The Buffer Effect of Therapy Dog Exposure on Stress Reactivity in Undergraduate Students


International  Journal  of

Environmental Research

and Public Health

Article

The Buffer Effect of Therapy Dog Exposure on Stress
Reactivity in Undergraduate Students

Alexandra J. Fiocco * and Anastasia M. Hunse

Department of Psychology, Institute for Stress and Wellbeing Research, Ryerson University, 350 Victoria Street,
Toronto, ON M5B 2K3, Canada; anastasia.hunse@gmail.com
* Correspondence: afiocco@psych.ryerson.ca; Tel.: +1-41-6979-5000 (ext. 3008)

Received: 31 May 2017; Accepted: 28 June 2017; Published: 30 June 2017

Abstract: Stress is an insidious health risk that is commonly reported among university students.
While research suggests that dog exposure may facilitate recovery from a stress response, little is
known about the buffer effect of dog exposure on the stress response to a future stressor. This study
examined whether interaction with a therapy dog could reduce the strength of the physiological
stress response when exposed to a subsequent stressor. Sixty-one university students were randomly
assigned to either a therapy dog (TD, n = 31) or a no-dog control (C, n = 30) group. The stress response
was measured by electrodermal activity (EDA) in response to the Paced Auditory Serial Addition
Test (PASAT). Participants also completed questionnaires that assessed pet attitude, general stress
levels, and affect. Analyses of covariance (ANCOVAs) showed that increase in EDA was significantly
more pronounced in the C group than in the TD group (p < 0.01). Pet attitudes did not modulate
the buffer effect of therapy dog exposure. Results suggest that therapy dog exposure may buffer the
stress response in university students, which has implications for the promotion of a viable stress
management program on university campuses.

Keywords: stress; therapy dog; intervention; human-animal interaction

1. Introduction

Stress is an insidious pathophysiological mechanism that underlies a number of health-related
disorders, both physical and psychological in nature [1,2]. Both affective and physiological stress is
particularly pervasive in undergraduate students and has been linked to a number of negative health
outcomes [3,4]. Further, it has been shown that students are commonly unknowledgeable of viable
stress reduction options available to them on or off of campus [5].

The negative effect of stress on physical and psychological health outcomes in university and
college students has been well documented. The transition into university can be associated with a
number of perceived stressors, including: multiple examinations, concerns about grades, financial
difficulty, and interpersonal or relationship stressors [4]. Heightened levels of stress are pervasive in
the undergraduate student population and have been linked to the development of overall physical
illness [6], depression [3,7], and anxiety [3]. Increased blood pressure has also been found to correlate
with stress in the undergraduate population, both of which significantly increase during times of
academic study [8,9].

Int. J. Environ. Res. Public Health 2017, 14, 707; doi:10.3390/ijerph14070707 www.mdpi.com/journal/ijerph

http://www.mdpi.com/journal/ijerph
http://www.mdpi.com
http://dx.doi.org/10.3390/ijerph14070707
http://www.mdpi.com/journal/ijerph


Int. J. Environ. Res. Public Health 2017, 14, 707 2 of 11

In a 2013 survey that gathered information from 30,000 students at 30 Universities, the American
College Health Association (ACHA) found that 40% of students had not received information about
stress reduction from their university, while 74% were interested in receiving information on stress
reduction. The same survey reported that 45% of students rated their stress as above average and 12%
indicated that they were under tremendous stress [5]. In the ACHA Fall 2016 survey, completed by
36,385 students, when questioned which factors had a negative impact on their academic performance,
32.2% of students reported general stress, 24.9% reported anxiety, 15.4% reported depression and
20.6% reported sleep difficulties [10]. Further, 82.6% of students reported feeling exhausted, 60.8% felt
overwhelmed by anxiety, 60.6% felt lonely, 50.9% reported feeling that things were hopeless, and 10.4%
seriously considered suicide [10]. There has also been a notable rise in stress-related health ailments
between 2013 and 2016; including a 50% increase in anxiety, 47% increase in depression, and a 47%
increase in suicide attempts [10]. Together, these reports highlight the need for an effective, timely, and
accessible source of stress relief for students on campus. One such source may exist in the therapy dog
programs that have been increasing in popularity on university campuses.

A plethora of research suggests that pet ownership is significantly associated with wellbeing in
Western, European, and Eastern countries (for review, see [11]). Research shows that animal assisted
therapy produces a number of benefits in clinical populations, including improved focus and awareness
in children with pervasive development disorders [12], increased language use in children with
autism [13], decreased stress physiology within a social context in children with autism [14], increased
social interactions in patients with dementia [15], and decreased depression in institutionalized
patients [16]. One hour of interaction with a therapy dog has been shown to decrease self-report
ratings of depression, anxiety, and pain in patients admitted to a mental health hospital [17]. Further,
a study that examined residents of a nursing home found that weekly 15-minute interactions with a
therapy dog led to an improvement in mood [18,19].

In non-patient populations, exposure to a therapy dog is associated with an increase in sense of
well-being and pleasure [20], and is also found to be associated with greater decreases in endocrine
and cardiovascular reactivity following stress exposure [21]. A study conducted by Odendaal and
Meintjes [22] found that as little as five minutes of interaction with a therapy dog lowered cortisol levels
and blood pressure compared to pre-test levels in healthy adults. Additionally, a study conducted by
Barker et al. [23] demonstrated that a five-minute interaction with a therapy dog lowered serum and
salivary cortisol levels in healthcare professionals compared with baseline levels. Presence of a therapy
dog may further reduce cardiovascular arousal while engaged in a stressful situation [24,25].

While previous research suggests that dog exposure may facilitate recovery from a stress response,
few studies have explored whether prior interaction with a therapy dog before stress exposure can
act as a buffer to subsequent stress responsivity. Allen et al. [26], examined the effect of a human
versus animal companion on stress reactivity in response to an arithmetic challenge in 45 female dog
owners, aged 27 to 55 years of age, who were self-described as “lovers of dogs”. Women were tested
in their home and were randomly assigned to one of three conditions: a no companion condition, a
human companion condition, and a pet companion condition. Results showed that women assigned
to the pet companion condition displayed lower stress reactivity, as measured by the galvanic stress
response (i.e., electrodermal activity, EDA) and systolic blood pressure, compared with the human
companion and no companion condition [26]. This study suggests that the presence of a pet during
stress exposure serves as a buffer to the stress response. Although research suggests that presence
of a pet may reduce stress physiology during stress exposure [26–28], these studies have focused on
participants who are pet owners, using the participants’ personal pet in the protocol. In these study
designs, participants underwent a mental stress induction protocol in the comfort of their home while
their pet roamed freely. There is a paucity of research that has examined the effect of brief therapy dog
exposure on subsequent stress responsivity to a stress induction protocol during which the therapy
dog is not present. This research question is important in the context of university and college students
who may not have access to a personal pet, but may have brief access through programs such as a



Int. J. Environ. Res. Public Health 2017, 14, 707 3 of 11

therapy dog program. Indeed there is a growing interest among students for the use of therapy dogs
as a method of stress reduction [29].

To this end, the present study aimed to determine whether interaction with a therapy dog impacts
the physiological stress response in the face of a subsequent stressor, and whether attitude towards
pets might moderate this effect. Based on previous literature, it was hypothesized that interaction with
a therapy dog would be associated with lower levels of physiological stress reactivity, as measured by
EDA. It was further predicted that the buffer effect would be enhanced by high self-report positive
pet attitudes.

2. Materials and Methods

2.1. Participants

Sixty-one university students, with a mean age of 21.02 (SD = 5.503, range 18–47) were randomized
to either the therapy dog (TD) group (n = 31) or the control group (n = 30). There were 14 male
participants and 47 female participants. Exclusion criteria for the study included fear and/or allergies
to dogs. Participants were invited to the Institute for Stress and Wellbeing Research where they signed
an informed consent form before undergoing the study protocol. Participants were naïve to the true
purpose of the study, and were fully debriefed at study completion. This study was carried out
following the rules of the Declaration of Helsinki of 1975. This study was granted ethics approval by
the Ryerson University Research Ethics Board (2014-308).

2.2. Procedure

Participants were randomized to either a Therapy Dog (TD) or no-dog Control (C) group, using a
blocked design randomizing software called Research Randomizer [30]. Participants were unaware
of which group they had been assigned to prior to their appointment, and were informed upon
enrollment that group assignment was random. Each participant was tested in a private testing room.

Once consent had been collected, participants’ finger-tips were fitted with a Biopac galvanic skin
response amplifier. Following a five-minute baseline rest period, participants in both groups completed
questionnaires that gathered information about demographics, perceived stress, and pet attitudes.
Participants in the C group were then told to relax in a seated position for 10 min. Participants in the
TD dog were asked to remain seated while a therapy dog was brought to sit beside them. TD group
participants were informed that they could interact with the therapy dog in a seated position for 10 min,
after which time the therapy dog would be removed from the room. After this 10-min experimental
period (i.e., no dog vs. dog) participants were asked to complete an affect questionnaire. Upon
completion, participants were given instructions about how to complete the Paced Auditory Serial
Attention Task (PASAT). Upon completion of the PASAT, participants were asked to fill out a second
affect questionnaire before being detached from the Biopac system and undergoing the debriefing
process. See Figure 1 for a flowchart of the procedure.



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Figure 1. Flowchart of the study procedure. PAS: Pet Attitude Scale; PANAS: Positive and Negative 

Affect Scale; PASAT: Paced Auditory Serial Attention Task; PSS: Perceived Stress Scale. 

2.3. Measures 

2.3.1. Stress Induction 

Paced Auditory Serial Addition Task (PASAT) [31]. The PASAT is a computerized audio task that 

assesses attentional processing, immediate memory, and attention [32]. It has been also been shown 

to reliably induce a stress response [33]. In order to induce participants’ perceived threat to ego and 

increase  their  stress  response,  participants  were  told  that  their  performance  was  going  to  be 

monitored  by  the  researcher  and  was  being  compared  with  other  students.  Completion  of  the 

PASAT included listening to a standardized audio recording of single digits being presented every 3 

s, with the participant expected to add each digit to the one immediately prior to it and input it at 

increasing speed. The PASAT took approximately 8 min to complete. 

2.3.2. Stress Buffer 

St. John Ambulance Therapy Program (Toronto, ON, Canada). The present study used ten therapy 

dogs recruited from the St. John Ambulance organization. Dogs ranged in age and size. Breed of dog 

included an Irish Setter, Schnoodle, Miniature Poodles, Greyhound, King Charles Spaniel, Golden 

Retrievers, and Australian Cattle Dog. All dogs were certified by the organization, and as such had 

certified good health, hygiene, and had been trained to interact with people in a docile manner. 

Participants in the TD group interacted with the therapy dog for ten min before stress induction. 

2.3.3. Physiological Stress Measures 

Figure 1. Flowchart of the study procedure. PAS: Pet Attitude Scale; PANAS: Positive and Negative
Affect Scale; PASAT: Paced Auditory Serial Attention Task; PSS: Perceived Stress Scale.

2.3. Measures

2.3.1. Stress Induction

Paced Auditory Serial Addition Task (PASAT) [31]. The PASAT is a computerized audio task that
assesses attentional processing, immediate memory, and attention [32]. It has been also been shown
to reliably induce a stress response [33]. In order to induce participants’ perceived threat to ego
and increase their stress response, participants were told that their performance was going to be
monitored by the researcher and was being compared with other students. Completion of the PASAT
included listening to a standardized audio recording of single digits being presented every 3 s, with the
participant expected to add each digit to the one immediately prior to it and input it at increasing
speed. The PASAT took approximately 8 min to complete.

2.3.2. Stress Buffer

St. John Ambulance Therapy Program (Toronto, ON, Canada). The present study used ten therapy
dogs recruited from the St. John Ambulance organization. Dogs ranged in age and size. Breed
of dog included an Irish Setter, Schnoodle, Miniature Poodles, Greyhound, King Charles Spaniel,
Golden Retrievers, and Australian Cattle Dog. All dogs were certified by the organization, and as such
had certified good health, hygiene, and had been trained to interact with people in a docile manner.
Participants in the TD group interacted with the therapy dog for ten min before stress induction.



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2.3.3. Physiological Stress Measures

Galvanic Skin Response. To monitor the physiological stress response, participants’ electrodermal
(EDA) activity was measured throughout the entire testing process by a trained researcher using the
Biopac EDA100C (Biopac Systems Canada Inc., Montreal, PQ, Canada). The EDA100C measures skin
conductance levels as they increase when an individual is under stress, and is an efficient and effective
means of measuring stress reactivity [34].

2.3.4. Questionnaires

General Perceived Stress [35]. The Perceived Stress Scale (PSS) is a measure that determines the
degree to which an individual perceives their life as stressful in the past month. The PSS contains
14 items on a 5-point scale with the following response options: never, almost never, sometimes,
fairly often, and very often. The PSS has been shown to have excellent reliability and validity [36,37].
Higher scores on the PSS indicate greater perceived stress.

Positive and Negative Affect [38]. The Positive and Negative Affect Schedule (PANAS) is a measure
that uses a 5-point scale, from “Not at all” to “Extremely”, to determine the range of feelings for
20 different emotions, including 10 positive (e.g., Interested, Excited, Enthusiastic) and 10 negative
emotion (e.g., Irritable, Distressed, Nervous). The PANAS measures an individual’s emotions in
the moment and is a way to determine change in affect after a stimulus is administered [38], Clark,
& Tellegen, 1988). It has been shown to possess cross-sample stability, internal reliability, temporal
stability, cross-cultural invariance, and convergent and criterion-related validity [39]. In the current
study, the PANAS measured self-reported affect before intervention, after intervention, and following
stress exposure. The scale provides a total score for positive affect (PA) and negative affect (NA), with
higher scores indicating higher endorsement of the emotion.

Pet Attitudes [40]. The Pet Attitude Scale (PAS) measures participant’s attitudes towards pets. It is
most commonly used to evaluate the interaction between testing results and people’s pre-existing
attitudes towards pets. The PAS contains 18 items on a 7-point scale with response options including
strongly disagree, disagree, slightly disagree, unsure, slightly agree, agree, and strongly agree.
Higher score on the PAS indicates more positive attitude towards pets. The PAS is a viable choice
to explore the relationship between participants’ physiological responses to the stressor and their
pre-existing attitude towards pets, and has been shown to have high reliability [41].

2.4. Statistical Analyses

Data were assessed for assumptions of normality and outliers. One-way analyses of variance
(ANOVA) and chi-square analyses were conducted to assess for between-group differences at baseline.
Baseline factors that significantly differed between groups (p < 0.05) were controlled for in subsequent
analyses. To address the study hypotheses, EDA and positive and negative affect levels were converted
into change scores by subtracting the mean levels at baseline from the mean levels during the stressor.
One-way ANOVAs were conducted on the change scores, controlling for covariates and baseline
physiology scores. To assess the moderating role of pet attitude, a median split was conducted to
create high and low categories for Pet Attitude. Interaction terms were then entered into the model
(i.e., Group × Pet Attitude). Subgroup analysis was then conducted within the TD group to assess
for moderation of pet attitude on therapy do buffer effect. All analyses were conducted using SPSS
Statistics 22 (IBM Corp., North Castle, NY, USA) and results were considered significant at p < 0.05.

3. Results

3.1. Participant Characteristics

Recruitment for this study was conducted from January–February 2015. Overall, participants
had a mean age of 21.02 years (range = 18–47). Analyses of variance and chi-square analyses showed



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that groups did not significantly differ on any of the baseline variables. Table 1 summarizes detailed
sample characteristics and baseline measures.

Table 1. Baseline characteristics of participants.

Characteristic Therapy Dog (n = 31) Control (n = 30) p-Value

Mean (SD) or N (%) Mean (SD) or N (%)
Age, years 20.13 (3.364) 21.93 (7.017) 0.20

Female, N (%) 24 (39.3%) 23 (37.7%) 0.94
Ethnicity, N (%) 0.33

Black/African American 4 (6.6%) 1 (1.6%)
White/Caucasian 10 (16.4%) 13 (21.3%)

Other 17 (27.9%) 16 (26.2%)
PAS 105.35 (14.87) 102.37 (17.83) 0.48
PSS 28 (8.34) 26.53 (6.25) 0.44

PANAS
Positive 26.52 (6.51) 30 (7.31) 0.05

Negative 14.29 (3.37) 17.03 (6.87) 0.05

PAS: Pet Attitude Schedule; PSS: Perceived Stress Scale; PANAS: Positive and Negative Affect Schedule; EDA:
Electrodermal Activity.

3.2. Effect of Therapy Dog Exposure on Affective Reactivity

Controlling for baseline affect, ANCOVA did not reveal a significant Group effect on change in
positive affect, F(1, 61) = 3.17, p = 0.08. Although not statistically significant, there was a trend for
positive affect to decrease more in the C group (MC = −4.37, SD = 7.15) compared to the TD group
(MTD = −0.35, SD = 6.656) in response to the PASAT. Controlling for baseline affect, ANCOVA did
not reveal a significant Group effect on change in negative affect F(1, 60) = 0.26, p = 0.61. Although
not statistically significant, the mean change in negative affect was smaller in the C group (MC = 0.60,
SD = 6.10) than the TD group (MTD = 2.29, SD = 5.62), see Figure 2.

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Table 1. Baseline characteristics of participants. 

Characteristic  Therapy Dog (n = 31) Control (n = 30) p‐Value 

  Mean (SD) or N (%)  Mean (SD) or N (%)   

Age, years  20.13 (3.364)  21.93 (7.017)  0.20 

Female, N (%)  24 (39.3%)  23 (37.7%)  0.94 

Ethnicity, N (%)      0.33 

Black/African American  4 (6.6%)  1 (1.6%)   

White/Caucasian  10 (16.4%)  13 (21.3%)   

Other  17 (27.9%)  16 (26.2%)   

PAS  105.35 (14.87)  102.37 (17.83)  0.48 

PSS  28 (8.34)  26.53 (6.25)  0.44 

PANAS       

Positive  26.52 (6.51)  30 (7.31)  0.05 

Negative  14.29 (3.37)  17.03 (6.87)  0.05 

PAS:  Pet  Attitude  Schedule;  PSS:  Perceived  Stress  Scale;  PANAS:  Positive  and  Negative  Affect  Schedule;   

EDA: Electrodermal Activity. 

3.2. Effect of Therapy Dog Exposure on Affective Reactivity 

Controlling for baseline affect, ANCOVA did not reveal a significant Group effect on change in 

positive affect, F(1, 61) = 3.17, p = 0.08. Although not statistically significant, there was a trend for 

positive affect to decrease more in the C group (MC = −4.37, SD = 7.15) compared to the TD group 

(MTD = −0.35, SD = 6.656) in response to the PASAT. Controlling for baseline affect, ANCOVA did 

not reveal a significant Group effect on change in negative affect F(1, 60) = 0.26, p = 0.61. Although 

not statistically significant, the mean change in negative affect was smaller in the C group (MC = 0.60, 

SD = 6.10) than the TD group (MTD = 2.29, SD = 5.62), see Figure 2. 

 

Figure 2. Buffer effect of therapy dog exposure on positive and negative affect. 

3.3. Effect of Therapy Dog Exposure on Physiological Reactivity 

Controlling for baseline EDA, ANCOVA showed a significant effect of Group on EDA change 

from baseline to post‐stress, F(1, 59) = 15.24, p < 0.00. Specifically, the TD group showed a lower 

increase in EDA in response to the PASAT compared with the C group (MTD = 1.58, SD = 4.93 vs. 

MC = 7.07, SD = 5.81). See Figure 3. 

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Change in Affect

Positive Affect Negative Affect

Control Group

Therapy Dog Group

Figure 2. Buffer effect of therapy dog exposure on positive and negative affect.

3.3. Effect of Therapy Dog Exposure on Physiological Reactivity

Controlling for baseline EDA, ANCOVA showed a significant effect of Group on EDA change
from baseline to post-stress, F(1, 59) = 15.24, p < 0.00. Specifically, the TD group showed a lower
increase in EDA in response to the PASAT compared with the C group (MTD = 1.58, SD = 4.93 vs.
MC = 7.07, SD = 5.81). See Figure 3.



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Figure 3. Buffer effect of therapy dog exposure on mean electrodermal activity. 

3.4. Moderating Role of Pet Attitude in the Relationship Between Therapy Dog Exposure and Stress Reactivity 

ANOVA revealed no significant  interaction between Group and Pet Attitude on change  in 

EDA, F(1, 60) = 0.31, p = 0.31. Subgroup analysis restricted to TD participants showed no effect of 

High  vs.  Low  Pet  Attitudes  on  EDA, F(1,  31)  =  0.41, p =  0.53.  These  results  were  confirmed  by 

regression analyses. 

4. Discussion 

To date, a wealth of research has shown that pet ownership and therapy dog exposure can have 

tremendous beneficial effects for persons of all ages [11]. Research has shown that the presence of 

one’s pet during stress induction may buffer physiological reactivity [26,28]. Previous research also 

shows that exposure to a therapy dog can have beneficial effects in patient populations and can 

modulate physiological indices of stress such as blood pressure and cortisol [21]. This study adds to 

the wealth of knowledge in this area as it is the first study to show that interacting with a therapy 

dog for as little as 10 min may significantly buffer the stress response to a subsequent stressor. 

Although the current findings are limited to university students, it is imperative to examine this 

population as they commonly report heightened levels of stress. Indeed, high stress levels in this 

population have been shown to associate with poor psychological outcomes, including increased 

levels of depression and anxiety  [3]. Unsurprisingly, a  large number of undergraduate students 

report that they desire access and information about effective stress reduction methods available on 

campus [5]. 

In accordance with the study hypothesis, therapy dog exposure significantly buffered the stress 

response, as measured by EDA. This is the first study to show that interacting with a therapy dog 

can dampen physiological reactivity in response to a future stressor, when the therapy dog is not 

present. In contrast, although a trending result was found for positive affect, the current study did 

not find therapy dog exposure to significantly influence self‐reported affect in response to a stressor. 

Although null findings were not predicted, the contrast in findings between the physiological data 

and self‐report data is not surprising. Indeed, it is well documented that objective measures of stress 

are not highly correlated with self‐report measures [42]. Self‐report measures may be affected by a 

number of extraneous variables,  including personality and response bias. Accordingly, previous 

studies using affect as an outcome variable have been mixed; therapy dog exposure has been found 

to  associate  with  increased  feelings  of  calmness  [43]  and  decreased  depressive  symptoms  [44]. 

However, studies have also shown that interaction with a therapy dog can result in no change in 

dysphoria, positive affect [45], or mood in general [46]. Although not statistically significant, it is 

worth noting that participants exposed to a therapy dog reported a smaller decrease  in positive 

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Change in Electrodermal Activity 

Control Therapy Dog
Control Group

Therapy Dog Group

Figure 3. Buffer effect of therapy dog exposure on mean electrodermal activity.

3.4. Moderating Role of Pet Attitude in the Relationship between Therapy Dog Exposure and Stress Reactivity

ANOVA revealed no significant interaction between Group and Pet Attitude on change in EDA,
F(1, 60) = 0.31, p = 0.31. Subgroup analysis restricted to TD participants showed no effect of High vs.
Low Pet Attitudes on EDA, F(1, 31) = 0.41, p = 0.53. These results were confirmed by regression analyses.

4. Discussion

To date, a wealth of research has shown that pet ownership and therapy dog exposure can have
tremendous beneficial effects for persons of all ages [11]. Research has shown that the presence of one’s
pet during stress induction may buffer physiological reactivity [26,28]. Previous research also shows
that exposure to a therapy dog can have beneficial effects in patient populations and can modulate
physiological indices of stress such as blood pressure and cortisol [21]. This study adds to the wealth
of knowledge in this area as it is the first study to show that interacting with a therapy dog for as little
as 10 min may significantly buffer the stress response to a subsequent stressor.

Although the current findings are limited to university students, it is imperative to examine this
population as they commonly report heightened levels of stress. Indeed, high stress levels in this
population have been shown to associate with poor psychological outcomes, including increased levels
of depression and anxiety [3]. Unsurprisingly, a large number of undergraduate students report that
they desire access and information about effective stress reduction methods available on campus [5].

In accordance with the study hypothesis, therapy dog exposure significantly buffered the stress
response, as measured by EDA. This is the first study to show that interacting with a therapy dog
can dampen physiological reactivity in response to a future stressor, when the therapy dog is not
present. In contrast, although a trending result was found for positive affect, the current study did
not find therapy dog exposure to significantly influence self-reported affect in response to a stressor.
Although null findings were not predicted, the contrast in findings between the physiological data
and self-report data is not surprising. Indeed, it is well documented that objective measures of stress
are not highly correlated with self-report measures [42]. Self-report measures may be affected by
a number of extraneous variables, including personality and response bias. Accordingly, previous
studies using affect as an outcome variable have been mixed; therapy dog exposure has been found to
associate with increased feelings of calmness [43] and decreased depressive symptoms [44]. However,
studies have also shown that interaction with a therapy dog can result in no change in dysphoria,
positive affect [45], or mood in general [46]. Although not statistically significant, it is worth noting that
participants exposed to a therapy dog reported a smaller decrease in positive affect after completion
of the stress task than participants in the control group, suggesting that a recent interaction with a



Int. J. Environ. Res. Public Health 2017, 14, 707 8 of 11

therapy dog may impact affective reactions to subsequent stress. The ability to mitigate the impact
of stress on positive affect has intriguing implications, particularly since positive affect is associated
with increased social engagement [47] and subjective wellbeing [48]. With respect to negative affect,
while participants exposed to the therapy dog tended to display a greater increase in negative affect
compared with participants in the control condition, it is important to note that participants in the
control group reported a slightly higher mean negative affect at baseline. Therefore, these findings may
be explained by a ceiling effect with respect to possible change in negative affect following the stressor.

Surprisingly, pet attitude did not moderate the stress-buffer effect of therapy dog exposure.
Although this area is relatively unexplored in the literature, this finding differs from one study
conducted in 1985 that found a significant positive correlation between positive pet attitudes and
reduction in mean arterial pressure, systolic pressure, and diastolic pressure while petting a dog at
rest [49]. The lack of significant findings regarding the relationship between pet attitude and stress
reactivity in the present study may be explained by the characteristics of the current sample. The mean
score for pet attitude was relatively high overall (M = 103.86). This indicates that a larger sample is
needed to explore this relationship, where there is a wider distribution of participants scoring low
on positive pet attitudes and those scoring high on positive pet attitudes. However, in the context
of a university sample, the fact that a majority of students display a positive attitude towards pets
may suggest that therapy dog exposure within the university is a viable stress-management program
for undergraduates.

Although the current findings are promising, the study was not without limitations. The largest
limitation was the relatively small sample size. Although there were sufficient participants per group
to detect a significant difference in EDA, the sample may not have been large enough to assess
the moderating role of pet attitudes. However, even with a larger sample size, the challenge of
selection bias would likely remain. That is, students who dislike or fear dogs will likely choose not to
participate in this research. This challenge may be addressed using more ecologically valid research
designs, including the assessment of students who attend therapy dog sessions at their university.
Another study limitation was that the majority of the sample was female. This is a consistent challenge
with research, and is similar to previous studies that have largely based their findings on female
participants (e.g., [26]). Given the importance of sex and gender differences in stress physiology [50],
it is important to examine whether the buffer effect of pet therapy is moderated by gender or sex.

Additional research is needed to determine how pet attitudes and history of pet ownership
moderates the beneficial effects of pet therapy on stress physiology and health outcomes. Further,
research examining the longevity of the stress buffer effect is needed to provide more insight into how
long individuals can benefit from therapy dog exposure.

Currently, there is a growing amount of interest in the student population for the use of therapy
dogs as a method of stress reduction [29]. Qualitative reports suggest that therapy dog programs
may decrease stress among university students who experience stress [51]. However, these programs
require systematic evaluation to assess how therapy dog programs are helping student populations.
We hope that this study will encourage additional research, assessing therapy dog exposure as a stress
buffer in different populations that report relatively high levels of stress, including a more diverse
group of university and college students from low socio-economic communities.

5. Conclusions

This study provides support for the use of therapy dog exposure as a viable stress-management
tool to decrease stress physiology in undergraduate students, a segment of the population that displays
increasing negative stress-related physical, mental and emotional health outcomes.

Acknowledgments: Many thanks to the St. John’s Ambulance Therapy Dog Program for partnering with us on
this project, and to Carson Pun for his technical expertise in physiological monitoring.

Author Contributions: Both Alexandra J. Fiocco and Anastasia M. Hunse conceptualized the project, analyzed
the data, and co-wrote the manuscript. Anastasia M. Hunse conducted all testing procedures.



Int. J. Environ. Res. Public Health 2017, 14, 707 9 of 11

Conflicts of Interest: The authors have nothing to disclose.

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© 2017 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access
article distributed under the terms and conditions of the Creative Commons Attribution
(CC BY) license (http://creativecommons.org/licenses/by/4.0/).

http://dx.doi.org/10.1188/08.ONF.225-232
http://www.ncbi.nlm.nih.gov/pubmed/18321834
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http://creativecommons.org/
http://creativecommons.org/licenses/by/4.0/.

	Introduction 
	Materials and Methods 
	Participants 
	Procedure 
	Measures 
	Stress Induction 
	Stress Buffer 
	Physiological Stress Measures 
	Questionnaires 

	Statistical Analyses 

	Results 
	Participant Characteristics 
	Effect of Therapy Dog Exposure on Affective Reactivity 
	Effect of Therapy Dog Exposure on Physiological Reactivity 
	Moderating Role of Pet Attitude in the Relationship Between Therapy Dog Exposure and Stress Reactivity 

	Discussion 
	Conclusions