从偶然选择到必然需求：尼古丁成瘾的计算模型。

From occasional choices to inevitable musts: a computational model of nicotine addiction.

机构信息

Electrical and Electronic Engineering Faculty, Istanbul Technical University, Maslak, Istanbul 34469, Turkey.

出版信息

Comput Intell Neurosci. 2012;2012:817485. doi: 10.1155/2012/817485. Epub 2012 Nov 20.

DOI:10.1155/2012/817485

PMID:23251144

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3508524/

Abstract

Although, there are considerable works on the neural mechanisms of reward-based learning and decision making, and most of them mention that addiction can be explained by malfunctioning in these cognitive processes, there are very few computational models. This paper focuses on nicotine addiction, and a computational model for nicotine addiction is proposed based on the neurophysiological basis of addiction. The model compromises different levels ranging from molecular basis to systems level, and it demonstrates three different possible behavioral patterns which are addict, nonaddict, and indecisive. The dynamical behavior of the proposed model is investigated with tools used in analyzing nonlinear dynamical systems, and the relation between the behavioral patterns and the dynamics of the system is discussed.

摘要

虽然已经有相当多的关于基于奖励的学习和决策的神经机制的研究，而且大多数研究都提到成瘾可以用这些认知过程的功能障碍来解释，但实际上只有很少的计算模型。本文主要关注尼古丁成瘾问题，并基于成瘾的神经生理学基础提出了一个尼古丁成瘾的计算模型。该模型由从分子基础到系统水平的不同层次组成，并展示了三种不同的可能行为模式：成瘾者、非成瘾者和犹豫不决者。使用非线性动力学系统分析工具研究了所提出模型的动力学行为，并讨论了行为模式与系统动力学之间的关系。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cd39/3508524/dd7e928e0a4f/CIN2012-817485.001.jpg

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从偶然选择到必然需求：尼古丁成瘾的计算模型。

From occasional choices to inevitable musts: a computational model of nicotine addiction.

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