Evaluation of the effects of tramadol on analgesic response and locomotor activity on two different strains of laboratory mice


IRENE SYMEON
ALEXIA POLISSIDIS
EVANGELOS BALAFAS
MARIANNA STASINOPOULOU
PAVLOS ALEXAKOS
CHRYSA VOYIATZAKI
NIKOLAOS KOSTOMITSOPOULOS
Abstract
Analgesia of laboratory animals consists an important component in experimental studies where painful stimuli or procedures may take place. When choosing analgesics, the severity of pain along with the response to medication is among the factors that determine the choice of agent. Tramadol is a known synthetic opioid analgesic used to treat main acute or chronic pain including perioperative pain. The purpose of this study was to evaluate the analgesic response as well as the effect on locomotor activity in two different strains of mice after the intraperitoneal (i.p.) administration of tramadol. Subjects were 11-13 week-old male C57BL/6J (n=39) and BALB/cJ (n=38) mice, randomly assigned to receive either saline, tramadol 10 mg/kg or tramadol 40 mg/kg. Analgesia was measured using the hot-plate test, 30 or 60 minutes after drug administration while the open field test was used in order to assess locomotor activity. Both strains exhibited a significant increase of hot-plate latencies after administration of tramadol 40 mg/kg while the same dose induced significantly greater analgesia in BALB/cJ as compared with the C57BL/6J mice. BALB/cJ mice presented a dose-dependent decrease in locomotor activity following tramadol administration whereas C57BL/6J mice receiving 40 mg/kg tramadol showed hyperactivity. In conclusion, the lower dose of tramadol (10 mg/kg) has insufficient antinociceptive effects on acute thermal pain for both strains. The highest dose of tramadol used in this study (40 mg/kg) was greater than the one required for BALB/cJ mice, as they were under sedation for at least 60 minutes after drug administration. The same dose of tramadol appeared to be effective on C57BL/6J tramamice as latency times on the hot plate were significantly increased. Despite this fact, it is not a suitable choice as an analgesic, especially postoperatively, as it causes hyperactivity to this strain. Special concern should be given to the fact that tramadol’s analgesic and behavioral effects depend not only on its dosage, but also on the strain in which it is administered.
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Literaturhinweise
Aydin ON, Ek RO, Temoçin S, Uğur B, Alaçam B, Şen S (2012) The antinociceptive effects of systemic administration of tramadol, gabapentin and their combination on mice model of acute pain. Agri (The Journal of the Turkish Society of Algology) 24:49-55.
Bannon AW, Malmberg AB (2007) Models of nociception: hot-plate, tail-flick, and formalin tests in rodents. Curr Protoc Neurosci 41:8.9.1.-8.9.16.
Belknap JK, Lamé M, Danielson PW (1990) Inbred strain differences in orphineinduced analgesia with the hot plate assay: a reassessment. Behav Genet 20:333-8.
Cannon CZ, Kissling GE, Hoenerhoff MJ, King-Herbert AP, Blankenship-Paris T (2010) Evaluation of dosages and routes of administration of tramadol analgesia in rats using hot-plate and tail-flick tests. Lab Anim (NY). 2010 39: 342-51.
Carbone ET, Lindstrom KE, Diep S, Carbone L (2012) Duration of action of sustainedrelease buprenorphine in 2 strains of mice. J Am Assoc Lab Anim Sci 51:815-9.
Carola V, D’Olimpio F, Brunamonti E, Mangia F, Renzi P (2002) Evaluation of the elevated plus-maze and open-field tests for the assessment of anxiety-related behaviour in inbred mice. Behav Brain Res 134:49-57.
Duthie DJ (1998) Remifentanil and tramadol. Br J Anaesth 81:51-7.
FELASA working group on revision of guidelines for health monitoring of rodents and
rabbits, Mähler Convenor M, Berard M, Feinstein R, Gallagher A, Illgen-Wilcke B, Pritchett-Corning K, Raspa M. (2014) FELASA recommendations for the health monitoring of mouse, rat, hamster, guinea pig and rabbit colonies in breeding and experimental units. Lab Anim. 48:178-192.
Flecknel P, Liles JH (1991) The effects of surgical procedures, halothane anaesthesia
and nalbuphine on locomotor activity and food and water consumption in rats. Lab
Anim. 25:50-60.
Flecknel P (2009) Analgesia and Post-operative Care. Laboratory Animal Anaesthesia.
UK: Academic Press, p 139-79.
Gould TD, Dao DT, Kovacsics CE (2009) The Open Field Test. In: Gould TD, (ed.). Mood and Anxiety Related Phenotypes in Mice. Humana Press, p 1-20.
Hall CB, Ballachey EL (1932) A study of the rat’s behavior in a field. A contribution to method in comparative psychology. University of California Publications in Psychology 6:1-12.
Heavmer JE (1997) Pharmacology of Analgesics. In: Kohn SF WS, White WJ, Benson GJ., (ed.). Anesthesia and Analgesia in Laboratory Animals. San Diego, California: Academic Press, p 43-56.
Ide S, Minami M, Ishihara K, Uhl GR, Sora I, Ikeda K (2006) Mu opioid eceptordependent and independent components in effects of tramadol. Neuropharmacology 51:651-658.
Jansen van’t Land C, Hendriksen CF (1995) Change in locomotor activity pattern in mice: a model for recognition of distress? Lab Anim. 29:286-93.
Korostynski M, Kaminska-Chowaniec D, Piechota M, Przewlocki R (2006) Gene expression profiling in the striatum of inbred mouse strains with distinct opioidrelated phenotypes. BMC Genomics 7:146.
Liang JH, Wang K, Sun HL, Han R (2006) Potentiating effect of tramadol on methamphetamine-induced behavioral sensitization in mice. Psychopharmacology (Berl)185:1-10.
Mattia A, Vanderah T, Raffa RB, Vaught JL, Tallarida RJ, Porreca F (1993) Characterization of the Unusual Antinociceptive Profile of Tramadol in Mice. Drug Development Research 28: 176-82.
McKeon GP, Pacharinsak C, Long CT, Howard AM, Jampachaisri K, Yeomans DC, Felt
SA (2011) Analgesic effects of tramadol, tramadol-gabapentin, and buprenorphine in an incisional model of pain in rats (Rattus norvegicus). J Am Assoc Lab Anim Sci 50:192-7.
Miranda HF, Pinardi G (1998) Antinociception, Tolerance, and Physical Dependence Comparison Between Morphine and Tramadol. Pharmacol Biochem Behav 61:357-60.
Mogil JS, Wilson SG, Bon K, Lee SE, Chung K, Raber P, Pieper JO, Hain HS, Belknap JK, Hubert L, Elmer GI, Chung JM, Devor M (1999) Heritability of nociception I: responses of 11 inbred mouse strains on 12 measures of nociception. Pain 80: 67-82.
Murphy NP, Lam HA, Maidment NT (2001) A comparison of morphine-induced locomotor activity and mesolimbic dopamine release in C57BL6, 129Sv and DBA2 mice. J Neurochem 79: 626-35.
Nolan AM (2000) Pharmacology of Analgesic Drugs. In: Flecknel P, Waterman-Pearson, A., (ed.). Pain Management in Animals. Newcastle Upon Tyne, UK: Saunders Ltd., p 21-52.
O’Leary TP, Gunn RK, Brown RE (2013) What are we measuring when we test strain
differences in anxiety in mice? Behav Genet 43:34-50.
Rätsep MT, Barrette VF, Winterborn A, Adams MA, Croy BA (2013) Hemodynamic and behavioral differences after administration of meloxicam, buprenorphine, or tramadol as analgesics for telemeter implantation in mice. J Am Assoc Lab Anim Sci 52:560-6.
Szkutnik-Fiedler D, Kus K, Balcerkiewicz M, Grześkowiak E, Nowakowska E, Burda K, Ratajczak P, Sadowski C (2012) Concomitant use of tramadol and venlafaxine - evaluation of antidepressant-like activity and other behavioral effects in rats. Pharmacol Rep 64:1350-8.
Tzschentke TM, Bruckmann W, Friderichs E (2002) Lack of sensitization during place conditioning in rats is consistent with the low abuse potential of tramadol. Neurosci Lett. 329:25-8.
Zhang Y, Du L, Pan H, Li L, Su X (2011) Enhanced analgesic effects of propacetamol and tramadol combination in rats and mice. Biol Pharm Bull 34: 349-53.
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