Jolanda Malamud, Sinan Guloksuz, Ruud van Winkel, Philippe Delespaul, Marc A F De Hert, Catherine Derom, Evert Thiery, Nele Jacobs, Bart P F Rutten, Quentin J M Huys
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引用次数: 0
Abstract
Background: Mood disorders involve a complex interplay between multifaceted internal emotional states, and complex external inputs. Dynamical systems theory suggests that this interplay between aspects of moods and environmental stimuli may hence determine key psychopathological features of mood disorders, including the stability of mood states, the response to external inputs, how controllable mood states are, and what interventions are most likely to be effective. However, a comprehensive computational approach to all these aspects has not yet been undertaken.
Methods: Here, we argue that the combination of ecological momentary assessments (EMA) with a well-established dynamical systems framework-the humble Kalman filter-enables a comprehensive account of all these aspects. We first introduce the key features of the Kalman filter and optimal control theory and their relationship to aspects of psychopathology. We then examine the psychometric and inferential properties of combining EMA data with Kalman filtering across realistic scenarios. Finally, we apply the Kalman filter to a series of EMA datasets comprising over 700 participants with and without symptoms of depression.
Results: The results show a naive Kalman filter approach performs favourably compared to the standard vector autoregressive approach frequently employed, capturing key aspects of the data better. Furthermore, it suggests that the depressed state involves alterations to interactions between moods; alterations to how moods responds to external inputs; and as a result an alteration in how controllable mood states are. We replicate these findings qualitatively across datasets and explore an extension to optimal control theory to guide therapeutic interventions.
Conclusions: Mood dynamics are richly and profoundly altered in depressed states. The humble Kalman filter is a well-established, rich framework to characterise mood dynamics. Its application to EMA data is valid; straightforward; and likely to result in substantial novel insights both into mechanisms and treatments.
背景:情绪障碍涉及多方面的内部情绪状态和复杂的外部输入之间的复杂相互作用。动态系统理论认为,情绪的各个方面与环境刺激之间的相互作用可能决定情绪障碍的主要精神病理学特征,包括情绪状态的稳定性、对外部输入的反应、情绪状态的可控性以及哪些干预措施最可能有效。方法:在此,我们认为将生态瞬时评估(EMA)与成熟的动态系统框架--简陋的卡尔曼滤波器--相结合,可以对所有这些方面进行全面的阐述。我们首先介绍卡尔曼滤波器和最优控制理论的主要特点,以及它们与精神病理学的关系。然后,我们研究了将 EMA 数据与卡尔曼滤波相结合的心理测量和推断特性。最后,我们将卡尔曼滤波法应用于一系列 EMA 数据集,这些数据集由 700 多名有抑郁症状和无抑郁症状的参与者组成:结果表明,与经常使用的标准向量自回归方法相比,天真的卡尔曼滤波方法表现出色,能更好地捕捉数据的关键方面。此外,它还表明抑郁状态涉及情绪之间相互作用的改变、情绪对外部输入反应的改变以及情绪状态可控性的改变。我们在不同的数据集上定性地复制了这些发现,并探索了最优控制理论的延伸,以指导治疗干预:结论:抑郁状态下的情绪动态发生了丰富而深刻的变化。不起眼的卡尔曼滤波器是一个成熟、丰富的框架,可用于描述情绪动态特征。将卡尔曼滤波器应用于 EMA 数据是有效的、简单的,而且有可能在机制和治疗方面产生大量新的见解。
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PLOS Computational Biology features works of exceptional significance that further our understanding of living systems at all scales—from molecules and cells, to patient populations and ecosystems—through the application of computational methods. Readers include life and computational scientists, who can take the important findings presented here to the next level of discovery.
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