Brain compensatory mechanisms in depression and memory complaints in fibromyalgia: The role of theta oscillatory activity.

BACKGROUND: The different clinical presentations of fibromyalgia (FMS) may play independent roles in the unclear etiology of cognitive impairments and depressive symptoms seen in this population. Understanding how these clinical presentations are associated with FMS's clinical and neurophysiological aspects is important when developing effective treatments. AIM: To explore the relationship between memory complaints and depressive symptoms, and the different clinical and neurophysiological characteristics of FMS. METHODS: Cross-sectional data analysis from a randomized clinical trial. Baseline demographics, physical fitness, sleep, anxiety, depression, cortical excitability, and pain (clinical and mechanistic) data from 63 FMS subjects were used. Multiple linear and logistic association models were constructed. RESULTS: Final regression models including different sets of predictions were statistically significant (p < 0.001), explaining approximately 50% of the variability in cognitive complaints and depression status. Older subjects had higher levels of anxiety, poor sleep quality, lower motor threshold, and higher relative theta power in the central area, are more likely to have clinical depression. Higher anxiety, pain and theta power were associated with an increase memory complaint. CONCLUSION: Depression symptoms seem to be associated with TMS-indexed motor threshold and psychosocial variables, while memory complaints are associated with pain intensity and higher theta oscillations. These mechanisms may be catalyzed and/or triggered by some behavioral and clinical features such as older age, sleep disruption, and anxiety. The correlation with clinical variables suggests the increasing of theta oscillations is a compensatory response in patients with FMS, which can be explored in future studies to improve the treatment for FMS.

Using Home-based, Remotely Supervised, Transcranial Direct Current Stimulation for Phantom Limb Pain.

Transcranial direct current stimulation (tDCS) is a noninvasive brain stimulation technique that uses low-amplitude direct currents to alter cortical excitability. Previous trials have established the safety and tolerability of tDCS, and its potential to mitigate symptoms. However, the effects are cumulative, making it more difficult to have adherence to the treatment since frequent visits to the clinic or outpatient center are required. Moreover, the time needed for transportation to the center and the related expenses limit the accessibility of the treatment for many participants. Following guidelines for remotely supervised transcranial direct current stimulation (RS-tDCS) implementation, we propose a protocol designed for remotely supervised and home-based participation that uses specific devices and materials modified for patient use, with real-time monitoring by researchers through an encrypted video conferencing platform. We have developed detailed instructional materials and structured training procedures to allow for self- or proxy-administration while supervised remotely in real time. This protocol has a specific design to have a series of checkpoints during training and execution of the visit. This protocol is currently in use in a large pragmatic study of RS-tDCS for phantom limb pain (PLP). In this article, we will discuss the operational challenges of conducting a home-based RS-tDCS session and show methods to enhance its efficacy with supervised sessions.

Understanding the Effects of Non-Invasive Transauricular Vagus Nerve Stimulation On EEG and HRV.

Several studies have demonstrated promising results of transcutaneous auricular vagus nerve stimulation (taVNS) in treating various disorders; however, no mechanistic studies have investigated this technique's neural network and autonomic nervous system effects. This study aims to describe how taVNS can affect EEG metrics, HRV, and pain levels. Healthy subjects were randomly allocated into two groups: the active taVNS group and the sham taVNS group. Electroencephalography (EEG) and Heart Rate Variability (HRV) were recorded at baseline, 30 min, and after 60 min of 30 Hz, 200-250 µs taVNS, or sham stimulation, and the differences between the metrics were calculated. Regarding vagal projections, some studies have demonstrated the role of the vagus nerve in modulating brain activity, the autonomic system, and pain pathways. However, more data is still needed to understand the mechanisms of taVNS on these systems. In this context, this study presents methods to provide data for a deeper discussion about the physiological impacts of this technique, which can help future therapeutic investigations in various conditions.