Open-access Safety and efficacy of ketamine xylazine along with atropine anesthesia in BALB/c mice

Abstract

Anesthetics are an indispensable prerequisite for surgical intervention and pharmacological animal studies. The objective of present study was to optimize the dose of ketamine (K) and xylazine (X) along with atropine sulfate (A) in order to achieve surgical tolerance in BALB/c mice. Several doses of ketamine (100, 150, 200 mg/kg) and xylazine (10, 15, 20 mg/kg) were mixed and combination of nine doses (K/X: 100/10, 100/15, 100/20, 150/10, 150/15, 150/20, 200/10,200/15,200/20) were evaluated (n=9 per combination). A constant dose of atropine (0.05 mg/kg) was also used to counter side effect. Time-related parameters were evaluated on the basis of reflexes. KX at dose 200/20 mg/kg produced surgical tolerance in all nine mice with duration 55.00±6.87 minutes. The induction time 0.97±0.09 minutes, sleeping time 90.67±5.81 minutes and immobilization time (102.23±6.83 minutes) were significantly higher than all combination. However, this combination was considered unsafe due to 11 % mortality. While, KX at dose 200/15 mg/kg results in none of the mortality, so was considered as safe. Moreover, this combination produces surgical tolerance in 89 % mice with duration (30.00±7.45 minutes). It was concluded that KX at dose 200/15 mg/kg along with atropine 0.05 mg/kg is safe for performing surgical interventions in BALB/c mice.

Keywords: Ketamine hydrochloride; Xylazine hydrochloride; Atropine sulfate; Surgical tolerance; BALB/c mice


INTRODUCTION

The mouse is regarded as a model animal for biomedical research (Popova et al., 2002). Anesthesia in the mouse is an indispensable prerequisite for surgical interventions as well as pharmacological animal studies (Chong et al., 2016). Moreover, an increasing number of transgenic mouse models are being explored by the scientific community, to evaluate the functional and patho-physiological consequences of gene manipulation (Zuurbier et al., 2014). Anesthesia usually comprises of two or more drugs, because no single drug is consider as an ideal for providing anesthesia (Alves et al., 2009; Arras et al., 2001). Methods of induction and maintenance of anesthesia include gaseous and injectable anesthetics. Although gaseous anesthetics provide good control over anesthesia depth but equipment cost and lack of skilled manpower limit their use (Buitrago et al., 2008).

The selection of anesthetic depends upon drug availability, safety, and attainment of surgical tolerance (Arras et al., 2001). Surgical tolerance is the stage of anesthesia during which animal is completely unconscious from surrounding and has no pain perception (Arras et al., 2001; Buitrago et al., 2008). This is the most significant parameter in the selection of an anesthetic during this stage, and surgical interventions are performed and duration of surgical interventions also depends upon the duration. Mostly dissociative drugs (ketamine, K) with α2-agonists (xylazine, X) are commonly used for mice (Arras et al., 2001; Chaves, Weinstein, Bauer, 2001; Buitrago et al., 2008; Alves et al., 2009). But it is documented that, KX at recommended doses do not produce surgical tolerance in all animals (Arras et al., 2001; Chaves, Weinstein, Bauer, 2001; Dittmar et al., 2004; Kawahara et al., 2005; Chu et al., 2006), therefore, some other drugs are added to produce surgical tolerance. In this regard, acepromazine with KX is considered as best combination due to its safety and surgical tolerance (Arras et al., 2001; Buitrago et al., 2008). Since acepromazine is not available in the local market, an alternate need to be search and various doses of KX in conjunction with the new drug need to be readjust.

Anticholinergic drugs such as atropine sulfate (A) are commonly used as pre-anesthetic and reduce hypersalivation and bradycardia induced by ketamine (Wellington, Mikaelian, Singer, 2013). Moreover, atropine along with KX is frequently used in veterinary practices (Cruz et al., 2000). Therefore, the objective of the present study was to select the best dose of KX along with atropine that should be safe and produce surgical tolerance for performing surgical interventions in BALB/c mouse.

MATERIAL AND METHODS

Male BALB/c mice at the age of 9-10 weeks, maintained at mice housing facility, Department of Theriogenology, University of Veterinary and Animal Sciences, Lahore, Pakistan were selected. Mice were housed in 12 hours dark-light cycles and were cared for according to animal protocols approved by the ethical committee. All chemicals were of high grade and purchased from Sigma-Aldrich.

Experimental design

Three doses (100, 150, 200 mg/kg) of ketamine and three doses (10, 15, 20 mg/kg) of xylazine along with constant dose (0.05 mg/kg) of atropine sulfate were mixed. Total nine combinations (KX: 100/10, 100/15, 100/20, 150/10, 150/15, 150/20, 200/10, 200/15, 200/20) with constant dose of atropine (0.05 mg/kg) were prepared. All combinations were diluted in sterile saline and 0.1 mL per 10 g of body weight was injected intraperitoneally (Timeline 1). Once the righting reflex was lost, mice were placed on a heated platform and their eyes were lubricated with normal saline.

TIME LINE 1
Experimental Design. A constant dose of atropine (0.05 mg/kg) was added in each combination and n=9 mice per each combination were used.

The reflexes monitored were cutaneous reflex (CR), tail pinch reflex (TPR), pedal withdrawal reflex (PWR), corneal reflex (Cr.R) and righting reflex (RR). All reflexes were assessed as described previously (Foote, Livingston, 1978; Arras et al., 2001; Buitrago et al., 2008; Stoicea et al., 2016). Briefly, the CR was assessed by pinching needle at the abdomen. The TPR was monitored by pinching at the tip of the tail. For assessing PWR, the hind limb was slightly extended and the interdigital webbing of the foot firmly was pinched between thumb and index finger and this reflex was monitored alternatively between the left and right hind limbs. Movement from dorsal to sternal recumbency was considered RR. All these reflexes were monitored from loss of RR to spontaneous movement at the interval of five minutes. Reflexes were monitored by scoring system: 0 (no response), 1 (weak response), 2 (moderate response) and 3 (strong response). Time-related parameters are demonstrated in timeline 2. All parameters were assessed by the same operator to reduce variability in the experiment.

TIME LINE 2
Time related parameters
Data analysis

The statistical analyses were performed using statistical software SAS Enterprise Guide (version 4.2; SAS Inst. Inc., Cary NC, USA) and statistical significance was set at p<0.05. Data for all parameters were presented as mean ± S.E.M. The means were separated using Tukey’s test. Data for three doses of two anesthetic groups were analyzed as 3 x 3 factorial model using Proc Mixed procedure of SAS. The groups were separated using pdmix800 utility. Chi-square test was used for analyses of the number of mice attaining surgical tolerance.

RESULTS AND DISCUSSION

All doses of ketamine and xylazine along with atropine were evaluated for their safety on the basis of mice attaining surgical tolerance and death rate. The surgical tolerance (Table I) showed that highest dose of KX (200/20 mg/kg) produced surgical tolerance in all nine mice with maximum duration 55.00±6.87 minutes and 11 % death rate (1/9). While 200/15 mg/kg KX produced surgical tolerance in eight mice without any death. Hence 200/15 mg/kg KX was consider as a safe. Furthermore, induction time at 200/15 mg/kg KX was comparable with all combinations except 100/10, 100/20 mg/kg KX. However, the duration of immobilization (102.23±6.83 minutes) and surgical tolerance (55.00±6.87 minutes) at 200/20 mg/kg KX was significantly higher from other combinations. Similarly, the sleeping time at KX (200/20 mg/kg) was significantly higher than other combinations except KX (200/10 mg/kg). While the recovery period at KX (200/15 mg/kg) was comparable with all combination. When the duration of different reflexes was analyzed, the duration of PWR, CR, TPR, Cr.R, and TS at KX (200/20 mg/kg) was significantly higher (Table II) than other combinations. Duration for the onset of different reflexes (Table III) represented that onset of CR, Cr.R, and TS was quick in KX (200/20 mg/kg) as compared to other combination suggesting that the onset of these reflexes result after injecting anesthesia. However, the onset of PWR and TPR in KX (200/20 mg/kg) were comparable with others.

TABLE I
Comparison of safety, efficacy and time related parameters using different doses of ketamine/xylazine in BALB/c mouse
TABLE II
Comparison of duration of various reflexes using different doses of ketamine/xylazine in BALB/c mouse
TABLE III
Comparison of onset of various reflexes of anesthesia using different doses of ketamine/xylazine in mouse

The significance of an anesthetic depend on safety and efficacy which is evaluated on the basis of mortality rate and surgical tolerance (Arras et al., 2001). In the present study, the attainment of this stage was observed in dose-dependent manner. Five mice (out of nine) attained at the lowest dose (KX: 100/15 mg/kg) and all mice (9/9) attained at the highest dose (KX: 200/20 mg/kg). The duration of surgical tolerance was also dose-dependent. The lowest dose of KX (100/10 mg/kg) produce 15.00±5.8 minutes while the highest dose (200/20 mg/kg KX) produce 55.00±6.87 minutes. However, some variations were observed at dose 100/20 KX and 150/20 mg/kg KX as only three mice (3/9) attained tolerance with low duration (Table I). Similar variations about KX are already reported (Green et al., 1981). The possible reason for such variability are mouse age, nutrition, and liver metabolism. It is documented that short-term fasting before anesthesia leads to increase drug metabolism resulting in decrease response. Moreover, failure of injection site (injection into muscle or sub cut tissue instead of peritoneum) may be another contributing factor because up to 20% failure rate had been reported (Struck et al., 2011).

The data for mortality rate revealed that all doses of KX are safe for mouse except the highest one (KX: 200/20 mg/kg) as one mouse (1/9) was found dead at this dose (Table I). The death may be due to hypotension (Picollo et al., 2012), cardiac arrhythmias and hypersalivation (Green et al., 1981) produced by KX. These findings were not in line with previous studies where it was reported that KX caused significant mortalities at the recommended dose. The decreased mortality could be due to the addition of the anticholinergic drug, atropine sulfate as it subsides cardiac dysfunctions and hypersalivation. Moreover, atropine produces sedation by crossing blood brain-barrier (Lu et al., 2014) and also increase the sleeping time (Foote, Livingston, 1978). Furthermore, age, sex, genetic and environmental factors as well as inherent inter-individual variability might have contributed to anesthetic variability (Struck et al., 2011).

The purpose of anesthesia is analgesia and unconsciousness. Different reflexes such as cutaneous reflex, tail pinch reflex, pedal withdrawal reflex, corneal reflex and tactile stimuli (Green et al., 1981; Arras et al., 2001) were used for pain perception and anesthesia depth. The onset of all reflexes revealed that PWR disappeared later and re-appeared earlier than other reflexes (Table III). Although cutaneous reflex, tail pinch reflex, tactile stimulus were also used for pain perception, their onset was earlier and remained absent while PWR was still present. Hence, PWR is the best indicator of anesthetic depth as it disappears later and reappears earlier than all other reflexes (Arras et al., 2001; Buitrago et al., 2008; Alves et al., 2009; Struck et al., 2011). The duration of loss of PWR was increased with dose and maximum duration (55.00±6.87 minutes) was observed at the highest dose (KX: 200/20 mg/kg) (Table II). However, the duration was compromised at (KX: 100/20, 150/20 mg/kg). This may be due to the decrease in response of mice attaining surgical tolerance (Table I). Moreover, inter-individual variations are also reported at same dose. The duration of PWR revealed that KX: 200/20 mg/kg is the best than all other doses as it produces 55.00±6.87 minutes anesthesia.

On the basis of attainment of surgical tolerance, and loss of reflexes although KX; 200/20 mg/kg was the best for surgical interventions but one mouse (1/9) was found dead which render this dose unsafe to be used as anesthesia. While KX: 200/15 mg/kg was considered safe as no mouse found dead (Table I). Moreover, this dose produces surgical tolerance of 30.00±7.45 minutes. This dose was considered best for surgical intervention.

Best anesthetic is one which has minimum induction, acceptable surgical tolerance and quick recovery with no mortalities. The dose (KX: 200/15 mg/kg) has the similar response like low induction time (1.04±0.17 minutes) with the surgical tolerance of 30 minutes. Moreover, the recovery period was minimized (11.85±3.3 minutes) without mortality (Table I). However, some surgeons prefer anesthetic with minimum duration to potentiate their efficiency so they use lower doses of anesthetics. Although minimum duration was achieved at lower doses (KX: 100/10 mg/kg) but the number of mice attaining surgical tolerance were compromised (5/9). Furthermore, the variability of the individual mouse to same anesthetic dose revealed that there is no standard anesthetic combination as there is no standard mouse (Arras et al., 2001; Zuurbier et al., 2014). So, each laboratory maintain own standard according to experimental design. Hence, KX (200/15mg/kg) was suggested to be the best dose.

It is acknowledged that KX with acepromazine is considered suitable for the mouse but in the present study, we reported first time that KX along with atropine is also suitable combination to produce surgical tolerance without significant mortalities. Present study results were comparable to previous reports as KX with acepromazine produces surgical tolerance in 85% mice (17/20) (Arras et al., 2001) while KX with atropine result in surgical tolerance in 88 % mice (8/9). Moreover, induction time, immobilization, duration of surgical tolerance and recovery periods were also comparable to KX with acepromazine (Arras et al., 2001; Buitrago et al., 2008).

It is concluded that ketamine: xylazine along with atropine at dose rate 200/15/0.05 mg/kg is suitable for surgical interventions in BALB/c mouse. However, further studies should be conducted to observe cardiac dynamics and physiological parameters for this combination.

ACKNOWLEDGMENTS

Authors are thankful to Higher Education Commission (HEC; 20-2242/R&D/11-2455) Pakistan for providing funds to establish mice colony and embryology laboratory in Department of Theriogenology, University of Veterinary and Animal Sciences, Lahore, Pakistan and to Dr. Mushtaq Ahmed, Lecturer, Department of Theriogenology, for statistical analyses.

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Publication Dates

  • Publication in this collection
    24 Oct 2019
  • Date of issue
    2019

History

  • Received
    20 Apr 2017
  • Accepted
    23 Sept 2018
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