1
Abstract
Sleep has been shown to play a crucial role in the consolidation of emotionally
salient memories. However, the influence of sleep, and Sleep Deprivation (SD), on
emotional memory consolidation in depressive individuals remains elusive. For this
experiment we recruited two groups of healthy students, one reporting mild-to-severe
depressive symptoms, and another reporting minimal/no depressive symptoms
(assessed using the Beck Depression Inventory; BDI-II). We measured recognition
performance for positive, neutral and negative images before and after a 12 h
overnight retention interval, during which participants either remained awake in the
laboratory or returned home to sleep normally. We found a significant depressive
symptomatology group x sleep condition x image valence interaction on memory
consolidation across the 12 h retention interval [F(2, 98) = 3.12, p = .049, ηp² =
0.060]. We also found that depressive participants who slept normally consolidated
significantly more negative and neutral images across the 12 h retention interval than
depressive participants who were sleep deprived [t(24) = 2.35, p = .028, t(24) = 2.79,
p = .010, respectively]. Our preliminary results indicate that SD may impair the
consolidation of negative and neutral memories in depressive participants, but not in
participants reporting minimal/no depressive symptoms.
Keywords: sleep deprivation; emotional memory; depression; REM sleep
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1. Introduction
Individuals reporting symptoms of depression such as despair and
hopelessness exhibit greater recall and recognition performance for negative
emotional stimuli, relative to individuals reporting minimal/no depressive symptoms
(Everaert, Duyck, & Koster, 2014; Fattahi Asl, Ghanizadeh, Mollazade, & Aflakseir,
2015; Howe & Malone, 2011). This emotional memory bias may increase
vulnerability to the development and recurrence of Major Depressive Disorder (MDD;
Beck, 1967; Everaert, Koster, & Derakshan, 2012; Gotlib & Joormann, 2010). In
healthy participants, emotionally salient memories are better remembered than their
neutral or mundane counterparts (Kensinger, 2004; McGaugh, 2004). Emotionally
enhanced memory may be facilitated by sleep, which selectively consolidates
memories which elicit emotional arousal (Payne, Chambers, & Kensinger, 2012;
Payne, Stickgold, Swanberg, & Kensinger, 2008).
Empirical evidence suggests that Rapid Eye Movement (REM) sleep, in
particular, plays a crucial role in the consolidation of emotional memories (Groch,
Zinke, Wilhelm, & Born, 2015; Nishida, Pearsall, Buckner, & Walker, 2009; Payne et
al., 2012; Wagner, Gais, & Born, 2001; Wiesner et al., 2015). For example, in
healthy students selective REM Sleep Deprivation (SD) has been shown to impair
the consolidation of negative emotional images, but not emotionally neutral images,
to a greater extent than selective Slow-Wave Sleep (SWS) deprivation (Wiesner et
al., 2015). Furthermore, correlational analyses reveal that, for healthy individuals,
greater consolidation of emotionally negative images is predicted by longer duration
of time spent in REM sleep during retention intervals (Nishida et al., 2009; Payne et
al., 2012). Similarly, split-night studies in healthy participants have shown that 3h of
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late night REM-rich sleep fosters the selective consolidation of emotionally negative
stimuli more abundantly than 3 h of early night sleep where REM sleep is less
plentiful (Groch et al., 2015; Wagner et al., 2001). Importantly, although it is clear
that REM sleep is centrally involved in emotional memory consolidation, SWS has
also been shown to contribute to this process in some studies (e.g. Cairney, Durrant,
Power, & Lewis, 2015; Sabine Groch et al., 2011). Moreover, contrary to the bulk of
the existing literature, some investigations have failed to detect a specific role for
REM sleep in emotional memory consolidation (Ackermann, Hartmann,
Papassotiropoulos, de Quervain, & Rasch, 2015; Cellini, Torre, Stegagno, & Sarlo,
2016; Morgenthaler et al., 2014).
Experiments investigating the relationship between sleep and memory in
depressive participants have mostly shown that sleep-associated consolidation is
impaired in MDD patients. For example, healthy controls have been shown to exhibit
greater overnight improvements on a motor memory task than MDD patients (Dresler
et al., 2011; Dresler, Kluge, Genzel, Schüssler, & Steiger, 2010; Nishida,
Nakashima, & Nishikawa, 2016). Moreover, MDD patients who performed poorly on
a declarative visual memory task exhibited shorter REM sleep duration and total
sleep time than patients who performed well on the task (Göder et al., 2007). The
association between sleep and emotional memory in depressive participants has
received comparatively less empirical attention. Nonetheless, we recently revealed
that late night REM-rich sleep promotes the consolidation of negative emotional
images more readily in participants reporting mild-to-moderate depressive symptoms
than participants reporting minimal/no symptoms of depression (Harrington,
Johnson, Croom, Pennington, & Durrant, 2018).
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The current study aimed to investigate the short- and long- term effect of post-
learning sleep, or SD, on recognition performance for positive, neutral and negative
images in samples of healthy participants reporting either minimal/no depressive
symptoms or mild-to-severe depressive symptoms. These two groups of participants
are referred to below as the low Beck Depression Inventory (BDI-II) score group and
the higher BDI-II score group, respectively. Although it has been shown that SD, and
selective REM SD, impairs the consolidation of emotionally negative information in
healthy participants (Tempesta, De Gennaro, Natale, & Ferrara, 2015; Wiesner et
al., 2015); the effect of SD on emotional memory consolidation in participants
reporting depressive symptoms remains unexplored. We predicted that SD would
impair the consolidation of negative emotional memories, and that this effect would
be more robust in the higher BDI-II score group than the low BDI-II score group.
2. Materials and Methods
2.1. Participants
Recruitment was based on BDI-II (Beck, Steer, & Brown, 1996) scores
obtained from a prescreen of 128 student volunteers who signed up using an online
research participation system. Fifty-six participants were selected based on their
prescreen BDI-II scores and assigned to one of two depressive symptomatology
groups: a low BDI-II score group and a higher BDI-II score group (see Section 2.1.1
for group criteria). Both depressive symptomatology groups were then randomly sub-
divided into a further two separate sleep condition groups, a Sleep Deprivation (SD)
condition and a Normal Sleep (NS) condition (see Section 2.3 for information about
sleep conditions). Participants were required to have no history of sleep,
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neurological, endocrine or psychiatric disorders as assessed through self-report.
Participants were also free of long-term medication (except for the female
contraceptive pill), and were native English speakers.
Of the selected participants, two were excluded from final analyses for failing
to meet the eligibility criteria at the first subsequent test session (i.e. they were
originally assigned to the higher BDI-II score group, but reported a BDI-II score
below the cut-off boundary for this group at the first subsequent test session). Data is
reported from the remaining 54 participants (see Table 1): 14 in the higher BDI-II
score SD group (four male, ten female) aged 19 – 23, 12 in the higher BDI-II score
NS group (three male, nine female) aged 18 – 23, 14 in the low BDI-II score SD
group (six male, eight female) aged 18 – 22, and 14 in the low BDI-II score NS group
(four male, ten female) aged 18 – 25.
Table 1. Summary of participants’ demographic data, separately for each depressive symptomatology group and sleep condition group
Low BDI-II score group Higher BDI-II score group
NS group SD group NS group SD group
n 14 14 12 14
Gender (m/f) 4/10 6/8 3/9 4/10
Age (years) 19.86 (0.62) 19.43 (0.33) 19.92 (0.45) 20.14 (0.36)
BDI-II 1.86 (0.50) 2.43 (0.62) 21.50 (2.01) 20.50 (1.27)
PSQI 3.64 (0.53) 4.29 (0.47) 8.17 (0.92) 8.00 (0.79)
Mean values are presented with SEM in parenthesis. Higher scores indicate greater depressive symptoms or sleep quality impairment. Abbreviations: NS, Normal Sleep; SD, Sleep Deprivation; BDI-II, Beck Depression Inventory; PSQI, Pittsburgh Sleep Quality Index.
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Participants were asked to abstain from alcohol, caffeine, and other drugs for
24 h prior to test sessions. Participants were rewarded for their participation with
course credits. Each participant gave informed consent for this study, which was
approved by the School of Psychology Research Ethics Committee at the University
of Lincoln.
2.1.1. Depressive Symptomatology Groups
The BDI-II measures depressive symptom severity with 21 items rated on a
scale from zero to three. This self-report measure has good reliability and validity in
both healthy and depressed samples (Beck et al., 1996) and is widely used in
cognitive research (Everaert et al., 2014; Hindash & Amir, 2011; Newby, Lang,
Werner-Seidler, Holmes, & Moulds, 2014). Prescreen data showed that BDI-II scores
ranged from zero to 52, with 92 individuals reporting minimal/no (BDI-II cut off range:
0 - 13), 16 mild (BDI-II cut off range: 14 - 19), 13 moderate (BDI-II cut off range: 20 -
28), and seven severe symptom levels (BDI-II cut off range: 29 - 63). We invited
individuals reporting BDI-II scores ≥ 14, and a matching number of individuals who
reported the lowest BDI-II scores at the prescreen, to participate in this study.
Individuals who accepted our invitation, reported BDI-II scores ≤ 13 at both the
prescreen and the first test session, and successfully completed the study, make up
the low BDI-II score group (BDI-II score: mean = 2.14, range = 0 - 6). Individuals who
accepted our invitation, reported BDI-II scores ≥ 14 at both the prescreen and the
first test session, and successfully completed the study, make up the higher BDI-II
score group (BDI-II score: mean = 20.96, range = 14 - 35). BDI-II scores did not
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fluctuate between the prescreen and the first test session to the extent that they no
longer fit the ranges outlined above.
2.2. Stimuli
Three hundred and sixty images were selected from the International Affective
Picture System (IAPS; Lang, Greenwald, Bradley, & Hamm, 1993). IAPS images
range from photographs depicting happy relationships, to everyday scenes, to
images of injury and violence, and each are rated on nine-point scales for emotional
valence (1 = negative, 5 = neutral, 9 = positive) and arousal (1 = calm, 9 = exciting).
Images were selected based on their valence and arousal ratings, and placed into
one of three emotion categories: “positive”, “neutral” or “negative”, each of which
contained 120 images. Pairwise comparisons demonstrated that there was a
significant difference in the mean IAPS valence rating (i.e. normative valence ratings
from the IAPS database) between all emotion categories (positive: [7.31 ± 0.04;
mean ± SEM], neutral: [5.04 ± 0.02], negative: [2.42 ± 0.05]; all pairwise p < .001).
There was also a significant difference in the mean IAPS arousal rating (i.e.
normative arousal ratings from the IAPS database) for the neutral category relative
to the positive and negative categories (positive: [5.5 ± 0.06], neutral: [3.33 ± 0.06],
negative: [5.5 ± 0.06]; both p < .001), however we ensured that there was no
significant difference in the mean normative arousal rating between the positive and
negative categories [p = .886].
Selected images were divided into two equal sets of 180 (60 positive, 60
neutral, 60 negative), which were matched as closely as possible for IAPS valence
and arousal ratings. During learning phases, each participant viewed one of these
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two sets of images which served as the targets during subsequent recognition tests
(see Section 2.4 for details regarding learning phases and recognition tests). Each of
the two sets of images was further subdivided into three equal sets of 60 (20
positive, 20 neutral, 20 negative), which were also matched as closely as possible
for IAPS valence and arousal ratings. During each of the three recognition tests
(immediate recognition, 12 h recognition, 7 d recognition; see Section 2.3 for
information about the study protocol), participants viewed one of the three sets of 60
images which they saw during the learning phase (targets) intermixed with one of the
three sets of 60 images from the other set of 180 (foils). The image sets used for
encoding and recognition tests were counterbalanced across depressive
symptomatology groups and sleep condition groups as closely as possible (i.e. each
set of learning phase images and recognition test images was viewed approximately
an equal number of times by each depressive symptomatology group and each
sleep condition group). The image sets used for recognition tests were also viewed
approximately an equal number of times at each recognition test (i.e. immediate
recognition, 12 h recognition, 7 d recognition).
2.3. Experimental Protocol
The experimental protocol is summarised in Fig 1. Participants took part in
one of two experimental conditions, a SD condition or a NS condition. All participants
arrived at the Lincoln Sleep and Cognition Laboratory at 8 PM. The study protocol
began with participants completing the BDI-II and the Pittsburgh Sleep Quality Index
(PSQI; a self-report measure of subjective sleep quality over the last month; Buysse,
Reynolds, Monk, Berman, & Kupfer, 1989). This was immediately followed by a
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learning phase and immediate recognition test (see Section 2.4 for details) which
lasted approximately 1 h in total. Participants assigned to the NS group then
returned home where they were asked to be in bed from 10.30 PM to 7.30 AM and to
sleep normally, before returning to the laboratory at 8 AM the following morning. This
group of participants recorded their sleep using portable, in-home PSG devices
(Sleep ProfilerTM; Levendowski et al., 2017; see Section 2.5.2 for details).
Participants assigned to the SD group remained awake in the laboratory under the
supervision of the researcher until the following morning. During this time
participants were free to eat, drink, read, listen to music, communicate with the
researcher, or use the computer. Participants were not permitted to consume
alcohol, caffeine, or other drugs during this time.
Fig 1. Pictorial representation of the study protocol. Participants in the SD condition began a learning phase at 8 PM which was followed by an immediate recognition test. They then remained awake in the laboratory until 8 AM the following morning, before completing a 12 h recognition test. Participants in the NS condition began a learning phase at 8 PM which was followed by an immediate recognition test. They then returned home to sleep normally between 10.30 PM and 7.30 AM, before returning to the laboratory for a 12 h recognition test at 8 PM. These participants recorded their sleep using a Sleep ProfilerTM In-home EEG Sleep Monitor. Participants in both conditions returned to the laboratory at 8 PM, one week after the learning phase, to complete a 7 d recognition test. Abbreviations: PSG, Polysomnography; SD, Sleep Deprivation; NS, Normal Sleep.
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At 8 AM (12 h after the learning phase) all participants completed a 12 h
recognition test which lasted approximately 30 min and provided a measurement of
consolidation processes which occurred during the preceding 12 h of sleep or
wakefulness. One week after the learning phase, participants returned to the
laboratory at 8 PM where they completed a 7 d recognition test which also lasted
approximately 30 min. The purpose of this one week follow-up was to examine the
impact of SD on long-term consolidation processes. The 7 d recognition test was
carried out at the same time of day as the immediate recognition test to control for
the impact of circadian rhythms on cognitive performance (Blatter & Cajochen, 2007;
Kyriacou & Hastings, 2010).
2.4. Learning Phases and Recognition Tests
The immediate recognition test was administered immediately after the
learning phase. Prior to each recognition test participants indicated their level of
sleepiness on a scale from one (alert, wide awake) to seven (fighting sleep) using
the Stanford Sleepiness Scale (SSS; Hoddes, Dement, & Zarcone, 1972). The two
delayed recognition tests (i.e. 12 h and 7 d) were identical to the immediate
recognition test, except that they contained different target and foil images (see
Section 2.2 for more information about image sets).
The learning phase and recognition tests are summarised in Fig 2. At the
beginning of the learning phase participants saw a black screen with a white central
fixation cross for 500 ms. They were then presented with the first image (size: 15 cm
x 11 cm) for 1000 ms which appeared in the centre of the screen. Following the
image, participants were prompted to provide a valence rating for the image on a
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scale from one (very negative) to nine (very positive) using corresponding keys.
Once a valence rating had been submitted, participants were prompted to rate the
image for emotional arousal on a scale from one (low arousal) to nine (high arousal).
After the arousal rating had been submitted, participants were again presented with
the fixation cross followed by the second image. This pattern continued until every
image had been viewed and rated. Participants were instructed to provide their
emotion ratings quickly and spontaneously, and were informed prior to the learning
phase that their memory for the images would be tested immediately after learning
and again after both 12 h and 7 d.
Fig 2. Pictorial representation of the learning phase and recognition tests. During learning phases and recognition tests participants were required to rate each image on a scale from one to nine in terms of emotional valence (1 = very negative, 9 = very positive) and emotional arousal (1 = low arousal, 9 = high arousal). During recognition tests, participants were additionally required to provide remember (R), know (K), or new (N) response.
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The recognition tests were identical to the learning phase except that before
providing their emotion ratings participants were required to make a remember/
know/ new judgement for the image using corresponding keys (i.e. R, K or N). For
the R/K/N procedure, participants were instructed to provide a remember (R)
response if they could consciously recollect seeing that specific image during the
prior learning phase. They were asked to provide a know (K) response if they felt the
image was familiar, but they could not consciously recollect details about its previous
occurrence. They were asked to press the new (N) key if they felt that they had not
seen the image during the prior learning phase. These instructions were presented
both orally and as text on the computer monitor before the task commenced. A
“remember” response indicates recollection of the episodic details of an item,
whereas a “know” response reflects item familiarity in the absence of recollection
(Mickley & Kensinger, 2008); these different forms of remembering are thought to be
supported by different neural processes (Dobbins, Kroll, & Yonelinas, 2004;
Yonelinas, 2002). For this study, we were particularly interested in examining
remember responses (see Section 2.6.1 for more information). Participants were
asked to provide their memory judgements as quickly and accurately as possible.
There was no time constraint for memory judgments or emotion ratings in the
learning phase or recognition tests.
2.5. Equipment
2.5.1. Experimental Task
Stimulus presentation and data collection used custom-written scripts running
in SuperLab 5TM (Cedrus Corp, San Pedro, CA) on a Windows desktop computer
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with a 15.6” screen. Participant responses were recorded using the computer
keyboard.
2.5.2. Polysomnography
Overnight sleep monitoring of participants in the NS group was carried out in
the homes of participants using a Sleep ProfilerTM in-home EEG Sleep Monitor,
which provides data comparable to lab-based PSG (Lucey et al., 2016). Disposable
electrodes were attached at two standard locations according to the international 10
- 20 system (Homan, Herman, & Purdy, 1987): Fp1 and Fp2, as well as upper and
lower chin electromyogram and a reference electrode placed at Fpz. All electrodes
were verified to have a connection impedance of < 5 000 Ω. All signals were digitally
sampled at a rate of 256 Hz.
2.6. Data Analysis
2.6.1. Behavioural Data Analysis
Although our experimental task provided an index of both recollection (R
responses) and familiarity (K responses) recognition performance (see Fig 2), we
were particularly interested in recollection as this has previously shown emotion-
specific sensitivity to sleep (Cairney et al., 2015; Harrington et al., 2018). Therefore,
we made this the primary focus of this manuscript. Nonetheless, analyses pertaining
to familiarity recognition performance, and combined recollection and familiarity
recognition performance, are available in Supplement 1 and Supplement 2,
respectively.
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Data from recollection trials were first converted to d’ scores (d’ = Z (hits / hits
+ misses) – Z (false alarms / false alarms + correct rejections); extreme proportions
of zero or one were replaced with values of “1 / (2N)” and “1 – 1 / (2N)”, respectively,
where N equals the number of trials upon which the proportion is based; Macmillan &
Kaplan, 1985), a signal detection process widely used in memory studies to account
for response bias (Macmillan & Creelman, 2005). This was done separately for
positive, neutral and negative image trials for each participant. In accordance with
previous research (Cairney et al., 2015; Groch et al., 2015; Nishida et al., 2009), to
measure the time course of memory consolidation we created a difference measure,
which we refer to as ‘behavioural consolidation’, by subtracting d’ scores at
immediate recognition testing from d’ scores at 12 h and 7 d recognition testing. The
resulting behavioural consolidation scores provide indices of the emotional memory
processes taking place across the 12 h and 7 d retention intervals, respectively.
Our main analysis used a two (depressive symptomatology group: higher BDI-
II score group, low BDI-II score group) x two (sleep condition group: SD, NS) x three
(image valence: positive; neutral; negative) mixed-measures ANOVA with
behavioural consolidation as the dependent variable. Our primary hypothesis was
that there would be a significant three-way ‘depressive symptomatology group’ x
‘sleep condition group’ x ‘image valence’ interaction, driven by impaired
consolidation of negative images in the higher BDI-II score SD group.
2.6.2. Sleep Data Analysis
Each participant’s sleep data was divided into 30 s epochs and scored
manually by trained sleep researchers using REM Logic© 1.1 according to the AASM
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standardised criteria (Iber, Ancoli-Israel, Chesson, & Quan, 2007). Sleep data was
scored from a channel created by referencing Fp1 to Fp2 (for more information see:
Lucey et al., 2016). This gave the duration and proportion of each sleep stage (N1,
N2, SWS, and REM), as well as measures of sleep efficiency and total sleep time.
3. Results
3.1. Participant Demographics
The participants’ demographic characteristics are shown in Table 1. To
compare demographic characteristics between depressive symptomatology groups
(higher BDI-II score group, low BDI-II score group) we conducted independent-
samples t-tests, which confirmed that the higher BDI-II score group had significantly
higher BDI-II scores than the low BDI-II score group [t(52) = 16.18, p < .001]. The
higher BDI-II score group also reported significantly higher PSQI scores than the low
BDI-II score group [t(52) = 6.08, p < .001], indicating poorer sleep quality in the
higher BDI-II score group, as expected (Baglioni et al., 2011; Palagini et al., 2013).
There was no significant age difference between the two depressive
symptomatology groups [t(52) = 0.88, p = .382].
To examine whether demographic characteristics differed between sleep
condition groups (i.e. SD group, NS group), the independent-samples t-tests
reported above were repeated, this time comparing sleep condition groups,
separately for each depressive symptomatology group (i.e. higher BDI-II score
group, low BDI-II score group). There was no significant difference between the SD
group and the NS group in BDI-II score, PSQI score, or age in either the higher BDI-
II score group [all p ≥ .668] or the low BDI-II score group [all p ≥ .374]. These results
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suggest that between- sleep condition group differences in depressive symptom
severity, sleep quality or age can reasonably be discounted as a source of variability
in recognition performance.
3.2. Alertness
Subjective sleepiness scores are shown in Table 2. To examine the effect of
recognition test (immediate, 12 h, 7 d), depressive symptomatology group, and sleep
condition group on subjective sleepiness, we conducted a three (time: immediate, 12
h, 7 d) x two (depressive symptomatology group: higher BDI-II score group, low BDI-
II score group) x two (sleep condition group: SD group, NS group) mixed-measures
ANOVA on SSS scores. A significant main effect of time was revealed [F(2, 98) =
45.82, p < .001, ηp² = 0.483], which was largely driven by a significant interaction
between time and sleep condition group [F(2, 98) = 24.91, p < .001, ηp² = .337]. The
ANOVA revealed no other significant main effects or interactions [p ≥ .124],
suggesting that between- depressive symptomatology group differences in alertness
at any of the three test sessions can reasonably be discounted as a source of
variability in recognition performance.
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Table 2. Subjective sleepiness scores before each recognition test, separately for each depressive symptomatology group and sleep condition group
Low BDI-II score group Higher BDI-II score group
NS group SD group NS group SD group
SSS immediate 2.29 (0.13) 2.29 (0.19) 3.00 (0.28) 3.29 (0.22)
SSS 12 h 2.21 (0.21) 4.86 (0.35) 3.58 (0.42) 4.93 (0.40)
SSS 7 d 2.07 (0.20) 1.77 (0.17) 2.83 (0.39) 2.50 (0.25)
Mean values are presented with SEM in parentheses. Higher values indicate greater subjective sleepiness. Abbreviations: NS, Normal Sleep; SD, Sleep Deprivation; SSS, Stanford Sleepiness Scale.
To explore the interaction between time and sleep condition, we compared
SSS scores between the two sleep conditions, separately for each recognition test
(immediate, 12 h, 7 d), using independent-samples t-tests. It was revealed that
relative to the NS condition, participants in the SD condition reported significantly
greater subjective sleepiness before the 12 h recognition test [t(52) = 5.59, p < .001].
There was no difference in SSS scores between the two sleep condition groups
before the immediate recognition test [t(52) = 0.72, p = .473] or the 7 d recognition
test [t(52) = 1.01, p = .316]. These results confirm that, unsurprisingly, participants in
the SD group felt more tired before the 12 h recognition test, following a night of SD.
Importantly, however, there was no correlation between 12 h SSS scores and
behavioural consolidation of positive, neutral or negative images for participants who
completed the SD condition [all p ≥ .490], suggesting that decreased subjective
alertness is unlikely to underlie any between-condition differences in recognition
performance.
3.3. Sleep Parameters
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Sleep parameter data obtained from the higher BDI-II score NS group and the
low BDI-II score NS group are shown in Table 3. To compare sleep parameters
between the two depressive symptomatology groups in the NS condition we
conducted independent-samples t-tests on total sleep time, sleep efficiency, and
duration and proportion of sleep stages N1, N2, SWS and REM. It was revealed that
there was no significant difference between the two depressive symptomatology
groups in any of these sleep parameters [all p ≥ .124]. These results suggest that
sleep structure on the night of testing was comparable between participants with
higher BDI-II scores and participants with low BDI-II scores. Correlational analyses
examining the relationship between sleep parameters and post-sleep recognition
performance are available in Supplement 3.
Table 3. Sleep parameter data, separately for each depressive symptomatology group
Low BDI-II score group Higher BDI-II score group P-value
N1 (min)
N1 (%)
5.75 (1.51)
1.41 (0.36)
5.92 (0.79)
1.51 (0.18)
.927
.826
N2 (min)
N2 (%)
208.61 (9.49)
51.13 (1.81)
184.25 (15.94)
47.16 (2.55)
.187
.207
SWS (min)
SWS (%)
91.79 (5.47)
22.54 (1.30)
87.42 (5.67)
22.70 (1.16)
.585
.927
REM (min)
REM (%)
103.68 (8.73)
24.93 (1.51)
110.75 (8.90)
28.64 (1.79)
.577
.124
TST (min) 413.64 (14.16) 388.33 (22.53) .337
Efficiency (%) 94.53 (2.35) 91.78 (2.67) .445
Mean values are presented with SEM in parenthesis. Abbreviations: REM, Rapid Eye Movement sleep; N1 and N2, stages of non-REM sleep; SWS, Slow-Wave Sleep; TST, Total Sleep Time; BDI-II, Beck Depression Inventory.
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3.4. Subjective Ratings of Valence and Arousal
Subjective valence and arousal ratings obtained from participants during the
learning phase of this study are shown in Table 4. The subjective valence and
arousal ratings provided by six participants - four from the low BDI-II score SD group,
one from the higher BDI-II score NS group, and one from the low BDI-II score NS
group - were not recorded due to a technical fault. The valence and arousal ratings
obtained from the remaining participants during the learning phase were analysed
using two (depressive symptomatology group: higher BDI-II score group, low BDI-II
score group) x two (sleep condition group: SD group, NS group) x three (image
valence: positive, neutral, negative) mixed-measures ANOVAs. Given that sleep
quality differed significantly between the two depressive symptomatology groups,
mean-centered PSQI score was included as a covariate in these analyses, and all
subsequent analyses where appropriate. A significant main effect of image valence
was revealed for both valence ratings [F(1.12, 48.24) = 634.33, p < .001, ηp² = 0.937,
Greenhouse-Geisser corrected] and arousal ratings [F(1.36, 58.42) = 88.28, p
< .001, ηp² = 0.672, Greenhouse-Geisser corrected]. The ANOVA revealed no other
significant main effects or interactions [all p ≥ .234], suggesting that between-
depressive symptomatology group and sleep condition group differences in
subjective emotional responses to images can reasonably be discounted as a source
of variability in recognition performance.
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Table 4. Subjective ratings of valence and arousal obtained from learning phases, separately for each depressive symptomatology group, sleep condition group, and image valence
Low BDI-II score group Higher BDI-II score group
NS group SD group NS group SD group
Positive images
Valence 6.82 (0.16) 6.48 (0.26) 6.79 (0.20) 6.81 (0.17)
Arousal 4.33 (0.39) 4.42 (0.46) 4.36 (0.51) 4.51 (0.34)
Neutral images
Valence 5.03 (0.06) 5.04 (0.08) 5.03 (0.06) 4.97 (0.09)
Arousal 2.41 (0.36) 2.66 (0.44) 2.48 (0.45) 2.86 (0.35)
Negative images
Valence 2.27 (0.12) 2.61 (0.15) 2.44 (0.18) 2.57 (0.20)
Arousal 5.64 (0.35) 5.34 (0.65) 5.53 (0.55) 5.63 (0.30)
Mean values are presented with SEM in parenthesis. Abbreviations: BDI-II, Beck Depression Inventory; NS, Normal Sleep; SD, Sleep Deprivation.
Paired-samples t-tests comparing valence and arousal ratings between image
valence categories revealed that negative images were rated as significantly more
negative and greater in emotional arousal than both neutral images (valence [t(47) =
27.47, p <.001]; arousal [t(47) = 11.64, p < .001]) and positive images (valence [t
(47) = 26.31, p <.001]; arousal [t(47) = 4.86, p < .001]). Positive images were also
rated as significantly more positive and greater in emotional arousal than neutral
images (valence [t(47) = 20.36, p < .001]; arousal [t(47) = 14.72, p < .001]). These
results suggest that the stimuli evoked the expected emotional response from
participants.
Conflicting findings exist regarding the effects of sleep, and sleep deprivation,
on changes in subjective emotional reactivity (for review see: Tempesta, Socci, De
21
Gennaro, & Ferrara, 2017). Accordingly, we sought to investigate whether the sleep
condition groups and depressive symptomatology groups in this study differed with
regard to their change in valence and arousal ratings between the encoding session
and each of the recognition tests. These analyses are reported in Supplement 4.
Briefly, changes in emotionality ratings between the encoding and recognition tests
were not influenced by depressive symptomatology group, sleep condition or image
valence, and there were no interactions between these factors.
3.5. Immediate Recognition Performance
As described in Section 2.6.1, the results presented in this section focus
exclusively on recollection responses. Immediate recognition performance data is
available in Table 5. For unstandardized hit-rates and false alarm- rates at
immediate recognition see Supplement 5.
Table 5. Immediate recognition performance (d’), separately for each depressive symptomatology group, sleep condition group, and image valence
Low BDI-II score group Higher BDI-II score group
NS group SD group NS group SD group
Positive images 3.63 (0.23) 3.49 (0.27) 3.89 (0.23) 3.42 (0.22)
Neutral images 3.84 (0.19) 3.67 (0.29) 3.97 (0.16) 4.22 (0.22)
Negative images 4.07 (0.14) 3.69 (0.27) 3.88 (0.26) 3.68 (0.20)
Mean values are presented with SEM in parenthesis. Abbreviations: BDI-II, Beck Depression Inventory; NS, Normal Sleep; SD, Sleep Deprivation.
To test for any effects of depressive symptomatology group, sleep condition
group, or image valence on immediate recognition performance we conducted a two
22
(depressive symptomatology group: higher BDI-II score group, low BDI-II score
group) x two (sleep condition group: SD group, NS group) x three (image valence:
positive, neutral, negative) mixed-measures ANOVA on immediate recognition
scores (d’). The analysis showed a significant main effect of image valence [F(2, 98)
= 3.46, p = .035, ηp² = 0.066], which was driven by significantly greater recognition
performance for neutral images (3.92 ± 0.11) relative to positive images (3.60 ± 0.12)
[t(53) = 2.94, p = .005]. No other significant main effects or interactions were
revealed [p ≥ .290].
3.6. Behavioural Consolidation
As described in Section 2.6.1, to measure the consolidation processes which
occurred across the 12 h sleep or wake interval we created a measure which we
refer to as behavioural consolidation. Behavioural consolidation is calculated as the
difference between d’ scores at immediate and 12 h recognition tests [d’ 12 h
recognition – d’ immediate recognition], or immediate and 7 d recognition tests [d’ 7
d recognition – d’ immediate recognition]. Memory performance data for the 12 h and
7 d recognition tests is available in Supplement 6.
To investigate the effect of depressive symptomatology group, sleep condition
group, and image valence on memory consolidation we performed a two (depressive
symptomatology group: higher BDI-II score, low BDI-II score) x two (sleep condition
group: SD group, NS group) x three (image valence: positive, neutral, negative)
mixed-measures ANOVA on behavioural consolidation scores. This was done
separately for behavioural consolidation at 12 h and 7 d. Mean-centered PSQI score
was included as a covariate in these analyses. In accordance with the hypothesis,
23
we found a significant three-way interaction between depressive symptomatology
group, sleep condition, and image valence on 12 h behavioural consolidation scores
[F(2, 98) = 3.12, p = .049, ηp² = 0.060]. This interaction was also marginally
significant for 7 d behavioural consolidation [F(2, 98) = 2.79, p = .066, ηp² = 0.054]. A
significant main effect of sleep condition group on 12 h behavioural consolidation
[F(1, 49) = 6.10, p = .017, ηp² = 0.111] was also revealed, where participants in the
NS group exhibited greater overall behavioural consolidation than participants in the
SD group (NS group [-0.63 ± 0.10], SD group [-0.93 ± 0.14]). No other main effects
or interactions were revealed [all p ≥ .135]. Behavioural consolidation data are
shown in Fig 3.
To explore the significant depressive symptomatology group x sleep condition
group x image valence interaction, we performed two (sleep condition group: SD
group, NS group) x three (image valence: positive, neutral, negative) mixed-
measures ANOVAs on 12 h behavioural consolidation, separately for each
depressive symptomatology group. The ANOVAs revealed a significant main effect
of image valence in the higher BDI-II score group [F(2, 48) = 3.51, p = .038, ηp² =
0.128], which was driven by significantly greater consolidation of negative images (-
0.64 ± 0.18) relative to neutral images (-1.23 ± 0.15) [t(25) = 2.86, p = .008]. A
significant main effect of sleep condition group on 12 h behavioural consolidation
was also revealed in the higher BDI-II score group [F(1, 24) = 4.49, p = .045, ηp² =
0.158], where overall behavioural consolidation (i.e. regardless of image valence)
was greater in the NS group (-0.80 ± 0.15) than the SD group (-1.20 ± 0.22). No
other significant main effects or interactions were revealed [all p ≥ .114].
To test our hypothesis that SD would impair the consolidation of negative
memories in participants reporting mild-to-severe depressive symptoms, we
24
performed a priori independent-samples t-tests comparing behavioural consolidation
scores at 12 h between sleep condition groups for participants in the higher BDI-II
score group, separately for each image valence. In further support of our hypothesis,
it was revealed that the higher BDI-II score NS group exhibited significantly greater
behavioural consolidation of negative images at 12 h, relative to the higher BDI-II
score SD group [t(24) = 2.35, p = .028]. The t-tests also showed significantly greater
behavioural consolidation of neutral images at 12 h in the higher BDI-II score NS
group, relative to the higher BDI-II score SD group [t(24) = 2.79, p = .010]. Notably,
neither of these effects were observed in the low BDI-II score group [both p ≥ .447].
However, an additional a priori t-test showed that the low BDI-II score NS group
consolidated significantly more positive memories than the low BDI-II score SD
group [t(26) = 2.14, p = .042]. The consolidation of positive images was not
influenced by sleep condition for participants in the higher BDI-II score group [t(24) =
0.13, p = .895]. These findings suggest that SD may impair the consolidation of
negative and neutral memories for participants reporting mild-to-severe depressive
symptoms.
25
Fig 3. Mean behavioural consolidation [d’ 12 h or 7 d recognition – d’ immediate recognition] for recollection (R) responses separately for each depressive symptomatology group, sleep condition group, image valence, and recognition test. Error bars represent SEM. *, p < .05. Abbreviations: BDI-II, Beck Depression Inventory; NS, Normal Sleep; SD, Sleep Deprivation.
To examine differences in sleep- and sleep deprivation- related consolidation
between the two depressive symptomatology groups we conducted a two
(depressive symptomatology group: higher BDI-II score group, low BDI-II score
group) x three (image valence: positive, neutral, negative) mixed-measures ANOVA
on 12 h behavioural consolidation, separately for each sleep condition group. Mean-
centered PSQI score was included as a covariate in these analyses. The analysis
revealed a marginally significant depressive symptomatology group x image valence
interaction in the NS condition [F(2, 46) = 2.55, p = .089, ηp² = 0.100], which was
driven by greater consolidation of positive images in the low BDI-II score NS group,
relative to the higher BDI-II score NS group [t(24) = 2.13, p = .043]. The ANOVA
revealed no other significant main effects or interactions [all p ≥ .153].
26
4. Discussion
We investigated the effect of sleep, and SD, on the consolidation of
emotionally positive, neutral and negative images in participants reporting either
mild-to-severe depressive symptoms or minimal/no depressive symptoms. We
hypothesized that SD would impair the consolidation of negative emotional
memories, particularly in the higher BDI-II score group. Offering some support to our
hypothesis, we found that a night of SD, relative to a night of sleep, significantly
impaired the consolidation of negative and neutral images after 12 h in participants
reporting mild-to-severe depressive symptoms. Importantly, these effects were not
observed in participants reporting minimal/no depressive symptoms.
Research has shown that in healthy participants overnight sleep supports the
consolidation of negative emotional memories, relative to an equal duration of
daytime wakefulness (Payne et al., 2008) or overnight SD (Tempesta et al., 2015).
However, to our knowledge, our results are the first to demonstrate that the
detrimental effect of SD on the consolidation of negative and neutral memories is
more robust in participants reporting mild-to-severe depressive symptoms than
participants reporting minimal/no depressive symptoms.
A multitude of recent studies in healthy participants have demonstrated the
active and selective role of REM sleep in the processing and consolidation of
negative emotional memories (Groch et al., 2015; Nishida et al., 2009; Payne et al.,
2012; Wagner et al., 2001; Wiesner et al., 2015). REM sleep is thought to support
the consolidation of emotionally salient memories through the reactivation of, and
coherence between, neural regions implicated in emotional memory processing
27
during wake, in particular the amygdala, entorhinal cortex and medial prefrontal
cortex (Hutchinson & Rathore, 2015; Maquet et al., 1996; Nir & Tononi, 2010). By
inhibiting this pattern of neural activation associated with REM sleep, SD may have
impaired the processing and consolidation of negative emotional images in this
study. Indeed, a recent study found that healthy students selectively deprived of
REM sleep exhibited significantly less overnight consolidation of negative emotional
images, relative to participants selectively deprived of SWS (Wiesner et al., 2015),
supporting the interpretation that REM sleep suppression, rather than SD per se,
impaired the consolidation of negative emotional images in this study. Importantly,
however, this interpretation alone does not explain why the detrimental effect of SD
on negative emotional memory consolidation in the higher BDI-II score group was
absent in the low BDI-II score group.
One possible explanation for this effect is that REM sleep facilitated emotional
memory consolidation more readily in the higher BDI-II score group than the low
BDI-II score group. Indeed, in a recent study we found that the consolidation of
emotional memories during REM sleep was greater in participants reporting mild-to-
moderate depressive symptoms than participants reporting minimal/no depressive
symptoms (Harrington et al., 2018). However, in this study, negative memory
consolidation did not differ significantly between the higher BDI-II score NS group
and the low BDI-II score NS group. In addition, no relationship was observed
between REM sleep duration and recognition performance for negative images in
either depressive symptomatology group (see Supplement 3). Further research
including larger sample sizes are required to understand why the detrimental effect
of SD on negative emotional memory consolidation, relative to a night of sleep, is
more robust in participants reporting greater depressive symptoms. Moreover,
28
additional experiments are required to investigate whether this effect is specifically
linked to REM sleep. Such studies will benefit from the inclusion of a selective REM
SD condition, and a sleep group that sleeps in the laboratory under constant
observation by a researcher. Both conditions should include a comprehensive
polysomnographic assessment. Moreover, the current study lacks a control group
wherein which the participants are tested individually to prevent interactions amongst
participants which could have influenced the results.
Besides our hypothesis-related finding that SD impaired the consolidation of
negative emotional images in our higher BDI-II score group, our data also showed
that SD, relative to a night of sleep, impaired the consolidation of neutral images in
our higher BDI-II score group after 12 h. Considering the plentiful evidence that SWS
is critically involved in the consolidation of hippocampus-based, emotionally neutral
declarative memories (Stickgold, 2005), this finding is not surprising. However, it is
unclear why this effect was found in our higher BDI-II score group, and not in our low
BDI-II score group, especially considering that sleep-related consolidation of
emotionally neutral memories has been shown to be impaired in MDD patients
(Dresler et al., 2011, 2010; Göder et al., 2007; Nishida et al., 2016). Intriguingly,
however, although overnight motor memory consolidation was impaired in MDD
patients relative to controls in the Nishida et al. (2016) study, it was reported that
greater SWS duration predicted greater consolidation in participants with MDD, but
not control participants (Nishida et al., 2016). These findings corroborate a recent
study of ours, which showed that SWS supported the consolidation of neutral images
more readily in individuals reporting mild-to-moderate depressive symptoms than
individuals reporting minimal/no depressive symptoms (Harrington et al., 2018).
These findings suggest that the consolidation of neutral memories may be more
29
dependent on SWS in depressive individuals, and explains why SD, relative to a
night of sleep, had a detrimental effect on the consolidation of neutral images in our
higher BDI-II score group but not our low BDI-II score group. However, it is important
to consider that the differences in neutral memory consolidation between the NS and
SD groups may not be related specifically to SWS. Similarly, REM sleep in particular
may not subserve differences in negative memory consolidation. Indeed, both effects
could be related to the same process.
Our results also showed that overnight sleep supported the consolidation of
positive memories more readily in the low BDI-II score NS group than the higher
BDI-II score NS group. The effect of sleep on the consolidation of positive images
has been scarcely investigated, (however, see: Cairney, Durrant, Power, & Lewis,
2015; Harrington et al., 2018; Sterpenich et al., 2007) so it is difficult to explain why
sleep consolidated positive memories more effectively for individuals reporting
minimal/no depressive symptoms. One plausible explanation for this effect relates to
the mechanisms underlying emotional memory encoding. It has been proposed that
the amygdala activity elicited by encoding an emotional memory may act as an
‘emotional tag’, leading to the prioritised consolidation of these memories during
subsequent sleep intervals (Bennion, Payne, & Kensinger, 2015). Neuroimaging
research reveals that healthy participants exhibit greater amygdala responses to
positive stimuli (masked happy human facial expressions) than MDD patients
(Stuhrmann et al., 2013; Suslow et al., 2010). In this study, the positive images may
have elicited greater amygdala activity in the low BDI-II score group than the higher
BDI-II score group, which led to greater consolidation of positive images during sleep
in the low BDI-II score group. Further research employing fMRI is required to confirm
this interpretation.
30
In sum, the behavioural consolidation data obtained from this study suggests
that for participants reporting mild-to-severe depressive symptoms, sleep
preferentially preserved memory for negative and neutral items. Conversely, memory
for positive items was preserved across a night of sleep, relative to a night of SD, for
participants reporting minimal/no symptoms of depression. Although SD did not
exclusively suppress the consolidation of negative images in the higher BDI-II score
group (i.e. the consolidation of neutral images was also impaired), the ability of SD to
prevent negative memory consolidation in these individuals may have implications
for our understanding of SD therapy in MDD.
4.1. Implications
Growing clinical evidence supports the efficacy of SD therapy as an
antidepressant intervention for MDD (for reviews see: Benedetti & Colombo, 2011;
Wu & Bunney, 1990). Remarkably, SD has been reported to produce a clinical
improvement in depressive symptoms within a single 24 h period for approximately
60 % of MDD patients (Berger, van Calker, & Riemann, 2003; Leibenluft & Wehr,
1992; Wirz-Justice & Van Den Hoofdakker, 1999; Wu & Bunney, 1990). However,
this effect is typically transient, with approximately 80 % of SD responders
experiencing a return of depressive symptoms following subsequent recovery sleep
or daytime naps (Riemann, Wiegand, Lauer, & Berger, 1993).
Several researchers have attempted to explain the neurobiological basis of
this phenomenon (e.g. Brunner, Dijk, & Borbély, 1993; Wolf et al., 2015; Wu &
Bunney, 1990), however, no consensus has been reached on the mechanisms
underlying the therapeutic effect of SD in MDD. Nonetheless, in accordance with the
31
predictions of our Affect Tagging and Consolidation (ATaC) model (Harrington,
Pennington, & Durrant, 2017), we propose that SD may improve depressive
symptoms by suppressing the processing and consolidation of negative emotional
memories which typically occurs during REM sleep (Groch et al., 2015; Nishida et
al., 2009; Payne et al., 2012; Wagner et al., 2001; Wiesner et al., 2015). Our finding
that SD significantly impairs the consolidation of negative emotional images in
participants reporting mild-to-severe depressive symptoms may provide some
support for this notion. However, given that we utilized the BDI-II as our measure of
depressive symptom severity, which assesses depressive symptoms over the
preceding two weeks, it is impossible to determine whether the suppression of
negative emotional memory consolidation was associated with improvements in
depressive symptoms in this study. It is of course plausible that the impaired
emotional memory consolidation elicited by SD in the higher BDI-II score group
represents an effect which is independent of the therapeutic response to SD
observed in MDD patients. Future research is required to examine whether
impairments in negative emotional memory consolidation associated with SD,
relative to a night of sleep, correlate with improvements in depressive symptoms.
Such studies will require the use of clinically depressed MDD patients (confirmed
using structured clinical interview for DSM-5; SCID-5) and measures of current
depression severity that are sensitive to changes across a single SD interval such as
self-ratings and external ratings from psychiatrists who are blind to the experimental
conditions (e.g. Elsenga & van den Hoofdakker, 1982).
In addition to elucidating the mechanisms underlying SD therapy in MDD,
such research may also improve our understanding of the mechanisms of action of
several antidepressant medications. It is well reported that most antidepressant
32
drugs considerably inhibit REM sleep, thus increasing REM sleep latency or
decreasing REM sleep density and duration (Mayers & Baldwin, 2005; Murck et al.,
2003; Palagini et al., 2013; Steiger & Kimura, 2010; Thase, 2006; Vogel, Buffenstein,
Minter, & Hennessey, 1990). This finding lead researchers to propose that REM
sleep suppression may be an essential component of any effective form of MDD
therapy (Vogel, McAbee, Barker, & Thurmond, 1977). However, this notion is
contested by studies which report that a few pharmaceuticals effective in the
treatment of MDD such as the tricyclic antidepressant trimipramine, the
norepinephrine-dopamine reuptake inhibitor bupropion, and the serotonin reuptake
enhancer tianeptine, do not inhibit REM sleep (Murck et al., 2003; Nofzinger et al.,
1995; Sonntag et al., 1996). Although it is clear that REM sleep suppression is not
an exclusive mechanism by which antidepressants improve depressive symptoms,
the effect of pharmaceuticals which inhibit REM sleep on the overnight consolidation
of negative emotional memories is certainly one possible mechanism.
4.2. Limitations
Our analyses of SSS scores revealed that during the 12 h recognition test,
participants in the SD group reported greater subjective sleepiness than participants
in the NS group. Whilst this finding was expected, it could be argued that the
emotion-specific effects of SD on memory consolidation were due to reduced
alertness, rather than reduced sleep-dependent memory consolidation. However,
there is no inherent reason for tiredness in SD to impair negative and neutral but not
positive memory, so we do not believe this is the most parsimonious explanation of
our results. Indeed, 12 h SSS scores did not correlate with 12 h behavioural
33
consolidation of positive, neutral or negative images for participants who completed
the SD condition.
Similarly, it is plausible that the data from our 12 h recognition test may have
been influenced by the effect of circadian rhythms on cognitive performance and
memory formation (Gerstner & Yin, 2010; Schmidt, Collette, Cajochen, & Peigneux,
2007). Although we carried out the 7 d recognition test at the same time of day as
the immediate recognition test, it would have been impossible to match for time of
day between the immediate recognition test and the 12 h recognition test without
depriving our participants of a further 12 h of sleep. Nonetheless, as both groups
were tested at the same time of day throughout the study, circadian effects cannot
easily explain the differences we see between groups.
Our t-tests revealed significant differences in behavioural consolidation for
negative and neutral images between the SD and NS higher BDI-II score groups.
However, it is important to note that no significant interaction was found in the
preceding sleep condition x image valence ANOVA. Accordingly, the finding that SD
impairs the consolidation of negative and neutral memories in participants reporting
depressive symptoms should be regarded as preliminary, as opposed to solid
empirical evidence. Further studies utilizing larger sample sizes are required to
ascertain the impact of SD on emotional memory consolidation in depressive
participants.
Finally, between-group comparisons of our two depressive symptomatology
groups revealed that sleep quality in the month preceding the first session was
significantly lower in the higher BDI-II score group, relative to the low BDI-II score
group. This result is unsurprising, considering that sleep disturbances are reported
34
by up to 90 % of MDD patients (Baglioni et al., 2011; Palagini et al., 2013).
Importantly, sleep quality has been shown to influence emotional memory
processing (Tempesta, De Gennaro, Natale, & Ferrara, 2015). Nevertheless, we see
differences between our two higher BDI-II score groups which cannot be due to
these differences in sleep quality. Moreover, we included PSQI score as a covariate
in our analyses where appropriate, ensuring that our findings were not confounded
by between-group differences in sleep quality.
4.3. Conclusion
Our study has shown that a night of SD, relative to a night of sleep,
significantly impairs the consolidation of negative and neutral images after 12 h in
participants reporting mild-to-severe depressive symptoms. Notably, these effects
were not found in participants reporting minimal/no depressive symptoms. Our
findings may support the notion that the antidepressant response to SD in MDD is
related to the suppression of REM sleep- related negative emotional memory
processing and consolidation (Harrington et al., 2017). Further research including
larger sample sizes, MDD patients, and a more clinically robust measure of
depressive symptom severity should examine whether the suppression of negative
emotional memory consolidation associated with a night of SD, relative to a night of
sleep, correlates with improvements in depressive symptoms.
Acknowledgements
35
This research did not receive any specific grant from funding agencies in the public,
commercial, or not-for-profit sectors.
36
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