The role of the l-IPS in the comprehension of reversible and irreversible sentences: an rTMS study

In all languages, sentence comprehension requires information at different levels to be computed and integrated. Regardless of the language spoken by an individual, correctly establishing who/what is taking which part in the event described by the verb is essential for sentence interpretation. To understand a sentence like The girl watches the tree‚ for example, the listener must identify the girl as the one who is doing the action (the agent), and the tree as what the action is being performed on (the patient/theme). This process requires the integration of syntactic and semantic information.

Word order is an important syntactic dimension in sentence comprehension. In S-V-O languages like Italian and English, words usually appear in canonical order in active sentences (agent-verb-theme), and in non-canonical order in passive sentences (theme-verb-agent). Therefore, the processing of passive sentences is more demanding. Unsurprisingly, children learn to produce passives later than actives (e.g., Kirby 2010). Evidence that passive sentences pose a greater computational load than active sentences has been provided by several studies (see for example Ferreira (2003); Meyer et al. 2012). Processing cost in passives is increased by the fact that, due to the presence of the auxiliary verb and of the by-phrase, they are also longer and structurally more complex than actives. Finally, sentences in the passive voice are used less frequently than active sentences. In languages with an S-V-O structure, in active sentence the syntactic role of the subject always matches the semantic role of the agent (subject = agent), so that one can apply a rule according to which the first constituent corresponds to the role of agent; in passive sentences, instead, there is a mismatch between syntactic and semantic roles (subject ≠ agent = theme; object ≠ theme = agent). This means that in all languages with an S-V-O structure the systematic rules driving the assignment of thematic roles are equivalent. English and Italian, for example, share the same S-V-O structure, so they are completely interchangeable.

Sentence comprehension is also modulated by semantic dimensions. In semantically irreversible sentences, only one constituent can be the agent. In the active sentence La ragazza guarda l’albero (The girl watches the tree), word order and semantic constraints greatly facilitate thematic role assignment. In the corresponding passive sentence L’albero è guardato dalla ragazza (The tree is watched by the girl)‚ non-canonical word order makes role assignment less easy. In this case, agent and theme roles can still be assigned based solely on semantic knowledge. In semantically reversible sentences, however, both constituents can be agent or theme. Therefore, comprehension requires syntactic processing. In active sentences (La ragazza bacia il ragazzo—The girl kisses the boy), canonical word order facilitates thematic role assignment. In passive sentences (Il ragazzo è baciato dalla ragazza—The boy is kissed by the girl), however, word order is non-canonical and semantic knowledge cannot constrain thematic role assignment. Due to non-canonical word order and semantic reversibility, these sentences must be re-analysed and thematic roles re-assigned (Chomsky 1965, 1981; Pollard and Sag 1994; Bresnan 2000).

The neuroanatomical bases of sentence comprehension, particularly of passive and semantically reversible sentences, have been investigated in several studies, focusing on both normal and clinical populations, as well as involving different techniques (lesion studies via Voxel-based Lesion Symptom Mapping (VLSM), fMRI studies, and TMS studies in neurologically intact volunteers). For a recent review of neuroimaging data see Walenski et al. (2019).

Historically, the neural mechanisms underlying the comprehension of reversible sentences were first investigated indirectly in studies focusing on language disorders of aphasic patients (see for example Caramazza and Zurif 1976; Caplan and Futter 1986; Grodzinsky 2000; Love et al. 2008; Thompson and Choy 2009). The inability to comprehend and produce sentences as a consequence of the inability to map thematic roles onto syntactic roles and vice versa was reported in two individuals with aphasia suffering from damage to left parieto-temporal regions (Caramazza and Miceli 1991; Martin and Blossom-Stach 1986). These early, almost anecdotal observations have been replicated by more systematic investigations. Thothathiri et al. (2012) used VLSM (Bates et al. 2003) in a large group of aphasic participants. Poor comprehension of reversible sentences, resulting in role reversal errors, correlated significantly with damage to the left temporo-parietal cortex, but not with lesions in the inferior frontal gyrus. These results are consistent with other VLSM studies (see Dronkers et al. 2004 or Bates et al. 2003) and with an investigation of PET metabolism in patients with aphasia, that found a correlation between parieto-temporal damage and the comprehension of sentences of varying syntactic complexity (Caplan et al. 2007, 2015). Evidence from these studies is consistent with the hypothesis that parieto-temporal areas are critical for the comprehension of reversible sentences, perhaps because they are involved in thematic labeling in non-canonical sentences, such as passive declaratives. Similar results were reported by Rogalsky et al. (2018), who studied the comprehension of canonical and non-canonical reversible sentences in patients with chronic focal cerebral damage through a VLSM approach. They found maximal overlap in left posterior superior temporal and inferior parietal regions.

A number of neuroimaging investigations on cognitively unimpaired participants provides converging evidence (for reviews see Meyer and Friederici 2015; Rodd et al. 2015; Martin et al. 2015; Walenski et al. 2019). For instance, an fMRI study by Richardson et al. (2010) evaluated the impact of semantic reversibility on the comprehension of semantically reversible sentences over a range of syntactic structures. The contrast between reversible and irreversible sentences showed activation in a lateral portion of the left posterior-superior temporal gyrus and in an inferior parietal region.

Neuromodulation studies provide additional support for the role of left parietal regions in the comprehension of reversible sentences. Finocchiaro et al. (2015) delivered transcranial magnetic stimulation (rTMS) to three sites along the l-IPS, in order to investigate their contribution to thematic role assignment during a sentence comprehension task. Experimental stimuli consisted of active and passive, semantically reversible sentences. In agreement with predictions, rTMS to the posterior l-IPS site selectively increased performance accuracy on reversible passives, while leaving performance on reversible actives unaffected.

The increasing evidence in support of the involvement of inferior parietal regions in the assignment of thematic roles raises fundamental questions on the functional role of the inferior parietal lobe in sentence comprehension. The aim of the present work is to shed light on the specific contribution of this region to sentence comprehension and more specifically to thematic role mapping.

The results in Finocchiaro et al. converge with available lesion data and neuroimaging investigations in supporting the idea that parietal regions are critical for the comprehension of reversible sentences. However, the study’s experimental stimuli included only reversible sentences. This leaves the mechanisms underlying the observed effect unclear. Thematic re-analysis is required for sentences in which syntactic cues (word order) or semantic cues (reversibility) are insufficient to constrain thematic role assignment. This is the case for reversible passives. In these sentences, however, re-analysis could be triggered and/or constrained by several features of the stimulus. To establish whether passive diathesis, semantic reversibility, or both are involved in re-analysis, and to analyze in greater detail the role of l-IPS in sentence comprehension, reversible and irreversible, active and passive stimuli were included in the present rTMS study.

During a sentence comprehension task, focal rTMS was delivered online to the posterior part of l-IPS. This site was selected because in Finocchiaro et al. (2015) only stimulation of this portion affected performance accuracy on reversible passives, whereas rTMS on anterior and middle l-IPS sites had no effect. In addition, lesion and neuroimaging studies converge in assigning this region a role in the comprehension of reversible sentences. Stimuli were organized in a 2 × 2 design: sentences could be either active or passive, and reversible or irreversible. We wished to understand whether the effect is due to passive diathesis or semantic reversibility per se, or to a combination of the two. If the effect were driven by reversibility, both active and passive reversibles should be affected by rTMS; on the contrary, if diathesis per se were relevant, the effect should involve passive sentences regardless of semantic reversibility.

A sample of 136 sentences was prepared. Of these sentences, 120 were used as experimental stimuli; the remaining 16 served as practice items. The following procedure was used in stimulus preparation.

A preliminary set of sentences was created. Sentences included commonly used nouns (e.g. architetto, architect, bambina, girl) and verbs (e.g., colpire, hit) that could be used in both reversible and irreversible stimuli. The sentences presented during the experimental procedure contained 30 verbs. Each verb was paired with two sets of two nouns. In one set both nouns were animate, while in the other set a noun was animate and the other inanimate. As a result, each verb was used to generate two reversible and two irreversible sentences (one active, one passive). Hence, four types of sentences were prepared: reversible active sentences (RA), reversible passive sentences (RP), irreversible active sentences (IA), and irreversible passive sentences (IP). Examples of each sentence type are presented in Table 1.

Word frequency was controlled based on an Italian corpus (Bertinetto et al. 2005). Raw frequency values were used to obtain log frequencies before finalizing the list, to exclude extremely frequent or infrequent verbs/nouns. The log frequency of words in reversible and irreversible sentences was comparable. Word length was also balanced across reversible and irreversible sentences. Given the presence of the auxiliary verb and of the by-phrase, passive sentences were systematically 2 syllables longer than actives. In a pilot study, reversible and irreversible sentences were comparable for response times and performance accuracy.

A training procedure was administered before the actual experiment. Training sentences included four verbs, each of which was presented in the four contexts (RA, RP, IA and IP).

To establish the numerosity of our sample, we estimated an "ideal" sample size based on previous data in the relevant literature. The ideal number of participants was 14 for α = 0.05 and ten for α = 0.01. Since we adopted a within-participants design, in which all participants took part in two experimental sessions, we decided to set our sample size at 24. We also calculated the size of our effect based on the data we collected. In particular, we compared means of real vs sham significant post hoc contrasts (Cohen's d = 0.5, Glass's delta = 0.43 and Hedges's d = 0.53).

24 native Italian speakers (healthy and right-handed) were tested (f = 15, m = 9; mean age = 24.70, SD = 2.34). All participants were students from the University of Trento. They had unimpaired or corrected-to-normal vision, and had no prior history of neurological conditions, seizures, or psychiatric symptoms. For each participant, a structural MRI was used to accurately identify the area that would be targeted by rTMS stimulation. To establish eligibility for the rTMS study, each participant completed a safety questionnaire. All participants read and signed a consent form before the experiment started. The testing protocol was authorized by the Ethical Committee of the University of Trento.

Each participant took part in two experimental sessions, spaced by 1 week. Overall, the experiment required ~ 1.5 h per participant.

During the experiment, participants were seated in front of a computer screen. They were asked to read a sentence presented at the center of the screen and to answer the question presented at the beginning of each block by pressing one of two keys on the computer keyboard (2-alternative, forced choice task). The experiment was run on the E-Prime software.

Six blocks with the identical structure were created. Two served as practice, while the remaining four were the experimental blocks.

At the beginning of each block participants were presented with one of the following instructions written on the computer screen:

Each instruction applied to an entire sentence block (n = 30). Participants were asked to identify the agent in one half of the blocks, and the theme in the other half (see Table 2 for examples). Task demands were diversified across blocks to reduce the likelihood that participants would develop a systematic strategy. For example, if all blocks had been of the ‘identify-the-agent’ type, the correct response to irreversible stimuli could be obtained by systematically looking for the inanimate constituent that would appear to the right of the verb in actives (“La bambina mangia la mela—The girl eats the apple”) and to the left of the verb in passives (“La mela è mangiate dalla bambina—The apple is eaten by the girl”). Blocks were counterbalanced so that two ‘agent’ or two ‘theme’ blocks were not administered consecutively (ABBA or BAAB). The same stimuli were presented in the real and sham conditions.

Accuracy and RT measures were also collected.

Four experimental blocks were prepared, each containing 30 sentences. Half of the sentences in each block were active and the other half were passive. Each block had the following structure:

30 sentences:

- 15 active sentences (alternately seven or eight reversible)

- 15 passive sentences (alternately eight or seven irreversible)

Trials in each block were randomized and counterbalanced across participants. As mentioned above, participants had a fixed response window of 3000 ms. First, all responses were standardized by converting RT scores into z scores. For RT analyses, responses that exceeded this temporal window, as well as responses faster or slower than the mean RT of each subject by ≥ 2 SD, were excluded. Overall, 4.3% of the responses were excluded. For performance accuracy, responses that exceeded the fixed temporal window were excluded from the analyses. (Fig. 1 shows the experiment timeline).

The experiment was run in two conditions: real-TMS and sham-TMS. Each participant completed both conditions. The order of sessions (sham, real vs real, sham) was counterbalanced across participants. Participants received three biphasic pulses at 5 Hz starting from stimuli onset via a MC-B70 butterfly coil and a MagPro Compact stimulator (MagVenture). Hence, pulses were administered at stimulus onset (0 ms), at 200 ms, and at 400 ms (see Fig. 1). The sham-TMS was administered by inserting a spacer between the TMS coil and the scalp. Before starting the experiment, the individual visible resting motor threshold (RMT) was calculated as the lowest stimulation intensity applied over the primary motor cortex which produces more than five visible twitches of the right hand out of ten stimuli. Stimulation intensity during the experiment was set at 90% of the individual visible resting state motor threshold (RMT).

The stimulator was triggered by the E-Prime software through the parallel port. TMS was delivered in an event-related fashion, time-locked to the presentation of visual stimuli.

A structural MRI of each participant was available for spatially accurate administration of TMS. Structural images (T1 sequences) were previously acquired through a Prisma Siemens 3 T MRI scan. Stimulation sites were identified on individual 3D brain reconstructions based on macroanatomical landmarks. Before each session, the participant's head, the TMS coil, and the 3D reconstruction of brain and scalp from individual MRI images were co-registered in space by means of the Softaxic Neuronavigation System using a Polaris Spectra camera. Coil position was checked online via the Softaxic Neuronavigation System and was adjusted to the target location based on reconstructions of individual brain anatomy. To locate the spot to be stimulated, the intraparietal sulcus was identified and its length was divided into three segments. Subsequently, the midpoint of the most posterior segment was marked as the TMS target (Fig. 2 shows the anatomy and target points for all subjects).

For each participant, we also compared the localisations of the stimulation sites based on the 3D reconstructions of individual MRIs (native space) to the corresponding stimulation targets based on MNI coordinates. Mean coordinates on the MNI space corresponded to: x = − 22.2 (SD =  ± 4.13); y = − 79.8 (SD =  ± 3,06); z = 53.2 (SD =  ± 4,13). Table 3 shows the MNI coordinates for each participant. Figure 3 shows the mean stimulation point across participants, plotted on a template (spm152).

Statistical analyses were run on the sham vs TMS contrast for each experimental condition (irreversible active (IA), irreversible passive (IP), reversible active (RA) and reversible passive (RP)). Table 4 compares descriptive statistics for the sham and TMS contrast in all experimental conditions.

The experiment followed a 2 × 2 × 2 design: Stimulation (Real vs. Sham); Diathesis (Active vs. Passive); Reversibility (Reversible vs. Irreversible).

To study the effect of stimulation on response times, we used linear mixed-effects regression (LMER). Analyses were performed on jamovi (version 1.2) (The jamovi project, 2020; retrieved from: https://​www.​jamovi.​org/​). The General analyses for linear models (GAMLj) jamovi module was used (Gallucci M., 2019; retrieved from https://​gamlj.​github.​io/​). In our model, we wanted to see how differences in RT scores in STIMULATION (real-TMS vs sham-TMS) were able to explain differences in DIATHESIS (active vs passive) and REVERSIBILITY (reversible vs irreversible), taking into account the amount of inter-subject variability in these differences.

Results showed a main effect of DIATHESIS (F(1, 23) = 44.379, p < 0.001) and REVERSIBILITY (F(1, 23) = 30.880, p < 0.001). No main effect of STIMULATION was found ((F(1, 138) = 0.167, p = 0.683). The effects found on all 2-way interactions failed to reach significance: DIATHESIS × REVERSIBILITY (F(1, 138) = 2.936, p = 0.089), DIATHESIS × STIMULATION (F(1, 138) = 2.064, p = 0.153) and REVERSIBILITY × STIMULATION F(1, 138) = 2.349, p = 0.128). Remarkably, a 3-way interaction of all the factors DIATHESIS × STIMULATION × REVERSIBILITY was found F(1, 138) = 4.223, p = 0.042), showing that stimulation significantly influenced response times (see Fig. 4). To further explore this effect, Bonferroni’s Post Hoc Comparisons were performed (see Table 5). These contrasts showed that stimulation affected response speed only on reversible passive sentences (RP). In particular, TMS increased RT on RPs, while having no affect on performance during reversible active sentences (RA) (Fig. 5). No effect of stimulation was found on irreversible sentences (IA, IP).

Performance accuracy was analyzed in the same way as response times. Table 6 compares descriptive statistics for the sham and TMS contrast in all experimental conditions. Overall, stimulation did not affect performance accuracy in either experimental condition. Significant main effects of DIATHESIS (F(1,40.1) = 18.51640, p < 0.001), and REVERSIBILITY (F(1,161) = 74.88433, p < 0.001) were observed. In addition, no interaction effects were found: DIATHESIS × REVERSIBILITY (F(1,161) = 0.82296, p = 0.366), DIATHESIS × STIMULATION (F(1,161) = 0.00241, p = 0.961), REVERSIBILITY × STIMULATION (F(1,161) = 0.31636, p = 0.575), DIATHESIS × STIMULATION × REVERSIBILITY (F(1,161) = 0.39822, p = 0.529). See Figs. 6 and 7 for a graphical presentation of the results.