BACKGROUND: Abrupt cessation of therapy with a selective serotonin reuptake inhibitor (SSRI) is associated with a discontinuation syndrome, typified by numerous disabling symptoms, including anxiety. Surprisingly, little is known of the behavioural effect of SSRI discontinuation in animals. AIM: Here, the effect of SSRI discontinuation on anxiety-like behaviour was systematically investigated in mice. METHODS: Experiments were based on a three-arm experimental design comprising saline, continued SSRI and discontinued SSRI. Mice were assessed 2 days after SSRI discontinuation over a 5-day period using the elevated plus maze (EPM) and other anxiety tests. RESULTS: An exploratory experiment found cessation of paroxetine (12 days) was associated with decreased open-arm exploration and reduced total distance travelled, in male but not female mice. Follow-up studies confirmed a discontinuation effect on the EPM in male mice after paroxetine (12 days) and also citalopram (12 days). Mice receiving continued paroxetine (but not citalopram) also showed decreased open-arm exploration but this was dissociable from the effects of discontinuation. The discontinuation response to paroxetine did not strengthen after 28 days of treatment but was absent after 7 days of treatment. A discontinuation response was not discernible in other anxiety and fear-learning tests applied 3-5 days after treatment cessation. Finally, discontinuation effects on the EPM were typically associated with decreased locomotion on the test. However, separate locomotor testing implicated anxiety-provoked behavioural inhibition rather than a general reduction in motor activity. CONCLUSION: Overall, this study provides evidence for a short-lasting behavioural discontinuation response to cessation of SSRI treatment in mice.
BACKGROUND: Abrupt cessation of therapy with a selective serotonin reuptake inhibitor (SSRI) is associated with a discontinuation syndrome, typified by numerous disabling symptoms, including anxiety. Surprisingly, little is known of the behavioural effect of SSRI discontinuation in animals. AIM: Here, the effect of SSRI discontinuation on anxiety-like behaviour was systematically investigated in mice. METHODS: Experiments were based on a three-arm experimental design comprising saline, continued SSRI and discontinued SSRI. Mice were assessed 2 days after SSRI discontinuation over a 5-day period using the elevated plus maze (EPM) and other anxiety tests. RESULTS: An exploratory experiment found cessation of paroxetine (12 days) was associated with decreased open-arm exploration and reduced total distance travelled, in male but not female mice. Follow-up studies confirmed a discontinuation effect on the EPM in male mice after paroxetine (12 days) and also citalopram (12 days). Mice receiving continued paroxetine (but not citalopram) also showed decreased open-arm exploration but this was dissociable from the effects of discontinuation. The discontinuation response to paroxetine did not strengthen after 28 days of treatment but was absent after 7 days of treatment. A discontinuation response was not discernible in other anxiety and fear-learning tests applied 3-5 days after treatment cessation. Finally, discontinuation effects on the EPM were typically associated with decreased locomotion on the test. However, separate locomotor testing implicated anxiety-provoked behavioural inhibition rather than a general reduction in motor activity. CONCLUSION: Overall, this study provides evidence for a short-lasting behavioural discontinuation response to cessation of SSRI treatment in mice.
Selective serotonin (5-hydroxytryptamine; 5-HT) reuptake inhibitors (SSRIs) are
currently the first-line pharmacological treatment for major depression and
anxiety disorders. Despite their generally improved tolerability and side
effect profile compared to older antidepressants (Cipriani et al., 2018), the
abrupt cessation of SSRI treatment, as with other antidepressants, is often
associated with a disabling discontinuation syndrome (Haddad, 1997). Typical SSRI
discontinuation symptoms include heightened anxiety, insomnia, nausea,
dizziness, irritability and increases in suicidal thoughts (Delgado, 2006;
Horowitz and
Taylor, 2019; Warner et al., 2006). SSRI
discontinuation is considered distinct from depression relapse in that
symptoms appear within days of discontinuation, whereas relapse typically
takes several weeks to manifest. Moreover, discontinuation symptoms are
often different to those evident during the depressive episode and include
the emergence of somatic symptoms (Delgado, 2006). Problematic
effects of SSRI discontinuation are reported by depressed patients and other
patient groups including those with seasonal affective disorder, social
anxiety and panic disorder (Black et al., 1993; Lader et al.,
2004; Montgomery et al., 2005).SSRI discontinuation has recently risen to prominence following reports that
the syndrome may be more common, disabling and longer-lasting than
previously recognised (All-Party Parliamentary Group, 2018; Davies and Read, 2019). Despite
its clinical importance there are few systematic investigations of SSRI
discontinuation and its mechanism remains unknown. As an example of the
problem, we are aware of just two preclinical studies that directly address
the behavioural effects of SSRI discontinuation. One study reported an
enhanced acoustic startle response in rats 2 days after discontinuation from
repeated treatment with citalopram (Bosker et al., 2010). Another
study reported increased locomotor behaviour 4 h after the first ‘missed
dose’ of repeated fluoxetine in rats, and this effect dissipated within
4 days (Bjork et al.,
1998). In addition, although not reported as an investigation
of SSRI discontinuation itself, a small number of studies report no change
in anxiety or locomotor behaviour in rats 1–3 weeks after the last dose of
repeated SSRI administration (Bouet et al., 2012; Elizalde et al.,
2008; Popa
et al., 2010; Strekalova et al., 2013). Taken
together, these limited preclinical findings suggest short-lasting
behavioural changes associated with SSRI discontinuation in rodents, but
this requires systematic investigation.It is noteworthy that previous preclinical studies have identified behavioural
correlates of withdrawal from a wide variety of drugs, including opiates,
alcohol and psychostimulants (El Hage et al., 2012; Emmett-Oglesby et al.,
1990; Perez and De Biasi, 2015; Vuong et al., 2010). Much of
this work has centred on behavioural readouts of anxiety, a core feature of
many drug withdrawal states (note that the term ‘withdrawal’ as opposed to
‘discontinuation’ is commonly used for drugs associated with compulsive
drug-seeking behaviour, which is not the case for SSRIs or other
antidepressants). Such work led to novel insights into drug withdrawal
mechanisms and aided the identification of treatment strategies, as
exemplified by the use of clonidine to manage anxiety and other symptoms of
opiate withdrawal (Gowing et al., 2002; Kosten and Baxter, 2019).The present study systematically investigated the effect of SSRI
discontinuation on the behaviour of mice, with a focus on anxiety which is a
core symptom of SSRI discontinuation in patients. Also, both anxiety and
fear are well known to be modulated by pharmacological and genetic
manipulations of the 5-HT transporter (Barkus et al., 2014; Handley and McBlane,
1993; Lima
et al., 2019; Line et al., 2011). Paroxetine
was selected for detailed study since discontinuation from this SSRI is
considered particularly problematic in patients (Fava et al., 2015), likely due
in part to its short half-life (Price et al., 1996). Paroxetine
treatment duration and frequency were varied to optimise conditions to
detect discontinuation effects. Citalopram was also added for comparison due
to its greater selectivity for the 5-HT transporter than paroxetine and its
short half-life in rodents (Fredricson Overø, 1982).
Anxiety-like behaviours were measured using a battery of tests, including
the elevated plus maze (EPM), which has proven sensitive in detecting the
withdrawal states of other drugs (El Hage et al., 2012; Emmett-Oglesby et al.,
1990; Perez and De Biasi, 2015; Vuong et al., 2010) and is
highly sensitive to manipulations of the 5-HT system (Briley et al., 1990; Handley and McBlane,
1993; Ohmura et al., 2020).
Materials and Methods
Animals
Adult mice (C57BL/6J, 8–10 weeks, Charles River) were housed (21°C on a
12-h light/dark cycle; lights off 19:00–7:00) with littermates in
open-top cages (3–6 mice per cage) lined with sawdust bedding for at
least 1 week before the start of treatment. Food and water were
available ad libitum. Cardboard sizzle nests were used for cage
enrichment, and mice were handled using a cardboard tunnel to minimise
stress associated with repeated injections (Gouveia and Hurst, 2019).
Experiments followed the principles of the Animal Research: Reporting
of In Vivo Experiments (ARRIVE) guidelines and were conducted
according to the UK Animals (Scientific Procedures) Act of 1986 with
appropriate personal and project licence coverage.
Drugs and reagents
Paroxetine hydrochloride (Abcam, ab120069; Apexbio, B2252-APE) and
citalopram hydrobromide (Abcam, ab120133) were dissolved in saline (1
and 2 mg/mL, respectively). Drug dose (10 mg/kg s.c.) was chosen on
the basis of both the half-life of paroxetine (6.3 h) and citalopram
(1.5 h) in rodents (Fredricson Overø, 1982;
Kreilgaard
et al., 2008), and previous studies reporting
antidepressant actions of repeated administration of these drugs in
mice (Elizalde et
al., 2008). Treatment frequency (once or twice daily) and
duration (7–28 days) were varied in an attempt to optimise the
detection of discontinuation effects.
Experimental design
Mice were allocated to one of the three experimental groups by stratified
randomisation: (1) saline group: saline + saline continuation; (2)
continuation group: SSRI + SSRI continuation and (3) discontinuation
group: SSRI + saline continuation. Mice were weighed daily beginning
2 days before the start of the experiment to establish a baseline
weight and habituate mice to handling. Mice received once- or
twice-daily injections of paroxetine, or the equivalent volume of
saline, for 7, 12 or 28 days, then treatment was either continued
(saline and continuation groups) or swapped to saline injections
(discontinuation group) for a further 5 days during which behavioural
tests were conducted. The effect of twice-daily injections of
citalopram or saline for 12 days was also tested using a similar
experimental design. Testing commenced either 18 h (once daily) or 6 h
(twice daily) after the last injection. The 5-day discontinuation
period was based on previous rodent experiments reporting
discontinuation effects (Bosker et al., 2010; Trouvin et al.,
1993) and aimed to capture the timeframe when paroxetine
and citalopram fall to undetectable levels in the blood plasma (Benmansour et al.,
1999; Cremers et al., 2000). An
initial exploratory investigation of paroxetine used mixed sex groups
(six males, six females per group) and revealed sexually dimorphic
effects. Consequently, all follow-up experiments utilised male mice.
Details of this and all other experiments are summarised in Table
1.
EPM, elevated plus maze; NIH, novelty-induced
hyponeophagia; NSF, novelty-suppressed feeding; LMA,
locomotor activity; AOF, aversive open field; LDB,
light/dark box; FC, fear conditioning. Time since
last injection of SSRI for Continuation (CON) and
Discontinuation (DIS) groups; DIS groups receive
saline injections on discontinuation days.
Exploratory experiment, †data were pooled
with the exploratory experiment, ††data
excluded from the study (see Methods for
details).
Experimental design.EPM, elevated plus maze; NIH, novelty-induced
hyponeophagia; NSF, novelty-suppressed feeding; LMA,
locomotor activity; AOF, aversive open field; LDB,
light/dark box; FC, fear conditioning. Time since
last injection of SSRI for Continuation (CON) and
Discontinuation (DIS) groups; DIS groups receive
saline injections on discontinuation days.Exploratory experiment, †data were pooled
with the exploratory experiment, ††data
excluded from the study (see Methods for
details).
Behavioural tests
Mice were habituated to a holding room (i.e. not their home cage room)
for at least 1 h before testing and on the 3 days preceding
behavioural testing. All testing was conducted in the light phase
(10:00–17:00 h) by an observer blind to treatment. Other than the
changes in anxiety-related measures reported herein, no overt
behavioural or somatic effects to continued/discontinued SSRI
treatment were observed. Both a novelty-induced hyponeophagia test
(Line et
al., 2011) and novelty-supressed feeding test (Santarelli et
al., 2003) were conducted on Day 3 following
discontinuation from 12- and 28-day once-daily paroxetine treatment,
but results were confounded by an effect of test order, and hence data
were excluded from the study.
EPM
The EPM model assesses approach-avoidance behaviour, relying on the
conflict between the innate aversion of open, elevated spaces
and the exploratory drive in mice (Komada et al., 2008;
Pellow et al., 1985). EPM experiments were carried
out as previously described for studies examining the role of
altered 5-HT transporter expression on unconditioned anxiety
(Line
et al., 2011). The EPM (50 cm off the floor) was
placed in a dimly lit room and comprised two open arms
(35 × 6 cm2) perpendicular to two closed arms
(35 × 6 cm2, 20 cm walls), with a central
region (6 × 6 cm2). Mice were initially placed facing
the walls at the far end of the closed arm, and movement was
automatically tracked for 300 s (ANY-maze software, Stoelting
Co.). Key parameters were the time spent in the open arms,
open-arm entries and latency to enter open arms, with distance
travelled being used as the principal readout of locomotor
activity (LMA; closed-arm entry was also recorded).
LMA
Given the potential confound of changes in locomotion on anxiety
measures, previous studies highlight the value of assessing
locomotion in separate low-anxiety environments (Lister,
1990). Here, spontaneous LMA was assessed in a
dimly lit room as previously described (Line et al., 2011).
Mice were placed individually into an unfamiliar plastic cage
(42 × 22 × 20 cm) lined with sawdust and covered with a
perforated plexiglass lid. LMA was monitored by horizontal and
vertical infrared beams, and the number of beam breaks was
automatically recorded in 5 min bins for 60 min (Photobeam Frame
software, San Diego Instruments).
AOF
The aversive open-field test (AOF) assesses exploration and
behaviour in an anxiogenic environment (Prut and Belzung,
2003). Mice were placed in a brightly lit, white
cylindrical chamber (30 cm radius) and movement was
automatically tracked for 600 s (ANY-maze software). The centre
zone was designated as a central circle of 10 cm radius. Key
parameters were the time spent in the centre zone and distance
travelled.
LDB
The light/dark box (LDB) assesses approach-avoidance conflict in
rodents based on their innate fear of brightly lit places (Bourin and
Hascoët, 2003). The LDB arena (Pritchett
et al., 2015) was inside a sound-attenuating
cubicle and consisted of a dark, enclosed compartment (21 cm
long × 16 cm high × 16 cm wide) separated by a small doorway
from a brightly lit, open compartment (46.5 cm long × 21 cm
high × 21 cm wide). Mice were placed in a corner of the dark
compartment and their movement was automatically tracked for
600 s by horizontal infrared beams (activity monitor software,
Med Associates Inc). Key parameters were the time spent in light
zone and distance travelled.
Fear conditioning
Assessment of fear learning was performed as described previously
(Line
et al., 2014) using conditioning chambers (Med
Associates, Med Associates Inc., USA) with a floor of metal bars
connected to a scrambled-shock generator (controlled by Med-PC
IV software programme). In brief, mice were placed individually
in a covered plastic box for 30 min before each session. Two
different conditioning contexts were used, each associated with
a specific scent and distinctive wall layout (black- and
white-striped walls, lavender essential oil vs grey walls and
sandalwood essential oil). Mice were trained in one context and
tested in the other (context was counterbalanced across training
and test days). On the training day, after a 180-s
acclimatisation period, mice received two tone–shock pairings,
each consisting of a 30-s tone (72 dB, 2900 Hz) paired with a
shock (0.5 ms, 0.3 mA) delivered in the final 0.5 s of the tone
(180-s inter-trial interval). On the test day, 24 h later, mice
received the same tone presentations but did not receive the
shock. Freezing was determined from video recordings (analysed
by NIH ImageJ with a customised script) and defined as <0.07%
pixel change in two consecutive frames (one frame per second).
Pre-tone freezing was calculated as percentage of freezing in
the 30 s before the tone, and freezing to tone was calculated as
the percentage of freezing for 30 s of tone. The change in
freezing levels (∆Freezing) was then calculated (freezing to
tone–pre-tone freezing) and presented as average ∆Freezing per
day.
Statistical analysis
D’Agostino-Pearson test for normality was applied to all data sets. If
data were normally distributed, then one-way analysis of variance
(ANOVA) was used with Fisher’s Least Significant Difference (LSD) to
compare treatments. If data were not normally distributed,
Kruskal–Wallis with Fisher’s LSD was used. Sex was assessed as a
co-factor using two-way ANOVA, and Kruskal–Wallis used for small
sample sizes in within-sex comparisons (n ⩽ 6 per
group). For EPM data, the relationship between open-arm entry and
distance travelled was further analysed by analysis of covariance
(ANCOVA). Data were analysed mainly using GraphPad Prism (v8) and IBM
SPSS Statistics (v24) (two-way ANOVA). Data are presented as
mean ± standard error of the mean (SEM) values. A p
value less than 0.05 was considered statistically significant.
Results
Effect of discontinuation from 12 days of once-daily
paroxetine
An exploratory experiment (6 males, 6 females per group) tested the
effect of discontinuation from 12 days of once-daily paroxetine. On
day 2, behaviour was assessed on the EPM. Two-way ANOVA revealed a
main effect of group for the time spent in the open arms,
(F(2, 29) = 9.050, p = 0.0009,
although there was also a significant sex effect,
F(1, 29) = 16.85, p = 0.0003, and a
treatment × sex interaction, F(2, 29) = 6.357,
p = 0.0051. Further analysis was conducted on
male and female data, separately. For male mice there were significant
main effects of group for time in the open arms,
H(2) = 9.789, p = 0.0027 (Supplemental Fig. 1A), open-arms entries,
H(2) = 11.55, p = 0.0005
(Supplemental Fig. 1B), latency for open-arm entry,
H(2) = 6.327, p = 0.0360
(Supplemental Fig. 1C) and distance travelled,
H(2) = 10.96, p = 0.0009
(Supplemental Fig. 1D). Post hoc tests showed that
both discontinued and continued mice spent less time in the open arms
(p = 0.0309 continuation vs saline,
p = 0.0030 discontinuation vs saline) and made
fewer open-arm entries compared to saline controls
(p = 0.0285 continuation vs saline,
p = 0.0009 discontinuation vs saline). Notably,
discontinued mice had an increased latency to enter the open arms
(p = 0.0157 vs saline) and travelled less
distance (p = 0.0001 vs saline). In contrast, female
mice that discontinued from paroxetine were not different from saline
controls on any EPM parameter (Supplemental Fig. 1A–D), although those receiving
continued paroxetine had decreased latency to open-arm entry
(treatment effect: H(2) = 7.879,
p = 0.0119; Supplemental Fig. 1C).On day 4, discontinued male and female mice showed no changes in
spontaneous locomotion in the LMA test (Supplemental Table 1) and no differences on the AOF
(Supplemental Table 1). On day 5, male discontinued
mice spent less time in the light zone of the LDB,
H(2) = 8.667, p = 0.0069 (Supplemental Fig. 1E), with decreased distance
travelled, H(2) = 10.15, p = 0.0021
(Supplemental Fig. 1F), but these effects were not
different from male mice on continued paroxetine (Supplemental Fig. 1E–F). In contrast, female mice
discontinued from paroxetine actually spent more time in the light
zone, H(2) = 6.538, p = 0.0304
(Supplemental Fig. 1E).Overall, results of this exploratory experiment suggest that paroxetine
discontinued mice showed evidence of a behavioural effect compared to
saline controls on the EPM and LDB, but this effect was not readily
distingishable from continuous treatment and was apparent in males and
not females.To increase the power of this exploratory study, EPM measurements were
repeated in a separate group of male mice
(n = 8/group additional mice) and the two male data
sets were combined (n = 14/group total). The pooled
data confirmed that continued and discontinued mice spent less time in
the open-arms compared to saline controls (F(2,
38) = 6.830, p = 0.0029; post hoc
p = 0.0101 saline vs continuation,
p = 0.0011 vs saline vs discontinuation; Figure 1A).
Importantly, on other EPM measures, discontinued mice were
significantly different to continued paroxetine and saline controls.
Thus, discontinued mice made fewer open-arms entries
(F(2, 38) = 13.94,
p < 0.0001; post hoc p = 0.0349
vs continuation, p < 0.0001 vs saline; Figure 1B)
and showed increased latency for open-arm entry (F(2,
38) = 7.790, p = 0.0015; post hoc
p = 0.0201 vs continuation,
p = 0.0004 vs saline; Figure 1C). Discontinued
mice also demonstrated reduced distance travelled
(F(2, 38) = 17.96, p < 0.0001;
post hoc p = 0.0006 vs continuation,
p < 0.0001 vs saline; Figure 1D) and reduced
closed-arm entries (F(2, 38) = 8.546,
p = 0.009; Supplemental Fig. 2). ANCOVA revealed that changes
in open-arm entry were not statistically significant when co-varied
with distance travelled (F(2, 37) = 1.358,
p = 0.270).
Figure 1.
Performance on the EPM of male mice discontinued from 12 days
of once-daily paroxetine: panels show (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(n = 14); CON, Continuation
(n = 13, one mouse excluded due to
loss of data); DIS, Discontinuation
(n = 14). Mean ± SEM values are shown
with individual values indicated by dots. One-way ANOVA
followed by post hoc Fisher’s LSD.
*p < 0.05,
**p < 0.01.
Performance on the EPM of male mice discontinued from 12 days
of once-daily paroxetine: panels show (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(n = 14); CON, Continuation
(n = 13, one mouse excluded due to
loss of data); DIS, Discontinuation
(n = 14). Mean ± SEM values are shown
with individual values indicated by dots. One-way ANOVA
followed by post hoc Fisher’s LSD.
*p < 0.05,
**p < 0.01.Notably, mice continued on paroxetine also showed decreased open-arm
entries (post hoc p = 0.0046 vs saline) and reduced
distance travelled (post hoc p = 0.0494 vs saline)
but to a lesser extent than discontinued mice (Figure 1).
Effect of discontinuation from 28 days of once-daily
paroxetine
To test whether increased duration of paroxetine treatment would produce
a stronger discontinuation response, male mice were treated once-daily
with paroxetine for 28 days. On day 2 on the EPM, discontinued mice
spent less time in the open-arms compared to continued paroxetine and
saline controls (F(2, 29) = 6.649,
p = 0.0042; post hoc p = 0.0495 vs
continuation, p = 0.0011 vs saline; Figure 2A).
Continued and discontinued mice had reduced open-arm entries
(F(2, 29) = 11.19, p = 0.0002;
post hoc p = 0.0016 continuation vs saline,
p < 0.0001 discontinuation vs saline; Figure 2B)
and increased latency for open-arm entry
(H(2) = 13.38, p = 0.0012; post hoc
p = 0.0011 continuation vs saline,
p = 0.0021 discontinuation vs saline; Figure 2C).
These mice also had reduced distance travelled (F(2,
29) = 15.73, p < 0.0001; post hoc
p = 0.0004 continuation vs saline,
p < 0.0001 discontinuation vs saline; Figure 2D)
and decreased closed-arm entries (F(2, 29) = 12.93,
p < 0.0001; Supplemental Fig. 2) compared to saline controls.
ANCOVA revealed that changes in open-arm entry were not statistically
significant when co-varied with distance travelled
(F(2, 28) = 1.113, p = 0.343).
Figure 2.
Performance on the EPM and LDB of male mice discontinued from
28 days of once-daily paroxetine: panels show (a) time
spent in open arms, (b) entries to open arms, (c) latency
to enter the open arms, (d) distance travelled on the EPM,
(e) time spent in the light zone and (f) distance
travelled on the LDB. SAL, Saline
(n = 10–11); CON, Continuation
(n = 11); DIS, Discontinuation
(n = 10–11). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d–e),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.
Performance on the EPM and LDB of male mice discontinued from
28 days of once-daily paroxetine: panels show (a) time
spent in open arms, (b) entries to open arms, (c) latency
to enter the open arms, (d) distance travelled on the EPM,
(e) time spent in the light zone and (f) distance
travelled on the LDB. SAL, Saline
(n = 10–11); CON, Continuation
(n = 11); DIS, Discontinuation
(n = 10–11). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d–e),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.On day 4, discontinued mice had reduced activity on the LMA test compared
to saline controls, as did mice on continuous treatment,
F(2, 32) = 3.872, p = 0.032
(Supplemental Table 2). There was no effect of any
treatment on the performance on AOF compared to saline controls
(Supplemental Table 2). On day 5, discontinued mice
spent less time in the light zone of the LDB (F(2,
29) = 7.468, p = 0.0024; post hoc
p = 0.0014 vs saline; Figure 2E) and had decreased
the distanced travelled (F(2, 29) = 9.782,
p = 0.0006; post hoc
p = 0.0006 vs saline; Figure 2F) compared to
saline controls, but these effects were not different from mice on
continued paroxetine (time in light zone: post hoc
p = 0.0045 continuation vs saline; distance
travelled: post hoc p = 0.0007 continuation vs
saline; Figure
2).Overall, these results add evidence that 28-day paroxetine generates a
discontinuation effect on the EPM although this was not obviously a
greater and longer lasting than 12-day paroxetine treatment.
Effect of discontinuation from 7 days of once-daily
paroxetine
To investigate the duration of treatment with paroxetine required to
produce discontinuation effects, male mice received once-daily
paroxetine injections for 7 days. On day 2 following treatment
cessation, discontinued mice did not perform differently on the EPM
compared to saline controls or mice on continuous paroxetine in terms
of the time spent in the open arms, F(2,
33) = 0.1256, p = 0.8824, Figure 3A, open-arm entries,
F(2, 33) = 0.6936, p = 0.5069;
Figure
3B, latency to open-arm entry,
H(2) = 1.610, p = 0.4471; Figure 3C,
distance travelled, F(2, 33) = 1.262,
p = 0.2964; Figure 3D, or closed-arm
entries, F(2, 33) = 1.734,
p = 0.1923 (Supplemental Fig. 2).
Figure 3.
Performance on the EPM of male mice discontinued from 7 days
of once-daily paroxetine: panels show (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(males, n = 12); CON, Continuation
(males, n = 12); DIS, Discontinuation
(males, n = 12). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
Performance on the EPM of male mice discontinued from 7 days
of once-daily paroxetine: panels show (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(males, n = 12); CON, Continuation
(males, n = 12); DIS, Discontinuation
(males, n = 12). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).These results show that paroxetine treatment for 7 days was not
sufficient to induce a discontinuation response on the EPM.
Effect of discontinuation from 12 days of twice-daily
paroxetine
To test whether increasing the frequency of paroxetine treatment (and
hence increasing daily dose) would produce a more pronounced
discontinuation effect on the EPM, mice were treated twice-daily with
paroxetine for 12 days. This experiment also tested the possibility
that mice continuously treated with paroxetine may have been
experiencing discontinuation effects, in that up to this point all
‘continuous’ treatment groups were tested 18 h after the last
injection. Here, mice were tested 6 h after the last injection so that
plasma levels of paroxetine in the ‘continuous’ mice likely remained
high. This experiment also examined the possibility that
discontinuation from paroxetine would affect fear learning, which is
reported to be sensitive to manipulations of the 5-HT transporter
(e.g. Lima et
al., 2019).On day 2 following treatment cessation, discontinued mice showed reduced
time on the open arms (F(2, 33) = 10.83,
p = 0.0002; post hoc
p < 0.0001 vs saline; Figure 4A) and reduced
open-arm entries (F(2, 33) = 3.482,
p = 0.0424; post hoc
p = 0.0141 vs saline; Figure 4B), albeit with
unchanged latency for open-arm entry (F(2,
33) = 2.174, p = 0.3373; Figure 4C). Discontinued
mice also demonstrated reduced distance travelled
(F(2, 33) = 7.469, p = 0.0021; post
hoc p = 0.0086 vs continuation,
p = 0.0008 vs saline; Figure 4D) and decreased
closed-arm entries (F(2, 33) = 8.466,
p = 0.0011; Supplemental Fig. 2). Again, ANCOVA revealed that
changes in open-arm entry were not statistically significant when
co-varied with distance travelled (F(2, 28) = 0.123,
p = 0.884).
Figure 4.
Performance on the EPM male mice discontinued from 12 days of
twice-daily paroxetine: panels represent (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(n = 12); CON, Continuation
(n = 12); DIS, Discontinuation
(n = 12). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.
Performance on the EPM male mice discontinued from 12 days of
twice-daily paroxetine: panels represent (a) time spent in
open arms, (b) entries to open arms, (c) latency to enter
the open arms and (d) distance travelled. SAL, Saline
(n = 12); CON, Continuation
(n = 12); DIS, Discontinuation
(n = 12). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.In comparison, mice receiving continued paroxetine also spent less time
in open arms (post hoc p = 0.0070 vs saline; Figure 4A)
even when tested 6 h after the last injection, suggesting these
changes are not in themselves discontinuation effects.Importantly, given the above evidence that discontinued mice had reduced
motor activity on the EPM, on day 3 mice were tested for locomotor
changes in a separate LMA test. Neither discontinued mice nor mice
receiving continued paroxetine were different from saline controls on
the LMA test, F(2, 33) = 0.073,
p = 0.929. There was also no effect of any treatment
on activity on the AOF (Supplemental Table 3).On days 4 and 5 following cessation of paroxetine treatment, mice were
assessed for fear conditioning (training on day 4, testing on day 5).
All mice exhibited increased freezing with the onset of the
conditioned stimulus. However, neither discontinued mice nor mice on
continued treatment were different from saline controls in terms of
freezing to tone on the training day or in their response to the
conditioned tone during recall on the test day (Supplemental Table 3).These results add further evidence that paroxetine-treated mice produce a
discontinuation response on the EPM, but that increased treatment
frequency (and thereby dose) did not lead to more clear-cut and
longer-lasting effects. Furthermore, separate LMA testing found no
evidence of a general reduction in motor activity in the discontinued
mice.
Effect of discontinuation from 12 days of twice-daily
citalopram
A final experiment determined the effects of discontinuation from 12 days
of twice-daily treatment with another SSRI, citalopram. On day 2
following treatment cessation, discontinued mice showed increased
latency to enter the open arms (H(2) = 7.220,
p = 0.0221; post hoc
p = 0.0078 vs saline; Figure 5C) and a trend
effect for reduced number of open-arm entries (F(2,
51) = 1.751, p = 0.1839; post hoc
p = 0.0862 vs continuation; Figure 5B) although the time
spent in the open arms was not different between groups
(F(2, 51) = 0.5349; 0.5890; Figure 5A).
Discontinuation from citalopram had no effect on the distance
travelled (F(2, 51) = 1.949,
p = 0.1529; Figure 5D) or closed-arm
entries (F(2, 27) = 1.323,
p = 0.2830; Supplemental Fig. 2). Unlike mice treated
continuously with paroxetine, mice on continuous citalopram (tested
6 h after the last injection) were not different from saline controls
on the EPM (Figure
5).
Figure 5.
Performance on the EPM of male mice discontinued from 12 days
of twice-daily citalopram: panels represent (a) time spent
in open arms, (b) entries to open arms, (c) latency to
enter the open arms and (d) distance travelled. SAL,
Saline (n = 18); CON, Continuation
(n = 18); DIS, Discontinuation
(n = 18). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.
Performance on the EPM of male mice discontinued from 12 days
of twice-daily citalopram: panels represent (a) time spent
in open arms, (b) entries to open arms, (c) latency to
enter the open arms and (d) distance travelled. SAL,
Saline (n = 18); CON, Continuation
(n = 18); DIS, Discontinuation
(n = 18). Mean ± SEM values are
shown with individual values indicated by dots. One-way
ANOVA followed by post hoc Fisher’s LSD (a–b, d),
Kruskal–Wallis followed by post hoc Fisher’s LSD (c).
*p < 0.05,
**p < 0.01.Mice discontinued from citalopram were also not different from either
saline controls or mice maintained on citalopram on the LMA and AOF
tests (day 3 of discontinuation), nor on any parameter measured during
the training (day 4) or recall (day 5) stages of the fear conditioning
paradigm (Supplemental Table 4).These results suggest that as with paroxetine, citalopram produced a
discontinuation response on the EPM albeit a modest one.
Discussion
Abrupt cessation of a course of treatment with an SSRI in humans is often
associated with a discontinuation syndrome comprising unpleasant centrally
and peripherally mediated changes, but the effects of SSRI discontinuation
in animals are little studied. This study determined the effect of SSRI
discontinuation in mice with a focus both on anxiety-like behaviour, which
is a common discontinuation symptom, and paroxetine which is particularly
problematic in patients. A main finding was that 2 days following
discontinuation from repeated administration of paroxetine mice showed
differences in behaviour on the EPM compared to mice maintained on drug and
saline controls. A modest discontinuation effect on the EPM was also
detected with citalopram. Attempts to optimise treatment protocols found
that paroxetine exposure for more than a week was required to elicit a
discontinuation effect, and this was not obviously strengthened with
increasing duration or dose of treatment. Data from other anxiety tests
showed evidence of persistent behavioural effects in mice up to 5 days after
paroxetine discontinuation; however, these effects were relative to saline
controls and not mice maintained on drug (specifically paroxetine). Finally,
the discontinuation effect of paroxetine was sexually dimorphic in that, at
least under the present conditions, the response was detected in male and
not female mice. Overall, the current data provide the first evidence for
the emergence of a discontinuation effect in male mice within 2 days of
cessation of SSRI treatment although the experiments were unable to resolve
the duration of this effect.The EPM is widely used to assess anxiety levels in rodents and has been
previously used to detect increased anxiety evoked by discontinuation of
other drugs, including psychostimulants and alcohol, and for detecting
changes in 5-HT function (see ‘Introduction’). The majority of these studies
prioritise two EPM indices of anxiety: open-arm entries and time spent on
the open arms, which are closely correlated parameters (Lister, 1990).
Here, one or other of these parameters were found to be decreased in
SSRI-discontinued mice compared to those maintained on treatment. Detection
of anxiety-like behaviours on the EPM can be confounded by non-specific
changes in motor activity (Handley and McBlane, 1993; Lister, 1990;
Weiss et al.,
1998). In this study, SSRI discontinuation was often associated
with reduced distance travelled on the EPM which may have impacted on
open-arm exploration. ANCOVA can be used to help determine the influence of
changes in distance travelled on open-arm exploration parameters, but here
these changes could not be separated by this statistical approach. However,
the impact of ANCOVA in this regard is limited as pointed out elsewhere
(Lister,
1990). Thus, in the context of an anxiogenic environment a
decrease in distance travelled would be consistent with an increase in
anxiety since behavioural inhibition is a key component of the anxiety
response (Gray,
1982; McNaughton and Gray, 2000). Thus, these EPM parameters are
very likely to co-vary.To further explore the possibility that reduced open-arm exploration was simply
due to decrease in general motor activity, we carried out separate locomotor
assessments in a low anxiety, home cage-like environment as previously
recommended (Lister,
1990). This separate assessment found little evidence that mice
undergoing SSRI discontinuation exhibited a reduction in general motor
activity (with the exception of the 28-day paroxetine, see below). Thus,
decreased locomotion on the EPM appeared to be context-specific and
plausibly arose from increased anxiety levels due to exposure to a novel,
anxiogenic environment rather than decreased LMA per se. Nevertheless,
without further investigation, we cannot exclude the possibility that the
elevated anxiety measures in discontinued mice is not genuine anxiety but
instead linked to other unpleasant experiences of discontinuation including
somatic changes that feature in the clinical syndrome, which in itself would
be of great interest. Indeed, discontinuation from 28-day paroxetine were
confounded by reduced locomotion in separate assessments suggesting the
emergence of a syndrome which may be driven by hypolocomotion.The evidence of altered EPM performance within 2 days of discontinuation from
paroxetine and citalopram is consistent with the short half-lives of these
drugs in rodents (6.3 h and 1.5 h, respectively) (Fredricson Overø, 1982; Kreilgaard et al.,
2008), and an abrupt fall in brain levels of the drug once drug
administration has stopped. Moreover, a rapid appearance of a
discontinuation effect on the EPM is consistent with earlier evidence of
heightened startle responsivity in rats 2 days after discontinuation from
repeated treatment with citalopram (Bosker et al., 2010). Our
finding also fits with the clinical picture that SSRIs such as paroxetine,
which have a short half-life in humans, are particularly problematic with
patients often experiencing discontinuation effects within 2 days of
treatment cessation (Fava et al., 2015; Michelson et al., 2000; Rosenbaum et al.,
1998). Although plasma levels of paroxetine and citalopram were
not measured in the present experiments, previous studies report that the
administration of paroxetine or citalopram to rodents at the doses used here
produces plasma drugs levels broadly in the therapeutic range and that falls
quickly once administration ceases. For example, rat plasma levels of
citalopram (121 ng/mL) were reported to fall around eightfold within 24 h of
stopping administration (24 mg/kg per day for 15 days) and were at the
limits of detection at 48 h (Bosker et al., 2010). Similarly,
rat plasma levels of paroxetine (411 ng/mL) fell by a similar degree 48 h
after cessation of paroxetine (10 mg/kg for 21 days) and were undetectable
after 96 h of washout (Benmansour et al., 1999).A clinical feature of SSRI discontinuation is that in some patients the effects
can endure for several weeks or even months (Davies and Read, 2019; Fava et al.,
2007). This study applied a battery of different anxiety tests
to determine whether effects of SSRI discontinuation persist since animals
show an adaptive response following repeated testing on the EPM test and
other anxiety tests (either due to habituation or behavioural changes from
anxiety to acquired fear) (File, 2001). This test battery
also determined the generality of our findings across assays with different
sensorimotor and motivational demands. However, results were somewhat
inconclusive. For example, mice discontinued from paroxetine (eg. once-daily
for 12 days) showed evidence of increased anxiety on the LDB on Day 5
compared to saline controls, but it was not statistically different from
mice receiving continuous paroxetine in this test. These data potentially
accord with a short-lasting anxiogenic effect of SSRI discontinuation in
mice that may dissipate after 48 h. However, a previous study found an
enhanced acoustic startle response in rats discontinued from citalopram
compared to those still receiving treatment that persisted for at least
7 days after the last dose (Bosker et al., 2010). The
current data do not preclude the persistence of discontinuation effects as
it is possible that the use of a battery of tests over consecutive days
obscured the detection of genuine discontinuation versus continuation
effects due to prior test exposure.Here, a discontinuation response to paroxetine was detected after 12 and
28 days but not after 7 days of continuous drug treatment, suggesting the
involvement of a neuroadaptive mechanism. This timing accords with findings
in clinical studies that taking an SSRI for a week is not sufficient to
produce discontinuation symptoms (Yonkers et al., 2015).
Furthermore, randomised control trials show that discontinuation symptoms
already emerge after a few weeks of SSRI treatment (Baldwin et al., 2006). The nature
of the neuroadaptive responses underpinning SSRI discontinuation is unknown.
Although much is established regarding how the 5-HT systems adapts during a
course of SSRI administration (Artigas, 2013; Sharp, 2013),
remarkably few studies have investigated how 5-HT transmission changes when
chronic SSRI administration is immediately stopped. Two earlier studies
reported decreased 5-HT synthesis and metabolism in post-mortem rat brain
tissue for up to 3 days following withdrawal from citalopram and fluoxetine
((Bosker et al.,
2010; Trouvin et al., 1993). On the contrary, SSRI discontinuation
likely leaves 5-HT neurons in a state of reduced 5-HT1A
autoreceptor sensitivity (desensitisation), which theoretically would push
the 5-HT system in the opposite direction and increase 5-HT neuron firing
and 5-HT release (Richardson-Jones et al., 2010). Indeed, Trouvin and colleagues (1993)
reported an overshoot in brain 5-HT metabolite levels 7–21 days following
discontinuation from fluoxetine. Although the delayed timing of this 5-HT
overshoot is out of keeping with the current findings, it is in line with
the other lines of research reporting that increased anxiety is associated
with increased 5-HT (Briley et al., 1990; Handley and McBlane, 1993; Ohmura et al.,
2020).Neuroadaptive changes in certain postsynaptic 5-HT receptors and the 5-HT
transporter itself are also reported following genetic knockout or
pharmacological inhibition of the 5-HT transporter (Benmansour et al., 1999; Jennings et al.,
2012) and might rebound during discontinuation. Thus, contrary
to earlier speculations of either a hyper- or hyposerotonergic state
underpinning the symptoms of SSRI discontinuation syndrome (Blier and Tremblay,
2006; Renoir, 2013), a potentially more complex and dynamic picture
emerges of decreased synaptic availability of 5-HT, elevated 5-HT cell
firing, altered postsynaptic 5-HT receptors and overall destabilised (and
dysfunctional) 5-HT signalling and related 5-HT-induced changes in neural
plasticity. Although as a drug class SSRIs are pharmacologically selective,
5-HT has multiple interactions with other transmitter systems, including the
co-release of glutamate from 5-HT neurons and the 5-HT regulation of
noradrenergic, dopaminergic and GABAergic circuits (Sharp and Barnes, 2020). Thus,
it is plausible that such transmitters also contribute to the effects of
SSRI discontinuation. The key role of noradrenaline in the effects of opiate
withdrawal (eg. Kosten
and Baxter, 2019) illustrates the potential link between
discontinuation effects and other neurotransmitter systems. Finally,
numerous studies have reported enhanced neuroplasticity and structural
changes following repeated SSRI treatment which are thought to be
responsible for their therapeutic effects (Castrén and Hen, 2013; Harmer et al.,
2017). For example, paroxetine induced an adaptive increase in
hippocampal neurogenesis following several weeks of treatment in mice (Elizalde et al.,
2010), which plausibly relates to the behavioural effects of
paroxetine discontinuation observed here. However, it is unlikely that such
changes reverse immediately following SSRI discontinuation. Nonethless, the
lack of information on the timing of changes in plasticity such as
neurogenesis during SSRI discontinuation, means that this possibility cannot
currently be excluded.Our initial exploratory study did not detect an effect of discontinuation from
paroxetine (once-daily, 12 days) in female mice. Further investigation of
this finding is required as there are many sexual dimorphisms reported in
mice, some of which offer a plausible explanation for the male–female
difference found here. For example, female mice metabolise fluoxetine more
effectively than males through increased activity of cytochrome
P450 enzymes (Hodes et al., 2010). Since
paroxetine is also metabolised by these enzymes, the paroxetine dosing
regimen used here may not have been sufficiently high for female mice. Also,
evidence of sexual dimorphism in the 5-HT system is reported for mice (Renoir et al.,
2011), in particular female mice were found to exhibit lower
5-HT transporter mRNA compared to males. If this difference translated to
the female mice used in the present study, it would account for their
reduced sensitivity to paroxetine. The stage of the estrous cycle of mice
was also found to influence the behavioural response to fluoxetine treatment
on tests of anxiety, with mice in the diestrus phase of the cycle being less
sensitive to the drug (Yohn et al., 2020). Furthermore, we cannot exclude the
possibility that these differences reflect different homecage experiences of
male and female mice, particularly in terms of aggressive behaviours and
social dominance hierarchies. Nonetheless, there is evidence from clinical
studies that men are more likely to report discontinuation symptoms
following SSRI cessation (Coupland et al., 1996), so the
current findings may reflect this clinical picture rather than pitfalls of
the preclinical model.Finally, it is interesting to note that in these experiments mice
maintained on paroxetine showed evidence of increased
anxiety on the EPM and LDB. One possible explanation is that discontinuation
effects are occurring even in these animals because in some experiments,
mice were tested 18 h after the last injection of paroxetine (see Table 1) when
drug levels are likely to have fallen. However, since mice tested 6 h after
the last injection still showed evidence of increased anxiety,
discontinuation is not the likely cause. Another explanation is that
increased anxiety is due to continuing blockade of the 5-HT transporter and
the consequent increase in synaptic 5-HT. In support of this idea, previous
studies with mice reported that continuous treatment with certain SSRIs is
anxiogenic on the EPM (Oh et al., 2009; Turcotte-Cardin et al., 2019;
Venzala et al.,
2012). Ourselves and others have also reported that 5-HT
transporter knockout mice show heightened anxiety on the EPM and other
anxiety tests (Ansorge
et al., 2004; Line et al., 2011). However,
other findings argue against this position. First, the high anxiety
phenotype of the 5-HT transporter knockout mice may in part involve a
neurodevelopmental mechanism (Ansorge et al., 2004). Second,
previous studies on the effect of repeated administration of paroxetine to
mice on EPM performance do not consistently detect increased anxiety (Elizalde et al.,
2008; Goeldner et al., 2005; Guilloux et al., 2011; Thoeringer et al.,
2010), but mouse strain difference is one potential confound
(Jin et al.,
2017). Third, the present study found that mice continuously
treated with citalopram (twice-daily for 12 days) did not show an anxiogenic
response on the EPM. Thus, on balance, available data suggest that the
anxiogenic effect of continuous paroxetine detected here is not easily
explained by either discontinuation itself or a simple 5-HT-related
mechanism. Alternative explanations include a role for other pharmacological
effects of paroxetine (muscarinic receptor antagonism and noradrenaline
reuptake blockade).In conclusion, this study reports evidence of a discontinuation response in
mice within 48 h of cessation from a course of SSRI treatment that likely
involves a neuroadaptive mechanism. This discontinuation response had
features consistent with anxiety-provoked behavioural inhibition rather than
a general reduction in motor activity, which correlates with the findings of
increased anxiety in patients within days of stopping a course of SSRI
therapy. SSRI discontinuation in mice may provide a useful model to aid the
investigation of the neurobiological mechanisms involved.Click here for additional data file.Supplemental material, sj-docx-1-jop-10.1177_02698811221093032 for Effect
of selective serotonin reuptake inhibitor discontinuation on
anxiety-like behaviours in mice by Helen M Collins, Raquel Pinacho,
Dersu Ozdemir, David M Bannerman and Trevor Sharp in Journal of
Psychopharmacology
Authors: Jean-Philippe Guilloux; Denis J P David; Lin Xia; Hai Thanh Nguyen; Quentin Rainer; Bruno P Guiard; Christelle Repérant; Thierry Deltheil; Miklos Toth; René Hen; Alain M Gardier Journal: Neuropharmacology Date: 2011-02-17 Impact factor: 5.250
Authors: Christopher Barkus; Samantha J Line; Anna Huber; Liliana Capitao; Joao Lima; Katie Jennings; John Lowry; Trevor Sharp; David M Bannerman; Stephen B McHugh Journal: Biol Psychiatry Date: 2013-10-08 Impact factor: 13.382
Figure 1.
Figure 2.
Figure 3.
Figure 4.
Figure 5.