Participants

Twenty native Polish speaking volunteers (10 females), mainly students of Adam Mickiewicz University in Poznan, ranging in age from 19 to 24 years (mean age=22.7 years; SD=1.6) participated in two counterbalanced experiments testing their dominant right and non-dominant left hands, respectively. All participants were strongly right-handed (Edinburgh Handedness Inventory index: M=92.9; SD=13.9; Oldfield, Reference Oldfield1971), had normal or corrected-to-normal visual acuity, and none had a history of neurological/psychiatric disorders. All participants completed a pre-scan MRI safety questionnaire, were familiarized with the study protocols, and gave their written informed consents. At study conclusion they were reimbursed financially for their time and efforts, and debriefed. The Bio-Ethics Committee at Poznan University of Medical Sciences approved the protocols and procedures, which conformed to the principles of the 2013 WMA Helsinki Declaration.

The Stimuli and Set-up

Twelve familiar tools were photographed and used as stimuli. Some of these objects, for example a rake or screwdriver, serve as an arm extension, others, namely a hammer or knife, as a reinforcement of the hand. Their most common/typical functions were studied and participants were extensively instructed/trained. Twelve control stimuli with no obvious functions were either natural fragments of wooden sticks or man-made objects. An attempt was made to match graspable parts of these items, their general visual appearance or structural complexity, that is number of parts, and their size/surface area. The examples of stimuli in 3 different orientations are shown in Figure 2A, and all the remaining objects are presented in panel B and C.

Fig. 2 Stimuli and designs. A: Examples of stimuli used in our study. (Left panel) Tools, and (right panel) control objects, presented at 3 different orientations. B: Trial structure and timing of the main study with an event-related design. The stimulus picture was followed by a variable delay interval for grasp planning, and a “Go” cue for the pantomimed execution of the pre-planned grasp. Trials concluded with pseudo-randomly introduced variable inter-trial intervals (ITIs) or rest intervals. C: Trial structure and timing of the localizer scans with a block design. There were 5 blocks in which participants simulated the use of the depicted tools, five blocks of non-tool objects in which participants manually counted the number of object parts, and five blocks of rest periods, all presented in pseudo-random order. The inset at the bottom shows all the remaining objects.

Each object was photographed using a Sony Cybershot DSC H2 digital-reflex camera on a white background, in three different orientations: 0, 135, 225 degrees (as in Garofeanu et al., Reference Garofeanu, Kroliczak, Goodale and Humphrey2004). The 0° orientation, with a tool handle pointing toward 12:00 or 0:00 o’clock, typically demanded an uncomfortable hand rotation for the functional grasp regardless of the hand used. The 135° orientation, with a tool handle pointing between 4 and 5, and the 225° orientation, with a handle pointing between 7 and 8, were less demanding. The former required easier hand rotations for the right, and the latter for the left hand, and as complementary they were also matched for both hands. For non-tools, the objects’ 0° orientation would be associated with the most convenient grasps. Therefore, the 135° and 225° orientations were critical: only in these two conditions hand movement kinematics such as wrist rotations, and grip apertures were matched for tools and non-tools.

All objects were shown in foreshortened perspectives as if viewed by a person standing by the table on which they were put. The images were displayed one at a time, in grayscale, using NordicNeuroLab 40” 4K UHD InroomViewingDevice (http://www.nordicneurolab.com) positioned 60 cm behind the scanner bore and viewed via a mirror attached to the head coil. SuperLab 4.5.4 (http://www.superlab.com) installed on a MacBook Pro computer (with OSX v10.8) was used for stimulus presentation. The beginnings of trials, but not the timing of events within trials, were controlled by the MRI scanner triggers. During grasp planning, participants’ fingers rested on the LU400-Pair response pads (http://cedrus.com/lumina/) positioned near the legs. Hence, grasp movement onsets were recorded. These movements were also constantly monitored by the experimenter to immediately detect incorrect responses, such as movement onsets during planning or wrong hand rotations during grasp performance. Participants’ heads were supported and immobilized with padding. Thus, hand movements during task execution did not easily translate into head displacements.

Procedure

An event-related paradigm was used in the main study. Participants completed two separate sessions on consecutive days, using their dominant right and the non-dominant left hands, counterbalanced. Each functional run comprised of 24 trials, 12 involving tools and 12 non-tools, 6 items of each type per single run, 6 presented at the 0° orientation, and 6 at 135° and 225. Four runs were required to use each of the 12 objects in 135° and 225° orientations. Therefore, each participant was initially tested with 4 pseudorandom orders of tools and non-tools assigned to the first 4 runs. An additional 5^th run comprised pseudorandom combination of all stimuli, counterbalanced across the two sessions.

Thus, each participant received a different sequence of target objects. All stimuli were presented in the same central location marked with a black cross which reminded participants to pay attention to the presented objects. There was no specific instruction about how the grasp planning should be performed. It was emphasized that hand movements and their rotations should be as precise as possible, that an upper arm should remain as static as possible, and head motion must be avoided.

Each trial consisted of an initial variable ISI of 0, 0.25, 0.5, or 0.75 s, which ensured that stimulus onset occurred at variable delays relative to the onset of the acquisition of functional volumes, followed by a 1.5-s visual presentation of a stimulus object and a variable 1.5, 2.5, or 3.5-s delay interval for grasp planning. Subsequently, the “GRASP” cue, a central green circle lasting 1.5 s, was shown to prompt participants to simulate preplanned grasps. A trial concluded with an obligatory variable inter-trial interval (ITI) of 2.5, 3.5, or 4.5 s plus time required for synchronization with the scanner trigger. Notably, each object type was followed equally often by each of the 3 delay intervals. Similarly, each grasp type was also followed equally often by each of the 3 ITIs. In each run there were also six additional 5.5-s periods introduced pseudorandomly between trials with the longest ITIs, which resulted in six 10-s time intervals serving as resting baseline. Trial structure and timing is shown in Figure 2B. The timing of events within trials is consistent with an oversampling method (Miezin, Maccotta, Ollinger, Petersen, & Buckner, Reference Miezin, Maccotta, Ollinger, Petersen and Buckner2000) suitable for rapid, event-related fMRI testing.

Additional Localizer Scans

All participants were tested in a functional Tool Use Localizer (TUL) whose goal was to independently reveal the areas belonging to the PRN. Importantly, our TUL involved simulated grips and subsequent tool use pantomimes. The control task was “manual counting” of non-tool parts, wherein an inversion of a palm with an extended index finger meant one part, the index finger and thumb meant two parts, and an inversion of a palm and the extension of a thumb, index, and middle finger meant three or more parts. Notably, native speakers of Polish do not count this way; typically, the hand is positioned as in a hitch-hiking gesture and counting starts with a thumb. A single stick or shaft was treated as having one part, few objects had two distinct parts, while some objects were more complex and by definition would have three or more parts.

There were five 24-s blocks of a pantomimed “grasp-and-tool-use” task in response to 12 tool stimuli displayed for 2 s, and five 24-s blocks of counting parts in response to 12 non-tool stimuli shown for 2 s. Additional five 24-s blocks of rest periods were introduced pseudorandomly between task blocks. Time structure and timing is illustrated in Figure 2C. The stimuli and their number was exactly the same as in the main experiment. Participants were to disregard changes in orientation during TUL. There were two different pseudorandom orders of task and rest blocks assigned pseudorandomly across hands used on a given day and testing sessions.

Data Acquisition

Scanning was performed on a Siemens (Erlangen, Germany) 3 Tesla Trio MRI scanner in the Laboratory of Brain Imaging (http://lobi.nencki.gov.pl) at the Nencki Institute of Experimental Biology (http://en.nencki.gov.pl) in Warsaw, Poland. The MRI scanner was equipped with echo planar imaging (EPI) capabilities and a 32-channel PA head coil for radio frequency transmission and signal reception. Before the beginning of functional runs, Auto Align Scout and True FISP sequences were used to help with slice prescription. The blood-oxygen-level-dependent (BOLD) echoplanar images were collected using a T₂ ^*-weighted gradient echo sequence: time repetition (TR)=2000 ms; time echo (TE)=30 ms; flip angle=90°; 64 × 64 matrix; field of view (FOV)=200 mm; 35 contiguous axial slices, 3.1-mm isotropic voxels.

There were 145 volumes acquired in each run of the main experiment, and 194 volumes in each of the localizer scans. High-resolution T₁-weighted structural images were acquired using magnetization prepared rapid gradient echo (MP-RAGE) pulse sequence: TR=2530 ms; TE=3.32 ms; inversion time (TI)=1200 ms; FA=7°; 256 × 256 voxel matrix size; FOV=256 mm; 176 contiguous axial slices; 1.0-mm isotropic voxels. To enhance registration between functional EPIs and structural T1-weighted images, fast spin echo T2-weighted structural images were also acquired with the following parameters: TR=3200 ms; TE=402 ms; FA=120°; 512 × 512 voxel matrix size; FOV=256 mm; 176 contiguous sagittal slices; 0.5-0.5-1 mm non-isotropic voxels. Raw data were converted to NIFTI-1 format with MRI-Convert software (http://lcni.uoregon.edu/downloads/mriconvert).

Image Analyses

Structural T1- and T2-weighted images were processed using FSL (FMRIB’s Software Library, http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/) v5.0.6 (Jenkinson, Beckmann, Behrens, Woolrich, & Smith, Reference Jenkinson, Beckmann, Behrens, Woolrich and Smith2012) and FreeSufer v5.3 (Fischl, Reference Fischl2012). MP–RAGE scans were first averaged using FMRIB Linear Image Registration Tool because for all participants two such images were obtained. Further pre-processing involved a pipeline described by Bidula and Kroliczak (Reference Bidula and Kroliczak2015). Functional images were analyzed with FSL’s FMRI Expert Analysis Tool v.6.00 (Jenkinson et al., Reference Jenkinson, Beckmann, Behrens, Woolrich and Smith2012). The non-brain tissues were removed using the FSL’s Brain Extraction Tool, and head motion was corrected with the FSL motion correction algorithm. The average absolute head displacement equaled 0.162 mm (the range was 0.04–0.61 mm) when participants used the right hands, and 0.176 mm (0.06–0.43 mm) when the left hands were used. The images were spatially smoothed with a Gaussian kernel of full-width-half-maximum=6.2 mm (twice the voxel size), and temporally smoothed using high-pass filtering σ=50.0 s.

Each fMRI run was analyzed separately at the first level. Before statistical analyses, autocorrelation in the data was corrected using a pre-whitening procedure (Woolrich, Ripley, Brady, & Smith, Reference Woolrich, Ripley, Brady and Smith2001). Hemodynamic responses were modeled using a double-gamma function. In the main experiment, planning-related activity was modeled as the 3.0-s period beginning with the onset of the stimulus picture and lasting through the end of the shortest 1.5-s delay interval (see Figure 2B). Execution-related activity was modeled as the 1.5-s period during which the “grasp” cue was visible.

In the localizer experiment, activity from the whole 24-s blocks was modeled. The runs from a given experiment were averaged using the fixed effects model. The group analyses were performed using random-effects components of mixed-effects variance modeled and estimated with FLAME Stage 1 procedure (Beckmann, Jenkinson, & Smith, Reference Beckmann, Jenkinson and Smith2003). The resulting Z (Gaussianized t/F) statistic images were thresholded using the FSL’s settings of Z>3.1, p=.001, and corrected for multiple comparisons using clusterwise significance threshold of p=.05. Namely, family-wise error rate (FWER) was controlled at α=0.05 (Eklund, Nichols, & Knutsson, Reference Eklund, Nichols and Knutsson2016).

Hand-independent activity was obtained using inclusive contrast masking (Nichols, Brett, Andersson, Wager, & Poline, Reference Nichols, Brett, Andersson, Wager and Poline2005). To directly compare neural activities across hands and tasks, 2 (Hand: right, left) × 2 (Task: grasp planning, grasp execution or pantomimed tool use) repeated-measures analyses of variance (ANOVAs) were run. Anatomical locations of clusters with significant activity were established with help from the Juelich Histological, and Harvard-Oxford probabilistic atlases implemented in the FSL. These clusters were visualized using the CARET software mapping onto the human Population-Average, Landmark- and Surface-based (PALS) brain atlas (Van Essen, Reference Van Essen2005).

Region of Interest Analyses

Six regions of interest (ROIs) for the right, and six for the left hand were created: cMTG, aSMG, rMFG, the caudal superior parietal lobule (cSPL), ventral premotor cortex (PMv), and dorsal premotor cortex (PMd). They were 5-mm radius spheres centered on peak voxels from clusters involved in planning functional versus control grasps. Using FSL FEATQuery, mean percent signal change values within these ROIs were calculated from all voxels for planning functional or control grasps versus resting baseline. Subsequently 2 (Hand: right, left) ×2 (Task: planning, execution) × 2 (Object: tool, control) repeated-measures ANOVAs were run separately for each ROI from the two sets, with post hoc Bonferroni correction for multiple comparisons.