Effect of sound similarity and word position on lexical selection

Megan Reilly; Sheila E Blumstein

doi:10.1080/23273798.2014.917193

. Author manuscript; available in PMC: 2015 May 15.

Published in final edited form as: Lang Cogn Neurosci. 2014 May 15;29(10):1325–1341. doi: 10.1080/23273798.2014.917193

Effect of sound similarity and word position on lexical selection

Megan Reilly ¹, Sheila E Blumstein ¹

PMCID: PMC4243184 NIHMSID: NIHMS591450 PMID: 25436217

Abstract

Spoken word production research has shown that phonological information influences lexical selection. It remains unclear, however, whether this phonological information is specified for its phonological environment (e.g., word position) or its phonetic (allophonic) realization. To examine this, two definition naming experiments were performed during which subjects produced lexical targets (e.g., “balcony”) in response to the targets’ definitions (“deck higher than a building’s first floor”) after naming a series of phonologically related or unrelated primes. Subjects produced target responses significantly more often when the primes were phonologically related to the target, regardless of whether the phonologically related primes matched the target’s word position or did not. For example, subjects were equally primed to produce the target “balcony” after the prime “ballast” or “unbalanced” relative to unrelated primes. Moreover, equal priming occurred irrespective of phonological environment or phonetic realization. The results support models of spoken word production which include context-independent phonological representations.

Keywords: spoken word production, phonological encoding, lexical access, phonological representations

Introduction

Models of spoken word production agree on the existence of at least two stages of processing (Levelt, 1989): a high-level lexical-semantic stage at which lexical items are retrieved from semantic memory and mapped onto an abstract lexical representation and a low-level phonological stage at which the sounds of a word are prepared for articulation. Psycholinguistics research has debated about the representations at each substage of spoken word production, as well as the extent to which information flows between adjacent stages (Dell, 1986; Rapp & Goldrick, 2000). The current research seeks to examine the representation of abstract phonological units and their ability to independently impact lexical-semantic processing. In particular, this study will investigate the extent to which information at the phonological stage impacts processing at the lexical stage, and whether these phonological representations are position-sensitive and specified for acoustic realization in a given environment.

Current models of spoken word production implement two substages during which phonological information about a word is available. First, abstract information about the phonemes becomes available during access to the word form; second, during preparation for articulation, this information is specified for each phoneme’s relative position and phonetic realization. Evidence for this division between abstract and phonetically-specified representations is reported in both patient and covert speech research.

Buchwald and Miozzo (2011) report the repetition shadowing patterns of a patient with aphasia who showed a frequent word-initial s-deletion deficit. In English, stop consonants which follow /s/ word-initially are unaspirated, whereas word-initial voiceless stops are aspirated (Klatt, 1975). Buchwald & Miozzo’s patient produced stops which followed these rules even after an s-deletion as if the preceding /s/ were never present; that is, he produced utterances with aspirated initial stop consonants (e.g., “p^hil” following s-deletion of intended “spill”). The authors argue that since the word position of the stop consonant was specified after the deletion, the original target could not have been specified for phonetic position. Other studies have identified similar cases with specific deficits for abstract phoneme representations (Béland, Caplan & Nespoulous, 1990; Goldrick & Rapp, 2007; Ash et al., 2011).

Studies which use covert speech (or “inner speech”), during which subjects retrieve a lexical form but must suppress articulation, also suggest a division between the lexical-phonological word form and the fully specified articulatory output. During a covert speech task, subjects necessarily activate the abstract phonological forms but do not need to complete acoustic specification. Oppenheim and Dell (2008) presented subjects with four-word lists and analyzed self-reported errors when subjects were asked to rehearse the lists either overtly or covertly. Both covert and overt speech showed a lexical effect, such that subjects reported errors that were much more likely to be words than nonwords (“reef leach”→“leaf reach” was more common than “heath leech” → “leath heach”). This lexical effect, which is robust among speech errors (Dell & Reich, 1980), reflects activation of a lexical-phonological representation during both overt and covert speech. However, only the overt speech showed a phonemic similarity effect: there was a tendency for more phonetically similar phonemes to be exchanged (“reef” → “leaf”, with only one altered phonetic feature, was more likely that “reef” → “beef”). Covert speech showed no phonemic similarity effect, suggesting that the activated representations for the covert speech were not sensitive to the phonetic properties of each phoneme. An alternative explanation is that overt speech limits the opportunity for self-repair of errors through an internal monitoring mechanism (Postma, 2000), but Oppenheim & Dell concluded that covert speech is “impoverished” in that it is unspecified for phonetic detail.

Although the existence of separate stages of phonological processing is widely accepted, it is less clear how these two substages of phonological processing differentially influence access to the lexical word form. If phonological information influences lexical selection, heightened activation of a word’s phonemes will increase the likelihood that the word will be produced. For example, a speaker who is trying to think of a word for the deck outside his second-story hotel room might activate the words “balcony” and “veranda”, and the semantic representations of each word will compete for selection based on their relevance, frequency, and the recency with which the speaker has used them, among other factors. If the speaker has recently used the word “ballast”, the first three phonemes of “balcony” may still be residually activated. If these phonemes share residual activation with the lexical entry for “balcony”, the activation of “balcony” during lexical selection will be boosted relative to that of “veranda”.

There is evidence from both cloze sentence completion and tip-of-the-tongue states that phonological information has some influence on lexical-semantic processes, but these studies do not distinguish between the abstract and phonetically specific levels of phonological processing. Rapp and Samuel (2002) asked subjects to fill in the final words of open-ended sentences. The rate with which subjects used a given word was modulated by whether a rhyme for that word appeared earlier in the sentence. Subjects were more likely to choose a word if a phonologically similar word had already been activated (e.g., “The man walked into the bank and slipped on some ice. He’d gone to deposit his payment/check and nearly broke his ________.”; target, “neck”). Ferreira and Griffin (2003) used a similar paradigm and found that subjects were more likely to produce a word if either a semantic competitor or a homophone of a semantic competitor was present in the preceding sentence (e.g., “nun” and “none” both increased the likelihood of a “priest” response). These findings indicate that lexical selection of a target (“neck”, “nun”) is influenced by the activation of words with shared phonology (“check”, “none”).

Tip-of-the-tongue (TOT) research has found similar effects. This line of investigation attempts to characterize the phenomenon in which speakers have accessed some aspects of a word’s form, e.g., first phoneme, metrical structure, or number of syllables, but fail to fully encode and produce the intended word. The TOT effect was first induced experimentally by Brown and McNeill (1966), who presented subjects with the definitions of infrequent words and asked them to report whether they knew the words being defined or if they were “stuck” in a TOT state. Later studies have shown that exposure to phonologically related primes before presentation of the target definitions increased the number of target responses and decreased the number of TOT states reported (James & Burke, 2000; Meyer & Bock, 1992). It also decreased the number of non-target responses (Perfect & Hanley, 1992), suggesting that the locus of the phonological priming effect is lexical access rather than phonological encoding. If the effect of priming was simply to facilitate encoding of the sounds of the target word, the identity of the response would not be affected.

The studies described above provide ample evidence that phonological activation influences lexical access. However, these studies used phonological primes which matched the target in word position and phonetic realization. It has not been shown whether the phonological representations which show this influence are specified for the position and phonetic information which is not available until the latest stage of production. If the sound units which influence lexical selection are specified for word position and phonetic realization, then activated phonemes should fail to show any influence on word selection unless they match the target word’s position and/or phonetic context. For example, the /b/ in “unbalanced” is in a different context (/n_a/ or C_V) than the /b/ in “balcony” (/#_a/or #_V). Likewise, voiceless stops are produced differently in English when they begin a stressed syllable (aspirated) then when they do not (unaspirated). If the /p/ representation in “apron” is specified as “unaspirated” or “word-medial”, then it should fail to prime the aspirated initial /p/ in “principal”. On the other hand, if these representations are abstract, then any /p/ realization should prime all other /p/’s.

Although the spoken word production literature has not addressed this question, the auditory word recognition literature suggests that at least some aspects of word retrieval are influenced by phonological priming independent of a phoneme’s word position or realization. Subjects are able to identify words whose onsets are embedded in the middle of other words or nonwords (Norris, McQueen, & Cutler, 2002). Luce and Cluff (1998) found that subjects access the semantics of embedded words; they made facilitated lexical decisions for target words which were semantically related to an embedded word in the prime (e.g., “key” primed by “hemlock”). Van Alphen and van Berkum (2010) also found that the N400, an ERP measure of violated semantic expectations, was modulated by whether a stimulus sentence contained a semantically relevant word embedded in an otherwise semantically incoherent word. That is, subjects showed semantic processing of the word “pain” when they heard the word “champagne” in a sentence about an injury.

It is unknown whether abstract phonological representations influence lexical access in production. To this end, the current research investigates whether phonological information can influence the selection of a word when preceding phonological primes are presented in a different position than the target (Experiment 1) or when this information is presented in a different allophonic context than the target (Experiment 2). If lexical access is only primed by the production of phonological information which matches the target word in word position and phonetic realization (e.g., ‘balcony’, ‘ballast’), then the sound forms which influence lexical selection are specified for both their phonetic position and articulatory properties. If, on the other hand, positionally and acoustically different forms also prime lexical access (e.g., ‘balcony’, ‘cannibal’), then the units of phonological information which influence lexical access are abstract.

Experiment 1

The goal of experiment 1 is to investigate the effect of phonological information on lexical selection, and in particular to determine whether phonological priming is possible for sounds which share abstract phonemic information, but not their word position. Experiment 1 adopts a modified TOT definition naming paradigm, modeled after James & Burke (2000). James & Burke presented subjects with the definitions of low-frequency target words and asked them if they could identify the word being defined, and if not, whether they were in a TOT state. Each definition was preceded by ten visually presented prime words, which subjects overtly produced. Trials were in one of two conditions: Unrelated, in which primes were not semantically or phonologically related to the target; and Phonologically Related, in which five of the primes shared some phonemes with the target (e.g., for the target “sextant”: “secondary”, “semblance”, “restrain”, “pheasant”, “feint”). Five filler words were used in each trial in the Related condition to prevent subjects from using the primes as a strategy to identify the target (a concern raised by Hamburger & Slowiaczek, 1996; Sullivan & Riffel, 1999; Monsell & Hirsh, 1998; and Norris, McQueen, & Cutler, 2002). James & Burke were interested in the effect of phonological information on TOT states in different age groups. The phonological information always appeared in the same word position in the prime and target and they did not control for repetition of primed information or for the amount of phonological overlap (e.g., “ant” in “pheasant” vs. “nt” in “feint”) nor did they ensure complete overlap between the target and its corresponding set of primes (e.g., the /k/ in “sextant” is never primed).

The current experiment uses a similar task but more highly controlled phonologically related stimuli, and manipulates the word position of the overlapping phonemes between the prime and target. Because this is a priming study and not a TOT investigation, we did not collect data on TOT experiences, nor did we attempt to elicit TOT states; rather, we investigated the proportion of trials on which subjects selected and produced the target word.

Stimuli

Seventy-two three-to-five syllable words were selected as potential stimuli from previous studies (Meyer & Bock, 1992; Burke, McKay, Worthley & Wade, 1991; Harley & Brown, 1998; Morsella & Kraus, 1999) and from the MRC Linguistic Database (Coltheart, 1981). Definitions were adapted from the Merriam-Webster dictionary to between six and ten words each, to provide consistency across stimuli and to minimize variation in reading times.

Targets were selected from a pool of 106 words during a norming pilot experiment in which 15 subjects named the candidate target words in response to their definitions. In order to minimize variation in difficulty between items, targets were eliminated if fewer than 60% of pilot subjects named the target word. Targets were also eliminated if the mean naming latency across conditions and subjects was longer than 4000 ms. The mean number of words per definition in the 72 selected target words for Experiment 1 was 8.18 (SD 1.23) and the average Kučera-Francis frequency (Kučera & Francis, 1967) of each target word was 18.34 (SD = 47.5).

In the experiment proper, a single trial consisted of the presentation of six prime words presented one at a time, followed by the definition of a target word. Subjects were told to produce each prime word aloud and then indicate by button press whether they thought they had pronounced it correctly. Subjects were told that when presented with a definition, they were to produce the word being defined as quickly as possible, and then indicate by button press whether they had pronounced it correctly.

In every trial, three of the six primes were fillers which were phonologically and semantically unrelated to the target. The other three primes (or, in rare instances, compound words, e.g., “dry cleaner”) were in one of three conditions. In the Control condition, all primes were phonologically unrelated to the target. In the Match condition, three of the six primes contained the same initial, middle, or final syllable as the target word (e.g., for the target “balcony”, “ballast”, “reconcile”, “villainy”). The shared syllables were in the same word position as the target. In the Mismatch condition, three primes contained the initial, middle, and final syllable of the target word in a different word position (e.g. for the target “balcony”, “unbalanced”, “contagion”, “cranium”). No primes across conditions were semantically related to their targets.

For targets with four or more syllables, the medial syllable with primary or secondary stress was selected for overlap with a prime. To account for ambisyllabicity in English, any consonant which could be both the coda of the preceding syllable and the onset of the following syllable (e.g., the /l/ in “calorie”) was treated as both part of the onset and part of the coda.

Three unrelated filler words were also used for each trial to reduce the likelihood that subjects would use a strategy. Match and Mismatch primes were used as fillers for phonologically unrelated targets; for example, the Match primes for the target “balcony” for one subject might be used as unrelated fillers for the target “studio” for another subject. This controlled for frequency differences between primes, since every prime was presented to one-third of all subjects in each condition. No subject saw a prime more than once and no subject reported employing a strategy to use phonologically related primes to identify targets. The six primes, including both critical and filler words, were presented in random order before their corresponding target.

Each of the 72 targets was presented to every subject once, such that any given subject was presented with 24 targets in each of three conditions. The stimuli presented in each condition were counterbalanced for difficulty; difficulty was estimated using the mean target reaction time of participants in the pilot study. Order of presentation was not counterbalanced except that each block of trials (three blocks in Experiment 1, two blocks in Experiment 2) contained the same number of trials in each condition. Additionally, the pattern of response results is the same in each presentation block for both experiments. See Appendix A for a listing of the stimuli.

Procedure

Stimulus presentation was controlled using the BLISS software suite (Mertus, 2002) on a Dell PC. Verbal responses were recorded using a Sony microphone and an Edirol R-09 24-bit Digital Recorder. Responses were recorded as 24-bit uncompressed WAV files sampled at 44.1 kHz, and then down-sampled, using BLISS, to 16-bit WAV before analysis.

Thirty-three subjects (8 male) participated in the experiment and all received payment for their involvement. All participants were native English speakers, reported normal hearing and had no known history of neurological disorders. Each subject gave written informed consent in accordance with the guidelines established and approved by the Human Subjects Committee of Brown University. Data from three subjects were discarded due to a failure to meet an a priori response criterion of 67% correctly produced targets. The experiment took approximately 40 minutes to complete.

Participants were seated in front of a screen and button box and were visually presented with all primes and target definitions. Each trial consisted of the 6 prime words followed by a definition. Figure 1 shows the experimental design and an example trial in each condition. Subjects were asked to read each word aloud as quickly as possible without sacrificing accuracy, then to indicate on the button box whether or not they had pronounced it correctly. After each set of six primes, the target definition was presented. Subjects were asked to produce the word best described by the definition, and then to indicate by button press whether they had pronounced it correctly. Experiment 1 was self-timed unless a subject did not respond within 12000 ms, in which case the response was scored as a timeout and the next trial was initiated.

Responses were scored as correct if the subject named the target word. If a subject changed his or her mind and produced the correct target after a nontarget response or a meaningless utterance such as “uh”, the response was scored as correct, irrespective of reaction time latencies.

Reaction times (RTs) were measured from the onset of sentence definition to the fully correct response; for example, the RT of a response, “b… balcony” would be measured from the presentation of the definition to the onset of the second “b”. This metric was used to ensure that the phonological form of the word had been accessed before the utterance onset. RTs were measured for all correct responses using the waveforms on BLISS. For the RT analysis, RTs were discarded if the subject’s response was more than two standard deviations above his or her mean RT for that condition or if the target had fewer than 20 measured reaction times across participants (i.e., fewer than 67% of participants correctly named the target).

Results

Target responses

Figure 2 shows the mean number of correct responses to the target across conditions (Match, M = 0.851; Mismatch, M = 0.854; Control, M = 0.811). As can be seen, both the Match and Mismatch conditions increased the proportion of correct target responses relative to the Control condition.

A one-way ANOVA confirmed these observations. There was a main effect of condition in the within-subject analysis (F[2,28] = 3.45, MSE = 0.017, p = 0.038, Figure 2a) and marginal effect in the item analysis (F[2,70] = 2.76, MSE = 0.042, p = 0.067, Figure 2b). We attribute the weaker effects in the within-subject analysis to the high variability of difficulty across items.

Post-hoc pairwise two-tailed t-tests showed a difference for the subject analysis between the Match and Control conditions (subject analysis: t[29] = 2.53, p = 0.017) and a marginal difference in the item analysis (t[71] = 1.78, p = 0.080), as well as significant differences between the Mismatch and Control conditions (subject analysis: t[29] = 2.21, p = 0.035; item analysis, t[71] = 2.17, 0.034), but no difference between Match and Mismatch conditions. These results indicate that the phonologically related conditions improved the likelihood that subjects produced the target, e.g., “balcony”, and that this effect emerged irrespective of syllable position. This pattern of results holds even if we eliminate trials during which subjects gave multiple responses (“veranda… balcony”, accounting for 1.4% of total responses) or if we eliminate the ‘hesitation’ trials (“uh… balcony”, accounting for 2.4%).

Because ANOVA-type tests are nonideal for binomial dependent variables (Jaeger, 2008), we also ran treatment-coded comparisons between pairs of conditions using a mixed logit model, using lme4 (Bates, Maechler, & Bolker, 2012) in R (R Foundation for Statistical Computing, 2011). The dependent variable was target response, and the model used maximal random effect structure (Condition was included as a fixed effect as well as Subject and Item as random effects). The pattern of significance was the same as the analyses above: there was a significant difference between both the Match and Control (z = 2.15, p = 0.031) and Mismatch and Control (z = 2.28, p = 0.026) conditions. A Helmert-coded model was also tested to further examine differences between conditions. One contrast used coefficients that grouped together the Match and Mismatch conditions and compared them to the Control condition (z = 2.57, p = 0.010), and a second contrast compared the Match and Mismatch conditions (p > 0.1). These contrasts confirm the pattern of results above.

Nontarget response analysis

When subjects failed to give a correct target response, these responses were coded based on what type of error was made. These types included: the production of a semantic competitor, a word which did not fit the definition, a nonword, a phonologically related word to the target, an expressed TOT state, a mispronunciation of the target, a partial but incomplete production of the target, and a failure to respond within 12 seconds. The two most common types of errors were production of semantic competitors, e.g., “veranda” in response to the definition of “balcony”; and a failure to respond within the response window, which was coded as a timeout. These responses were still relatively rare, accounting for 9.8% of error types. Nonetheless, the pattern of differences between conditions is of interest to the question of what drives the target response effect. Qualitative analysis revealed that the proportion of semantic competitor responses was highest in the Control condition, but the proportion of timeouts did not differ between conditions. See Table 1 for a summary of the response types in Experiment 1.

Table 1.

Data from Experiment 1: Item analysis. Mean (SE)

	Match	Mismatch	Control
Proportion of correct target responses	0.851 (0.131)	0.854 (0.126)	0.811 (0.166)
Proportion of semantic competitor responses	0.082 (0.012)	0.093 (0.012)	0.118 (0.015)
Proportion of timeouts	0.044 (0.008)	0.034 (0.008)	0.039 (0.009)
Other responses	0.022 (0.006)	0.021 (0.006)	0.033 (0.007)
Reaction time	2897 (67)	2845 (61)	2754 (54)

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Reaction time analysis

Figure 3 shows the RT results. A one-way ANOVA indicated there was no effect of reaction time across conditions in the subject analysis (F[2,28] = 1.35, MSE = 107837, p > 0.1), but there was a marginal effect of condition in the item analysis (F[2,70] = 2.64, MSE = 347679, p = 0.078, Figure 3b). Post-hoc pairwise comparisons showed marginally higher reaction times in the Match condition than in the Control condition in the subject analysis (t[29] = 1.73, p = 0.094) and significantly higher reaction times in the item analysis (t[65] = 2.25, p = 0.028). No other comparisons were significant.

Reaction times from Experiment 1. a) Within-subject analysis; b) Item analysis.

Discussion

It was the goal of Experiment 1 to investigate the extent to which phonological priming of lexical access is sensitive to word position of the primed sound units. The data showed a significant effect of phonological priming even when the primes did not match the target’s word position. There was also no difference in the proportion of target responses between the Match and Mismatch conditions, suggesting that there is no priming advantage to the position-matched primes over the mismatched primes.

Most trials during which subjects did not name the target were either semantic competitor responses (e.g., balcony-veranda) or timeouts (no response). In Experiment 1, the proportion of semantic competitor responses was not equally distributed across conditions. There were fewer semantic competitor responses in the phonologically matched conditions than in the Control condition, suggesting that the increased activation of the phonological properties of a word result in its selection over semantic competitors. On the other hand, timeouts did not differ across conditions.

Experiment 1 also showed slower reaction times in the Match condition than in the Control condition. These slowed response latencies in the Match condition may reflect competition between the phonologically unshared portions of the prime and target. For example, the phonological segments of “last” in “ballast” compete with the unshared segments “cony” in the target word “balcony”. Consistent with this interpretation is evidence that slowed response times during word naming are proportional to the number of unshared phonemes between target words and competing lexical items (Wheeldon, 2003; Dufour & Peereman, 2003). Indeed, Sevald & Dell (1994) and Sullivan & Riffel (1999) conclude that articulatory plans are constructed sequentially from initial to final sounds, even though early phonological encoding occurs in parallel. As a consequence, the slowed RT latencies in the Match condition could be due to the greater competition during articulatory preparation from primes which matched the target word than from the unrelated Control primes. Consistent with this interpretation is the failure to show a difference in RT latencies between the Mismatch and Control conditions. Here, phonological planning and implementation stages are not influenced by the phonological prime because they occur in different “slots” within the word frame.

Experiment 2

The response data from Experiment 1 support the notion that context-independent phonological representations influence lexical access (Stemberger, 1990; Buchwald & Miozzo, 2011) since there was no difference in the magnitude of the effect for either type of phonological prime (whether or not they matched the syllable context of the target). However, in the Mismatch condition, some of the primes shared phonetic properties with the target and in other cases they did not. For example, on some Mismatch trials, the syllables in the prime and target shared syllable stress, e.g., “balcony” and “unbalanced”. On other trials, the prime and target stimuli differed in syllable stress, e.g., “intersection” and “secretary”. The same was true for other aspects of phonetic realization (e.g., the /k/ in “balcony” is unaspirated, but the /k/ in its prime “contagion” is aspirated). Thus, it is unclear whether the phonetic realization of a mismatched phonological prime influences the activation of the lexical representation of a target word.

To address this possibility, Experiment 2 manipulated the phonetic similarity between the prime and target stimuli by examining the effects of two Mismatch conditions: one in which the position of the primed syllable varies but the phonetic realization of the target is similar to that of the target stimulus, and one in which both the phonetic position and the phonetic realization of the prime stimulus vary in relation to the target stimulus. If phonological priming of lexical selection is influenced by the similarity between the phonetic realization of the prime and target, then the two Mismatch conditions should differ in the proportion of target responses. If, on the other hand, lexical selection processes are driven by abstract phonological representations, then the Mismatch Phonetics condition will show the same proportion of target responses as the Match and Mismatch Position conditions.