Abstract
We reviewed the literature in an attempt to determine the importance of aseptic technique when implanting electronic tags in fish. Given that there was negligible information on this topic we embarked on a study where bluegill (Lepomis macrochirus) were used as a model to investigate the effects of different aseptic surgical techniques for the intracoelomic implantation of electronic tags in fish. First we tested the effects of water entry into the incision using five treatments: lake, distilled and saline water introduced into the incision, water-free controls, and non-surgery controls. For fish in the water treatments, 1 mL of the sample was introduced into their coelom prior to incision closure. Fish were held for 10 days to monitor survival and at the end of the study, the survivors were blood sampled and euthanized to evaluate condition and health using the health assessment index. In a second experiment, four aseptic treatments were used: non-sterile, field-based, high-grade sterility, and non-surgery controls and fish were monitored as in the first experiment. For both experiments, no differences in physiological status, health or mortality were noted among treatment groups. However, in the aseptic techniques experiment, surgical times were approximately twice as long for fish in the sterile treatment as compared to other groups and the costs of surgical supplies was greater than that of the less-sterile treatments. Although we failed to document any benefit of keeping water out of the incision or using aseptic technique for bluegill, in other situations and for other species, such approaches may be important. As such, we encourage fish surgeons practicing intracoelomic implants to attempt to prevent water entry into the coelom. We also encourage, at least some level of infection control (e.g., non-sterile gloves, clean tags and surgical tools) consistent with good veterinary practices to maintain the welfare status of tagged fish and ensure that the data from tagged fish representative of untagged conspecifics. However, the most prudent and ethical approach would be to work with veterinarians to incorporate formal sterilization procedures, equipment (e.g., sterile gloves) and aseptic technique into field surgical techniques.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adams SM, Brown AM, Goede RW (1993) A quantitative health assessment index for rapid evaluation of fish condition in the field. Trans Am Fish Soc 122:63–73
Barton BA, Iwama GK (1991) Physiological changes in fish from stress in aquaculture with emphasis on the response and effects of corticosteroids. Annu Rev Fish Dis 1:3–26
Barton BA, Morgan JD, Vijayan MM (2002) Physiological and condition-related indicators of environmental stress in fish. In: Adams SM (ed) Biological indicators of stress in fish. American Fisheries Society, Bethesda, pp 111–148
Block BA (2005) Physiological ecology in the 21st century: advancements in biologging science. Integr Comp Biol 45:305–320
Bridger CJ, Booth RK (2003) The effects of biotelemetry transmitter presence and attachment procedures on fish physiology and behaviour. Rev Fish Sci 11:13–34
Brown LA, Richards RH (1979) Surgical gonadectomy of fish: a technique for veterinary surgeons. Vet Rec 104:215
Cooke SJ (2008) Biotelemetry and biologging in endangered species research and animal conservation: relevance to regional, national, and IUCN Red List threat assessments. Endanger Species Res 4:165–185
Cooke SJ, Wagner GN (2004) Training, experience, and opinions of researchers who use surgical techniques to implant telemetry devices into fish. Fisheries 12:10–18
Cooke SJ, Graeb BDS, Suski CD, Ostrand KG (2003) Effects of suture material on incision healing, growth and survival of juvenile largemouth bass implanted with miniature radio transmitters: case study of a novice and experienced fish surgeon. J Fish Biol 62:1360–1388
Cooke SJ, Hinch SG, Wikelski M, Andrews RD, Wolcott TG, Butler PJ (2004) Biotelemetry: a mechanistic approach to ecology. Trends Ecol Evol 19:334–343
Cooke SJ, Suski CD, Danylchuk SE, Danylchuk AJ, Donaldson MR, Pullen C, Bulte G, O’Toole A, Murchie KJ, Goldberg TL (2008) Effects of capture techniques on the physiological condition of bonefish (Albula vulpes) evaluated using field physiology diagnostic tools. J Fish Biol 73:1351–1375
Cooke SJ, Woodley CM, Eppard MB, Brown RS, Nielsen JL (2011) Advancing the surgical implantation of electronic tags in fish: a gap analysis and research agenda based on a review of trends in intracoelomic tagging effects studies. Rev Fish Biol Fisheries. doi:10.1007/s11160-010-9193-3
Copeland SE, Ladd LA, Gu XQ, Mather LE (2008) The effects of general anesthesia on the central nervous and cardiovascular system toxicity of local anesthetics. Anesth Analg 106:1429–1439
Gallepp GW, Magnuson JJ (1972) Effects of negative buoyancy on the behavior of the bluegill, Lepomis macrochirus Rafinesque. Trans Am Fish Soc 101:507–512
Harms CA (2005) Surgery in fish research: common procedures and postoperative care. Lab Anim 34:28–34
Harms CA, Lewbart GA (2000) Surgery in fish. In: Bennett RA (ed) Veterinary clinics of North America: exotic animal practice. Saunders Co., New York, pp 759–774
Hill JV, Davison W, Forster ME (2002) The effects of fish anaesthetics (MS222, metomidate and AQUI-S) on heart ventricle, the cardiac vagus and branchial vessels from Chinook salmon (Oncorhynchus tshawytscha). Fish Physiol Biochem 27:19–28
Knights BC, Lasee BA (1996) Effects of implanted transmitters on adult bluegills at two temperatures. Trans Am Fish Soc 125:440–449
Litwack G (1955) Photometric determination of lysozyme activity. Proc Soc Exp Biol Med 89:401–403
Lucas MC, Baras E (2000) Methods for studying the spatial behaviour of freshwater fishes in the natural environment. Fish Fish 1:283–316
Maule AC, Schrock R, Slater C, Fitzpatrick MC, Schreck CB (1996) Immune and endocrine responses of adult chinook slamon during freshwater immigration and sexual maturation. Fish Shellfish Immunol 6:221–233
Mulcahy DM (2003) Surgical implantation of transmitters into fish. ILAR J 44:295–304
Murray MJ (2002) Fish surgery. Sem Avian Exotic Pet Med 11:246–257
Paukert CP, Willis DW (2002) Seasonal and diel habitat selection of bluegills in a shallow natural lake. Trans Am Fish Soc 131:1131–1139
Paukert CP, Chvala PJ, Heikes BL, Brown ML (2001) Effects of implanted transmitter size and surgery on survival, growth, and wound healing of bluegill. Trans Am Fish Soc 130:975–980
Paukert CP, Willis DW, Bouchard MA (2004) Movement, home range, and site fidelity of bluegills in a Great Plains lake. N Am J Fish Manage 24:154–161
Prince ED, Maughan OE (1978) Ultrasonic telemetry technique for monitoring bluegill movement. Prog Fish Cult 40:90–93
Stoskopf MK (1993) Surgery. In: Stoskopf MK (ed) Fish medicine. Saunders, Philadelphia, pp 91–97
Summerfelt RC, Smith LS (1990) Anesthesia, surgery, and related techniques. In: Schreck CB, Moyle PB (eds) Methods in fish biology. American Fisheries Society, Bethesda, pp 213–272
Wagner GN, Cooke SJ (2005) Methodological approaches and opinions of researchers involved in the surgical implantation of telemetry transmitters in fish. J Aquat Anim Health 17:160–169
Wagner GN, Stevens D, Harvey-Clark C (1999) Wound healing in rainbow trout following surgical site preparation with a povidone-iodine antiseptic. J Aquat Anim Health 11:373–382
Wagner GN, Stevens D, Byrne P (2000) Effects of suture type and patterns on surgical wound healing in rainbow trout. Trans Am Fish Soc 129:1196–1205
Wang WB, Wang YP, Hu W, Li AH, Cai TZ, Zhu ZY, Wang JG (2006) Effects of the “all-fish” growth hormone transgene expression on non-specific immune functions of common carp, Cyprinus carpio L. Aquaculture 259:81–87
Acknowledgments
We thank the staff of the Queen’s University Biology Station for assistance. Financial support for the project was provided by the Canada Foundation for Innovation, the Natural Science and Engineering Research Council, and the Ontario Ministry of Research and Innovation. All experiments were conducted in accordance with the Canadian Council of Animal Care Guidelines as administered by Carleton University. The Ontario Ministry of Natural Resources kindly provided a scientific collection permit. We thank Karen Murchie and three anonymous referees for comments on the manuscript.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Chomyshyn, L., McConnachie, S.H. & Cooke, S.J. Evaluation of water entry into the coelom and different levels of aseptic technique during surgical implantation of electronic tags in freshwater fish. Rev Fish Biol Fisheries 21, 61–70 (2011). https://doi.org/10.1007/s11160-010-9189-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11160-010-9189-z