Vitamin A is an essential fat-soluble vitamin that has functions supporting vision, bone growth, reproduction, cellular differentiation and immune response in dogs(Reference Goldy, Burr and Langardener1). The dog, unlike non-carnivorous species such as humans or rodents, transports vitamin A in the plasma predominantly in the form of retinyl esters, in both adequate and vitamin A-deprived states(Reference Wilson, Hejazi and Elstad2). In human subjects, retinyl esters are only detected in the plasma in cases of intoxication or following a vitamin A-rich meal(Reference Schweigert and Bok3). The concentrations of retinol found in dog serum are unaffected by dietary vitamin A intake, whereas the concentrations of serum retinyl esters have been shown to parallel the concentrations of vitamin A in the diet(Reference Schweigert and Bok3). In the dog, excess vitamin A is stored in esterified form in lipid droplets contained within the hepatic stellate cells as well as the kidneys(Reference Raila, Buchholz and Aupperle4). In addition to the unusual mechanism of vitamin A transport, dogs, unlike humans(Reference Lawrie, Moore and Rajagopal5), excrete vitamin A in the urine(Reference Worden, Bunyan and Davies6) as both retinol and retinyl esters(Reference Schweigert, Thomann and Zucker7).
As a result of the species differences in metabolism and excretion, data from other species cannot be used to establish a dietary safe upper limit for retinol inclusion in the diets of growing dogs. Some studies in dogs, however, do exist. In growing dogs (10–12 months of age), prolonged activated prothrombin time, although not to levels outwith the reference range, and elevated retinol binding protein concentrations have been reported following feeding a diet containing 131·00 μmol retinol (125 000 IU vitamin A)/4184 kJ (1000 kcal) metabolisable energy (ME) for a period of 26 weeks potentially resulting from an interaction with vitamin K(Reference Goldy, Burr and Langardener1). Exceptionally high dietary intakes (>576·42 μmol retinol (550 000 IU vitamin A)/4184 kJ (1000 kcal) ME) were associated with severe side effects including reduced energy intake, reduced growth rates, pain responses in the carpal and tarsal joints as well as abnormal bone development and premature closure of the epiphyseal plate(Reference Frohring8–Reference Wiersig and Swenson10). These adverse effects are potentially a result of interactions with vitamin D, as one study reported a reduction in the severity of effects when retinol was co-administered with vitamins D and E(Reference Cho, Frey and Guffy11). Much lower concentrations (10·48 μmol retinol (10 000 IU vitamin A) kg/body weight) fed to three Cocker Spaniels from weaning to 10 months of age had no apparent adverse effects(Reference Hendricks, Morgan and Freytag12).
The lack of published studies involving retinol concentrations above 10·48 μmol retinol (10 000 IU vitamin A)/kg body weight that have not observed adverse effects may explain the disparity in recommendations among key nutrition authorities. The National Research Council(13) recommends a safe upper limit of 13·10 μmol retinol (12 500 IU vitamin A)/4184 kJ (1000 kcal) for growing dogs, the American Association of Feed Control Officials(14) recommends 74·86 μmol retinol (71 429 IU vitamin A)/4184 kJ (1000 kcal) and the Federation Européenne de l'Industrie des Ailments pour Animaux Familiers (FEDIAF)(15) recommends 104·80 μmol retinol (10 000 IU vitamin A)/4184 kJ (1000 kcal). The purpose of the present study was to examine the effect on puppies of feeding four concentrations of vitamin A from weaning until 12 months of age. The hypothesis tested was that feeding dietary retinol concentrations up to 104·80 μmol retinol (10 000 IU vitamin A)/4184 kJ (1000 kcal) to puppies during growth does not result in a statistically significant change in biomarkers associated with health.
Experimental methods
The research protocol was evaluated and approved by the WALTHAM® Internal Ethics Committee. The study was a randomised, blinded, parallel design. A total of forty-nine puppies, from eight litters, born at the WALTHAM Centre for Pet Nutrition were entered into the study. The puppies were of two breeds, Labrador Retrievers (LR) and Miniature Schnauzers (MS). Dogs were housed in litter groups with their mother until 8 weeks of age and subsequently in pairs, in purpose-built, environmentally enriched kennels with free access to outdoor areas. The puppies could interact with other dogs in paddock groups, and all puppies participated daily in supervised group and individual exercise, training and socialisation. The puppies were habituated to all procedures from 4 weeks of age.
Diet and feeding
The base diet was a standard dry commercial recipe (Perfect Fit Junior; Mars GmbH) compliant with FEDIAF 2008 recommendations(15) for growth and reproduction (Table 1). For each group, ten batches of the diet were used throughout the study. The predicted ME content of the diet was calculated according to the National Research Council(13).
PME, predicted metabolisable energy.
* PME calculated according to the National Research Council (13).
The maternal bitch was fed the base diet throughout lactation until the puppies were fully weaned to the base diet at 6 weeks of age. For 7 d following weaning (week 6–7), the puppies were group fed the base diet three times daily. For the following 7 d (week 7–8), the puppies were individually fed the base diet for three, 1 h periods daily. Feeding amounts were calculated from amounts consumed during the previous week and adjusted weekly for the remainder of the study with the aim of maintaining puppies on standard growth curves with ideal body condition scores(Reference Hawthorne, Booles and Nugent16, Reference German, Holden and Moxham17). At 8 weeks of age, puppies were randomised within litter, to one of four dietary concentrations of vitamin A, namely: group A 5·24 μmol retinol (5000 IU vitamin A)/4184 kJ (1000 kcal) ME; group B 13·10 μmol retinol (12 500 IU vitamin A)/4184 kJ (1000 kcal) ME; group C 78·60 μmol retinol (75 000 IU vitamin A)/4184 kJ (1000 kcal) ME; group D 104·80 μmol retinol (100 000 IU vitamin A)/4184 kJ (1000 kcal) ME. For the following 18 weeks (week 8–26), the puppies were offered their respective diet for a period of 45 min at 08.30, 12.30 and 15.30 hours. For the final 26 weeks of study (week 26–52), the puppies were offered their daily ration in two meals at 08.30 and 15.30 hours. Puppies were given free access to drinking-water at all times.
Vitamin A supplementation
The base diet was supplemented to achieve the required level of vitamin A by the addition of retinyl acetate (DSM Nutritional Products Limited) diluted to the required concentration in vegetable oil. Stock solutions were prepared weekly for each group according to the manufacturer's instructions and were refrigerated in light-proof bottles under N2 until required. Individual supplements were prepared in 1 ml syringes from the stock solution and kept refrigerated in light-proof containers before being added to the diet at a ratio of 1 ml supplement/100 g of diet immediately before feeding and mixed thoroughly. A 1 ml aliquot of each stock solution was analysed within 48 h of the stock solution preparation for retinyl acetate concentrations using modified gradient reversed-phase HPLC analysis(Reference Schweigert and Bok3) to allow for the calculation of actual vitamin A intake.
Measurement of food intake and body weight
Food intake was recorded immediately following each meal as the difference between the mass of food presented and the mass of food returned (Sartorius UK Limited). Body weight was recorded weekly using calibrated scales (Sartorius UK Limited) immediately before the first meal of the day. Although not fully validated in puppies, the body condition score was conducted weekly (WALTHAM S.H.A.P.E. guide(Reference German, Holden and Moxham17)), immediately before feeding.
Blood sample analysis
A 2·8 ml blood sample was taken from a jugular vein following an overnight fast of at least 16 h at week 8, before dietary supplementation, and at weeks 10, 12, 14, 16, 20, 26, 35 and 52. Blood samples were collected into a single syringe and immediately distributed between tubes containing either tripotassium EDTA, lithium heparin or no anticoagulant.
For biochemical analysis, 0·5 ml of blood were deposited into a tube containing lithium heparin as an anticoagulant. The tube was mixed gently for 10 s before being stored on ice for a maximum of 30 min. The sample was then centrifuged at 2000 g for 10 min at 4 °C. The resultant plasma was pipetted into an AU400 sample cup before automated colorimetric analysis (Olympus AU400; Olympus, Inc.) for concentrations of total protein, albumin, alkaline phosphatase, aspartate aminotransferase, alanine aminotransferase, total cholesterol, urea, creatinine, Ca, phosphate, TAG, glutamate dehydrogenase and total bile acids.
For haematological analysis, a 0·2 ml blood sample was deposited into a tube containing tripotassium EDTA as an anticoagulant. This was gently mixed on a roller for 10 min at room temperature before automated analysis for leucocyte count, erythrocyte count, Hb concentration, haematocrit, platelet count, mean corpuscular volume, mean corpuscular Hb, mean corpuscular Hb concentration, number and percentage of lymphocytes, monocytes and granulocytes (ABC, Scil Vet).
For retinol and retinyl esters, the remaining 2·1 ml blood sample was deposited into a light-proof tube containing no anticoagulant. The tube was placed in an upright position for 90 min at room temperature, to allow clot formation, before centrifugation at 2000 g for 10 min at room temperature. The resultant serum was pipetted into 1·5 ml light-proof Eppendorf tubes, frozen at − 80 °C, shipped overnight on ice and stored at − 80 °C for a maximum of 30 d before analysis using modified gradient reversed-phase HPLC analysis, as described elsewhere(Reference Schweigert and Bok3), to determine the concentrations of retinol, retinyl oleate, retinyl stearate and retinyl palmitate. The total retinyl ester concentration was calculated as the sum of retinyl oleate, retinyl stearate and retinyl palmitate concentrations.
For bone turnover assessment, the remainder of the serum sample used for retinol and retinyl ester analyses was used to measure cross-linked carboxyterminal telopeptides of type I collagen (CTx) concentrations, as an indicator of bone resorption, using a commercial ELISA (Serum CrossLaps ELISA; IDS). Serum bone-specific alkaline phosphatase activity, as an indicator of osteoblastic activity, was measured with a commercial ELISA assay (Osteomedical).
Urine samples
At 1 d before blood sampling, a 1·2 ml urine sample was collected following a 16 h fast between the hours of 08.00 and 10.00 by a free-catch method. If a urine sample could not be obtained on the first day of sampling, the process was repeated on the following day before blood sampling. The samples were placed in light-proof Eppendorf tubes, and then stored, shipped and analysed for retinol and retinyl esters as described above.
Bone mineral density and bone mineral content
Bone mineral density (BMD) was assessed at 26 and 52 weeks of age by means of dual-energy X-ray absorptiometry (DXA, total body software package, Lunar Hologic QDR-1000W; GE Healthcare). Dogs were sedated following a minimum 16 h fast, with a combination of Torbugesic (0·3 mg/kg; Pfizer Animal Health), Medetomidine (MS: 20 μg/kg, LR: 5 μg/kg; Pfizer Animal Health) and Midazolam (MS: 0·25 mg/kg, LR: 0·20 mg/kg; Roche Limited), and reversed with Atipamezole (0·1 mg/kg; Pfizer Animal Health).
Clinical examinations and adverse event reporting
The puppies underwent physical examination before the start of the trial and every 4 weeks thereafter. Particular attention was paid to signs of joint or muscle pain. In addition, any illness or injury between the examinations that required veterinary attention was considered an adverse event. Adverse events were classified into ten categories, namely: poor faeces quality, vomiting, foreign body ingestion, lameness, accident/injury, skin conditions, eye conditions, ear conditions, dental conditions and urinary conditions. On each occasion, the type and duration of treatment were recorded. Any blood parameters outside of the puppy reference range(Reference Harper, Hackett and Wilkinson18) were referred to the veterinarian for investigation and re-tests were conducted within 24 h and repeated as required for diagnosis. The veterinarian was blinded to the dietary treatment groups.
Data analysis and statistics
The primary outcome variable was total serum retinyl ester concentration. Retinyl ester concentration was selected as the primary outcome variable to demonstrate a biological impact of feeding various levels of retinol to growing dogs. The study was powered at 90 % to detect differences between the groups based on a previously described log-linear relationship between dietary vitamin A intake and serum retinyl ester concentration(Reference Schweigert and Bok3). The power calculation determined a minimum of nine dogs per group; this was increased to eleven to account for potentially greater variability in puppies compared with adult dogs. Following the conclusion of the study, post hoc power analyses were conducted on each of the safety biomarkers to determine whether there was sufficient power (>80 %) to detect a clinically relevant effect size with the variation associated with the dataset. A clinically relevant change was defined as a change from the mean of each variable to a mean outside the reference range(Reference Harper, Hackett and Wilkinson18).
Data were analysed by means of linear mixed model analysis including the fixed terms sample number, sex, breed and dietary group, and also the baseline measurement of the variable being modelled. The model included the random terms dog and litter (to take account of possible similarities between littermates), with a correlation between successive samples (within an individual dog) accounted for via use of an appropriate correlation structure (determined using graphical methods of residuals from a model with identity correlation structure). Where necessary, data were loge transformed to improve the distribution of the data, as assessed by residual plots. Non-significant terms were removed from the model. Data analyses were performed using R.2.10.1 (R Foundation for Statistical Computing).
All primary and secondary endpoints were separately subjected to Bonferroni correction to account for the presence of multiple endpoints; the overall significance level used was 0·05. Data are presented as means with their 95 % CI unless otherwise stated, and P values are reported as Bonferroni-corrected P values.
Results
Population demographics
The study population demographics are described in Table 2. A total of forty-eight dogs completed the study. A total of forty-eight dogs completed the study. A single LR, allocated to group C, was removed from the study at 9 months of age following diagnosis of a congenital kidney defect. All data from this dog were removed from the analysis. There were no differences in breed or sex distribution between the groups.
MS, Miniature Schnauzer; LR, Labrador Retriever.
* Group A, 5·24 μmol retinol (5000 IU vitamin A)/4184 kJ (1000 kcal) metabolisable energy (ME); group B, 13·10 μmol retinol (12 500 IU vitamin A)/4184 kJ (1000 kcal) ME; group C, 78·60 μmol retinol (75 000 IU vitamin A)/4184 kJ (1000 kcal) ME; group D, 104·80 μmol retinol (100 000 IU vitamin A)/4184 kJ (1000 kcal) ME.
Dietary intake and growth
There were no significant differences in energy intake on a per kg body weight or per kg metabolic body-weight basis between the groups. As intended, there were significant differences in dietary vitamin A intake between the groups (P = 0·0001). When expressed on a per kg body-weight basis (P = 0·0001) and on a per kg metabolic body-weight basis (P = 0·0001) (Fig. 1), both vitamin A and energy intake significantly decreased over time with maximal intake recorded at week 8. Body weight significantly increased in all groups with time (P = 0·0001; Fig. 2), and all dogs maintained an ideal body condition score (score D) throughout the trial. There were no significant differences in body weight between the groups at any time point (P = 1·00) nor any significant differences in the rate of growth (P = 1·00). There was a significant effect of breed, with LR having significantly higher body weights than MS (P = 0·0008).
Blood sample analysis
There were no significant differences in any of the haematological or biochemical parameters between the groups at any time point. However, some variables (Table 3), namely erythrocyte count, mean corpuscular volume, mean corpuscular Hb, mean corpuscular Hb concentration, mean platelet volume, number of monocytes, number of granulocytes, alanine aminotransferase, aspartate aminotransferase, alkaline phosphatase and cholesterol, showed statistically significant changes with age. Bone-specific alkaline phosphatase significantly decreased (P = 0·0001) and cross-laps (CTx) significantly increased (P = 0·0001) with age. There were no significant differences, however, in the concentrations of bone-specific alkaline phosphatase (P = 1·00) or CTx (P = 1·00) between any of the groups at any time point.
ALP, alkaline phosphatase; ALT, alanine aminotransferase; AST, aspartate aminotransferase; GLDH, glutamate dehydrogenase; bALP, bone-specific ALP; CTx, carboxyterminal telopeptides of type I collagen.
* Data were analysed via mixed model.
† 5·24 μmol retinol (5000 IU vitamin A)/4184 kJ (1000 kcal) metabolisable energy (ME).
‡ 13·10 μmol retinol (12 500 IU vitamin A)/4184 kJ (1000 kcal) ME.
§ 78·60 μmol retinol (75 000 IU vitamin A)/4184 kJ (1000 kcal) ME.
∥ 104·80 μmol retinol (100 000 IU vitamin A)/4184 kJ (1000 kcal) ME.
¶ Significance of difference between the treatment groups (Bonferroni corrected).
Both serum retinol (P = 0·0001) and serum total retinyl ester concentrations (P = 0·015) increased with time. There was no significant difference in serum retinol concentration between the groups (P = 1·00), whereas total retinyl ester concentrations were significantly different (Fig. 3) between each group and all the other groups at all time points (P = 0·0001) with the exception of baseline (week 8).
Urine sample analysis
Excretion of retinol and retinyl esters in the urine was negligible up to 26 weeks of age and was not consistently detected until 35 weeks of age (Fig. 4). There were no significant differences in the time to excretion of retinol (P = 1·00) or retinyl esters (P = 1·00) between the groups nor were there differences between the groups in concentrations of retinol (P = 1·00) and retinyl esters (P = 1·00) excreted at weeks 35 and 52.
Bone mineral density and bone mineral content
There was no significant effect of dietary vitamin A concentration on BMD (P = 0·137) or bone mineral content (P = 0·936) as assessed by DXA (Table 4). There was a significant effect of breed, with LR having greater BMD (P = 0·0001) and bone mineral content (P = 0·0020) than MS at both time points.
MS, Miniature Schnauzer; LR, Labrador Retriever.
* Data were analysed via mixed model.
† 5·24 μmol retinol (5000 IU vitamin A)/4184 kJ (1000 kcal) metabolisable energy (ME).
‡ 13·10 μmol retinol (12 500 IU vitamin A)/4184 kJ (1000 kcal) ME.
§ 78·60 μmol retinol (75 000 IU vitamin A)/4184 kJ (1000 kcal) ME.
∥ 104·80 μmol retinol (10 000 IU vitamin A)/4184 kJ (1000 kcal) ME.
¶ Significance of difference between the treatment groups (Bonferroni corrected).
Clinical examination and adverse events
There were no significant differences between the treatment groups in the number and type of adverse events reported. Poor faeces quality was the most commonly reported adverse event (n 22), with twenty individual dogs affected. All cases were resolved within 3 d. In LR, two cases of lameness without apparent cause were observed, one in group A and one in group C; both cases were resolved following treatment in less than 7 d.
Discussion
The hypothesis tested was that feeding dietary vitamin A at concentrations up to 104·80 μmol retinol (100 000 IU vitamin A)/4184 kJ (1000 kcal) ME to puppies during growth would not result in any significant changes in biomarkers associated with health.
No significant differences were found in any of the biomarkers of health including biochemical markers or haematological parameters. Previous data from human subjects and other animal species indicate that excess vitamin A is associated with a stimulation of bone resorption and an inhibition of bone formation leading to a reduction in BMD potentially resulting from interactions between vitamins A and D(Reference Cho, Frey and Guffy11). No significant differences were found in the biomarkers of these processes namely bone-specific alkaline phosphatase and CTx, and there was no significant effect of dose on either BMD or bone mineral content as assessed by DXA. There are no specific studies examining the interaction between vitamins A and D in the dog. In rats and broiler chickens, biochemical studies have suggested an antagonism between vitamins A and D at the receptor level(Reference Rohde, Manatt and Clagett-Dame19, Reference Aburto, Edwards and Britton20) as well as an interaction with Ca-regulating hormones such as parathyroid hormone(Reference Lui, Hellman and Li21). There was no significant effect of dietary vitamin A concentration on plasma Ca or P levels, which suggests that vitamin D deficiency did not occur, although the levels of cholecalciferol in the diet were approximately three times the FEDIAF's recommended allowance(15). Further studies are required to understand whether there is an interaction between vitamins A and D in the dog and if so, at which dietary concentrations an interaction occurs.
Feeding high levels of retinol has also been shown to prolong activated prothrombin time in the dog, although not outwith the reference range(Reference Goldy, Burr and Langardener1). This is potentially due to the interactions with vitamin K. Activated prothrombin time was not directly measured in the present study; however, no signs of clinical vitamin K deficiency such as increased bleeding tendency were observed.
Unlike previous studies in young dogs fed much higher dietary concentrations of vitamin A (314·41 μmol retinol (300 000 IU vitamin A)/kg body weight)(Reference Maddock, Wolbach and Maddock9), there were no differences in the rate of growth, energy intake or body weight at any time between the groups. No differences in the number, type or duration of adverse effects were observed and those that were observed could not be attributed to the variation in dietary vitamin A concentration. The present study was limited to the first 52 weeks of life and suggests that dietary vitamin A at the concentrations tested is safe to feed during this growth phase.
As with observations in adult dogs(Reference Schweigert and Bok3), increased dietary retinol concentration was associated with increased serum retinyl ester concentrations (Fig. 3) but not with serum retinol concentrations. Until 26 weeks of age, the concentrations of retinol observed in the present study were significantly lower than concentrations previously reported in adult dogs(Reference Schweigert and Bok3). This observation is consistent with previous reports of increasing concentrations of retinol in the serum of maned wolf cubs with age that reached adult concentrations at approximately 5 months of age(Reference Schweigert, Ryder and Rambeck22).
Unlike observations in adult dogs, however, the puppies excreted negligible amounts of retinol and retinol esters in the urine (Fig. 4). The excretion of these compounds appears to be age dependent rather than as a result of storage capacity, as there was no difference between the groups in time to excretion or total amounts of the compounds excreted despite a 20-fold difference in the doses fed. Previous research in adult dogs(Reference Raila, Buchholz and Aupperle4) suggested that excess dietary vitamin A is stored in the stellate cells of the liver but in the present study, we were unable to confirm whether, and how, vitamin A was stored in the liver of puppies since this would have required serial liver biopsies to determine the effect of time. Liver biopsies were not included in the protocol due to the host institution's ethical policy. The lack of retinol and retinyl ester excretion in the urine until 35 weeks of age certainly requires further investigation. Examination of the proteins known to be involved in retinyl ester transport and excretion such as retinal-binding protein and Tamm–Horsfall-like protein(Reference Schweigert, Raila and Haebel23) may provide an insight into the mechanism behind this age-dependent effect.
In summary, no adverse effects were detected with feeding dietary vitamin A at concentrations up to 104·80 μmol retinol (10 000 IU vitamin A)/4184 kJ (1000 kcal) to MS and LR puppies from 8 weeks to 12 months of age. We therefore propose that 100 000 IU vitamin A/4184 kJ (1000 kcal) is a suitable safe upper limit for use in the formulation of diets designed for puppy growth.
Acknowledgements
This study was jointly funded by the FEDIAF and Mars PetCare™. The authors wish to recognise Karen Holmes, Gaëlle Thomas and Amelia Wagstaff for their dedicated participation in the running of this study. All authors were involved in the design and oversight of the study. P. J. M. was responsible for the conduct of the study. J. R. and F. J. S. were responsible for the analysis of vitamin A metabolites and bone turnover markers. C. S. performed the statistical analyses. P. J. M. wrote the paper and all authors were responsible for the final manuscript. Conflicts of interest: P. J. M., C. S. and T. B. are employees of Mars PetCare™.