |
| K | Environmental capacity | 106 | [ |
| δ | Net bacterial mortality rate | 12.1667 | [ |
numerical simulation, α 1 , α 2 , α 3 are positively proportional to I, γ is negatively proportional to I. Undoubtedly, reducing the coefficient of disease transmission α 1 and α 2 , such as epidemic prevention propaganda, isolation, sterilization, and wearing masks can effectively control the spread of cholera. On the other hand, shortening the disease course of disease γ can reduce the number of infected individuals. Therefore, it is possible for policy-makers to use multiple control measures jointly during the influenza pandemic.
Our study delves deep into the intricacies of the SIBR cholera transmission model, incorporating multiple modes of infection and a generalized incidence function. Initially, we derive the expression for the basic reproduction number. Subsequently, employing the Routh-Hurwitz condition and constructing the Lyapunov function, we establish a pivotal insight: when R 0 ≤ 1 , the disease-free equilibrium point is globally asymptotically stable. This implies that, absent any interventions, infectious diseases will eventually fade away. However, if R 0 > 1 , we ascertain that the endemic equilibrium point becomes globally asymptotically stable, indicating the disease’s perpetual presence. Notably, we address and surmount the constraints posed by the existing literature [
This work is supported partially by National Natural Science Foundation of China (Nos.12001178).
The authors declare no conflicts of interest regarding the publication of this paper.
Li, D.J. and Wang, L.W. (2023) Global Dynamics Analysis of a Cholera Transmission Model with General Incidence and Multiple Modes of Infection. Journal of Applied Mathematics and Physics, 11, 3747-3759. https://doi.org/10.4236/jamp.2023.1111236