Laureate Institute for Brain Research, Tulsa, Oklahoma; Department of Psychiatry, University of California San Diego, La Jolla, California.
Laureate Institute for Brain Research, Tulsa, Oklahoma; Department of Family Medicine and Public Health, University of California San Diego, La Jolla, California.
Biol Psychiatry Cogn Neurosci Neuroimaging. 2020 Apr;5(4):412-419. doi: 10.1016/j.bpsc.2019.12.011. Epub 2019 Dec 24.
Real-time control of goal-directed actions requires continuous adjustments in response to both current error (i.e., distance from goal state) and predicted future error. Proportion-integral-derivative control models, which are extensively used in the automated control of industrial processes, formalize this intuition. Previous computational approaches to anxiety have separately addressed behavioral inhibition and exaggerated error processing, but a proportion-integral-derivative control approach that decomposes error processing into current and anticipated error could integrate these accounts and extend them to a real-time sensorimotor control domain.
We applied a simplified proportion-derivative control model to a virtual driving task in a transdiagnostic psychiatric sample of 317 individuals and computed a drive parameter (weighting of current error) and a damping parameter (weighting of the rate of change of error, enabling adjustment based on future error).
Self-reported fear, but not negative affect, was selectively associated with lower drive and lower damping. Those individuals that were characterized by lower drive and damping also exhibited lower caudal anterior cingulate cortex, but not insula, volume in a structural magnetic resonance imaging analysis.
The proportion-derivative control approach reveals that fear is specifically associated with reduced weighting of current error and overestimation of future error, resulting in both approach inhibition and overcorrecting overshoots around a goal state.
实时控制目标导向的动作需要根据当前误差(即与目标状态的距离)和预测的未来误差不断进行调整。比例积分微分控制模型广泛应用于工业过程的自动控制,形式化了这种直觉。以前针对焦虑的计算方法分别解决了行为抑制和过度错误处理的问题,但将错误处理分解为当前和预期误差的比例积分微分控制方法可以整合这些解释,并将其扩展到实时感觉运动控制领域。
我们将简化的比例微分控制模型应用于一个跨诊断精神科样本中的 317 个人的虚拟驾驶任务中,并计算了一个驱动参数(当前误差的权重)和一个阻尼参数(误差变化率的权重,能够根据未来的误差进行调整)。
自我报告的恐惧,但不是负面情绪,与较低的驱动和较低的阻尼选择性相关。那些表现出较低驱动和阻尼的个体,在结构磁共振成像分析中也表现出较低的尾状前扣带皮层,但没有岛叶体积。
比例微分控制方法表明,恐惧与对当前误差的权重降低和对未来误差的高估有关,导致接近目标状态时的两种趋近抑制和过度校正过度。
