Open Access
Abstract
Objective
To
characterize obese or overweight dogs that visited private Japanese
veterinary clinics located in humid subtropical climate zones.
Methods
Dogs
were categorized into four body condition score groups and five body
size groups based on their breed. Multilevel logistic regression models
were applied to the data. A Chi-squared test was used to examine whether the percentage of obese or overweight dogs differed between breeds.
Results
There
were 15.1% obese dogs and 39.8% overweight dogs. Obese dogs were
characterized by increased age and female sex, whereas overweight dogs
were characterized by increased age and neuter status (P < 0.05).
Peak probabilities of dogs being either obese or overweight were
between 7 and 9 years of age, with the probabilities then declining as
the dogs got older. For example, in toy sized dogs, the probability of
dogs being overweight increased from 33.4% to a peak of 55.1% as dog age
rose from 1 to 8 years old. Also, in medium, small and toy sized dogs,
neutered dogs were more likely to be overweight than intact dogs,
whereas neutered small sized dogs were more likely to be obese than
intact small sized dogs (P < 0.05). Additionally, the
percentages of obese or overweight dogs differed between the 10 selected
breeds with the highest percentage of obese or overweight dogs.
Conclusions
By
taking age, body size, sex and neuter status into account,
veterinarians can advise owners about maintaining their dogs in ideal
body condition.
Keywords
- Age;
- Canine;
- Factors;
- Obesity;
- Overweight
1. Introduction
Numbers of obese and overweight people are increasing in developed countries [1] and [2]. Also, excessive body weight is a growing problem in dogs [3],
and has been implicated in a range of medical concerns such as diabetes
mellitus, cardio-vascular diseases, dyslipidemia and osteoarticular
diseases [4], [5] and [6].
Dog obesity in developed countries is also a widespread problem. The
prevalence (%) of dogs being obese and overweight in the USA, the UK,
Australia and China reported was estimated to be 34.1% [5], 59.3% [7], 25.0% [8] and 44.4% [9], respectively.
Factors
commonly associated with dogs having excessive body weight are middle
age, neutering, female sex, low physical activity and also low human
population density [4], [5], [7] and [9].
Specific breeds, such as Labrador Retrievers, Beagles and Shetland
Sheepdogs, have also been reported as being at highest risk of either
obesity or being overweight [5] and [10].
For example, Cocker Spaniels have been reported as having the highest
risk for being overweight, whereas Shetland Sheepdogs were at the
highest risk of obesity [5].
Dogs could also be categorized into different size groups based on their breed [4] and [11],
such as large, medium and small size; this would take account of some
breed effects. However, no studies in Japan have used medical records in
a single model to quantify the characteristic factors (body size, age,
sex, neuter status and human population density) associated with dogs
being either obese or overweight, and the interactions between these
factors.
Dogs'
veterinary medical records are in a multi-level structure because health
related checks, guidance and treatments on an individual dog are all
performed in a clinic. The clinic is a variable that includes some
unique information, such as a dog's location, the average social and
economic status of owners coming with their dogs to the clinic, and
veterinary health guidance. Therefore, the objective of the present
study was to examine characteristic or risk factors and interactions
associated with obese dogs and overweight dogs in Japan by using a
mixed-effects model with clinics as a random intercept.
2. Materials and methods
2.1. Dog database including dog characteristics and body condition score (BCS)
Institutional
Animal Care and Use Committee approval at Meiji University (IACUC
15-0013) was obtained for this study. A dog database has been created at
Meiji University (Kawasaki, Japan) by cooperating with a veterinary
service (Spectrum Lab Japan, Tokyo, Japan). The veterinary service
recorded information about individual dog's characteristics (BCS, age,
sex, neuter status and breed) when they received serum samples for
lipoprotein analysis from veterinarians in private clinics throughout
Japan. The veterinarians who submitted the samples were not informed
about the specific purposes of the present study. The serum samples were
collected from clinically non-diseased dogs that received a health
check and from dogs that were being assessed for suspected dyslipidemia.
The dogs' health conditions were diagnosed by their veterinarians when
the serum samples were taken. The BCS for each dog was evaluated by the
dog's veterinarian using a five-point scale system (1: thin, 2:
underweight, 3: ideal, 4: overweight and 5: obese). The BCS five-point
scale system is widely used in Japan [12],
and website information and brochures about the system are widely
available to veterinary clinics across Japan, provided by the Pet Food
Institute (Washington D.C., USA) and a nutrition company [Hill's-Colgate
(Japan) Ltd., Tokyo, Japan].
2.2. Data and exclusion criteria
The
database comprised data of 9 120 dogs from 116 breeds, collected from
1 198 veterinary clinics between 2006 and 2013, amounting to 10.9% of
the 11 032 small animal clinics in Japan [12].
The samples were submitted from all the 47 prefecture regions, which
are mostly located in humid subtropical climate zones. The proportions
of the samples in Northern Japan, East Japan (including Tokyo), West
Japan and Kyushu were 9.6%, 56.7%, 28.1% and 5.6%, respectively.
Additionally, the proportions of the samples submitted in January to
March, April to June, July to September and October to December were
20.9%, 29.5%, 24.9% and 24.7%, respectively.
Records
of second or later visits were not used in the present study (2 170
records). Records of dogs having diabetes mellitus, hypothyroidism or
hyperadrenocorticism health problems, which would influence body
condition, were excluded from the dataset (563 records) if the
veterinarians had made a diagnosis of endocrine diseases from blood and
urinary tests, on the basis of clinical signs such as polydipsia and
polyuria. Also, the records of dogs with BCS 1 were excluded (12
records) because those dogs were few and were suspected of having a
health problem. With the exception of the above exclusion criteria, all
the other cases submitted by the clinics were included in the present
study.
Two datasets
were created in the present study. Dataset 1 (including BCS 2, 3, 4 and 5
dogs) contained the records of 5 605 dogs in 108 breeds from 1 094
clinics, and was used to investigate characteristic factors associated
with obese dogs. In Dataset 2 (including only dogs of BCS 2, 3 and 4),
dogs with BCS 5 were excluded (844 records) because this dataset was
used to examine factors only related to overweight dogs with BCS 4.
Hence, Dataset 2 included the records of 4 761 dogs in 103 breeds from
1 020 clinics.
2.3. Categories and definitions
Obese
and overweight dogs were defined as dogs having BCS 5 and BCS 4,
respectively. Additionally, dogs were classified into two sex groups
(male dogs or female dogs) and also two neuter status groups (intact
dogs or neutered dogs). The dogs in the 103 breeds were grouped into six
body size categories (breed body size) based on their breed [6]: giant (e.g. Saint Bernard), large (e.g. Labrador Retriever), medium (e.g. Beagle, Pembroke Welsh Corgi), small (e.g. Miniature Schnauzer, Shetland Sheepdog), toy (e.g.
Chihuahua, Miniature Dachshund, Pomeranian, Shih Tzu, Yorkshire
Terrier) and unknown. In the present study, giant sized dogs (23
records) were included in the large sized dog group because there were
relatively few samples. Finally, the unknown group consisted of mixed
breed dogs. In addition, human population density (people per km2)
values were based on the population density of the city where each
clinic was located, and were obtained from the Statistics Bureau in the
Ministry of Internal Affairs and Communications, Japan [13].
2.4. Statistical analysis
All
statistical analyses were performed using SAS software (SAS Institute
Inc., Cary, USA). Two-level analysis was applied, using a clinic at
level 2 and an individual dog at level 1, to take account of the
hierarchical structure of the individual dogs within a clinic. A
two-level mixed-effects logistic regression model, using the GLIMMIX
procedure with logit link function, was performed to determine risk
factors for obese or overweight dogs. Also, ILINK (inverse link
function) was used to convert the logit to a probability [14]. Pairwise multiple comparisons were performed using the Tukey–Kramer test.
Outcome
variables in Models 1 and 2, respectively, were whether or not dogs
were obese (1 or 0; reference category = dogs with BCS 2 – 4), and
whether or not dogs were overweight (1 or 0; reference category = dogs
with BCS 2 and 3). Age, sex, neuter status, breed body size groups and
human population density were included in both Models as possible
factors (explanatory variables). Quadratic expressions of continuous
variables (e.g. age) and all possible Two-way interactions
between explanatory variables were also examined in both Models, and
were then removed from the Models if they were not significant (P > 0.10).
The years when BCS was evaluated were taken as a fixed effect in the
Models, even though in preliminary analysis the year was not associated
with the probability of dogs being obese or overweight (P ≥ 0.11).
Additionally, both Models included the clinic as a random intercept. To
assess the variations in the probability of dogs being obese or
overweight that could be explained by the clinic, intraclass correlation
coefficients (ICC) were calculated by the following equation [15],
where ρ represents the ICC, 
is the between-clinic variance and π2/3
is the assumed variance at the individual dog level. Normality of the
residuals in the final Models was evaluated by using normal probability
plots [14]. Finally, for the 10 breeds with the highest percentages of obese or overweight dogs and with at least 60 dogs in Dataset 1, a Chi-squared test was used to examine whether or not the percentage of obese or overweight dogs differed between the 10 breeds.3. Results
BCS
(mean ± SEM) and median BCS in the 5 827 dogs, excluding BCS 1 dogs,
were 3.6 ± 0.01 and 4.0, respectively. Also, mean age at sampling was
8.4 ± 0.05, ranging from 0 to 18 years old. Relative frequencies (%) of
BCS 2, 3, 4 and 5 were 3.7%, 41.4%, 39.8% and 15.1%, respectively (Table 1). Mean population density (people per km2) was 5 859 ± 76 people, ranging from 29 to 21 882 people.
- Table 1. Relative frequency of 5 605 dogs categorized on the basis of BCS∗ and breed body size.
Measurements N % BCS 2: underweight 207 3.7 3: ideal 2 325 41.4 4: overweight 2 229 39.8 5: obese 844 15.1 Breed body size† Giant 24 0.4 Large 281 5.1 Medium 408 7.4 Small 1 676 30.6 Toy 2 696 49.3 Unknown‡ 397 7.2 - ∗: Dogs with BCS 1 (12 dogs) were excluded because those dogs were suspected of having a health problem; †: The remaining records (5 605) were treated as missing values; ‡: Unknown group consisted of mixed breed dogs.
Obese
dogs were characterized by increased age and being female, whereas
overweight dogs were characterized by increased age and neuter status (Table 2; P < 0.05). Increased age was non-linearly associated with a higher probability of dogs being obese or overweight (P < 0.05). The probability of dogs being either obese or overweight peaked between 7 and 9 years of age, and then declined ( Figure 1). Female dogs were 1.3 times (odds ratio = 1.3; P < 0.01; Table 3) more likely to be obese than male dogs, but no such association was found between the groups for being overweight (P = 0.29; Table 2).
- Table 2. Estimates of fixed effects, random effect variance and ICC included in the final models for the probability of dogs being obese or overweight∗.
Fixed effects (factors), variance and ICC
Being obese
Being overweight
Estimate P-value Estimate P-value Intercept −2.452 7 ± 0.254 2 < 0.01 −1.263 3 ± 0.191 4 < 0.01 Age (years old) 0.222 3 ± 0.055 0 < 0.01 0.273 4 ± 0.039 9 < 0.01 Age squared −0.015 8 ± 0.003 4 < 0.01 0.016 2 ± 0.002 4 < 0.01 Sex groups Female dogs 0.229 0 ± 0.084 7 < 0.01 – Neuter status Neutered dogs 0.109 6 ± 0.123 7 0.10 0.331 8 ± 0.100 3 < 0.01 Breed body size groups Large −0.091 3 ± 0.059 9 < 0.01 0.484 9 ± 0.427 4 0.16 Medium −0.050 6 ± 0.047 3 −0.784 9 ± 0.425 6 Small 0.034 6 ± 0.033 4 0.422 0 ± 0.217 0 Unknown† 0.004 1 ± 0.447 0 −0.074 3 ± 0.432 3 Population density (people/km2) – −0.000 1 ± 0.000 0 0.04 Age × breed body size groups Large – −0.098 0 ± 0.042 7 < 0.01 Medium – 0.087 5 ± 0.041 3 Small – −0.058 0 ± 0.022 0 Unknown† – −0.020 6 ± 0.037 0 Neuter status × breed body size groups Large with neutering 0.134 0 ± 0.400 0 0.06 −0.291 9 ± 0.311 4 0.02 Medium with neutering −0.523 3 ± 0.307 4 0.216 1 ± 0.293 3 Small with neutering 0.363 2 ± 0.225 2 −0.327 2 ± 0.155 7 Unknown with neutering† 0.575 7 ± 0.399 6 0.596 4 ± 0.308 1 Clinic variance 0.510 0 ± 0.093 0 0.260 0 ± 0.093 0 ICC (%) 15.5 7.9 - ∗: Sampling year is not shown in the table; †: Unknown group consisted of mixed breed dogs.
- Figure 1.
Estimated probability of dogs being obese or overweight at different age.
- Table 3. Comparisons between characteristic variables for the probability of dogs being obese or overweight.
Explanatory variables
Probability of dogs being obese∗
Odds ratio (95% confidence interval) P-value Probability of dogs being overweight†
Odds ratio (95% confidence interval) P-value N Mean ± SE‡ (%) N Mean ± SE (%) Sex group Male dogs 2 459 15.8 ± 1.1b Reference 2 125 44.8 ± 1.6 Reference Female dogs 2 770 13.0 ± 1.0a 1.3 (1.1–1.5) < 0.01 2 310 43.1 ± 1.7 1.1 (0.9–1.2) 0.29 Neuter status group Intact dogs 1 756 15.7 ± 1.0 Reference 1 523 39.4 ± 2.2b Reference Neutered dogs 3 473 13.0 ± 1.4 1.2 (0.9–1.6) 0.10 2 912 48.5 ± 1.6a 1.4 (1.2–1.8) < 0.01 Breed body size groups Large 305 11.4 ± 2.2bc 0.7 (0.4–1.0) 0.07 265 36.4 ± 3.8 0.6 (0.8–1.4) 0.75 Medium 408 21.3 ± 2.5a 1.4 (1.1–1.9) 0.03 324 43.5 ± 3.5 0.8 (0.6–1.1) 0.19 Small 1 676 9.7 ± 0.9c 0.6 (0.4–0.7) < 0.01 1 495 42.5 ± 3.4 0.8 (0.7–0.9) < 0.01 Toy 2 696 16.0 ± 1.0b Reference 2 249 48.2 ± 1.6 Reference Unknown§ 397 15.4 ± 2.6bc 1.0 (0.6–1.5) 0.82 324 49.5 ± 1.4 1.1 (0.8–1.4) 0.54 - ∗: The remaining records (5 605) were treated as missing values; †: Dogs with BCS 5 were excluded, and the remaining records (4 761) were treated as missing values; ‡: Mean and SE were estimated by mixed-effects multivariable models; §: Unknown group consisted of mixed breed dogs; a–c: Within a column different letters are significantly different (P < 0.05).
Breed body size groups were associated with obesity (P < 0.01; Table 2), but not for being overweight (P = 0.16; Table 2). Medium sized dogs were 1.4 times more likely to be obese than toy sized dogs (odds ratio = 1.4; P = 0.03; Table 3).
In addition, there was a two-way interaction between dog age and breed
body size groups for the probability of dogs being overweight (P < 0.01; Table 2).
In toy sized dogs, the probability of dogs being overweight increased
from 33.4% to a peak of 55.1% as dog age rose from 1 to 8 years old (Figure 2).
Also, in medium sized dogs, the probability of dogs being overweight
increased from 19.5% to a peak of 48.9% as dog age rose from 1 to 10
years old.
- Figure 2.
Estimated probability of dogs in different breed body size groups being overweight at different age.
Neuter status was associated with being overweight (P < 0.01; Table 2), but not with obesity (P = 0.10). Neutered dogs were 1.4 times (odds ratio = 1.4; P < 0.01; Table 3)
more likely to be overweight than intact dogs. There was a two-way
interaction between neuter status and breed body size groups for the
probability of dogs being obese (P = 0.06; Table 2). Neutered small sized dogs were more likely to be obese than intact small sized dogs (P < 0.05; Table 4).
In intact dogs, medium sized dogs were more likely to be obese than the
other sized dogs. However, for neutered dogs, there were no differences
in the probabilities of large, medium, small and toy sized dogs being
obese (Table 4).
Also, there was a two-way interaction between neuter status and breed
body size groups for the probability of dogs being overweight (P = 0.02; Table 2). Neutered medium, small and toy sized dogs were more likely to be overweight than respective sized intact dogs (P < 0.05; Table 4). For intact dogs, there were no differences between breed body size groups for the probability of dogs being overweight (P ≥ 0.10), whereas for neutered dogs, the small and toy sized dogs were more likely to be overweight than large sized dogs (P < 0.05).
There was an association between overweight dogs and the population
density of the cities where the clinics were located (P = 0.04; Table 2), although there was no such association between obese dogs and city population density (P = 0.20).
- Table 4. Comparisons between neuter status and breed body size groups for the probability of dogs being obese or overweight.
Probability of dogs Breed body size groups Intact dogs
Neutered dogs
N Mean ± SE∗ (%) N Mean ± SE (%) Being obese Large 91 10.2 ± 3.3bc 196 12.7 ± 2.5b Medium 135 24.9 ± 4.2a 242 18.0 ± 2.6ab Small 586 7.8 ± 1.2cy 965 11.9 ± 1.2bx Toy 806 15.3 ± 1.4bc 1 727 16.8 ± 1.1ab Unknown† 90 11.5 ± 3.6bc 277 20.4 ± 2.7a Being overweight‡ Large 81 35.9 ± 5.7 168 36.8 ± 3.7d Medium 103 36.9 ± 5.4y 194 47.6 ± 4.0cx Small 538 42.4 ± 2.4y 848 50.3 ± 3.9cx Toy 680 44.1 ± 2.1y 1 427 52.4 ± 1.5bx Unknown† 80 38.1 ± 6.0y 218 60.9 ± 3.7ax - ∗: Mean and SE were estimated by mixed-effects multivariable models; †: Unknown group consisted of mixed breed dogs; ‡: Dogs with BCS 5 were excluded; a–c: Within a column different letters are significantly different (P < 0.05); x,y: Within a row different letters are significantly different (P < 0.05).
Miniature
Dachshunds had the highest percentage in obese dogs, whereas Chihuahuas
had the highest percentage in overweight dogs. A Chi-square
test also showed that there were clear differences in the percentages of
obese or overweight dogs between different breeds (P < 0.05; Table 5).
Finally, the ICC showed that the clinic effect explained 15.5% and 7.9%
of the total variation for the respective probabilities of dogs being
obese or overweight.
- Table 5. Top 10 breeds with the highest percentages of obese or overweight dogs out of 103 breeds studied∗.
Rank Obese dogs
Overweight dogs
Breeds N % Breeds N % 1 Miniature Dachshund 355 29.3 Chihuahua 260 61.2 2 Chihuahua 362 28.2 Pomeranian 195 55.9 3 Pembroke Welsh Corgi 58 25.9 Miniature Dachshund 251 54.6 4 Beagle 130 26.2 Mongrel 324 54.0 5 Shiba Inu 165 24.2 Shih Tzu 443 53.1 6 Labrador Retriever 79 22.8 Beagle 96 53.1 7 Mongrel 397 18.4 Shiba Inu 125 52.0 8 Pomeranian 232 16.0 Maltese 178 48.3 9 Shih Tzu 521 15.0 Yorkshire Terrier 236 46.2 10 Cavalier King Charles Spaniel 132 14.4 Miniature Schnauzer 659 43.1 - *: Only selected breeds with more than 60 dogs.
4. Discussion
The
present study quantified the effects of increased age on dogs being
obese or overweight, and showed that the effects differed between breed
body size groups for overweight dogs. It also showed that the
probability of dogs being obese or overweight decreased from middle age
in dogs of all sizes. Increasing age is related to decreasing physical
activity, lean body mass and maintenance energy requirements [16] and [17].
It appears that energy intake in some young to middle aged dogs of all
sizes is not being managed appropriately by their owners. The decline
from middle age in the probability of dogs in our study being obese or
overweight might be explained by a decline in the appetite of dogs aged 7
years or older, as was found in a previous study [17].
Another possible reason is that dogs of middle age or older are more
likely to have unrecorded chronic disease that reduces their digestive
capability and causes moderate weight loss.
Furthermore,
our study suggests that the changes with age in appetite, energy
requirements and energy expenditure also depend on dog body size and
breed [18].
Our study revealed that medium sized dogs, including Beagles and
Corgis, were 1.4 times more likely to be obese than toy sized dogs. Both
Beagles and Corgis had 20% or more obese dogs in our study. These
findings are consistent with another study that reported Beagles being
prone to obesity [5].
The breed differences of being obese appear to be related to genes
related to fat metabolism which are hypothesized to be due to the breed
selection process in dogs [19] and [20].
The high odds ratios of female dogs being obese in our study are consistent with the results of a previous study [9].
Also, our study indicated that neutering accentuates the propensity for
medium, small and toy sized dogs to be overweight and accentuates the
propensity for small sized dogs to be obese. This could be explained by
the fact that neutering appears to cause a reduced metabolic rate [17].
Neutering predisposes dogs to having excessive body weight by reducing
the concentrations of androgens and estrogens that act as satiety
factors in the central nervous system [3].
Our
study showed characteristic factors, including breeds, for obese dogs
were not completely same as for overweight dogs. A previous study
analyzing specific diseases related to obese and overweight dogs found
some differences between obesity and being overweight for diseases [5].
For example, diabetes mellitus was associated with obesity but not with
being overweight, whereas hyperadrenocorticism (Cushing's disease) was
related to being overweight but not with obesity [5]. Being overweight may be a symptom different from obesity, and may have slightly different characteristics from obesity [7].
Also, our study indicates that breed and genetics differently affect
the propensity of dogs being obese or overweight, as shown by the
differences in the percentages of obese or overweight dogs between the
10 highest risk breeds. This could explain some of the difference in
characteristics for being obese or overweight.
Our
study showed the population density of the city where the dogs' clinics
were located was associated with the probability of dogs being
overweight, but not with the probability of them being obese.
Previously, an Australian study using a three-point scale system
(underweight, correct-weight or overweight) reported that dogs living in
rural and semi-rural areas were at greater risk of being overweight
than urban dogs, due to high amounts of feeding and less exercise time [4] and [8].
The similar results in the two studies suggest that in Japan there is a
difference in the lifestyles of dogs and their owners between rural and
densely populated areas.
Our
study is the first report indicating relatively large differences
between clinics in the probability of dogs being obese or overweight, as
indicated by the respective ICCs of 15.5% and 7.9% for clinic variance
in the probability of dogs being obese and overweight. This suggests
that there are relatively large explained effects of the clinic in
relation to obese dogs, such as clinic location, dog owner's social
status and veterinarians' guidance for dogs' dietary and exercise
management [21] and [22].
In
conclusion, our study characterized obese or overweight dogs by age,
sex, neutering status and breed body size. This finding could help
veterinarians to improve their advice to owners on how to maintain their
dogs in ideal body condition, by taking age, body size or dog breed,
and neuter status into account.
Finally,
it should be noted that there are some limitations in this present
study. Dogs were not randomly selected because it was a cross-sectional
study using veterinarian-submitted samples from private clinics.
Consequently, there was a lack of information on diseases affecting BCS (e.g.
protein losing nephropathy) because we did not collect specific disease
data except for endocrine diseases. Our study may include dogs with
false positive test results of endocrine diseases, and diseased dogs
which were not tested due to subtle clinical signs. Additionally, the
dogs' rearing environments and nutrition were not taken into account in
the analyses. The level of agreement between the BCS evaluations
conducted by the participating veterinarians was not evaluated. However,
our statistical models included the clinic as a random effect. Even
with such limitations, this research provides valuable information for
veterinarians about the risk factors related to dog obesity and being
overweight.
Conflict of interest statement
We declare that we have no conflict of interest.
Acknowledgments
The
authors gratefully thank the cooperating veterinarians for providing
their data for use in the present study. We also thank Dr. I. McTaggart
for his critical review of this manuscript. This work was supported by
the Research Project Grant (Giken 2012–2016 A) from Meiji University.
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