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Survey of interdigital phlegmon outbreaks and their risk factors in free stall dairy herds in Finland
Acta Veterinaria Scandinavica volume 59, Article number: 46 (2017)
Severe outbreaks of interdigital phlegmon (IP) associated with a high morbidity and major economic losses have occurred in Finland in the past decade. A survey was performed to indicate the current occurrence of infectious hoof diseases and to identify herd level risk factors predisposing to an outbreak of IP.
Responses to a questionnaire revealed that an outbreak of IP defined as morbidity ≥5% within the 1st month of the outbreak, had occurred in 18.0% of the respondent study farms. Risk factors for an outbreak included animal transport between herds, i.e. either animal purchase or contract heifer rearing, enlargement or renovation of the barn, and if the fields of the farm had been organically cultivated. Having any kind of mechanical ventilation in comparison to natural ventilation seemed to lower the risk of IP. Additionally, the farms that had experienced an outbreak of IP often had other infectious hoof diseases. However, it was unclear which disease appeared first.
More attention is needed before and during enlargement or renovation of the barn and substantial planning is crucial for every part of the enlargement process in dairy farms.
Recently, several dairy herds in Finland experienced a sudden outbreak of interdigital phlegmon (IP). These outbreaks mainly occurred in recently built or renewed free stall barns and caused major economic losses due to high morbidity, antibiotic treatment of the affected cows and discarded milk . No preceding trauma to the interdigital cleft of the affected cows has been reported. Previously, only a few cases of infectious hoof diseases were detected in Finnish dairy farms.
At the same time, the structure of dairy industry in Finland has changed; based on the statistics of National Resources Institute Finland the average number of lactating cows per herd has more than doubled during last 15 years, and the change from tie stalls to free stalls have also occurred simultaneously. In addition, several new techniques have been introduced in the farms, like mixed ration feeding and automatic milking system.
A lot of research has been done on the aetiology and possible risk factors of IP. Fusobacterium necrophorum is considered a major pathogen in IP [2, 3] although several other bacteria and environmental factors influence the development of disease [4, 5]. Typically, the first sign of IP is slight lameness, which becomes more apparent when the infection progresses. A swelling of the interdigital area and the bulbs of the heels together with a fetid odour are regarded as characteristic. Soon a fissure forms with swollen protruding edges along the interdigital cleft. In severe cases, systemic signs may appear, which include fever, recumbency, anorexia and decrease in milk production . IP reduces milk yield  and can result in an early culling of the affected cow [7, 8].
In general, IP occurs as a sporadic disease in cattle. The frequency or prevalence of IP has been reported being 0.2–5% in herds in North America [9,10,11], but some other reports of earlier outbreaks of IP exist where the incidence may be as high as 17–25% [12, 13].
As long ago as 1945, Johnson  reported that the increase in the incidence of IP is associated with increased animal traffic between herds and cases occur when cattle are introduced to a pasture with alfa–alfa hay or clover. A trauma to the interdigital skin and muddy conditions were mentioned as predisposing factors for the disease. Other studies have also investigated a preceding trauma and muddy or moist conditions underneath the hooves as predisposing factors [4, 6]. In addition, Gupta et al.  mentioned seasonality, intensive farm practice, concrete flooring and coarse sand. A Danish study reported cow-level risk factors that included calving, first parity and free stall housing in comparison to tie stall housing .
However, most of this research on IP is quite old or does not focus on the actual outbreaks. In response to numerous outbreaks of IP in dairy herds in Finland, we wanted to investigate the possible herd level risk factors and furthermore, to describe the current situation of infectious hoof diseases in Finland.
In the spring of 2013, a questionnaire regarding infectious hoof diseases was sent to all Finnish dairy farms in a dairy herd recording database that had ≥50 cows in 2012 (n = 1134). The total number of comparable dairy herds in Finland in the spring of 2013 was 1245  and therefore, our initial target population covered 91.1% of the herds of similar size in Finland. The contact data was received from ProAgria agricultural data processing center. Only free stall herds were included in the study.
The final draft of the five-page questionnaire contained 35 questions of general herd data, which included herd size, mean milk yield and region, and questions about the barn characteristics and herd management details. The key items asked are listed in Table 1. The number of the cow compartments meant the number of barns or separate sections of a barn for milking cows. Some farmers separate their milking cows for example based on udder health or milk yield. The flooring choices in the questionnaire were slatted or solid with or without rubber, where the choice ‘with rubber’ included rubber everywhere or only partly in the alleys or manure pack flooring in non-insulated free stall barns. The ventilation system choices contained natural or mechanical systems with or without an additional precision ventilation of the manure drain.
The mixed ration feeding included total or partial mixed ration. One question covered any possible enlargement or renovation of the barn in 3-year period prior to the outbreak of IP or 3 year period prior to answering the questionnaire. Two questions inquired about the animal transport between herds i.e. the animal purchase during the past year and information about where the heifers of the herd are kept. Some farms in Finland do not raise their own heifers and instead their calves are sent to another herd, where they are kept until the animals return to the home herd before the first calving. In general, Finnish contract heifer rearing units have animals from several independent farms. Another question inquired about whether the fields of the farm were cultivated organically.
Additionally, the dairy farmers were asked several questions about the leg and claw health in their herd. First, they had to clarify whether they had experienced (1) an outbreak of IP in the last 10 years, in other words had several cases of IP in a short period, or (2) had only a few cases of IP, or (3) had no cases of IP at all. The common signs of IP were described as a list. They included fever, lameness, swelling above a hoof, shaking of a leg, bad odour in the hoof region, and lesions in between the hooves or in the heel. The farmers had to choose the signs exhibited by their affected animals and record the number of the affected cows within first 2 weeks of the outbreak.
Second, we inquired about the signs of interdigital dermatitis (ID), digital dermatitis (DD), interdigital hyperplasia (IH) and verrucous dermatitis. Similarly, the signs of ID and DD were listed and included lesions between the hooves or in the heel and reddish, painful lesions in the hoof region. Third, we asked for the dairy farmer’s observations about whether the herd had occurrences in excess of 5% white line lesions that needed a hoof blocking for treatment and any visual signs of calf diphtheria i.e. buccal abscesses in suckling calves.
Most of the cases of IP in Finland are diagnosed and treated by veterinarians, because of a strict national antibiotic policy. In the outbreaks, the correct diagnosis is achieved relatively straightforward. Therefore, we expected the IP status given in the questionnaire to be accurate. On the other hand, ID and DD are rarer and their signs are confusing, so we predicted more variation with these answers. Because of this unpredictability and possible confusion of the farm staff in making the correct diagnosis of ID and DD we considered the existence of any of their listed signs as other infectious hoof disease than IP.
The questionnaire was pilot tested with two dairy veterinarians and producers and modified based on their feedback. The final drafts of the questionnaire were mailed to dairy farmers with an enclosed paid return envelope. An alternative option was to answer the same questionnaire online. Furthermore, all dairy veterinarians in Finland were informed about the survey and asked to remind their dairy farmer clients. No separate reminders were sent to farmers themselves. After the return of the questionnaires, some of the farms were called to clarify certain answers.
We collated and inserted the data from the original paper document questionnaire into Excel spreadsheets and used Stata IC version 14 (Stata Corporation, Texas, USA) for statistical analyses. Only free stall barns with a complete information on the IP status of the herd were included in the analyses. A P value <0.05 was considered statistically significant. The descriptive data are presented as percentages. The possible outbreak of IP associated putative disorders were tested using the Chi squared test.
Our study herds were categorized into three groups according to the IP status of the herd, thus: (1) outbreak of IP, (2) few cases of IP, and (3) no IP in the herd. The herds with no IP are hereafter referred to as the control herds. An outbreak of IP was defined as morbidity due to IP being ≥5% during the 1st month of the outbreak.
The predictors included herd size, milk yield, region and all variables listed in Table 2. Herd size was a continuous variable. Data on herd size were not normally distributed, thus they were divided into three herd size classes: (1) 50–65, (2) 66–99, and (3) ≥100 cows per herd. Milk yield was a normally distributed continuous variable and was presented as 1000 kg in analyses. The geographical location of the herd was categorized into four groups based on counties in Finland; (1) southern, (2) western, (3) eastern, and (4) northern region. The flooring variable was categorized into (1) slatted concrete, (2) solid concrete, (3) slatted floor with rubber, and (4) solid floor with rubber. The ventilation system was divided in two groups; (0) natural ventilation, (1) natural ventilation with an additional precision ventilation of the manure drain or mechanical ventilation with or without an additional precision ventilation of the manure drain. This latter option is later referred as a mechanical ventilation system.
The enlargement or renovation of the barn was a dichotomous variable, where (0) no enlargement or renovation in 3 years prior to the outbreak in outbreak herds or no enlargement or renovation in 3 years’ prior replying to the survey in control herds and (1) enlargement or renovation in 3 year period prior to the outbreak in outbreak herds or enlargement or renovation during the 3 year period prior to replying to the survey in control herds. The open or closed herd variable discriminated between two groups; (0) closed herd i.e. no purchase of cattle and no contract heifer rearing, (1) open herd i.e. purchase of cattle or contract heifer rearing or both.
The sample size in the model was 294 herds with an occurrence of an outbreak of IP 19%. An odds ratio (OR) 2.7 with a power of 0.9 for predictors was determined as significant for this sample size, assuming the proportion of exposed controls for this predictor was 25%.
We excluded the herds with few cases of IP from the statistical analysis of the risk factors of an IP outbreak. Associations between all predictors and the outcome were computed using simple logistic regression. The predictors with association ≤0.2 were included in the full model. A manual stepwise backwards procedure was used to build the nested model. Removed variables were evaluated at each step for confounding effects by checking if the coefficients for remaining variables had changed over 20%. The region, herd size and the milk yield were considered to be confounding variables and therefore, were kept in the model. Moreover, full and nested models were compared with the logistic likelihood ratio test.
We tested all biologically plausible interactions, but detected no significant association. We also evaluated the model by sensitivity and specificity test and roc-curve of the model. The assumptions of the model were controlled by normality and scatter plots of the model residuals. One herd was found to be an outlier, but because it did not change the results essentially, it was kept in the model.
A total of 390 questionnaires were returned resulting in a response rate of 34.4%. Of these responses, 355 free stall herds had complete information on their IP status and therefore were included in the study.
The mean herd size was 79.8 dairy cows (range 50–293.7) and the mean yearly milk yield of the herds was 9364 kg (6800–12,500 kg). Table 2 summarizes the barn characteristics and management practices of the study herds.
Sixty-four out of 355 herds (18.0%) had had an outbreak of IP with morbidity ≥5% within the 1st month of the outbreak. All reported outbreaks had occurred in the year 2004 or later and a majority (68.8%) within the 2009–2013 period (Fig. 1). Furthermore, 32 (9.0%) respondents reported few cases of IP in the herd. Out of 64 IP herds 14 (21.9%) reported cases of IP in heifers and 11 (17.2%) in calves. A year after the outbreak, in 21 out of 47 outbreak herds (44.7%) still had sporadic cases of IP in cows, in 4 herds (8.5%) in heifers, and in 1 herd (2.1%) in calves. Signs of IP cases in the 64 outbreak herds were as follows: 33 (51.6%) herds reported fever, 62 (96.9%) lameness, 62 (96.9%) swelling above a hoof, 36 (56.3%) shaking of a leg, 34 (53.1%) bad odour in the hoof region, 50 (78.1%) lesions in between the hooves and 25 (39.1%) lesions in the heel.
Risk factors for an outbreak of IP
We compared control farms (n = 239) and farms with an outbreak of IP (n = 55) and analyzed the associations of various predictors. Out of 323 herds, we included 294 herds with a complete dataset in the analysis. Table 3 presents the results of a logistic regression model.
Occurrence of an outbreak of IP associated putative diseases
We studied the association of an outbreak of IP with the occurrence of various other hoof diseases and visual signs of calf diphtheria such as buccal abscesses. Interdigital hyperplasia, verrucous dermatitis and other infectious hoof diseases, like ID and DD, were detected more frequently (Pearson’s Chi2 28.6, 10.4, and 46.4 respectively, in all P < 0.01) among the herds with an outbreak of IP (Fig. 2). Similarly, buccal abscesses in suckling calves were observed more often (Pearson’s Chi2 65.3, P < 0.01).
We determined the current situation regarding infectious hoof diseases in Finland. Eighteen percent of the herds who responded to the questionnaire in our study were diagnosed as having an outbreak of IP with morbidity ≥5% within the 1st month of the outbreak, whereas 9.0% of the herds who reported having sporadic cases of IP did not fulfill our definition of an outbreak. Interestingly, those farms that had experienced an outbreak of IP, often had other infectious hoof diseases. However, it was impossible to deduce from our study design and survey data, which disease appeared first in the herd. Likewise, a study from the Netherlands reported that the presence of other infectious hoof disorders, such as interdigital dermatitis and heel horn erosion (IDHE) and IP, increased the risk for DD, and IP appeared to be strongly associated with DD (OR = 4.4) . Other reports of correlations between other infectious hoof diseases than IP also exist [18,19,20]. Recently, veterinary practitioners in Finland have observed an increase in the number of buccal abscesses in young dairy calves in herds with a previous outbreak of IP. Our survey data supports this observation. A buccal abscess may characterize a sign of calf diphtheria; a respiratory tract disease where F. necrophorum plays a part in the pathogenesis [21, 22].
We investigated the possible herd level risk factors for an outbreak of IP to occur. Our study determined recent enlargement or renovation of the barn to be a risk factor for an outbreak of IP. During the enlargement process, both the cattle and the dairy producers suffer from stress; they must adapt to a new building, and management regime that differ from the old system. Before the introduction of the new free stall, some overstocking may occur in the old building, which would plausibly increase the infection pressure. Occasionally, when the cattle are compelled to move into new free stall, the facility can still be a construction site, which might increase the risk for injuries and is an additional burden and stress factor to farmers. As part of the restructuring and the enlargement, the tradition of the family managed farm may end, and the cattle in the enlarged herds will be managed by employed staff. If the management is not of sufficient quality or there are fewer stockmen to look after more cows, the risk of mistakes and unnoticed signs of ill-health may increase.
We also determined the animal transport between herds to be a risk factor for an outbreak of IP. This was not surprising, because of the infectious nature of the disease [3, 6]. Moreover, the purchase of new animals occurs more frequently during the enlargement of a herd, and contract heifer rearing is also more common before or after the enlargement when producers try to adapt to different management strategies to deal with the increasing herd size. Buying in new heifers from other farms has been reported as a risk for DD [23,24,25]. On the other hand, a new animal in a herd always meets different environment and management, which may affect its immunology. The possible causality of the animal purchase and the IP outbreak in our study was unclear in the questionnaire data and therefore, purchase of heifers may not be a causal factor in the IP outbreak but simply be a simultaneous management course of action in the farm.
We also found that organically cultivated fields were a risk factor. Even though the number of the herds with organically cultivated fields (n = 24) was small in our model, the post hoc power analysis (0.88) showed that the group was big enough to detect the possible risk. In Finland, the soil lacks selenium (Se), and in conventional farming the use of fertilizers with Se supplement is standard. However, the regulations of organic farming limit the use of fertilizers and if Se supplement is not added in the feed, a deficiency might occur. Low blood Se level might alter the immunological status of the cows and increase disease susceptibility. For example, some studies have detected an association with low Se and vitamin E deficiency and udder health [26, 27]. Another possible underlying cause in organic farming may be the excessive use of clover in the silage. Johnson  speculated as long ago as 1945 that clover might be a reason for an increased incidence of IP. Moreover, due to the EU regulations of organic farming (Council regulation 2007/834/EC) animal purchase is more likely to happen between other organic herds. The risk of IP spreading from one organic farm to another is increased if the IP is more common in organic farms than conventional ones. None of these possible factors listed above could be ascertained by only one question in this survey. More details about the grazing conditions, trace element status and grass and clover species content of fields would be needed in future studies to investigate such possible factors.
Any form of mechanical ventilation was found to decrease the risk of an outbreak of IP. We presume that the better the ventilation the drier the indoor air and less ammonia in the free stall. Furthermore, the drier the indoor air the cleaner the cows are. Two Norwegian studies reported that barns with low air humidity had cleaner animals  and for each 10% increase in relative air humidity, the risk of dirty thighs increased . In the past, moist conditions underneath the hooves have been associated with IP [4, 6]. Several studies have also found associations between other infectious hoof diseases and dirty claws or legs or dirty alleys [20, 25, 30, 31]. The flooring type had no effect on the outbreaks of IP in our study in contrast to studies of DD from the UK and USA. Solid flooring of grooved concrete was identified as a risk factor for DD in the UK  and in the USA  when compared to textured concrete floors.
In this study, an overstocking was not a risk for an outbreak of IP. However, the animal protection law in Finland prohibits an overstocking and one stall per cow is compulsory. This may have affected the responses of farmers. Additionally, the stocking situation in the barn varies constantly.
Replies to our survey represented the regional differences in dairy farming in Finland quite well; all areas were represented and replies from areas with more dairy cows, like provinces Pohjanmaa and Savo, were a greater number. Additionally, the mean milk yield of the study herds related appropriately to free stall herds of similar size. However, some bias may exist in our results. Presumably the farms that had problems with infectious hoof diseases were more prone to answer the survey and therefore, our results may be moderately skewed. Although we could detect several possible risk factors for an outbreak of IP, we were not able to specify why there has been so many of these outbreaks in Finland. One reason could be that other countries had experienced similar outbreaks much earlier [12, 13, 33], and due to Finland’s relative isolation Finnish dairy herds are still immunologically quite naïve and therefore more susceptible to IP.
This study revealed risk factors that were associated with the outbreaks of IP in Finland. These risk factors were animal transport between herds, enlargement or renovation of the barn and organic cultivation of the fields. However, having a forced ventilation system in the free stall barn lowered the risk. These results suggest that more attention is needed before and during the enlargement process and substantial planning is crucial in every part of that undertaking. Since the farms that had experienced an outbreak of IP, often had other infectious hoof diseases as well we speculated that this strategic approach would additionally reduce the incidence of these further diseases.
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All authors participated in planning the study, MKo, MKu, RJ, TS, and HS designed the questionnaire, MKo collected the data, MKo, MKu and HS performed the statistical analyses and MKo drafted the manuscript. All authors read and approved the final manuscript.
We thank Anne Mikkola and Maarit Mäki from University of Helsinki, Saari unit for the technical assistance with the mailing of the questionnaires and we also thank all the dairy farmers who replied to our survey.
The authors declare that they have no competing interests. TS is a deputy editor of Acta Veterinaria Scandinavica but has not in any way been involved in the editorial handling of the manuscript or decision making.
Availability of data and materials
The datasets analyzed during this study are available from the corresponding author on reasonable request.
Our study protocol was reviewed and approved by the Viikki Campus Research Ethics Committee of Helsinki University in 2012.
This study was funded by the Ministry of Agriculture and Forestry project (2066/312/2011) for infectious hoof diseases in new free stalls in Finland, Valio Ltd and the Mercedes Zachariassen Foundation.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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Kontturi, M., Kujala, M., Junni, R. et al. Survey of interdigital phlegmon outbreaks and their risk factors in free stall dairy herds in Finland. Acta Vet Scand 59, 46 (2017). https://0-doi-org.brum.beds.ac.uk/10.1186/s13028-017-0313-0
- Interdigital phlegmon
- Risk factors
- Infectious hoof diseases
- Foot rot
- Foul in the foot
- Interdigital necrobacillosis