The present study suggests that memory NF for MTL may modulate not only theta-band power, but also high-frequency band power. Theta power was significantly increased while high-frequency power (fast beta and gamma) was significantly decreased after more than five sessions of NF training in one (P01) of two participants with intractable epilepsy. In addition, in P01, the PSD of the left MTL during memory encoding was lower in the correct trials than in the error trials, especially in the theta band, although this was not significant.
Decreases in theta power during episodic memory processing, especially successful encoding, have often been reported in intracranial studies in humans (Burke et al., 2013; Ezzyat et al., 2017, 2018; Fellner et al., 2019; Greenberg et al., 2015; Herweg, Solomon, et al., 2020; Kragel et al., 2017; Long et al., 2014; Long & Kahana, 2015; Sederberg et al., 2007; Solomon, Stein, et al., 2019). The results for P01 are in line with those of previous studies. The decrease in theta power at encoding in intracranial studies, including the present study, is inconsistent with the findings of scalp EEG studies, which are characterized by an increase in theta power (Düzel et al., 2005; Hanslmayr et al., 2009; Osipova et al., 2006). This discrepancy between scalp EEG and intracranial electrode studies is most likely due to the difference in the spatial resolution of the EEG measurement methods (Herweg, Solomon, et al., 2020). Herweg, Solomon, et al. (2020) suggested that intracranial electrodes recorded a decrease in theta power in localized areas, but the oscillations were highly correlated between electrodes; meanwhile, scalp electrodes observed this synchronization as a relative increase in theta power. As such, intracranial electrodes, which can acquire signals directly from the MTL, are more useful than scalp EEG in modifying memory functions in the MTL located deep in the brain.
After conducting memory NF training for P01, we observed an increase in theta power and decrease in the high-frequency band, consistent with previous findings (Greenberg et al., 2015; Long & Kahana, 2015; Solomon, Stein, et al., 2019). Increased coupling between the theta rhythm phase and the amplitude of high-frequency rhythm in the MTL, especially in the hippocampus, during episodic memory encoding has also been reported (B. Lega et al., 2016; Mormann et al., 2005), suggesting the importance of interaction between these two frequency bands in memory formation.
Interestingly, the increased theta power in P01 occurred during the late NF training stage. This could be because the intermittent feedback method is employed in neurofeedback. The usefulness of intermittent feedback has been reported in several studies (Emmert et al., 2017; Hellrung et al., 2018; Johnson et al., 2012; Zilverstand et al., 2015). In a previous study, intermittent feedback took longer to learn than continuous feedback when participants can directly influence the feedback signal through simple behavioral strategy choices (Oblak et al., 2017). Continuous feedback may allow for faster and more efficient learning of memory functions. The risk of interference between memory tasks and continuous NF can be decreased by adjusting the background color of the screen presenting the memory task according to the power of theta (Monseigne et al., 2019) or by visually presenting the memory task while aurally presenting NF using music (Takabatake et al., 2021).
The different result for P02 can be explained as follows. The first was the difference in the difficulty of the memory task for each participant. P02 had a smaller number of sessions (only three) for comparing PSDs in the correct-and-error trials. Thus, the confidence intervals were large, and it was more difficult to observe the difference between the correct and incorrect trials than in P01. The second is the difference in the electrodes used for NF: P01 used a subdural electrode, whereas P02 used a depth electrode. Compared with depth electrodes, subdural electrodes are implanted to cover the cortical area and acquire signals from a broader area of the targeted region (Herff et al., 2020; Parvizi & Kastner, 2018). In addition, the four platinum contacts used in P02 were aligned at 5-mm intervals from the tip located in the hippocampus toward the lateral temporal lobe, which may have been more affected by other brain region activity than subdural electrodes. The impact of different electrodes used on the NF effect needs to be examined in the future. The third is the effect of the mental strategy employed by the P02. P02 started to remember by relating words displayed in the middle stage. Increased high-frequency power in the hippocampus in word memory encoding has been suggested to be related to semantic processing (Sederberg et al., 2007) and the process of linking words to context (Long & Kahana, 2015). Compared to session 1, the final session of P02 may have had significantly increased high-frequency PSD during encoding using the mental strategy of word association.
Interestingly, P02 stated that bar height increased when word associations were made, especially when good word associations were made, while bar height was decreased when word associations were made forcibly. The use of semantic encoding strategies and episodic (temporal) encoding strategies have a trade-off relationship (Golomb et al., 2008; Healey et al., 2014; Sederberg et al., 2010). Differences in EEG rhythm depend on whether a semantic encoding strategy is used and on the context during encoding (Hanslmayr et al., 2009; Staudigl & Hanslmayr, 2013). A recent study reported an increase in theta power in the left hippocampus when recalling words with a close semantic distance and a decrease in theta power when recalling words with distant semantic distance (Solomon, Lega, et al., 2019). A good word association can be interpreted as a state in which a closer semantic relationship is found between words than when word associations are made forcibly. As such, the increase in relative theta power due to the shift from temporal to semantic encoding strategies and due to good word associations may be reasonable.
This study has some limitations as in both participants, there was no correlation between changes in neural activity and changes in memory function. First, based on several memory studies (Düzel et al., 2005; Guderian & Düzel, 2005; Hanslmayr et al., 2009; Herweg et al., 2016; Herweg, Solomon, et al., 2020; Hsieh & Ranganath, 2014), theta (4–8 Hz) was set as the frequency band targeted by memory NFs, and other frequency bands were not targeted. Some studies have reported that hippocampal activity in the low-theta band, below 4 Hz, is essential for human memory encoding (Miller et al., 2018; Solomon, Lega, et al., 2019; Staudigl & Hanslmayr, 2013). Further research is needed to evaluate the effects of different targeted frequency bands on memory NF. Second, it was difficult to recruit participants who had implanted electrodes in the MTL and could participate in NF training within a limited time frame. Therefore, this study was limited by the different types of electrodes, small sample size, small number of sessions, and inability to set a control condition. The results need to be further validated by recruiting a larger number of participants and establishing a control condition. Third, the participants were required to perform monotonous tasks throughout the assignment, which may have resulted in increased fatigue and drowsiness and decreased motivation. The importance of attention, mood, and motivation in effective learning and success in NF training has been noted (Kadosh & Staunton, 2019), and it is important to consider updating the modality from the traditional one (bar height adjustment) to one that incorporates the rewarding and gaming aspects in future studies.
Nevertheless, to our best knowledge, no studies have addressed the artificial reorganization of memory function by NF using intracranial electrodes in the MTL, and this study is the first to suggest that neural activity in the MTL, related to verbal memory function, can be modulated by NF training using intracranial electrodes.