The value of urinary soluble urokinase plasminogen activator receptor (suPAR) in children with nephrotic syndrome

Phuong Anh Le Thy; Kiem Hao Tran; Thuy Yen Hoang Thi; Minh Phuong Phan Thi; Huu Son Nguyen; Phuong Anh Le Thy; Kiem Hao Tran; Thuy Yen Hoang Thi; Minh Phuong Phan Thi; Huu Son Nguyen

doi:10.3934/medsci.2021015

AIMS Medical Science

2021, Volume 8, Issue 2: 163-174. doi: 10.3934/medsci.2021015

Previous Article Next Article

Research article

The value of urinary soluble urokinase plasminogen activator receptor (suPAR) in children with nephrotic syndrome

1.
Pediatric Department, Hue University of Medicine and Pharmacy, Hue University, Hue city, Vietnam
2.
Pediatric Center, Hue Central hospital, 16 Le Loi street, Hue city, Vietnam

Received: 19 April 2021 Accepted: 14 June 2021 Published: 17 June 2021

Objectives

To investigate the value of urinary suPAR with steroid responsiveness in childhood nephrotic syndrome (NS).

Methods

A longitudinal follow-up study was carried out in 92 children diagnosed with nephrotic syndrome (49 initial NS and 43 relapsed NS).

Results

The urinary suPAR/creatinine ratio was significantly high in the relapsed NS group (with a mean = 628 (386–1015) pg/µmol) compared with the initial NS group (mean = 509 (237–840) pg/µmol) and the control group (mean = 248 (88–609) pg/µmol) (p = 0.001). In the initial group, the concentration of urinary suPAR/creatinine ratio was higher in steroid-resistant NS (SRNS) than in steroid-sensitive NS (SSNS) after 6 weeks and 6 months of treatment, but the difference was not significant (p > 0.05). In the relapsed NS group, the concentration of urinary suPAR/creatinine ratio was higher in SRNS than that in SSNS (p = 0.02). The urinary suPAR/creatinine ratio had sensitivity (73.9%) and specificity (89.5%) at the cut-off point of 950 pg/µmol to predict SRNS (p < 0.001).

Conclusions

Urinary suPAR could help distinguish the steroid responsiveness between SRNS and SSNS in children.

Keywords:

soluble urokinase plasminogen activator (suPAR),
nephrotic syndrome,
urinary suPAR/creatinine ratio

Citation: Phuong Anh Le Thy, Kiem Hao Tran, Thuy Yen Hoang Thi, Minh Phuong Phan Thi, Huu Son Nguyen. The value of urinary soluble urokinase plasminogen activator receptor (suPAR) in children with nephrotic syndrome[J]. AIMS Medical Science, 2021, 8(2): 163-174. doi: 10.3934/medsci.2021015

Related Papers:

[1]	Jing Huang, Qian Wang, Rui Zhang . On a binary Diophantine inequality involving prime numbers. AIMS Mathematics, 2024, 9(4): 8371-8385. doi: 10.3934/math.2024407
[2]	Jing Huang, Ao Han, Huafeng Liu . On a Diophantine equation with prime variables. AIMS Mathematics, 2021, 6(9): 9602-9618. doi: 10.3934/math.2021559
[3]	Bingzhou Chen, Jiagui Luo . On the Diophantine equations $x^2-Dy^2=-1$ and $x^2-Dy^2=4$. AIMS Mathematics, 2019, 4(4): 1170-1180. doi: 10.3934/math.2019.4.1170
[4]	Jing Huang, Wenguang Zhai, Deyu Zhang . On a Diophantine equation with four prime variables. AIMS Mathematics, 2025, 10(6): 14488-14501. doi: 10.3934/math.2025652
[5]	Hunar Sherzad Taher, Saroj Kumar Dash . Repdigits base $ \eta $ as sum or product of Perrin and Padovan numbers. AIMS Mathematics, 2024, 9(8): 20173-20192. doi: 10.3934/math.2024983
[6]	Liuying Wu . On a Diophantine equation involving fractional powers with primes of special types. AIMS Mathematics, 2024, 9(6): 16486-16505. doi: 10.3934/math.2024799
[7]	Ashraf Al-Quran . T-spherical linear Diophantine fuzzy aggregation operators for multiple attribute decision-making. AIMS Mathematics, 2023, 8(5): 12257-12286. doi: 10.3934/math.2023618
[8]	Cheng Feng, Jiagui Luo . On the exponential Diophantine equation $ \left(\frac{q^{2l}-p^{2k}}{2}n\right)^x+(p^kq^ln)^y = \left(\frac{q^{2l}+p^{2k}}{2}n\right)^z $. AIMS Mathematics, 2022, 7(5): 8609-8621. doi: 10.3934/math.2022481
[9]	Jinyan He, Jiagui Luo, Shuanglin Fei . On the exponential Diophantine equation $ (a(a-l)m^{2}+1)^{x}+(alm^{2}-1)^{y} = (am)^{z} $. AIMS Mathematics, 2022, 7(4): 7187-7198. doi: 10.3934/math.2022401
[10]	Sohail Ahmad, Ponam Basharat, Saleem Abdullah, Thongchai Botmart, Anuwat Jirawattanapanit . MABAC under non-linear diophantine fuzzy numbers: A new approach for emergency decision support systems. AIMS Mathematics, 2022, 7(10): 17699-17736. doi: 10.3934/math.2022975

Abstract

Objectives

To investigate the value of urinary suPAR with steroid responsiveness in childhood nephrotic syndrome (NS).

Methods

A longitudinal follow-up study was carried out in 92 children diagnosed with nephrotic syndrome (49 initial NS and 43 relapsed NS).

Results

Conclusions

Urinary suPAR could help distinguish the steroid responsiveness between SRNS and SSNS in children.

1. Introduction

In many areas of the objective world, such as target tracking, machine learning system identification, associative memories, pattern recognition, solving optimization problems, image processing, signal processing, and so on ^[1,2,3,4,5], a lot of practical problems can be described by delay differential equations (DDEs). Therefore, the research of delay differential equations has been the subject of significant attention ^[6,7]. As we all know, time delays are inevitable in population dynamics models. For example, the maturation period should be considered in the study of simulated biological species ^[8,9], incubation periods should be considered in epidemiology area ^[7], and the synaptic transmission time among neurons should be considered in neuroscience field ^[10]. In particular, the dynamic behavior of most cellular neural network models is significantly affected by time delay, so the investigation on delayed cellular neural networks has been the world-wide focus.

It should be mentioned that proportional delay is one of important time-varying delays, which is unbounded and monotonically increasing, and is more predictable and controllable than constant delay and bounded time-varying delay. Over past decade, by introducing proportional time delay, investigations of the following neutral type proportional delayed cellular neural networks (CNNs) with D operators:

$\begin{align*} [x _{i} (t)-p_{i}(t)x_{i}( r _{i} t )]' = \; & -a_{i}(t) x_{i}(t )+ \sum\limits_{j = 1}^{n}e_{ij}(t)f_{j}(x_{j}(t ))+ \sum\limits_{j = 1}^{n}b_{ij}(t)g_{j}(x_{j}(q_{ij}t))+I_{i}(t), \\ & t\geq t_{0} \gt 0, \ i\in N = \{1, 2, \cdots, n\}, \end{align*}$

(1.1)

with initial value conditions:

$\begin{align*} x_{i}(s) = \varphi_{i}(s), \ s\in [\rho_{i}t_{0}, \ t_{0}], \ \varphi _{i }\in C([\rho_{i}t_{0}, \ t_{0}], \mathbb{R}) , \ \rho_{i} = \min \{r_i, \min\limits _{1 \leq j\leq n }\{q_{ ij }\}\}, \ i\in N, \end{align*}$

(1.2)

have attracted great attention of some researchers. The main reason is that its successful applications in variety of areas such as optimization, associative memories, signal processing, automatic control engineering and so on (see ^{[11,12,13,14,15]} and the references therein). Here $n$ is the number of units in a neural network, $(x_{1}(t), x_{2}(t), \cdots, x_{n}(t))^T$ corresponds to the state vector, the decay rate at time $t$ is designated by $a_{i}(t)$ , coefficients $p_{i}(t)$ , $e_{ij}(t)$ and $b_{ij}(t)$ are the connection weights at the time $t$ , $f_{j}$ and $g_{j}$ are the activation functions of signal transmission, $r_{i}(t)\geq 0$ denotes the transmission delay, $r_{i}$ and $q _{ij}$ are proportional delay factors and satisfy $0 < r_{i}, \ q _{ij} < 1$ , $I_{i}(t)$ is outside input.

As pointed out by the authors of reference ^[16], the weighted pseudo almost periodic function consists of an almost periodic process plus a weighted ergodic component. It is well known that the weighted pseudo-almost periodic phenomenon is more common in the environment than the periodic, almost periodic and pseudo-almost periodic phenomenon, so the dynamic analysis of the weighted pseudo-almost periodic is more realistic ^{[17,18,19,20]}. Furthermore, when $p_{i}(t)\equiv 0$ , the existence and exponential stability of weighted pseudo almost periodic solutions (WPAPS) of proportional delayed cellular neural networks (CNNs)

$\begin{align*} x _{i} '(t) = -a_{i}(t) x_{i}(t )+ \sum\limits_{j = 1}^{n}e_{ij}(t)f_{j}(x_{j}(t ))+ \sum\limits_{j = 1}^{n}b_{ij}(t)g_{j}(x_{j}(q_{ij}t))+I_{i}(t), { \ t\geq t_{0} \gt 0, \ i\in N }, \end{align*}$

(1.3)

have been established in ^[22] under the following conditions

$\begin{align*} {\sup\limits_{t\in \mathbb{R}}\bigg\{-\tilde{a}_{i} (t)+K_{i}\bigg[ \xi^{-1}_{i}\sum^n_{j = 1}(| e_{ij}(t)| L^{f}_{j} +| b_{ij}(t)| L^{g}_{j} )\xi_{j} \bigg]\bigg\} \lt -\gamma_{i} }. \end{align*}$

(1.4)

{Here, for $i\in N$ , $\tilde{a}_{i} \in C(\mathbb{R}, \ (0, \ +\infty))$ is a bounded function, and $K_{i} > 0$ is a constant with

$e ^{ -\int_{s}^{t}a_{i}(u)du}\leq K_{i} e ^{ -\int_{s}^{t}\tilde{a}_{i}(u)du} \ \ \ \mbox{for all } \ t, s\in \mathbb{R} \ \mbox{ and } \ t-s\geq 0.$

In addition, $f_{j}$ and $g_{j}$ are the activation functions with Lipschitz constants $L^{f}_{j}$ and $L^{g}_{j}$ obeying

$|f_{j}(u )-f_{j}(v )|\leq L ^{f}_{j}|u -v |, \ \ |g_{j}(u )-g_{j}(v )| \leq L^{g}_{j}|u -v | \ \ \ \mbox{for all} \ u , v \in \mathbb{R}, \ i\in N.$

} It should be mentioned that the authors in ^[22] use (1.4) to show that there exists a constant $\lambda \in (0, \min\limits_{i\in N}\tilde{a}_{i} ^{-})$ such that

$\begin{align*} \Pi_{i}(\lambda) = { \sup\limits_{t\in \mathbb{R}}\bigg\{\lambda-\tilde{a}_{i}(t)+K_{i}\bigg[ \xi^{-1}_{i}\sum^n_{j = 1}(| e_{ij}(t)| L^{f}_{j} + | b_{ij}(t)| L^{g}_{j}e^{ \lambda (1-q_{ij}) t } )\xi_{j} \bigg]\bigg\}} \lt 0, \ i\in N. \end{align*}$

(1.5)

With the aid of the fact that $\lim\limits_{t\rightarrow +\infty}e^{ \lambda (1-q_{ij}) t} = +\infty$ , it is easy to see that (1.4) can not lead to (1.5). Meanwhile, Examples 4.1 and 4.2 in ^[22] also have the same error, where

$b _{ij}(t) = \frac{1}{10(i+j)} \sin 2t, \ i, j = 1, 2,$

and

$\left.\begin{array}{ll} b _{1j}(t) = \frac{1}{100}(\cos (1+j) t ), b _{2j}(t) = \frac{1}{100}(\cos (1+j) t +\cos \sqrt{2} t), \\ b _{3j}(t) = \frac{1}{100}(\cos (1+j) t +\sin \sqrt{2} t), \end{array}\right\}j = 1, 2, 3,$

can not also meet (1.5). For detail, the biological explanations on equations (1.4) and (1.5) can be found in ^[22]. Now, in order to improve ^[22], we will further study the existence and exponential stability of weighted pseudo almost periodic solutions for (1.1) which includes (1.3) as a special case. Moreover, this class of models has not been touched in the existing literature.

On account of the above considerations, in this article, we are to handle the existence and generalized exponential stability of weighted pseudo almost periodic solutions for system (1.1). Readers can find the following Remark 2.1 for extensive information. In a nutshell, the contributions of this paper can be summarized as follows. 1) A class of weighted pseudo almost periodic cellular neural network model with neutral proportional delay is proposed; 2) Our findings not only correct the errors in ^[22], but also improve and complement the existing conclusions in the recent publications ^[22,23]; 3) Numerical simulations including comparison analyses are presented to verify the obtained theoretical results.

The remainder of the paper is organized as follows. We present the basic notations and assumptions in Section 2. The existence and exponential stability of weighted pseudo almost periodic solutions for the addressed neural networks models are proposed in Section 3. The validity of the proposed method is demonstrated in Section 4, and conclusions are drawn in Section 5.

2. Notations and assumptions

Notations. $\mathbb{R}$ and $\mathbb{R}^n$ denote the set of real numbers and the $n$ -dimensional real spaces. For any $x = \{x_{ij}\}\in\mathbb{R}^{mn}$ , let $|x|$ denote the absolute value vector given by $|x| = \{|x_{ij}|\}$ , and define $\|x\| = \max\limits_{ij\in J}|x_{ij}(t)|$ . Given a bounded continuous function $h$ defined on $\mathbb{R}$ , let $h^{+} = \sup\limits_{t\in \mathbb{R}}|h(t)|, \ h^{-} = \inf\limits_{t\in \mathbb{R}}|h(t)|$ . We define $\mathbb{U}$ be the collection of functions (weights) $\mu : \mathbb{R}\rightarrow (0, +\infty)$ satisfying

$\mathbb{U}_{\infty}: = \bigg\{\mu \ |\ \mu\in \mathbb{U}, \inf\limits_{x\in \mathbb{R}}\mu(x) = \mu_{0} \gt 0 \bigg\},$

and

$\mathbb{U}^{+}_{\infty}: = \bigg\{\mu |\mu\in \mathbb{U} _{\infty}, \limsup\limits_{|x|\rightarrow +\infty}\frac{\mu(\alpha x)}{\mu(x)} \lt +\infty, \limsup\limits_{r\rightarrow +\infty}\frac{\mu([-\alpha r, \ \alpha r])}{\mu([-r, \ r])} \lt +\infty, \ \forall \alpha \in (0, +\infty) \bigg\}.$

Let $BC(\mathbb{R}, \mathbb{R}^{n})$ denote the collection of bounded and continuous functions from $\mathbb{R}$ to $\mathbb{R}^{n}$ . Then $(BC(\mathbb{R}, \mathbb{R}^{n}), \|\cdot\|_{\infty})$ is a Banach space, where $\|f\|_{\infty} : = \sup\limits_{ t\in \mathbb{R}} \|f (t)\|$ . Also, this set of the almost periodic functions from $\mathbb{R}$ to $\mathbb{R}^{n}$ will be designated by $AP(\mathbb{R}, \mathbb{R}^{n})$ . Furthermore, the class of functions $PAP_{0}^{\mu}(\mathbb{R}, \mathbb{R}^{n})$ be defined as

$PAP_{0}^{\mu}(\mathbb{R}, \mathbb{R}^{n}) = {\Big\{\varphi\in BC(\mathbb{R}, \mathbb{R}^{n})|\lim\limits_{r\rightarrow+\infty}\frac{1}{\mu([-r, \ r])}\int_{-r}^{r}\mu(t)|\varphi(t)|dt = \bf{0}\Big\}}.$

A function $f\in{BC(\mathbb{R}, \mathbb{R}^{n})}$ is said to be weighted pseudo almost periodic if there exist $h\in{AP(\mathbb{R}, \mathbb{R}^{n})}$ and $\varphi\in{PAP_{0}^{\mu}(\mathbb{R}, \mathbb{R}^{n})}$ satisfying

$f = h+\varphi,$

where $h$ and $\varphi$ are called the almost periodic component and the weighted ergodic perturbation of weighted pseudo almost periodic function $f$ , respectively. We designate the collection of such functions by $PAP^{\mu}(\mathbb{R}, \mathbb{R}^{n}).$ In addition, fixed $\mu\in \mathbb{U}^{+}_{\infty}$ , $(PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n}), \|.\|_{\infty})$ is a Banach space and $AP (\mathbb{R}, \mathbb{R}^{n})$ is a proper subspace of $PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ . For more details about the above definitions can be available from ^[17,18] and the references cited therein.

In what follows, for $i, j\in N,$ we shall always assume that $\ e_{ij }, b_{ij}, p_i, I_{i} \in PAP^{\mu}(\mathbb{R}, \mathbb{R})$ , and

$\begin{align*} a_{i }\in AP(\mathbb{R}, \mathbb{R} ), \ \ M[a_{i }] = \lim\limits_{T\rightarrow+\infty}\frac{1}{T}\int_{t}^{t+T}a_{i }(s)ds \gt 0. \end{align*}$

(2.1)

For $i, j \in N$ , we also make the following technical assumptions:

$(H_1)$ there are a positive function $\tilde{a}_{i} \in BC(\mathbb{R}, \mathbb{R})$ and a constant $K_{i} > 0$ satisfying

$e ^{ -\int_{s}^{t}a_{i}(u)du}\leq K_{i} e ^{ -\int_{s}^{t}\tilde{a}_{i}(u)du} \ \ \ \mbox{for all} \ t, s\in \mathbb{R} \ \mbox{ and } \ t-s\geq 0.$

$(H_2)$ there exist nonnegative constants $L^{f}_{j}$ and $L^{g}_{j}$ such that

$|f_{j}(u )-f_{j}(v )|\leq L ^{f}_{j}|u -v |, |g_{j}(u )-g_{j}(v )| \leq L^{g}_{j}|u -v | \ \ \ \mbox{for all} \ u , v \in \mathbb{R}.$

$(H_3)$ $\mu \in \mathbb{U}^{+}_{\infty}$ , we can find constants $\xi_{i} > 0$ and $\Lambda_{i} > 0$ such that

$\begin{align*} \sup\limits_{t\in\mathbb{ R}} \frac{1}{\tilde{a}_{i}(t)} K_{i} [|a_{i}(t)p_{i}(t)| +\xi_{i}^{-1}\sum^n_{j = 1} (|e_{ij} (t)| L^{f}_{j}+|b_{ij} (t)|L^{g}_{j}) \xi_{j} ] \lt \Lambda_{i}, \end{align*}$

$\begin{eqnarray*} &\sup\limits_{t\geq t_{0}} \{ -\tilde{a}_{i}(t)+K_{i} [| a_i(t)p_i(t)|\frac{1 }{1- p_{i} ^{+} } +\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(t)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} } \\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(t)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} }] \} \lt 0, \end{eqnarray*}$

and

$p_{i} ^{+}+\Lambda_{i} \lt 1, \ i\in N.$

Remark 2.1. From $(H_1)$ and $(H_2)$ , one can use an argument similar to that applied in Lemma 2.1 of ^[24] to demonstrate that every solution of initial value problem (1.1) and (1.2) is unique and exists on $[t_{0}, \ +\infty).$

3. Results

In this section, we will establish some results about the global generalized exponential stability of the weighted pseudo almost periodic solutions of (1.1). To do this end, we first show the following Lemma.

Lemma 3.1. (see[^[22], Lemma 2.1]). Assume that $f\in PAP^{ \mu}(\mathbb{R}, \mathbb{R})$ and $\beta \in \mathbb{R}\setminus \{0\}$ . Then, $f(\beta t)\in PAP^{\mu}(\mathbb{R}, \mathbb{R}).$

Using a similar way to that in lemma 2.3 of ^[22], we can show the following lemma:

Lemma 3.2. Assume that $(H_{1})$ and $(H_{2})$ hold. Then, the nonlinear operator $G$ :

$\begin{align*} (G\varphi)_{i}(t) = &\int_{-\infty}^{t}e^{-\int_{s}^{t}a_{i}(u)du}[-a_i(s)p_i(s)\varphi_i( r_i s )+\xi^{-1}_{i}\sum^n_{j = 1}e_{ij}(s)f_{j}(\xi_{j}\varphi_{j}(s ))\\ & + \xi^{-1}_{i}\sum^n_{j = 1}b_{ij}(s)g_{j}(\xi_{j}\varphi_{j}(q_{ij}s))+\xi^{-1}_{i}I_{i}(s)]ds, \ i\in N, \ \varphi \in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n}), \end{align*}$

maps $PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ into itself.

Theorem 3.1. Suppose that $(H_{1})$ , $(H_{2})$ and $(H_{3})$ are satisfied. Then, system (1.1) has exactly one WPAPS $x^{*}(t)\in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ , which is globally generalized exponentially stable, that is, for every solution $x(t)$ agreeing with $(1.1)-(1.2)$ , there exists a constant $\sigma\in (0, \min\limits_{i\in N}\tilde{a}_{i}^{-})$ such that

$x_{ i }(t) -x^{*}_{i}(t) = O( (\frac{1}{1+t})^{\sigma}) \ \mbox{ as} \ t\rightarrow +\infty \ \ \ \mbox{for all} \ i\in N.$

Proof. With the help of $(H_{3})$ , it is easy to see that there are constants $\sigma, \lambda \in (0, \ \min\limits_{i\in N}\tilde{a}_{i} ^{-})$ such that

$\begin{align*} p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } } \lt 1, \ \sup\limits_{t\in \mathbb{R}} \frac{e^{\lambda }}{\tilde{a}_{i}(t)} K_{i} [|a_{i}(t)p_{i}(t)| +\xi_{i}^{-1}\sum^n_{j = 1} (|e_{ij} (t)| L^{f}_{j}+|b_{ij} (t)|L^{g}_{j}) \xi_{j} ] \lt \Lambda_{i}, \ i\in N, \end{align*}$

(3.1)

and

$\begin{align*} &\sup\limits_{t\geq t_{0}} \{ \sigma -\tilde{a}_{i}(t)+K_{i} [| a_i(t)p_i(t)|\frac{1 }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{ \sigma\ln \frac{1 }{ r_{i} } } +\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(t)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }} \\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(t)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{\sigma \ln(\frac{1 }{ q_{ij} })}] \} \lt 0 , \ i\in N, \end{align*}$

(3.2)

which, along with the inequalities

$\frac{\sigma }{1+t}\leq \sigma, \ \ln(\frac{1+t}{1+r_{i }t})\leq \ln\frac{1}{r_{i }} , \ \ln(\frac{1+t}{1+q_{ij}t})\leq \ln\frac{1}{q_{ij}} \ \ \mbox{for all} \ t\geq 0, \ i, j\in N,$

yield

$\begin{align*} &\sup\limits_{t\geq t_{0} }\bigg\{ \frac{\sigma }{1+t}-\tilde{a}_{i}(t)+K_{i} [| a_i(t)p_i(t)|\frac{1 }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{ \sigma\ln \frac{1+ s}{1+r_{i}t} }\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(t)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(t)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{\sigma \ln(\frac{1+t}{1+q_{ij}t})}]\bigg\}\\ \leq\; & \sup\limits_{t\geq t_{0}}\bigg\{ \sigma -\tilde{a}_{i}(t)+K_{i} [| a_i(t)p_i(t)|\frac{1 }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{ \sigma\ln \frac{1 }{ r_{i} } }\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(t)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }} \\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(t)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{\sigma \ln(\frac{1 }{ q_{ij} })}]\bigg\} \lt 0 , \ i\in N. \end{align*}$

(3.3)

Consequently, applying a transformation:

$y_{i}(t) = \xi^{-1}_{i}x_{i}(t), \ Y_{i}(t) = y_{i} (t)-p_{i}(t)y_{i} ( r_{i} t ), \ i\in N,$

leads to

$\begin{align*} Y_{i}'(t) = & -a_{i}(t)Y_{i}(t )-a_i(t)p_i(t)y_i( r_i t )+ \xi^{-1}_{i}\sum\limits_{j = 1}^{n}e_{ij}(t)f_{j}(\xi_{j}y_{j}(t ))\\ &+ \xi^{-1}_{i}\sum\limits_{j = 1}^{n}b_{ij}(t)g_{j}(\xi_{j}y_{j}(q_{ij}t)) + \xi^{-1}_{i}I_{i}(t) , \ i\in N. \end{align*}$

(3.4)

Now, define a mapping $P: PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})\rightarrow PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ by setting

$\begin{align*} (P\varphi)_{i}(t) = p_i(t)\varphi_i(r_it) +(G\varphi)_{i}(t) \ \ \ \mbox{for all} \ i\in N, \ \varphi \in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n}), \end{align*}$

(3.5)

it follows from Lemma 3.1 and Lemma 3.2 that $P\varphi \in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ .

Moreover, by means of $(H_{1})$ , $(H_{2})$ and $(H_{3})$ , for $\varphi, \psi \in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ , we have

$\begin{align*} & | (P \varphi)_{i}(t) -(P \psi)_{i}(t) | \\ = \; & |p_i(t)[\varphi_i( r_i t )-\psi_i( r_i t )]+\int_{-\infty}^{t}e^{-\int_{s}^{t}a_{i}(u)du}[ \xi^{-1}_{i}\sum^n_{j = 1}e_{ij}(s)(f_{j}(\xi_{j}\varphi_{j}(s))-f_{j}(\xi_{j}\psi_{j}(s)))\\ &+ \xi^{-1}_{i}\sum^n_{j = 1}b_{ij}(s)(g_{j}(\xi_{j}\varphi_{j}(q_{ij}s))-g_{j}(\xi_{j}\psi_{j}(q_{ij}s))) ]ds| \\ \leq\; & \{p_i^+ +\int^t_{-\infty }e^{-\int_{s}^{t}\tilde{a}_{i} (u)du}K_{i} [ \xi^{-1}_{i}\sum^n_{j = 1}(| e_{ij}(s)| L^{f}_{j} +| b_{ij}(s)| L^{g}_{j})\xi_{j}]ds\} \|\varphi(t)-\psi(t)\|_{\infty} \\ \leq \; & \{p_i+\Lambda_i \int^t_{-\infty }e^{-\int_{s}^{t}\tilde{a}_{i} (u)du} \frac{1}{e^\lambda} \tilde{a}_{i} (s) ds\} \|\varphi(t)-\psi(t)\|_{\infty} \\ \leq\; & \{p_i+\Lambda_i \frac{1}{e^\lambda}\} \|\varphi(t)-\psi(t)\|_{\infty} , \end{align*}$

which and the fact that $0 < \max\limits_{ i \in N}\{ p_i^++\Lambda_i\} < 1$ suggest that the contraction mapping $P$ possesses a unique fixed point

$y^{*} = \{y_{i}^{*}(t)\}\in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n}), \ P y^{* } = y^{* }.$

Thus, (1.5) and (3.5) entail that $x^{* } = \{x_{i}^{* }(t)\} = \{\xi_{i}y_{i}^{*}(t)\}\in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ is a weighted pseudo almost periodic solution of (1.1).

Finally, we demonstrate that $x^{* }$ is exponentially stable.

Designate $x(t) = \{x_{i}(t)\}$ be an arbitrary solution of (1.1) with initial value $\varphi(t) = \{\varphi_{i}(t)\}$ satisfying $(1.2).$

Label

$\begin{align*} x_{i}(t) = \varphi_{i}(t) = \varphi_{i}(\sigma_{i}t_{0}), \ \mbox{for all } \ t\in [r_{i}\sigma_{i}t_{0}, \ \sigma_{i}t_{0}], \ \end{align*}$

(3.6)

$y_{i} (t) = \xi^{-1}_{i}x_{i} (t), \ y_{i}^*(t) = \xi^{-1}_{i}x_{i}^*(t), z_i(t) = y_{i}(t)-y^{*}_{i}(t)), Z_i(t) = z_{i} (t)-p_{i}(t)z_{i} ( r_{i} t ), \ i\in N.$

Then

$\begin{align*} Z_{i}'(t) = \; &-a_{i}(t)Z_i (t )-a_i(t)p_i(t)z_i(r_it)+\xi_{i}^{-1}\sum^n_{j = 1}e_{ij}(t) (f_{j}( \xi_j y_{j}(t)) -f_{j}(\xi_j y^{*}_{j}(t)))\\ &+\xi_{i}^{-1}\sum^n_{j = 1}b_{ij}(t) (g_{j}(\xi_j y_{j}(q_{ij}t)) -g_{j}(\xi_j y^{*}_{j}(q_{ij}t))) , \ i\in N. \end{align*}$

(3.7)

Without loss of generality, let

$\begin{align*} \|\varphi-x^{*}\|_{\xi} = \max\limits_{i\in N }\{\sup\limits_{t\in [\rho_{i}t_{0}, t_{0}] }\xi_{i}^{-1}|[\varphi_{i} (t)-p_i(t)\varphi_i( r_i t )] -[x^{*}_{i}(t)-p_i(t)x_i^*( r_i t )]|\} \gt 0, \end{align*}$

(3.8)

and $M$ be a constant such that

$\begin{align*} M \gt \sum\limits_{i = 1}^{N}K_{i}+1 . \end{align*}$

(3.9)

Consequently, for any $\varepsilon > 0$ , it is obvious that

$\begin{align*} |Z_{i}(t) | \lt M(\|\varphi-x^{*}\|_{\xi}+\varepsilon)e^{-\sigma\ln \frac{1+ t}{1+t_{0}} } \ \mbox{ for all } \ t \in(\rho_{i}t_{0} , \ t_{0}], \ i\in N. \end{align*}$

(3.10)

Now, we validate that

$\begin{align*} \|Z(t)\| \lt M(\|\varphi-x^{*}\|_{\xi}+\varepsilon)e^{-\sigma\ln \frac{1+ t}{1+t_{0}} } \ \mbox{ for all } \ t \gt t_{0} . \end{align*}$

(3.11)

Otherwise, there must exist $i \in N$ and $\theta > t_{0}$ such that

$\begin{align*} \left\{ \begin{array}{rcl} |Z_{i}(\theta)| & = & M(\|\varphi-x^{*}\|_{\xi}+\varepsilon)e^{-\sigma\ln \frac{1+ \theta}{1+t_{0}} }, \ \ \\ \ \|Z(t)\| & \lt &M(\|\varphi-x^{*}\|_{\xi}+\varepsilon)e^{-\sigma\ln \frac{1+ t}{1+t_{0}} } \ \mbox{ for all } \ t \in(\rho_{i} t_{0} , \ \theta). \end{array} \right. \end{align*}$

(3.12)

Furthermore, from (3.6), we obtain

$\begin{align*} e^{\sigma\ln \frac{1+ \nu}{1+t_{0}} }|z_{j} (\nu)| \leq\; & e^{\sigma\ln \frac{1+ \nu}{1+t_{0}} }|z_{j} (\nu)- p_{j}(\nu)z_{j} ( r_{j} \nu )| +e^{\sigma\ln \frac{1+ \nu}{1+t_{0}} }| p_{j}(\nu)z_{j} ( r_{j} \nu )| \\ \leq\; & e^{\sigma\ln \frac{1+ \nu}{1+t_{0}} }|Z_{j} (\nu) |+ p_{j} ^{+} e^{\sigma\ln \frac{1+\nu}{1+ r_{j}\nu} }e^{\sigma\ln \frac{1+ r_{j}\nu}{1+t_{0}} }| z_{j} ( r_{j} \nu )| \\ \leq\; & M (\|\varphi-x^{*} \|_{\xi}+\varepsilon) + p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }\sup\limits_{s\in[r_{j}\rho_jt_0, \ r_{j}t]} e^{\sigma\ln \frac{1+ s}{1+t_{0}} }| z_{j} ( s )|\\ \leq\; & M (\|\varphi-x^{*} \|_{\xi}+\varepsilon) + p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }\sup\limits_{s\in[\rho_it_0, \ t]} e^{\sigma\ln \frac{1+ s}{1+t_{0}} }| z_{j} ( s )|, \end{align*}$

(3.13)

$\mbox{for all}\ \ \nu\in [\rho_jt_0, \ t], \ t \in[t_0, \ \theta), \ j\in J,$ which entails that

$\begin{align*} e^{\sigma\ln \frac{1+ t}{1+t_{0}} }|z_{j} (t)| \leq \sup\limits_{s\in[\rho_jt_0, \ t]} e^{\sigma\ln \frac{1+ s}{1+t_{0}} }| z_{j} ( s )|\leq \frac{M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}, \ \end{align*}$

(3.14)

$\mbox{for all} \ t \in[\rho_it_0, \ \theta), \ j\in N.$

Note that

$\begin{align*} &Z_{i}'(s)+a_{i}(s)Z_{i }(s ) \\ = \; & -a_i(s)p_i(s)z_i( r_i s )+\xi_{i}^{-1}\sum^n_{j = 1}e_{ij}(s) (f_{j}(\xi_jy_{j}(s)) -f_{j}(\xi_jy^{*}_{j}(s)))\\ &+\xi_{i}^{-1}\sum^n_{j = 1}b_{ij}(s) (g_{j}(\xi_j y_{j}(q_{ij}s)) -g_{j}(\xi_jy^{*}_{j}(q_{ij}s))), \ \ s\in [t_{0}, t], \ t\in [t_{0}, \theta]. \end{align*}$

(3.15)

Multiplying both sides of (3.15) by $e ^{\int_{t_{0}}^{s}a_{i}(u)du}$ , and integrating it on $[t_{0}, t]$ , we get

$\begin{align*} Z_{i}(t) = \; &Z_{i} (t_{0}) e ^{-\int_{t_{0}}^{t}a_{i}(u)du} + \int_{t_{0}}^{t}e ^{ -\int_{s}^{t}a_{i}(u)du}[ -a_i(s)p_i(s)z_i( r_i s )+\\ &\xi_{i}^{-1}\sum^n_{j = 1}e_{ij}(s) (f_{j}(\xi_jy_{j}(s)) -f_{j}(\xi_jy^{*}_{j}(s)))\\ &+\xi_{i}^{-1}\sum^n_{j = 1}b_{ij}(s)(g_{j}( \xi_jy_{j}(q_{ij}s)) -g_{j}(\xi_jy^{*}_{j}(q_{ij}s)))]ds, \ t\in [t_{0}, \theta]. \end{align*}$

Thus, with the help of (3.3), (3.9), (3.12) and (3.14), we have

$\begin{align*} |Z_{i} (\theta)| = \; &\bigg| Z_{i} (t_{0}) e ^{-\int_{t_{0}}^{\theta}a_{i}(u)du}+ \int_{t_{0}}^{\theta}e ^{ -\int_{s}^{\theta}a_{i}(u)du}[-a_i(s)p_i(s)z_i( r_i s )+\\ & \xi_{i}^{-1}\sum^n_{j = 1}e_{ij}(s) (f_{j}(\xi_jy_{j}(s)) -f_{j}(\xi_jy^{*}_{j}(s)))\\ &+\xi_{i}^{-1}\sum^n_{j = 1}b_{ij}(s) (g_{j}( \xi_jy_{j}(q_{ij}s)) -g_{j}(\xi_jy^{*}_{j}(q_{ij}s)))]ds \bigg| \\ \leq \; & (\|\varphi-x^{*}\|_{\xi}+\varepsilon) K_{i}e ^{ -\int_{t_{0}}^{\theta}\tilde{a}_{i}(u)du}\\ &+ \int_{t_{0}}^{\theta}e ^{ -\int_{s}^{\theta}\tilde{a}_{i}(u)du}K_{i}[|-a_i(s)p_i(s)z_i( r_i s )|+ \xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(s)| L^{f}_{j}\xi_{j}|z_{j}(s)|\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(s)|L^{g}_{j}\xi_{j}|z_{j} (q_{ij}s)|]ds \\ \leq \; & (\|\varphi-x^{*}\|_{\xi}+\varepsilon) K_{i}e ^{ -\int_{t_{0}}^{\theta}\tilde{a}_{i}(u)du}\\ &+ \int_{t_{0}}^{\theta}e ^{ -\int_{s}^{\theta}\tilde{a}_{i}(u)du}K_{i}[| a_i(s)p_i(s)|\frac{M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{-\sigma\ln \frac{1+ r_{i}s}{1+t_{0}} }\\ &+ \xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(s)| L^{f}_{j}\xi_{j}\frac{M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{-\sigma\ln \frac{1+ s}{1+t_{0}} }\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(s)|L^{g}_{j}\xi_{j} \frac{M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{-\sigma\ln \frac{1+ q_{ij}s}{1+t_{0}} }]ds\\ = \; & M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) e^{-\sigma\ln \frac{1+ \theta }{1+t_{0}} } \{ \frac{K_{i}}{M}e ^{ -\int_{t_{0}}^{\theta}[\tilde{a}_{i}(u)-\frac{ \sigma }{1+u}]du}\\ &+ \int_{t_{0}}^{\theta}e ^{ -\int_{s}^{\theta}[\tilde{a}_{i}(u)- \frac{ \sigma }{1+u}]du}K_{i}[| a_i(s)p_i(s)|\frac{1 }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{ \sigma\ln \frac{1+ s}{1+r_{i}s} }\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(s)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(s)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{\sigma \ln(\frac{1+s}{1+q_{ij}s})}]ds\} \\ \leq \; & M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) e^{-\sigma\ln \frac{1+ \theta }{1+t_{0}} } \{ \frac{K_{i}}{M}e ^{ -\int_{t_{0}}^{\theta}[\tilde{a}_{i}(u)-\frac{ \sigma }{1+u}]du}\\ &+ \int_{t_{0}}^{\theta}e ^{ -\int_{s}^{\theta}[\tilde{a}_{i}(u)- \frac{ \sigma }{1+u}]du}K_{i}[| a_i(s)p_i(s)|\frac{1 }{1- p_{i} ^{+} e^{\sigma\ln \frac{1 }{ r_{i} } }}e^{ \sigma\ln \frac{1 }{ r_{i} } }\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|e_{ij}(s)| L^{f}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}\\ &+\xi_{i}^{-1}\sum^n_{j = 1}|b_{ij}(s)| L^{g}_{j}\xi_{j}\frac{1 }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}e^{\sigma \ln(\frac{1 }{ q_{ij} })}]ds \} \\ \leq \; & M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) e^{-\sigma\ln \frac{1+ \theta }{1+t_{0}} }[ 1-(1-\frac{K_{i}}{M})e ^{-\int_{t_{0}}^{\theta}(\tilde{a}_{i}(u)- \frac{ \sigma }{1+u})du}] \\ \lt \; & M (\|\varphi-x^{*}\|_{\xi}+\varepsilon) e^{-\sigma\ln \frac{1+ \theta }{1+t_{0}} }. \end{align*}$

This is a clear contradiction of (3.12). Hence, (3.11) holds. When $\varepsilon\longrightarrow 0^{+}$ , we obtained

$\begin{align*} \|Z(t)\| \leq M\|\varphi-x^{*} \|_{\xi}e^{-\sigma\ln \frac{1+ \theta }{1+t_{0}} } \ \ \ \ \mbox{ for all } \ t \gt t_{ 0}. \end{align*}$

(3.17)

Then, using a similar derivation in the proof of (3.13) and (3.14), with the help of (3.17), we can know that

$\begin{align*} e^{ \sigma\ln \frac{1+ t }{1+t_{0}} }|z_{j} (t)| \leq \sup\limits_{s\in[\rho_j t_0, \ t]} e^{ \sigma\ln \frac{1+ s }{1+t_{0}} }|z_{j} (s)|\leq \frac{M \|\varphi-x^* \|_{\xi} }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}, \end{align*}$

and

$\begin{align*} |z_{j} (t)| \leq \frac{M \|\varphi-x^* \|_{\xi} }{1- p_{j} ^{+} e^{\sigma\ln \frac{1 }{ r_{j} } }}(\frac{1+t_{0}}{1+t })^{\sigma} \ \ \ \ \mbox{ for all } \ t \gt t_0, \ j\in N. \end{align*}$

The proof of the Theorem 3.1 is now finished.

Theorem 3.2. Let $\mu\in \mathbb{U}^{+}_{\infty}$ . Assume that $(H_{1})$ and $(H_{2})$ hold, and there exist constants $\gamma_{i}, \xi_{i} > 0$ such that

$\begin{align*} \sup\limits_{t\in \mathbb{R}}\{-\tilde{a}_{i} (t)+K_{i} [ \xi^{-1}_{i}\sum^n_{j = 1}(| e_{ij}(t)| L^{f}_{j} +| b_{ij}(t)| L^{g}_{j} )\xi_{j} ]\} \lt -\gamma_{i} \ \ \ \mbox{for all} \ \ i\in N, \end{align*}$

(3.18)

holds. Then, system (1.3) has a unique WPAPS $x^{*}(t)\in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{n})$ , and there is a constant $\sigma\in (0, \min\limits_{i\in N}\tilde{a}_{i}^{-})$ such that

$x_{ i }(t) -x^{*}_{i}(t) = O( (\frac{1}{1+t})^{\sigma}) \ \mbox{ as} \ t\rightarrow +\infty, \$

here $i \in N,$ $x(t)$ is an arbitrary solution of system (1.3) with initial conditions:

$\begin{align*} x_{i}(s) = \varphi_{i}(s), \ s\in [\rho_{i}^{*}t_{0}, \ t_{0}], \ \varphi _{i }\in C([\rho_{i}^{*}t_{0}, \ t_{0}], \mathbb{R}) , \ \rho_{i}^{*} = \min\limits _{1 \leq j\leq n }\{q_{ ij }\} , \ i\in N. \end{align*}$

Proof. From $(3.18)$ we can pick a positive constant $\Lambda_{i}^{*}$ such that

$\begin{align*} \sup\limits_{t\in \mathbb{R}} \frac{1 }{\tilde{a}_{i}(t)} K_{i}\bigg[ \xi_{i}^{-1}\sum^n_{j = 1} (|e_{ij} (t)| L^{f}_{j}+|b_{ij} (t)|L^{g}_{j}) \xi_{j} \bigg] \lt \Lambda_{i}^{*} \lt 1, \ i\in N. \end{align*}$

(3.19)

According to fact that (1.3) is a special case of (1.1) with $p_{i} ^{+} = 0 \ (i\in N)$ , the proof proceeds in the same way as in Theorem 3.1.

Remark 3.1. Obviously, it is easy to see that all results in ^[22] are the special case of Theorem 2.2 in this manuscript. In particular, the wrong in (1.5) has been successfully corrected. This indicates that our results supplement and improve the previous references ^[22,23]

4. A numerical example

In order to reveal the correctness and feasibility of the obtained results, an example with the simulation is introduced in this section.

Example 4.1. Consider the following CNNs with D operator and multi-proportional delays:

$\left\{ \begin{array}{rcl} &&[x_{1} (t)-\frac{\sin t}{100} x_1(\frac{1}{3}t) ]'\\& = & - (\frac{1}{5}+\frac{3}{10}\sin 20 t)x_{1}(t ) + \frac{1}{20}(\sin 2 t +e^{-t^2}(\sin t)^{2}) \frac{1}{20}\arctan ( x_{1}(t ))\\ &\;&+ \frac{1}{20}(\sin 3 t+ e^{-t^4}(\sin t)^{4}) \frac{1}{20}\arctan ( x_{2}(t )) \\& & + \frac{1}{20}(\cos 2 t +e^{-t^2}(\cos t)^{2}) \frac{1}{20} x_{1}(\frac{1}{2}t )\\ &\;&+ \frac{1}{20}(\cos 3 t+ e^{-t^4}(\cos t)^{4}) \frac{1}{20} x_{2}(\frac{1}{3}t ) +e^{-t^2}+\sin (\sqrt{3}t), \\ && [x_{2} (t)-\frac{\cos t }{100} x_2(\frac{1}{3}t) ]'\\& = & - (\frac{1}{5}+\frac{3}{10}\cos 20 t)x_{2}(t ) + \frac{1}{20}(\cos 2 t +e^{-t^2}(\cos t)^{2}) \frac{1}{20}\arctan ( x_{1}(t ))\\ &\;&+ \frac{1}{20}(\cos 3 t+ e^{-t^4}(\cos t)^{4}) \frac{1}{20}\arctan ( x_{2}(t )) \\& & + \frac{1}{20}(\cos 3 t +e^{-t^6}(\cos t)^{6}) \frac{1}{20} x_{1}(\frac{1}{3}t )\\ &\;&+ \frac{1}{20}(\cos 5 t+ e^{-t^8}(\cos t)^{8}) \frac{1}{20} x_{2}(\frac{1}{4}t ) +e^{-t^4}+\sin (\sqrt{5}t). \\ \end{array} \right.$

(4.1)

Clearly,

$\begin{align*} \left.\begin{array}{ll} n = 2, \ q_{ij} = \frac{1}{i+j}, \ t_{0} = 1, \ f_{i}(x) = \frac{1}{20} \arctan x , \ g_{i}(x) = \frac{1}{20} x, \ i, j = 1, 2. \end{array}\right. \end{align*}$

Then, we can take

$\tilde{a}_{i} (t) = \frac{1}{5}, \ \xi_{i} = 1, \ L^{f}_{i} = L^{g}_{i} = \frac{1}{20}, \ K_{i} = e^{\frac{3}{10 } }, \ \mu(t) = t^{2} +1, \ i, j = 1, 2,$

such that CNNs (1.1) with (4.1) satisfies all the conditions $(H_1)-(H_3)$ . By Theorem 2.1, we can conclude that CNNs (4.1) has a unique weighted pseudo almost periodic solution $x^{*}(t)\in PAP^{ \mu}(\mathbb{R}, \mathbb{R}^{2})$ , and every solutions of (4.1) is exponentially convergent to $x^{*}(t)$ as $t\rightarrow+\infty$ . Here, the exponential convergence rate $\sigma\approx 0.01$ . Simulations in Figure 1 reflect that the theoretical convergence is in sympathy with the numerically observed behaviors.

Figure 1. Numerical solutions x(t) to system (3.1) with initial values:

$(\varphi_1(s), \ \varphi_2(s)) = (2, -2), \ (-3, 2), \ (3, -2), \ t_0 = 1$ .

DownLoad: Full-Size Img PowerPoint

As far as we know, the weighted pseudo almost periodic dynamics of cellular neural networks with D operator and multi-proportional delays has never been studied in the previous literature ^{[29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52]}. It is easy to see that all results in ^{[16,17,18,19,20,21,22,23,24,25,26,27,28]} cannot be directly applied to show the case that all solutions of (4.1) converge globally to the weighted pseudo almost periodic solution. In particular, all parameters in system (4.1) are chosen by applying Matlab software. It should be mentioned that the nonlinear activation function $f_{i}(x) = \frac{1}{20} \arctan x$ has been usually used as the sigmoid functions to agree with the experimental data of signal transmission in the real cellular networks networks.

5. Conclusions

In this paper, we investigate the global dynamic behaviors on a class of neutral type CNNs with D operator and multi-proportional delays. Some new criteria have been gained to guarantee that the existence and exponential stability of weighted pseudo almost periodic solutions for the addressed system by combining the fixed point theorem and some differential inequality techniques. The obtained results are new and complement some corresponding ones of the existing literature. It should be mentioned that the technical assumptions can be easily checked by simple algebra methods and convenient for application in practice. In addition, this method affords a possible approach to study the weighted pseudo dynamics of other cellular neural networks with D operator and delays. In the future, we will make this further research.

Acknowledgments

The author would like to express his sincere appreciation to the editor and reviewers for their helpful comments in improving the presentation and quality of the paper. This work was supported by the Postgraduate Scientific Research Innovation Project of Hunan Province (No. CX20200892) and "Double first class" construction project of CSUST in 2020 ESI construction discipline, Grant No. 23/03.

Conflict of interest

We confirm that we have no conflict of interest.

Authors' contributions

P.A.L.T., K.H.T. and T.Y.H.T. conceptualized and designed the study. P.A.L.T. and M.P.P.T. analysed the data. K.H.T. and H.S.N. drafted the manuscript. K.H.T. and H.S.N revised the article. P.A.L.T. and K.H.T. provided intellectual content of critical importance to the work described. All authors gave final approval of the version to be published.

Conflicts of interest

The authors declare no conflicts of interest.

References

[1]	Hari P, Tarafdar S (2020) Nephrotic Syndrome. Nephrology: A Comprehensive Guide to Renal Medicine Wiley-Blackwell, 112-122.
[2]	Hjorten R, Anwar Z, Reidy KJ (2016) Long-term outcomes of childhood onset nephrotic syndrome. Front Pediatr 4: 53. doi: 10.3389/fped.2016.00053
[3]	Ibrahim T, Flamini E, Mercatali L, et al. (2010) Pathogenesis of osteoblastic bone metastases from prostate cancer. Cancer 116: 1406-1418. doi: 10.1002/cncr.24896
[4]	Alfano M, Cinque P, Giusti G, et al. (2015) Full-length soluble urokinase plasminogen activator receptor down-modulates nephrin expression in podocytes. Sci Rep 5: 1-12.
[5]	Kim EY, Khayyat NH, Dryer SE (2018) Mechanisms underlying modulation of podocyte TRPC6 channels by suPAR: role of NADPH oxidases and Src family tyrosine kinases. Biochim Biophys Acta Mol Basis Dis 1864: 3527-3536. doi: 10.1016/j.bbadis.2018.08.007
[6]	Wei C, El Hindi S, Li J, et al. (2011) Circulating urokinase receptor as a cause of focal segmental glomerulosclerosis. Nature Med 17: 952-960. doi: 10.1038/nm.2411
[7]	Segarra A, Jatem E, Quiles MT, et al. (2014) Diagnostic value of soluble urokinase-type plasminogen activator receptor serum levels in adults with idiopathic nephrotic syndrome. Nefrología (English Edition) 34: 46-52.
[8]	Palacios CRF, Lieske JC, Wadei HM, et al. (2013) Urine but not serum soluble urokinase receptor (suPAR) may identify cases of recurrent FSGS in kidney transplant candidates. Transplantation 96: 394-399. doi: 10.1097/TP.0b013e3182977ab1
[9]	Huang J, Liu G, Zhang YM, et al. (2014) Urinary soluble urokinase receptor levels are elevated and pathogenic in patients with primary focal segmental glomerulosclerosis. BMC Med 12: 1-11. doi: 10.1186/1741-7015-12-1
[10]	Fujimoto K, Imura J, Atsumi H, et al. (2015) Clinical significance of serum and urinary soluble urokinase receptor (suPAR) in primary nephrotic syndrome and MPO-ANCA-associated glomerulonephritis in Japanese. Clin Exp Nephrol 19: 804-814. doi: 10.1007/s10157-014-1067-x
[11]	Fujimoto K, Kagaya Y, Fujii A, et al. (2020) P0221 soluble urokinase receptor (suPAR) is a predictor of disease state and renal prognosis in primary nephrotic syndrome. Nephrol Dial Transplant 35: gfaa142. P0221. doi: 10.1093/ndt/gfaa142.P0221
[12]	Cattran DC, Feehally J, Cook HT, et al. (2012) Kidney disease: improving global outcomes (KDIGO) glomerulonephritis work group. KDIGO clinical practice guideline for glomerulonephritis. Kidney Int Suppl 2: 139-274. doi: 10.1038/kisup.2012.9
[13]	Gordillo R, Spitzer A (2009) The nephrotic syndrome. Pediatr Review 30: 94. doi: 10.1542/pir.30-3-94
[14]	Schlöndorff D (2014) Are serum suPAR determinations by current ELISA methodology reliable diagnostic biomarkers for FSGS? Kidney Int 85: 499-501. doi: 10.1038/ki.2013.549
[15]	Winnicki W, Sunder-Plassmann G, Sengölge G, et al. (2019) Diagnostic and prognostic value of soluble urokinase-type plasminogen activator receptor (suPAR) in focal segmental glomerulosclerosis and impact of detection method. Sci Rep 9: 1-9. doi: 10.1038/s41598-019-50405-8
[16]	Bock ME, Price HE, Gallon L, et al. (2013) Serum soluble urokinase-type plasminogen activator receptor levels and idiopathic FSGS in children: a single-center report. Clin J Am Soc Nephrol 8: 1304-1311. doi: 10.2215/CJN.07680712
[17]	Peng Z, Mao J, Chen X, et al. (2015) Serum suPAR levels help differentiate steroid resistance from steroid-sensitive nephrotic syndrome in children. Pediatr Nephrol 30: 301-307. doi: 10.1007/s00467-014-2892-6
[18]	Ochocińska A, Jarmużek W, Janas R (2018) The clinical pattern of nephrotic syndrome in children has no effect on the concentration of soluble urokinase receptor (suPAR) in serum and urine. Pol Merkur Lekarski 44: 183-187.
[19]	Mousa SO, Saleh SM, Aly HM, et al. (2018) Evaluation of serum soluble urokinase plasminogen activator receptor as a marker for steroid-responsiveness in children with primary nephrotic syndrome. Saudi J Kidney Dis Transpl 29: 290-296. doi: 10.4103/1319-2442.229266
[20]	Sun P, Yu L, Huang J, et al. (2019) Soluble urokinase receptor levels in secondary focal segmental glomerulosclerosis. Kidney Dis 5: 239-246. doi: 10.1159/000497353
[21]	Weidemann DK, Abraham AG, Roem JL, et al. (2020) Plasma soluble urokinase plasminogen activator receptor (suPAR) and CKD progression in children. Am J Kidney Dis 76: 194-202. doi: 10.1053/j.ajkd.2019.11.004
[22]	Nourbakhsh N, Mak RH (2017) Steroid-resistant nephrotic syndrome: past and current perspectives. Pediatric Health Med Ther 8: 29-37. doi: 10.2147/PHMT.S100803
[23]	Li F, Zheng C, Zhong Y, et al. (2014) Relationship between serum soluble urokinase plasminogen activator receptor level and steroid responsiveness in FSGS. Clin J Am Soc Nephrol 9: 1903-1911. doi: 10.2215/CJN.02370314
[24]	Königshausen E, Sellin L (2016) Circulating permeability factors in primary focal segmental glomerulosclerosis: a review of proposed candidates. BioMed Res Int 2016. doi: 10.1155/2016/3765608
[25]	McCarthy ET, Sharma M, Savin VJ (2010) Circulating permeability factors in idiopathic nephrotic syndrome and focal segmental glomerulosclerosis. Clin J Am Soc Nephrol 5: 2115-2121. doi: 10.2215/CJN.03800609
[26]	Shuai T, Jing YP, Huang Q, et al. (2019) Serum soluble urokinase type plasminogen activated receptor and focal segmental glomerulosclerosis: a systematic review and meta-analysis. BMJ Open 9: e031812. doi: 10.1136/bmjopen-2019-031812
[27]	Verdelho M, Ferreira AC, Santos MC, et al. (2018) Soluble urokinase-type plasminogen activator receptor as a biomarker for focal segmental glomerulosclerosis; a retrospective analysis. J Nephropathol 7: 182-187. doi: 10.15171/jnp.2018.38
[28]	Wada T, Nangaku M (2015) A circulating permeability factor in focal segmental glomerulosclerosis: the hunt continues. Clin Kidney J 8: 708-715. doi: 10.1093/ckj/sfv090

Reader Comments

Your name:*

Email:*
© 2021 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

AIMS Medical Science

0.7

Metrics

Article views(2866) PDF downloads(146) Cited by(0)

Preview PDF

Download XML

Export Citation

Article outline

Show full outline

AIMS Medical Science

The value of urinary soluble urokinase plasminogen activator receptor (suPAR) in children with nephrotic syndrome

Related Papers:

Abstract

1. Introduction

2. Notations and assumptions

3. Results

4. A numerical example

5. Conclusions

Acknowledgments

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Catalog

Abstract

1. Introduction

2. Notations and assumptions

3. Results

4. A numerical example

5. Conclusions

Acknowledgments

Conflict of interest

References

AIMS Medical Science

The value of urinary soluble urokinase plasminogen activator receptor (suPAR) in children with nephrotic syndrome

Related Papers:

Abstract

1. Introduction

2. Notations and assumptions

3. Results

4. A numerical example

5. Conclusions

Acknowledgments

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Related pages

Tools

Export File

Citation

Format

Content

Catalog

Abstract

1. Introduction

2. Notations and assumptions

3. Results

4. A numerical example

5. Conclusions

Acknowledgments

Conflict of interest

References