Frontoparietal Cortex Controls Spatial Attention through Modulation of Anticipatory Alpha Rhythms

Subjects.

Sixteen right-handed (Edinburgh Inventory) healthy adult volunteers (age range: 20–30 years old; 3 females) with no previous psychiatric or neurological history participated in the main experiment. Their vision was normal or corrected to normal. All experiments were conducted with the understanding and written consent of each participant according to the Code of Ethics of the World Medical Association, and the standards established by the University of Chieti Institutional Review Board and Ethics Committee. A second behavior-only control experiment involved 9 right-handed healthy volunteers (age range: 24–33 years old; 5 females), and checked for visual field differences in stimulus identification (see below). Finally, we enrolled an additional 8 right-handed healthy adult volunteers (age range: 22–31 years old; 4 females) in a separate rTMS experiment designed to control for the effects of cue encoding/attention shifts (see below).

Experimental task.

All studies were conducted at the Institute of Technology and Advanced Bioimaging (ITAB) by the first author (P.C.). The subjects were seated in a comfortable reclining armchair and kept their arms resting on the keyboard of a computer. The computer monitor was placed in front of them at a distance of ∼80 centimeters. The experimental paradigm is shown in Figure 1a. Subjects maintained fixation on a small white cross (subtending 0.7° of visual angle), displayed on a black background at the center of the screen. Every 5.9 ± 1 s (sec) a cue stimulus (a white small filled rectangle subtending ∼0.2° visual angle and overlapping the left or right horizontal segment of the fixation cross) was presented for 200 ms duration, cueing randomly (50%) either a left or right visual field location. After 2 s (stimulus onset asynchrony, SOA), a target stimulus was briefly presented for 70 ms at one of two target locations positioned in the left or right visual field along the horizontal meridian at 0.7° degrees of visual angle from the fixation point. The target stimulus was either the letter L (50%) or the letter T (50%) shown either in the canonical upright orientation (50% of trials) or rotated 180 degrees along the vertical axis (the other 50%). Both letters had a diameter of 0.7° visual angle. The target stimulus appeared on 80% of the trials at the location indicated by the cue (valid trials), and on 20% of the trials at the uncued location (invalid trials) (Posner, 1980). Immediately after the target stimulus, a mask stimulus (130 ms duration) formed by all the possible line segments forming the letter stimuli L or T was presented to interrupt the visual processing of the target shape. The subject's task was to maintain fixation throughout the trial, pay attention covertly to the location indicated by the cue, and discriminate the shape of the target by pressing a left keyboard button (key A) when they saw the letter T (upright or rotated), and a right keyboard button (key L) when they saw the letter L (upright or rotated). The assignment of “target” (T or L) to the specific key for response (A or L) was randomized across subjects. Moreover, subjects were asked to maintain the hands on the keyboard and the sight fixed on the screen so that they could not really see the keyboard. The spatial cue indicated the position of the stimulus, but did not provide any information about the response. This is important to insure that preparatory processes are indeed visuospatial and not motor in origin (Broadbent, 1971). Reaction times and the accuracy of the response were recorded for behavioral analyses.

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Figure 1.

Task and rTMS localization. a, Sequence of events during a trial. b, Magnetic resonance imaging (MRI)-constructed stereotaxic template showing the sagittal (a), coronal (b), and axial (c) projections of the three rTMS sites on the right hemisphere. c, Inflated view of right hemisphere atlas brain with regions of dorsal and ventral attention network as in meta-analysis of He et al. (2007). Regions with coordinates are stimulated with rTMS in this experiment.

Procedures for rTMS and identification of target scalp regions.

To interfere with neural activity during the allocation of spatial attention, we used repetitive transcranial magnetic stimulation (rTMS). The stimulation was delivered through a focal, figure eight coil (outer diameter of each wing 7 cm), connected with a standard Mag-Stim Rapid 2 stimulator (maximum output 2.2 tesla). Individual resting excitability threshold for right motor cortex stimulation was preliminarily determined by following standardized procedure (Rossini et al., 1994; Rossi et al., 2001). The rTMS train was delivered at the onset of the cue stimulus based on the following parameters: 150 ms duration, 20 Hz frequency, and intensity set at 100% of the individual motor threshold. These parameters are consistent with published safety guidelines for TMS stimulation (Wassermann, 1998; Anderson et al., 2006; Machii et al., 2006). While previous studies have successfully used rTMS for studying the role of prefrontal and parietal cortices in target detection and reorienting of attention to sensory stimuli (Pascual-Leone et al., 1994; Hilgetag et al., 2001; Rushworth et al., 2001; Grosbras and Paus, 2002, 2003; Chambers et al., 2004; Thut et al., 2005; Taylor et al., 2007), this experiment concentrates on the anticipatory delay activity between cue and target stimuli.

The experimental design included four conditions of rTMS, pseudorandomized across subjects. In the “Sham” condition, a pseudo-rTMS was delivered at scalp vertex; it was ineffective due to the reversed position of the coil with respect to the scalp surface (i.e., the magnetic flux was dispersed to air). In the FEF, IPS, and PrCe conditions, rTMS interfered with activity at the predetermined scalp sites since we placed the anterior end of the junction of the two coil wings. A mechanical arm maintained the handle of the coil angled at ∼45° away from the midline.

The location of right FEF, IPS, and PrCe locations was automatically identified on the subject's scalp using the SofTaxic navigator system (E.M.S. Italy, www.emsmedical.net), which uses a set of digitized skull landmarks (nasion, inion, and two preauricular points), and ∼30 scalp points entered with a Fastrak Polhemus digitizer system (Polhemus), and an averaged stereotaxic MRI atlas brain in Talairach space (Talairach and Tournoux, 1988). The average Talairach coordinates in the SofTaxic navigator system were transformed through a linear transformation to each individual subject's scalp. This strategy has been successful in previous rTMS studies of posterior parietal cortex and visuospatial attention (Babiloni et al., 2006).

The coordinates of the different cortical regions were based on a recent meta-analysis of task-evoked studies of spatial attention (He et al., 2007) and were as follows: right FEF: 32, −9, 48 (x, y, z); right IPS: 23, −65, 48; right PrCe: 38, −3, 50 (Fig. 1b). The chosen coordinates correspond respectively to the epicenters of the two core regions of the dorsal attention frontoparietal network (IPS, FEF), and one control region in the ventral attention network (PrCe) just lateral and anterior to FEF (vector distance = 8.7 mm) (Fig. 1c). The center of mass of these regions, although close, are reliably different across subjects as they were derived from a meta-analysis of several converging fMRI studies [N = 4 studies including >80 subjects, as described by He et al. (2007)].

Right PrCe is an ideal control region for several reasons. It is part of the ventral attention network that responds to the presentation of targets especially when relevant and unattended. It has been proposed that the ventral attention network contributes a signal for reorienting attention to important stimuli in the environment or “stimulus-driven reorienting” (Corbetta and Shulman, 2002; Corbetta et al., 2008). Therefore, similarly to FEF, right PrCe is sensitive to visual stimuli and attention shifts; but, unlike FEF, it does not respond when these shifts are driven by endogenous expectancies. Its location <1 cm away from FEF (see Fig. 1b,c) makes it ideal to study the effect of rTMS on occipital alpha rhythms given both regions are approximately at the same distance from the parieto-occipital cortex where the alpha rhythms are more prominent.

Electroencephalography recordings.

To assess the physiological impact of rTMS on anticipatory neural activity, we recorded simultaneously EEG activity from the scalp. Specifically, we measured the effect of magnetic stimulation at different cortical loci on the desynchronization of alpha rhythms in parieto-occipital cortex, a reliable physiological index of anticipatory spatial attention modulation (Worden et al., 2000; Yamagishi et al., 2003; Sauseng et al., 2005; Thut et al., 2006).

EEG data were recorded (BrianAmp; bandpass, 0.05–100 Hz, sampling rate, 256 Hz) from 27 EEG electrodes placed according to an augmented 10–20 system, and mounted on an elastic cap resistant to magnetic pulses. Electrode impedance was <5 KΩ. The artifact of magnetic stimulation on the EEG activity lasted ∼10 ms (supplemental Fig. 4a, available at www.jneurosci.org as supplemental material). Two electro-oculographic channels were used to monitor eye movement and blinking. The acquisition time for all data was set from −2 to +2 s after cue stimulus. Approximately 120 EEG trials were collected for each rTMS stimulation site and for each subject. The EEG single trials contaminated by eye movement, blinking, or involuntary motor acts (e.g., mouth, head, trunk, or arm movements) were rejected off-line. To remove the effects of the electric reference, EEG single trials were rereferenced by the common average reference. The common average procedure includes the averaging of amplitude values at all electrodes and the subtraction of the mean value from the amplitude values at each single electrode. The mean number of trials per condition that were artifact-free data was 92 (±11).

Computation of the event-related desynchronization/synchronization.

For the EEG spectral analysis, the frequency bands of interest were low alpha and high alpha. These frequencies were determined in according to a standard procedure based on the peak of individual alpha frequency (IAF) (Klimesch et al., 1998). With respect to the IAF, these frequency bands were defined as follows: (1) low alpha, IAF − 2 Hz to IAF, and (2) high alpha, IAF to IAF + 2 Hz. This power spectrum analysis was based on an FFT approach using the Welch technique and Hanning windowing function. The length of the EEG periods used as an input for FFT was of 1 s. The event-related desynchronization/synchronization (ERD/ERS) of alpha EEG oscillations was obtained using: where E indicates the power density at the “event” (lasting 1 s) and R the power density at the “rest” (lasting 1 s). The ERD/ERS was computed for the IAF-based low and high alpha (supplemental Fig. 4b, available at www.jneurosci.org as supplemental material). The “rest” of ERD/ERS computation was defined as a period from −1.5 to −0.5 s before the cue stimulus. The “event” of ERD/ERS computation was defined as a period from 0.5 to 1.5 s after the cue stimulus. Topographic maps of the alpha ERD/ERS were calculated in the period following the cue stimulus and rTMS stimulation (from 0.5 to 1.5 s after cue onset). The maps were represented on a 3D template cortical model by a spline interpolating function. This model is based on the magnetic resonance data of 152 subjects digitized at Brain Imaging Center of the Montreal Neurological Institute (SPM96).

Statistical analysis.

Statistical comparisons were performed by ANOVAs for repeated measures. We used a Mauchley's test to evaluate the sphericity assumption of the ANOVA, a Green-house-Geisser procedure for the correction of the degrees of freedom based, and Duncan tests for post hoc comparisons (alpha, p < 0.05). For the behavioral analyses on the effects of rTMS we used reaction times (RTs) or percentage of correct responses (Hits) with Condition (Sham, right PrCe, right FEF, right IPS), Side (target stimulus on the right or left side of the screen), and cue Validity (valid or invalid trials) as within-subject factors.

To verify the normal hemispheric lateralization of anticipatory alpha rhythms in parieto-occipital electrodes, we ran an ANOVA for each Condition (Sham, right PrCe, right FEF, right IPS), using the alpha ERD/ERS, separately for low and high alpha sub-bands, respectively, as dependent variable and Hemisphere (contra or ipsi to cue stimulus), and Electrode of interest (parietal or occipital) as within-subject factors,

To test the influence of rTMS on anticipatory EEG alpha rhythms, we used alpha ERD/ERS, separately for low and high alpha sub-bands, respectively, as dependent variable and Condition (Sham, right PrCe, right FEF, right IPS), Hemisphere (right or left hemisphere), and Electrode of interest (parietal or occipital) as within-subject factors.

To test for significant relationships between electrophysiological measures and visual performance, we computed a correlation analysis (Pearson test, p < 0.05) between alpha ERD/ERS (at electrodes P3, P4, O1, O2) during the cue period, and RTs to target stimuli. For this analysis, alpha ERD/ERS values obtained for the three conditions of active rTMS stimulation (right FEF, IPS, PrCe) were normalized with respect to those obtained in the Sham condition according to the following formula: rTMS site − Sham/rTMS site + Sham. This normalization insured that we correlated with behavior the specific changes induced by rTMS over different cortical sites above or below the physiological modulation observed in Sham. The two alpha sub-bands were considered separately (i.e., low- and high-frequency). We used the same formula for the normalization of RTs.

A significant correlation across subjects suggest that the modulation of alpha ERD/ERS induced by rTMS covaries with behavioral performance differently in different individuals. A more stringent relationship is to show a correlation within each subject on a trial-by-trial basis. Trial-by-trial analyses are limited in EEG by low signal-to-noise, but we circumvented this problem through the following procedure. Trials for canonical and rotated targets, which yield on average faster and slower RT, respectively, were separately ranked in faster or slower RTs than the median value. ERD/ESR % change values for each group of trials (faster, slower) and for each condition (canonical, rotated) were averaged to generate four mean alpha ERD/ERS values, one for each category, i.e., canonical-fast, canonical-slow, rotated-fast, rotated-slow. For each stimulation site (FEF, IPS, PrCe, Sham), we ran a within-subject ANOVA on the ERD/ERS % change during the period preceding the target stimuli with Stimulus (canonical, rotated), RT (fast, slow) and electrodes (P3, O1, P4, O2) as within-factors.

Several control analyses were also performed. One ANOVA compared the size of the early sensory evoked components (P1/N1) across conditions for valid trials. Unfortunately, we did not have enough artifact-free trials to perform a proper random-effect analysis of the target-related P1/N1 component comparing valid and invalid trials. Invalid trials were only a small proportion (20%) of the total number of trials and invalid targets were detected with lower accuracy. Another ANOVA compared power changes in the period preceding the cue used to calculate a baseline to verify that rTMS at different cortical sites did not affect the baseline alpha power in both low and high-frequency sub-bands. The ANOVA factors were Condition (Sham, PrCe, FEF and IPS), hemisphere (left, right), and electrodes (P3, O1, P4, O2).

Control experiment.

In a separate rTMS experiment the stimulation was delivered as Sham or on right IPS at two different times: simultaneously to the onset of the cue stimulus (R-IPS t₍₀₎), or 350 ms after the cue (R-IPS t₍₃₅₀₎). The parameters of rTMS and the task were identical to the main experiment. ANOVAs were run with reaction times (RTs) or percentage of correct responses (Hits) as dependent variable, and Condition (Sham, R-IPS t₍₀₎, and R-IPS t₍₃₅₀₎), and cue Validity (valid or invalid trials) as within-subject factors.