In Dogs Bitten by the European Adder (Vipera Berus), Do Corticosteroids and Supportive Treatment Improve Clinical Outcome Compared to Supportive Treatment Alone?

a Knowledge Summary by

Hannah Harjen BVetMed, MRCVS ^1*

¹Department of Companion Animal Clinical Sciences, Norwegian University of Life Sciences (NMBU), Ullevålsveien 72, 0454 Oslo, Norway
^*Corresponding Author (hannah.harjen@nmbu.no)

Clinical scenario

Many dogs are bitten by the European adder (Vipera berus) between April and October each year. Treatment has often included administration of glucocorticoids and, in some countries, owners have traditionally carried glucocorticoid tablets to administer as an emergency treatment prior to seeking veterinary help (Lund et al., 2013, Turkovic et al., 2015).

Through their anti-inflammatory effects, glucocorticoids may reduce the pain and inflammation associated with snakebites in dogs as well as treating adverse reactions following antivenom administration (Lund et al., 2013, Armentano and Schaer, 2011). Potential disadvantages of glucocorticoid administration in these patients may include dose-dependent immunosuppression and increased catabolism (Leisewitz et al., 2004). The potential for delay in seeking veterinary help when owners administer glucocorticoids as an emergency treatment is also a concern.

A client comes into your practice and requests prednisolone tablets to administer to their dog in case of a bite by the European adder (Vipera berus). You wish to know whether there is any evidence that giving glucocorticoids will improve clinical outcome in dogs bitten by the European adder, compared to supportive treatment alone.

The evidence

One double-blinded randomised placebo-controlled trial (Brandeker et al., 2015) and two prospective case series (Lervik et al., 2010, Lund et al., 2013) were identified as relating to this question. The studies by Lund et al. (2013) and Lervik et al. (2010) had a relatively low sample size (n= 54 and n= 53, respectively). The largest sample size studied was 75 (Brandeker et al., 2015). Sample size was reduced by loss to follow-up in all three studies.

Two studies were identified (Brandeker et al., 2015, Lervik et al., 2010) as specifically considering the effect of glucocorticoids on outcome in dogs bitten by the European adder. No studies of time to recovery in relation to glucocorticoid treatment were found. The study by Brandeker et al. (2015) was a double-blinded randomised controlled trial and thus ranks highly in term of evidence hierarchy. It does have some limitations which somewhat reduce its value and applicability to general first opinion practice. Findings in the prospective case series by Lervik et al. (2010) are in accordance with those of Brandeker et al. (2015); however, the evidence is weaker due to study design. Lund et al. (2013) focused on adverse effects of antivenom in a prospective case series. This study is not directly related to the PICO question and is of lower evidentiary value but was accepted after full review, based on the inclusion of dogs treated with glucocorticoids.

No studies found a beneficial effect of corticosteroid treatment in these patients apart from in one case of adverse reaction to antivenom (Lund et al., 2013). No detrimental effect of corticosteroid administration was identified by the current evidence.

Two retrospective case series by Turkovic et al. (2015) and Sutton et al. (2011) provided the lowest ranking evidence considered. These were of limited use and provided statements relating to the use of glucocorticoids, which appeared to be based on conjecture, or findings relating to other snake species. These two studies are therefore not included in the evidence summary.

Summary of the evidence

Appraisal, application and reflection

Evidence pertaining to this PICO question is limited and of variable evidentiary value. The quality of evidence available is generally limited by bias due to non-standardised treatment and intervention protocols as well as potential bias towards more severely affected dogs and a reliance on measurement of subjective outcome variables. Confounders such as the amount of venom per bite, non-homogenous venom in different adder populations, location of bite, body size of dog and time to presentation are present in all three studies and are difficult to control for in a clinical research setting. Routine investigations are relatively insensitive for detecting cardiac arrhythmia and renal injury and, as such, these potential markers of clinical outcome are difficult to fully assess in these studies (Palviainen et al., 2013, Vestberg et al., 2017).These factors limit the conclusions that can be drawn from these studies regarding effects of glucocorticoids in envenomated patients.

The study by Brandeker et al. (2015) reports no difference in mental status, extent of oedema, appetite, vomiting and diarrhea, cardiac arrhythmias, C-reactive protein (CRP), prothrombin time (PT), total leucocyte count or duration of hospitalisation between prednisolone and placebo-treated groups. These findings are relevant to answering this PICO question since many of these parameters could influence clinical outcome. This study ranks highly in terms of evidence hierarchy. However, there are a number of limitations which do influence the quality of the evidence produced and its applicability in general small animal practice. The randomised and double-blinded status of this study is questioned by a lack of adequate description of the methods used and the fact that one of the outcome parameters was recorded retrospectively. There is a bias towards earlier treatment in the placebo group as demonstrated by a wider distribution of time from bite to presentation in the prednisolone-treated group compared to the placebo group. Non-standardisation of the treatment protocol beyond the initial prednisolone or placebo injection and of treatment within the prednisolone-treated group also creates problems with comparability. Dogs requiring antivenom were excluded. Whilst this eliminates this confounding factor, another source of bias is created since the patients requiring antivenom may have been more severely affected. Furthermore, information regarding the proportional group allocation of dogs excluded once they were deemed to require antivenom is not provided. Many of the outcome parameters are subjective variables with multiple observers involved, again leading to objectivity problems when comparing the two groups. A sample size calculation is not described and statistical analysis does not appear to account for confounders. Twenty-one dogs were lost to follow up and the exact proportions of cases lost to follow-up between the two groups is not described. Milder cases may have been under-represented in this study and as such the applicability to first opinion practice is limited.

Lervik et al. (2010) also compared glucocorticoidtreated dogs to non-glucocorticoid treated dogs. This study can be considered of some use in answering this PICO. Findings of no significant difference in degree of oedema and mental status between glucocorticoid-treated and non-glucocorticoid treated untreated dogs are consistent with those of Brandeker et al. (2015). This study does however suffer similar limitations to the study by Brandeker et al. (2015), in addition to its lower ranking evidentiary status due to design. Bias due to lack of randomisation, non-standardised intervention and treatments as well as the confounding effects of concurrent disease make comparisons difficult. Sample size calculation is lacking and statistical analysis is poorly reported, thus hindering interpretation of significance. There is a greater bias towards most severely affected dogs in this study since the decision to administer glucocorticoids was based on the individual clinician’s opinion. The authors discuss the fact that no difference was found in mortality rates or time to recovery between the two groups. However, this should be interpreted with caution given the fact that these parameters are not defined in the materials and methods or reported in the results. The mortality rate of dogs bitten by the European adder is reported to be between 3% and 4.8% (Sutton et al., 2011, Kängström, 1989). It is therefore possible that the lack of observed difference found in this study is due to small sample size rather than lack of effect.

The study by Lund et al. (2013) is at first glance not related to the PICO question. However, on more thorough review, it does provide some useful insights and thoughts to base further research on despite not being able to provide direct conclusive evidence specifically regarding glucocorticoid treatment and outcome. Approximately 39% of dogs in this study received steroids; two dogs developed adverse reactions to antivenom despite prior treatment with steroids. Corticosteroid administration was of benefit to one dog in this study during an adverse reaction to antivenom treatment but did not prevent adverse reaction to antivenom in two dogs. A further 19 dogs received corticosteroids in this study and did not suffer an adverse reaction to subsequent antivenom treatment. Causation cannot be established but it does suggest that further studies regarding glucocorticoid use and adverse reactions following antivenom administration would be useful. This study also suffers a number of limitations including a lack of matching of the control group, subjective outcome measures and non-standardised treatments. Confounding effects of antivenom treatment and time of glucocorticoid administration in relation to antivenom treatment are also present, which limit the study’s value.

The studies by Brandeker et al. (2015) and Lervik et al. (2010) refer to the finding of a negative association between steroid  administration and survival in dogs bitten by Vipera palaestinae (Segev et al., 2004). Whilst this finding is interesting, viper venom varies between species and individuals (Malina et al., 2017, White, 2005) and findings from this study are subject to bias due to more severely affected dogs being more likely to be administered steroids. The study by Segev et al. (2004) also fails to specify route of corticosteroid administration, dose rates and timing of administration in relation to bite. Therefore, statements basing contraindications for steroid administration on the treatment of Vipera berus envenomation, on this evidence, should be interpreted with caution.  Controlled, randomised studies involving injecting venom in canine patients could help to answer this question more fully but are very unlikely to obtain ethical approval.

In summary the main findings of this review are that extent of oedema, mental status and duration of hospitalisation are not significantly different in Vipera berus envenomated dogs treated with glucocorticoids compared to dogs receiving supportive treatment alone. Hence, there is currently no evidence that glucocorticoids improve clinical outcome in these patients. However, these findings are largely from one randomised controlled trial subject to some limitations and largely apply to dogs presenting with more severe symptoms. Little evidence exists regarding the use of glucocorticoids in dogs with mild symptoms after envenomation. Further studies are needed to fully answer the question of whether glucocorticoids should be indicated or not in these patients. Whilst there is also currently no conclusive evidence to suggest that steroids are contraindicated in dogs bitten by the European adder, clinicians should consider that administration of glucocorticoids by an owner may delay them seeking veterinary help. Given the suggestion by the current evidence that glucocorticoids are unlikely to have a large beneficial effect, and the possibility of consequent delays in seeking expert help, steroids cannot currently be recommended as an emergency treatment for owners to administer or as a necessary part of a clinical treatment protocol, other than possibly in cases of adverse reaction to antivenom.

These findings are in accordance with the human literature. Studies in humans have failed to demonstrate improvement in clinical outcome following glucocorticoid administration in snake-envenomated patients other than in cases of adverse reaction to antivenom (Karlson-Stiber et al., 2006, Boels et al., 2012). Glucocorticoid administration following Vipera berus envenomation in humans is limited to cases of acute or delayed hypersensitivity to antivenom treatment.

Further high-quality evidence through randomised controlled trials with greater standardisation of treatment protocols would be helpful in answering this question fully. It would also be of use to study dogs presenting to first opinion practice. Studies comparing time to presentation between dogs administered glucocorticoids by the owner and dogs who do not receive glucocorticoids at point of bite,  could also be helpful in building a more convincing body of evidence, for or against the use of glucocorticoids in this scenario.

Methodology Section

Search Strategy
Databases searched and dates covered:	CAB Abstracts on OVID Platform 1973 - Week 20 2018 Web of Science (clarivate analytics) 1945 - 2018 Medline on OVID platform 1902 - present Scopus (Elsevier) 1960 - present
Search terms:	Dog* OR Cani* 'european adder' OR 'european viper' OR 'viper* berus' OR adder Treatment OR steroid* OR corticosteroid* OR glucocorticoid* OR glucocorticosteroid* OR predni* OR corticoid* 1 AND 2 AND 3  The same search terms were used for each database. Related terms and synonyms were allowed.
Dates searches performed:	27.05.2018

Exclusion / Inclusion Criteria
Exclusion:	Envenomation by snake species other than Vipera berus Non-english language. Letters, book chapters, short communications. Reviews of available treatments.
Inclusion:	Studies regarding the use of glucocorticoids in canine patients envenomated by Vipera berus.

Search Outcome
Database	Number of results	Excluded – non-English language publication	Excluded – did not meet PICO question	Excluded – conference proceeding or letter	Excluded – book chapter	Excluded – duplicate	Excluded – after full review did not meet PICO question	Total relevant papers
CAB Abstracts	30	9	13	3	1	0	1	3
Web of Science	13	3	5	1	0	4	0	0
Medline	15	2	7	1	0	4	0	0
Scopus	3	0	1	0	0	2	0	0
Total relevant papers when duplicates removed								3

The author declares no conflicts of interest.

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