Abstract
SummaryInnovation in the field of brain-machine interfacing offers a new approach to managing human pain. In principle, it should be possible to use brain activity to directly control a therapeutic intervention in an interactive, closed-loop manner. But this raises the question as to whether the brain activity changes as a function of this interaction. Here, we used real-time decoded functional MRI responses from the insula cortex as input into a closed-loop control system aimed at reducing pain and looked for co-adaptive neural and behavioral changes. As subjects engaged in active cognitive strategies orientated toward the control system, such as trying to enhance their brain activity, pain encoding in the insula was paradoxically degraded. From a mechanistic perspective, we found that cognitive engagement was accompanied by activation of the endogenous pain modulation system, manifested by the attentional modulation of pain ratings and enhanced pain responses in pregenual anterior cingulate cortex and periaqueductal gray. Further behavioral evidence of endogenous modulation was confirmed in a second experiment using an EEG-based closed-loop system. Overall, the results show that implementing brain-machine control systems for pain induces a parallel set of co-adaptive changes in the brain, and this can interfere with the brain signals and behavior under control. More generally, this illustrates a fundamental challenge of brain decoding applications—that the brain inherently adapts to being decoded, especially as a result of cognitive processes related to learning and cooperation. Understanding the nature of these co-adaptive processes informs strategies to mitigate or exploit them.
Highlights
The management of human pain is in desperate need of innovation, given the magnitude of the clinical and societal problem and the limited success of conventional pharmacological treatments
We aimed to establish whether, in principle, brain representations of pain can be decoded in real time from brain responses and used to instruct an adaptive search algorithm linked to a pain-relief intervention; this would show in principle that adaptive control systems can be applied to pain
The purpose of the first day (‘‘decoder construction’’) was to allow us to build a decoder, using offline multivoxel-pattern analysis (MVPA), that could subsequently be used for online decoding in the adaptive control system the following day
Summary
The management of human pain is in desperate need of innovation, given the magnitude of the clinical and societal problem and the limited success of conventional pharmacological treatments. By creating a closed-loop system, this allows the intervention to be constantly and automatically tracked and adjusted ‘‘online’’ to avoid over- or under-treatment [2,3,4]. Closed-loop control is potentially most valuable when the intervention itself has multiple parameters, and whereby the optimal configuration and setting of these parameters is not known. The biomarker can be used to guide algorithms to search and optimize them automatically—so-called adaptive control [5]. In this way, combining brain decoding with adaptive control algorithms can offer a powerful new approach to brain therapeutics
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