Agricultural and Food Science in Finland 185 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. Effects of group size and space allocation on physiological, behavioural and production-related welfare parameters in farmed silver fox cubs Leena Ahola, Jaakko Mononen, Teija Pyykönen, Maarit Mohaibes Institute of Applied Biotechnology, University of Kuopio, PO Box 1627, FIN-70211 Kuopio, Finland, e-mail: leena.ahola@uku.fi Teppo Rekilä MTT Agrifood Research Finland, Animal Production Research, FIN-69100 Kannus, Finland Traditionally farmed silver fox cubs are raised after weaning either in pairs or singly in a traditional fox cage (1.2 m2). However, this way of housing foxes has been criticised because the foxes may have limited chance to exercise and to show social behaviour. Therefore, the aim of the present study was to evaluate the effects of different social and spatial conditions on the welfare of silver fox cubs. The cubs were housed singly, in pairs or in quartets with space allocation of either 0.6 or 1.2 m2 per animal. Behavioural, physiological and production-related welfare parameters were assessed. The results revealed that space allocation had only minor effects on the measured welfare related param- eters. With regard to social conditions, the results showed that the possibility for social behaviour is important for the welfare of young cubs. However, the welfare of the cubs may be jeopardised if they are kept in quartets beyond their natural dispersal time. Therefore, the welfare of silver fox cubs could be enhanced by allowing the cubs to enjoy of social companionship during the first months of their lives and by separating them into pairs in later autumn. Key words: animal welfare, behaviour, fur farming, group size, physiology, space allocation, Vulpes vulpes © Agricultural and Food Science in Finland Manuscript received May 2002 Introduction One of the most efficient ways to enrich the en- vironment of farmed animals is to increase ani- mals’ possibilities for social behaviour (see Mendl and Newberry 1997). This beneficial role of social enrichment might be presumed to be in agreement also with farmed silver foxes (Vulpes vulpes): although in nature red foxes (Vulpes vulpes) have been viewed as rather solitary (see Cavallini 1996), they are also found in social groups that consist of a dominant male and one to five subordinate females, often related to each other (Macdonald 1983). Enhancing the social richness of the housing mailto:leena.ahola@uku.fi 186 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Ahola, L. et al. Effects of group size and space allocation in silver for cubs environment does not include only the compan- ionship of conspecifics but also an enlargement of the total living space for the members of the group if complying with the minimum space re- quirements for the species (e.g. 1.2 m2 for a pair of farmed juvenile foxes after weaning and an additional 0.5 m2 for each additional animal, European Convention 1999). This enlargement of the total space, further, provides the animals with an increased opportunity for physical exer- cise. In farmed silver foxes, only a few experi- ments in cage environment have been conducted to investigate whether a housing system with more than one or two foxes in the same living area could represent a potential housing sys- tem for this species. Bakken et al. (1994) re- port a study where one, two, four or eight sil- ver foxes were housed with a density of one animal per m2. No data was available on wheth- er the foxes within the group were related to each other. In larger groups, there were some problems with animals being bitten. On the oth- er hand, group housed foxes had a better growth rate and were more active. In two other studies (Ahola et al. 1996, Ahola and Mononen 2002), silver foxes were housed in family groups, e.g. a vixen together with its cubs and compared to housing silver foxes in sibling pairs. No clear effects of the housing system on body weight of the cubs were found but the family-housed foxes had more injuries than the foxes housed in pairs, especially when space allocation for the individuals within the group was diminished (Ahola et al. 1996). It was also noted that ag- gressive behaviour between the family mem- bers and the number of cages occupied simul- taneously by the family members increased with advancing autumn, i.e. the foxes tended to stay apart from one another (Ahola and Mononen 2002). The present study focused on exploring the behavioural, physiological and production-relat- ed effects of different group sizes (one, two or four fox cubs per group) and different space al- locations (0.6 or 1.2 m2 per animal) in farmed silver fox cubs housed in a cage environment. Material and methods The approval to conduct the present study was issued by the Institutional Animal Care and Use Committee of the University of Kuopio (Licence number 00-36). Animals and cage constructions A total of 98 silver fox cubs from 35 vixens were included in the study. The cubs were born in tra- ditional fox cages (115 × 105 × 70 cm, L × W × H) in April–May. At the time of weaning, i.e. when the cubs were approximately eight weeks old, they were divided into five different hous- ing systems with different group sizes (1, 2 or 4 animals per group) and different space alloca- tions (1.2 m2 per animal, large, L and 0.6 m2, small, S). The housing systems were: 1) a male or a female cub (siblings) housed singly in a tradi- tional cage (1.2 m2 per animal, L1), 2) a male- female sibling pair housed in a traditional cage (0.6 m2 per animal, S2), 3) a male-female sib- ling pair housed in two traditional cages con- nected together by an opening (20 × 20 cm, W × H) through the walls between the adjacent cages (1.2 m2 per animal, L2), 4) two male and two female siblings housed in two traditional cages connected together by openings (0.6 m2 per ani- mal, S4) and 5) two male and two female sib- lings housed in four traditional cages connected together by openings (1.2 m2 per animal, L4). Each of the cages were furnished with a resting platform (105 × 30 cm, L × W, 25 cm from the cage ceiling) and a feeding tray. The housing units were located in an outdoor fur shed with two cage rows. The number of each housing system was seven. Therefore, seven male and seven female cubs (siblings, from sev- en vixens) were housed singly in 14 traditional cages, 14 sibling pairs (from 14 vixens) were housed either in a system comprising of one cage (seven pairs) or of two cages (seven pairs), and 14 sibling quartets (from 14 vixens) were housed 187 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. either in a system comprising of two cages (sev- en quartets) or of four cages (seven quartets). The animals were fed, according to the rec- ommendations given by The Finnish Fur Breed- ers’ Association, on fresh fur animal feed twice a day until late September, thereafter once a day. The daily feed portion per animal was the same for each group. There was one feeding tray in each traditional (1.2 m2) cage. In groups com- prising of one traditional cage (L1 and S2) feed was delivered onto the only feeding tray. In groups comprising of two (L2 and S4) or four cages (L4) feed was delivered evenly onto two or four feeding trays, respectively. Measured parameters Each housing unit was video-recorded for 24 h in mid-August, at the beginning of October and at the beginning of December, as described in Ahola et al. (2001). Dim red bulbs (25 W) and fluorescent lamps (38 W) covered with red plas- tic film were used to provide dim light for the video-recordings. The behaviour of the animals was analysed from the videotapes using instan- taneous sampling with a 5-min sampling inter- val (Martin and Bateson 1993), i.e. each of the cameras used recorded the behaviour of the ani- mals in one unit approximately for 50-seconds giving 12 behavioural samples per each housing unit per one hour. The behavioural categories for the cubs were 1) active, i.e. moving, standing or sitting and 2) resting, i.e. lying awake or asleep. The activity of the animals was determined sep- arately for the morning hours (0000–0800), working hours (0800–1600) and evening hours (1600–0000). The extent of the use of available cages (L2, S4, L4) and resting platforms were also deter- mined. Group preference index (GPI) for 24-h days in August, October and December was cal- culated for the groups S2, L2, S4 and L4 accord- ing to Gattermann (1990). GPI is a comparative value of a preference for staying in groups com- puted from the paired relations occurring in a group and ranges from 0% (all the animals within a housing unit singly, i.e. not touching each other) to 100% (all the animals within a housing unit together, touching each other). The occurrence of locomotor stereotyped behaviour (i.e. repeated pacing or jumping along the cage wall without any obvious goal or func- tion and performed without the neighbour, du- ration more than 5 seconds) was monitored from the December video-recordings. The feeding test (see Rekilä 1999) was per- formed for the foxes in mid-August, late August, late September, late October and late Novem- ber. To be able to recognise individual foxes they were painted with colorants on furs a day before the test. In the test, the experimenter presented feed on the feeding tray. The feed was placed on the only tray (L1, S2), on the tray of the first cage (L2, S4) and on the second cage of the cage system (L4). During the test, the experimenter stayed in the front of the cage (approximately 0.5 m from the cage wall) for 60 sec and recorded the individuals that were eating during the test. In late October, a 24-h urine was collected from all the housing units, i.e. 42 urine samples were obtained. The samples were stored at –20°C until analysis for cortisol and creatinine. The cortisol concentration (nmol l–1) of the samples was analysed by a competitive immunoassay technique (Coat-A-Count Cortisol Assay by Diagnostic Products Corporation, Los Angeles, CA). The concentration of creatinine (nmol l–1) was analysed in the University Hospital of Kuo- pio (Finland) by kinetic Jaffe’s reaction. Due to the variation in the dilution of urine, the content of cortisol in the urine was expressed as the cor- tisol-creatinine ratio (C:C) (Novak and Drew- sen 1989, Lasley and Kirkpatric 1991). In group L1, the urine samples of the siblings housed in different cages were analysed separately but the results were thereafter pooled together. Stress-induced hyperthermia (SIH) test was performed in the beginning of November. Due to the diurnal variation in foxes’ deep body tem- perature with lowest temperatures between 0700–1600 (Moe and Bakken 1997), the SIH test was performed between 0800–1500. In the test, a set of animals including all the experimental 188 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Ahola, L. et al. Effects of group size and space allocation in silver for cubs housing systems (i.e. 14 animals) situating in one side of the aisle of the shed were successively caught from their home cages. The time needed for catching the animal (TIME) was recorded. TIME was determined as the time lapsed from the moment when humans entered the shed for the first time to carry out the SIH test to the time the cub was captured in its cage. The rectal tem- perature (Tre) at the beginning of the test (Tre0) was measured with a digital thermometer (Om- ron). Thereafter the fox was placed into a small wire mesh cage (70 × 35 × 35 cm, L × W × H) situated inside the shed for 35 min. Tre was meas- ured again (Tre35) to obtain the maximum SIH (Moe and Bakken 1997). SIH was calculated as Tre35 – Tre0. Only one or two sets of animals were tested during one day. When two sets were test- ed during a day the animals tested situated in the shed some 12 meters apart from each other, and the animals in the set tested later were not disturbed by humans before the SIH test. At pelting time in January, the foxes were caught and injected i.m. with ACTH (0.3 mg per animal synthetic ACTH1–24, Synacthen Depot, Ciba). The foxes were placed alone into a smaller cage (70 × 35 × 35 cm, L × W × H), and 2 h after the injection they were euthanized according to the methods recommended by the Standing Com- mittee of the European Convention for the Pro- tection of Animals Kept for Farming Purposes (European Convention 1999) by electrocution. Blood samples were drawn with cardiac punc- ture. The serum cortisol level (nmol l–1), as a maximum response to ACTH administration (Fraser and Broom 1990, Broom and Johnson 1993, Terlouw et al. 1997, Ahola et al. 2000, 2001), was analysed by a competitive immu- noassay technique (Coat-A-Count Cortisol As- say by Diagnostic Products Corporation, Los Angeles, CA). Body mass of the animals was monitored before pelting. After pelting, both adrenals, heart, and gastrocnemius muscle (GAST) from the left hindlimb were removed, cleaned and weighed. GAST samples were frozen in liquid nitrogen and stored at –70ºC until assayed. Succinate- dehydrogenase (SDH) activity (µmol substrate utilised · mg protein–1 · min–1 at 37°C) was de- termined according to the procedure of Penning- ton (1961) as described in Ahola et al. (2000). Left tibias were cleaned from muscles and me- chanical properties of the tibias were determined, using a three-point bending test with Lloyd In- strumental Testing Machine in Jokioinen at the Agrifood Research Finland, as described in Aho- la et al. (2000). The number of bite wounds from the leather side of the skins was monitored. Professional fur graders at the Finnish Fur Sales Ltd (Helsinki, Finland) evaluated the quality of the furs using a 10-point scale (1: poorest, 10: best). The length of dry skins was measured one week after pelting. Statistical analysis Since the siblings in the housing units with more than one animal (S2, L2, S4, L4) were not indi- vidually recognised from the videotapes, activi- ty, use of available cages and platforms as well as locomotor stereotyped behaviour of the ani- mals was expressed as the mean value of the sib- lings in each unit. Therefore, the number of cases in each housing system was seven with regard to the behavioural data, except for the results from the feeding tests where data from individ- ual animals was used. In group L1 the be- havioural (except the feeding tests) as well as the urinary cortisol-creatinine ratio data of the male and the female sibling housed in different cages were pooled together. Therefore, there were seven cases in each housing system also for the urinary cortisol-creatinine ratio. Further- more, since each housing unit with more than one animal comprised of cubs from the same litter (i.e. not independent of each other) the mean values of the other measured physiologi- cal parameters (body mass, SIH, serum cortisol level after ACTH administration, the masses of adrenals, heart and GAST, SDH-activity of the GAST, breaking force of tibia) and the mean quality scores of furs as well as the mean number of bite wounds within each housing unit, sepa- 189 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. rately for male and female cubs, were used in statistical analyses (Martin and Bateson 1993). Therefore, the number of cases in each housing system was seven for both males and females with regard to the physiological (except the cor- tisol-creatinine ratio) and fur quality data. The General Linear Model (GLM) for repeat- ed measures was used to analyse differences between the five housing systems in activity levels, in the use of available cages and resting platforms and in GPI. The preference for the available cages in August, October and Decem- ber in groups L2, S4 and L4 was tested with a random 50% by Paired Samples T-test (in groups L2 and S4 the first vs. the second cage, in group L4 the two first cages vs. the two last cages com- bined). Since the mass parameters (heart, adre- nal and GAST masses) correlated well with the length of the dry skin in each of the five housing system, the GLM for univariate measures with dry skin length as a covariate was used to ana- lyse the effects of the housing systems on these parameters, i.e. the masses were corrected for the effect of the animal’s body size. Differences between the housing systems in body mass, SIH, serum cortisol level after ACTH administration, cortisol-creatinine ratio, SDH-activity of GAST and breaking force of tibias were analysed with the GLM for univariate measures. The results from the five feeding tests were analysed using Pearson Chi-Square test. Kruskal-Wallis test and Mann-Whitney test were used to evaluate the effects of group size and sex or space allocation, respectively, on the quality scores of the furs and on the incidence of bite wounds as well as on the incidence of stereotyped behaviour. All results have been expressed as mean ± SD. P-values over 0.1 have been considered as non-significant (NS). Results During the whole experiment, two foxes from group L1 were found dead (one female in mid- October, one male in late November) and the number of cases in group L1 was, therefore, de- creased from seven to six. Furthermore, one male from group L4 had to be removed from its hous- ing unit due to an ear mite infection in late Oc- tober. In this housing unit the results were de- fined by the data obtained from the animals left in the unit (two females and one male). No differences were found in the 24-h activ- ity levels between different group sizes or dif- ferent space allocations (Table 1). Group size of the housing unit affected significantly only the mean activity level during the three 8-hour peri- ods through the whole experiment: the cubs housed singly were, in general, most active dur- ing the working hours (0800–1600) whereas the cubs housed in pairs or in quartets were more active during the evening hours (1600–0000). In general, the daily activity level was constant from August till December. The activity of the cubs was lowest during the morning hours, with decreasing activity levels during the evening hours from August till December. In groups with more than one cage available (L2, S4 and L4), the cubs preferred to use the cage (L2, S4) or the two cages (L4) nearest to the door from which the humans normally en- tered the shed than the cage/cages further back (Fig. 1). No significant differences in the pref- erence for these cages between the housing sys- tems and between the months were revealed. The extent of the use of the resting platforms decreased from August till December (Fig. 2). The use of platforms through the whole experi- ment increased with increasing group size and with increasing space allocation. In groups S2 and L2, GPI did not change with advancing time (Fig. 3). In groups S4 and L4, GPI decreased with advancing autumn, i.e. the cubs within the quartets were more and more apart from each other when they grew older. Space allocation had no effect on GPI in the pair housed cubs. In quartets, GPI was significantly lower when the foxes were given more space. There were no differences between the males and females in eating behaviour during the five feeding tests performed during the growing sea- son. Therefore, the feeding test results from 190 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Ahola, L. et al. Effects of group size and space allocation in silver for cubs males and females were pooled together. There were no differences in the percentage of animals never coming to eat during the five feeding tests between the measured space allocations where- as the percentage of animals never coming to eat during the tests was highest in the foxes housed in quartets (Table 2). From the five separate feed- ing tests, no significant differences were revealed between different space allocations. Group size affected only the test performed in late October when the percentage of animals eating during the test was significantly lower in quartets than in other housing systems (percentage of foxes eat- ing during the test 39%, 46% and 20% in sin- gles, pairs and quartets, respectively, P < 0.05). In December, the cubs housed singly spent Table 1. Total 24-h activity (total, % of time) and activity during the morning (0000–0800), working (0800–1600) and evening hours (1600–0000) in the silver fox cubs in five experimental groups. L1 S2 L2 S4 L4 August 0000–0800 15 ± 3 18 ± 8 025 ± 10 22 ± 6 024 ± 11 0800–1600 36 ± 5 31 ± 7 23 ± 2 26 ± 5 24 ± 2 1600–0000 39 ± 8 43 ± 9 34 ± 8 38 ± 4 37 ± 6 total 30 ± 3 30 ± 3 28 ± 3 28 ± 3 28 ± 3 October 0000–0800 19 ± 5 22 ± 9 24 ± 7 24 ± 7 21 ± 9 0800–1600 34 ± 9 25 ± 6 23 ± 7 26 ± 7 21 ± 9 1600–0000 36 ± 8 36 ± 5 30 ± 6 34 ± 5 39 ± 8 total 30 ± 4 28 ± 5 26 ± 2 28 ± 3 27 ± 5 December 0000–0800 16 ± 6 12 ± 8 15 ± 7 16 ± 7 14 ± 2 0800–1600 42 ± 7 42 ± 7 37 ± 8 36 ± 8 37 ± 4 1600–0000 029 ± 11 030 ± 13 28 ± 9 33 ± 8 034 ± 10 total 29 ± 3 28 ± 5 27 ± 5 28 ± 3 28 ± 3 L1 = singly housed with 1.2 m2 per animal, S2 = pair housed with 0.6 m2 per animal, L2 = pair housed with 1.2 m2 per animal, S4 = quartet housed with 0.6 m2 per animal, L4 = quartet housed with 1.2 m2 per animal. Significance levels: group size NS, space allocation NS, hours P < 0.001, month NS. Interaction month × hours P < 0.001, hours × group size P < 0.001, other interactions non-significant. Fig. 1. Use of different cages (% of time spent in cages 1.–4., 1. = the cage nearest to the door hu- mans normally entered the shed) in housing systems with more than one cage available in silver fox cubs. L2 = pair housed with 1.2 m2 per animal, S4 = quartet housed with 0.6 m2 per animal, L4 = quar- tet housed with 1.2 m2 per animal. Significance levels (L2, S4: cage 1. vs. 50%, L4: cages 1. and 2. vs. 50%): NS P > 0.1, * P < 0.05, ** P < 0.01, *** P < 0.001. % o f ti m e 191 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. significantly more time in locomotor stereotyped behaviour than the cubs housed in pairs or in quartets (Table 2). Space allocation had no ef- fect on stereotyped behaviour. Because no sex differences in TIME, Tre0, Tre35 and the change in rectal temperatures were revealed the results from males and females were pooled together. TIME, Tre0, Tre35 and the change in rectal temperature were not affected by either group size or space allocation (Table 2). No significant effects of group size and space allocation were found on urinary cortisol-creat- inine ratio, serum cortisol level after ACTH ad- ministration and mass of adrenals (Table 2). A sex difference was evident in the mass of adrenals even though this mass was corrected with the dry skin length as a covariate for the effect of body size. The body mass of the cubs was not affected by either group size or space allocation (Table 2). In general, the males were significantly heavier than the females. A sex difference existed in the masses of heart and GAST as well as in the breaking force of tibia (Table 2). The mass of heart was influenced by space allocation: the cubs in housing systems with a larger area per animal had heavier hearts than the cubs with 0.6 m2 per animal. Further- more, the animals in groups of four showed a tendency to have lighter hearts than the animals housed either singly or in pairs. Neither group size nor space allocation had any effects on the mass of GAST, SDH-activity of GAST and on the breaking force of tibia. The quality of furs (quality scores in males: 7.3 ± 0.8, 6.9 ± 1.5, 6.9 ± 1.5, 4.9 ± 1.8 and 6.4 ± 1.1, in females: 7.0 ± 1.1, 6.3 ± 0.5, 6.1 ± 1.9, 3.6 ± 1.4 and 5.4 ± 1.3 in groups L1, S2, L2, S4 and L4, respectively) decreased with increasing group size (P < 0.001) and with decreasing space allocation (P < 0.05). In general, males had bet- ter fur quality than females (P < 0.05). In males, Fig. 2. Use of available resting platforms (% of time spent on platform/platforms) in five different housing systems. L1 = singly housed with 1.2 m2 per animal, S2 = pair housed with 0.6 m2 per animal, L2 = pair housed with 1.2 m2 per animal, S4 = quartet housed with 0.6 m2 per animal, L4 = quartet housed with 1.2 m2 per animal. Significance levels (GLM for repeated measures): month P < 0.001, group size P < 0.01, space allocation P < 0.05. No significant interac- tions. Fig. 3. Group preference index (%, above the bars) and occurrence of different group compositions (% of time) in silver fox cubs in August, October and December. S2 = pair housed with 0.6 m2 per animal, L2 = pair housed with 1.2 m2 per ani- mal, S4 = quartet housed with 0.6 m2 per animal, L4 = quartet housed with 1.2 m2 per animal. Hor- izontal lines: all singly, grids: one pair and two singly, open: two pairs, diagonal lines: one singly and one trio, solid: all together. Significance levels for GPI: S2 month NS, L2 month NS, S4 month P < 0.01, L4 month P < 0.01, S2 vs. L2 space allocation NS, S4 vs. L4 space allocation P < 0.01. No significant interactions. % o f ti m e % o f ti m e 192 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Ahola, L. et al. Effects of group size and space allocation in silver for cubs T ab le 2 . B od y m as s (k g) , m as s of h ea rt a nd g as tr oc ne m iu s m us cl e (G A S T ) (g ), s uc ci na te -d eh yd ro ge na se a ct iv it y (S D H ) (µ m ol s ub st ra te u ti li se d · m g pr ot ei n– 1 · m in –1 at 3 7 °C ), b re ak in g fo rc e (N ) of t ib ia , s er um c or ti so l le ve l (n m ol l –1 ) 2 h af te r A C T H a dm in is tr at io n, m as s of a dr en al s (m g) , c or ti so l- cr ea ti ni ne r at io ( C :C , × 10 –3 ), t im e sp en t in l oc om ot or s te re ot yp ed b eh av io ur ( % o f ti m e) i n D ec em be r, p er ce nt ag e of a ni m al s th at d id n ev er e at i n th e fi ve f ee di ng t es ts ( F T ), t im e (s ) ne ed ed t o ca tc h th e fo x fr om i ts c ag e (T IM E ), r ec ta l te m pe ra tu re ( ºC ) im m ed ia te ly ( T re 0) a nd 3 5 m in a ft er c ap tu re ( T re 35 ), a nd c ha ng e in r ec ta l te m pe ra tu re ( T re 35 –T re 0) i n si lv er f ox c ub s in fi ve e xp er im en ta l gr ou ps . L 1 S 2 L 2 S 4 L 4 P M F M F M F M F M F S ex G S S A B od y m as s 7. 6 ± 0. 8 6. 6 ± 0. 6 8. 1 ± 1. 3 7. 3 ± 1. 0 7. 6 ± 0. 8 6. 6 ± 0. 5 7. 8 ± 0. 7 6. 3 ± 0. 8 7. 9 ± 0. 8 6. 8 ± 0. 5 < 0 .0 01 N S N S H ea rt 49 ± 4 0 41 ± 2 0 47 ± 5 0 41 ± 4 0 50 ± 4 0 42 ± 4 0 46 ± 4 0 37 ± 4 0 48 ± 2 0 40 ± 2 0 < 0 .0 01 < 0 .1 0 < 0 .0 1 G A S T 34 ± 3 0 29 ± 3 0 34 ± 3 0 30 ± 3 0 32 ± 3 0 29 ± 4 0 34 ± 3 0 26 ± 3 0 33 ± 3 0 29 ± 3 0 < 0 .0 10 N S N S S D H 14 ± 6 0 15 ± 4 0 14 ± 7 0 15 ± 6 0 12 ± 4 0 18 ± 3 0 14 ± 2 0 14 ± 2 0 17 ± 2 0 16 ± 2 0 N S N S N S B re ak in g fo rc e 82 4 ± 12 2 62 4 ± 88 0 84 7 ± 13 6 69 5 ± 13 5 83 4 ± 14 0 70 7 ± 14 4 84 4 ± 12 6 63 2 ± 14 0 80 8 ± 14 6 68 8 ± 13 9 < 0 .0 01 N S N S C or ti so l 42 1 ± 59 0 34 5 ± 53 0 35 5 ± 38 0 36 6 ± 63 0 37 9 ± 44 0 36 2 ± 70 0 36 4 ± 28 0 37 4 ± 47 0 38 8 ± 48 0 36 7 ± 35 0 N S N S N S A dr en al s 60 5 ± 10 7 48 7 ± 33 0 55 5 ± 61 0 51 7 ± 83 0 50 9 ± 58 0 45 9 ± 33 0 56 1 ± 55 0 47 8 ± 48 0 60 5 ± 96 0 46 8 ± 39 0 < 0 .0 10 N S N S C :C 4. 0 ± 1. 7 3. 7 ± 0. 7 5. 1 ± 3. 0 4. 1 ± 1. 6 4. 1 ± 1. 0 N S N S S te re ot yp ie s 3. 9 ± 5. 2 0. 7 ± 1. 2 0. 3 ± 0. 3 0. 2 ± 0. 2 0. 1 ± 0. 3 < 0 .0 5 N S F T 25 36 21 46 59 N S < 0 .0 5 N S T IM E 40 6 ± 25 5 40 5 ± 22 3 53 5 ± 27 4 49 1 ± 17 1 53 2 ± 23 0 N S N S N S T re 0 39 .9 ± 0 .5 0 39 .8 ± 0 .5 0 39 .7 ± 0 .4 0 40 .0 ± 0 .3 0 40 .0 ± 0 .4 0 N S N S N S T re 35 40 .1 ± 0 .6 0 40 .1 ± 0 .7 0 40 .0 ± 0 .5 0 40 .2 ± 0 .2 0 40 .2 ± 0 .2 0 N S N S N S T re 35 –T re 0 0. 2 ± 0. 7 0. 3 ± 0. 5 0. 3 ± 0. 5 0. 2 ± 0. 3 0. 3 ± 0. 5 N S N S N S L 1 = s in gl y ho us ed w it h 1. 2 m 2 p er a ni m al , S 2 = p ai r ho us ed w it h 0. 6 m 2 pe r an im al , L 2 = p ai r ho us ed w it h 1. 2 m 2 pe r an im al , S 4 = q ua rt et h ou se d w it h 0. 6 m 2 p er an im al , L 4 = q ua rt et h ou se d w it h 1. 2 m 2 p er a ni m al M = m al e, F = f em al e G S = g ro up s iz e, S A = s pa ce a ll oc at io n N S = n on -s ig ni fi ca nt . N o si gn if ic an t in te ra ct io ns . 193 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. neither group size nor space allocation had any effects on the number of bite wounds (L1: 0.8 ± 0.8, S2: 1.1 ± 1.8, L2: 1.3 ± 2.1, S4: 0.3 ± 0.6 and L4: 0.9 ± 1.4, group size NS, space alloca- tion NS). In females, the number of bite wounds was lower in the cubs that were given larger space allocation while group size had no effects on the incidence of bite wounds (L1: 1.0 ± 1.7, S2: 2.3 ± 2.0, L2: 0.3 ± 0.5, S4: 1.6 ± 1.4 and L4: 1.4 ± 1.4, group size NS, space allocation P < 0.05). No significant sex difference in the number of bite wounds was revealed. Discussion Earlier studies on canids kept for laboratory or farming purposes (e.g. dogs, foxes) exploring the linkage between increased available space or increased number of animals within a housing unit and activity level have led to contradictory conclusions. As the amount of space available increases, the activity level of the animals has either increased (dog: Hetts et al. 1992), re- mained constant (raccoon dog: Korhonen and Harri 1988), or decreased (dog: Hughes et al. 1989). Increasing the number of animals within a housing unit, which usually means also increas- ing the total available area for the members of the group, has typically increased the activity level of the animals (dog: Hubrecht et al. 1992; silver fox: Bakken et al. 1994, Ahola et al. 2000, but see dog: Hetts et al. 1992). In the present study, neither increasing space allocation (0.6 m2 vs. 1.2 m2) nor increasing the number of animals within a housing unit (one vs. two vs. four) evoked any differences in activity levels of the animals. However, the mass of heart was great- er in the cubs that had 1.2 m2 per animal com- pared to the cubs that had only 0.6 m2, perhaps indicating that larger space allocation enables the animals to exercise more. This result is, howev- er, not unambiguous in regard of the increased space because the hearts tended to be lighter in the cubs housed in quartets with total area avail- able for the cubs being 2.4 or 4.8 m2 than in the cubs housed either singly or in pairs with 1.2 or 2.4 m2 available area. The reason for this result may be that, even though in theory an animal could have exercised more in the larger area, the possibility for this was turned down by the cage mates in the quartets. However, all the results of the other exercise-related parameters (i.e. mass of GAST as well as SDH-activity of GAST and the breaking force of tibia) support the conclu- sion that increasing space from 1.2 m2 to 4.8 m2 does not necessarily alter the rate of exercise in silver fox cubs. The result that the cubs housed singly were more active during the working hours than the cubs housed with their littermates may be due to the absence of conspecifics and, therefore, these singly housed cubs were perhaps more bonded to human activity. The impact of the pres- ence of humans on activity has earlier been doc- umented in singly housed laboratory dogs (Hite et al. 1977, Hughes et al. 1989). That the cubs housed in quartets were more tied with the ac- tivities of their cage mates became obvious also during the feeding tests: significantly less ani- mals were eating during the five feeding tests in quartets than in other housing systems. This re- sult would suggest that the foxes housed in quar- tets were experiencing human proximity as more aversive than the other foxes, as the feeding test is validated to measure animals’ fear responses towards human (see Rekilä 1999). However, the SIH test (see Moe and Bakken 1997) indicated that there were no differences in fear responses towards human between the foxes housed in dif- ferent group sizes or space allocations. There- fore, the present results revealed that the feed- ing test may also indicate the effects of group housing and of social tension within a group on the behaviour of the foxes rather than only the level of fear towards humans, as earlier shown in farmed blue foxes housed in sibling groups (Ahola et al. 2002). The cubs that had more than one cage avail- able used their area unevenly. Most often the animals were in the cage (groups L2 and S4) or in the two cages (group L4) situated nearest to 194 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Ahola, L. et al. Effects of group size and space allocation in silver for cubs the door that was used by humans when they entered the shed. The same result has earlier been reported in dogs that did not utilise the additional floor space which was three times the area of the smaller cage size but preferred to stay most of their time in the front parts of their cage (Hite et al. 1977). This preference for the foreparts of the cage area may be due to the general inquisi- tiveness of the animals towards human activity or the animals’ tendency to ensure that there is some space for escape from a sudden appearance of humans. In any case, the foxes ability to choose between some more or less favourable areas in their cage systems may have promoted their sense of control which, in turn, may en- hance the welfare of animals (e.g. Fraser and Broom 1990, Broom and Johnson 1993, Peder- sen and Jeppesen 1998). Although the group members were often in a single cage they were not huddled together all the time. The resting platforms in each cage en- abled the animals within a housing unit to keep their own space in one cage either on the floor of the cage or on the resting platform. The ten- dency to be apart from the littermates with the passing of autumn was seen especially in group L4 where, on the one hand, the situations that the cubs were in tight trios or quartets became more and more rare and, on the other hand, the cubs’ preference for being alone increased. This phenomenon of loosing bonds between the lit- termates is well known from the wild red foxes during the autumn, at the time of dispersion (Be- koff 1977). In the wild, red foxes may or may not disperse, and eventually live in social units with only one male and 1–5 females, often re- lated to each other (Macdonald 1983). Therefore, it may be that for the pair housed cubs there was no such reason to evade each other during the late autumn as there was in quartets with two males. Other possible explanation is that the in- creased space (4.8 m2 in group L4) allowed the group members to be more apart from each oth- er. This explanation is supported by the finding that group housed dogs placed more distance between themselves when given larger cages (Bebak and Beck 1993). The present study did not reveal differences in the serum cortisol level after ACTH adminis- tration, adrenal mass or urinary cortisol-creati- nine ratio between the five housing systems, in- dicating that no housing system examined here was better or worse than any of the other in terms of the measured parameters. The same result, i.e. that cage size or exercise level or combination of these two has little or no effect on the physi- ological indicators of stress, has earlier been re- ported in dogs (Campbell et al. 1988, Clark et al. 1991). The social environment an animal lives in, in contrast, has been found to have effects on the incidence of stereotyped behaviour. Dogs in social isolation exhibited the greatest number of bizarre movements (Hetts et al. 1992) and spent considerably more time in repetitive behaviour (Hubrecht et al. 1992). When dogs were trans- ferred from group conditions into smaller, in- dividual housing systems they showed lower postures, signs of repetitive behaviour and auto- grooming (Beerda et al. 1999). In the present study, only locomotor stereotyped behaviour performed without the neighbour was monitored. This was due to the ambivalence about which of the behaviours measured in earlier studies and considered to represent stereotyped behaviour actually meet the criteria of stereotypes (Wik- man et al. 1999). The results from the present study show that the amount of locomotor stere- otyped behaviour in the cubs housed either in pairs or in quartets was similar to that earlier reported in singly housed silver foxes (0.3% of a 24-h day, Wikman et al. 1999). In contrast to earlier results by Wikman et al. (1999), in the present study the singly housed cubs performed locomotor stereotyped behaviour almost 4% of the time. One reason for the higher occurrence of stereotyped behaviour in the present study may be that stereotyped behaviour develops with time (see Mason 1991), and in the study of Wik- man et al. the age of the animals was 4–5 months whereas in the present study the foxes were 7–8 months old. The other reason may be that in the present study the cubs were put straight after weaning singly in their experimental cage, whereas in Wikman et al. (1999) and according 195 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. to normal farming practice the siblings after weaning are first kept in groups and only after some time separated into pairs or singles. What- ever the reason, and although there were no dif- ferences in the present study between the hous- ing systems in the HPA-axis activity, the occur- rence of stereotyped behaviour in group L1 sug- gests that some cubs housed singly (not all the animals performed this behaviour: in December, three out of six male cubs accounted for 99% and two out of six female cubs accounted for 89% of the total amount of stereotypes in singly housed males and females, respectively) may have had poorer welfare, e.g. they were frustrat- ed because did not have any cage mates. Although the physiological stress indicators measured or the body mass of the animals were not affected by group size and space allocation, these factors did affect the quality of the furs and the incidence of bite wounds. The quality of the furs decreased with increasing group size and with decreasing space allocation, resulting in poor quality furs especially in the group with four cubs housed with 0.6 m2 per animal (group S4). The reason for this may be that in group S4 the combination of group size and space allocation resulted in crowded conditions, which can af- fect the performance of animals more than if only one of these factors is changing in the housing conditions (see Fraser and Broom 1990). Space allocation as such had an effect on the incidence of bite wounds in the female cubs. It seems ob- vious that females had difficulties in avoiding aggressive contacts with their cage mates when the foxes were given less space per individual. Conclusion The cubs that were separated from their mother and siblings straight into single living performed significantly more locomotor stereotyped behav- iours than the cubs housed in pairs and in quar- tets. This result indicates that a possibility for social behaviour is important for the welfare of young silver fox cubs. However, at the time of foxes’ natural dispersal, the cubs housed in quar- tets tended to stay apart from each other possi- bly due to increased within-group social tension. Therefore, to enhance the welfare of silver fox cubs, the group housed cubs should possibly be separated in later autumn to live in pairs. Space allocation as such had only minor effects on the physiology and behaviour of the cubs. Howev- er, the effect of decreased space allocation was revealed as decreased fur quality and as in- creased biting injuries in female cubs. Acknowledgements. This study was supported by The Re- search Council for the Environment and Natural Resourc- es of the Academy of Finland and by the Finnish Fur Breed- ers’ Association (FFBA). We are grateful to Mrs. Maija Mis- kala for her skilful assistance during the field experiments. 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Proceedings of the 33 rd International Con- gress of the International Society for Applied Etholo- gy. 17–21 August 1999, Lillehammer, Norway. p. 109. 197 A G R I C U L T U R A L A N D F O O D S C I E N C E I N F I N L A N D Vol. 11 (2002): 185–197. SELOSTUS Ryhmäkoon ja käytössä olevan tilan vaikutus tarhattujen hopeakettupentujen hyvinvointiin Leena Ahola, Jaakko Mononen, Teija Pyykönen, Maarit Mohaibes ja Teppo Rekilä Kuopion yliopisto ja MTT (Maa- ja elintarviketalouden tutkimuskeskus) Tarhattuja hopeakettuja kasvatetaan vieroituksen jäl- keen yleisimmin uros-naaraspareittain perinteisissä kettuhäkeissä. Kritiikki kasvatusmuotoa kohtaan ja kiinnostus tuotantoeläinten hyvinvointiin on lisännyt tarvetta etsiä vaihtoehtoisia kasvatusmuotoja tarhat- taville turkiseläimille. Tässä työssä selvitettiin voi- daanko tarhattujen hopeakettupentujen hyvinvointia parantaa rikastuttamalla perinteisiä kettujen kasvatus- oloja sosiaalisella ja fyysisellä ympäristöllä. Hopeakettupentuja kasvatettiin vieroituksen jäl- keen yksittäin, pareittain tai neljän kettupennun ryh- missä. Tilaa ketuille annettiin 0,6 m2 tai 1,2 m2 eläintä kohti. Erilaisten kasvatusolojen vaikutusta hyvinvoin- tiin selvitettiin määrittämällä hopeakettupentujen käyttäytymistä, fysiologiaa ja nahan laatua. Saadut tulokset osoittivat, että mahdollisuus oles- kella lajikumppaneiden kanssa on tärkeää nuorille hopeakettupennuille. Kettupentuja kannattaisikin ehkä kasvattaa sisarusryhmissä perinteistä tarhaus- käytäntöä pidempään. Tilanne on kuitenkin hieman toinen vanhemmilla pennuilla. Hopeaketut näyttävät säilyttäneen luontaisen taipumuksensa erota perheen- jäsenistään ensimmäisen syksyn aikana. Hopeakettu- pentujen hyvinvoinnin kannalta on kenties hyvä, että pennut myöhemmin syksyllä erotetaan sisaruksistaan elämään sisaruspareissa. Käytössä olevalla tilalla ei ollut kovin suurta merkitystä kettujen käyttäytymisel- le ja fysiologialle. Tuotanto-ominaisuudet kuitenkin heikkenivät, kun tila pieneni 1,2 m2:stä 0,6 m2:iin kettua kohden. Title Introduction Material and methods Results Discussion Conclusion References SELOSTUS