Pilot study

Using the online experimental platform, Gorilla Experiment Builder (www.gorilla.sc – Anwyl-Irvine et al., Reference Anwyl-Irvine, Massonnié, Flitton, Kirkham and Evershed2020b), a small number of participants participated in a pilot study (adults: N = 2, infants N = 4). As previously mentioned, Gorilla Experiment Builder can access a participant’s webcam and record, with their consent, but this feature is in Beta, and has its limitations. One of which is its inability to simultaneously record a participant and the experiment, or precisely what the participant sees on screen and when. While the timing of stimuli presentation and duration can be precisely programmed into the experiment on Gorilla Experiment Builder, when the experiment is run on a participant’s device, some variability may exist because of the differences in devices used, internet browsers, and internet connection speeds, though timing accuracy does seem quite stable (Anwyl-Irvine et al., Reference Anwyl-Irvine, Dalmaijer, Hodges and Evershed2020a). Another potential variable aspect of the webcam recording feature is a delay in the command from Gorilla requesting access to a participant’s webcam, and the point at which the recording starts. Although this can be up to 500ms according to one of the developers (personal communication, 23rd May, 2021), we found only marginal delays (10-20ms) through piloting. Additionally, a design feature was added to the experimental design (see below) to note which trials began recording before visual stimulus onset, and which did not.

Piloting the experiment on adults and infants was crucial to devise satisfactory solutions to these limitations and to decide how to best minimise variability in executing the experiment online. Email correspondence with parents and viewing the data that were successfully generated allowed us to make a set of small changes to the paradigm. Differences between the pilot and test are described below in the Procedure section.

Participants

Participants were recruited through the University of Plymouth BabyLab database and Facebook page. Following recommendations for minimum sample sizes for infant studies that are based on a simulation study of the systematic effect of sample size on the results of infant studies (N = 20-32; Oakes, Reference Oakes2017), 20 monolingual British English-learning infants (13 boys, 7 girls) were tested. The target sample size was reached before analyses of the data. The mean age of participants was 24 months 3 days (range 23 months 3 days - 25 months 28 days). Participants were considered ineligible if they spoke more than one language, were born more than six weeks prematurely, or had a diagnosed language or developmental delay. No participants had to be excluded on these bases. For each of our three experiments, parental education was measured on a scale from 1 to 6 (1= primary education - 6= postgraduate degree) with the highest value taken from either parent (e.g., Mäkinen et al., Reference Mäkinen, Laaksonen, Lahelma and Rahkonen2006; Mossakowski, Reference Mossakowski2008).

Materials

A total of twenty-four target words (e.g., bed, key) were selected which were familiar, common, highly-imageable nouns known by at least 60% of English monolingual 18-month-olds according to the Oxford Communicative Development Inventory (Hamilton et al., Reference Hamilton, Plunkett and Schafer2000) and the UK CDI (UK-CDI Database, 2016) (see Table 2 for the list and exact percentages). All words were monosyllabic.

Table 2. Experiment 1. Percentage of 18-month-olds with knowledge of the stimuli words used in the online IPL task

Auditory stimuli were recorded individually by a female adult with a neutral south-west British accent. The carrier word “Look!” was also recorded separately. Visual stimuli were colour photographs from the internet, cut out from their background and placed centrally on a light grey background to reduce brightness on the screen. Two versions of each image were created: one for presentation on the left of the screen, and one for the right. Animate objects were positioned to face the centre of the screen.

Target words were organised into word pairs in which there was no semantic or phonological overlap. The twelve pairs formed one block. In each pair, one word acted as the target and the other as a distractor. The distractor words then became the targets in the second block of trials, and these were paired with a different word that had acted as a target in the first block.

Procedure

Through piloting, the following modifications were made to the experimental design and procedure:

• - Participants were restricted to using a laptop or computer. Those without such a device were deemed ineligible. This criterion was set to ensure visual stimulus presentation would be as large and as predictably positioned as possible. Gorilla Experiment Builder’s default positioning of two adjacent images is to space them as far apart, to each edge of a device’s screen as possible.

• - The experiment was programmed to only run on the web browser Google Chrome as there were some upload and display issues with other browsers.

• - A calibration phase was added at the start of the experiment to ensure a participant’s screen was not working in a ‘flipped’ mode, and to validate that, when an image was presented on the right only, the child looked to the right.

• - A short beep of 100ms was added to coincide with the visual stimulus onset. In the absence of seeing when the pictures appeared on screen in a participant’s webcam recording, the beep was a feature to enable the coder to have a reference point when manually coding eye movement offline. Each trial was checked for the presence of the beep during analysis, to ensure that the webcam recording started ahead of the images being presented on screen.

• - Trials were divided into two blocks and separated using a short video to maintain attention. As the experiment could not be driven by the child’s attention to the screen on every trial, the short video was a way of re-focusing the child if they had lost interest. Piloting showed inattention to be very infrequent.

• - A duration of 500ms was added to each trial, resulting in the images remaining on screen for 5500ms (compared to 5000ms in a typical lab-based experiment). This was to compensate for any potential clipping towards the end of the recording.

All of our studies were approved by the University of Plymouth Faculty of Health Ethics Committee. Parents were invited to participate in the study through the Plymouth BabyLab database and through adverts posted to the BabyLab’s social media accounts. When a parent expressed interest, further communication moved to email. A participant information sheet was issued and the technical requirements for the online study were reiterated through email communication. A day and time were agreed, on which to complete the study. On the appointed day, an email with instructions for the study was sent to the parent and a unique link to the experiment was activated on the Gorilla Experiment Builder website. By using a unique link, it meant participants could leave the experiment and return to it later, continuing where they left off. The reason behind establishing a day and time to do the online experiment was to ensure a researcher could be available for any questions or support required while participants did the taskFootnote ¹. Parents were instructed to begin the procedure without their child present, to minimise the time a child would need to stay engaged. It was made clear that the parent would be instructed when to prepare their child for the task.

When clicking on the Gorilla Experiment Builder weblinkFootnote ², an overview of the study was displayed, including the eligibility criteria for participation. The next screen was an eligibility questionnaire, to ensure participants were the right age; were not born more than six weeks prematurely; were exposed only to English; and did not have a language or developmental delay. At this point, a participant could be excluded in which case the parent would see an ineligibility screen and be asked to email the Plymouth BabyLab if they believed this to be incorrect, or if they wanted to find out about other studies running that their child might be eligible for.

If eligible, a participant had to consent to the study by completing an online questionnaire which detailed the procedure, the data collected and the right to withdraw. Demographic information was collected in a series of short online questionnaires before the experiment startedFootnote ³.

Following this, participants progressed to a technical eligibility check so they could test their sound and webcam before the experiment, and to grant Gorilla access to webcam recording. A Gorilla pop-up appeared in the web browser asking for consent to access the webcam, at which point a parent could refuse access if they did not agree to their data being accessed in this way. Furthermore, the recording test established the audio and video recording capabilities of a participant’s device and it also allowed parents to playback the recording to fully understand the footage that would be recorded of their child when the experiment began. Throughout the procedure, an ‘Exit’ button was made available in the bottom left-hand corner of the screen in case a participant chose to withdraw from the studyFootnote ⁴. There was explicit mention in the instructional email that a participant should click on this ‘Exit’ button if they wanted to withdraw and to request, by email, the withdrawal of any data collected on their child up to that point if they desired, without any explanation for their decision.

The experimental procedure began by instructing the parents to place their child on their lap, with their device’s webcam focused on their child’s eyes. Detailed instructions were provided, using images, so that the parent could see how to prepare their child for the experiment. Rough measurements were provided (e.g., place the device at arm’s length, mirroring what other researchers were trialing at the time for online experiments), and opportunities were available for the parent to perform test recordings before they began testing. Based on all this information, the parent deemed when the position of their child was satisfactory, and when they were ready to begin the task. Parents were instructed not to engage with their child when starting the experiment.Footnote ⁵

The experiment was preceded by four calibration trials in which the word “Look” was followed by the word “biscuit” and an image of a biscuit appeared on the left-hand side of the screen. This process was repeated on the left side with the word “monkey” and a corresponding image. The two words were then repeated with the same images now appearing on the right-hand side of the screen. Neither of the words were used as targets, or distractors on critical trials. The calibration phase established a baseline for the participant’s individual looking pattern and validated that the image was presented on the correct side and not in a ‘flipped screen’ mode.

The parent controlled the start of the word recognition task by clicking on a button. The experiment began with a 5000ms black and white attention-getting video showing simple geometric shapes accompanied by sound. Then, the automatic presentation of trials began and did not stop in their delivery until all trials had been presented, which lasted for about three minutes.

Each experimental trial began with a smiley fixation point in the centre of the screen for 1000ms to focus the child’s attention to the middle of the screen. This was replaced by two visual stimuli, positioned on the left and right sides of the screen for 5500ms. In an equivalent lab-based study, a trial would last 5000ms but an additional 500ms was added in case of clipping at the end of the recording. The auditory stimuli began with a beep for 100ms to coincide with the visual stimulus onset, necessary for analysis. This preceded a silence and the carrier ‘Look’ before the target word onset at 2500ms. Each trial was thus divided into a 2500ms pre-naming and 2500ms post-naming window (see Figure 1).

Figure 1. Experiment 1. Trial timeline. Onset of the auditory label of the target picture was always at 2500ms.

After 12 trials, the same attention-getting video from the start was played to maintain the child’s attention before a second block of 12 trials resumed. The video also separated the two blocks in which visual stimuli acted as targets in one block and distractor pictures in the other. The order of blocks was counterbalanced. The side of the target visual stimulus was counterbalanced. The experiment ended with the same ‘reward’ video that was played at the start and middle of the experiment.

To complete the procedure, the parent marked a list of target words as known or unknown to the child, before a final debrief screen, inviting any questions or comments and a chance to mark whether any technical difficulties had been experienced during the tasks.

After completion of the full procedure, a participant’s data were downloaded, and the calibration trials were checked to confirm audio and video recording was satisfactory. Questionnaires were reviewed to see if the participant had experienced any technical issues or if further information relating to their responses in the questionnaires was required. A final email was sent, requesting clarification pertaining to comments in the questionnaires (where necessary) and issuing a certificate and £5 Amazon voucher to acknowledge participation. The final email also included a short debrief of the study’s aims and application and invited the participant to ask questions if necessary.

Participants

A total of 19 parents with monolingual children (10 boys and 9 girls) aged 17 months, ranging 16 months 4 days to 18 months 10 days, were recruited from the Plymouth Babylab database (with the same inclusion criteria). They were all residents of Plymouth and its surroundings and had signed up to the Babylab to take part in any proposed studies.

Stimuli

The audio stimuli were two nonsense consonants–vowel labels: neem and lef recorded in infant-directed speech (IDS). IDS is efficient in capturing and keeping the attention of infants (Fernald, Reference Fernald1985). These stimuli highly differ in articulation and a highly dissimilar nonsense consonant-vowel noun, pok, was used during the pre- and post-test trials.

An English-speaking female from the South West of England produced several tokens of each syllable in a rise-fall intonation phase, in an infant-directed speech (Fennell & Werker, Reference Fennell and Werker2003; Stager & Werker, Reference Stager and Werker1997). Following Fennell and Werker (Reference Fennell and Werker2003), the final stimuli contained 10 exemplars, each lasting approximately 0.7 sec, including a 1.5-sec silent interval between each exemplar, resulting in audio files of 22.5 sec in duration.

The stimuli were shown as 3D moving objects to highly attract and maintain infants’ attention (Baldwin, Reference Baldwin1989; L. B. Cohen, Reference Cohen1973; Fennell, Reference Fennell2012). A trophy topper was used for both the pre- and post-tests (see Figure 3a) and a marker toy windmill object was used for the habituation and test trials (see Figure 3b). During the trials, the two objects spinned, moved back and forth. The video clips were edited via the Photos laptop Windows application. The Switch task was administered online with the Zoom app using computer/laptop devices and it was recorded through the Zoom app for coding purposes.

Figure 3. Experiment 2. (a) Trophy topper and (b) Marker toy windmill new objects.

Material

Zoom was chosen as the platform of testing for this experiment because unlike many other virtual technologies, it includes advantages that can be used for research purposes. Indeed, according to Archibald et al. (Reference Archibald, Ambagtsheer, Casey and Lawless2019), Zoom’s capacity to safely record and store sessions without any other third-party software is one of the advantages of protecting sensitive research data. Also, they reported that the capacity to back-up recordings to online server networks such as “the cloud” or local drives, is an additional security benefit as it allows for recordings to be shared safely for teamwork and real-time encryption (Zoom Video Communications Inc., 2016).

Pilot

Using Zoom, a small number of participants participated in a pilot study (N = 9). Piloting the experiment was essential to test the quality of the stimuli (video and sound), the data collection and to check how many habituation trials were needed for this online Switch task. A laptop Lenovo ThinkPad and the Photos app in Windows 10 were used to create, edit the video stimuli, and conduct the experiment. Participants were asked to operate with a computer or laptop to ensure satisfactory visual stimulus presentation.

A limitation of testing online with Zoom was the impossibility of controlling the pace of the trial presentation due to our specific set-up using the auto-advance feature of the Photo app. Therefore, all trials were presented at once without being able to control when to present the next one (as in Experiment 1 using Gorilla). Piloting showed that looking times noticeably declined after 4 trials, therefore the habituation phase was set at 4 trials for further data collection.

Procedure

The parent was sent via email the consent and information forms. At the same time, the parent completed a Communicative Development Inventory (short form of the Oxford CDI, Hamilton et al., Reference Hamilton, Plunkett and Schafer2000). The Oxford CDI is a list of words that are typical in children’s vocabularies. Parents were asked to tick whether their child could understand and/or say the words on the list. Then, the parent and child were invited to participate in the online Switch task.

Contrary to Experiment 1 where the researcher was not in the same virtual space as the child, here the researcher, the parent and the child were connected on Zoom together. The researcher was sitting in front of a laptop, while the child was sitting at home in front of the family electronic device. The session was video recorded. The child was asked to look at the computer’s screen and the parent sat in a chair next to his/her child. It should be noted that the researcher was not visible to the infant during the testing task.

When the child was attentive, the researcher started a 3min30s video to the participant consisting of 8 trials from the Switch task including a short clip of 30s (a talking bunny chasing a flying kite) to test if the participant’s devices’ sound and camera were correctly working. The infants were tested using a modified habituation paradigm, similar to the structure used by Werker et al. (Reference Werker, Cohen, Lloyd, Casasola and Stager1998) but with only one word-object pairing and not two, as in Fennell and Waxman (Reference Fennell and Waxman2010). Also, it was modified for the trial duration (increased from 14 sec to 22.5 sec). Each trial started with a flashing red light to get the infant’s attention on the screen. On the first trial, infants were presented with a pre-test stimulus: the label pok paired with the trophy topper. This pre-test stimulus was re-presented at the end of the experiment, during the post-test phase, and acted as a control of infants’ attention. During the following habituation phase, the infant was shown one word–object pairing (word neem and object toy windmill). After exactly 4 trials, the habituation phase ended, and was followed by the test phase. One test trial was the “same” trial, in which the word-object pair presented during the habituation phase was shown again to the infant. The other test trial, called the “switch” trial, contained the familiar toy windmill object but was paired with a novel word lef. The order of presentation of the trials was counterbalanced across participants. If infants had learned the pairing, it was expected that they would notice the switch and look longer during the “switch” trial than during the “same” trial (Fennell & Werker, Reference Fennell and Werker2003). In the final post-test trial, the child was presented again with the word pok and the trophy topper. It was expected that if infants remained engaged throughout the experiment, the looking time during this last trial would be similar to the looking time during the pre-test trial (Fennell & Werker, Reference Fennell and Werker2003) (see diagram in Figure 4 for more details).

Figure 4. Experiment 2. Diagram of the online Switch task.

Results

Table 5 provides the descriptive data for the children’s ages, gender (10 boys and 9 girls), parental education, income deprivation scores, CDI scores and looking times.

Table 5. Experiment 2. Descriptive data of the whole sample

Note. Difference score is the difference between the looking time to same and switch trials.

To ensure that infants did not lose interest throughout the experiment, a paired sample t-test was conducted to compare looking time on the pre-test versus post-test trial. Contrary to what was expected (Fennell, Reference Fennell2012; Werker et al., Reference Werker, Fennell, Corcoran and Stager2002), children were significantly more engaged at the beginning of the task during the pre-test (M = 19.67, SD = 5.39) than during the post-test (M = 14.95, SD = 7.80, t(18) = 3.85 p = .001).

The main set of analyses addressed infants’ performance on the test trials. A paired sample t-test revealed a significant main effect for test trials, with the children looking longer to the switch trial (M = 17.89, SD = 5.52) than the same trial (M = 13.37, SD = 7.96), t(18) = -2.31, p = 0.03, Cohen’s d = 0.53. There was no main effect of gender and age on looking times. Thus, the 17-month-old infants exposed to the first pairing of word-object did notice the switch in label (see Figure 5).

Figure 5. Experiment 2. Mean looking times to same and switch trials for each child.

A Pearson correlation was conducted between vocabulary knowledge as assessed by the CDI (see Table 2 for vocabulary statistics) and the performance on the Switch task as indexed by the “switch” versus “same” difference score in order to determine whether vocabulary size is related to children’s Switch task performance (Werker et al., Reference Werker, Fennell, Corcoran and Stager2002). The correlation was not significant for comprehensive, r(17) = -.54, p = .816, nor for production scores, r(17) = -.34, p = .883. Age and gender did not have a significant effect on children’s performance either.

Discussion of Experiment 2

In this second experiment, 17-month-old infants successfully learned the association between a new object and a new label, as indexed by their longer looking time in switch trials as compared to same trials. Thus, they were able to encode phonetic detail when learning a new word, which is consistent with previous in-lab findings (e.g., Stager & Werker, Reference Stager and Werker1997; Yoshida et al., Reference Yoshida, Fennell, Swingley and Werker2009). Our results are also consistent with Bulgarelli and Bergelson’s (Reference Bulgarelli and Bergelson2022) which showed that younger infants successfully performed the one-word Switch task on Zoom.

No significant relation was found between vocabulary size and performance on the minimal-pair word-learning task, which is not in line with Werker et al. (Reference Werker, Fennell, Corcoran and Stager2002). They found that at 14 months, both comprehensive and productive vocabulary size correlated with performance on the Switch task, and at 17 months, the correlation was found for comprehension only. However, they did not find an association between vocabulary size and performance success on the Switch task at the age of 20 months. It must be pointed out that many previous studies did not find a consistent relation between vocabulary knowledge as assessed by the CDI and word recognition (Hamilton et al., Reference Hamilton, Plunkett and Schafer2000; Swingley & Aslin, Reference Swingley and Aslin2000). According to Werker et al. (Reference Werker, Fennell, Corcoran and Stager2002), this would imply that vocabulary knowledge is only predictive of the phonetic detail when children are first building their vocabulary. After the vocabulary reaches some critical threshold, as measured by either comprehension or production, the relation is no longer consistent.

Another unexpected finding is that we did not find a renewed interest in the post-test phase as compared to the pre-test, suggesting that children’s interest in the task decreased as the trials went on. It should be noted that Bulgarelli and Bergelson’s (Reference Bulgarelli and Bergelson2022) Switch task did not have a post-test phase and therefore cannot speak to whether attention recovery was comparable to offline testing. One first reason for our finding is that we used a fixed familiarisation phase, due to technical limitations, contrary to previous researchers who applied a sliding habituation criterion (e.g., Bulgarelli & Bergelson, Reference Bulgarelli and Bergelson2022; Fennell & Waxman, Reference Fennell and Waxman2010; Werker et al., Reference Werker, Fennell, Corcoran and Stager2002). Therefore, some of our participants might have lost interest by the time the test phase ended. Maintaining children’s interest and engagement for a prolonged period of time can be a limitation of online methods, at least for the Switch task. Another reason might be that our selection of new objects might have been less interesting than, for example, the objects used by Fennell (Reference Fennell2012). Also, the effect size obtained in our study (Cohen’s d = 0.53), which is smaller than the effect size of 1.04 by Bulgarelli and Bergelson (Reference Bulgarelli and Bergelson2022), was noticeably higher than the average effect size of 0.32 computed in the meta-analysis by Tsui et al. (Reference Tsui, Byers-Heinlein and Fennell2019), which might potentially suggest a robust online replication of the main finding in the Switch task – that is, that children react to a change of word-object pairing. It should be noted that this interpretation cannot be certain as we cannot know whether our results reveal the robustness of the effect or an over-estimate of the effect size.

Experiment 3: Language assessment task in 19 to 26 months

Developmental language research typically involves the estimation of children’s language knowledge, which tends to rely on parental questionnaires like the MacArthur CDI (Fenson et al., Reference Fenson, Marchman, Thal, Dale, Reznick and Bates2006). However, there are situations where a face-to-face assessment is needed, to complement or replace a parental questionnaire. In this experiment, a comparison between a parental report of the child’s vocabulary knowledge and a vocabulary test directly administered to the child was explored (regardless of the setting). But most importantly, we also asked whether administering a test online would provide equivalent data to running it face-to-face. Most available language tests have been standardised with face-to-face data, with clinical evaluation requiring a face-to-face assessment of a child’s language skills. It was an open question as to whether similar scores could be obtained for an online and a face-to-face version of the same standardised test. This is a pragmatic question: could early years professionals, practitioners and researchers trust data obtained in a virtual space? In our third experiment, we collected data with a standardised language assessment test, the WinG test (Cattani et al., Reference Cattani, Krott, Dennis and Floccia2019) to estimate toddlers’ vocabulary knowledge, either online or in the Babylab. It was expected that children’s performance on the WinG test would be affected by the environment the test is administered in (home vs Babylab). Our initial hypothesis was that face-to-face children would outperform online children on the WinG test, because it would be more difficult to maintain their attention remotely, and because sound and picture quality might get in the way of a clear communication.

Parents were also asked to fill in the Oxford CDI, which they would do similarly in their own time, whether the session would take place online or in the lab, and therefore the setting (online or face-to-face) was not expected to affect the CDI scores. Additionally, we analysed whether our WinG scores collected were positively correlated with the CDIs scores. Indeed, when the external validity of the WinG was assessed, a subsample of children performed one or more other language assessments including the Oxford CDI. The receptive score of the CDI was significantly positively correlated with the WinG comprehension subtests (noun (n = 116) and predicate (n = 104) separately). Similarly, the expressive score of the CDI was significantly positively correlated with the production subtests (noun and predicate separately) of the WinG (WinG manual: Cattani Krott et al., Reference Cattani, Krott, Dennis and Floccia2019).

A sample size of 60 participants was chosen for a study described in another manuscript, which examined the relationship between children’s vocabulary knowledge and parental screen time. Before reaching the sample size target, we did not analyse and compare the results of the online and face-to-face groups.

Participants

Seventy children were tested and the data from 8 children were excluded due to the non-full completion of the WinG test (4 online and 4 face-to-face participants). The final sample included sixty-two healthy monolingual infants (31 boys and 31 girls) aged 19 to 26 months who were recruited from the Plymouth Babylab database with the same inclusion criteria as before. Thirty-two participated in the experiment online due to Covid restrictions at the time of testing and thirty were invited to do it face-to-face in the Babylab when restrictions were lifted. Participants were recruited the same way but were not randomly assigned to participate in the experiment remotely or face-to-face as a result of the COVID-19 pandemic. Forty-six parents completed the CDI (16 from the online group and 30 from the face-to-face group).

Materials

After completing a consent form, parents first filled in a demographic questionnaire to collect information about the family’s socioeconomic status (SES). Then, they were invited for their child to do a language test, the WinG test (Cattani et al., Reference Cattani, Krott, Dennis and Floccia2019), either online, or in the Babylab. At the same time, they were asked to complete the Oxford CDI, prior to the WinG test or during the visit to the Babylab. Parents were also involved in another task related to their usage of screens, with data reported elsewhere (Nguyen, Reference Nguyen2024).

For the video chat condition, the WinG was administered online with the Zoom app using computer/laptop devices. The test consists of 44 groups of 3 cards, 4 pre-tests and 40 experimental. Each set of 3 cards contains a comprehension card, a production card and a distractor card. The comprehension task contains 20 noun words and 20 predicate words, the production task also contains 20 noun words and 20 predicate cards. For each of the four components, a standardised score and percentile can be calculated for the number of correct answers that should be reached for each age and each gender. Following the WinG recommendations, only the comprehension tasks for both the noun and predicate were administered with children aged from 19 to 24 months old, whereas for children aged 24 to 26 months, the production task for the noun score was additionally given. The WinG scoring sheet was used to code the child’s answers, as included in the WinG manual. For the video chat condition, the WinG test was recorded through the Zoom app, and children’s responses were transcribed later. For the face-to-face experiment, the WinG test was recorded on a Canon video camera and responses coded afterwards.

Procedure

The parent was sent via email the consent and information forms. Then, the parent and child were invited to participate in the WinG game test.

For the Zoom session, the WinG cards were set standing against a cardboard box on a table, so that the cards would be visible through the child’s screen. The researcher was sitting in a chair behind the table and a laptop was placed in front of the table, facing the picture cards. The child was in a room at home and sat in front of the electronic device using Zoom and the parent sat in a chair next to their child.

For the face-to-face language test condition, the parent and child were invited to enter the Babylab, in which the WinG cards were set upon a table, with two chairs adjacent to each other on the table (for the child and the experimenter). The parent was sitting beside their child. The camera recorded the session to code offline the responses from the WinG test on the scoring sheet.

The WinG test was administered in line with the instructions from the WinG manual (Cattani et al., Reference Cattani, Krott, Dennis and Floccia2019), where children were invited to pick up or touch the card corresponding to a target word (in the comprehension task). However, for the WinG test online with Zoom, children could not touch or take the cards. Instead, they were asked to point to their computer’s screen at the correct card. The session was video recorded, and the child’s answers were scored offline according to their hand gesture and/or eye gaze going to the right, middle or left card. The WinG test started with 2 pre-tests of 3 cards each to give the child practice of what is required for the game. The 3 cards were presented in a random order in a line in front of the child, one comprehension, and 2 distractor cards. The children were first asked to point out or touch the named comprehension card; once they pointed to one of the cards, it did not matter if it was the right one. Then, the comprehension and distractor cards were taken away to move on to the next set of cards (see diagram in Figure 6). This was repeated for the next set of pre-test cards, all 20 experimental noun cards, the 2 sets of pre-test cards for the predicate condition and all 20 experimental predicate cards. Praise was always regularly provided, irrespective of the child’s answers.

Figure 6. Experiment 3. Diagram of the structure of the WinG.

The WinG test was performed to the best of the child’s ability, lasting around 30 minutes. Not all children can stay focused during the entire length of the testing session. Following the WinG manual, when a child began to show signs of boredom or restlessness, they were offered a short break (e.g., getting a snack or drink). When the child was ready to resume testing, the administrator restarted from the last set of pictures before the break. If necessary, the test was stopped and was resumed another day within one week. The data collected for this study were the children’s percentile score for noun comprehension and predicate comprehension as calculated by the standardised scores in the WinG manual. Moreover, the two parents’ highest educational levels were used as the SES. The parent’s postcode was collected with the demographic questionnaire and was used as a proxy for income, leading to the income deprivation score (IDS). The IDS were obtained from a government website (Ministry of Housing, Communities, and Local Government, 2019). The scores hold significance and correspond to the percentage of the relevant population experiencing that type of deprivation in that area. So, for instance, if an area receives a score of 0.27, it indicates that 27 percent of the population in that area is experiencing income deprivation. The larger the score, the more deprived the area.

It should be noted that the production task data were not reported here because none of the online children did the production task of the WinG test (as they were less than 24 months old and the WinG production part can only be tested on children older than 24 months), so we could have not compared production scores between the online and face-to-face participants.

Results

Table 6 provides the descriptive data for the children’s ages, gender (31 boys and 31 girls), parental education, income deprivation scores, CDI scores, and WinG scores.

Table 6. Experiment 3. Descriptive data of the sample

There was an absence of correlation between parental education and the income deprivation score (r = -.062, N = 77, p = .63). Therefore, only parental education was kept as the SES indicator as it is usually the best predictor of children development (Davis-Kean et al., Reference Davis-Kean, Tighe and Waters2021; Duncan & Magnuson, Reference Duncan, Magnuson, Bornstein and Bradley2003).

First, participants from the two groups were compared on demographic measures. The online group included 16 boys and 16 girls, and the in-person group had 14 boys and 16 girls. Online participants had similar educational levels (M = 4.94, SD = 0.70) to the in-person parents (M = 4.70, SD = 0.91; t(60) = -1.15, p = .25). Children from the online group were about a month younger (M = 649.22, SD = 54.14) than those in the in-person group (M = 685.73, t(60) = -2.35, p = 0.02).

Then correlations were made between the CDI scores and the WinG scores. No associations were found between the CDI comprehension scores and the WinG comprehension (neither on nouns nor on predicates) scores. Our sample might have not been large enough to detect a relation between the CDI and WinG scores.

Next, independent t-tests were conducted to compare the online and face-to-face children’s WinG performances. The results were adjusted by the Bonferroni correction (Abdi, Reference Abdi and Salkind2007) as the nouns and predicates are both measures of comprehension. Thus, the significance value was divided by 2 and adjusted to 0.025.

It should be noted that standardised WinG scores incorporate age and gender. Online children performed significantly better on the WinG test noun comprehension (M = 45.47, SD = 22.05) than face-to-face children (M = 28.00, SD = 22.27); t(60) = 3.10, p = .003. Similarly, online children did better at the WinG test predicate comprehension (M = 45.94, SD = 21.08) than the in-person group (M = 33.83, SD = 19.73), t(60) = 2.34, p = .023. Figure 7 illustrates the comparison of the online and in-person performances on the noun comprehension.

Figure 7. Experiment 3. Comparison of WinG comprehension scores between online participants (N = 32) and face-to-face participants (N = 30).

On CDI comprehension, a regression model forcing age, parents’ education, gender and the type of performance (online/in-person) led to a significant model (R² = .32, F(4,41) = 4.83, p = .003) with only age as a significant contributor (β = .15, t = 4.09, p <. 001). On CDI production, the same regression model led to a significant model (R² = .37, F(4,41) = 5.90, p = .001) with only age (β = .20, t = 3.44, p = .001) and gender (β = 17.52, t = 2.50, p = .016) as significant predictors.

Independent t-tests were conducted to compare the online and face-to-face groups on their CDI comprehension and production scores. No corrections for multiple comparisons were made as comprehension and production vocabulary scores are different measures of language. Results indicated that there were no significant differences on the CDI comprehension between online children (M = 68.06, SD = 16.57) and in-person children (M = 71.03, SD = 18.11); t(44)= 1.06, p =. 57. Also, there were no significant differences on the CDI production between online participants (M = 26, SD = 20.56) and face-to-face participants (M = 39.52, SD = 31.18); t(44) = -1.60, p = .12. Children who were tested online did not have significantly higher scores on the CDI. It supports the finding that online participants outperformed those who did the language test at the Babylab, but only for the WinG test. However, having no significant differences on the CDI scores between the online and face-to-face groups does not establish that there is no difference between the two groups, which we will discuss further in the discussion.

Discussion of Experiment 3

In this last experiment, we investigated the reliability of using a language assessment test, the WinG, online as compared to face to face. We originally expected that the children who did the WinG in the Babylab would outperform the online participants. Indeed, online children were not able to touch or take the cards which could diminish their engagement. In addition, they might have not seen the pictures and heard the words as clearly as in face-to-face interaction. However, the findings are exactly opposite to this hypothesis as online children outperformed the in-person group. Critically the two groups did not differ on CDI scores. A possible explanation for those results is that online children might have been more focused on the task because, first, they were in a familiar environment at home, and second, looking at a computer’s screen might be more unusual and compelling. This is in line with what was found in the two previous experiments, where high effect sizes and low attrition rates were observed when testing online. Those results are in line with P. M. Nelson et al. (Reference Nelson, Scheiber, Laughlin and Demir-Lira2021) who compared children’s performances between face-to-face and online tasks. They tested children aged 4 to 5 years old on various tasks related to working memory – for example, visual spatial, and numeral competences. On five tasks out of eight, findings did not reveal differences across the two formats that they administered, but on the three other tasks (two related to verbal comprehension and one related to fluid reasoning), online children were found to outperform face-to-face ones.

There could be other explanations for our findings. Participants were recruited the same way and have similar SES but were not randomly assigned to participate in the experiment remotely or face-to-face as a result of the COVID-19 pandemic. Differences in composition of the sample can be one of the reasons why the online and offline group results differ on WinG scores. However, we did not find a difference in CDI scores, so our results are unlikely to be due to the online group having better language skills than the offline group. It might be more likely that participants recruited during the lockdowns might have performed better on the language test because they might have been more at ease with computers due to parents engaging more with them this way at home.

Our findings demonstrate that online data collection might be a feasible option for children’s language assessment; however, it also means that norms may not be useful when testing online. Note that our data do not allow us to conclude firmly in this direction: the face-to-face group scored around 30 on the WinG test, and the online group around 50. As expected of standardised scores, 50 is what would be expected from a representative group similar to the population from which standardised scores were derived. It is possible that our face-to-face participants scored particularly low.

One possible explanation for children scoring low in the face-to-face condition was that all adults wore an opaque mask in the aftermath of lockdown. However, it was found by Singh et al. (Reference Singh, Tan and Quinn2021) that opaque masks do not prevent children from recognising spoken words. In their study, 2-year-old toddlers were asked to identify eighteen familiar spoken words (e.g., “Can you see the spoon?”) under three distinct conditions: words spoken without any mask, words transmitted through a transparent mask, and words conveyed through an opaque mask. The results indicated that the toddlers could identify familiar words when presented without a mask or through opaque masks. However, they had difficulties to recognise words when heard through clear masks. Moreover in our study, we ensured at the start of the testing that children understood what was being said with the pre-test cards.

Another possibility would be about the timing of the visits and the general effect of the lockdowns. The online children were tested about 6 months after the start of the initial lockdown in the UK, which means that they had experienced their first years of life in a normal environment. In contrast, the face-to-face group was seen after having experienced lockdowns for at least one year, which represents a proportionally longer time of non-typical experience. Although their language skills might have been comparable (as demonstrated by the CDI scores in the two groups), their level of engagement might have been different enough to explain their lower scores on the WinG test. Davies et al. (Reference Davies, Hendry, Gibson, Gliga, McGillion and Gonzalez‐Gomez2021) showed that children aged 8 to 36 months who did not attend childhood education and care (ECEC) during lockdowns had lower cognitive executive functions skills (cognitive flexibility, inhibitory control and working memory) than those who did.

The important conclusion of our findings here is that children tested online, and who were drawn from the same population as those tested face to face, outperformed the latter. It would have been interesting to replicate these findings, but the data collection opportunity was unique and unrepeatable due to the exceptional lockdowns’ circumstances.