**4. Biosecurity**

Ranaviruses are emerging pathogens and a threat to global amphibian populations. Following the guidelines of the World Organization for Animal Health [35], biosafety measures, a set of management and physical measures designed to mitigate the risk of introduction of pathogenic agents into, or spread within, or release from, aquatic animal populations, should be implemented in aquaculture establishments.

Managing ranaviral disease in captive facilities is more straightforward than in natural populations, requiring surveillance, control measures and basic biosecurity conditions, namely for the purpose of international trade [21, 35]. The definition of compartment, one or more aquaculture establishments under a common biosecurity management system containing an aquatic animal population with a distinct health status, should encompass disease-specific epidemiological factors, the aquatic animal species in the compartment, production systems, biosecurity practices, infrastructural factors and surveillance [35].

#### **4.1 Disease surveillance**

Amphibian ranaviruses have been found in animals that are traded over international borders for a variety of reasons, including human consumption and the pet trade [14]. The OIE listing provides the impetus for disease surveillance and required testing of amphibians prior to transport among states or between nations [2, 35, 36].

Epidemiological and geographic factors should be taken into consideration in disease surveillance, as the disease status in adjacent areas and in areas epidemiologically linked to the compartment and the location, disease status and biosecurity of the nearest epidemiological units or other epidemiologically relevant premises [35, 36].

Disease transmission can occur between captive and free-ranging populations and a strategy of comprehensive disease surveillance in captive amphibians and

frog farm facilities, should be implemented. Captive breeding population health status must be considered when intended for release [2], and is not recommend wild amphibians, housed for any period of time, returned to their natural population unless been kept in isolation and their captive history consider as diseasefree [16]. Disease emergence also may occur through geographical transport of pathogens.

Ranaviruses isolated from frog farm facilities appear to be more virulent than wild strains, emphasizing the importance for disease monitoring at these facilities. In areas with multiple endemic ranaviruses strains or species, slight variations in genetic coding can increase virulence.

Isolation of positive individuals and disinfection of animal enclosures are important steps, but similar to wild populations, it is essential to minimize possible stressors and maintain proper biosafety procedures to prevent cross contamination [23].

Simultaneous infection by multiple pathogens is possible, and some diseases become evident only after the post-metamorphic (Lucke's tumor herpesvirus). Also, the lack of gross signs of disease does not imply healthy populations, as tadpoles with no signs of illness can be infected with ranaviruses [2].

In the event of a die-off in a captive facility, freshly dead animals should be submitted for diagnostic evaluation. Live animals that are infected should be euthanized or treated, if a treatment exists, and facilities decontaminated with disinfectant [2]. To identify the causal factors for outbreaks, ideally host densities and stages of development, water and ambient temperature, and water quality should be measured during surveillance programs [36].

Testing for Ranavirus can be done with lethal and non-lethal samples. Testing liver samples for infection is a common lethal sampling technique to estimate ranavirus prevalence because the pathogen often targets this organ, especially in larval amphibians, and the liver is easy to identify and collect [11].

False negative can result from testing tail clips in [2, 11], and occur when the number of virions circulating in the host's tissues is low, or few virions are shed [11]. Lethal samples (organ tissue) will likely result in greater detection of ranavirus compared to nonlethal samples (swabs, tail-clips) [11, 36]. Non-lethal sampling techniques can be useful for ranavirus surveillance, although the prevalence of infection may be underestimated when compared to results obtained with liver samples [11].

Sample collection may include whole live or dead animals, sections of tissues, swabs of lesions or orifices or habitat samples. To prevent disease transmission between infected and uninfected individuals [17] and protect professionals from zoonotic diseases, is mandatory wearing disposable gloves when handling amphibians and, between animals, change gloves. When handling amphibians, professionals should use disposable vinyl or nitrile gloves, rinsed with distilled or sterilized water [2, 16]. Dipping gloves into disinfectant between processing animals might reduce iatrogenic pathogen transmission, however, these practices may have toxic effects on wild animals [17].

Samples can be frozen in a standard 20 °C freezer if stored for short duration (1 month); otherwise, should be stored in an 80 °C freezer. Samples can also be promptly fixed in 75% ethanol or 10% neutral buffered formalin for histology. Swabs are typically performed in the oral then cloacal regions, and the swab stored, placed on ice and frozen similar to tissues [2].

Lethal infectious diseases of amphibians may response to stressors, whether anthropogenic or natural [2], and some natural factors are host density, species composition, temperature, and host development [36]. Prevention of the spread of endemic diseases to naive populations or species is a high conservation *Frog Virology: Biosafety in an Experimental Farm DOI: http://dx.doi.org/10.5772/intechopen.96605*

priority [2], thus is very important to implement appropriate strategies to minimize this risk [16].

No treatment or vaccine are currently available for ranaviruses [9, 16], but the potential for development of a Ranavirus vaccine is promising particularly considering that prior infection with a ranavirus led to enhanced immunity against subsequent exposure [37], particularly valuable in captive populations [21].

Organizations with limited knowledge about ranaviruses, in the region, supplementary efforts and time are required to document the distribution of ranaviruses, identify infection hotspots, and implement disease intervention strategies that thwart the introduction of ranavirus or reduce its prevalence [36].

#### **4.2 Human and animal safety**

Commercial exchange of live amphibians for food, pets, and laboratory animals may be adversely influencing wild populations by direct harvesting or through the spread of disease. Ranaviruses can remain viable outside of hosts for a considerable duration, and can be transported on sampling equipment, recreational gear and fomites [21, 25, 34].

Few infectious diseases of amphibians are contagious to humans, even if mandatory the decontamination of surfaces that come in contact with water bodies that contain amphibians to stop the unnecessary spread of the pathogen [21, 34]. Professionals should wear sanitary wear protection, gloves and waterproof footwear, easily disinfected, when monitoring or capturing animals. Disposable gloves should be worn whenever handling amphibians, and hands washed thoroughly after removing gloves [2].

A correct distinction between cleaning, disinfecting, and sterilizing should be considered. Cleaning refers to the action of physically removing organic and inorganic debris. Disinfecting reduces the load of contaminating organisms to a large extent, but not completely. For a well-established amphibian collection, that has had no infectious diseases or new specimens added within a year, there is little need to attempt to sterilize cages and tools. However, if a collection is experiencing disease, and/or is adding new animals, items should be sterilized [38].

Washing and disinfecting equipment is recommended whether in the presence of pathogens or not [2]. Disinfectants must be safe for use with amphibians and must inactivate a significant proportion of Ranavirus to be considered effective [9]. Common disinfectants used are chlorhexidine [2], potassium compounds [9] and sodium hypochlorite (bleach) [9, 16, 19]. Bleach is often preferred because it is cost effective, easily obtained, and effective against most bacteria and many viruses. However, bleach is not very effective at inactivating Ranavirus, requiring at least a 3% concentration [2, 9] for 10 to 15 minutes between animals [9, 16, 19] which can be toxic to amphibians. In contrast, chlorhexidine used at a dosage that is safe for amphibians (0.75% for a 1-minute exposure) can inactivate Ranavirus [2, 9]. For potassium peroxymonosulfate is recommend at 1.0% solution for disinfecting equipment for 10 minutes [9]. After disinfection, equipment may be allowed to air dry or rinsed with clean water [2].

Proper health of any aquaculture operation depends on water quality, proper nutrition, quarantine and sanitation. Warm (e.g., >25 °C) and frequently filtered water, along with low host densities, may be good preventative strategies to minimize ranavirus outbreaks in captivity [23, 39]. Sanitation can be achieved by: avoid accumulation of organic matter; disinfections of nets and other equipment used; and providing clean environment [32, 40].

Morbid animals and carcasses should not be released or discarded at the same or other sites because this may facilitate the spread or persistence of infectious

diseases. Dead amphibians that are not used for testing should be placed in doublelayered plastic trash bags and disposed by burial or incineration [2, 22, 41].

## **4.3 Recommended procedures – biosafety plan**

Health examinations to captive anuran and good biosecurity methods need to be employed because, often, little is known about the life cycles of infectious diseases, modes of transmission, and the persistence of the pathogen within and outside the amphibian host. The goal of biosecurity is to prevent mechanical transmission of pathogens and contaminants from one location to another by equipment, supplies and people, involving the safety of the humans and animals and disinfection of facilities and equipment [2].

In many cases, a pathogen will only cause disease in a host if environmental conditions are favorable. Such circumstances cause prevalence of disease in a population and leads to host mortality in frog farm facilities or wild populations. In general, the most important environmental factors affecting pathogen survival are temperature, moisture and solar, although pH, the presence of organic matter and exposure to chemicals can also be important [1].

The biosecurity program of a production unit must use healthy and disease-free breeders [32, 35, 41]; disease testing of all incoming lots [19]; treatment of water to eliminate pathogens [41]; sterilization and maintenance of materials and equipment; use of personal hygiene measures including hand, footwear, and clothing washing [16]; knowledge of potential pathogens, sources of risk and methods for their control and eradication; development and use of batches that are resistant to specific pathogens; and maintaining the environment in optimal conditions within all phases of quarantine [41].

Structural aspects should, then, be considered as the water supply (an effective transmission medium for ranaviruses) warm and frequently filtered; effective means of physical separation and facilities for people entry including access control; vehicle and vessel access [2, 23, 35]. Inadequate transportation prior to arrival at the facility, inappropriate housing and overcrowding are husbandry practices that facilitate infection diseases [18, 32].

Facilities should also consider location (isolation from other facilities); animal management and practices (unloading and loading); facilities for the introduction of material and equipment; infrastructure to store feed and veterinary products, and isolation facilities for introduced aquatic animals (quarantine) [18, 32, 35].

Quarantine is a vital component of a production-level biosecurity program, which includes a set of standard used procedures and is an essential part of good management for research facilities or farms. It is an important risk management measure and is a key activity that should be considered when developing strategies during farm production [41]. Quarantine areas can be relatively rustic for this purpose [22] and enclosures should be easily disinfected [39].

The protocol should include a detailed clinical examination that includes monitoring the animal's weight, physical posture, and changes in appearance. At least one blood smear can provide important information on the animal's health, stress, and immune status. A stool examination should be performed [22] as well as microbial culture of the oropharynx and cloaca. Diligent surveillance of the amphibian is essential for successful quarantine. Feeding time generally stimulates activity and allows to assess the amphibian's vigor and appetite [39].

A minimum length of 30 days is recommended for the quarantine period of any amphibian that arrived with a clean fecal sample, but often 60 days of quarantine is needed to process an amphibian through a prophylactic protocol. Wild-caught amphibians, whether obtained directly or indirectly, should be held for an extended quarantine of 90 days or more [19, 22, 41]. This is also recommended for amphibians of unknown origin and those that have been exposed to especially stressful conditions during shipment or prior to shipment.

Quarantine tools and cages should be maintained well separated from established amphibians. New and ill amphibians should be serviced after the healthy and established members of a collection. Disposable vinyl or nitrile gloves are recommended [16, 17] when working with the quarantined amphibians [34]. Washing and disinfection procedures; disposal of aquatic animal waste; measures to prevent exposure to fomites or vectors; feed supply/source are hygienic or nutritional measures determent not only in the quarantine facility but in all the farm, integrating a well-designed Biosecurity Plan [21, 35, 36, 41].

The integrity of an experimental farm relies on effective biosecurity, with the implementation and monitorization of a biosecurity plan [21]. Following OIE guidelines, this plan integrate the potential pathways for introduction of identified (aquatic animal movements, wild aquatic animals, potential vectors, vehicles, people, biological products, equipment, fomites, feed, waterways); the critical control points for each pathway; measures to mitigate exposure for each critical control point; standard operating procedures; corrective actions; process verification and documentation; contingency plan; educating and training program (for workers, farmers and students) and a surveillance program [35, 36].
