Contribution of a Ca<sup>2+</sup>-activated K<sup>+</sup> channel to neuronal bursting activities in the Chay model

Danqi Feng; Yu Chen; Quanbao Ji; Danqi Feng; Yu Chen; Quanbao Ji

doi:10.3934/era.2023380

Electronic Research Archive

2023, Volume 31, Issue 12: 7544-7555. doi: 10.3934/era.2023380

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Research article Special Issues

Contribution of a Ca²⁺-activated K⁺ channel to neuronal bursting activities in the Chay model

1.
School of Mathematics and Physics, Guangxi Minzu University, Nanning 530006, China
2.
Center for Applied Mathematics of Guangxi, Guangxi Minzu University, Nanning 530006, China

Received: 27 September 2023 Revised: 21 November 2023 Accepted: 22 November 2023 Published: 28 November 2023

The central nervous system extensively expresses Ca²⁺-stimulated K⁺ channels, which serve to use Ca²⁺ to control their opening and closing. In this study, we explore the numerical computation of Hopf bifurcation in the Chay model based on the equilibrium point's stability and the center manifold theorem to illustrate the emergence of complicated neuronal bursting induced by variation of the conductance of the Ca²⁺-sensitive K⁺ channel. The results show that the formation and removal of various firing activities in this model are due to two subcritical Hopf bifurcations of equilibrium based on theoretical computation. Furthermore, the computational simulations are shown to support the validity of the conceptual approach. Consequently, the conclusion could be helpful to improve and deepen our understanding of the contribution of the Ca²⁺-sensitive K⁺ channel.

Keywords:

bifurcation,
neuron,
computation,
burst

Citation: Danqi Feng, Yu Chen, Quanbao Ji. Contribution of a Ca2+-activated K+ channel to neuronal bursting activities in the Chay model[J]. Electronic Research Archive, 2023, 31(12): 7544-7555. doi: 10.3934/era.2023380

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Abstract

1. Introduction

Over the last two decades, many researches used LKF method to get stability results for time-delay systems ^[1,2]. The LKF method has two important technical steps to reduce the conservatism of the stability conditions. The one is how to construct an appropriate LKF, and the other is how to estimate the derivative of the given LKF. For the first one, several types of LKF are introduced, such as integral delay partitioning method based on LKF ^[3], the simple LKF ^[4,5], delay partitioning based LKF ^[6], polynomial-type LKF ^[7], the augmented LKF ^[8,9,10]. The augmented LKF provides more freedom than the simple LKF in the stability criteria because of introducing several extra matrices. The delay partitioning based LKF method can obtain less conservative results due to introduce several extra matrices and state vectors. For the second step, several integral inequalities have been widely used, such as Jensen inequality ^{[11,12,13,14]}, Wirtinger inequality ^[15,16], free-matrix-based integral inequality ^[17], Bessel-Legendre inequalities ^[18] and the further improvement of Jensen inequality ^{[19,20,21,22,23,24,25]}. The further improvement of Jensen inequality ^[22] is less conservative than other inequalities. However, The interaction between the delay partitioning method and the further improvement of Jensen inequality ^[23] was not considered fully, which may increase conservatism. Thus, there exists room for further improvement.

This paper further researches the stability of distributed time-delay systems and aims to obtain upper bounds of time-delay. A new LKF is introduced via the delay partitioning method. Then, a less conservative stability criterion is obtained by using the further improvement of Jensen inequality ^[22]. Finally, an example is provided to show the advantage of our stability criterion. The contributions of our paper are as follows:

$\bullet$ The integral inequality in ^[23] is more general than previous integral inequality. For $r = 0, 1, 2, 3$ , the integral inequality in ^[23] includes those in ^{[12,15,21,22]} as special cases, respectively.

$\bullet$ An augmented LKF which contains general multiple integral terms is introduced to reduce the conservatism via a generalized delay partitioning approach. For example, the $\int_{t-\frac{1}{m}h}^{t} x(s)ds$ , $\int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t} x(s)dsdu_1$ , $\cdots$ , $\int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t}\cdots\int_{u_{N-1}}^t x(s)dsdu_{N-1}\cdots d_{u_1}$ are added as state vectors in the LKF, which may reduce the conservatism.

$\bullet$ In this paper, a new LKF is introduced based on the delay interval $[0, h]$ is divided into $m$ segments equally. From the LKF, we can conclude that the relationship among $x(s)$ , $x(s-\frac{1}{m}h)$ and $x(s-\frac{m-1}{m}h)$ is considered fully, which may yield less conservative results.

Notation: Throughout this paper, $\mathbb{R}^m$ denotes $m$ -dimensional Euclidean space, $A^{\top}$ denotes the transpose of the A matrix, $0$ denotes a zero matrix with appropriate dimensions.

2. Preliminary

Consider the following time-delay system:

$\begin{equation} \begin{split} \dot x(t) = Ax(t)+ B_1x(t-h)+B_2\int_{t-h}^tx(s)ds, \end{split} \end{equation}$

(2.1)

$\begin{equation} x(t) = \Phi(t), t\in[-h, 0], \end{equation}$

(2.2)

where $x(t)\in R^{n}$ is the state vector, $A, B_1, B_2 \in R^{n\times n}$ are constant matrices. $h > 0$ is a constant time-delay and $\Phi(t)$ is initial condition.

$\bf{Lemma\; 2.1.}$ ^[23] For any matrix $R > 0$ and a differentiable function $x(s), \; s\in [a, b]$ , the following inequality holds:

$\begin{equation} \int_a^b\dot x^T(s)R\dot x(s)ds\geq \sum\limits_{n = 0}^{r}\frac{\rho_n }{b-a}\Phi_n(a,b)^TR\Phi_n(a,b), \end{equation}$

(2.3)

where

${\rho_n } = \left(\sum\limits_{k = 0}^n\frac{c_{n,k}}{n+k+1}\right)^{-1},$

$c_{n,k}{\rm = }\left\{ {\begin{array}{*{20}c} 1,\; \; k = n,\; n\geq 0, \\ -\sum\limits_{t = k}^{n-1}f(n,t)c_{t,k},\; k = 0, 1, \cdots n-1,\; n\geq1, \end{array}} \right.$

$\Phi_l(a,b){\rm = }\left\{ {\begin{array}{*{20}c} x(b)-x(a),\; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; l = 0, \\ \sum\limits_{k = 0}^{l}c_{l,k}x(b)- c_{l,0}x(a)-\sum\limits_{k = 1}^{l}\frac{c_{l,k}\;k!}{(b-a)^k}\varphi_{(a,b)}^kx(t),\; l\geq1, \end{array}} \right.$

$f(l, t) = \sum\limits_{j = 0}^{t}\frac{c_{t,j}}{l+j+1}/\sum\limits_{j = 0}^{t}\frac{c_{t,j}}{t+j+1},$

$\varphi_{(a,b)}^kx(t){\rm = }\left\{ {\begin{array}{*{20}c} \int_{a}^{b}x(s)ds,\; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; k = 1, \\ \int_{a}^{b}\int_{s_1}^{b}\cdots \int_{s_{k-1}}^{b}x(s_k)ds_{k}\cdots ds_{2}ds_{s_1},\; k > 1. \end{array}} \right.$

$\bf {Remark\; 2.1.}$ The integral inequality in Lemma 2.1 is more general than previous integral inequality. For $r = 0, 1, 2, 3$ , the integral inequality (2.3) includes those in ^{[12,15,21,22]} as special cases, respectively.

3. Results

$\bf{Theorem\; 3.1.}$ For given integers $m > 0, \; N > 0$ , scalar $h > 0$ , system (2.1) is asymptotically stable, if there exist matrices $P > 0$ , $Q > 0$ , $R_i > 0, \; i = 1, 2, \cdots, m$ , such that

$\begin{equation} \begin{split} \Psi = & \xi_1^TP\xi_2+\xi_2^TP\xi_1+\xi_3^TQ\xi_3-\xi_4^TQ\xi_4+\sum\limits_{i = 1}^m(\frac{h}{m})^2 A_d^TR_iA_d\\&-\sum\limits_{i = 1}^m\sum\limits_{n = 0}^r\rho_n\omega_n(t-\frac{i}{m}h, t-\frac{i-1}{m}h)R_i\times\omega_n(t-\frac{i}{m}h, t-\frac{i-1}{m}h) < 0, \end{split} \end{equation}$

(3.1)

where

$\xi_1 = \left[ {\begin{array}{*{20}c} e_1^T& \bar E_0^T&\bar E_1^T & \bar E_2^T&\cdots&\bar E_N^T \end{array}} \right]^T,$

$\xi_2 = \left[ {\begin{array}{*{20}c} A_d^T&E_0^T& E_1^T & E_2^T&\cdots& E_N^T \end{array}} \right]^T,$

$\xi_3 = \left[ {\begin{array}{*{20}c} e_1^T& e_2^T &\cdots& e_m^T \end{array}} \right]^T,$

$\xi_4 = \left[ {\begin{array}{*{20}c} e_2^T& e_3^T &\cdots& e_{m+1}^T \end{array}} \right]^T,$

$\bar E_0 = \frac{h}{m} \left[ {\begin{array}{*{20}c} e_2^T& e_3^T &\cdots& e_{m+1}^T \end{array}} \right]^T,$

$\bar E_i = \frac{h}{m} \left[ {\begin{array}{*{20}c} e_{im+2}^T& e_{im+3}^T &\cdots& e_{im+m+1}^T \end{array}} \right]^T,\; i = 1, 2, \cdots, N,$

$E_i = \frac{h}{m} \left[ {\begin{array}{*{20}c} e_1^T- e_{im+2}^T& e_2^T-e_{im+3}^T &\cdots& e_m^T-e_{m(i+1)+1}^T \end{array}} \right]^T,\; i = 0, 1, 2, \cdots, N,$

$A_d = Ae_1+B_1e_{m+1}+B_2\sum\limits_{i = 0}^{m}e_{m+1+i},$

$\omega_n(t-\frac{i}{m}h, t-\frac{i-1}{m}h){\rm = }\left\{ {\begin{array}{*{20}c} e_i-e_{i+i},\; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; \; n = 0, \\ \sum\limits_{k = 0}^{n}c_{n,k}e_i- c_{n,0}e_{i+1}-\sum\limits_{k = 1}^{n}c_{n,k}k!e_{(k-1)m+k+1}, \; n\geq1, \end{array}} \right.$

$e_i = \left[ {\begin{array}{*{20}c} 0_{n\times (i-1)n}&I_{n\times n}&0_{n\times (Nm+1-i)} \end{array}} \right]^T,\; i = 1, 2, \cdots, Nm+1.$

Proof. Let an integer $m > 0$ , $[0, h]$ can be decomposed into $m$ segments equally, i.e., $[0, h] = \bigcup_{i = 1}^{m}[\frac{i-1}{m}h, \frac{i}{m}h]$ . The system (2.1) is transformed into

$\begin{equation} \dot x(t) = Ax(t)+ B_1x(t-h)+B_2\sum\limits_{i = 1}^{m}\int_{t-\frac{i}{m}h}^{t-\frac{i-1}{m}h}x(s)ds. \end{equation}$

(3.2)

Then, a new LKF is introduced as follows:

$\begin{equation} \begin{split} V(x_t) = \eta^T(t)P\eta(t)+\int_{t-\frac{h}{m}}^t\gamma^T(s)Q\gamma(s)ds+\sum\limits_{i = 1}^{m}\frac{h}{m}\int_{-\frac{i}{m}h}^{-\frac{i-1}{m}h}\int_{t+v}^t\dot x^T(s)R_i\dot x(s)dsdv, \end{split} \end{equation}$

(3.3)

where

$\begin{array}{l} \eta(t) = \left[ {\begin{array}{*{20}c} x^T(t)& \gamma_1^T(t) & \gamma_2^T(t) & \cdots & \gamma_N^T(t)\\ \end{array}} \right]^T , \end{array}$

$\gamma_1(t) = \left[ {\begin{array}{*{20}c} \int_{t-\frac{1}{m}h}^{t} x(s)ds\\ \int_{t-\frac{2}{m}h}^{t-\frac{1}{m}h} x(s)ds \\ \vdots \\ \int_{t-h}^{t-\frac{m-1}{m}h} x(s)ds \end{array}} \right],\; \; \gamma_2(t) = \frac{m}{h} \left[ {\begin{array}{*{20}c} \int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t} x(s)dsdu_1\\ \int_{t-\frac{2}{m}h}^{t-\frac{1}{m}h}\int_{u_1}^{t-\frac{1}{m}h} x(s)dsdu_1 \\ \vdots \\ \int_{t-h}^{t-\frac{m-1}{m}h}\int_{u_1}^{t-\frac{m-1}{m}h} x(s)dsdu_1 \end{array}} \right], \cdots,$

$\gamma_N(t) = (\frac{m}{h})^{N-1}\times \left[ {\begin{array}{*{20}c} \int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t}\cdots\int_{u_{N-1}}^t x(s)dsdu_{N-1}\cdots d_{u_1}\\ \int_{t-\frac{2}{m}h}^{t-\frac{1}{m}h}\int_{u_1}^{t-\frac{1}{m}h}\cdots \int_{u_{N-1}}^{t-\frac{1}{m}h} x(s)dsdu_{N-1}\cdots d_{u_1}\\ \vdots \\ \int_{t-h}^{t-\frac{m-1}{m}h}\int_{u_1}^{t-\frac{m-1}{m}h} \cdots \int_{u_{N-1}}^{t-\frac{m-1}{m}h} x(s)dsdu_{N-1}\cdots d_{u_1} \end{array}} \right],$

$\gamma(s) = \left[ {\begin{array}{*{20}c} x(s)\\ x(s-\frac{1}{m}h)\\ \vdots \\ x(s-\frac{m-1}{m}h) \end{array}} \right].$

The derivative of $V(x_t)$ is given by

$\begin{equation*} \label{eq:a1} \begin{split} \dot V(x_t) = &2\eta^T(t)P\dot \eta(t)+\gamma^T(t)Q\gamma(t)-\gamma^T(t-\frac{h}{m})Qx(t-\frac{h}{m})\\&+\sum\limits_{i = 1}^m{(\frac{h}{m})^2}\dot x^T(t)R_i\dot x(t)-\sum\limits_{i = 1}^m{\frac{h}{m}}\int_{t-\frac{i}{m}h}^{t-\frac{i-1}{m}h}\dot x^T(s)R_i\dot x(s)ds. \end{split} \end{equation*}$

Then, one can obtain

$\begin{equation} \begin{split} \dot V(x_t) = &\phi^T(t)\left\{ {\xi_1^TP\xi_2+\xi_2^TP\xi_1+\xi_3^TQ\xi_3-\xi_4^TQ\xi_4} {+\sum\limits_{i = 1}^m(\frac{h}{m})^2A_d^TR_iA_d} \right\}\phi(t) \\&-\sum\limits_{i = 1}^m{\frac{h}{m}}\int_{t-\frac{i}{m}h}^{t-\frac{i-1}{m}h}\dot x^T(s)R_i\dot x(s)ds, \end{split} \end{equation}$

(3.4)

$\begin{array}{l} \phi(t) = \left[ {\begin{array}{*{20}c} x^T(t)& \gamma_0^T(t) & \gamma_1^T(t) & \cdots & \gamma_N^T(t)\\ \end{array}} \right]^T , \end{array}$

$\begin{array}{l} \gamma_0(t) = \left[ {\begin{array}{*{20}c} x^T(t-\frac{1}{m}h)& x^T(t-\frac{2}{m}h) & \cdots &x^T(t-h)\\ \end{array}} \right]^T . \end{array}$

By Lemma 2.1, one can obtain

$\begin{equation} \begin{split} -{\frac{h}{m}}\int_{t-\frac{i}{m}h}^{t-\frac{i-1}{m}h}\dot x^T(s)R_i\dot x(s)ds \le -\sum\limits_{l = 0}^r\rho_l\omega_l(t-\frac{i}{m}h, t-\frac{i-1}{m}h)R_i\times\omega_l(t-\frac{i}{m}h, t-\frac{i-1}{m}h). \end{split} \end{equation}$

(3.5)

Thus, we have $\dot V(x_t)\le \phi^T(t)\Psi \phi(t)$ by (3.4) and (3.5). We complete the proof.

$\bf {Remark\; 3.1.}$ An augmented LKF which contains general multiple integral terms is introduced to reduce the conservatism via a generalized delay partitioning approach. For example, the $\int_{t-\frac{1}{m}h}^{t} x(s)ds$ , $\int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t} x(s)dsdu_1$ , $\cdots$ , $\int_{t-\frac{1}{m}h}^{t}\int_{u_1}^{t}\cdots\int_{u_{N-1}}^t x(s)dsdu_{N-1}\cdots d_{u_1}$ are added as state vectors in the LKF, which may reduce the conservatism.

$\bf {Remark\; 3.2.}$ For $r = 0, 1, 2, 3$ , the integral inequality (3.5) includes those in ^{[12,15,21,22]} as special cases, respectively. This may yield less conservative results. It is worth noting that the number of variables in our result is less than that in ^[23].

$\bf {Remark\; 3.3.}$ Let $B_2 = 0$ , the system (2.1) can reduces to system (1) with $N = 1$ in ^[23]. For $m = 1$ , the LKF in this paper can reduces to LKF in ^[23]. So the LKF in our paper is more general than that in ^[23].

4. Numerical examples

This section gives a numerical example to test merits of our criterion.

Example 4.1. Consider system (2.1) with $m = 2, \; N = 3$ and

$A = \left[ {\begin{array}{*{20}c} 0 &1 \\ -100&-1 \\ \end{array}} \right],\; B_1 = \left[ {\begin{array}{*{20}c} 0.0&0.1 \\ 0.1 &0.2\\ \end{array}} \right],\; B_2 = \left[ {\begin{array}{*{20}c} 0&0 \\ 0 &0\\ \end{array}} \right].$

lists upper bounds of $h$ by our methods and other methods in ^{[15,20,21,22,23]}. Table 1 shows that our method is more effective than those in ^{[15,20,21,22,23]}. It is worth noting that the number of variables in our result is less than that in ^[23]. Furthermore, let $h = 1.141$ and $x(0) = [0.2, -0.2]^T$ , the state responses of system (1) are given in Figure 1. Figure 1 shows the system (2.1) is stable.

Table 1.

$h_{max}$ for different methods.

Methods	$h_{max}$	NoDv
^[15]	0.126	16
^[20]	0.577	75
^[21]	0.675	45
^[22]	0.728	45
^[23]	0.752	84
Theorem 3.1	1.141	71
Theoretical maximal value	1.463	$-$

| Show Table

DownLoad: CSV

Figure 1. The state trajectories of the system (2.1) of Example 4.1.

DownLoad: Full-Size Img PowerPoint

5. Conclusions

In this paper, a new LKF is introduced via the delay partitioning method. Then, a less conservative stability criterion is obtained by using the further improvement of Jensen inequality. Finally, an example is provided to show the advantage of our stability criterion.

Acknowledgments

This work was supported by Basic Research Program of Guizhou Province (Qian Ke He JiChu[2021]YiBan 005); New Academic Talents and Innovation Program of Guizhou Province (Qian Ke He Pingtai Rencai[2017]5727-19); Project of Youth Science and Technology Talents of Guizhou Province (Qian Jiao He KY Zi[2020]095).

Conflict of interest

The authors declare that there are no conflicts of interest.

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Contribution of a Ca²⁺-activated K⁺ channel to neuronal bursting activities in the Chay model

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Contribution of a Ca2+-activated K+ channel to neuronal bursting activities in the Chay model

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Contribution of a Ca²⁺-activated K⁺ channel to neuronal bursting activities in the Chay model