#foodie: Implications of interacting with social media for memory


ORIGINAL ARTICLE Open Access

#foodie: Implications of interacting with
social media for memory
Jordan Zimmerman and Sarah Brown-Schmidt*

Abstract

Background: Social media is an increasingly popular outlet for leisure and social interaction. On many social media
platforms, the user experience involves commenting on or responding to user-generated content, such as images
of cats, food, and people. In two experiments, we examined how the act of commenting on social media images
impacts subsequent memory of those images, using Instagram posts as a test case. This project was inspired by
recent findings of laboratory studies of conversation which found that describing a picture for a conversational
partner boosts recognition memory for those images. Here we aimed to understand how this finding translates to
the more ecologically valid realm of social media interactions. A second motivation for the study was the popularity
of food- and dieting-related content on Instagram and prior findings that use of Instagram in particular is
associated with disordered eating behaviors.

Results: Across two experiments, we observed that commenting on Instagram posts consistently boosted
subsequent recognition and that correct recognition increased with comment length. Stable individual differences
in recognition memory were observed, and “unhealthy” food images such as chocolates were particularly well
remembered; however, these memory findings did not relate to self-reported eating behavior.

Conclusions: Taken together, our findings show that the way in which we engage with social media content
shapes subsequent memory of it, raising new questions about how our online lives persist in memory over time,
potentially shaping future behavior.

Keywords: Social media, Memory, Elaborative encoding, Food, Disordered eating

Significance Statement
Engaging with other persons through social media plat-
forms such as Facebook, LinkedIn, Twitter, Pinterest,
and Instagram is becoming increasingly ubiquitous. Ac-
cording to Instagram’s “Year in Review” publicity mate-
rials, in 2018, the heart emoji was used over 14 billion
times, and the hashtag #metoo was used 1.5 million
times (Instagram, 2018). Food-related content is particu-
larly popular on Instagram, with #foodporn tagged on
over 206 million posts, #foodie on over 133 million
posts, and #vegan on over 83 million posts. A notable
feature of Instagram is that users add comments such as
“OMG YUMMM,” or hashtag comments such as #food

(used over 354 million times) and #fitspo (used over 67
million times). The sheer number of communicative acts
demands a better understanding of the cognitive impli-
cations of this type of social media engagement. The
present research builds on prior studies of conversa-
tional interactions which show that describing a picture
to a communication partner boosts memory for that
image. Here we asked if commenting on Instagram posts
similarly boosts memory for those posts. Across two ex-
periments, we observed that commenting on Instagram
posts consistently boosted subsequent recognition and
that correct recognition increased with comment length.
Stable individual differences in recognition memory were
observed, and “unhealthy” food images such as choco-
lates were particularly well remembered, but these mem-
ory findings did not relate to self-reported eating

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* Correspondence: sarahbrownschmidt@gmail.com
Department of Psychology and Human Development, Vanderbilt University,
230 Appleton Place, Nashville, TN 37203, USA

Cognitive Research: Principles
and Implications

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications
           (2020) 5:16 
https://doi.org/10.1186/s41235-020-00216-7

http://crossmark.crossref.org/dialog/?doi=10.1186/s41235-020-00216-7&domain=pdf
http://orcid.org/0000-0002-5647-0875
http://creativecommons.org/licenses/by/4.0/
mailto:sarahbrownschmidt@gmail.com


behavior. Taken together, our findings show that the
way in which we engage with social media images shapes
subsequent memory for them, raising new questions
about how our online lives persist in memory, poten-
tially shaping future behavior.

Introduction
Engaging with other persons through language and
media is both common and impactful. According to the
American Time Use Survey (US Department of Labor,
2019), in 2018, American civilians aged 15 years and
older engaged in leisure and sports activities 5.27 h/day,
on average, including 38 min/day socializing and com-
municating and 2.8 h/day watching television. Although
the amount of time Americans spent engaging with so-
cial media per se is not reported, “playing games and
computer use for leisure” was also popular, with an aver-
age of 28 min/day, though notably, this varied consider-
ably by age, with 15–19-year-olds reporting 62 min/day
and 20–24-year-olds reporting 58 min/day. Blank and
Lutz (2016) examined a UK sample and reported that
social media platforms such as Facebook, LinkedIn,
Twitter, Pinterest, and Instagram are becoming increas-
ingly ubiquitous and that, at the time of their study,
Instagram was the fastest-growing of these sites. Accord-
ing to Instagram’s “Year in Review” publicity materials, in
2018, the heart emoji was used over 14 billion times on
the platform, and the hashtag #metoo was used 1.5 million
times (Instagram, 2018). In its 2017 “Year in Review,”
Instagram reported a “global community of 800 million”
(Instagram, 2017). One motivation for the present re-
search is the popularity of food-related content on Insta-
gram, such as #foodporn (tagged on over 206 million
posts), #vegan (tagged on over 83 million posts), @food-
network (9.3 million followers), @foodgod (3.4 million
followers), and @feelgoodfoodie (2.1 million followers).
The popularity of social media makes it increasingly

important to understand how engaging with this type of
media shapes cognition. Previous research suggests that
memory for social media content is high among the gen-
eral population: Memory for Facebook microblogs is sig-
nificantly higher than memory for sentences from books,
news headlines, and even human faces (Mickes et al.,
2013). The popularity of health- and dieting-related con-
tent on Instagram in particular emphasizes the import-
ance of understanding how the act of viewing and
interacting with these images impacts the viewer. Poten-
tially relevant to this question are cognitive processes
underlying disordered eating, phenomena that are
thought to be complex and multidimensional, being
shaped by the external environment and social culture
(Culbert, Racine, & Klump, 2015; Levine, Smolak, &
Hayden, 1994; Stevenson, Doherty, Barnett, Muldoon, &
Trew, 2007). Indeed, some prior work indicates a

relationship between the use of media and disordered
eating habits (Harrison & Cantor, 1997; Turner &
Lefevre, 2017; also see Mejova, Hamed Haddadi, Anasta-
sios Noulas, & Ingmar Weber, 2015). Here, we examined
the cognitive processes that occur when engaging with
social media content on Instagram.
A notable feature of the Instagram platform is that in-

stead of simply browsing through the content, users can
also add comments to the images they see (and see
others’ comments as well). These comments often fea-
ture evaluations or descriptions of the image, as in “This
pasta looks sooo darn good!,” “OMG YUMMM,” or
“#foodie.” This act of commenting was the primary focus
of the present research. Our research question was in-
spired by recent findings from the study of conversation
that the act of describing an image for another person
boosts memory for that image (McKinley, Brown-
Schmidt, & Benjamin, 2017; Yoon, Benjamin, & Brown-
Schmidt, 2016;). For example, Yoon et al. (2016) exam-
ined situations in which pairs of participants viewed four
images at a time (on separate computer screens) and
took turns describing the images to each other in a task
in which the listener had to locate that image and click
on it. Despite the fact that the image descriptions were
fairly simple (e.g., “the argyle sock,” “the bunny,”) over a
series of experiments, speakers consistently exhibited
better recognition memory than listeners for these refer-
enced images. Further, memory for viewed but nonde-
scribed images was considerably worse than memory for
images that the speaker had described. In a converging
finding, McKinley et al. (2017) examined the length of
image descriptions and found that longer descriptions
promoted better recognition memory for those images.
This observed memory benefit for describing images

likely owes to the fact that the labels were generated and
produced by the speakers, both of which benefit memory
(i.e., the “generation effect” and “production effect”; Faw-
cett, Quinlan, & Taylor, 2012; Macleod, Gopie, Houri-
han, Neary, & Ozubko, 2010; Slamecka & Graf, 1978;
Zormpa, Brehm, Hoedemaker, & Meyer, 2019; also see
Knutsen & Le Bigot, 2014). Action memory is similarly
better for self-performed actions than for observed ac-
tions (Koriat, Ben-Zur, & Druch, 1991). These findings
can more generally be considered a type of elaborative
encoding effect (Bradshaw & Anderson, 1982), where
the elaboration of the image with descriptive phrases
promotes encoding of that image in memory.
Although it is clear that generating image descriptions

for a partner in laboratory tasks with carefully selected
images promotes image recognition, an unanswered
question is how this might translate into more typical
experiences with images in social media contexts. To
this end, the present article presents the results of two
experiments examining how the act of engaging with

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 2 of 16



social media posts, by commenting on the images,
impacts subsequent memory for those posts. Due to
the aforementioned prevalence of food- and dieting-
related content on this platform and associated com-
ments generated by users (e.g., “We love cucumbers!
#instafood #yummy”), we examined several categories
of food and non-food-related images and used an
established questionnaire to inquire about partici-
pants’ eating behaviors. We then modeled the data
using a quantitative technique that allowed us to
examine whether there were stable individual differ-
ences in memory for images in general and in mem-
ory for food in particular. If so, we would then be
positioned to ask whether a person’s eating behaviors
relate to their memory for food-related content on
social media. This research question is motivated by
previous evidence of selective processing and atten-
tional biases for pictorial stimuli among individuals
with eating disorders (Giel et al., 2011; Nikendei
et al., 2008; Shafran, Lee, Cooper, Palmer, & Fairburn,
2007; Stormark & Torkildsen, 2004; also see Castella-
nos et al., 2009), as well as by findings that use of so-
cial media platforms by young adults is marginally
associated with depressive symptoms (Lup, Trub, &
Rosenthal, 2015; cf. Aalbers, McNally, Heeren, Wit, &
Fried, 2019). Of note is that platforms such as Insta-
gram are used to share information relevant to eating
disorder behavior (see Chancellor, Pater, Clear, Gil-
bert, & De Choudhury, 2016), and use of Instagram
in particular has been associated with higher rates of
orthorexia nervosa (an obsession with eating healthy;
Turner & Lefevre, 2017). If individuals who experi-
ence disordered eating interact with social media on a
daily basis and process social media differently on the
basis of their symptomology, this could have major
implications for how social media platforms affect an
already vulnerable population.

Experiment 1
The aims of Experiment 1 were twofold. First, we tested
whether previously observed benefits of generating pic-
ture descriptions (McKinley et al., 2017; Yoon et al.,
2016; Zormpa et al., 2019) would generalize to the ubi-
quitous practice of commenting on social media images.
Second, we evaluated whether there were stable individ-
ual differences in memory for these images, particularly
those related to food. If so, this would allow us to take
the first step in investigating if and how eating behaviors
shape memory for food in social media.

Methods
This experiment was preregistered with the Open Sci-
ence Framework Registries (https://osf.io/s5ez8).

Participants
Participants were recruited thorough an online platform
(Amazon Mechanical Turk; www.mturk.com) and were
compensated $4.50 for participating. Criteria for partici-
pation were a HIT approval rate of 95% or greater, loca-
tion as the United States, and number of approved HITS
as 100+. Criteria for inclusion in the study were that the
participant was a self-reported native English speaker
(learned from birth) and that they completed at least
80% of the study. To achieve the final planned sample
size of 100 participants, 106 participants completed the
study. Six participants were removed for reporting being
other than a native speaker of English (n = 5), and one
was removed for completing the study twice with the
same Internet Protocol (IP) address (the second partici-
pation in the study was excluded). Thus, the final sample
size was 100. The average age of the sample was 37 years
(range, 22 to 70). Participants reported gender as female
(n = 46), male (n = 53), or genderqueer (n = 1).

Materials
The materials were assembled by perusing a large number
of Instagram posts gathered from Instagram accounts cre-
ated by the first author for this purpose. We focused on
gathering images from one of five categories. Posts featur-
ing dogs, cats, or nature were used as control images.
Posts featuring food served as critical stimuli and were
further divided into the categories of “healthy” and “un-
healthy” food. Note that categorization of the food images
into “healthy” and “unhealthy” was based on group discus-
sion and our intuition about popular cultural beliefs rather
than quantitative analysis of nutritional properties. Ex-
ample “healthy” food images included berries, seafood,
and salad. Example “unhealthy” food images included
brownies, cheeseburgers, and cake. Posts that originated
from private accounts were edited so that the usernames
were obscured by overlaying the username with text such
as “pics123.” In total, the materials used for the study were
200 Instagram posts, 40 in each of the 5 categories. We
intentionally used a 3:2 ratio of control to food-related im-
ages in order to obscure the focus on food-related images.
The 200 Instagram posts were rotated across condi-

tions using four lists, counterbalancing which images
were shown to participants in the exposure phase (“old”
images at test) and which were not shown to partici-
pants during exposure (“new” images at test). For old
images, we also rotated across lists whether the partici-
pant commented on them or not. To create list 1, half of
the images in each of the five categories (“healthy food”,
“unhealthy food”, cats, dogs, and nature) were randomly
selected to be shown to participants in the exposure
phase (100 old items); the other half were to be “new”
items at test. For each category, half of the “old” images
were assigned randomly to the commenting condition,

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https://osf.io/s5ez8


and half were assigned to the no-commenting condition.
List 2 then swapped which were commented on and
which not. Lists 3 and 4 swapped which were old and
new. As a result, on each list, the new items were drawn
from among the same categories as the images viewed in
the exposure phase. Consequently, there was never a
novel item from a completely new category that was not
previously encoded. For example, across the whole ex-
periment (study and test), participants saw five total im-
ages of pizza, some of which were new items and some
of which were old (which ones were old vs. new
depended on the list). Please see the Appendix for a list
of all of the food stimuli in the study for list 1. Each par-
ticipant was randomly assigned to complete the trials on
a single list (list 1, n = 27; list 2, n = 29; list 3, n = 23; list
4, n = 21).

Procedure

Exposure phase After consenting to participate, partici-
pants were given the following instructions: “In the fol-
lowing section, you will see a series of Instagram posts.
Some will require you to generate an original comment,
while others will not. Please think of appropriate and
thoughtful comments for the pictures you will see, and
simply attend to the posts that do not require comments.
Treat the following experience as you would scrolling
through your own social media feed.” The instructions did
not mention that there would be a subsequent memory
test. Participants then clicked to the next screen and
began viewing a series of 100 Instagram posts, one per
page. The posts were presented in a different random
order for each participant. For half of the posts, the partic-
ipants were prompted to provide a comment using the
same phrasing as on the Instagram platform (i.e., “Add a
comment….”). For comment trials, there was no restric-
tion on the length of the comment, though the participant
needed to type something in order to proceed to the next
trial. These trials were self-paced.

Test phase After viewing the 100 Instagram posts, par-
ticipants were then asked to complete a series of 17
math problems. This task took about 5 min and was
intended to bring memory performance off ceiling be-
cause recognition memory performance for pictures can
be high (Shepard, 1967); this is a method used in our
prior work with success (Yoon et al., 2016). Participants
were then told, “In the following section, your memory
will be tested on the images you were previously shown.
If an image is presented that you have previously seen
(one you saw in the first part of the study), select ‘OLD.’
If an image is presented that is new and not previously
shown, select ‘NEW.’” They viewed a series of 200 im-
ages, half of which were old and seen in the exposure

phase (20 images from each of the 5 categories), and half
of which were new (20 new images from each of the 5
categories). The images were shown one at a time in a dif-
ferent random order for each participant, and the partici-
pant was asked to respond “old” or “new” for each image.

Additional measures
Following the recognition memory task, participants
completed the Eating Disorder Examination Question-
naire (EDE-Q). The EDE-Q is the self-report version of
the Eating Disorder Questionnaire, which is used to de-
termine the frequency and severity of behavioral features
and the psychopathology of eating disorders. The ques-
tionnaire provides a global score of severity as well as
four subscale scores that correspond to certain aspects
of psychopathology. The four subscales are restraint, eat-
ing concern, shape concern, and weight concern. The
range of ratings for each item is 0 to 6, with 6 being the
most frequent or severe. To obtain a subscale score, the
average of the ratings for the relevant items is calculated.
To obtain a global score, the sum of the four subscale
scores is divided by 4 (Fairburn, Cooper, & O’Connor,
2014). This examination is reported to be a valid meas-
ure of eating disorder symptomology (Mond, Hay, Rod-
gers, Owen, & Beumont, 2004), and higher values on
each of the scales reflect higher symptomology. Finally,
participants were asked to report their age, gender, and
ability in the English language.

Predictions Recent studies in our laboratory revealed
that following conversation, partners had better memory
for pictures that they described themselves than for ones
their partner described (McKinley et al., 2017; Yoon
et al., 2016). If this generation benefit extends to written
comments in online communication, we hypothesized
that memory would be better for Instagram posts for
which individuals generated original comments than for
posts that were passively viewed. Further, we expected
that the likelihood of correct recognition would increase
the longer the comment. This pattern of findings would
be expected if posting comments on social media pro-
moted elaborative encoding of the post (Bradshaw &
Anderson, 1982), compared with simply viewing them.
There is, however, good reason to think that com-

menting may not benefit picture memory. Social media
images are often selected to be glossy and captivating,
and recognition memory for pictures tends to be good
(Shepard, 1967). Thus, ceiling effects may obtain, such
that commenting has no effect on memory despite the
use of a filled delay between study and test. Another
possibility is that an elaborative encoding benefit of
commenting trades off with an attentional shift toward
the “Add a comment…” box where the comment is
typed, and inward toward one’s own reflections on the

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 4 of 16



image. Memory for item and context can trade off
(Gopie & MacLeod, 2009; Jurica & Shimamura, 1999;
Koriat et al., 1991), such that manipulations that benefit
item memory impair or have no effect on context mem-
ory. If so, commenting may boost memory for the com-
ment, but not the picture; in linguistic terms, it would
be the reference and not the referent that receives the
boost. Such a pattern of findings would circumscribe the
scope of generation-based memorial benefits following
conversation, pointing to a distinction between reference
and referent.
In addition to effects of commenting, we tested the hy-

pothesis that individual differences in memory for food
vs. nonfood could be predicted by self-reported disor-
dered eating behaviors. Support for the idea that mem-
ory for food might be linked with disordered eating
comes from findings of attentional processing differ-
ences for food-related stimuli in persons with an eating
disorder (Giel et al., 2011; Nikendei et al., 2008; Shafran
et al., 2007; Stormark & Torkildsen, 2004) and a link be-
tween hunger/satiation and attentional processing of
food-related stimuli (Mogg, Bradley, Hyare, & Sui, 1997;
Placanica, Faunce, & Job, 2002; Stockburger, Schmälzle,
Flaisch, Bublatzky, & Schupp, 2009). These findings, along
with evidence of a relationship between the use of media
and disordered eating habits (Harrison & Cantor, 1997;
Turner & Lefevre, 2017; also see Mejova et al., 2015), led
to the predictions (1) that there would be stable individual
differences in memory for food (vs. nonfood) images and
(2) that these individual differences would be related to a
measure of disordered eating behavior.
Critically, however, examining the relationship between

this digital generation effect and behaviors associated with
disordered eating first requires us to demonstrate reliable

individual differences in memory for the images and for
food-related images in particular. To preview, while per-
sons did exhibit stable individual differences in recogni-
tion memory, the difference in memory between food and
nonfood items was itself not a stable property of the indi-
viduals we tested. Unfortunately, this prevented us from
testing hypotheses relating memory for food-related Insta-
gram posts to disordered eating behaviors.

Results
Each participant commented on 50 of 100 viewed Insta-
gram posts, followed by an old–new recognition memory
test. Performance in the recognition memory task is illus-
trated using a measure of memory sensitivity (d′) in Fig. 1.
The primary analyses focus on memory for the posts, an-

alyzed using a logistic mixed-effects approach to a signal
detection theoretic analysis (see Fraundorf, Benjamin, &
Watson, 2013; Wright, Horry, & Skagerberg, 2009). In
addition, we characterize the relationship between the form
of the comments and memory and finally explore whether
there are stable individual differences in these effects.

Memory for Instagram posts
A logit-link mixed effects model for memory judgments
(old = 1; new = 0) was fit to the 19,999 recognition mem-
ory judgments in this dataset; note that one data point
was lost due to computer error. Planned analyses of
fixed effects include orthogonal Helmert codes for item
type (old vs. new) and whether the image had been com-
mented on (comment vs. no comment). We also con-
sider two different effects of image type using a dummy-
coding scheme where the control images (nature, dogs,
or cats) were dummy-coded as baseline, allowing us to
test if memory for healthy food differed from baseline

Fig. 1 Experiment 1: Illustration of memory sensitivity (d′) by condition. Error bars indicate by-participant standard deviation

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 5 of 16



and separately whether memory for unhealthy food dif-
fered from baseline. Note that the effects of item type
and commenting can be interpreted as simple effects at
the reference level (control images), and interactions
with item type test whether these effects differ for
healthy and for unhealthy food.
The model included participants and items as crossed

random effects. An initial model that included only the
random intercepts revealed that there was very little
variance in the intercepts by item, though slightly more
variability among participants. On the basis of lack of
item variability and the lack of hypotheses regarding in-
dividual item differences, we did not attempt models
with random slopes by item. While our analysis plan
was to relate a person-level covariate (EDE-Q score) to
the memory data, attempts to include random slopes by
persons for each of the fixed effects were met with con-
vergence failures. Using a backward-fitting approach
(Barr, Levy, Scheepers, & Tily, 2013), we simplified the
model until we identified a model that included random
slopes by person for the effects of item type (old vs.
new), and commenting (for old items, whether the par-
ticipant commented on the image). While this model
failed to converge, refitting the model with different op-
timizers using the allFit function (Bates et al., 2018) re-
vealed consistent estimates for each of the fixed effects
to two decimal places, except for the intercept and the
(nonsignificant) interaction between commenting and
healthy food, which were consistent across optimizers
only to one decimal place. For the random effects, esti-
mates for the by-person random intercept and slopes
were consistent to two decimal places, except for the by-
participant random slope for item type (old vs. new) and
commenting, which were consistent only to one decimal
place. This model was taken to be satisfactory and is
presented in Table 1.

The intercept term in the model was not significant,
indicating there was no evidence for a significant re-
sponse bias (participants responded “old” and “new” at
similar rates). A significant effect of item type (z = 22.11,
p < .0001) indicated good memory for the previously
viewed images. A significant effect of commenting indi-
cated that for previously viewed images, they were more
likely to be correctly recognized if the participant had
commented on them (z = 18.09, p < .0001). These effects
were qualified by interactions with item type. Healthy
food was remembered less well than control images (z =
− 2.87, p < .01), whereas unhealthy food was remem-
bered better than control images (z = 2.69, p < .01). In
addition, the effect of commenting was smaller for un-
healthy food images than for control images (z = − 2.22,
p < .05), possibly due to the fact that memory was over-
all better for the unhealthy food images.

Effect of comment length on memory for Instagram posts
This exploratory analysis investigated whether the length
of the Instagram comments modulated memory for
those images. This analysis was restricted to old items
for which participants generated a comment, as the pre-
dictor variables are defined for those items only. The
number of words per comment ranged from 1 to 45
(median = 3, mean = 4.18). On average, comments were
longer for pictures that would ultimately be correctly
recognized (mean number of words = 4.30, SD = 3.24)
than for pictures that were not recognized (mean = 2.86,
SD = 2.13). A logit-link mixed effects model for memory
judgments (old = 1; new = 0) was fit to the data. Fixed ef-
fects include a centered measure of the number of words
used to comment on the picture. The same dummy-
coding scheme as in the primary analysis was used,
where control images (nature, dogs, or cats) were
dummy-coded as baseline, allowing us to test if the effect

Table 1 Experiment 1: Memory by condition, model with random slopesa

Fixed effects Estimate SE z Value p value

(Intercept) 0.086 0.076 1.128 .259

Commenting (commented items = 0.5, noncommented items = −0.5, new = 0) 2.613 0.144 18.090 <.0001

Item type (old vs. new) (commented = 0.5, noncommented = 0.5, new = −1) 2.786 0.126 22.114 <.0001

Commenting * Healthy food −0.122 0.146 −0.836 .403

Commenting * Unhealthy food −0.335 0.151 −2.218 <.05

Item type * Healthy food −0.218 0.076 −2.869 <.01

Item type * Unhealthy food 0.217 0.081 2.692 <.01

Random effects Variance SD Correlations

Item (intercept) 0.206 0.454

Subject (intercept) 0.389 0.623

Item type (old vs. new) 1.343 1.159 0.27

Commenting 1.285 1.134 −0.12 .47
aNumber of observations: 19,999, 200 items, 100 participants

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 6 of 16



of comment length was different for healthy food and for
unhealthy food (compared with baseline). Note that the
effects of the number of words can be interpreted as sim-
ple effects at the reference level (control images) and in-
teractions with item type test whether these effects differ
for healthy food and for unhealthy food.
Participants and items were included as random inter-

cepts. A null model was initially fit to the data and indi-
cated very little variability by items but some variability
by participants. Thus, the effect of commenting was in-
cluded as a by-participant random slope. This model
converged. Models with more complex random effects
structures failed to converge with warnings indicating
singular fits. Thus, results of this converged model were
taken to be satisfactory and interpreted (Table 2). The
significant intercept term indicates that for these
commented-on images (all of which were old), correct
recognitions were more likely than not (z = 18.94,
p < .0001). A significant effect of word count (z = 6.09,
p < .0001) shows us that for each additional word pro-
duced in the comment, the odds ratio of correct recogni-
tion was 1.37 times greater at test. A significant
interaction between word count and healthy images (z =
− 2.43, p < .05) indicated that the effect of commenting
was smaller for healthy food images than for control im-
ages (dogs, cats, or nature).

Participant variability and Individual differences
In order to ask questions about individual differences in
these processes, it is first necessary to determine
whether the models provided evidence that there were
stable (reliable) individual differences in our memory
measures. To this end, for the analysis of recognition
memory presented in Table 1, we extracted the by-
person random effects as well as the standard errors of
those random effects using the “arm” package in R (Gel-
man, Su, Yajima, Hill, et al., 2018). Following Cho, Shen,
and Naveiras (2019), we calculated the model-based reli-
ability of the item type (old vs. new) and comment ef-
fects. Rho can be interpreted as the ratio of the

estimated variance theta over the observed variance theta,
with values closer to 1 indicating better reliability. Rho for
the item type effect was fairly high, .882, indicating stable
individual differences in memory for the pictures. Rho for
the effect of commenting was less reliable, .654.
As noted above, more complex models including ran-

dom slopes for image type (healthy and unhealthy food)
failed to converge, and refitting these models revealed
inconsistent fits with different optimizers as well as sin-
gularities (random effects parameters being at or near
zero), indicating poor model fit. Together, these findings
indicate that there was some consistent variability by
persons in their memory for the images and in the effect
of commenting on those pictures. However, we were not
able to extract a stable measure of individual differences
in memory for healthy or unhealthy food in particular
(above and beyond overall measures of memory), making
it impossible to conduct planned analyses of the rela-
tionship between memory for food and the EDE-Q
measure of eating behavior.
For the second analysis of the relationship between

comment length and memory (Table 2), inspection of
the random effects indicated that while there was some
variability in the by-person intercept (reflecting the cor-
rect recognition rate) the effect of word count on correct
recognition varied little across participants. Model-based
estimates of reliability (Cho et al., 2019) indicated a me-
diocre rho value for the by-person intercept (.557); the
extremely small variance for the random slope for word
count resulted in a negative rho (− 2.842). These findings
indicate that there was very little evidence for reliable in-
dividual differences in these effects, and they were not
explored further.
The person-level covariates in this sample include par-

ticipant age, and the EDE-Q measures (restraint, eating
concern, shape concern, weight concern, and the global
score). Descriptive statistics for these variables are
shown in Table 3.
We took an exploratory approach to examining bivari-

ate correlations between the EDE-Q measures (restraint,
eating concern, shape concern, weight concern, and the
global score), participant age, and the memory measures
(by-person random effects for response bias, overall
memory, and the effect of commenting). These correla-
tions were computed and interpreted with respect to a
Bonferroni-adjusted alpha level of .0013. The bivariate
correlations revealed the expected relationships among
the EDE-Q subscales and the overall global score (Table
7 in Appendix). In addition, the by-person random ef-
fects for memory and commenting were positively re-
lated (r = .487, p < .0001), indicating that participants
with better memory also tended to benefit more from
commenting on the images. There was also an unex-
pected positive correlation between the memory random

Table 2 Experiment 1: Effect of comment length on correct
identification of old images

Fixed effects Estimate SE z Value p Value

(Intercept) 2.969 0.157 18.936 < .0001

Word count 0.313 0.051 6.085 < .0001

Words*Healthy −0.137 0.057 −2.425 <.05

Words*Unhealthy −0.090 0.059 −1.530 0.126

Random effects Variance SD Correlations

Item (intercept) 0.318 0.564

Participant (intercept) 1.206 1.098

Word count 0.026 0.162 0.290

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 7 of 16



effect and age (r = .356, p < .001). The lack of stable indi-
vidual differences in memory for healthy and unhealthy
food in particular prevents examination of a relationship
between those food types and scores on the EDE-Q.

Discussion
The results of Experiment 1 revealed, for the first time,
that the process of commenting on social media images
boosts memory for those images. This effect can be
interpreted as a type of generation effect (Slamecka &
Graf, 1978). Further, the fact that longer comments pro-
duced better recognition extends prior findings from
studies of in-laboratory image descriptions (McKinley
et al., 2017) to a class of images – Instagram posts – that
are both ubiquitous and socially relevant. This effect can
be considered a type of elaborative encoding effect
(Bradshaw & Anderson, 1982) such that the more elab-
orately the participant commented on the post, the bet-
ter the memory. The memorial benefit for commented-
on pictures may be enhanced in part by a longer time
spent on trials where participants generated a comment.
(Unfortunately, the study software did not provide infor-
mation about timing.) If so, such a timing difference
would reflect properties of the natural phenomenon we
intended to study: commenting on social media images.
Here we have shown that the memorial boost conferred
by generating comments in communication extends to a
new type of item with a high degree of social relevance:
social media.

Experiment 2
The primary aim of Experiment 2 was to replicate the
findings of Experiment 1. Second, we aimed to examine
whether interacting with Instagram posts, in particular
posts about food, would be particularly memorable for a
sample of participants who are at a higher risk for exhi-
biting disordered eating behaviors. While we did not
find consistent individual differences in food-related

Instagram posts in Experiment 1, the participant sample
may have been too broad to capture the population of
interest. Lifetime prevalence of eating disorders in US
adults is higher in women than in men and in younger
adults (Hudson, Hiripi, Pope Jr, & Kessler, 2007; Udo &
Grilo, 2018; also see Cheng, Perko, Fuller-Marashi, Gau,
& Stice, 2019). Experiment 2 is therefore a replication of
Experiment 1, but with a participant sample restricted to
young females.

Methods
The project was preregistered with the Open Science
Framework (https://osf.io/dqrge). Experiment 2 was
identical to Experiment 1, with two exceptions. First, we
restricted the sample to participants who identified as fe-
male and who were between the ages of 18 and 30. Sec-
ond, we asked participants additional questions about
their education level.

Participants
As planned, we present an analysis of data of 150 partici-
pants. We used a 50% larger sample in this study be-
cause whereas the results of Experiment 1 showed a
large generation effect, attempts to fit models with more
complex random effects structures were met with con-
vergence issues. Thus, the larger sample size was se-
lected with the aim of reducing convergence issues.
We used Amazon Mechanical Turk Premium qualifi-

cations to select a sample of female participants, aged
18–30. As in Experiment 1, criteria for participation is a
HIT approval rate of 95% or greater, location as the
United States, and number of approved HITS as 100+.
Criteria for inclusion in the study were that the partici-
pant was a self-reported native English speaker (learned
from birth) and that they completed at least 80% of the
study. Repeated HITS from the same IP address (includ-
ing IP addresses from Experiment 1) are excluded (the
initial HIT is included).
Five additional participants completed at least 80% of

the study but were excluded due to missing demographic
information (n = 3), reporting gender as male (n = 2), or
reporting as a non-native English speaker (n = 1). We also
note that despite using Premium qualifications to select
participants who were between the ages of 18 and 30, of
the 150 participants included in the analysis, 17 partici-
pants reported an age of 31 or 32. Inclusion of these 17
participants in the final sample results in an average age of
26.2 years (SD = 3.3) versus 25.5 if they are excluded. As
this was unanticipated and the central tendency does not
shift much by including them, we chose to include these
17 participants in the final sample rather than remove
them in a post hoc decision. The majority of participants
(89%) had completed at least some college.

Table 3 Person-level covariates in Experiments 1 and 2, with
means and standard deviations by participants in parenthesesa

Experiment 1 Experiment 2

N 100 150

Age 36.77 (10.59) 26.17 (3.31)

Education – 3.13 (1.40)

Restraint 1.38 (1.6) 1.84 (1.85)

Eating concern 0.65 (0.95) 1.03 (1.19)

Shape concern 1.78 (1.66) 2.59 (1.88)

Weight concern 1.65 (1.52) 2.37 (1.74)

Global score 1.39 (1.33) 1.96 (1.51)
aNote that the education measure was not included in Experiment 1. The
Eating Disorder Examination Questionnaire measures are calculated for 143
participants in Experiment 2. See text for details

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 8 of 16

https://osf.io/dqrge


Materials
The materials were identical to Experiment 1, except that
we additionally asked about participants’ educational ex-
perience. Specifically, at the end of the study, participants
were asked the highest level of school they had completed
or the highest degree received, the year they graduated
from college, the year they received an undergraduate or
bachelor’s degree, and whether they were currently en-
rolled in school, along with the level of current enroll-
ment. These questions were included in order to better
characterize the sample, as prior work aims to understand
the social and physical factors that contribute to unhealthy
eating behaviors among college students (LaCaille, Dau-
ner, Krambeer, & Pedersen, 2011).

Predictions We expected to replicate the finding that
recognition memory for commented-on posts would be
better than posts that were passively viewed and that the
likelihood of correct recognition would increase with lon-
ger comments. If participants were to demonstrate reliable
individual differences in memory for food-related images
in particular, this would allow us to then test the hypoth-
esis that higher rates of disordered eating behaviors would
result in better memory for food-related images. To pre-
view, however, we again found that participants exhibited
stable individual differences in recognition memory but
that differences in memory between food and nonfood
items was itself not a reliable measure.

Results
As in Experiment 1, our primary analyses focused on
memory for the posts, analyzed using a logistic mixed-
effects model. In addition, we characterized the relation-
ship between the form of the comments and memory,
and finally we explored whether there were stable

individual differences in these effects. For illustration
purposes, the memory data are plotted using a measure
of memory sensitivity (d′) in Fig. 2.
A logit-link mixed effects model for memory judgments

(old = 1; new = 0) was fit to the 29,999 recognition mem-
ory judgments; note that one data point was lost due to
computer error. Planned fixed effects include orthogonal
Helmert codes for item type (old vs. new) and whether the
image had been commented on (comment vs. no com-
ment). Effects of image type were coded using the same
dummy-coding scheme as before, comparing memory for
nonfood (baseline) with memory for healthy and un-
healthy food. As before, the effects of item type and com-
menting can be interpreted as simple effects at the
reference level (control images), and interactions with
item type test whether these effects differ for healthy and
for unhealthy food. As in Experiment 1, a null model indi-
cated very little by-item variability but some by-subject
variability. Attempts to include the full random slopes
structure by person were met with convergence failures. A
backward-stepping procedure was used to remove random
slopes one by one to improve model fit. The final model
resulted in warnings, but refitting the model using the all-
Fit function indicated that estimates for the fixed effects
were identical to two decimal places for each of the opti-
mizers, indicating satisfactory model fit for inferences re-
garding the fixed effects. This model (Table 4) included
random intercepts for subjects and items and a random
slope for the item type effect by subjects.
A significant effect of item type (z = 30.23, p < .0001)

indicated good memory for the previously viewed im-
ages. A significant effect of commenting indicated that
previously viewed images were more likely to be cor-
rectly recognized if the participant had commented on
them (z = 37.41, p < .0001). These effects were qualified

Fig. 2 Experiment 2: Illustration of memory sensitivity (d′) by condition. Error bars indicate by-participant standard deviation

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 9 of 16



by interactions with image type. Unhealthy food was re-
membered better than control images (z = 8.81, p <
.0001). As in Experiment 1, the effect of commenting
was smaller for unhealthy food images, compared with
control images (z = − 3.22, p < .05); this interaction may
be due to the overall better memory for unhealthy food
in the first place.

Effect of comment length on memory for Instagram posts
Given the observed positive relationship between com-
ment length and recognition in Experiment 1, this
planned analysis was expected to reveal a positive rela-
tionship between comment length and successful recog-
nition. As before, the analysis was restricted to old items
for which participants generated a comment. The num-
ber of words in the comments ranged from 1 to 35
(mean = 4.12, median = 3). On average, comments were
longer for pictures that would ultimately be correctly
recognized (mean number of words = 4.15, SD = 1.90)
compared with pictures that were not recognized
(mean = 3.40, SD = 2.32). A logit-link mixed effects
model for memory judgments (old = 1; new = 0) was fit
to the data. Fixed effects included a centered measure of
the number of words used to comment on the picture.
The same dummy-coding scheme as in the primary ana-
lysis was used, comparing control images with healthy
and unhealthy food. Note that the effect of the number
of words can be interpreted as a simple effect at the ref-
erence level (control images) and interactions with item
type test whether this effect differs for healthy and for
unhealthy food images.
Participants and items were included as random inter-

cepts. A null model was initially fit to the data and indi-
cated very little variability by items but some variability
by participants. Thus, the effect of comment length was
included as a random by-participant slope. This model
converged. Attempts to fit more complex models with
interactions with image type were met with convergence

warnings indicating singular fits; thus, the results of this
model were taken to be satisfactory and interpreted
(Table 5). The significant intercept term indicates that
for these commented-on images (all of which were
old), correct recognitions were more likely than not
(z = 23.34, p < .0001). A significant effect of word
count (z = 4.61, p < .0001) shows that for each add-
itional word produced in the comment, the odds of
correct recognition were 1.20 times greater. The
remaining fixed effects were not significant, indicating
similar memory performance across the image types.

Participant variability and individual differences
The final model of recognition memory in Experiment 2
included a random slope for the item type effect by per-
sons (Table 4). As indicated above, models that included
more complex random slopes failed to converge, indicat-
ing that there was not strong support for consistent indi-
vidual differences in memory for healthy and unhealthy
food over nonfood images. We calculated the model-
based reliability for the by-participant effect of item type
(old vs. new). As in Experiment 1, Rho for the item type

Table 4 Experiment 2: Number of observations: 29,999, 200 items, 150 participants

Fixed effects Estimate SE z Value p Value

(Intercept) 0.127 0.067 1.894 .058

Commenting (commented = .5, noncommented = −.5, new = 0) 2.419 0.065 37.408 <.0001

Item type (commented = .5, noncommented = .5, new = − 1) 2.736 0.091 30.225 <.0001

Commenting * Healthy food −0.211 0.125 −1.684 .092

Commenting * Unhealthy food −0.433 0.135 −3.218 <.01

Item type * Healthy food 0.062 0.064 0.961 .336

Item type * Unhealthy food 0.625 0.071 8.806 <.0001

Random effects Variance SD Correlation

Item 0.1949 0.4415

Subject 0.4497 0.6706

Item type (subject) 1.0073 1.0036 0.09

Table 5 Experiment 2: Effect of comment length on
recognition of old images

Fixed Effects Estimate SE z Value p Value

(Intercept) 3.119 0.134 23.344 < .0001

Word count 0.182 0.039 4.612 < .0001

Words*Healthy 0.033 0.050 0.662 .508

Words*Unhealthy −0.002 0.050 −0.048 .962

Random Effects Variance SD Correlation

Item (intercept) 0.560565 0.74871

Participant (intercept) 1.212417 1.1011

Word count 0.008459 0.09197 0.43

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 10 of 16



effect was fairly high, .863, indicating stable individual
differences in memory for the pictures.
For the model of the effect of comment length on correct

recognition (Table 5), inspection of the random effects pa-
rameters indicated that while there was some variability in
the by-person intercept (reflecting individual differences in
correct recognition), the effect of word count on correct
recognition varied little across participants. Model-based
estimates of reliability (Cho et al., 2019) indicated a poor
rho value for the by-person intercept (.572); the extremely
small variance for the random slope for word count re-
sulted in a negative rho value (− 4.23). These findings indi-
cated that there was very little evidence for reliable
individual differences in these effects; thus, we do not ex-
plore them further.
Measures of individual differences in this sample include

the same EDE-Q measure as in Experiment 1, as well as age
and education level. EDE-Q scores for seven participants
were missing, and those participants were excluded from this
analysis. Descriptive statistics for the remaining 143 partici-
pants are shown in Table 3. The EDE-Q scores were higher
in this sample than for the participants in Experiment 2, con-
sistent with prior work indicating a higher incidence of disor-
dered eating in women (Cheng et al., 2019; Hudson et al.,
2007). Education level was recoded as a numeric variable
ranging from 0 to 6 to reflect highest level of educational
achievement attained (0 = less than high school degree; 6 =
post-graduate degree).
Exploratory bivariate correlations between the EDE-Q

measure, participant age, education level, and the by-
person random effects for response bias and overall
memory were computed and interpreted with respect to
a Bonferroni-adjusted alpha level of .0013. The bivariate
correlations revealed the expected relationships among
the EDE-Q subscales and the overall global score (Table
8 in Appendix). None of the other relationships were
significant. As in Experiment 1, the lack of stable indi-
vidual differences in memory for healthy and unhealthy
food in particular prevents examination of a relationship
between those food types and scores on the EDE.

Discussion
Experiment 2 repeated Experiment 1 on a sample of
young adults who reported their gender as female. Con-
sistent with the literature on disordered eating behaviors,
the average EDE-Q scores for this group were higher,
though still within 1 SD of published norms (Fairburn
et al., 2014). Despite these differences, the central results
of Experiment 1 were replicated. We replicated the find-
ing that the process of commenting on social media im-
ages boosts memory for those images, and we replicated
the finding that longer comments result in more correct
recognitions. We also replicated the curious effect that
unhealthy images were correctly recognized more often

than control images and that, in turn, the effect of com-
menting was smaller for unhealthy food images. While
the experiment failed to provide strong evidence for sys-
tematic individual differences in memory for food-
related Instagram posts, thus preventing our relating
food-specific memory to EDE-Q scores, we replicated
the finding that there were stable differences in overall
memory for the pictures. This finding indicates that fu-
ture work could use this paradigm as a starting point to
build an explanatory model of individual differences in
memory for social media images.

General discussion
Our most robust finding is that the act of commenting on
an Instagram post boosts memory for that post and, fur-
ther, that the odds of correct recognition increase the lon-
ger the comment. This finding, which was consistent
across five image categories (“healthy” and “unhealthy”
food, cats, dogs, and nature) indicates that the way in
which a user engages with content on social media shapes
memory for it. The Instagram platform is designed to
allow users to engage with content by commenting on it
(with emojis, text, and other in-app actions such as “lik-
ing” or sharing). Our findings indicate that engaging in
this way promotes the ability to later recognize those im-
ages. Another notable feature of the Instagram experience
is that users select what types of accounts to follow. While
we did not explore the implications of choosing what con-
tent to view, the fact that the observed relationship be-
tween commenting and memory was apparent for all
image types indicates that whatever content the user
chooses to follow, when they choose to engage with that
content, it is likely to impact memory.
We investigated memory for images of food in particular

due to their popularity on Instagram (e.g., #foodporn,
#foodie). Prior arguments that individuals with disordered
eating process food-related stimuli differently from healthy
participants (Nikendei et al., 2008; Shafran et al., 2007), along
with the fact that platforms such as Instagram are commonly
used to share information relevant to disordered eating be-
havior (see Chancellor et al., 2016), make it important to
understand how interacting with these types of stimuli im-
pacts the user. The present findings provide clear evidence
against the idea that there are stable individual differences in
memory for food, at least in a nonclinical sample. Instead of
an individual trait, the observed memory benefit for “un-
healthy” food over control images may be a more general
phenomenon, potentially related to the fact that food, par-
ticularly high-calorie food, is rewarding (see Frank et al.,
2010; Simmons, Martin, & Barsalou, 2005).
While we do not find consistent individual differences

in memory for food in particular, it is important to con-
sider the fact that some users may curate their content
in order to view primarily food- and/or dieting-related

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 11 of 16



content. Our findings show that engaging with social
media images through commenting extends the user ex-
perience beyond the in-the-moment experience of the
platform, promoting subsequent ability to recognize that
content later. Thus, an important question for future work
is whether the observed memory effects impact future
real-world behaviors associated with that content, particu-
larly in clinical samples. Social media users will retain
memory for whatever content they choose to view; thus,
choices over what to view may be relevant to consider-
ations of how social media use impacts the user. Finally,
the lack of reliable individual differences in memory for
food, despite a consistent finding across experiments of
better memory for unhealthy food vs. control, may owe to
the fact that low between-participant variance may be ne-
cessary to produce a stable experimental effect – the “reli-
ability paradox” (Hedge, Powell, & Sumner, 2018).
We also found that the “unhealthy” food images,

which included posts featuring items such as cake,
cheeseburgers, and pizza, were remembered better in
both experiments than our control images, which in-
cluded cats, dogs, and nature pictures. This unexpected
finding may relate to the attention-captivating properties
of high-calorie food (Castellanos et al., 2009), along with
arguments that thinking about the survival relevance of
a stimulus boosts memory for it (Nairne & Pandeirada,
2010). A limitation of this explanation, however, is that
Nairne and Pandeirada (2010) found that it is processing
an item’s relevance to survival that boosts memory, re-
gardless of whether those items were in fact relevant to
survival. Of course, explaining this item-specific effect
would require further study and ruling out other expla-
nations related to specific item properties.
This project was inspired by previously observed bene-

fits of generating picture descriptions for subsequent
recognition memory (McKinley et al., 2017; Yoon et al.,
2016; Zormpa et al., 2019). Here we show that this result
extends to the socially relevant domain of social media
images. Consistent with the present results are findings
that sharing personal memories on social media plat-
forms improves memory for memories that were shared
compared with those that were not shared (Wang, Lee,
& Hou, 2016; see Stone & Wang, 2019, for discussion).
One issue that Stone and Wang (2019) raised is that in-
formation that persons choose to share may be inher-
ently more memorable. We note that in the present
research, participants did not choose what to comment
on; yet, we similarly observed a benefit to memory for
engaging with the images.
However, other research indicates that engaging with

media and technology more generally can impair mem-
ory. For example, the use of media to record or share
thoughts during an experience harms subsequent mem-
ory for that experience compared with not using media

to memorialize the experience (Tamir, Templeton,
Ward, & Zaki, 2018). Similarly, the act of photographing
objects can harm memory for those objects (Henkel,
2014). The presence of smartphones nearby in the room
impairs performance on working memory tests (Ward,
Duke, Gneezy, & Bos, 2017), suggesting that even the
potential to disengage may harm one’s ability to fully
process the current experience. Further, frequent use of
social media is associated with poorer academic out-
comes (Feng, Wong, Wong, & Hossain, 2019) and with
memory failures (Sharifian & Zahodne, 2019).
The present finding that engaging with social media

through commenting improved memory for it is not ne-
cessarily inconsistent with this evidence of technology-
related memory impairment. The difference in findings
may relate to the fact that extracting the self from an ex-
perience long enough to memorialize it with media de-
tracts from the experience itself. By contrast, generating
a comment about a social media image may enhance the
experience of the image through elaborative encoding
(Bradshaw & Anderson, 1982). Commenting on social
media images may also invite rehearsal (Roediger and
Karpicke, 2006) or offloading (Storm & Stone, 2015) ef-
fects, promoting recollection (for discussion, see Marsh
& Rajaram, 2019; Stone & Wang, 2019). Thus, the im-
pact of engaging with technology on memory may de-
pend on the user experience and whether the experience
interferes with the processing of the to-be-encoded
event in the first place. More generally, understanding
the cognitive implications of engaging with the Internet
and social media may require a better understanding of
how usage patterns change with time and with increased
use (see Storm, Stone, & Benjamin, 2017).

Conclusion
The tremendous popularity of social media as an outlet
for leisure and social interaction makes it increasingly im-
portant to understand how engaging with social media
shapes cognitive processes. Consider the fact that on
Instagram alone, the comment #foodporn has been used
over 206 million times, #food over 354 million times, and
even #omgyum over 38,000 times. The results of two ex-
periments show that generating comments such as these
changes the way those images are memorialized, offering
an ecologically valid replication and extension of prior
work (McKinley et al., 2017; Yoon et al., 2016). The fact
that “unhealthy” food images such as chocolates were par-
ticularly well remembered raises new questions about the
impact of engaging with food-related content on subse-
quent cognition. Taken together, our findings show that
the way in which we engage with social media content
shapes subsequent memory for it, raising tantalizing ques-
tions about how our online lives persist in memory over
time, potentially shaping future behavior.

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 12 of 16



Appendix

Table 6 Descriptions of the “healthy” and “unhealthy” food items for List 1 in the studya

Healthy food (old) Unhealthy food (old)

1. Diced watermelon with lemon 1. Chocolate filled donuts

2. Grilled shrimp + broccoli 2. Pepperoni pizza, stuffed crust

3. Salad with avocado and brown rice 3. Slice of Oreo cheesecake

4. Strawberry yogurt + whole strawberries 4. Cinnamon rolls

5. Grain bowl with tofu + broccoli 5. Whole chocolate cake filled with candy

6. Sliced fruit with fruit juice 6. Chocolate- and Oreo-covered strawberries

7. Toast with smoked salmon and zucchini 7. Fudge brownies with pretzels

8. Corn, avocado, and tomato salad 8. Slice of red velvet cake

9. Acai bowl topped with berries and banana 9. Peanut butter brownies with M&Ms

10. Salmon, veggies, and quinoa 10. Bacon double cheeseburger

11. Sautéed vegetables 11. Cheese and jalapeño pizza

12. Tomato, cucumber, and avocado salad 12. Pecan praline French toast

13. Spaghetti squash 13. Chicken wings + ranch dressing

14. Tropical smoothie bowl 14. Chocolate cannolis

15. Bowl of berries and kiwi 15. Milkshakes with whipped cream

16. Vegetable kabobs 16. Ice cream cookie sandwich

17. Vegetable sandwich 17. Whole Nutella cake

18. Bowl of strawberries, raspberries, and mangos 18. Cheesy pizza missing a slice

19. Fruit and nut granola 19. Oreo candy bar

20. Sautéed shrimp + orange slices 20. Six whole chocolate cakes

Healthy (new) Unhealthy (new)

1. Bowl of watermelon, kiwi, and orange 1. Slice of chocolate cake

2. Rice bowl with tofu, greens, and tomato 2. Cheesy pizza

3. Fruit and nut cereal with milk 3. Whole chocolate layer cake

4. Tropical fruit bowl + flowers 4. Whole chocolate truffle cake with cream

5. Grilled shrimp + asparagus 5. Chocolate-drizzled brownies

6. Breakfast porridge with banana and mango 6. Bacon cheeseburger with fries

7. Fruit + nut yogurt bowl 7. Oreo cookie milkshakes

8. Bowl of strawberries, raspberries, and watermelon 8. Box of chocolate-covered donuts

9. Pumpkin + spinach pasta serving 9. Cookie dough + sprinkles on ice cream

10. Vegan dish of chicken, veggies, and brown rice 10. Box of stuffed bagel bites

11. Fruit kabobs 11. Cookies and cream brownies

12. Cauliflower rice, cucumber, and salmon bowl 12. Basil pizza

13. Bowl of mangos, kiwi, blueberries, and dragon fruit 13. Multiple Oreo candy bars

14. Grain bowl with veggies, greens, and salmon 14. Cheese pizza on the beach

15. Banana and almond butter granola 15. Large jalapeño and pepperoni pizza in a box

16. Blueberries 16. Barbecue sandwich with fries

17. Avocado + egg Cobb salad 17. Chocolate and Kit Kat candy bar whole cake

18. Caprese avocado toast 18. Fried chicken + fries and dip

19. Smoothie bowl with strawberries, cocoa nibs, and bananas 19. Donut topped with candy, sprinkles, and cookie dough

20. Cinnamon and raisin oatmeal 20. Cadbury Creme Egg stuffed brownie
aAcross the four lists, we counterbalanced which items were old vs. new

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 13 of 16



Table 7 Experiment 1: bivariate correlations between person-level covariates of age and Eating Disorder Examination Questionnaire
subscales and global scale, as well as correlations with model-derived by-person estimates for response bias, memory, and the effect
of commentinga

Bias Memory Comment Restraint Eating Shape Weight EDE global Age

Bias 1.000

Memory 0.288 1.000

Comment −0.226 0.487 1.000

Restraint 0.088 0.034 0.043 1.000

Eating 0.275 −0.126 − 0.255 0.579 1.000

Shape 0.236 0.004 − 0.093 0.675 0.812 1.000

Weight 0.197 −0.016 − 0.103 0.644 0.795 0.958 1.000

EDE global 0.229 0.021 −0.097 0.821 0.828 0.953 0.939 1.000

Age 0.055 0.356 0.309 0.042 −0.052 0.055 0.014 0.038 1.000

Correlations that are significant at a Bonferroni-corrected alpha level of .0013 (for 36 comparisons) are marked in boldface. The Eating Disorder Examination Ques-
tionnaire (EDE) included the following scales: Restraint, Eating, Shape, Weight, EDE global

Table 8 Experiment 2: bivariate correlations between person-level covariates of age, education, and Eating Disorder Examination
Questionnaire subscales and global scale, as well as correlations with model-derived by-person estimates for response bias and
memorya

Bias Memory Education Restraint Eating concern Shape concern Weight concern Global Age

Bias 1

Memory 0.122 1

Education 0.048 0.046 1

Restraint 0.010 0.006 −0.097 1

Eating concern −0.072 0.028 −0.129 0.664 1

Shape concern −0.034 0.034 −0.095 0.689 0.783 1

Weight concern −0.073 0.008 −0.077 0.690 0.771 0.946 1

Global −0.043 0.020 −0.107 0.851 0.867 0.950 0.946 1

Age 0.087 −0.037 0.183 0.082 −0.086 0.021 0.007 0.016 1

Correlations that are significant at a Bonferroni-corrected alpha level of .0013 (for 36 comparisons) are marked in boldface. The Eating Disorder Examination Ques-
tionnaire (EDE) included the following scales: Restraint, Eating, Shape, Weight, EDE global

Zimmerman and Brown-Schmidt Cognitive Research: Principles and Implications            (2020) 5:16 Page 14 of 16



Abbreviation
EDE-Q: Eating Disorder Examination Questionnaire

Acknowledgements
Thank you to Lisa Fazio for helpful conversations about this research project.

Authors’ contributions
The authors jointly conceived of, designed, and ran the experiments;
analyzed the data together; and wrote the paper together. Both authors
read and approved the final manuscript.

Funding
Preparation of the manuscript was supported in part by National Science
Foundation grants BCS 15-56700 and BCS 19-21492 to SBS.

Availability of data and materials
The raw, de-identified data associated with this article are available at
(https://osf.io/8gafu/). Materials are available upon request.

Ethics approval and consent to participate
The research procedures were approved by the Vanderbilt University Human
Research Protections Program, and all participants consented prior to
participation in this research.

Consent for publication
Not applicable.

Competing interests
The authors declare that they have no competing interests.

Received: 18 September 2019 Accepted: 18 February 2020

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	Abstract
	Background
	Results
	Conclusions

	Significance Statement
	Introduction
	Experiment 1
	Methods
	Participants
	Materials
	Procedure
	Additional measures

	Results
	Memory for Instagram posts
	Effect of comment length on memory for Instagram posts
	Participant variability and Individual differences

	Discussion

	Experiment 2
	Methods
	Participants
	Materials

	Results
	Effect of comment length on memory for Instagram posts
	Participant variability and individual differences

	Discussion

	General discussion
	Conclusion

	Appendix
	Abbreviation
	Acknowledgements
	Authors’ contributions
	Funding
	Availability of data and materials
	Ethics approval and consent to participate
	Consent for publication
	Competing interests
	References
	Publisher’s Note