Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-20T15:29:54.053Z Has data issue: false hasContentIssue false

Regular recreational Cannabis users exhibit altered neural oscillatory dynamics during attention reorientation

Published online by Cambridge University Press:  22 September 2021

Seth D. Springer
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Rachel K. Spooner
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Mikki Schantell
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Yasra Arif
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Michaela R. Frenzel
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Jacob A. Eastman
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
Tony W. Wilson*
Affiliation:
Institute for Human Neuroscience, Boys Town National Research Hospital, Boys Town, NE, USA College of Medicine, University of Nebraska Medical Center, Omaha, NE, USA
*
Author for correspondence: Tony W. Wilson, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background

Cannabis is the most widely used illicit drug in the United States and is often associated with changes in attention function, which may ultimately impact numerous other cognitive faculties (e.g. memory, executive function). Importantly, despite the increasing rates of cannabis use and widespread legalization in the United States, the neural mechanisms underlying attentional dysfunction in chronic users are poorly understood.

Methods

We used magnetoencephalography (MEG) and a modified Posner cueing task in 21 regular cannabis users and 32 demographically matched non-user controls. MEG data were imaged in the time−frequency domain using a beamformer and peak voxel time series were extracted to quantify the oscillatory dynamics underlying use-related aberrations in attentional reorienting, as well as the impact on spontaneous neural activity immediately preceding stimulus onset.

Results

Behavioral performance on the task (e.g. reaction time) was similar between regular cannabis users and non-user controls. However, the neural data indicated robust theta-band synchronizations across a distributed network during attentional reorienting, with activity in the bilateral inferior frontal gyri being markedly stronger in users relative to controls (p's < 0.036). Additionally, we observed significantly reduced spontaneous theta activity across this distributed network during the pre-stimulus baseline in cannabis users relative to controls (p's < 0.020).

Conclusions

Despite similar performance on the task, we observed specific alterations in the neural dynamics serving attentional reorienting in regular cannabis users compared to controls. These data suggest that regular cannabis users may employ compensatory processing in the prefrontal cortices to efficiently reorient their attention relative to non-user controls.

Type
Original Article
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

Introduction

Following tobacco and alcohol, cannabis is the most widely used psychoactive substance in the United States (Azofeifa et al., Reference Azofeifa, Mattson, Schauer, McAfee, Grant and Lyerla2016; Carliner, Brown, Sarvet, & Hasin, Reference Carliner, Brown, Sarvet and Hasin2017), with an estimated 24 million Americans aged 12 or older found to be current users of cannabis in 2016 (SAMHSA, 2017). The main psychoactive component of cannabis is Δ9-tetrahydrocannabiol (THC), which acts, most notably, as an agonist of the endocannabinoid CB1 receptor (CB1R; (Bloomfield et al., Reference Bloomfield, Hindocha, Green, Wall, Lees, Petrilli and Freeman2019). CB1R is a common G-protein-coupled receptor that is found in high concentrations in the neocortex (particularly frontal and limbic areas), hippocampus, amygdala, cerebellum, thalamus, and the basal ganglia (Bloomfield et al., Reference Bloomfield, Hindocha, Green, Wall, Lees, Petrilli and Freeman2019). Concomitant with widespread CB1R activation are cognitive and behavioral changes that occur with acute (i.e. online, current use) and chronic cannabis use (i.e. persistent, repetitive use), including memory, executive functioning, and attentional deficits (Bloomfield et al., Reference Bloomfield, Hindocha, Green, Wall, Lees, Petrilli and Freeman2019; Broyd, van Hell, Beale, Yucel, & Solowij, Reference Broyd, van Hell, Beale, Yucel and Solowij2016; Cohen & Weinstein, Reference Cohen and Weinstein2018; Ganzer, Bröning, Kraft, Sack, & Thomasius, Reference Ganzer, Bröning, Kraft, Sack and Thomasius2016; Lovell, Akhurst, Padgett, Garry, & Matthews, Reference Lovell, Akhurst, Padgett, Garry and Matthews2019; Scott et al., Reference Scott, Slomiak, Jones, Rosen, Moore and Gur2018). However, the neurobiological mechanisms underlying such cognitive dysfunction in the context of acute and chronic cannabis use remains poorly understood.

One behavioral hallmark of acute cannabis intoxication includes difficulty attending to pertinent stimuli in the environment, which may ultimately impact other cognitive domains including memory, executive, and motor functioning (Broyd et al., Reference Broyd, van Hell, Beale, Yucel and Solowij2016). While this relationship between cannabis use and the impairment of attentional domains (e.g. focused, divided, and sustained attention) is well established in acute users of cannabis (Broyd et al., Reference Broyd, van Hell, Beale, Yucel and Solowij2016; Cohen & Weinstein, Reference Cohen and Weinstein2018; Scott et al., Reference Scott, Slomiak, Jones, Rosen, Moore and Gur2018), the effect of chronic, persistent cannabis use on attention function is far less understood (Broyd et al., Reference Broyd, van Hell, Beale, Yucel and Solowij2016; Cohen & Weinstein, Reference Cohen and Weinstein2018; Ganzer et al., Reference Ganzer, Bröning, Kraft, Sack and Thomasius2016). In fact, the available data in this area is broadly conflicting (for an excellent review see Cohen & Weinstein, Reference Cohen and Weinstein2018), although this may be related to methodological considerations, including significant sample heterogeneity across studies. For example, inclusion criteria for chronic cannabis use varies widely from study to study, such as the amount of current use, the duration of use prior to study enrollment, and the duration of abstinence from cannabis use prior to study assessments (Ganzer et al., Reference Ganzer, Bröning, Kraft, Sack and Thomasius2016). Recently, meta-analytical approaches (Lovell et al., Reference Lovell, Akhurst, Padgett, Garry and Matthews2019; Schreiner & Dunn, Reference Schreiner and Dunn2012; Scott et al., Reference Scott, Slomiak, Jones, Rosen, Moore and Gur2018) have helped clarify the cognitive effects of chronic cannabis use. Taken together, there seem to be reasonable agreement that there are attentional deficits associated with chronic cannabis use that become less severe and even insignificant when users abstain from the drug for an extended period. Another factor crucial to the impact of cannabis on cognitive function is the age at which individuals start using cannabis. Specifically, it has been demonstrated that participants who began using cannabis at earlier ages tend to have worse cognitive function (Bosker et al., Reference Bosker, Karschner, Lee, Goodwin, Hirvonen, Innis and Ramaekers2013; Hooper, Woolley, & De Bellis, Reference Hooper, Woolley and De Bellis2014) and decreased cortical gray matter volumes (Wilson et al., Reference Wilson, Mathew, Turkington, Hawk, Coleman and Provenzale2000). Similar to the neuropsychological findings, neuroimaging studies have shown inconsistent results with regards to differences between cannabis users and nonusers. While some studies have found changes in brain morphology and activation patterns in cannabis users (Gilman et al., Reference Gilman, Yucel, Pachas, Potter, Levar, Broos and Evins2019; Jager et al., Reference Jager, Van Hell, De Win, Kahn, Van Den Brink, Van Ree and Ramsey2007; Lopez-Larson, Rogowska, & Yurgelun-Todd, Reference Lopez-Larson, Rogowska and Yurgelun-Todd2015; Schweinsburg et al., Reference Schweinsburg, Nagel, Schweinsburg, Park, Theilmann and Tapert2008; Wilson et al., Reference Wilson, Mathew, Turkington, Hawk, Coleman and Provenzale2000), others have found no such differences between cannabis users and nonusers (Block et al., Reference Block, O'Leary, Ehrhardt, Augustinack, Ghoneim, Arndt and Hall2000; Jager, Kahn, Van Den Brink, Van Ree, & Ramsey, Reference Jager, Kahn, Van Den Brink, Van Ree and Ramsey2006; Tzilos et al., Reference Tzilos, Cintron, Wood, Simpson, Young, Pope and Yurgelun-Todd2005).

Productive daily life depends upon one's ability to orient and reorient their attention to behaviorally pertinent stimuli and information. These attentional processes are thought to be served by the interaction between two neural networks: the dorsal attentional network (DAN) and the ventral attentional network (VAN; Chica, Bartolomeo, & Lupiáñez, Reference Chica, Bartolomeo and Lupiáñez2013; Corbetta & Shulman, Reference Corbetta and Shulman2002; Corbetta, Patel, & Shulman, Reference Corbetta, Patel and Shulman2008). The DAN appears to be involved in top-down control processes based on current objectives and preexisting information, and includes activation of bilateral superior parietal lobules, intraparietal sulci, and frontal eye fields. In contrast, the VAN has been shown to be involved in bottom-up detection of goal-relevant stimuli (Corbetta et al., Reference Corbetta, Patel and Shulman2008), with key hubs in the right temporo-parietal junction and the ventral prefrontal cortices. Importantly, regions within both networks are activated upon the detection of behaviorally relevant targets and further amplified when attentional resources need to be reallocated to more behaviorally relevant stimuli (Corbetta et al., Reference Corbetta, Patel and Shulman2008). In addition to the neuroanatomical origins serving these attentional processes, recent studies have shown such activation comprises multispectral neural oscillatory responses within these networks during attention reallocation (Arif et al., Reference Arif, Spooner, Wiesman, Embury, Proskovec and Wilson2020a, Reference Arif, Wiesman, O'Neill, Embury, May, Lew and Wilsonb; Proskovec, Heinrichs-Graham, Wiesman, McDermott, & Wilson, Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018; Spooner, Wiesman, Proskovec, Heinrichs-Graham, & Wilson, Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2020).

While the neural processes serving attention and attentional reorientation have been extensively studied, the impact of regular cannabis use on these processes remains poorly understood. Thus, we examined the neural oscillatory dynamics underlying attentional reorienting in demographically matched users and nonusers using magnetoencephalography (MEG) and a modified Posner cueing task. The Posner task is a well-vetted attention paradigm that is commonly used to investigate the reorienting of attentional resources to novel target locations by either validity or invalidly cueing the participant to the location of the upcoming target stimulus, which induces a robust behavioral effect termed the validity effect (Arif et al., Reference Arif, Spooner, Wiesman, Embury, Proskovec and Wilson2020a, Reference Arif, Wiesman, O'Neill, Embury, May, Lew and Wilsonb; Chica et al., Reference Chica, Bartolomeo and Lupiáñez2013; Daitch et al., Reference Daitch, Sharma, Roland, Astafiev, Bundy, Gaona and Corbetta2013; Macaluso & Patria, Reference Macaluso and Patria2007; Posner, Reference Posner1980; Proskovec et al., Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018; Spooner et al., Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2020; Thiel, Zilles, & Fink, Reference Thiel, Zilles and Fink2004; Vossel, Thiel, & Fink, Reference Vossel, Thiel and Fink2006; Vossel, Weidner, Driver, Friston, & Fink, Reference Vossel, Weidner, Driver, Friston and Fink2012; Wiesman & Wilson, Reference Wiesman and Wilson2019). Importantly, the validity effect refers to a behavioral decrement (e.g. slowing reaction time) in response to invalidly cued targets, which are targets that appear in a different spatial location than the previous spatial cue. This effect is reflected in the brain through greater activation in key DAN and VAN nodes for invalidly cued trials compared to valid ones (Corbetta et al., Reference Corbetta, Patel and Shulman2008; Posner, Reference Posner1980). Based on previous literature, we hypothesized that the reorienting of attention would involve temporally sustained decreases in alpha and beta activity during target processing in DAN hubs (e.g. superior parietal lobules). In contrast, we predicted that there would be robust, transient increases in theta oscillatory activity in the VAN (e.g. inferior frontal cortices) during target processing (Arif et al., Reference Arif, Spooner, Wiesman, Embury, Proskovec and Wilson2020a; Proskovec et al., Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018; Spooner et al., Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2020; Wiesman, Groff, & Wilson, Reference Wiesman, Groff and Wilson2019). Considering the relatively low difficulty of the Posner task, we expected there to be little to no behavioral differences between the users and nonusers. Conversely, we expected there to be major differences in the oscillatory dynamics of users, indicative of compensatory neural mechanisms to maintain proper functionality compared to their nonuser counterparts, as has been shown in several major fMRI studies (Chang, Reference Chang2006; Eldreth, Matochik, Cadet, & Bolla, Reference Eldreth, Matochik, Cadet and Bolla2004; Jager et al., Reference Jager, Kahn, Van Den Brink, Van Ree and Ramsey2006; Kanayama, Rogowska, Pope, Gruber, & Yurgelun-Todd, Reference Kanayama, Rogowska, Pope, Gruber and Yurgelun-Todd2004). Finally, we also hypothesized that chronic cannabis users would exhibit alterations in spontaneous neural activity prior to stimulus onset, further indicative of disrupted neural processing in the brain regions serving attention function (Böcker et al., Reference Böcker, Hunault, Gerritsen, Kruidenier, Mensinga and Kenemans2010; Herning, Better, Tate, & Cadet, Reference Herning, Better, Tate and Cadet2003; Ilan, Smith, & Gevins, Reference Ilan, Smith and Gevins2004).

Materials and methods

Participants

Fifty-three participants were enrolled in the study. Twenty-one active, regular cannabis users (7 females, mean age: 29.9, s.d.: 7.76) and 32 nonuser controls (13 females; mean age: 30.6, s.d.: 7.22). Exclusionary criteria included any medical illness affecting the central nervous system function, neurological or psychiatric disorder, history of head trauma, and standard exclusionary criteria for MEG (e.g. any type of ferromagnetic implanted material). After a complete description of the study, written informed consent was obtained from each participant.

Participants were identified as regular cannabis users based on the following criteria: (1) at least weekly cannabis use over the past 12 months, (2) current use of at least four times per week, and (3) not currently using any other illicit drugs (e.g. cocaine, heroin, etc.). Importantly, participants were asked to refrain from using any cannabis containing products on the day of their MEG appointment, to avoid any contamination of neural/behavioral effects by acute substance use. Further, participants in the user group were screened for drug use on the day of examination to ensure that they were not using any drugs other than cannabis. In contrast, the nonuser group consisted of individuals with no current or past substance use, and were demographically matched to the user group based on age, sex, race, SES, and levels of depression (measured by the Beck Depression Scale). Of note, the groups differed on years of education and head motion during MEG, but inclusion of these variables in the final statistical models resulted in no changes to the results. Additionally, our experimental groups were matched on current alcohol use as measured via the Alcohol Use disorders Identification Test – Consumption (AUDIT-C) scores (controls – M: 2.72, s.d.: 1.53; users – M: 4.05, s.d.: 2.85), to ensure that any cannabis-related effects in our data were not confounded by between-group differences in alcohol consumption.

Experimental paradigm

During the MEG recording, participants performed a modified Posner task (Posner, Reference Posner1980). As shown in Fig. 1 and described in prior works, each trial consisted of a fixation crosshair for 1500 ms (± 50 ms), followed by a green bar (the cue) appearing on either the left or right of the crosshair for 100 ms, a 200 ms fixation cross, and then a target on either the left or right side for 2500 ms. Importantly, the target could be validly (i.e. same side as cue; 50% of trials) or invalidly cued. Each cue location (left or right) and target (valid/invalid) appeared an equal number of times and participants responded as to the location of the opening in the target stimulus (top/bottom) using their right hand on a nonmagnetic button pad. Each trial lasted 4300 ms (± 50 ms), with a total of 200 trials (100 valid, 100 invalid).

Fig. 1. Posner cueing task and behavioral performance. (A) A fixation cross was first presented for 1500 (±50) ms, followed by a cue (green bar) presented to the left or right of the fixation cross for 100 ms. After 200 ms, the target stimulus (box with opening) appeared in either the left or right hemifield for 2500 ms. Participants responded as to whether the opening was on the bottom or top of the target with their index and middle finger, respectively. Validly cued trials (cue location on the same side as the impending target) were presented for 50% of the trials, and a total of 200 trials (both valid and invalidly cued) were completed by each participant. (B) Behavioral performance of all subjects is shown on the y-axis (i.e. reaction time on the left, accuracy on the right) with condition (valid or invalid) on the x-axis. Reaction times were significantly slower during invalid trials compared to valid ones, while accuracy was unchanged as a function of task condition. ***p < 0.001.

MEG data acquisition, preprocessing, and imaging

Neuromagnetic responses were sampled at 1 kHz using an Elekta/MEGIN MEG system with 306 sensors. MEG data from each participant was individually corrected for head motion and subjected to noise reduction using the signal space separation method with temporal extension (Taulu & Simola, Reference Taulu and Simola2006). The continuous magnetic time series was divided into epochs of 4000 ms duration, with the onset of the cue defined as 0 ms and the baseline defined as the 600 ms preceding the cue onset (−600 to 0 ms). Epochs containing artifacts were rejected based on a fixed threshold method. This process and the actual thresholds are described in the Supplemental Methods and, importantly, did not differ by group. Further, to ensure a balanced number of trials between groups and conditions, a mixed-model ANOVA was performed which showed no main effects of group, condition, nor interaction.

Artifact-free epochs were transformed into the time−frequency domain using complex demodulation (Kovach & Gander, Reference Kovach and Gander2016). The specific time−frequency windows used for subsequent imaging were determined using a stringent statistical analysis involving nonparametric permutation testing of the sensor-level spectrograms across the entire array of gradiometers (see (Proskovec et al., Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018; Spooner et al., Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2020; Wiesman et al., Reference Wiesman, O'Neill, Mills, Robertson, Fox, Swindells and Wilson2018). Prior to image reconstruction, each participant's MEG data were coregistered to their individual high-resolution structural MRI using three fiducial points, four MEG coils, and the scalp surface, which was digitized using a Polhemus (Supplementary Methods). Using a spherical head model, cortical networks were then imaged at 4.0 × 4.0 × 4.0 mm using the dynamic imaging of coherent sources beamformer (Gross et al., Reference Gross, Kujala, Hamalainen, Timmermann, Schnitzler and Salmelin2001). The DICS approach utilizes the cross-spectral density matrices computed from the sensor-level complex demodulation to estimate the data dependencies. Following convention, these images were normalized per voxel using a separately averaged prestimulus noise period (i.e. baseline) of equal duration and bandwidth (Hillebrand, Singh, Holliday, Furlong, & Barnes, Reference Hillebrand, Singh, Holliday, Furlong and Barnes2005). To assess the anatomical basis of the responses identified through the sensor-level analysis, three-dimensional maps were computed across both conditions and then averaged across all participants. To examine the effects of cannabis use, virtual sensors (i.e. voxel time-series data) were extracted from each participant's data using peak voxels. For each coordinate of interest, the envelope of spectral power was computed for the frequency range used in the beamforming analysis. From this, we computed the relative (i.e. baseline corrected) and absolute (i.e. non-baseline corrected) response time series of each participant per task condition by averaging the absolute amplitude time series across the baseline period (i.e. −600 to 0 ms), and the relative time series across the time windows used for beamforming (i.e. theta: 350–700 ms; alpha/beta: 300–900 ms). Finally, mixed-model ANOVAs were conducted to evaluate changes in task-related neural oscillations during target processing as a function of task validity, cannabis use, and their interaction, while two-sample t tests were used to assess differences in spontaneous baseline activity.

Results

Behavioral analysis

A mixed-model ANOVA of cue-validity, group, and their interaction on reaction time (RT) and task accuracy was conducted. In regard to reaction time, we observed a significant main effect of cue validity (F 1,51 = 107.93, p < 0.0001), such that participants were significantly slower to respond to invalid (M = 1030.2 ms, s.d. = 145.7 ms) compared to valid trials (M = 981.1 ms, s.d. = 143.1 ms). Interestingly, there was no main effect of group (F 1,51 = 0.014, p = 0.907), nor a cue validity-by-group interaction on reaction time (F 1,51 = 1.663, p = 0.203). In regard to task accuracy, we observed no main effect of cue validity (F 1,51 = 1.11, p = 0.297), group (F 1,51 = 3.94, p = 0.053), nor validity-by-group interaction (F 1,51 = 1.11, p = 0.297).

Sensor-level analysis

Since the goal of the study was to investigate the oscillatory dynamics associated with attention allocation during target processing, we focused our analysis on the time periods following target presentation (i.e. after 300 ms). Statistical analyses of the time−frequency spectrograms during the target interval revealed significant clusters of theta (3–6 Hz), alpha (9–13 Hz), and beta (15–23 Hz) oscillatory activity across all participants and conditions (Fig. 2). The significant theta synchronizations began around 50 ms after target presentation and tapered off about 350 ms later (350–700 ms; p < 0.001, corrected). Strong desynchronizations in alpha and beta were much more temporally extended with significant decreases beginning around the onset of the target interval and continuing for ~600 ms (300–900 ms; p < 0.001, corrected).

Fig. 2. Sensor-level analyses during attentional reallocation. Grand-averaged time−frequency spectrogram from a sensor near the left posterior parietal cortex, with time (ms) shown on the x-axis and frequency (Hz) denoted on the y-axis. A color scale bar shown above the spectrogram denotes the percent power change relative to the baseline period (−600 to 0 ms). The data per spectrogram have been averaged across all trials (both valid and invalid) and participants. Strong increases in theta (3–6 Hz) were observed following cue (blue dashed line) and target (white dashed line) onset. Additionally, robust decreases in alpha (9–13 Hz) and beta (15–23 Hz) activity were observed following target presentation.

Beamformer and virtual sensor analysis

Strong increases in theta activity were observed from 350 to 700 ms in the bilateral primary visual cortices, bilateral inferior frontal gyri (IFG), and right dorsolateral prefrontal cortex (dlPFC) (Fig. 3, insets). In contrast, strong decreases in alpha activity were observed from 300 to 900 ms in the lateral occipital gyri (LOG) bilaterally, left primary motor cortex, and bilateral intraparietal sulci (IPS; see Supplemental Materials). In regard to beta, strong decreases were observed from 300 to 900 ms in the bilateral LOG, left primary motor cortex and right superior parietal lobule (SPL; Figure 4, insets). Importantly, alpha and beta decreases in the left primary motor cortex were not further evaluated, as previous work has tightly linked these responses to motor planning and execution processes (Heinrichs-Graham & Wilson, Reference Heinrichs-Graham and Wilson2015; Heinrichs-Graham, Arpin, & Wilson, Reference Heinrichs-Graham, Arpin and Wilson2016; Heinrichs-Graham, Kurz, Gehringer, & Wilson, Reference Heinrichs-Graham, Kurz, Gehringer and Wilson2017; Wilson, Fleischer, Archer, Hayasaka, & Sawaki, Reference Wilson, Fleischer, Archer, Hayasaka and Sawaki2011), which are beyond the goals of the current study.

Fig. 3. Theta activity during target processing. Theta beamformer images (inset top right of each panel) were computed across both conditions and then averaged across all participants. The images are shown in pseudo-t units following the neurological convention (right hemisphere on the right side). Increases in theta activity were observed in the following regions: (A) bilateral primary visual cortices, (B) right dorsolateral prefrontal cortex, (C) left inferior frontal gyrus, and (D) right inferior frontal gyrus. From the peak voxel exhibiting the strongest neural activity (yellow dot), time courses were extracted to evaluate changes in neural response as a function of group (controls: orange; users: blue) and task condition (valid: solid line; invalid: dashed line) during the target processing time window identified through the sensor level analysis (i.e. 350–700 ms; shaded area). Average reaction times across all participants for valid and invalid trials are denoted in red solid and dashed lines, respectively. Bar graphs represent the neural validity effect (i.e. invalid—valid) with error bars reflecting SEM. *p < 0.05; #p = 0.0502. Insets showing occipital responses are in units of pseudo-t values scaled from 8.0 to 12.0 while the other insets are scaled from 5.0 to 6.0.

Fig. 4. Beta activity during target processing. Beta beamformer images (inset) were computed across conditions and then averaged across all participants. The output images are shown in pseudo-t units following the neurological convention (right hemisphere on the right side). Decreases in beta activity were observed in the following regions: (A) lateral occipital gyri and (B) right superior parietal lobule. Time courses (i.e. line graphs) of beta activity from the peak voxel (i.e. yellow dot on beamformer images) in each region were averaged over the beamforming window (i.e. 300–900 ms; gray box) and the difference was calculated across conditions (i.e. invalid – valid) to determine the neural validity effect (bar graphs). Asterisks mark significant neural validity effects (p < 0.05), with error bars reflecting SEM. The inset showing occipital responses is in units of pseudo-t values scaled from 12.0 to 16.0 while the other inset is scaled from 13.0 to 21.0.

To quantify the spectrotemporal dynamics in these regions and evaluate differences in the processing of valid and invalid targets as a function of cannabis use, we used mixed-model ANOVAs with cue validity (valid/invalid), group (users/non-users) and their interaction as factors of interest. Note that we did not collapse across hemisphere for frontal or parietal responses, as there is clear evidence of hemispheric specialization for attention function in these brain regions.

Theta activity increased during target processing in all four regions, with stronger activity elicited during the processing of invalid relative to valid trials (bilateral visual: F 1,50 = 15.20, p < 0.001; right DLPFC: F 1,50 = 24.47, p < 0.001; right IFG: F 1,48 = 52.24, p < 0.001; left IFG: F 1,50 = 60.47, p < 0.001). Activity in the left IFG also demonstrated a significant main effect of group, such that cannabis users exhibited stronger theta activity during target processing compared to controls (F 1,50 = 8.58, p = 0.005). Finally, we observed a significant cue validity by group interaction bilaterally in the IFG (left IFG: F 1,50 = 8.42, p = 0.006; right IFG: F 1,48 = 4.68, p = 0.035) and a trend towards significance in the bilateral visual cortices (F 1,50 = 4.03, p = 0.0502), such that greater theta activity during invalidly cued targets was accentuated in regular cannabis users compared to non-users (Fig. 3). To ensure that the IFG responses were not related to saccadic eye movements during invalid trials, a supplemental sensor-level analysis was performed, and this showed that there were no detectable eye movements in the frontal sensors (online Supplementary Fig. S2).

In contrast to theta activity, alpha power decreased during target processing in the left and right IPS and LOG (online Supplementary Fig. S1). We observed stronger decreases in alpha power during validly cued compared to invalidly cued targets in all three brain regions (bilateral LOG: F 1,50 = 5.00, p = 0.030; left IPS: F 1,50 = 4.35, p = 0.042; right IPS: F 1,51 = 5.71, p = 0.021), but there were no significant main effects of group nor interactions in any region (ps > 0.447).

Similarly, large decreases were also observed in the beta range throughout target processing in the bilateral LOG and right superior parietal lobule. Interestingly, stronger decreases in beta activity were observed during valid compared to invalid trials in the bilateral LOG (F 1,51 = 13.07, p = 0.001), while this effect was not present in the right superior parietal lobule (F 1,50 = 0.971, p = 0.329; Figure 4). Additionally, while there were no main effects of group in either region (ps > 0.603), there was a significant cue-validity by group interaction in the bilateral LOG, such that the neural validity effect (i.e. greater desynchronization during valid v. invalid trials) was greater for regular cannabis users compared to non-users (F 1,51 = 9.28, p = 0.004; Figure 4).

Finally, we evaluated whether regular cannabis use affects spontaneous neural activity (i.e. basal activity) during the baseline, and found that spontaneous theta was significantly decreased in cannabis users relative to non-users in the primary visual cortices, bilateral IFG, and right DLPFC (ps < 0.020; Figure 5). In contrast, baseline activity did not differ in any other regions exhibiting strong alpha/beta oscillations during target processing.

Fig. 5. Spontaneous theta activity during the baseline period. Spontaneous theta activity averaged over the baseline period (−600 to 0 ms) is shown for each spatially defined peak in our beamformer analysis. Basal theta power was significantly reduced in all regions in chronic cannabis users compared to non-user controls. Asterisks mark significant baseline differences between groups (p < 0.05), with error bars reflecting SEM.

Discussion

We used a modified Posner cueing paradigm and MEG to investigate the oscillatory dynamics underlying attentional reorientation in cannabis users and nonusers, and observed robust multispectral modulation of dorsal and ventral attention networks (DAN and VAN, respectively) during attentional reallocation. Importantly, our study was the first to demonstrate cannabis-related changes in task-induced neural oscillations in brain regions known to be critical for attention function. Below, these findings and their implications are discussed further.

Behaviorally, we observed a group-independent RT validity effect such that participants were slower to respond to invalid trails relative to valid trials. This RT cost associated with attention reorientation has been well documented in the Posner cueing paradigm (Posner, Reference Posner1980, Reference Posner2016). Interestingly, there were no group differences or group-by-cue validity interactions in RT or accuracy. These findings show that regular cannabis users in our study were able to perform at the same level as non-users on the Posner cueing task. Some studies (Bosker et al., Reference Bosker, Karschner, Lee, Goodwin, Hirvonen, Innis and Ramaekers2013; Dougherty et al., Reference Dougherty, Mathias, Dawes, Furr, Charles, Liguori and Acheson2013; Huijbregts, Griffith-Lendering, Vollebergh, & Swaab, Reference Huijbregts, Griffith-Lendering, Vollebergh and Swaab2014; Messinis, Kyprianidou, Malefaki, & Papathanasopoulos, Reference Messinis, Kyprianidou, Malefaki and Papathanasopoulos2006; Thames, Arbid, & Sayegh, Reference Thames, Arbid and Sayegh2014) have shown that chronic cannabis users perform worse than non-users while others (Hooper et al., Reference Hooper, Woolley and De Bellis2014; Verdejo-García et al., Reference Verdejo-García, Beatriz Fagundo, Cuenca, Rodriguez, Cuyás, Langohr and De La Torre2013) have shown that both groups perform at the same level. Previously, this relationship between task performance and behavioral outcomes has been found to be task-dependent and influenced by the length of time since last using cannabis, such that, as the abstinence period increases, behavioral defects become less robust or even insignificant (Fried, Watkinson, & Gray, Reference Fried, Watkinson and Gray2005; Hanson et al., Reference Hanson, Winward, Schweinsburg, Medina, Brown and Tapert2010; Lovell et al., Reference Lovell, Akhurst, Padgett, Garry and Matthews2019; Roten, Baker, & Gray, Reference Roten, Baker and Gray2015; Scott et al., Reference Scott, Slomiak, Jones, Rosen, Moore and Gur2018). Considering the short abstinence period (i.e. no use on the day of examination) used in the current study, the lack of behavioral differences between users and controls show that our task was relatively easy (i.e. 98.1% accuracy across group and condition), which was by design, and that any deficits in attention reorientation associated with regular cannabis use, at least as measured by the Posner cueing paradigm, were able to be internally overcome by users through neural compensatory mechanisms.

Recently, MEG analyses have specifically implicated IFG theta-band responses to be a key ventral network mediator involved in shifting the current attentional set to a new location (Proskovec et al., Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018; Spooner et al., Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2020). In the current study, significant cue-validity-by-group interactions were found in the bilateral IFG, such that, regular cannabis users exhibited significantly stronger theta responses during invalidly cued trials relative to validly cued ones compared to controls. Considering the importance of the prefrontal cortices in the reorientation of attention, it seems that regular cannabis users allocated greater neural resources to achieve the same level of attention reorientation as their non-user counterparts. Similarly, cue validity-by-group interactions approached significance (p = 0.0502) for theta responses in the bilateral primary visual cortices, and were significant for beta oscillations in the bilateral LOG. In both cases, the interactions were such that regular cannabis users had larger validity effects compared to non-users, although the directionality was reversed such that cannabis users had stronger theta oscillations in the IFG during invalid relative to valid trials and stronger beta LOG responses to valid relative to invalid trials compared to controls. The theta-band synchronization that was observed in the bilateral primary visual cortices is generally believed to reflect the initial encoding of visual stimuli (Fries, Reference Fries2015; Landau & Fries, Reference Landau and Fries2012), while the alpha- and beta-band desynchronization observed in the bilateral extrastriate regions have been associated with the detection of specific stimulus properties (e.g. shape, color, and location) (Klimesch, Reference Klimesch2012; Neuper & Pfurtscheller, Reference Neuper and Pfurtscheller2001; Proskovec et al., Reference Proskovec, Heinrichs-Graham, Wiesman, McDermott and Wilson2018). Group differences in the strength of theta oscillations in the primary visual and IFG during invalidly v. validly cued trials may reflect the dissemination of greater processing resources during invalid trials in regular users of cannabis. In regard to the stronger beta oscillations in the LOG during valid trials, this appeared to reflect both stronger and earlier responses during valid trials in cannabis users, with similar responses to invalid trials across groups.

In agreement with our findings, several studies in the domains of attention and working memory have found that, though neural differences existed between cannabis users and controls, there were no task-based behavioral differences between the groups (Chang, Reference Chang2006; Eldreth et al., Reference Eldreth, Matochik, Cadet and Bolla2004; Jager et al., Reference Jager, Kahn, Van Den Brink, Van Ree and Ramsey2006; Kanayama et al., Reference Kanayama, Rogowska, Pope, Gruber and Yurgelun-Todd2004). These results suggest that, at least in relatively easy tasks, cannabis users may be able to compensate to maintain the same level of task performance as their non-user peers, and our MEG findings provide at least some support for this contention. Such compensatory neural responses have been observed during task performance in the form of greater BOLD signal amplitude or duration in fMRI and/or the recruitment of neighboring cortical regions (Chang, Reference Chang2006; Eldreth et al., Reference Eldreth, Matochik, Cadet and Bolla2004; Jager et al., Reference Jager, Kahn, Van Den Brink, Van Ree and Ramsey2006; Kanayama et al., Reference Kanayama, Rogowska, Pope, Gruber and Yurgelun-Todd2004).

Another major finding of the current study was that regular cannabis use affected spontaneous cortical activity in attention-related brain regions. Previous work suggests that spontaneous neural activity prior to stimulus onset is modulated by healthy aging and disease-related processes (e.g. HIV-infection) (Casagrande et al., Reference Casagrande, Lew, Taylor, Schantell, O'Neill, May and Wilson2021; Heinrichs-Graham & Wilson, Reference Heinrichs-Graham and Wilson2016; Lew et al., Reference Lew, McDermott, Wiesman, O'Neill, Mills, Robertson and Wilson2018; Rossiter, Davis, Clark, Boudrias, & Ward, Reference Rossiter, Davis, Clark, Boudrias and Ward2014; Spooner et al., Reference Spooner, Wiesman, Mills, O'Neill, Robertson, Fox and Wilson2018; Spooner, Wiesman, Proskovec, Heinrichs-Graham, & Wilson, Reference Spooner, Wiesman, Proskovec, Heinrichs-Graham and Wilson2019; Wiesman et al., Reference Wiesman, O'Neill, Mills, Robertson, Fox, Swindells and Wilson2018). In the current study, we found significant decreases in pre-stimulus theta power in the bilateral primary visual cortices, bilateral IFG, and right dlPFC in regular cannabis users relative to controls, while pre-stimulus alpha and beta activity was unaffected by cannabis use. In regard to mechanism, in vivo and in vitro animal studies have demonstrated that CB1Rs on GABAergic interneurons in the cerebral cortex and hippocampus, which are regulated by the endocannabinoid system, mediate theta- and gamma-band (30–80 Hz) oscillations (Hajos et al., Reference Hajos, Katona, Naiem, MacKie, Ledent, Mody and Freund2000; Hajos, Hoffmann, & Kocsis, Reference Hajos, Hoffmann and Kocsis2008; Katona et al., Reference Katona, Sperlagh, Sik, Kafalvi, Vizi, Mackie and Freund1999; Morgan, Stanford, & Woodhall, Reference Morgan, Stanford and Woodhall2008; Robbe et al., Reference Robbe, Montgomery, Thome, Rueda-Orozco, McNaughton and Buzsaki2006; Skosnik et al., Reference Skosnik, D'Souza, Steinmetz, Edwards, Vollmer, Hetrick and O'Donnell2012). The disruption of GABAergic interneurons by exogenous CB1R agonists (e.g. THC) is thought to mediate decreased baseline theta and gamma power in cannabis users (Skosnik et al., Reference Skosnik, D'Souza, Steinmetz, Edwards, Vollmer, Hetrick and O'Donnell2012; Skosnik, Cortes-Briones, & Hajós, Reference Skosnik, Cortes-Briones and Hajós2016). Specifically, such decreased pre-stimulus theta power has been demonstrated in both acute cannabis use (Böcker et al., Reference Böcker, Hunault, Gerritsen, Kruidenier, Mensinga and Kenemans2010; Ilan et al., Reference Ilan, Smith and Gevins2004) and in abstinent regular users (Herning et al., Reference Herning, Better, Tate and Cadet2003). As such, it is not surprising that theta band spontaneous activity was found to be disrupted in our study of regular cannabis users. Furthermore, the chronic administration of CB1R agonists (e.g. THC) has been shown to cause a dramatic down-regulation and desensitization of CB1 receptors throughout the brain (Bonnet & Preuss, Reference Bonnet and Preuss2017; Sim-Selley, Reference Sim-Selley2003). Studies suggest that it takes about one month of abstinence for CB1R binding to normalize, and this timeframe roughly corresponds to the duration of cannabis withdrawal syndrome (CWS; Bonnet & Preuss, Reference Bonnet and Preuss2017). Interestingly, an EEG study by Herning et al. (Reference Herning, Better, Tate and Cadet2003) found that decreased resting state theta power in regular cannabis users persisted for 28 days of monitored abstinence. Taken together, we believe that the decreased spontaneous theta power observed in regular cannabis users is likely related to disruption of GABAergic interneurons by exogenous CB1R agonists and CB1R habituation (i.e. down-regulation and desensitization).

Before concluding, it is important to note the limitations of this study. First, each cannabis user in our study consumed their own cannabis day-to-day, and thus there were likely individual differences in the potency (i.e. concentration of cannabinoids), route of administration (e.g. smoke, dab, edible consumption, etc.), and composition (i.e. relative amounts of THC and CBD) of the consumed cannabis. These differences may be important because CBD may offset some of the effects of THC (Bloomfield et al., Reference Bloomfield, Hindocha, Green, Wall, Lees, Petrilli and Freeman2019) and minimize the harm (Weinstein, Livny, & Weizman, Reference Weinstein, Livny and Weizman2016). Second, there were differences in the duration of cannabis use in our sample and the impact of such duration differences is unknown. Future studies should directly focus on the impact of duration and potency. Third, the current study utilized relatively small sample sizes and future studies would benefit from including more participants. Additionally, nicotine and caffeine consumption were not directly controlled for in the current study. Finally, all of the cannabis users in our study were recreational users and thus our findings may not extend to medicinal users or those who use for both purposes.

To close, the current study was first to investigate alterations in the neural oscillatory activity underlying attentional reorienting in regular, recreational cannabis users. Briefly, we found that cannabis users had significantly altered oscillatory dynamics in key regions of the DAN and VAN during attentional reallocation relative to controls, as well as altered spontaneous theta in some of the same brain regions. Some of these oscillatory differences may serve a compensatory role and help users to maintain adequate performance. Future studies should further investigate the nature of such neural oscillatory differences and their role in maintaining task performance. Considering the regulatory shifts in the United States and other countries relating to the legality of cannabis use, it is becoming increasingly important that the effects of regular cannabis use are more thoroughly understood, and consequently further research on the cognitive and physiological effects are seriously needed.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291721002671.

Funding Support

This study was supported by the National Institutes of Health through grants R01-DA047828 (TWW), R03-DA041917 (TWW), R01-MH103220 (TWW), R01-MH116782 (TWW), and R01-MH118013 (TWW). The funders had no role in the study design, collection, analysis, or interpretation of data, nor did they influence writing the report or the decision to submit this work for publication. The data presented in this manuscript have not been published or presented elsewhere.

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

Author contributions

T.W.W. contributed to the experimental design. M.S. performed participant recruitment. M.S., J.A.E., and M.R.F. collected data. s.d.S., R.K.S., Y.A., and T.W.W. contributed to data analysis and interpretation. s.d.S. drafted the article. R.K.S., M.D.S., Y.A., and T.W.W. contributed to article revisions. All authors take responsibility for the content of this article.

Conflict of interest

None of the authors report any competing financial or other interests.

References

Arif, Y., Spooner, R. K., Wiesman, A. I., Embury, C. M., Proskovec, A. L., & Wilson, T. W. (2020a). Modulation of attention networks serving reorientation in healthy aging. Aging, 12(13), 1258212597. 10.18632/aging.103515.CrossRefGoogle ScholarPubMed
Arif, Y., Wiesman, A. I., O'Neill, J., Embury, C., May, P. E., Lew, B. J., … Wilson, T. W. (2020b). The age-related trajectory of visual attention neural function is altered in adults living with HIV: A cross-sectional MEG study. EBioMedicine, 61, 103065. doi: 10.1016/j.ebiom.2020.103065CrossRefGoogle ScholarPubMed
Azofeifa, A., Mattson, M. E., Schauer, G., McAfee, T., Grant, A., & Lyerla, R. (2016). National estimates of marijuana use and related indicators — national survey on drug use and health, United States, 2002–2014. MMWR. Surveillance Summaries, 65(11), 128. doi: 10.15585/mmwr.ss6511a1CrossRefGoogle Scholar
Block, R. I., O'Leary, D. S., Ehrhardt, J. C., Augustinack, J. C., Ghoneim, M. M., Arndt, S., & Hall, J. A. (2000). Effects of frequent marijuana use on brain tissue volume and composition. Neuroreport, 11(3), 491496. doi: 10.1097/00001756-200002280-00013CrossRefGoogle ScholarPubMed
Bloomfield, M. A. P., Hindocha, C., Green, S. F., Wall, M. B., Lees, R., Petrilli, K., … Freeman, T. P. (2019). The neuropsychopharmacology of cannabis: A review of human imaging studies. Pharmacology & Therapeutics, 195, 132161. doi: 10.1016/j.pharmthera.2018.10.006CrossRefGoogle ScholarPubMed
Böcker, K. B., Hunault, C. C., Gerritsen, J., Kruidenier, M., Mensinga, T. T., & Kenemans, J. L. (2010). Cannabinoid modulations of resting state EEG θ power and working memory are correlated in humans. Journal of Cognitive Neuroscience, 22(9), 19061916. doi: 10.1162/jocn.2009.21355CrossRefGoogle ScholarPubMed
Bonnet, U., & Preuss, U. (2017). The cannabis withdrawal syndrome: Current insights. Substance Abuse and Rehabilitation, 8, 937. doi: 10.2147/sar.s109576CrossRefGoogle ScholarPubMed
Bosker, W. M., Karschner, E. L., Lee, D., Goodwin, R. S., Hirvonen, J., Innis, R. B., … Ramaekers, J. G. (2013). Psychomotor function in chronic daily cannabis smokers during sustained abstinence. PLoS One, 8(1), e53127. doi: 10.1371/journal.pone.0053127CrossRefGoogle ScholarPubMed
Broyd, S. J., van Hell, H. H., Beale, C., Yucel, M., & Solowij, N. (2016). Acute and chronic effects of cannabinoids on human cognition—A systematic review. Biological Psychiatry, 79(7), 557567. doi: 10.1016/j.biopsych.2015.12.002CrossRefGoogle ScholarPubMed
Carliner, H., Brown, Q. L., Sarvet, A. L., & Hasin, D. S. (2017). Cannabis use, attitudes, and legal status in the U.S.: A review. Preventive Medicine, 104, 1323. doi: 10.1016/j.ypmed.2017.07.008CrossRefGoogle ScholarPubMed
Casagrande, CC, Lew, BJ, Taylor, BK, Schantell, M, O'Neill, J, May, PE, … Wilson, TW. (2021). Impact of HIV-infection on human somatosensory processing, spontaneous cortical activity, and cortical thickness: A multimodal neuroimaging approach. . Human Brain Mapping, 42(9), 28512861. doi: 10.1002/hbm.25408.CrossRefGoogle ScholarPubMed
Chang, L. (2006). Marijuana use is associated with a reorganized visual-attention network and cerebellar hypoactivation. Brain, 129(5), 10961112. doi:10.1093/brain/awl064.CrossRefGoogle ScholarPubMed
Chica, A. B., Bartolomeo, P., & Lupiáñez, J. (2013). Two cognitive and neural systems for endogenous and exogenous spatial attention. Behavioural Brain Research, 237, 107123. doi:10.1016/j.bbr.2012.09.027.CrossRefGoogle ScholarPubMed
Cohen, K., & Weinstein, A. (2018). The effects of cannabinoids on executive functions: Evidence from Cannabis and synthetic cannabinoids—A systematic review. Brain Sciences, 8(3), 40. doi: 10.3390/brainsci8030040CrossRefGoogle ScholarPubMed
Corbetta, M., Patel, G., & Shulman, G. L. (2008). The reorienting system of the human brain: From environment to theory of mind. Neuron, 58(3), 306324. doi: 10.1016/j.neuron.2008.04.017CrossRefGoogle ScholarPubMed
Corbetta, M., & Shulman, G. L. (2002). Control of goal-directed and stimulus-driven attention in the brain. Nature Reviews Neuroscience, 3(3), 201215. doi: 10.1038/nrn755CrossRefGoogle ScholarPubMed
Daitch, A. L., Sharma, M., Roland, J. L., Astafiev, S. V., Bundy, D. T., Gaona, C. M., … Corbetta, M. (2013). Frequency-specific mechanism links human brain networks for spatial attention. Proceedings of the National Academy of Sciences of the United States of America, 110(48), 1958519590. doi: 10.1073/pnas.1307947110CrossRefGoogle ScholarPubMed
Dougherty, D. M., Mathias, C. W., Dawes, M. A., Furr, R. M., Charles, N. E., Liguori, A., … Acheson, A. (2013). Impulsivity, attention, memory, and decision-making among adolescent marijuana users. Psychopharmacology, 226(2), 307319. doi: 10.1007/s00213-012-2908-5CrossRefGoogle ScholarPubMed
Eldreth, D. A., Matochik, J. A., Cadet, J. L., & Bolla, K. I. (2004). Abnormal brain activity in prefrontal brain regions in abstinent marijuana users. Neuroimage, 23(3), 914920. doi:10.1016/j.neuroimage.2004.07.032.CrossRefGoogle ScholarPubMed
Fried, P. A., Watkinson, B., & Gray, R. (2005). Neurocognitive consequences of marihuana—A comparison with pre-drug performance. Neurotoxicology and Teratology, 27(2), 231239. doi: 10.1016/j.ntt.2004.11.003CrossRefGoogle ScholarPubMed
Fries, P. (2015). Rhythms for cognition: Communication through coherence. Neuron, 88(1), 220235. doi: 10.1016/j.neuron.2015.09.034CrossRefGoogle ScholarPubMed
Ganzer, F., Bröning, S., Kraft, S., Sack, P.-M., & Thomasius, R. (2016). Weighing the evidence: A systematic review on long-term neurocognitive effects of cannabis use in abstinent adolescents and adults. Neuropsychology Review, 26(2), 186222. doi: 10.1007/s11065-016-9316-2CrossRefGoogle ScholarPubMed
Gilman, J. M., Yucel, M. A., Pachas, G. N., Potter, K., Levar, N., Broos, H., … Evins, A. E. (2019). Delta-9-tetrahydrocannabinol intoxication is associated with increased prefrontal activation as assessed with functional near-infrared spectroscopy: A report of a potential biomarker of intoxication. Neuroimage, 197, 575585. doi: 10.1016/j.neuroimage.2019.05.012CrossRefGoogle ScholarPubMed
Gross, J., Kujala, J., Hamalainen, M., Timmermann, L., Schnitzler, A., & Salmelin, R. (2001). Dynamic imaging of coherent sources: Studying neural interactions in the human brain. Proceedings of the National Academy of Sciences of the United States of America, 98(2), 694699. doi: 10.1073/pnas.98.2.694CrossRefGoogle ScholarPubMed
Hajos, M., Hoffmann, W. E., & Kocsis, B. (2008). Activation of cannabinoid-1 receptors disrupts sensory gating and neuronal oscillation: Relevance to schizophrenia. Biological Psychiatry, 63(11), 10751083. doi: 10.1016/j.biopsych.2007.12.005CrossRefGoogle ScholarPubMed
Hajos, N., Katona, I., Naiem, S. S., MacKie, K., Ledent, C., Mody, I., & Freund, T. F. (2000). Cannabinoids inhibit hippocampal GABAergic transmission and network oscillations. European Journal of Neuroscience, 12(9), 32393249. doi: 10.1046/j.1460-9568.2000.00217.xCrossRefGoogle ScholarPubMed
Hanson, K. L., Winward, J. L., Schweinsburg, A. D., Medina, K. L., Brown, S. A., & Tapert, S. F. (2010). Longitudinal study of cognition among adolescent marijuana users over three weeks of abstinence. Addictive Behaviors, 35(11), 970976. doi: 10.1016/j.addbeh.2010.06.012CrossRefGoogle ScholarPubMed
Heinrichs-Graham, E., Arpin, D. J., & Wilson, T. W. (2016). Cue-related temporal factors modulate movement-related beta oscillatory activity in the human motor circuit. Journal of Cognitive Neuroscience, 28(7), 10391051. doi: 10.1162/jocn_a_00948CrossRefGoogle ScholarPubMed
Heinrichs-Graham, E., Kurz, M. J., Gehringer, J. E., & Wilson, T. W. (2017). The functional role of post-movement beta oscillations in motor termination. Brain Structure & Function, 222(7), 30753086. doi: 10.1007/s00429-017-1387-1CrossRefGoogle ScholarPubMed
Heinrichs-Graham, E., & Wilson, T. W. (2015). Coding complexity in the human motor circuit. Human Brain Mapping, 36(12), 51555167. doi: 10.1002/hbm.23000CrossRefGoogle ScholarPubMed
Heinrichs-Graham, E., & Wilson, T. W. (2016). Is an absolute level of cortical beta suppression required for proper movement? Magnetoencephalographic evidence from healthy aging. Neuroimage, 134, 514521. doi: 10.1016/j.neuroimage.2016.04.032CrossRefGoogle ScholarPubMed
Herning, R. I., Better, W., Tate, K., & Cadet, J. L. (2003). EEG Deficits in chronic marijuana abusers during monitored abstinence: Preliminary findings. Annals of the New York Academy of Sciences, 993, 7578, discussion 79-81. doi:10.1111/j.1749-6632.2003.tb07513.x.CrossRefGoogle ScholarPubMed
Hillebrand, A., Singh, K. D., Holliday, I. E., Furlong, P. L., & Barnes, G. R. (2005). A new approach to neuroimaging with magnetoencephalography. Human Brain Mapping, 25(2), 199211. doi: 10.1002/hbm.20102CrossRefGoogle ScholarPubMed
Hooper, S. R., Woolley, D., & De Bellis, M. D. (2014). Intellectual, neurocognitive, and academic achievement in abstinent adolescents with cannabis use disorder. Psychopharmacology, 231(8), 14671477. doi: 10.1007/s00213-014-3463-zCrossRefGoogle ScholarPubMed
Huijbregts, S. C. J., Griffith-Lendering, M. F. H., Vollebergh, W. A. M., & Swaab, H. (2014). Neurocognitive moderation of associations between cannabis use and psychoneuroticism. Journal of Clinical and Experimental Neuropsychology, 36(8), 794805. doi:10.1080/13803395.2014.943694.CrossRefGoogle ScholarPubMed
Ilan, A. B., Smith, M. E., & Gevins, A. (2004). Effects of marijuana on neurophysiological signals of working and episodic memory. Psychopharmacology (Berl), 176(2), 214222. doi: 10.1007/s00213-004-1868-9CrossRefGoogle ScholarPubMed
Jager, G., Kahn, R. S., Van Den Brink, W., Van Ree, J. M., & Ramsey, N. F. (2006). Long-term effects of frequent cannabis use on working memory and attention: An fMRI study. Psychopharmacology, 185(3), 358368. doi:10.1007/s00213-005-0298-7.CrossRefGoogle ScholarPubMed
Jager, G., Van Hell, H. H., De Win, M. M., Kahn, R. S., Van Den Brink, W., Van Ree, J. M., & Ramsey, N. F. (2007). Effects of frequent cannabis use on hippocampal activity during an associative memory task. European Neuropsychopharmacology, 17(4), 289297. doi: 10.1016/j.euroneuro.2006.10.003CrossRefGoogle ScholarPubMed
Kanayama, G., Rogowska, J., Pope, H. G., Gruber, S. A., & Yurgelun-Todd, D. A. (2004). Spatial working memory in heavy cannabis users: A functional magnetic resonance imaging study. Psychopharmacology (Berl), 176(3–4), 239247. doi: 10.1007/s00213-004-1885-8CrossRefGoogle ScholarPubMed
Katona, I., Sperlagh, B., Sik, A., Kafalvi, A., Vizi, E. S., Mackie, K., & Freund, T. F. (1999). Presynaptically located CB1 cannabinoid receptors regulate GABA release from axon terminals of specific hippocampal interneurons. Journal of Neuroscience, 19(11), 45444558. doi: 10.1523/JNEUROSCI.19-11-04544.1999CrossRefGoogle ScholarPubMed
Klimesch, W. (2012). Alpha-band oscillations, attention, and controlled access to stored information. Trends in Cognitive Sciences, 16(12), 606617. doi: 10.1016/j.tics.2012.10.007CrossRefGoogle ScholarPubMed
Kovach, C. K., & Gander, P. E. (2016). The demodulated band transform. Journal of Neuroscience Methods, 261, 135154. doi: 10.1016/j.jneumeth.2015.12.004CrossRefGoogle ScholarPubMed
Landau, A. N., & Fries, P. (2012). Attention samples stimuli rhythmically. Current Biology, 22(11), 10001004. doi: 10.1016/j.cub.2012.03.054CrossRefGoogle ScholarPubMed
Lew, B. J., McDermott, T. J., Wiesman, A. I., O'Neill, J., Mills, M. S., Robertson, K. R., … Wilson, T. W. (2018). Neural dynamics of selective attention deficits in HIV-associated neurocognitive disorder. Neurology, 91(20), e1860e1869. doi: 10.1212/WNL.0000000000006504CrossRefGoogle ScholarPubMed
Lopez-Larson, M. P., Rogowska, J., & Yurgelun-Todd, D. (2015). Aberrant orbitofrontal connectivity in marijuana smoking adolescents. Developmental Cognitive Neuroscience, 16, 5462. doi: 10.1016/j.dcn.2015.08.002CrossRefGoogle ScholarPubMed
Lovell, M. E., Akhurst, J., Padgett, C., Garry, M. I., & Matthews, A. (2019). Cognitive outcomes associated with long-term, regular, recreational cannabis use in adults: A meta-analysis. Experimental and Clinical Psychopharmacology, 28(4). 10.1037/pha0000326.Google ScholarPubMed
Macaluso, E., & Patria, F. (2007). Spatial re-orienting of visual attention along the horizontal or the vertical axis. Experimental Brain Research, 180(1), 2334. doi:10.1007/s00221-006-0841-8.CrossRefGoogle ScholarPubMed
Messinis, L., Kyprianidou, A., Malefaki, S., & Papathanasopoulos, P. (2006). Neuropsychological deficits in long-term frequent cannabis users. Neurology, 66(5), 737739. doi:10.1212/01.wnl.0000201279.83203.c6.CrossRefGoogle ScholarPubMed
Morgan, N. H., Stanford, I. M., & Woodhall, G. L. (2008). Modulation of network oscillatory activity and GABAergic synaptic transmission by CB1 cannabinoid receptors in the rat medial entorhinal cortex. Neural Plasticity, 2008, 808564. doi: 10.1155/2008/808564CrossRefGoogle ScholarPubMed
Neuper, C., & Pfurtscheller, G. (2001). Event-related dynamics of cortical rhythms: Frequency-specific features and functional correlates. International Journal of Psychophysiology, 43(1), 4158. doi: 10.1016/s0167-8760(01)00178-7CrossRefGoogle ScholarPubMed
Posner, M. I. (1980). Orienting of attention. The Quarterly Journal of Experimental Psychology, 32(1), 325. doi: 10.1080/00335558008248231CrossRefGoogle ScholarPubMed
Posner, M. I. (2016). Orienting of attention: Then and now. Quarterly Journal of Experimental Psychology, 69(10), 18641875. doi: 10.1080/17470218.2014.937446CrossRefGoogle ScholarPubMed
Proskovec, A. L., Heinrichs-Graham, E., Wiesman, A. I., McDermott, T. J., & Wilson, T. W. (2018). Oscillatory dynamics in the dorsal and ventral attention networks during the reorienting of attention. Human Brain Mapping, 39(5), 21772190. doi: 10.1002/hbm.23997CrossRefGoogle ScholarPubMed
Robbe, D., Montgomery, S. M., Thome, A., Rueda-Orozco, P. E., McNaughton, B. L., & Buzsaki, G. (2006). Cannabinoids reveal importance of spike timing coordination in hippocampal function. Nature Neuroscience, 9(12), 15261533. doi: 10.1038/nn1801CrossRefGoogle ScholarPubMed
Rossiter, H. E., Davis, E. M., Clark, E. V., Boudrias, M. H., & Ward, N. S. (2014). Beta oscillations reflect changes in motor cortex inhibition in healthy ageing. Neuroimage, 91, 360365. doi: 10.1016/j.neuroimage.2014.01.012CrossRefGoogle ScholarPubMed
Roten, A., Baker, N. L., & Gray, K. M. (2015). Cognitive performance in a placebo-controlled pharmacotherapy trial for youth with marijuana dependence. Addictive Behaviors, 45, 119123. doi:10.1016/j.addbeh.2015.01.013.CrossRefGoogle Scholar
SAMHSA (2017). Key substance use and mental health indicators in the United States: Results from the 2016 national survey on drug Use and health. Rockville, MD: Center for Behavioral Health Statistics and Quality, Substance Abuse and Mental Health Services Administration. Retrieved from https://www.samhsa.gov/data/.Google Scholar
Schreiner, A. M., & Dunn, M. E. (2012). Residual effects of cannabis use on neurocognitive performance after prolonged abstinence: A meta-analysis. Experimental and Clinical Psychopharmacology, 20(5), 420429. doi: 10.1037/a0029117CrossRefGoogle ScholarPubMed
Schweinsburg, A. D., Nagel, B. J., Schweinsburg, B. C., Park, A., Theilmann, R. J., & Tapert, S. F. (2008). Abstinent adolescent marijuana users show altered fMRI response during spatial working memory. Psychiatry Research, 163(1), 4051. doi: 10.1016/j.pscychresns.2007.04.018CrossRefGoogle ScholarPubMed
Scott, J. C., Slomiak, S. T., Jones, J. D., Rosen, A. F. G., Moore, T. M., & Gur, R. C. (2018). Association of cannabis with cognitive functioning in adolescents and young adults. JAMA Psychiatry, 75(6), 585. doi: 10.1001/jamapsychiatry.2018.0335CrossRefGoogle ScholarPubMed
Sim-Selley, L. J. (2003). Regulation of cannabinoid CB1 receptors in the central nervous system by chronic cannabinoids. Critical Reviews in Neurobiology, 15(2), 91119. doi: 10.1615/critrevneurobiol.v15.i2.10CrossRefGoogle ScholarPubMed
Skosnik, P. D., Cortes-Briones, J. A., & Hajós, M. (2016). It's all in the rhythm: The role of cannabinoids in neural oscillations and psychosis. Biological Psychiatry, 79(7), 568577. doi: 10.1016/j.biopsych.2015.12.011CrossRefGoogle ScholarPubMed
Skosnik, P. D., D'Souza, D. C., Steinmetz, A. B., Edwards, C. R., Vollmer, J. M., Hetrick, W. P., & O'Donnell, B. F. (2012). The effect of chronic cannabinoids on broadband EEG neural oscillations in humans. Neuropsychopharmacology, 37(10), 21842193. doi: 10.1038/npp.2012.65CrossRefGoogle ScholarPubMed
Spooner, R. K., Wiesman, A. I., Mills, M. S., O'Neill, J., Robertson, K. R., Fox, H. S., … Wilson, T. W. (2018). Aberrant oscillatory dynamics during somatosensory processing in HIV-infected adults. Neuroimage Clinical, 20, 8591. doi: 10.1016/j.nicl.2018.07.009CrossRefGoogle ScholarPubMed
Spooner, R. K., Wiesman, A. I., Proskovec, A. L., Heinrichs-Graham, E., & Wilson, T. W. (2019). Rhythmic spontaneous activity mediates the age-related decline in somatosensory function. Cerebral Cortex (New York, N.Y.: 1991), 29(2), 680688. doi: 10.1093/cercor/bhx349CrossRefGoogle ScholarPubMed
Spooner, R. K., Wiesman, A. I., Proskovec, A. L., Heinrichs-Graham, E., & Wilson, T. W. (2020). Prefrontal theta modulates sensorimotor gamma networks during the reorienting of attention. Human Brain Mapping, 41(2), 520529. doi: 10.1002/hbm.24819CrossRefGoogle ScholarPubMed
Taulu, S., & Simola, J. (2006). Spatiotemporal signal space separation method for rejecting nearby interference in MEG measurements. Physics in Medicine and Biology, 51(7), 17591768. doi: 10.1088/0031-9155/51/7/008CrossRefGoogle ScholarPubMed
Thames, A. D., Arbid, N., & Sayegh, P. (2014). Cannabis use and neurocognitive functioning in a non-clinical sample of users. Addiction Behaviors, 39(5), 994999. doi:10.1016/j.addbeh.2014.01.019.CrossRefGoogle Scholar
Thiel, C. M., Zilles, K., & Fink, G. R. (2004). Cerebral correlates of alerting, orienting and reorienting of visuospatial attention: An event-related fMRI study. Neuroimage, 21(1), 318328. doi:10.1016/j.neuroimage.2003.08.044.CrossRefGoogle ScholarPubMed
Tzilos, G. K., Cintron, C. B., Wood, J. B., Simpson, N. S., Young, A. D., Pope, H. G. Jr., & Yurgelun-Todd, D. A. (2005). Lack of hippocampal volume change in long-term heavy cannabis users. The American Journal on Addictions, 14(1), 6472. doi:10.1080/10550490590899862CrossRefGoogle ScholarPubMed
Verdejo-García, A., Beatriz Fagundo, A., Cuenca, A., Rodriguez, J., Cuyás, E., Langohr, K., … De La Torre, R. (2013). COMT Val158met and 5-HTTLPR genetic polymorphisms moderate executive control in cannabis users. Neuropsychopharmacology, 38(8), 15981606. doi:10.1038/npp.2013.59.CrossRefGoogle ScholarPubMed
Vossel, S., Thiel, C. M., & Fink, G. R. (2006). Cue validity modulates the neural correlates of covert endogenous orienting of attention in parietal and frontal cortex. Neuroimage, 32(3), 12571264. doi: 10.1016/j.neuroimage.2006.05.019CrossRefGoogle ScholarPubMed
Vossel, S., Weidner, R., Driver, J., Friston, K. J., & Fink, G. R. (2012). Deconstructing the architecture of dorsal and ventral attention systems with dynamic causal modeling. Journal of Neuroscience, 32(31), 1063710648. doi: 10.1523/JNEUROSCI.0414-12.2012CrossRefGoogle ScholarPubMed
Weinstein, A., Livny, A., & Weizman, A. (2016). Brain imaging studies on the cognitive, pharmacological and neurobiological effects of cannabis in humans: Evidence from studies of adult users. Current Pharmaceutical Design, 22(42), 63666379. doi: 10.2174/1381612822666160822151323CrossRefGoogle ScholarPubMed
Wiesman, A. I., Groff, B. R., & Wilson, T. W. (2019). Frontoparietal networks mediate the behavioral impact of alpha inhibition in visual cortex. Cerebral Cortex (New York, N.Y.: 1991), 29(8), 35053513. doi: 10.1093/cercor/bhy220CrossRefGoogle ScholarPubMed
Wiesman, A. I., O'Neill, J., Mills, M. S., Robertson, K. R., Fox, H. S., Swindells, S., & Wilson, T. W. (2018). Aberrant occipital dynamics differentiate HIV-infected patients with and without cognitive impairment. Brain, 141(6), 16781690. doi: 10.1093/brain/awy097CrossRefGoogle ScholarPubMed
Wiesman, A. I., & Wilson, T. W. (2019). Alpha frequency entrainment reduces the effect of visual distractors. Journal of Cognitive Neuroscience, 31(9), 13921403. doi: 10.1162/jocn_a_01422CrossRefGoogle ScholarPubMed
Wilson, TW, Fleischer, A, Archer, D, Hayasaka, S, & Sawaki, L (2011). Oscillatory MEG motor activity reflects therapy-related plasticity in stroke patients. Neurorehabilitation & Neural Repair, 25(2), 188193. doi: 10.1177/1545968310378511.CrossRefGoogle ScholarPubMed
Wilson, W., Mathew, R., Turkington, T., Hawk, T., Coleman, R. E., & Provenzale, J. (2000). Brain morphological changes and early marijuana use: A magnetic resonance and positron emission tomography study. Journal of Addictive Diseases, 19(1), 122. doi: 10.1300/J069v19n01_01CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Posner cueing task and behavioral performance. (A) A fixation cross was first presented for 1500 (±50) ms, followed by a cue (green bar) presented to the left or right of the fixation cross for 100 ms. After 200 ms, the target stimulus (box with opening) appeared in either the left or right hemifield for 2500 ms. Participants responded as to whether the opening was on the bottom or top of the target with their index and middle finger, respectively. Validly cued trials (cue location on the same side as the impending target) were presented for 50% of the trials, and a total of 200 trials (both valid and invalidly cued) were completed by each participant. (B) Behavioral performance of all subjects is shown on the y-axis (i.e. reaction time on the left, accuracy on the right) with condition (valid or invalid) on the x-axis. Reaction times were significantly slower during invalid trials compared to valid ones, while accuracy was unchanged as a function of task condition. ***p < 0.001.

Figure 1

Fig. 2. Sensor-level analyses during attentional reallocation. Grand-averaged time−frequency spectrogram from a sensor near the left posterior parietal cortex, with time (ms) shown on the x-axis and frequency (Hz) denoted on the y-axis. A color scale bar shown above the spectrogram denotes the percent power change relative to the baseline period (−600 to 0 ms). The data per spectrogram have been averaged across all trials (both valid and invalid) and participants. Strong increases in theta (3–6 Hz) were observed following cue (blue dashed line) and target (white dashed line) onset. Additionally, robust decreases in alpha (9–13 Hz) and beta (15–23 Hz) activity were observed following target presentation.

Figure 2

Fig. 3. Theta activity during target processing. Theta beamformer images (inset top right of each panel) were computed across both conditions and then averaged across all participants. The images are shown in pseudo-t units following the neurological convention (right hemisphere on the right side). Increases in theta activity were observed in the following regions: (A) bilateral primary visual cortices, (B) right dorsolateral prefrontal cortex, (C) left inferior frontal gyrus, and (D) right inferior frontal gyrus. From the peak voxel exhibiting the strongest neural activity (yellow dot), time courses were extracted to evaluate changes in neural response as a function of group (controls: orange; users: blue) and task condition (valid: solid line; invalid: dashed line) during the target processing time window identified through the sensor level analysis (i.e. 350–700 ms; shaded area). Average reaction times across all participants for valid and invalid trials are denoted in red solid and dashed lines, respectively. Bar graphs represent the neural validity effect (i.e. invalid—valid) with error bars reflecting SEM. *p < 0.05; #p = 0.0502. Insets showing occipital responses are in units of pseudo-t values scaled from 8.0 to 12.0 while the other insets are scaled from 5.0 to 6.0.

Figure 3

Fig. 4. Beta activity during target processing. Beta beamformer images (inset) were computed across conditions and then averaged across all participants. The output images are shown in pseudo-t units following the neurological convention (right hemisphere on the right side). Decreases in beta activity were observed in the following regions: (A) lateral occipital gyri and (B) right superior parietal lobule. Time courses (i.e. line graphs) of beta activity from the peak voxel (i.e. yellow dot on beamformer images) in each region were averaged over the beamforming window (i.e. 300–900 ms; gray box) and the difference was calculated across conditions (i.e. invalid – valid) to determine the neural validity effect (bar graphs). Asterisks mark significant neural validity effects (p < 0.05), with error bars reflecting SEM. The inset showing occipital responses is in units of pseudo-t values scaled from 12.0 to 16.0 while the other inset is scaled from 13.0 to 21.0.

Figure 4

Fig. 5. Spontaneous theta activity during the baseline period. Spontaneous theta activity averaged over the baseline period (−600 to 0 ms) is shown for each spatially defined peak in our beamformer analysis. Basal theta power was significantly reduced in all regions in chronic cannabis users compared to non-user controls. Asterisks mark significant baseline differences between groups (p < 0.05), with error bars reflecting SEM.

Supplementary material: Image

Springer et al. supplementary material

Springer et al. supplementary material 1

Download Springer et al. supplementary material(Image)
Image 483.8 KB
Supplementary material: Image

Springer et al. supplementary material

Springer et al. supplementary material 2

Download Springer et al. supplementary material(Image)
Image 17.6 MB
Supplementary material: File

Springer et al. supplementary material

Springer et al. supplementary material 3

Download Springer et al. supplementary material(File)
File 26.3 KB